[From the U.S. Government Printing Office, www.gpo.gov]
Portsmouth
H a r b o r
Marine
F i r e f i g h t 1 n g
Contingency
Plan
OPERATION MANUAL
JUNE 1988
0
00
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PORTSMOUTH HARBOR MARINE FIREFIGHTING
CONTINGENCY PLAN
OPERATION MANUAL
June 1988
Prepared by: MARITECH of Newmarket, New Hampshire
Principals: Captain David B. Moskoff
Daphne M.N. Fotiades
Prepared for: New Hampshire State Port Authority
Director: Ernest Connor
In Conjunction with
New Hampshire Office of State Planning
Principals: William Ray
Stephanie D'Agostino
U . S . DEPARTMENT OF COMMERCE NOAA
COASTAL SERVICES CENTER
2234 SOUTH HOBSON AVENUE
CHARLESTON, SC 29405-2413
"The New Hampshire Coastal Program provided a grant for the
preparation of this manual which was financed in part by the
Coastal Zone Management Act of 1972, as amended, administered by
the Office of Ocean and Coastal Resources Management, National
Oceanic and Atmospheric Administration." June 1988. To MARITECH.
PMVertY Of CSC Library
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PORTSMOUTH HARBOR MARINE FIREFIGHTING
CONTINGENCY PLAN
OPERATION MANUAL
TABLE OF CONTENTS
i MAINTENANCE SHEET Record of Changes
1.0 INTRODUCTION Background
Purpose
Participants
Legal Basis
Maintenance
2.0 JURISDICTIONS
3.0 NOTIFICATION
4.0 'PLAN' ACTIVATION
5.0 ROLES AND RESPONSIBILITIES Vessel Personnel
Municipal Fire Departments
U.S.C.G. Agencies
6.0 C014MUNICATIONS
7.0 EQUIP14ENT AND RESOURCES Inventory
Special Resources
8.0 FACILITY INFORMATION
9.0 COMMAND POST
10.0 EMERGENCY OPERATING CENTER (EOC)
11.0 STAGING
12.0 INCIDENT RESPONSE POSITIONS
13.0 STRATEGY AND TACTICS
14.0 STABILITY
15.0 VESSEL MOVEMENT WITH FIRE ONBOARD
16.0 FIRE CONTROL BERTHS
17.0 GROUNDING, SCUTTLING AND SINKING SITES
18.0 ENVIRONMENT
19.0 APPENDIX
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MAINTENANCE SHEET
for the
PORTSMOUTH HARBOR MARINE FIREFIGHTING
CONTINGENCY PLAN
OPERATION MANUAL
'Change Number I Date Change Recorded Person Recording Change
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1.0 INTRODUCTION
1.1 Background
The New Hampshire Port Authority has undertaken to develop a
Marine Firefighting Contingency Plan (hereinafter referred to as
'Plan' or PHMFCP) for the Port of Portsmouth and Piscataqua
River. The 'Plan' is conceptually different from other U.S.
port and Portsmouth Harbor marine incident plans. The PHMFCP
Operation Manual is derived in part from these plans. It has
been developed with the intent to avoid conflict with the
Portsmouth Harbor and regional plans listed in Section 1.1.1.
The Operation Manual is intended to complement COTP plans for
the Port of Portsmouth which have been promulgated by MSO,
Portland, Maine. At this time, however, several port and
emergency plans on which this 'Plan' is based, are undergoing
revisions and updating. Until those revisions are finalized and
all plans coordinated, there are plan information differences.
The differences are basically Notification Schemes, the
Jurisdiction Grid, task descriptions, checklists and similar
information.
The Portsmouth Harbor Marine Firefighting Contingency Plan has
been promulgated by the New Hampshire Port Authority and Office
of State Planning as a series of project components. These
include Inventory, Fire Hazard Assessment, Training, Needs and
Recommendations, and, this Operation Manual. As a component of
this 'Plan'r the Operation Manual has been developed to help
provide for increased coordination of the established
multi-agency response to fire onboard a vessel. The 'Captain of
the Port(COTP) Joint Piscataqua River Marine Disaster Plan, is
the recognized marine firefighting and marine disaster plan for
Portsmouth Harbor. LPG incidents are covered under the 'COTP
LPG Vessel Management Plan and LPG Emergency Contingency Plan'.
The PHMFCP Operation Manual contains 1.)enhanced information
from the plans listed in Section 1.1.1, and, 2.)various matters
not written into the existing marine incident plans relevant to
marine firefighting. Information contained herein is 1.)unique
to the Portsmouth Harbor Marine Firefighting Contingency Plan
both in format and content, and 2.)generally accepted standard
for ports and harbors throughout the United States, customized
and developed for Portsmouth Harbor, New Hampshire and Maine.
No plan should be considered finalized as contingency planning
is an ongoing process. According to the USCG Marine Safety
Manual, "A contingency plan enables decision makers to take
expeditious and predictable actions to prevent or mitigate
potentially disastrous conditions. Contingency planning does
njo_t replace good judgment and experience in an emergency;
however, it augments those qualities significantly ... Contingency
planning is a long-established practice among emergency
services, its goal being to maximize efficiency when an
emergency occurs."
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Page 2
Every marine fire event is different. Plan participants and
agencies change. Ideas change; concepts change and new
information is constantly being researched. Marine firefighting
principles change. New products also affect strategy, tactics
and decision making. The guidelines set here must always be
applied on a case by case basis. Never hesitate to seek
technical and professional expertise. Marine firefighting is
highly specialized and it is impossible to determine all events
that may occur and/or actions to take. Concerns of and
interpretations by participants in the development of this
'Plan' and Operation Manual, and generally accepted practices
may change. Do not hesitate to question, confirm or redesign.
1.1.1 Plans.
Experience from previous marine firefighting incidents has
clearly indicated the importance of contingency planning and the
identification of necessary resources from federal, state, local
and private levels. A marine firefighting incident,
particularly of a major nature will most likely require
resources beyond those locally available. Accordingly, a number
of existing local plans were combined into the PHMFCPr and
marine fire resources were identified to address these issues.
Plans reviewed for applicability to the Portsmouth Harbor Marine
Firefighting Contingency Plan (PHMFCP) include:
-COTP LPG Vessel Management and Emergency Contingency
Plan
-Emergency Oil Spill Containment and Removal Strategies
for Piscataqua River Terminals
-Inventory of the Natural Resources of the Great Bay
Estuarine System
-COTP Joint Piscataqua River Marine Disaster Plan
-New Hampshire Hazardous Materials Incident Emergency
Response Plan
-Oil and Hazardous Materials Pollution Contingency Plan
-Oil Pollution Control Training Manual: NHWSPCC and
Coastal Energy Impact Program
-Sea-3, Inc. Emergency Procedures
Plans that were not reviewed nor incorporated in the development
of the PHMFCP, but are also important to the port area include:
the IMSO Portland Subregional Oil and Hazardous Substances
Pollution Contingency Plan', those under consideration by the
Portsmouth Naval Shipyard, Newington Mass Casualty Plan, and all
waterfront facilities and agency response plans, among several.
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Page 3
Agencies with responsibility for Portsmouth Harbor and outlying
marinas and harbor areas, as well as marinas outside the COTP
zone within state boundaries, have marine firefighting concerns.
The 'Plan' as is, does not specifically lend itself to incident
response in these areas. Further contingency planning by
individual fire departmentsf waterfront facilities, New
Hampshire and Maine State agenciesi, and federal agencies is
encouraged based upon the meetings, discussion and flow of
information between February 1988 and May 1988. Due to the
organizational and jurisdictional uniqueness of Portsmouth
Harbor, response planning for facilities and harbors should be
done as individual pre-fire plans where not already done so.
1.2 Purpose
The purpose of this Operation Manual is to provide increased
coordination between organizations and resources responding to a
marine fire incident for the protection of Portsmouth Harbor.
The manual includes information on prefire as well as marine
firefighting incident response activities. It addresses
multiple agency response to a waterborne emergency. It lists
current resources of equipment and personnel. The manual may
help establish design of a comprehensive resource and
information system which enables more timely and facilitated
response efforts.
This Operation Manual should not be viewed as the ultimate
version for enhancements are desirable. The schematics need to
be monitored and tested at regular intervals by marine fire
incident response agencies and other participants.
1.3 'Plan' Participants
Participation in the development of this project and use of this
Operation Manual is voluntary. Twenty nine (29) agencies listed
in various incident plans were invited to participate in the
development of the PHMFCP. These groups represent a cross
section of agencies who may or will be involved in marine fire
incident response. However, the list is not all inclusive. In
the event of a major marine fire, it is possible that other
plans may be initialized and other agencies will join.
Accordingly, all agency response will be automatic per existing
plans. Activity and response may come from many, including
Maine, New Hampshire, U.S. Department of Transportation and
U.S.C.G., Department of Defense and Portsmouth Naval Shipyard
and Pease Air Force Base, municipal and private agencies.
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Page 4
1.3 'Plan' Participants (continued)
The list of those who were contacted throughout the project
follows in the format used for PHMFCP development purposes.
Shorebasg
Department of Transportation - New Hampshire
Fire Marshal - New Hampshire Department of Safety
Mainer Department of Environmental Protection
Mainey York County Emergency Management Agency
Municipal Fire Departments of:
Newington, N.H. Rye, N.H.
New Castle, N.H. Eliot, Maine
Portsmouth, N.H. Kittery, Maine
Office of State Planning - New Hampshire
New Hampshire Department of Safety HAZMAT Inspectors
New Hampshire Fire Standards and Training Commission
Office of Emergency Management - New Hampshire Governor's
Pease Air Force Base
Marine ShiRboard
Isles of Shoals Steamship Company
Portsmouth Naval Shipyard
Portsmouth Navigation Division
United States Coast Guard
Marine shoreside
Granite State Minerals
Bureau of Bridge Maintenance
National Gypsum Company, Inc.
New Hampshire Port Authority
New Hampshire Water Supply and Pollution Control Commission
Public Service Company of New Hampshire
Sea-3, Inc.
Simplex Wire and Cable Company, Inc.
C.H. Sprague & Son Company, Inc.
This is not a mutual aid Operation Manual per se. The PHMFCP
operational organization relies on implementation of the
existing mutual aid organization of the involved agencies and
plans listed under Section 1.1.1 Plans, and Section 1.3 'Plan'
Participants. Mutual aid agreements are signed for other plans
whose implementation may be compatible with use of this
Operation Manual and the PHMFCP project components. It should
be recognized that effective mutual aid is necessary to a major
marine fire incident. Mutual aid requests should be originated
through appropriate channels according to existing arrangements.
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Page 5
1.3 'Plan' Participants (continued)
Events can occur however, which necessitate the withdrawal of
mutual aid resources by a response agency. According to policy
of the 'Piscataqua River Marine Disaster Plan', "Should the need
arise for participating agencies to withdraw their resources
during a response under this plan, it should be done after
discussion with other agencies on scene." The 'Piscataqua
River Marine Disaster Plan' does not apply to all agencies and
is a voluntary plan. However, this practice applies to most
mutual aid agreements. Conditions may also occur which limit
resources to 'assistance as available' which is the policy of
most federal agencies.
1.4 Legal Basis
The Portsmouth Harbor Marine Firefighting Contingency Plan
Operation Manual has no authority to supersede existing plans,
arrangements or agreements between various local, state,
federal, private agencies and parties; nor does implementation
of this Operation Manual exclude the invocation of any other
plan listed herewith, or, recognized elsewhere either locally,
statewide (Maine or New Hampshire) , federally or private. The
Operation Manual and PHMFCP integrate information and statements
from existing plans. This is not to designate, or imply consent
or approval by any agency as to the legal basis or acceptance of
this 'Plan'; or that this 'Plan' takes precedence over any other
existing plan or plans.
This Operation Manual is currently a guideline to be used in
conjunction'with accepted plans. All reasonable attempts have
been made to use accurate and reliable information. Use of
information from any plan does not imply, suggest, endorse, or
recommend validity and accuracy of plans.
1.5 'Plan' Maintenance
The PHMFCP is under the authority of the New Hampshire Port
Authority. Considerations regarding 'Plan' and Operation Manual
maintenance should be directed to the Director, New Hampshire
Port Authority, Box 506, Portsmouth, New Hampshire, 03801.
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Page 6
2.0 JURISDICTIONS
Jurisdictions are ofttimes considered the territorial range of
authority or control of an agency. They sometimes include lines
of authority and chain of command. For this Operation Manual,
jurisdiction is defined in standard terminology as the right and
power 1.) to interpret and apply a plan within its
jurisdiction, 2.) of authority or control, 3.) of administration
and rule, and 4.) within the territorial range of an agency.
Understanding the complexity of jurisdiction and change of
command has been one of the more difficult challenges past
marine fire response agencies have coped with. A triangle of
incident command is formed by the Chief Fire Officer, Captain
of the Port and Captain of the vessel; unless a Defense Area is
involved, or the incident is declared a pollution or HAZMAT
occurrence. Very basically said,, the Chief Fire Officer has
responsibility for the municipality and adjacent area as they
fall under Incident Command. The COTP has responsibility for
the safety of the Port. The Captain has responsibility for the
vessel and crew. Wherever the chain of responsibility leads
from or points to, each commander has an obligation to protect
life and structure within their jurisdiction. It is difficult
to prepare for disagreements between any one or all of these
Commanders. However, written understandings regarding the
authority of Incident Command may help and should be considered
for an Operation Manual.
This section contains three parts on jurisdictions. The first
is a List of Jurisdictions. It is derived from key marine
incident plans for some key marine incident organizations. This
information is included to supply an understanding of how
jurisdiction is defined for Portsmouth Harbor within the PHMFCP
scope. Only information supplied by the jurisdictional agency
is included except for that of fire departments.
The second part is a Jurisdiction Grid. It was developed from
existing information and discussed during workshops and
afterwards. It charts jurisdictional control as the
relationship between territorial boundaries and the nature of an
incident. The detail and format of the Grid is unique to
Portsmouth Harbor. It has been reviewed by and developed with
appropriate authorities. Howeverr its legal basis is only
insofar as it may be adopted by existing plans, and has been
preliminarily agreed to by agency representatives. It is at
this time, an up-to-date and detailed listing of who is in
charge and under what circumstances. The third part is Change
of Command. Since this is an important issue for Portsmouth
Harbor's multi-jurisdiction environment, some examples have been
highlighted.
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Page 7
2.1 Part One: Jurisdiction By Plan for Some Key Marine Fire
Incident Response Agencies.
l.municipal Fire Departments:
In general:
Jurisdiction: The geographical boundaries of the municipality
including the waters of the Piscataqua River up to the middle of
the river and state boundary, extending along the shoreline and
sided by boundaries of adjacent municipalities. Marine
firefighting incident jurisdiction for municipal firefighters is
also determined by the nature of the incident.
2.United States Coast Guard:
COTP Portland,, Maine LPG Vessel Management Plan and LPG
Emergency Contingency Plan
Jurisdiction: Navigable Waters of the United States
MSO Portland,, Maine Subregional Oil and Hazardous Substances
Pollution Contingency Plan
Jurisdiction: Discharges of oil or hazardous substances into or
upon the navigable waters of the United States, adjoining
shorelines, or into or upon the waters of the contiguous zone.
USCG MSO Piscataqua River Marine Disaster Plan (also referred to
as COTP)
Jurisdiction: Navigable waters of the United States and adjacent
waterfront facilities on the shores of Maine and New Hampshire
3. Vessel: Jurisdiction: master has responsibility for the
safety of the vessel and crew.
4.Sea-3, Inc.:
Sea-3r Inc. Contingency Plan
Jurisdiction: The Chief Fire Officer is in charge of an
incident at Sea-3r Inc.: such incident being within the
geographical boundaries of the Newington township. Presumably
the Chief Fire Officer is from the Newington Fire Department.
(See Needs and Recommendations - National Defense Areas.)
5.New Hampshire Governor's Office of Emergency Management:
N.H. Hazardous Materials Incident Response Plan
Jurisdiction: Covers all of New Hampshire which includes those
areas of the harbor that are within state boundaries.
Jurisdiction does not override local jurisdictions and is, by
definition, a support-role type of jurisdiction.
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Page 8
Jurisdiction by 'Plan' (continued)
6.New Hampshire Fire Marshal:
N.H. Hazardous Materials Incident Response Plan
Jurisdiction: In charge of hazardous materials transportation
incidents for all areas of New Hampshire within state boundaries
and those of New Hampshire harbor areas. This is under review.
7.N.H. Department of Safety/Division of Enforcement:
N.H. Hazardous Materials Incident Response Plan
Jurisdiction: Covers all of New Hampshire which includes those
areas of the harbor that are within state boundaries. Case by
case.
2.2 Part Two: Jurisdiction Grid
No single organization has the sole responsibility for fighting
ship f ires in and along the Piscataqua River. Numerous
agencies are tasked with protecting the harbor, riverr adjoining
waterways and land which may be affected by a marine fire
incident response. While the US Coast Guard is commonly thought
to be responsible for all ship fires,, this is not the case.
Coast Guard firefighting activity is limited. USCG authority
and responsibility to handle marine firefighting is not
comprehensive. (See Section 5 Roles and Responsibilities)
The Jurisdiction Grid following on pages 9 and 10 outlines
initial Incident Command (IC) / On Scene Coordinator (OSC) for
several locations of vessel fire according to the nature of the
incident and who is in overall charge. This grid addresses
jurisdictional authority for various local (Maine and New
Hampshire), state (Maine and New Hampshire), and federal
agencies including Department of Transportation and Department
of Defense.
Federal agencies will be represented by a federal On Scene
Coordinator (OSC) . As circumstances dictate, the federal OSC
may also act as OSC in overall charge; IC in other terms. When
a Chief Fire Officer assumes IC,, a federal OSC will also be
present though not in overall charge. To avoid semantics and
confusion on whether the individual is called IC or OSC per its
organization's title, a '/1 has been inserted between titles.
The term 'IC/OSC' indicates overall in charge of an incident,
whether or not the individual is called IC or OSC acting in
overall charge.
It is not customary in United States' ports for private agencies
to command an incident. This is so for facility owners and
operators as well as vessel owners and operators. Salvage
companies and the like are generally brought in after initial
response operations and command.
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PORTSMOUTH HARBOR MARINE FIREFIGHTING
1988 JURISDICTION GRID
FOR
VESSEL FIRE INCIDENT COMMAND/
VESSEL FIRE ON SCENE COORDINATOR
OCCURRENCE OF FIRE ONBOARD A VESSEL BY LOCATION AND THE NATURE
OF THE INCIDENT WITHOUT POLLUTION AND HAZARDOUS MATERIALS
FIRE EVENT INITIAL INCIDENT COMMAND/OSC
MOORED AT FACILITY:
1. PIER/WHARF Chief Fire Officer
---------------------------------------------------------------
2. DOCKING/UNDOCKING Chief Fire officer
NOT MOORED AT FACILITY:
3. ANCHORED WITHIN MAINE OR
NEW HAMPSHIRE FIRE DEPT.
JURISDICTION COTP or COTP REPRESENTATIVE
----------------------------------------------------------------
4. IN TRANSIT ENTER WITHOUT
FIRE; FIRE OCCURS COTP or COTP REPRESENTATIVE
----------------------------------------------------------------
5. IN TRANSIT ENTER WITH FIRE
UNDER CONTROL COTP or COTP REPRESENTATIVE
----------------------------------------------------------------
6. IN TRANSIT
COLLISION/HARD AGROUND
IMMOVABLE COTP or COTP REPRESENTATIVE
----------------------------------------------------------------
7. IN TRANSIT
COLLISION/GROUNDING
IM14EDIATELY MOVABLE COTP or COTP Representative
The term IC/OSC indicates overall in charge of an incident
whether or not the agency refers to the position as Incident
Command or On Scene Coordinator. Federal agencies are
represented by an OSC when acting as over all in charge or as
federal agency representatives.
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Page 10
VESSEL FIRE INCIDENT COMMAND/
VESSEL FIRE ON SCENE COORDINATOR
OCCURRENCE OF FIRE ONBOARD A VESSEL BY LOCATION AND THE NATURE
OF THE INCIDENT WITHOUT POLLUTION AND HAZARDOUS MATERIALS
FIRE EVENT INITIAL INCIDENT COMMAND/OSC
MISCELLANEOUS:
8. PNSY: WATERFRONT PNSY Chief Fire Officer
----------------------------------------------------------------
9. PNSY: DEFENSE AREA PNSY Chief Fire Officer
10. PAFB:PLANE WITH VESSEL
ON WATER Undetermined
----------------------------------------------------------------
11. PAFB: DEFENSE AREA-DFSP PAFB Fire Department
----------------------------------------------------------------
12. PAFB,: DEFENSE AREA-Sea-3j Inc. Undetermined
13. VISITING VESSEL-DOT Undetermined
14. -DOD Undetermined
15. -Foreign Undetermined
16. SMALL CRAFT-RECREATIONAL:AFLOAT USCG Station Portsmouth
Harbor in charge. Discretion
17. SMALL CRAFT-COMMERCIAL :AFLOAT used for vessel size and
response capability.
----------------------------------------------------------------
18. SMALL CRAFT-RECREATIONAL:DOCKED Chief Fire officer in
Charge. Remain at pier.
19. SMALL CRAFT-COMMERCIAL :DOCKED No setting afloat
unless permission granted
by the COTP.
20. OUTSIDE FIRE DEPT. JURISDICTION/ The COTP will consult with
IN JURISDICTION OF THE COTP Chief Fire officers for the
decision to bring the
vessel in.
21. STRADDLES STATE AND
MUNICIPALITY BOUNDARY COTP or COTP Representative
22. USCG STATION
PORTSMOUTH HARBOR Per the USCG Portsmouth
Harbor Plan
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Page 11
2.3 Part Three: Change of Command
There are events which may affect a change of command.
Possibilities include inter-agency jurisdiction change,
intra-agency change, geographic change, inability to perform,
and request to change.
For exampler due to the generally transited navigation routes of
the harbor, a vessel underway may change jurisdiction between
states, municipalities and federal areas. Referring to the Grid
for vessels with fire underway or anchoredf the OSC (IC in other
terms) is the COTP MSO Portland, Maine even as it changes
geographical water boundaries. As soon as the vessel is docked
or docking,, OSC shifts to landbased IC of the municipality or
agency where it has docked. To reverse this, if it is decided
to move the docked vessel per orders of the COTP consulting with
appropriate agencies, the IC originating with the landbased
agency shifts to the USCG COTP OSC as it moves from the dock.
Another example for a vessel underway is a person to person,
intra-agency change of command. During the time it takes the
COTP to travel from Portland,, Maine to the Portsmouth Harbor
areaf the COTP may appoint a federal OSC to command until the
COTP arrives to assume command. If the COTP is also IC/OSC,,
most likely this same representative will fill both positions
until assumption of command by the COTP. The appointment of the
COTP representative will be on a case by case basis. Incident
Command for a vessel underway with fire may by circumstance,
also temporarily rest with the vessel's masterf familiarly known
as the Captain.
Refer to the Jurisdiction Grids on Pages 9 and 10 for the
jurisdictional listing of these occurrences. Depicted below is
the triangle of command formed by the Chief Fire Officer,
Captain of the Port and Captain (Master) of the vessel.
Chief Fire Officer Captain of the Port
Captain of the Vessel
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Page 12
3.0 NOTIFICATION
The notifications for marine fire call-ups are:
1. Vessel Moored at Facility
2. Vessel Not Moored When in Transit or Anchored.
The incident is without declaration of pollution or hazardous
materials. Refer to pages 15 and 16 for the Notification
layout. It should be noted that these Notification schemes have
not been finally approved. They MUST be tested and all parties
MUST agree to their use.
Notification schemes from the following plans were
pictographically compiled and united into the call-ups for these
two Marine Fire Incident Notification Schedules. Since the
PHMFCP is a combination of these 'Plans', the notifications
differ accordingly.
-State of New Hampshire Oil and Hazardous materials Pollution
Contingency Plan:P.79
-State of New Hampshire Oil and Hazardous Materials Pollution
Contingency Plan:Initial Oil-Hazardous Material Spill
Notification
-
Newington oil Spills Notification Procedure
-Newington Hazardous Material Spills Notification Procedure
New Hampshire Hazardous Materials Incident Response Plan:
Hazardous Materials Notification
-Piscataqua River Marine Disaster Plan-Plan Activation
-COTP LPG Facility/Vessel Moored Incident:Emergency call-up
-COTP LPG Plan for Vessel Harbor Transit Incident:Emergency
Call-up
-Concept of York County Emergency Management Agency: Emergency
Operating Center initiation: on-scene coordinator
3.1 General Basis of Notification/Call-up
Some of the general rationale for both layouts is combined in
this section. It is mentioned for information purposes as there
are differences between existing schemes and these charts
regarding, 1. sequence of calls and, 2. agency contacts from
existing notif ications. Refer to the charts to follow these
points.
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Page 13
Rationale:
ROW l.: Most likely to be first observers/first callers. Each
group is able to telephone or marine radio.
Facility personnel- des i gnated per existing plans; may be first
to note incident; maintain contact with vessel or are able to
make notification for vessel; first on scene/first caller.
Vessel personnel-designated per existing plan; first on scene.
USCG on Scene-may be first on scene per existing LPG plan-MSO;
relationship with and proximity to New Castle Group;
Bridge Oper ators- excel lent observation of harbor; monitor
channel 13; may be first observer/first caller.
Pilot-first on scene; marine radio communications capability.
Tug Operators-first on scene; marine radio communications
capability.
ROW 2: Have the capability and responsibility to initialize long
series of vital telephone calls.
USCG Station Portsmouth Harbor -excellent observation point; 24
hour monitoring of marine radio and full time dispatch; landline
telephones; marine radio telephones; link with COTP;
relationship with fire departments; trained in emergency
response; back-up to round one of calls. Early notification
also affects immediate dispatch of SAR boats and 'assistance as
available'. Boats are usually crewed and depart New Castle
Station within two minutes of notification.
Row 3 and on: Emergency services responsible and capable of
initializing next series of calls.
Local Municipal Fire Department- important to notify as soon as
possible for incident response; has dispatch to follow emergency
operating procedures and additional notifications. The
municipal fire department will call the Portsmouth Naval
Shipyard Fire Department.
Newington Dispatch agency (Durham dispatch) operates from
Durham-expected to soon have two full-time professional
dispatchers on duty 24 hours a day who will in turn notify other
fire departments on alert status or as conditions warrant.
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Page 14
3.1 Notification (continued)
State Police-will notify local police; NH Office Of Emergency
Management and Maine Emergency Management Agency, and others as
appropriate.
NHOEM and MEEMA-may initialize various emergency plans as
necessary; NHOEM may activate the Hazardous Materials Incident
Response Plan; OEM/CD will open the EOC as appropriate in
Concord. Maine agencies will have been notified starting their
chain of emergency operations and EOC openings as appropriate.
USCG MSO Portland-required to be notified; can appropriately
organize maritime operations; responsible for port safety; will
notify appropriate federal agencies; Maine and New Hampshire
State Police and environmental agencies as required; tugs and
pilots to get underway; will notify the Portsmouth Naval
Shipyard Tugboats, NHPA and NH Dept. of Transportation.
Others-other appropriate agencies to alert or advise of a
potential or ongoing incident listed in existing plans.
3.2 Differences with Existing Notification Schedules
The Notification charts integrate several plans. Major
differences include:
1. Double notification of the Maine and New Hampshire State
Police for verification purposes . The fire departments notify
State Police early in the chain. USCG MSO notifies State Police
later in the chain.
2. Portsmouth Naval Shipyard (PNSY) mutual aid. The local fire
departments will notify the PNSY fire department. The USCG will
notify the PNSY tugboats.
3. Additions. Marine terminals and Marinas were added per
consideration of the Newington notification scheme and the need
for incident status notification along the river. Terminals,
marinas and piers will be notified by the fire department within
whose jurisdiction they are located.
4. Change of dispatch. For vessel fire moored, dispatch has been
changed to Newington. It is no longer Portsmouth.
S. USCG Station Portsmouth Harbor (SAR New Castle). Are able to
start SAR immediately.
6. Additions. Vessel distress signal for 'Fire Aboard'indicated
as a continuous sounding of the whistle.
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Facility ersonnel
Personnel No initial pollution
Vessel
USCG on Scene No initial flazmat
PROPOSED Bridge Operators
Vessel Fire Notification By Tele one or
When Moored at a Facility Marine Radio
June 1988 Unadopted Suggested Signal: If a
Vessel Moored at a facility sounds
the DISTRESS SIGNAL (a continuous
USOGSAR sounding of the whistle), this
Station New Castle should be considered a Notification
(Portsmouth Harbor) of Vessel Fire.
Verify Verify
Local Municipal FSCG MSO Portland
Fire Dept. (IC) COTP OSC)
Federal
Agencies
,Portsmo h-@FD
0/ ,Newington FD York County Sheriff's Department Portsmouth Navigation
New Ca-stle FD Rockingham County Sheriff's Dept. PNSY W.O. for Tugs
Kittery FD York County EMA NH Dept. of Transport.
.@,Elio FD Hospitals in NH Area, REMIS, E.R. NHPA
Hospitals in ME Area, REGENT, E.R. NH WSPCC
PNSY FD ME DEP
PAFB FD
ME State Police-
NH State Police
Verify Last
9
ia@ [A:
A-1,
Local Police NH State Police
Mar:ine Terminals Local Police ME State Police to
and :Mar=inas sl NH OEM (D
Ln
�
P't 0
vessel ersonnel
USCG on Scene No Initial Pollution
PROPOSED Bridge operators No initial Hazmat
Assist Tug Opertrs
Vessel Fire Notification
When Not Moored at a FacilitY
When in Tranjit or Anchored By Telephone or
June 1988 Marine Radio Unadopted Suggested Signal: -If a
W Vessel Moored at a facility sounds
USCG SAR the DISTRESS SIGNAL (a continuous
Station New Castle sounding of the whistle), this
.(Portsmouth Harbor) should be considered a Notification
of Vessel Fire.
Newington Local FD in USCG MSO Portland Federal
Fire Department Jurisdiction (ODTP OSC/IC) Agencies
Durham Dispatch
Portsmouth FD
New Castle FD Portsmouth Naviclation
York County Sheriff's Department PNSY W.O. for Tugs
Kittery FD
Eliot FD Rockinqham County Sheriff's Dept. NH Dept. of Transport.
York County EMA NHPA
PNSY FD Hospitals in NH Arear REMIS, E NH WSPCC
PAFB FD Hospitals in ME Area' REGE@7rv E.R. ME DEP
- - - - - .- - i
ME State Police
NH State Police Verify Last
Local Police
F
Ne in
Fir e De
ur m
Dhwa
4outhFD
E
Local Police NH State Police
NH OEM ME State Police
Marine Terminals
and Marinas
�
Page 17
4.0 PLAN ACTIVATION
The PHMFCP does not have a formal activation process. The
Operation Manual is designed for use as a guideline to marine
firefighting incident response. Initiation and activation of
marine incidents, medi-vac, pollution, HAZMATr police,
transportation, evacuation, and other plans and issues should
already be organized through emergency plans. Some of these
plans are being revised.
The following description of circumstances which activate some
incident 'Plans' relevant to marine firefighting is included for
information purposes. As a guideline, the Operation Manual may
be used in conjunction with these 'Plans' provided that
differences, such as Notification schemes, are appropriately and
reasonably worked with.
USCG MSO Piscataqua River Marine Disaster Plan.
Initial ization/Activation: The plan is activated at the request
of a Chief Fire officer of, New Castle, Newington, Portsmouth,,
Eliot, Kittery, PAFB,, PNSY or the COTP, when a fire or other
disaster is of such magnitude that several or all the listed
communities will or may be impacted.
COTP Portland, Maine LPG Vessel Management Plan and LPG
Emergency Contingency Plan
Initial ization/Activation: Notice of arrival of gas ship
scheduled to make a port call in Portsmouth.
Sea-3p Inc. Contingency Plan
Initialization/Activation: Incident to cause initial alarm to be
struck.
MSO Portland Subregional Oil and Hazardous Substances
Contingency Plan
Initial ization/Activation: Discharges of oil or hazardous
substances into or upon the navigable waters of the U.S.,,
adjoining shorelines, or into or upon the waters of the
contiguous zone.
N.H. Hazardous Materials Incident response Plan
Initialization/Activation: Any HAZMAT incident reported to State
Police Communications.
�
Page 18
5.0 ROLES AND RESPONSIBILITIES
Among the major items to design for an effective response effort
are Roles and Responsibilities. Roles and Responsibilities can
be detailed description of various tasks. An agency or response
person who assumes a role, should have as complete as possible
an understanding of that role, and the accompanying
responsibility. The Roles and Responsibilities which have been
assigned in 'Plans' of Section 1.1.1, are listed in the IPHMFCP
Needs and Recommendations Assessment'. They should be
considered for inclusion in this manual following appropriate
procedures. Due to a number of issues described in the Needs
and Recommendations Assessment, only generalized descriptions of
three groups are included in the Operation Manual. These are for
informational purposes only as follows:
5.1 Master of the Vessel and Crew: The master and crew can be
integral elements of response. A general organizational chart of
vessel personnel appears on Page 19.
The Master (Captain), officers and crew are familiar with the
vessel, cargoy and vessel fire protection system. The Chief
Engineer and Engineering officers are particularly familiar with
the ship's fire protection and vessel systems.
According to the Marine Safety manualr
"The presence of local firefighters does not relieve
the master of command or transfer the master's
responsibility for overall safety on the vessel.
However., the master should not countermand any
orders given by the local firefighters in the
performance of firefighting activities, unless
action taken or planned clearly endangers the
safety of the vessel or crew."
Policy regarding the relationship between local firefighters
and the master should be developed for Portsmouth Harbor
regarding jurisdictional in charge and expectations of each
party. If this is not developed and conflicts arise, the above
quote may be of assistance in resolving a dispute for the
interpretation as to who is in charge.
�
Page 19
Vessel Personnel
MASTER RADIO OPERATOR
PURSER
DECK DEPT.7 ENG. DEPT. I STEWARD DEPT
CH. MATE CH.ENG. CH. STEWARD
2nd MATE 1 st ASS'T. COOKS
3rd MATE 2nd ASS'T. F-MESS MEN
T 1
NLICENSEF@ 3rd ASS'T.
FU DECK -7---
NLICENSEE
ENGINE
The chain of command aboard ship. (Courtesy of the Maritime Administrati"on)
Towards the smallest possible crew
15,000 ton cargo liner
circa 1960
Master
Deck Department Engine Department Catenng Department
Chief Officer Chief Engineer Ch Stc-ard/Purscr
2nd Officer 2nd Engineer 2nd Steward
3rd Officer 3rd Engineer Chief Cook
4th Officer 4th Engineer 2nd GookIllakcr
2 Cade" (Deck) Sth Engineer Butcher
Radio Officer 6th Engineer 3 Sic.ards
4 Quartermasters C/Elce-trician 2 Catering Boys
ICarpenter 2nd Electrician
I Bosun 2 Cadets (Engine)
IBosun 's Mate I ER Storekeeper
8 Able Seamen I Donkeyman
2 Ordinary Seamen 4 Grcascrs
2Boys 2 Bo'Ys 1'0'1'A I - S 5
30,000 (on Containership 30,000 ton Containcrship
circa 1987 circa 1990
M as ter Ntaster
Deck Department Chief Watchkccpcr I Deck or
Chief Officcr 2nd Watchkccpcr Engine
2nd Officer 3rd Watchkorper CommunKJ111HIS
3rd Officer I Elcctronic@ Srecialist
Radio/ Elect ton ics Officer 4 Mechanics
/,- ffint Department ICook
Chief Engineer '1 *0 FA 1. 10
2nd Engineer
3rd Engineer
6 General Purpose Ratings
Catering
Cook
Cook/Ste-ard
TOTAL 16 T) 0 pl:
�
Page 20
5.0 Roles and Responsibilities (continued)
5.2 Municipal Fire Departments: Local Fire Departments are
responsible for fire protection within their jurisdiction.
When the Chief Fire Officer assumes position of Incident
Command, examples of Roles and Responsibilities may include:
-assume position of Incident Command if fire is at the pier
-assume charge of all aspects of the landbased fire fighting
operation. This action does not relieve the Master of command
of the vessel; nor should it conflict with circumstances when 1.
the COTP is IC/OSC, 2. the COTP is federal OSC,, 3. Defense
agency assumes federal OSC.
-establish and position personnel at the Command Post
-formulate a plan of action for the extinguishment of the fire
and the safety of personnel and property
-direct the activities of all personnel and equipment engaged in
firefighting
-determine the need for and request mutual aid
-request dispatch of necessary personnel and equipment
-make all requests for USCG personnel and equipment through the
COTP
-establish liaison with vessel master and crew
-establish liaison with other agencies as appropriate and in
accordance with initiation of other plans
-establish workable communications system if not pre-established
-procure damage control plansp damage stability data and
stability information of the vessel from pre-fire planning files
or on scene. Begin stability monitoring.
-request assistance from police regarding pre-assigned roles
-request assistance from emergency management and civil defense
agencies regarding pre-assigned roles
-alert Bureau of Bridge Maintenance to observe and be alert for
bridge openings and closings and evacuation if necessary
-alert railroad companies of incident response underway and SOP
on train movements through the area
-may request Temporary Flight Restrictions (TFR's) to provide a
safe operation environment for disaster relief aircraft and
prevent air congestion from observing aircraft(also through
Pease and COTP)
-request assistance from Red Cross as predetermined
-activate medical emergency plans as appropriate and within
jurisdiction
-assume roles and responsibilities through other plans
-assume Incident Command per conditions of 'Change of Command'
Section 2.3 of this Operation Manual
5.2 Mutual Aid Fire Departments: Perform normal operating
procedures.
-respond according to activated plans
�
Page 21
5.0 Roles and Responsibilities (continued)
5.3 US Coast Guard: The USCG has responsibility for safety and
security of ports and waterways as outlined in the Marine Safety
Manual and the COTP and MSO Portland, Maine plans. The Captain
of the Port (COTP) has federal responsibility for the safety and
security of the port. USCG Station Portsmouth Harbor acts
according to pre-assigned USCG SAR roles and responsibilities.
"The COTP renders assistance as available, based on
the level of training and the adequacy of equipment.
The Commandant intends to maintain this traditional
"assistance as available" posture without conveying
the impression that the Coast Guard is prepared to
relieve local fire departments of their
responsibilities."(Marine Safety Manual)
Various roles and responsibilities the COTP may assume during
marine fire incident response include:
-assume federal OSC as provided under jurisdictional authority
-assume OSCIIC if vessel is not docked
-assume operational control of Coast Guard forces
-establish safety or security zones as necessary
-
may control the movements of vessels and boats
-may obtain tugs, towboats and Pilots as necessary
may request Temporary Flight Restrictions (TFR's) to provide a
safe operation environment for disaster relief aircraft and
prevent air congestion from observing parties
-provide information on waterfront facilities which may be
involved
-respond to pollution or hazardous materials discharges. Removal
activities may be delayed until it is safe to proceed.
-provide advice on marine issues to fire departments
-assume roles and responsibilities through other plans
-assume Incident Command under conditions of Change of Commandr
Section 2.3 Operation Manual
�
Page 22
6.0 CONNUNICATIONS
Landbased and marine based firefighting require orderly and
planned communications operations. Basic communication
considerations include:
-Use designated frequencies only unless authorized to use
others.
-Do not engage in speculation over radio circuit. Radiotelephone
communications are monitored by numerous parties.
-Traffic should be limited to essential communications.
-Limit transmission time; Others may need to use the frequency.
-Establish and use dedicated landline relays and communcation
systems.
-Establish a dedicated marine firefighting channel/frequency.
-Establish communication SOP.
-Prepare backup communications.
Marine incident radio communications vary from those of typical
structure fires both in kind and number of response agencies.
Accordingly, a number of ongoing activities may be using radios.
These activities include:
-Search and rescue
-Resource coordination
-Harbor traffic control
-Movement of involved vessel(s)
-Fire control
-Hazardous materials control
-Pollution control
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Page 23
6.1 Frequencies.
For a marine fire, the municipal firefighters will probably use
the VHF-FM frequencies normally used and designated per the
'Piscataqua River Marine Disaster Plan.' These are:
-INITIAL TONE 154.190
-LOCAL GOVERNMENT Various
-SEACOAST 154.190 (usually channel 1)
-FIREGROUND (FMARS) 154.280 (usually channel 2)
If the incident is large, many agencies may be toned during the
initial 20-30 minutes. It should be anticipated that SEACOAST
may be difficult to work during this period. LOCAL GOVERNMENT
frequencies may not be clear if shared with local police who are
heavily involved in traffic control and/or resident evacuation.
The most likely waterborne units able to communicate on SEACOAST
and FIREGROUND are the PNSY tugs unless others are given a fire
department radio. However, floating units will probably have
marine radios. According to the 'Piscataqua River Marine
Disaster Plan't "the working radio frequency for all water based
responding units will be 157.100 MHz, channel 22FM".
Other important radio channels/frequencies include:
-CH 6 156.30 Safety
-CH 12 156.60 Vessel Traffic Management
-CH 13 156.65 Navigation
-CH 16 156.80 Calling; Distress
-CH 21 157.05 Government (USCG)
-CH 22 157.10 Government (USCG)
-CH 23 157.15 Government (USCG)
-CH 81 157.075 Government (USCG)
-CH 83 157.175 Government (USCG)
These frequencies may be utilized as designated by the COTP.
Their use for ship/ship or ship/shore traffic can be convenient
since most vessels are able to monitor "calls" from parties who
do not know what channel is being "worked". If the USCG
designated working channel (CHANNEL 22) became too crowded
during a Portsmouth Harbor fire, the COTP might designate one of
the other channels listed above to alleviate the situation. The
Communications section in Appendix 20 and the Training Manual
identifies various communication systems, capabilities,
limitations and logistical concerns. The next page is an Index
of Other Commonly Used Marine VHF Frequencies.
�
Page 24
Other Marine VHF Frequencies
Channel Ship TX Coast TX
Designator Use MHz MHz
6 Safety (IS) 156.300
7 Commercial 156.350 x
8 Commercial (IS) 156.400
9 Commercial 156.450 x
10 Commercial 156.500 x
11 Vessel Traffic Mgmt. 156.550 x
12 Vessel Traffic Mgmt. 156.600 x
13 Navigation 156.650 x
14 Vessel Traffic Mgmt. 156.700 x
15 Envior.(CS) ------- 156.750
16 Calling;Distress 156.800 x
17 State Cont. 156.850 x
18 Commercial 156.900 x
19 Commercial 156.950 x
20 Port Oper. 157.000 161.600
24 Pub.Corres. 157.200 161.800
25 Pub.Corres. 157.250 161.850
26 Pub.Corres. 157.300 161.900
27 Pub.Corres. 157.350 161.950
28 Pub.Corres. 157.400 162.000
65 Port Oper. 156.275 x
66 Port. Oper. 156.325 x
67 Commercial 156.375 x
68 Non-Commercial 156.425 x
69 Non-Commercial(SC,,CS) 156.475 x
70 Non-Commercial(IS) 156.525
71 Non-Commercial(SC,CS) 156.575 x
72 Non-Commercial(IS) 156.625
73 Port.Oper. 156.675 x
74 Port.Oper. 156.725 x
77 Commercial(IS) 156.875
78 Non-Commercial(CS,SC) 156.925 x
79 Commercial 156.975 x
80 Commercial 157.025 x
84 Pub.Corres. 157.225 161.825
85 Pub.Corres. 157.275 161.875
86 Pub.Corres. 157.325 161.925
87 Pub.Corres. 157.375 161.975
88 Commercial 157.425 -
Source: 'NHWSPCC Oil Pollution Control Training Manual' granted
permission by Motorola Corporation.
�
Page 25
7.0 EQUIPMENT AMD RESOURCES
7.1 Inventory
Identification and evaluation of inventory is necessary to plan
for and enact marine firefighting response decisions. Since
tactical decisions may be based on available resources, it is
necessary to identify resources that are particular to marine
firefighting needs. Equipment and resources necessary to handle
a major marine fire vary in type and quantity depending on
circumstances. Mutual aid resources may be provided by related
discipline agencies and are also helpful.
In an effort to coordinate with existing plans and operations'
inventories, an Inventory was conducted of PHMFCP agencies. All
agencies were requested to list only those resources and
equipment that would be committed to a mutual aid incident
involving Portsmouth Harbor marine fire. The inventory provided
by the respondents is listed in Appendices 22 and 23.
7.2 Special Resources
Special resources are available and may be necessary for marine
fire incident response. They range from paper documents to a
flare gun with which to re-ignite a fire if appropriate. It is
important that firefighting forces know what resources can
assist them with combat and where these sources can be obtained.
Unique attributes of marine fire incidents include:
- Lack of experience
- Lack of familiarity
- Access limitations to vessel
- Movability of vessel
- Potential amount of combustible material
- HAZMAT/Pollution potential of incident
- Special personnel and equipment hazards
- Special resources
Special resources which are designed for or may be adapted to
marine firefighting needs include:
-Special documents and information
-Special firefighting equipment
-Special support equipment and operations
-Special craft and apparatus
-Special fire extinguishing agents
-Special personnel and organizations
These items are detailed in Appendix 21 under Special Resources.
�
Page 26
8.0 FACILITY INFORMATION
Facility information may be provided by the facility owner or
operator, USCG or Army Corps of Engineer publications. The New
Hampshire Port Authority and fire departments have limited
facility information. Such information is useful in sizing up
an incident and for pre-fire planning. Appendix 24 contains
facility information from the following sources:
8.1 The New Hampshire Port Handbook: 1987-1988: Contains pier
and facility information on pages 32-38 and important port and
harbor information such as tides. This book is available from
the New Hampshire Port Authority or Portsmouth Chamber of
Commerce. It has been distributed at PHMFCP meetings. The
Appendix 24 contains a map of the terminals. (Current)
8.2 Directions for Responders: Directions to major harbor
terminals. Staging areas for mutual aid equipment/personnel may
be different locations.
8.3 U.S. Army Corps of Engineers Piers, Wharves, and Docks -
Piscataqua River:Port Series No. 1 : Contains information on
location of the waterfront facility, owned by, operated by,
purpose for which used, type of construction, description
including berthing space, transit sheds, mechanical handling
facilities, railway connections, highway connections, water
supply, electric current, fire protection other than city,
remarks. (Revised 1985) Available through the US Army Corps of
Engineers and various libraries.
8.4 MSO Subregional Oil and Hazardous Substances Pollution
Contingency Plan Section 302.2-1 Piscataqua River Basin:
Contains information on Facility name and address, products
handled at the facility, and the amount stored in barrels
(bbl).(1987) Available through the USCG.
8.5 US Coast Guard Monthly Traffic Summary for Portsmouth:
Contains current information on vessel activity in Portsmouth
usually for tankers, barges, and cargo vessels. (Monthly. An
example of the December 1987 Monthly listing is in the Appendix
24.) Available through the USCG.
�
0
Insert Facility/Vessel Pre-Fire Plans.
0
0
�
Page 27
9.0 COMMAND POST
The purpose of a Command Post is to provide the Incident Command
organization with a location from which to l.receive reports and
information, 2. meet with advisors and 3. make decisions. A
Command Post is the 'location where emergency personnel will
meet for evaluation and coordination of the incident response.'
(NH Hazardous Materials Incident Emergency Response Plan). The
best and most effective decisions are generally made with
accurate information supplied by knowledgeable resources. Also,
the environment of the Command Center will usually affect the
quality of those decisions.
Criteria to be examined when establishing a Command Post
include:
-proximity to fire
-safety of command personnel
-reasonable contact with non-command post personnel
-view of fire area
-sufficient space for advisors and technical experts
-out of the weather
-communications are set-up, functioning, and effective: includes
landline telephone(s)
-if a Command vehicle: upwind of the incident site; insure it is
remote enough to prevent having to relocate.
-physical comforts for extended stay
-logistics: proximity to copy machines, food, etc.
-locations: landbased or waterbased(not necessarily the vessel
on fire):vessel; pier; facility office; IFO; Coast Guard
Portsmouth Harbor Station; town halls.
Pre-fire planning on the location of Initial and Secondary
Command Posts for the various Jurisdiction Grid scenarios on
pages 9 and 10 is recommended. If Response Levels are enacted
per the Recommendations, list the various locations on the Chart
on page 29.
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Page 28
10.0 EMERGENCY OPERATING CENTER (EOC)
Emergency Operating Centers are operational locations. They may
double as an Incident Command Post depending on circumstances.
EOCs are also operated by agencies who are not Incident Command.
The next page is a Chart of a partial list of EOC and Initial
and Secondary Command Post locations for participating agencies.
The list is incomplete. Completed information may help to
locate a particular EOC or Command Post. If a responder has
incorrect directions, is unfamiliar with the area, or a change
of Command Post has occurred, this information might be useful
in this Operation Manual shared by multi-agency response groups.
�
June 1988 Portsmouth Harbor Marine Firefighting ContingencV Plan
Project Response Agencies Possible Sites for
Emergency Operating Centers (EOCs) and Incident Ccnmkand Posts
If Fire At: Possible EOC Sites/Tel. Initial Command Posts/Tel. Secondary Conmnd Posts/Tel. tv
0
Response Agency Terminal ... (For Any Size Fire) (For Initial/Minor Fire) (For Fallback/Major Fire)
-- - - - ----- - -------- - ------- - - ----------- ------------- - ----- - - - -- - ----- --
Municipal Fire Depts.:
Eliot FD N/A State Rd. 207-439-1355
Kittery FD WA Walker St. 207-439-2262
0
PNSY
New Castle FD N/A 43 Main St. 436-2515
USOG Pier
Newington FD N/A 80 Foxpoint 436-5737
Sprague-NIN
Sea-3, Inc.
Simplex W&C
Portsmouth FD N/A 170 Court436-1127/8-5000 W
PSNH-Schllr
PSNH-Mobil
Gold Bond
NiPA-State
Granite SM 0
Rye N/A 563 Washington 964-6411 Z
- -- - ----------- - -- - ------ --- ----------- --- - --------------------------------
Federal Agencies:
USOG ODTP WA
Offshore
PAFB FD N/A
DFSP La
PNSY FD N/A M
PNSY to
----------- ----- - --- - - - ------- - ---------- - ------- - --------- - ----- ko
State Agencies:
ME Dept. Envrn. Protec. WA
ME York County EMA N/A Court Hse 207-324-1573/78
NH Dept. of Safety Insp WA
NH Govenor's OEM N/A State E)DC NH 800-852-3792
NH Fire Marshal N/A
NH Port Author ity N/A
NH DES-WSPOC N/A
- - --- I------------------ - - - - - -- - ----------- - ------- L--------------- - -----------
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Page 30
11.0 STAGING
Staging areas may be devised into areas for apparatusy special
resources, medical and rescue units, large supplies, feeding and
rest, hazardous materials, pollution, police, public works,
media, and others. Pre-fire plans should determine the most
probable locations of these needs. If this has not been
planned, the appointment of a Staging Area Commander should
alleviate much of this problem during an incident. The Staging
Area Commander may coordinate all activities in the staging
area,
�
0
This section to be completed with Staging plans.
0
0
�
Page 31
12.0 INCIDENT RESPONSE POSITIONS
The need to assign tasks to responsible personnel is apparent
for a major marine fire incident. This page lists examples of
various roles that may be helpful to implement. The 'Incident
Command Personnel Checklist' on the following page may be of
assistance with this type of organization.
Command Post Supervisor: coordinate and supervise the ongoing
activities, present information to the Incident Commander.
Staging Area Commander: coordinate all activities in the staging
area. Responsible for briefing and directing companies to
appropriate areas. Recording arrival times and ETAs.
Logistics/Procurement Officer: procure firefighting equipment,
personnel and firefighting resources as directed by Incident
Command; track and monitor cost and expense aspects for later
disbursements.
communication Officer: establish and maintain communication
between Command Post and all other participating agencies;
monitor operations and be prepared to implement back-up
communications.
Coordinator of Air Supply: responsible for air supply and
monitoring full and used air bottles as well as advising the
Logistics officer or Incident Command of air status.
Coordinator of Equipment: responsible for establishing equipment
area and monitoring equipment. Advises Logistics Officer.
Stand-by area Coordinator: monitoring arrival of resources in
the stand-by area and maintaining communication with Staging
Area Commander regarding status of resources and equipment
arriving and waiting on assignment.
Historian or Scribe: responsible for recording information,
important times and events. Information is not only useful to
monitoring ongoing efforts but may be used for debriefing and
events i.e. legal at a later time.
Special Agency Coordinator: responsible for greeting, recording
and monitoring activities of special agency representatives.
Appraising Incident Command or Command Post Supervisor or
Staging Area Commander of status. Special agencies may include:
EPA, National Transportation Safety Board(NTSB), legal counsel,
insurance, facility and vessel owners and representatives,
Regional Response Team (RRT), Federal Railroad Administration
(FRA), etc.
Coordinator of Media/Public Affairs Officer: responsible for
media statements and contact between media and Incident Command.
Messenger: responsible for personally communicating information
between various officers, coordinators, Incident Command as
appropriate.
Other: other FEMA and IC positions as appropriate:i.e. Sector
Commander, Safety Officer, Water Supply Officer.
Liaison: Shipboard and Shorebased Incident Command Liaisons to
communicate messages between shoreside command and vessel
command.
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Page 32
INCIDENT COMMAND PERSONNEL CHECKLIST
for
PORTSMOUTH HARBOR MFCP
Location Date Time
Suggested Personnel Include:
Time Enroute Time
litle/pescription Name ed w/ETA On Scene
Fire Chief/Fire Officer
Vessel's Master/Officer
USCG COTP/Representative
Terminal Manager/Rep.
Vessel Owner/Rep. (Agent)
Cargo Owner/Rep. (Agent)
Insurance Representatives
Vessel Chief Engineer
Vessel Chief Mate
sarine Chemist (s)
Harbor Pilot(s)
N.H. Fire Marshal/Rep.*
N.H. Port Authority Dir.
N.H. OEM Representative
N.H. DES - W.S. & P.C.
York County EMA Rep.
Maine D.E.P. Rep.
Medical Response Rep.
Logistics Fire Officer
Staging Area Commander
Command Post Historian L
Presently, Fire Marshal is in charge of N.H. HAZMAT vessel incidents.
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Page 33
13.0 STRATEGY AND TACTICS
Considerations on strategic and tactical actions are always on a
case by case basis. Pages 32 - 48 contain information which may
be used in this regard. The sequence of information is:
1. STRAT/TAC Action outlines: Reviewed in the
training program. Possible actions to take for
various locations and types of shipboard fires.
(Pages 34-38).
2. Information Gathering Sheets:
A. Initial Response: Important types of information
to gather for size-up and response planning. The
information is also useful to relay to other
agencies who may initialize appropriate action
in addition to fire department response. (Page 39)
1
B. Secondary Vessel Information: Continue size-up,
provide more detail on vessel conditionr vessel
cargo, Search and Rescue (SAR). (Page 40)
3. Operational Checklists:
A. Incident Command Personnel: various personnelr
name and activity times for monitoring whereabouts
of key personnel. (Page 32)
B. Vessel Information and Documents: List of
pertinent information to obtain for response
efforts. Tracking the document inventory. (Page 41)
C. Vessel Fire Containment: Tactics and issues
to be considered for fire containment. (Page 42)
D. Vessel C02 Smothering: Approaches and
information regarding C02 issues. (Page 43)
4. Associated Tables:
A. C02 Guidelines (Page 44)
B. C02 Tables It IIr II: for concentrations of C02
and conversion. (Pages 45,46r47)
C. Time-Temperature Grid: useful.for temperature
0 recording of C02 and inerted spaces. (Page 48)
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Page 34
STRAT/TAC Action Outlines
Possible actions to take for various locations of shipboard
fires.
Accommodation Space Fires.
1. Rescue primary.
2. Secure power.
3. Ventilate through portholes if necessary only when all
resources are ready. Cover against interior spread.
4. Extinguish: Use quick attack if possible.
5. Flash-over potential HIGH.
6. Check for fire extension.
7. Extinguishers not usually effective (application techniques)
8. Overhaul thoroughly - remove wall and ceiling panels.
9. Do Not rely on watertight or fire resistive bulkheads to act
as fire stop.
10.Air and personnel critical.
Fires in Cargo Holds.
1. Rescue primary.
2. Close all openings to hold(s).
3. Batten down hatches.
4. Consider using fixed system.
5. Tighten down hatches (caulk if needed).
6. If cargo is nitrates or sulfatest use speed and water.
7. Never use steam smothering if explosives are present.
8. NEVER ENTER HOLD WITHOUT SCBA.
9. Place charged hose lines on deck.
10.If entry is mader use hose lines.
ll.Investigate adjoining holds.
12.Cut holes only as needed and NOT in outer skin of vessel.
13.Have plugs available for all holes cut.
14.Cool skin of vessel.
15.Close all side openings early.
16.Standby while cargo is unloaded.
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Page 35
STRAT/TAC Action Outlines (continued)
Engine Room Fires.
1. Rescue personnel.
2. Consider using fixed system . The SIS POMEROL has Steam
Smothering for the bunker tanks and C02 for the engine
room; the C/S LONGLINES has C02 for the engine room.
3. Secure all non-essential engine room systems.
4. Cool boundaries.
If an attack must be made:
5. Establish vertical ventilation.
6. Establish attack teams (3 deep).
7. Access and attack.
8. Use foam and dry chemical on fuels.
9. Check for extension.
10.Divert critical systems to alternates, if possible.
Machinery Room Fires.
1. Rescue personnel.
2. Enter from as low as possible.
3. Secure all automatic controls.
4. Secure all power to area.
5. Cool boundaries.
6. Establish vertical ventilation.,
7. Establish attack teams (3 deep).
8. Access and attack.
Check for extension.
Electrical Room Fires.
1. Rescue personnel.
2. Secure all power.
3. Cool boundaries.
4. Attack as a Class A fire.
5. Check for extension.
�
Page 36
STRAT/TAC Action Outlines (continued)
Chemical Tanker Fires.
1. Rescue personnel.
2. Shut down cargo pumps.
3. Shut down all power to area.
4. Attack from up-wind.
5. Attack with Universal foam AND dry chemical.
6. Keep adjacent tanks cool.
7. Consider using fixed systems if available.
8. Be prepared to evacuate one-half mile down-wind.
9. Protect all teams with hose lines.
10.Use SCBA.
Petroleum Tanker Fires.
Deck Fires:
1. Rescue personnel.
2. Attack from upwind (still use SCBA).
3. Shutdown cargo and disconnect lines if possible.
4. Secure source of fuel on deck.
5. Maneuver ship if necessary.
6. Secure all pumping.
7. Use fixed foam monitorst if available.
..8. Use foam hand lines as second choice and backup.
9. Cool crews with water.
10.Close ullage hatchest PV valves, ventsr manholes, sounding
manifolds and fuel lines.
ll.NEVER APPLY WATER ON TOP OF FOAM THAT IS ON THE DECK.
12.Cool surrounding deck and structures with water.
13.Replenish foam blanket as needed.
14.Attack burning pressure leaks with dry chemical then blanket
with water fog or foam ONLY IF YOU MUST EXTINGUISH.
�
Page 37
Petroleum Tanker Fires (continued)
Tank Fires:
1. Rescue personnel.
2. Endrgize inert gas system.
@3. Maneuver ship to bring wind and seas to best advantage
of firefighting.
4. Status of tanks on fire:
a. loaded
b. partially loaded
c. empty
d. inerted
e. gas free
5. Secure all tank vents.
6. When fighting tank fires, consider the following:
a. Attempt to apply extinguishing agent(s) directly on
burning fuel through a holer vent line, rupture, ullage
covert or manhole.
b. If unable to get extinguishing agent on burning liquid,
attempt to:
1. cool tank with water
2. inject foam through vents
3. press up the tank with fuel or water
4. extinguish fire by injecting inert gas
5. defuel the tank
6. a combination of the above recommendations
c. Prevent fire from spreading to surrounding tanks by the
following or any combination of the following:
1. cooling down with water
2. if ruptured but not burningr cover with foam. (Do
not put water on cargo that has been covered with foam.)
3. press-up with fuel or water
4. inerting
5. maneuvering ship
6. after fire has been extinguished, cool down
surrounding tanksr deck, and cargo long enough to
prevent a flash
NOTE: The above actions may take seve.ral hours or days.
�
Page 38
LPG Guidelines f or Emergency Procedures. (COTP LPG Emergency
Contingency Plan. Appendix I).
1. Shut off source.
2. Normally LPG fires should not be extinguished until the
source can be shut off.
3. In the event of ignition, use water to cool down tankst
pipingr equipment and structures. Use water spray to protect
involved personnel.
4. Use high velocity fog in the dispersion of LPG vapors. Never
apply high velocity fog to the liquid.
5. Personnel remain upwind of leaks.
6. If it is necessary to remove an LPG vessel from a facility
dock to a safer area within the porty a delay of 30 to 60
minutes for disconnect must be expected.
7. Review detailed information on LPG emergency procedures and
the physical properties of flammability, specific gravity,
expansion ratio, and vapor pressure in the ICOTP LPG Plan
Appendices.
Pires in Pore and After Peaks.
1. Rescue personnel.
2. Shut down all power to area.
3. Contain in vertical zone.
4. Attack from below if possible.
5. Consider piping in smothering agent.
6. Consider high-expansion foam.
7. Expend all options before sending teams down a 'chimney'
into a fire.
�
Page 39
INITIAL RESPONSE INFORMATION
for
PORTSMOUTH HARBOR MFCP
(Primary Information)
Location -Date -Time
Get as many details as possible concerning the fire, the vessel
and injuries. Always verify information as soon as practicable.
Suggested information:
Location of Vessel
Vessel Name
Type of Vessel
Possible Victims,
Inj ur ies, Deaths
Primary Cargoes
Type of Fire
Location of Fire
on Vessel
Hazardous Chemicals/
Commodities Onboard
Number of Crew
Language (s) of Crew
Number of Passangers
Local Vessel Agent
Jurisdictions
Incident Command(IC)
On Scene Coord.(OSC)
HAZMAT Incident
Pollution Incident
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Page 40
SECONDARY VESSEL INFORMATION
for
PORTSMOUTH HARBOR MFCP
(Secondary Informati.on)
Location _Date -Time
Suggested information includes:
NOTE: This information will normally be sought after the INITIAL
INCIDENT INFORMATION (Primary Info) has been acertained.
FIRE INFORMATION
Vessel Access
Shoreside Exposures
Is Fire Under Control
Extent of Fire
Crew's Initial
Response and Effect
Assistance Required
Classes of Materials
0 Involved (A.B.CrD)
Specific Cargos and
Stores Involved
Amount and Types of
Fuels/Bunkers
Designate Staging
and Supply Areas
VICTIM INFORMATION
Personnel Accounting:
Crew, Passengerr
Facility, Bridget
Other Vessel, etc.
Determine Missing
Personnel
Locate Victims
Determine Injuries
0 Type and Extent
Provide Medical Aid
Provide or Arrange
for Transportation
�
Page 41
VESSEL INFORMATION AND DOCUMENTS CHECKLIST
I . for
OLocation PORTSMOUTH HARBOR MFCP Date- Time
Suggestions Include:
Requested Available At C.P.
Information and/or Documents' Yes. No Yes No Yes No Notes
1. Obtain Primary Vessel Info
(See Primary Info Sheet)
2. Obtain Secondary Info Sheet
(See Secondary Info Sheet)
3. Vessel Plans:
A. Prefire Plan or Survey
B. Fire Control Plan
C. General Arangement Plan
D. Other Plans/Blueprints
4. Vessel Cargo Information:
A. Dangerous Cargo Manifest
B. General Cargo Manifest
C. Cargo Arrangement/Layout
5. Vessel Communications:
A. Portable FM Radios
B. Marine Radios
C. Sound Powered Telephones
D. Electric Telephones
E. Cellular Telephones
F. Other
6. Vessel Stability:
A. Trim/Stability Booklet
B.,,.Damage Stability Docmnt
C. Damage Control Document
D. Primary Stability Info
(See Stability Info Sheet)
E. Secondary Stability Infol-- I- I
(See Stability Sheet on Page 50)
�
Page 42
VESSEL FIRE CONTAINMENT CHECKLIST
for
PORTSMOUTH HARBOR MFCP
Location _Date Time-
Suggestions Include:
Requested Completed
Tactic/Task Yes No Yes No Notes/Comments
1. Establish or secure ventilation
as appropriate in area of fire.
2. Establish boundaries. Consider
using vessel's vertical zones.
Determine Class A (60 Min) and
Class B (30 Min) bulkheads.
3. Close all fire doors if
possible.
4. Close all watertight doors if
possible.
5. Close doors, ports, hatches and
ventilators as appropriate.
Cool all 6 sides of fire area
as necessary. Consider using
vessel's equipment for this
purpose. Water should come off
surface warm or hot. Use all'
water sparingly.
7. Secure electrical power to
affected area and consider
de-energizing the lines that
run through fire area.
8. Endeavor to move combustibles
away from bulkheads and decks
in proximity of fire.
9. Remove hazardous cargo if
possible.
10. Maintain fire watch of all
adjacent areas (sides,, above
and below). Use fixed heat
detectors for additional
monitoring capability.
�
Page 43
VESSEL C02 SMOTHERING CHECKLIST
for
PORTSMOUTH HARBOR MFCP
Location Date Time-
Suggestions Include:
DO NOT ATTEMPT to smother explosivest nitrates, or sulphates.
If oxidizing agents in cargo, REMOVE if possible.
(See Portsmouth Harbor MFCP Training Manual Section 5 Pages 11-17)
Requested Completed
Tactic/Task Yes No Yes No Notes/Comments
la. Call for a Marine Chemist
lb. Call for Additional C02
if Necessary
2. Stop all mechanical fans/
ventilation to/from space.
3. Close all dampers, doors,
hatchest ventst portst
accessing space. Consider
leaving one (1) vent open
to prevent over-pressure
of space. Close after
complete initial discharge.
4. Insure all personnel are
evacuated from space to
be flooded.
5. Consider having protected
personnel monitor open C02
Room for manifold leaks.'
6. Doublecheck that:
A. No personnel in space.
B. Fans off-Space sealed.
7. Discharge C02 for initial
concentration of 60% or
more. If 2 valve control
system, lst Valve Control
then Cylinder Control.
(Remember to close bleed
vent from item #3 above).
8. Maintain at least 80% C02
concentration if possible.
Do not open space for at
* least 48 hours if possible.
9. Monitor temps and gases at
approx. 15 min. intervals.
10. Consider logistics getting
extra C02 to vessel.
�
Page 44
C02 GUIDELINES
1. Be certain personnel are evacuated.
2. Seal the space and secure ventilation,
3. Sequentially pull the control and cylinder release valves
as appropriate.
4. No concentration of C02 can be considered excessive.
5. Strive for an initial target application of 60%. Guidelines
to achieve 60% level are:
o Calculate total cubic feet of space.
0 Divide this volume by 9.
o Apply this number (in pounds of C02) to space.
Volume of Space/9 = # Lbs. C02 for Initial Application.
6. Try to obtain 80% C02 concentration to provide a reasonable
safety margin to insure extinguishment. Endeavor to maintain
80% C02 or better concentration for at least 48 hours before
opening space.
7. Monitor gas and temperature readings. Usually accomplished
by marine chemist.
8. Other inert gases may be substituted but different guidelines
may apply.
9. See Also PHMFCP Training Manual.
�
Page 45
C02 TABLE I
Minimum Percent Concentrations of C02 to be used for
Extinguishment of Various Materials are listed below. Use Table
II to calculate all ships' C02 systems to 34%. Use Table III to
calculate higher concentrations. Attempt to achieve as high a
concentration as practical with available amount of inerting
gas.
Material Percent
Acetylene 66
Acetone 31
Benzol 37
Benzene 37
Butadene 41
Butane 34
Carbon Disulphide 66
Carbon Monoxide 64
Coal or Natural Gas 37
Cyclopropane 37
Dowtherm 46
Ethane 40
Ethyl Ether 46
Ethyl Alcohol 43
Ethylene 49
Ethylene Dichloride 25
Ethylene Oxide 53
Gasoline 34
Hexane 35
Hydrogen 78
Isobutane 36
Kerosene 34
Methane 30
Methyl Alcohol 31
Pentane 35
Propane 36
Propylene 36
Quench & Lube Oils 34
Miscellaneous:
Dry electrical wiring insulation
hazards in general 50
Small electrical machines, wire
enclosures under 2000 cubic feet 50
Bulk paper storage and ducts 65
�
Page 46
C02 TABLE II
Pounds of C02 to achieve a minimum 34% concentration. As gas is
available, endeavor to achieve higher percentage to insure
sufficient concentration for extinguishment. Use Table III for
calculating quantities necessary for higher concentrations. Any
openings that cannot be closed at the time of extinguishment
should be compensated for by the addition of not less than one
pound of C02 per square foot of opening.
Volume = Length x Width x Height = Total Cubic Feet
Space in Cubic Feet Lbs. of C02/Cubic ft. Conversion Factor
Start- 140 1 pound per 14 .072 x cu.ft.
141 - 500 1 pound per 15 .067 x cu.ft.
501 - lr6OO 1 pound per 16 .063 x cu.ft.
1601 - 4,500 1 pound per 18 .056 x cu.ft.
4501 -50,000 1 pound per 20 .050 X cu.ft.
Over 50'0,000 1 pound per 22 .046 x cu.ft.
Example:
Engine Room: L X W x H Volume in Cu.Ft.
so @X 50 x 50 125,000 Cu.Ft.
Cu.Ft. x Conv.Factor Lbs. of C02
125,000 Cu.Ft. x .046 5750 Lbs. C02
Therefore, 5750 Lbs. of C02 are required to achieve a 34%
concentration for the Engine Room of 125rOOO Cu. Ft.
To achieve an 80% concentration, multiply the Conversion Factor
for 80% by the 5750 Lbs. required for a 34% concentration.
3.71 x 5750 Lbs. 21,333 Lbs. of Co2
Therefore, 21,333 Lbs. of C02 are required to achieve an 80%
conc entration for the Engine Room of 125rOOO Cu. Ft.
�
Page 47
C02 TABLE III
Conversion Factors applied to 34% concentration. Apply these
factors for specific material in Table I after using Table II to
calculate pounds of C02 necessary for 34% concentration.
Percent Factor
35% 1.05
36% 1.08
37% 1.11
38% 1.14
39% 1.18
40% 1.2i
41% 1.25
42% 1.28
43% 1.32
44% 1.36
45% 1.40
46% 1.44
47% 1.48
48% 1.52
49% 1.56
50% 1.60
51% 1.65
52% 1.70
53% 1.75
54% 1.80
55% 1.85
56% 1.90
57% 1.95
58% 2.00
59% 2.07
60% 2.14
61% 2.20
62% 2.26
63% 2.32
64% 2.39
65% 2.46
66% 2.53
67% 2.60
68% 2.67
69% 2.74
70% 2.81
71% 2.89
72% 2.98
73% 3.06
74% 3.14
75% 3.22
76% 3.30
3.40
78% 3.50
79% 3.60
80% 3.71
81% 3.82
82% 3.95
�
.Page 48
TDM-TE"ZRATURE GH
For Recording Temperatures of Inerted Spaces.
Date:- Person Record 9- RCrdng Bqpmnt-
Location Time -Temp, Time Temp Time Temp Time Temp
�
14.0 STABILITY Page 49
The intent of stability information in the Operation Manual is
to provide a basic understanding of vessel stability and
dewatering to Portsmouth Har.bor fire personnel who must
comprehend and base decisions upon expert advice that should be
available during an incident. Special resources are important to
stability monitoring and calculations.
Though some degree of stability is built into a vessel, the
vessel's stability may become precarious. This may be due to
the introduction of large amounts of water among several
reasons. It is important that landbased firefighters understand
the principles of stability and need for dewatering in order to
practice prudent strategy and tactics.
The Stability Section in the Appendix is an enhanced version of
Section Seven in the 1PHMFCP Training Manual'. It includes
basic information, how to figure calculations with examples, and
explains the various resources for stability and dewatering
analysis. Stability is one of the more difficult marine studies
for the municipal Chief Fire Off icer/Inci dent Commander to
learn. Due to the importance of stability concerns and the
degree of difficulty in learning the subject, it is advised to
review stability information as often as possible. The
stability information on pages 50 and 51 are checklist issues
and concerns of vessel stability for Incident Command use.
�
Page 50
VESSEL STABILITY INFORMATION
for
Location PORTSMOUTH HARBOR MFCP -Date -Time
Suggested information includes: (See Stability section and Appendix 26)
PRIMARY STABILITY INFORMATION
Vessel Drafts: PORT STBD Comments
Fwd Fwd
Get the vessel's Mid Mid
drafts as soon Aft Mid
as possible. Read
the hull marks. Mean Mean
Vessel List: (In Degrees) PORT STBD Comments
A. Inclinometer Onboard
B. From Water - Fwd/Aft
C. Diff. in Mdshp Marks
D. Best Guess/Estimate
E. Other
Vessel Cargo Tank Status
Vessel Cargo Hold Status
Vessel Double Bottom & Deep Tanks
Other Ballastf Fuel & Water Tanks
Depth of Water at Site - Minus(-) Deepest Draft Clearance Dist
Type of Bottom Material (Rock, Glacial Till, etc.)
Tides Over the HIGH LOW
Next 48 Hours: Time Height Time Height COMMENTS
1. Always consider the
height of the tide when
predicting the vessel's
bottom clearance.
2. Also, convert all net
water weight forecasts to
increased mean draft with
the vessel's TPI Factor.
SECONDARY STABILITY INFORMATION
Water Flow Into Vessel
Vessel Dewatering Capability
Water Weight Net Gain/Loss
Vessel Watertight Capability
Mooring Line Status
�
Page 51
VESSEL STABILITY CHECKLIST
for
PORTSMOUTH HARBOR MFCP
Location Date Time
Suggestions Include: (See accompanying Stability section of this Manual.)
CAUTION: DO NOT Counterflood (add water low in vessel) to improve
stability if free surface is the cause of the list.
Requested Completed
Tactic/Task Yes No Yes No Notes/Comments
1. Gather stability info and
maintain during incident.
(See Stability Info Sheet)
2. Obtain Trim and Stability
Booklet, assoc. documents
and info from crew - most
likely Master, Chief Mate.
3. Determine and establish
primary and secondary
flooding boundaries.
A. Close watertight doors.
B. Seal spaces-plug leaks.
4. Coordinate expertise to
assist with stability
matters (crew, MSO, NHPA,
Pilots, PNSYt Strike Team)
5. Have Vessel Critical List
determined for present
loaded condition.
6. Calculate rate of water
introduction/flooding.
7. Calculate dewatering rate:
A. Vessel's fixed pumps.
B. Vessel's portable pumps.
C. Pumps brought onboard.
8. Reduce Free Surface first:
A. Pump out spaces.
B. Completely fill spaces.
9. Lower Center of Gravity:
A. Remove high weights.
B. Move high weights down.
C. Add weight low.
10. Lowering height of water
within the vessel:
A. Keep drains clear.
B. In accom. areas, remove
deck plumbing fixtures.
C. Drain swimming pools. I I I
�
Page 52
15.0 VESSEL MOVEMENT WITH FIRE ONBOARD
Pursuant to United States Coast Guard Marine Safety Manual Vol.
VI, Ports and Waterways Activities, Section 8.E. Firefighting On
Vessels 1. Essential Considerations: "Often , the COTP must make
the difficult decision whether to allow a burning vessel to
enter or be moved within the port." According to the Marine
Safety Manual, "A request for entry into the port by a burning
vessel under declaration of "force majeure" should be evaluated
under criteria listed in the Marine Safety Manual. For
Portsmouth Harbor, it would be an unusual case to bring a
burning vessel into the harbor per the COTP considerations.
There is the possibility of anchoring it off Gunboat Shoals, or
as conditions warrant, the vessel may go to Portland, Maine for
assistance.
Basic USCG considerations for allowing a burning vessel to enter
or be moved within the port are stated in the Marine Safety
Manual as:
a. Location and extent of fire
b. Class and extent of cargo involved
c. Possibility of explosion
d. Possibility of sinking/capsizing
e. Hazard to crew or other resources at present location
f. Weather forecast
g. Maneuverability of vessel (Is it a dead ship?)
h. Effects on bridges
i. Alternatives if the vessel is not allowed entry or movement
j. Inspection to determine that the fire is already contained
and under control
k. Little likelihood it will spread
1. A great possibility exists that the fire may be extinguished
with available port equipment before secondary explosion or
spread of fire
m. Appropriate parties, including officials have been
consulted.
Other general criteria include:
a. Fire Chiefs within whose jurisdiction the vessel will move
have been consulted, as well as other appropriate parties
b. shoreside firefighting is ready
c. pier for firefighting
d. firefighting capability
e. pollution potential - equipment and resources ready
f. HAZMAT potential - equipment and resources ready
g. stability and dewatering situation
h. must obtain plans of vessel
i. status of vessel extinguishing systems
j. have contacted owners, agents or master of vessel regarding
arrangements to pay for all costs
k. liability, insurance
1. availability of tugs and barges
m. if no SOP exists, this type of information should be
considered.
�
16.0 FIRE CONTROL BERTHS Page 53
Several considerations are involved in the selection of a pier
for vessel fire suppression and salvage operations. These
include pier flammability and combustibilityr proximity to other
piers, structural and safety integrity, access for boats,
vehicles, and staging areas. Suitability of site selection may
be determined by municipal, state and federal regulations and,
opinions. For site specific determination, the US ARMY Corps of
Engineers Port Series Number one contains a detailed listing of
facility and equipment. NFPA 300 series documents also provide
suggestions for safe firefighting piers and suitable pier
design. NFPA 1405 should address this issue when released in
1989. It is suggested that a review of standards from several
disciplines, including oil companies terminal and waterfront
facility design specifications, for pre-fire planning is
helpful.
Other considerations include:
- location readily accessible to equipment and resources
including adequate water supplies
- sufficient water depth; however, the depth of water should not
exceed the depth of the vessel's hull. For large vessels in
Portsmouth Harbor, this should not be a critical concern as
most berths have depths of forty-five feet or less. The depth
should not be so deep as to cover the vessel's main deck in
the event of sinking
- the harbor bottom should be as level as possible, preferably
sandy sediment or fine glacial tills as is the case at some
Portsmouth sites
- severity of the fire
- possible spread of fire to shore areas
- possible damage to piers and shore facilities
- potential loss of facility revenue
- proximity of the pier to populated areas, bridges, railroad,
highways, national defense areas
- environmentally sensitive areas
- water and electricity availability
- prevailing winds and currents
- pollution potential
- HAZMAT potential
- vessel cargo
- vessel stability
- vessel extinguishing systems
- vessel plans
- vessel construction
�
Page 54
17.0 GROUNDING, SCUTTLING AND SINKING SITES
Grounding, scuttling and sinking sites require review of
environment, navigational hazard, salvage operations, available
resources and the vessel and cargo issues. The offshore
grounding site selection criteria may be different from harbor
grounding and anchorage site selection. Portsmouth Harbor sites
must account for limited waterborne firefighting capability,
harbor activity and harbor use. The lack of shoreside
International Shore Connections further limits the use of
makeshift waterborne firefighting platforms. Criteria selected
from the Marine Safety Manual for anchoring or grounding
locations includes:
- bottom material; regarding the risk of rupturing vessel hull
- water depth, shallow enough so it will not sink below the
main deck level, yet deep enough that fireboats, salvage
barges, and tugs can approach
- environmental conditions: environmental protection
Criteria for intentional sinking are similar. These areas can
be selected pre-incident. A good selection comes from using the
input from related disciplines.
other considerations include:
- effects on Defense areas
- bridge and water traffic
- marinas
- involvement of two states: New Hampshire and Maine
- out of harbor: Isles of Shoals and vessel traffic in and out
of the Port of Portsmouth
�
0
Insert Locations:
Groundingr Scuttling and Sinking Sites
and Relevant Information.
0
�
Page 55
18.0 ENVIRONMENT
Environmental concerns are of great significance to the
protection of Portsmouth Harbor. Marine fire incident response
efforts should be coordinated with the various agencies tasked
with environmental protection. Such agencies include the USCG,
EPA, New Hampshire Water Supply and Pollution Control
Commission, and Maine Department of Environmental Protection
among others. There are various plans addressing environmental
issues. For New Hampshire they include 'The Oil Pollution
Control Training Manual I , 'The Oil and Hazardous Materials
Contingency Plan' , and 'Emergency Oil Spill Containment and
Removal Strategies for Piscataqua, River Terminals'.
Environmental considerations are important if it is necessary to
scuttle or sink the vessel.
various concerns include:
1. Selection of Grounding, Scuttling and Sinking Sites.
2. Salvage Operations Procedures.
3. Pollution Issues.
4. Hazardous Materials Issues.
5. The Environment and Commercial and Recreational Activity.
�
Page 56
19.0 APPENDIX
This Appendix, similar to the information guides interspersed
throughout this Manual, contains reference guide information
which may be helpful for organizing vessel fire response
efforts.
20.0 Communications:
Narrative
21.0 Special Resources:
Narrative
Equipment Lists
22.0 Project Agency Inventory Information:
General Information Sheets
2-Way Radio Communications Inventory
Fire Department Apparatus and Onboard Equipment
Fire Station Stored Equipment
23.0 Vessel Inventories:
Condensed Vessel Inventories
24.0 Portsmouth Harbor Terminals:
NHPA Diagram of Portsmouth Harbor and Terminals
Directions for Responders to Terminals
Army Corp of Engineers Piers, Wharves and Docks
USCG MSO Portland Subregional Oil and Hazardous
Substances Pollution Contingency Plan
waterfront facility information on the
Piscataqua River Basin.
USCG Vessel and Cargo Information: December 1987
25.0 Stability:
Narrative
26.0 Tables: To provide marine-related mathematical conversions:
Common Equivalents
Determining Water Flow Through Holes
Static Head Pressure, Gallons Vs. Cubic Feet
27.0 Intentionally left blank
28.0 Intentionally left blank
29.0 Glossary
30.0 Acronym List and Abbreviations
31.0 Bibliography
�
Appendix 20
COMMUNICATIONS
This section identifies various communication systems,
capabilities, limitations and logistical concerns.
Ra-dio CommUnicationg
Radio communication planning is necessary to minimize confusion
and misinformation. Fireground communication considerations for
planning should include:
� The likelihood that many firefighting and emergency
response agencies may be operating at the incident.
� What common frequencies are available and what pre-
assignments can be practically addressed?
� What established, recognized radio procedures and call
signs can be used by the participating agencies?
� Limitations of portable radios onboard vessels.
Hardware. In addition to fire department radios, vessel,
terminal facility, USCG and others may have radios. Some may
have FM handheld portables that are very useful, particularly
for large scale incidents. others may have transportable or
mobile units that can also be of great benefit. Uncoordinated, a
number of problems might occur.
Radio capability such as programmability, scanning, simplex,
low/high wattage outputs, fixed channels and frequencies should
be considered when determining who may most need special
features. Features for handhelds to be used inside a large
steel vessel include:
� intrinsically safe or explosion proof
� minimum 5 or 6 watt output capability
� resistance to high humidity environments
� capability to attach remote microphones
� availability of charged spare batteries
� capability to charge spare batteries
Shipboard fire incidents are often complex situations requiring
hours and sometimes days to control. Therefore, it is important
to have spare handhelds and batteries as the hours wear on.
Inadequate information and communications due to lack of radio
equipment can be costly.
�
Appendix 20 Page 2
Radio Comunications (continued)
Presently, there are no full channel marine radios listed in the
inventories of municipal Portsmouth Harbor f ire departments.
Marine radios operate within the VHF-FM Maritime Mobile
Frequencies 156-162 MHz band. They have dedicated channels
corresponding to specified frequencies. Large vessels will
generally have at least two marine radios. Mounted units will
most often be located in the wheelhouse or the radio room. They
are normally electrified by the ship's emergency circuit.
Therefore, the radios would be operable by the ship's emergency
generator(s) should the main generators fail. At least one
radio is usually backed up by battery in case ship generated
electrical power is unavailable.
Agencies that have marine radios include:
� USCG units
� Portsmouth Pilots, Inc. (3 handheld portables)
� Portsmouth Navigation Tugs (2 mobiles in each)
� PNSY Tugboats YTB 771 & YTL 602
� NHPA Director (1 handheld portable)
Another type of radio is the single sideband radio (SSB). Large
vessels will probably have one. It may not have battery backup
since SSBs are usually more powerful radios. Some USCG cutters
have SSBs. Also, landline telephone patch can be performed by
marine operators for SSB traffic. This radio could be important
if the vessel was inbound with fire onboard, and, was outside
the 50 +/- mile marine radio range.
Many large vessels and marine terminals have their own handheld
FM portables. These radios will probably have preset frequencies
which should not interfere with fire department frequencies.
This provides for multiple dedicated working channels besides
154.280 (FIREGROUND) . These radios may be intrinsically safe
and are useful to safe operation in certain areas. An expanded
list of marine radiotelephone channels is provided at the end of
this section.
Concerns. The heavy steel construction of most large vessels
will inhibit interior transmission/recept ion capabilities of
most portable radios. Radio surveys will indicate the extent, if
any, of limitations that may exist. If inside an accommodation
area that is above the waterline and experiencing radio
difficulty, find a room against the outside. Try the radio next
to a porthole or window. The radio's capability should
significantly improve.
�
Appendix 20 Page 3
Radio Communications (continued)
Disadvantages. There are two major disadvantages of the handheld
radio. one is public exposure of the transmissions. The other
is the susceptibility of the transmissions to interference,
especially from more powerful units. Scanners have given
everyone the ability to monitor almost anyone's conversation and
high wattage units can blast through channels from dozens of
miles away. An Incident Commander on the pier deciding the
ship's fate with the Master on the bridge may need more privacy
and less interference than handhelds may provide.
Microwave Telenhone, Communicatigns
Cellular Telephone. Cellular telephones operate in the 800-900
MHz bands from repeater towers that provide coverage to specific
geographical areas. Dover's tower would be used for Portsmouth
Harbor communications. Some vessels may already have the phone
onboard and be immediately accessible by either another cellular
or landline-linked telephone.
SATCOM Telephone. Many larger vessels may also have Satellite
Communications (SATCOM) onboard. This unit's voice circuit has
extremely high integrity and reliability. With SATCOM, calls
can be placed or received just like a landline telephone through
the vessel's microwave satellite relay system. If the vessel is
inbound and on fire, this unit will succeed where cellular may
not, because it essentially has no limiting range. SATCOM is,
however, very expensive to use with charges about $10 per minute
for the voice circuit. When calling the vessel, it is possible
to reverse the charges or charge the call to the vessel's owner
or operator.
Intra-Vessel Fixed Communication Systems
Most large vessels have their own phone systems, intercoms,
public address systems, and other vessel communication systems.
It was previously mentioned that many ships have FM radios. If
the ship has an FM radio, often the compatible "base" FM units
are fixed in the wheelhouse, cargo office and/or engine room
control station.
Sound Powered Phones. Large vessels, especially US Government
vessels, will usually be fitted with sound powered phones (see
photograph on next page) . These phones are located throughout
the vessel at critical locations such as the wheelhouse, engine
room control station, emergency diesel generator room, cargo
control room, bow lookout post and steering gear room.
�
Appendix 20 Page 4
Sound Powered Phone
Handset
Operationl____7@
Button
(Depressed Under
Man's Index
Finger) Handset
Cradle
'J, *@-__.Generator
(Text by Crank Handle
MARITECH)
Station
Selector List
Station
(Photo Courtesy Dept,
Selector Switch
of Transportation)
Sound powered telephones are a reliable means of communication
within the vessel. They are not subject to the limitations of
radios. They have advantages over runners in that simultaneous
conversations by two or three parties can be conducted.
Sound powered telephones do not require an outside source of
electricity as do ship's intercoms or "talkbacks" and public
address systems. They make their own power supplies through two
different methods.
To signal another station onboard, set the selector switch to
the station number you are calling. Station numbers are listed
on the index. Then crank the generator handle. Be sure to give
at least three or four rapid cranks to activate a bell or buzzer
by the magneto current. This cranking rings a bell or sounds
the buzzer at the station being called.
On the inside of the handset is a spring-loaded button which
MUST BE DEPRESSED to either listen or talk. The speaker's voice
activates a diaphragm in the mouthpiece which transmits the
sound to the receiving station. Speech should be clear and
forceful, particularly if loud background noise exists.
�
Appendix 20 Page 5
Intra-Vessel Fixed-Communication Systems (continued)
Electric Telephone. Most commercial vessels including tugs,
have electric telephones. These will be much like landbased
telephones with rotary or push button operation. However, they
depend on the vessel's electricity to operate. On larger ship's,
they will probably be on the emergency circuit.
NTalkbackw or Intercom. The master control for this unit is
usually in the wheelhouse. The unit may function as follows.
The master control unit can monitor selected stations on a one
way basis. The master control station always receives unless a
sub-station is deliberately monitored through the sub-station's
speaker/microphone. The sub-station does not usually have the
ability to call the master control unit. This system may also
be connected to the vessel's emergency generator circuit like
the telephones. These systems vary from vessel to vessel.
Public Address System. This system operates similarly to
labdbased systems. It might be useful for immediate notification
of many people. A good example would be a decision to evacuate
the vessel. It might also be prudent to establish some Universal
Evacuation Signals and Procedures with the ship's whistle and
general alarm bells for personnel onboard. The International
Distress Signal for all vessels is "a continuous sounding of any
fog apparatusn (i.e. ship's whistle).
Runners. As mentioned, a major vessel fire incident requires
numerous agencies using large numbers of radios operating on
common frequencies. One of the methods to minimize radio
traffic is the use of "runners" or messengers as situations
dictate. Messages and/or responses are walked back and forth
between parties. Advantages and disadvantages of using runners
should always be considered.
Concerns. Communication equipment onboard seagoing vessels is
subject to considerable abuse from daily routine. Therefore,
most equipment is extremely rugged and dependable as long as the
unit and wire trunks remain intact.
Sound powered and battery operated units will be independent of
the vessel's electrical supply. Loss of the vessel's generation
capability does not necessarily become the loss of critical
communication equipment. This will depend on the individual
vessel. The wheelhouse need not be abandoned as a communications
center because vessel-generated electricity is lost. Successful
communications require flexibility and resourcefulness.
�
Appendix 21
SPECIAL RESOURCES
This section details six areas of special resources for marine
fire incidents of:
- Special documents and information
- Special firefighting equipment
- Special support equipment and operations
- Special craft and apparatus
- Special fire extinguishing agents
- Special personnel and organizations
SRecial Documents and-Informatign
Vessel Inventory or Survey. A sample MARITECH vessel inventory
has been provided each fire agency on the harbor. As possible,
this information should be obtained for larger vessels. It will
take vessel and fire department time to complete. However, once
completed the agencies are more prepared to respond if fire
occurs.
General Arrangement Plan. This plan shows the vessel layout
including accommodation areas, machinery spaces, cargo tanks or
holds and miscellaneous storerooms and spaces.
Vessel Fire Control Plan. Most self-propelled vessels more than
100 gross tons should have this plan. This is basically a
general arrangement plan of the vessel showing for each deck:
o the various fire retardant bulkheads
o fire detection and manual alarm systems
o fire extinguishing systems
o fire doors, compartment ingress/egress
o ventilation systems including dampers and remote stops
incident Command should obtain a copy of the vessel inventory as
well as a copy of the vessel's Fire Control Plan. These can be
most helpful. Any number of reasons may make it difficult to
obtain this information during an incident. Fire Control Plans
are required to be kept near the gangway in a watertight
container.
Vessel Safety Plan. This plan illustrates the locations of
safety equipment that may not be found on the Fire Control Plan.
Example items are lifeboats, resuscitators and lifejackets.
�
Appendix 21 Page 2
SRegial--Documents and Information (continued)
Vessel Trim and Stability Booklet. This booklet contains
information that is needed regarding vessel stability. The
booklet should be obtained as soon as possible along with the
other documents. It is necessary for stability issues.
Information usually included in the booklet is:
� The vessel's Hydrostatic Curves (or Curves of Form)
� The Hydrostatic Table -displacement, DWTr TPI, etc.
� The Curve of Righting Levers (or Stability Curve)
� Data of flooding effects on compartments singly/combined
Special Firefighting EquiRm-ent
The following items of equipment should be made available to
firefighters, particularly fire combat teams. These pieces will
assist with safe, effective fire combat.
60 Minute Air Packs Especially if fire is deep in large ship
60 Minute Spare Tanks Large number of spares may be needed
4500# Cascade System To recharge tanks at fireground site
4500# Air Compressor To recharge tanks or cascade system
Special Water Nozzles As appropriate
Lifevests/Floatcoats If approved FF equipment
Intl. Shore Connection See Sect. 5 - PHMFCP Training Manual
Foam Eductors If using foam for vapor suppression
Foam Pick-up Tubes For local foam access and application
Foam Nozzles For application of mechanical foam
Infrared Detectors To see fire through dense smoke
Explosimeters For detecting combustible atmospheres
Monitoring Equipment Thermocouples, 02 & C02 monitors, etc.
The next section, Appendix 22, lists the Special Firefighting
Equipment from the inventories of the fire departments that
responded to the project survey. No 60 Minute Air Packs and
no International Shore Connections were listed
�
Appendix 21 Page 3
SRpcial SupRort Equiipment and operations
Vessel fires may take several days to ultimately extinguish.
Therefore, special support equipment should be available and in
quantities beyond those normally needed. These resources would
be used by incident response groups. Some equipment and
operations not normally used might include:
Spare Radio Batteries Many spares needed if long duration
Battery Chargers Sufficient to recharge spares
Special Portable Radios High wattage, intrinsically safe, etc.
Copier Machine For plans, instructions and other info
CAMEO Computer For plumes and HAZMAT information
Recording Equipment For documentation (tape recorder, video)
Portable Pumps For vessel dewatering-intrinsically safe
Water Eductors For vessel dewatering
Diving Equipment For survey or dewatering assistance
Oxy-Acetylene Torches For dewatering assistance or other
Underwater Torches For cutting holes (Isothermic Torch)
Hoisting Equipment To move equipment/personnel on/off ship
Cargo Handling Equipt. For removing cargo from vessel
Mooring Equipment To replace/enhance vessel equipment
Shoring/Patching Aids For control of watertight integrity
Tarps and Sealing Aids For control of space being smothered
C02 Transfer Equipment To aid bulk transfer (hose, couplings)
Remote Ignition Device Ignition/re-ignition LPG (i.e.flare gun)
Portable Generators Trailer-mounted 50 KW unit at PNSY
Portable Light Units For outside nighttime or inside vessel
Light Strings As above (may require explosion-proof)
Extra Extension Cords For department electrical equip onboard
Smoke Ejectors & Fans For ventilation-smoke/fumes/fresh air
Ejector and Fan Socks To assist ventilation tactics
Forcible Entry Equipt. Especially metal cutting FE saw
Spare Fuel for Equipt. If incident of long duration
Hand Trucks or Dollies For movement of heavy equip (pumps/gens)
Fork Lift Trucks To move drums of agent/palletized equipt
Personnel Shelters For rest/recovery, rain or cold weather
First Aid Stations If large mass casualty or potential of
Canteen Trucks/Huts For food/refreshments if long duration
Portable Heatrs/Lights For above shelters in cold weather/night
Outhouses For obvious reasons
�
Appendix 21 Page 4
Special Craft and Apparatus
Search and rescue (SAR) activity around the harbor may best be
accomplished by the USCG SAR Unit stationed at New Castle. They
have equipment and apparatus suitable to SAR. Their boats are
staffed and away from their facility within two (2) minutes of
notification. Their 41 foot high speed patrol boats can exceed
25 knots (29 MPH) and may be on scene in a matter of minutes.
These boats may also provide limited firefighting capability for
small fires. The USCG Cutter TAMAROA, stationed in New Castle,
may be the first large Coast Guard vessel on scene. Cutters'
personnel contingents are considerable and well trained to deal
with different types of incidents. However, it is not the USCG's
responsibility to fight large shipboard fires.
Once notified of the incident, according to the 'Piscataqua
River Marine Disaster Plan', the USCG Group Portland may take
charge of the SAR operations. Depending on the scope of the
incident, they may request additional watercraft from USCG Base
South Portland including USCG cutters. USCG Group Portland may
also request helicopter assistance as necessary. However,
helicopters near the scene will produce excessive noise and may
also produce VHF interference. This could be disruptive to
local communications. USCG helicopters servicing this area will
be responding from Air Station Cape Cod with about 45 minute
response. They should be able to communicate on marine
channels, especially distress/calling channel 16 (156.80 MHz)
and channel 22 (157.10 MHz).
The local military bases at Portsmouth Naval Shipyard in Kittery
and Pease Air Force Base in Newington-Portsmouth may provide
specialty pieces of apparatus and watercraft. The inventory
includes two tugboats with mounted firefighting monitors
(YTB-771 & YTL-602) at PNSY and 3 crash trucks at PAFB. If
available to assist, these units should respond quickly due to
their close proximity. If off hours, the PNSY tugs require
about 45 minutes to staff and warm up..
SRecial craft and aRRaratus wouIA-therefore include:
USCG SAR Boats For SARf FF and waterborne support
USCG Cutters IC/OSC firefighting and water support
USCG Helicopters For SAR, offdack personnel/equip support
Portsmouth Navigation Tugs for various waterborne support
YTB-771 PNSY Firefighting tugboat-2000 GPM
YTL-602 PNSY Firefighting tugboat- 500 GPM
PNSY Barges and Boats Offshore equipment/personnel transfer
Lines Boats For assisting with mooring lines at pier
Harbormaster Boats For SARr traffic, waterborne support
Private Boats Waterborne support-SAR/traffic/pollution
�
Appendix 21 Page 5
special Craft and AMaratus (continued)
Mobile Command Post If Mobile On Scene IC Post-NH OEM/S.Port
SCBA Service Trucks To recharge expended SCBA bottles/tanks
Foam and Crash Trucks If large amounts of foam are required
Trailer-Mounted Equipt Foam generators, elec. generators, etc.
School Buses and Vans For person transfer to/from fireground
Flatbed/Pickup Trucks Transfer equip & foam to/from fireground
SRecial Fire Extingmishing Agents
Here again, the local military units are good sources of supply.
PAFB has four to five thousand gallons of AFFF and will probably
loan out at least half of it if necessary. They must retain
adequate supplies for the protection of the base. The USCG SAR
Unit at New Castle, the TAMAROA, and PNSY each maintain supplies
of AFFF totaling hundreds of gallons. Within the IEU Mutual Aid
System, hundreds more could be mustered.
If the incident is of great magnitude, many thousands of gallons
of foam may be needed. Catastrophic fires could require tens
of thousands. Airbases and airports probably have the best
stockpiles and may provide supplies. Regional airports include:
� Loring Air Force Base
� Manchester Airport
� Portland International Jetport
� Logan International Airport (Massport)
� All New York/New Jersey Airports
Another important source of large foam supplies is the foam
manufacturer. There are few firms in the United States producing
these products. Most offer 24 hour emergency service to deliver
very large amounts of foam directly from their sites. PAFB has
indicated that emergency shipments of items like foam, may be
flown into the facility unless defense requirements conflict.
Foam Types. Except for the 2000 gallons of fluroprotein foam
stored at the Fuel Storage fixed unit, foams in the Seacoast
area are mostly the AFFF type. AFFF has very quick knockdown
power but may lose its vapor suppression control in a relatively
short period of time compared to protein-based foams. For polar
solvent Class B fires, AFFF may not be as effective. These
products may require more specialized universal polar solvent,
alcohol-resistant or alcohol-type foams.
Stabilizers. To prolong the effectiveness of the foam, firms
offer a stabilizing agent to be mixed with the foam prior to
application on the fireground. With stabilizer, vapor
suppression can be extended many times that of unstabilized
foamp depending on the foam and the product burning.
�
Appendix 21 Page 6
sRecial--Fire Extinguishing &gents (continue'd"IL)
New Products. New water-applied f ire extinguishing agents are
being introduced and researched. One product, is a jelly-like
agent that smothers the fire with a coating it produces. The
PNSY Fire Department has purchased this product for their
protection.
Bulk Carbon Dioxide. In the section on fixed systems, steps to
seal and smother fire with C02 were discussed. Possible time
frames for proper inertion of a space may be days. It may be
necessary to re-inert the space for reasons such as improper
space sealing. It may be possible to use an alternate inerting
agent other than C02. If available, however, C02 should be used
in most cases because of its inherent firefighting qualities.
Bulk C02 will normally be delivered in tanker trucks at about
zero degrees farenheit under about 270 PSI. Transfer logistics
require a very long single length of special hose, maybe
hundreds of feet. Without this hose, or its equivalent, bulk
transfer is not possible. Presently, no local inventories or
emergency plans list such a hose.
SRecial Personnel and Organizational Resources includei
Personnel;
Marine Chemist - Has equipment and expertise to obtain
temperature readings, check for presence and concentration of
gases, may assist with chemical related hazard concerns.
Media - Keep public informed and assist with keeping
unauthorized personnel away from danger
Pilots - Necessary to move vessels, knowledge of marine
environment.
Translators - For communication and translating documents.
Should be familiar with fire and the marine environment.
Organizations:
Barge - Offload cargo or fuel; provide firefighting platform,,
remove containers or cargo from vessels.
Crane - Remove containers or cargo from vessel.
Environmental - For protection and cleanup.
Port Authority - Is familiar with port and operations that may
be affected by Incident Command decisions.
Salvage - Vessel casualty operations.
Tug companies Needed to move vessels.
�
Appendix 22
PORTS14OUTH HARBOR MARINE PIREFT!rzR-PTNQ CONTINGENCY PLAN
AGENCY IMNTORY AND SURVJRY
May, 1988
Code ELOT Code EMT
A, General information
1. Agency Name ....... Eliot Fire Department
2. Mail Address ...... 141 State Road, Eliot, Maine 03903
3. Site/Station 3a ... 141 State Road
Locations 3b.
3c.
4. Phone Numbers: Workdays Nights/Weekends
Main Number *1-207-439-1355
Site 3a.
Site 3b.
Site 3c.
5. Dispatch Center Name .... Kittery Dispatch
Address ................. Kitteryr Maine
Business Phone .......... Not Known
# Dispatchers per Shift.Not Known ... 1 1 Think
6. Comments
B. Key Pgrgoanel Informati
Rank/ Name Home Work Call
Title First .... Last Phone Phone slan
1. Chief Richard Wood 439-0166 17C
2. Asst Chief Gerald Moynahan 439-3409 17CI
3. Captain Dennis Spinney 439-4323 17C2
4.
5.
6.
7.
C. Ggnergl Personnel Infogmation
# Total # Certified Familiar With
Personnej, (Firg-Fighter 1) Large Vessels
Prior Fgb, 1988
1. Permanent:
2. Part Time:
3. Volunteer: 45 7 1
4. Call:
5. Auxiliary:
6. Comments
Percent of agency.staff familiar prior Feb. 1988 .... 02%
D. Radio Communications
1. Radio Call Sign ............................ KCD 355
2. Main 2a. Initial Tone: 154.190 Chnl# 1
Fre uencies 2b. operations: 154.190 Chnl# 1
2c. Local: 154.310 Chnl# 2
2d. Other: 154.280 Chnl# 3
�
Appendix 22 Page 2
PORTSKOUTH BAN= MARINE ZIREFIGHTING CONTINGENCY PLAN
AGENCY INVENTORX AND SUP-VEY
May, 1988
Code NEWC Code NEWC
A. General Informatip
1. Agency Name ....... New Castle Fire Department
2. Mail Address ...... 43 Main Street, New Castle, N.H. 03854
3. Site/Station 3a ... 43 Main Street
Locations 3b.
3c.
4. Phone Numbers: * NERGENCY * Workdays Nightg/Weekends
Main Number * 436-2515 * 436-1132 436-1132
Site 3a.
Site 3b.
Site 3c.
5. Dispatch Center Name .... Rye Fire Department -
Address ................. 563 Washington Road, Rye, N.H. 03870
Business Phone .......... 964-6411
# Dispatchers per Shift.One (1)
6. Comments
B. Key Personnel Informat'_
Rank/ Name Home Work Call
Title Eirst .... Last Phone Ehone S-19n
1. Chief Richard H. White 436-9025 431-2000 X240 31C
2. Asst Chief Richard A. Hopley 436-3694 431-2000 X243 31C1
3. Captain Rene Boisvert 436-5556 436-8709 31C2
4. Lieutenant Warren Jones 436-8441 436-8744 3103
5. Lieutenant Scott Whitehouse 436-6532 431-2000 X240 3104
6.
7.
C. General Personnel Information
# Total # Certified Familiar with
Personnel (Firg Fighter 1) Large Vessels
Prior Fgb. 1988
1. Permanent:
2. Part Time:
3. Volunteer:
4. Call: 25 20 0
5. Auxiliary:
6. Comments
Percent of agency staff familiar prior Feb. 1988....00%
D. Radio Communications
1. Radio Call Sign ......... KQR 417 New Castle Fire Department
2. Main 2a. Initial Tone: 154.190 Chnl# 1
Frequencies 2b. Operations: 154.280 Chnl#' 2
used 2c. Local: 153.905 Chnl# 4
2d. Other: 154.415 Chnl# 3
�
Appendix 22 page 3
PORTSMOUTH HARBOR MARINE FIREFIGHTING CONTINGENCY PLAN
AGENCY INVENTORY AND SURVEY
May, 1988
Code NWTN Code NWTN
A. General Information
1. Agency Name ....... Newington Fire Department
2. Mail Address ...... 80 Fox Point Road, Newington, N.H. 03801
3. Site/Station 3a ... Corner of Fox Point Road & Nimble Hill Road
Locations 3b.
3c.
4. Phone Numbers: * EMERGENCY * Workdays Nights/Weekends
Main Number * 436-5737 * 436-9441
Site 3a.
Site 3b.
Site 3c.
5. Dispatch Center Name .... Durham/ UNH Dispatch
Address ...... College Rdr Service Building, Durham, N.H. 03824
Business Phone .......... 862-1392
# Dispatchers per Shift.1 sometimes 2
6. Comments
B. Key Personnel Information
Rank/ Name Home Work Call
Title First .... Laqgt Phone Phone Sign
1. Chief Larry Wahl 436-7638 436-9441 33-C
2. Asst Chief Norman Rogers 431-1825 742-2028 33-C2
3. Captain Robert Wayss 431-4069 33-KI
4. Captain Joseph Sukeforth 436-8743 33-K2
5.
6.
7.
C. General Personnel information
# Total # Certified Familiar With
Personnel (Fire Fighter 1) Large Vessels
Prior Feb. 1988
1. Permanent: 2 2 1
2. Part Time:
3. Volunteer:
4. Call: 29 16 5
5. Auxiliary:
6. Comments
Percent of agency staff familiar prior Feb. 1988 .... 19%
D. Radio Communications
1. Radio Call Sign ............................ KCC 991
2. Main 2a. Initial Tone: 154.190 Chnl# 1
Fre uencies 2b. Operations: 154.280 Chnl# 2
A 2c. Local: 154.115 Chnl# 4
Used
2d. Other: Chnl#
�
�
Appendix 22 Page 4
PORTSMOUTH HARBOR MRINE I!TREFTGH-rTNG CONTINGENCX nM
&GENCY IMNTORY AND SURVEX
May, 1988
Code PORT Code PORT
A. General Information
1. Agency Name ....... Portsmouth Fire Department
2. Mail Address ...... 170 Court Street, Portsmouth, N.H. 03801
3. Site/Station 3a ... 170 Court Street
Locations 3b ... 2700 Lafayette Road
3c.
4. Phone Numbers: * * Workdays Nights/Weekends
Main Number * 6-5000 * 431-2003 X244 431-2003
Site 3a. 431-2003 X246
Site 3b.
Site 3c.
5. Dispatch Center Name..Portsmouth Fire Department
Address .............. 170 Court Streetp Portsmouth, N.H. 03801
Business Phone ....... 431-2003
# Dispatchers per Shift..l
6. Comments
B. Key PersQnnel-Information
Rank/ Name Home Work Call
Title First .... Last Phone Phone si=
1. Chief Randal Sage 431-2003 40C -
2. Deputy George Pierce 431-2003 40CI
3. Deputy Richard Mason 431-2003 40C2
4. Captain Ralph DiBernado 431-2003 40-0-1
5. Captain Edward Tully 431-2003 40-0-2
6. Captain Everett Weare 431-2003 40-0-3
7. Captain Frank Fernald 431-2003 40-0-4
C. General personnel.Information
# Total # Certified Familiar With
Personnel (Eirg Fighter 1) Large Vessels
Prior Feb. 1988
1. Permanent: 59
2. Part Time:
3. Volunteer:
4. Call: 16
5. Auxiliary:
6. Comments
Percent of agency staff familiar prior Feb. 1988
D. Radio Communications
1. Radio Call Sign ............................ KCB, 207
2. Main 2a. Initial Tone: 154.190 Chnl# 1
Frequencies 2b. Operations: 154.280 Chnl# .2
Used 2c. Local: 153.905 Chnl# 3
2d. Other: Chnl#
�
Appendix 22 Page 5
PORTSMOUTH HARBOR MARINE FIREFIGHTING CONTINGENCY PLAN
AGENCY INVENTORY AND SURVEY'
May, 1988
Code RYE Code RYE
A. General Information
1. Agency Name ....... Rye Fire Department
2. Mail Address ...... 563 Washington Road, Rye, N.H. 03870
3. Site/Station 3a. 563 Washington Road, Rye, N.H. 03870
Locations 3b.
3c.
4. Phone Numbers: * fdJERGE= Workdays Nights/Weekends
Main Number * 964-8683 964-6411 964-6411
Site 3a.
Site 3b.
Site 3c.
5. Dispatch Center Name .... Rye Fire Department
Address ................. 563 Washington Roadr Ryer N.H. 03870
Business Phone .......... 964-6411
# Dispatchers per Shift.1
6. Comments
B. Kgy Persgnnel Infogmation
Rank/ Name Home Work Call
Title Eirst..,-.Last Phone Phgne S-i-ga
1. Chief George Moynahan, Jr. 964-8044 964-6411 42C
2. Asst Chief Bruce Walker 964-6034 964-6411 42C2
3. Captain Ian Johnston 964-6058 964-6411 42-03
4. Lieutenant Leon Blaisdell 431-4067 964-6411 42-04
5.
6.
7.
C,_General Pergonnel Information
# Total # Certified Familiar With
Personnel (Fire Fighter 1) Large Vessels
Prior Feb- 1988
1. Permanent: 7 7 2
2. Part Time:
3. Volunteer:
4. Call: 14 10 0
5. Auxiliary:
6. Comments
Percent of agency staff familiar prior Feb. 1988....10%
D. Radio Communications
1. Radio Call Sign ............................ KCD 685
2. Main 2a. Initial Tone: 154.190 Chnl# 1
Frequencies 2b. operations: Chnl# ,
Used 2c. Local: 156.240 Chnl# 2
2d. Other: 154.280 Chnl# 3
�
Appendix 22 Page 6
PORTSMOUTH-HARBOR MTNE FTREPIGHTTNG CONTINGENCY P
AGENCY INVENTORY AND SUBMEY
Code NHDT May, 1988 Code NHDT
A- Genergl Informatio,
1. Agency Name..N.H. Dept. of Transportation, Bridge Maintenance
2. Mail Address ... PO Box 483, Hazen Drive, Concord, N.H. 03302
3. Site/Station 3a.ME-NH Bridge Authority (Long Brdg-Bypass Rtl)
Locations 3b.Memorial Bridge (US Rtl)
3c.High Level Bridge (US 1 95)
4. Phone Numbers: FJCMGENCY Workdays - Nightsaeakends
Main Number 271-3667/485-5767 271-3667
Site 3a.(Opertr) 436-2432 436-2432 436-2432
Site 3b.(Opertr) 436-3830 436-3830 436-3830
Site 3c. 436-1099(Supt of 3 Bridges)
5. Dispatch Center Name..State Offfice Build, Hookset Toll Plaza
Address ............... PO Box 398, Hookset, N.H. 03106
Business Phone .... Emergency 485-5767 office 485-3851
# Dispatchers per Shift.Center in Hookset manned 24 hrs/7days
6. Comments...Hooksett has Master List of N.H. Department of
Transportation Personnel - N.H. D.O.T. personnel handle
Maine - N.H. Bridge Authority.
B. lay Personnal-Information
Rank/ Name Home Work Call
Title First.,.-Last Phone Phone Sj1=
1. See Above
2. Administrator Kenneth R. Olsen 753-4765 271-3667
3. Sr. Supt. Richard Giles 679-5426 436-1099
4.
5.
6.
7.
C. GRneral Permnel informatio
Total Certified Familiar With
Persgnngl (Firg Fighter 1) Large Vessels
Prior Feb. 1988
1. Permanent: N/A
2. Part Time:
3. Volunteer:
4. Call:
5. Auxiliary:
6. Comments
Percent of agency staff familiar prior Feb. 1988
D. Mdjo Communications
1. Radio Call Sign ......................
2. Main 2a. Initial Tone: Chnl#
Frequencies 2b. Operations: Chnl#
Used 2c. Local: Chnl#
2d. Other: Chnl#
�
Appendix 22 Page 7
PORTSMOUTH HARBOR MARINE FIREFIGHTING CONTINGENCY PLAN
AGENCY INVENTORY AND SURVEY
Code NHFM May, 1988 Code NBFM
A. General Information
1. Agency Name ....... N.H. Fire Marshal office
2. Mail Address ...... Hazen Drive, Concordt N.H. 03305
3. Site/Station 3a.
Locations 3b.
3c
4. Phone Numbers: * EMERGENCY * Workdays Nights/Weekends
Main Number * 271-3294 * 271-3204 271-3636
Site 3a.
Site 3b.
Site 3c.
5. Dispatch Center Name .... State Police Dispatch
Address ................. Hazen Drivep Concordt N.H. 03305
Business Phone .......... 271-3636
# Dispatchers per Shift.2 Plus Supervisor
6. Comments
B. Key Personnel Information
Rank/ Name Home Work Call
Title First .... Last Phone Phone Sign
1. Fire Marshal Bill Toland 778-8779 271-3294 904
2. Deputy Allen Britton 889-1833 271-3294 907
3.
4.
5.
6.
7.
C. General Personnel information
# Total # Certified Familiar With
Personnel (Fire Fighter 1) Large Vessels
Prior Feb. 1988
1. Permanent: 11 5
2. Part Time:
3. Volunteer:
4. Call:
5. Auxiliary:
6. Comments
Percent of agency staff familiar prior Feb. 1988 .... 00%
D. Radio Communications
1. Radio Call Sign .................... KCA 999 (NH State Police)
2. Main 2a. Initial Tone: Chnl#
Fre uencies 2b. Operations: Chnl#
Used 2c. Local: Chnl#
2d. other: Chnl#
�
�
Appendix 22 Page 8
PQRTSKOQTH HARBOR 14ARINE FIREFIGHTIRG CONTINGENCY PLAN
AGENCY INVENTORY AND SURVVY
Code NHPA May, 1988 Code NHPA
A. General Information
1. Agency Name ....... N. H. Port Authority
2. Mail Address ...... PO Box 506, Portsmouth, N.H. 03801
3. Site/Station 3a ... 555 Market Street, Portsmouth
Locations 3b.
3c.
4. Phone Numbers: EFMGE= * Workdays Nights/Weekends
Main Number * 436-8500 692-3135
Site 3a.
Site 3b.
Site 3c.
5. Dispatch Center Name..
Address ...............
Business Phone ........
# Dispatchers per Shift..
6. Comments .... Facility work hours are 8-5 weekdays. No night,
weekend, or holiday work without prior arrangements.
B. Key Personnel-Informatio
Rank/ Name Home Work Call
Title Eirst .... Last Phone Phone ai=
1. Director Ernest Connor 692-3135 436-8500
2. Manager Ivan Milton 431-8500
3. Foreman Robert Moore 436-7560 431-8500
4.
5.
6.
7.
C. General Personnel information
# Total # Certified Familiar With
Personnel (Fire Fighter 11 Large Vessels
Prior Feb. 198.a
1. Permanent: 13 0 6
2. Part Time: 5 0
3. Volunteer:
4. Call:
5. Auxiliary:
6. Comments
Percent of agency staff familiar prior Feb. 1988.....33%.
D. Radio Communications
1. Radio Call Sign .................... Port Authority
2. Main 2a. Initial Tone: Chnl#
Frequencies 2b. Operations: Chnl#
Used 2c. Local: Chnl#
2d. Other: Chnl#
�
Appendix 22 Page 9
PORTSMOUTH HARBQR 14ARINE FIREFIGHTING CONTINGENCY PL
AGEMY INVENTORY AND SURVEY
May, 1988
Code PHAV Code PNAV
A.-General InfQrmatiQ
1. Agency Name ....... Portsmouth Navigation Division
2. Mail Address ...... PO Box 472, Portsmouth, N.H. 03801 1
3. Site/Station 3a.
Locations 3b.
3c.
4. Phone Numbers: * EMERGENCY * Workdays Nights/Weekgnds
Main Number * 436-1209 * 436-1209 436-1209
Site 3a. (Answering Serv.)
Site 3b.
Site 3c.
5. Dispatch Center Name..Same as Above
Address ...............
Business Phone .......
# Dispatchers per Shift..
6. Comments ... 23 Ft. runabout with 200 H.P. motor.
Key Personnel Information
Rank/ Name Home Work Call
Title First....Lagt phone Phone si=
Richard Holt 436-1097 436-1209
2. Shirley Holt 436-1317 436-1209
3. Mathew Cote 1-207-439-9177 436-1209
4.
6.
7.
C. General Personnel Information
# Total # Certified Familiar With
Persgnnel (Fire Fighter 1) Large Vessels
Prior Feb. 1988
1. Permanent: 13 3
2. Part Time:
3. Volunteer: 3
4. Call:
5. Auxiliary:
6. Comments
Percent of agency staff familiar prior Feb. 1988 ..... 23%
D. Radio Communications
1. Radio Call Sign ......................
2. Main 2a. Initial Tone: Chnl#
Frequencies 2b. operations: Chnl# -
Used 2c. Local: Chnl#
2d. Other: Chnl#
�
Appendix 22 Page 10
PORTSMOUTH HARBOR MINE FIREFIGHTING rQNTINGENCY PLU
AGENCY INVE M RY AND SURVEX
Code NHWS may, 1988 Code NHWS
A. General Informatio
1. Agency Name.....DES - N.H. Water Supply and Pollution Control
2. Mail Address .... 6 Hazen Drive, PO Box 95y Concord, N.H. 03301
3. Site/Station 3a.Concord, N.H. Only
Locations 3b.
3c.
4. Phone Numbers: ZMERGZ= Workdays Nighta/Weekends
Main Number *1-800-852-3411 271-3503 271-3636
Site 3a.
Site 3b.
Site 3c.
5. Dispatch Center Name..State Police Dispatch
Address ............... Hazen Drive, Concordr N.H. 03305
Business Phone ........ 271-3636
# Dispatchers per Shift..
6..Comments
B. Key Personnel Informati
Rank/ Name Home Work Call
Title First .... Last Phgne Phone
1. N/A - Pollution Control Personnel Only
2.
3.
4.
5.
6.
7.
C. General Pgrsgnngl infgrmation
Total Certified Familiar With
Personnel (Fire Fighter 1) Large Vessels
Prior Fph. 1988
1. Permanent: 3 0 0
2. Part Time:
3. Volunteer:
4. Call:
5. Auxiliary:
6. Comments
Percent of agency staff familiar prior Feb. 1988 ..... 00%
D. Radio Communications
1. Radio Call Sign ............................ N/A
2. main 2a. Initial Tone: Chnl#
Frequencies 2b. Operations: Chnl#
Used 2c. Local: Chnl#
2d. Other: Chnl#
�
Appendix 22 Page 11
PORTSMOUTH HARBOR MRINK FIREFIGHTING CONTINGENCY PLAN
AGENCY INVENTORY AND SURVEY-
Code .SEA3 May, 1988 Code SEA3
A. General Information
1. Agency Name.. ...Sea-3p Inc.
2. Mail Address.:: ... 103 old Dover Road, Newington, N.H. 03801
3. Site/Station 3a...Same
Locations 3b.
3c
4. Phone Numbers: * EXEMENCY * WorkdavS Nights/Weekends
Main Number * 431-5990 * 431-5990 431-5990
Site 3a.
Site 3b.
Site 3c.
5. Dispatch Center Name..Same
Address ............... Same
Business Phone ........ Same
# Dispatchers per Shift..l
6. Comments
B. Key Personnel Information
Rank/ Name Home Work Call
Title First .... Last Phone Phone
1. Sr. VP Lawrence Heffron 964-5704 436-6225
2. Manager Paul Bogah 431-5224 431-5990
3. Maintnce. John Mielke 778-0286 431-5990
4.
5.
6.
7.
C. General Personnel Information
# Total # Certified Familiar With
Personnel, (Pirg-Fighter. 11 Large Vessels
Prior.Feb. 1988
1. Permanent: 15 N/A 15.
2. Part Time: N/A
3. Volunteer:
4. Call:
5. Auxiliary:
6. Comments
Percent of agency staff familiar prior Feb. 1988 ..... 100%
D. Radio Communications
1. Radio Call Sign ............................ KYF 700
2. Main 2a. Initial Tone: Chnl#
Fre uencies 2b. Operations: 464.675 Chnl#*
Ned- 2c. Local: Chnl#
2d. Other: Chnl#
�
Appendix 22 Page 12
PORTSLIOUTH.HARBOR WMINE FIREFIGHTING CONTINGENCY
AGENCY INVERTORX AND SURVEY
May, 1988
Code SMPX Code SKPX
A. General information
1. Agency Name .. ... Simplex Wire and Cable Company
2. Mail Address.:: ... PO Box 479, Portsmouth, N.H. 03801
3. Site/Station 3a ... 2073 Woodbury Avenue, Newington, N.H.
Locations 3b.
3c.
4. Phone Numbers: * EMRGENCY * Workdays Nights/Weekends
Main Number * 436-6100 * 436-6100 436-6100
Site 3a.
Site 3b.
Site 3c.
5. Dispatch Center Name..Simplex Wire and Cable Guard Station
Address ............... 2073 Woodbury Avenue, Newington, N.H.
Business Phone ........ 436-6100
# Dispatchers per Shift..2
6. Comments .... Guard Station is manned 24 hrs/ 7 days per week.
20 Ft. flat boat - no motor - attached to pier.
B. Key Personnel-Informat*
Rank/ Name Home Work Call
Title First .... Last Phgne Phonp.
1. Guard Station 436-6100 436-6100
2. The Guards will notify the appropriate personnel at Simplex.
3.
4.
S.
6.
7.
C. General Personnel Information
# Total # Certified Familiar With
Peraonne], (Firg-Fighter 1) Large Vessels
Prior eb. 1988
1. Permanent: 603 0 0
2. Part Time: 256 0 0
3. Volunteer: 0 0 0
4. Call: 0 0 0
S. Auxiliary: 0 0 0
6. Comments
Percent of agency staff familiar prior Feb. 1988....00%
D. Radio Communications
1. Radio Call Sign ................ Base Station - Portables 1-5
2. Main 2a. Initial Tone: Chnl#
Frequencies 2b. Operations: Chnl#.
Used 2c. Local: Chnl#
2d. Other: Chnl#
�
Note: NH DES-WSPOC lists no units. Portsmouth Harbor Marine Pirefi(@htinq Contin@encv Plan may 1988
NH Fire Marshal lists no units. Project Agencies 2-Way Radio Communications
2-way Radio Sections Eliot New Castle Newington Portsmouth Rye NH Dep Trns NH Port Portsmouth Sea-3, ;Simplex Wire
Equipment/Information Fire Dept Fire Dept , Fire Dept. Fire Dept Fire Dept Brdge Maint Authority Navigation Inc. Wire & Cable
1. Radio Call or Sign KCD 355 MR 417 KCC 991 KCB 207 KCD 685 Call NHPA KYF 700
Main Frequencies Used:
a. Initial Thne/Channel 154.190/1 154.190/1 154.190/1 154.190/1 154.190/1
b. Operations/Channel 154.190/1 154.280/2 154.280/2 154.280/2 464.675
c. Local/Channel 154.310/2 153.905/4 154.115/4 153.905/3 156.240/2
d. Other/Channel 154.280/3 154.415/3 154.280/3
2. Marine Radiotelephone
a.. .of Handhelds Units a 1 1 0 1 3* 1
All Invtry Crails/Partial 22 13,16,22,23 All =,2 6-16 7,13,16,77
b. No. of Mobile Units 0 1-Car'l-Uty 2
All Invtry Chnls/Partial 13,16,22,23 16
c. No. of Fixed Units 0 1 1 2-1 Ea Brdg
All Irwtry Chnls/Partial 0 22 1 16,23 13,16
3. Handheld EM Portables
a. -Rake Motorola Mtrla MI!500 Motorola Motrla 500 Motorola Ritron Motorola Regency
b. No. of Units 2 5 6 14 2 3 4 5
c. Maximum Wattage 5 5 5 5? 5
d. No. of Remote Mikes 2 2 4 5
e. No. of Channels 4 4 2/8, 4/4 8 4 1 1
f. Frequencies See Sec #1 See Sec #1 See Sec #1 See Sec 1&2 153.23
g. Intrinsically Safe x No No No No NO Yes
h. No. of Spare Batteries 0 2 2 5 2 0 Yes 1
i. No. of Chargers/Capacity 2/1 3 7 24 2 3 2 5
4. Other Handheld FM Prtbles
a.'Make Sonar Maxon G.E.
b. No. of Units 3 9 2
c. Maximum Wattage 5 5 5
d. No. of Remote Mikes
e. No. of channels 1 4 4/22 1
f. Frequencies 154.190 See Sec #1
g. Intrinsically Safe ? No
h. No. of Spare Batteries 0 0 2
j. No. of ch argers/Capacity 3/1 9 2
Portsmouth Navigation usually works CHNLS 7 & 77 between vessels or between ship and dock.
�
Note: Portsmouth Harbor Marine Firefighting Contingency Plan Floating
1. The only foams carried are AFFF type. Fire Department Agency Inventory - May 1988 Codes:
2. All vehicles have FIREGROUND 154.280.
3. No vehicles have 60 minute air packs. Fire Department Vehicle Apparatus and Onboard quipment
4. No 3 inch hose was inventoried. (For Commitment of Mutual Aid For Marine Fire)
5. Only NWTN listed Around-the-Pump
Proportioners (for 33EI & 33E2).
Fire 30 Minute Capacity 3% 6% In Pick Foam
Type Dept Year Call Pump Tank Air Spare Portable Light Smoke AFFF AFFF Line UP Nozzles
Equipment Code Built Sign Cap. Cap. Packs Tanks Genertr Pump Units Eject Foam Foam Educt Tubes 1.5" 2.5
Eng ine / ELOT 1964 17E2 750 500 4 0 50OW No 2 1 0 0 0 0 0 8q0
Pumper NEWC 1972 31E1 1000 600 5 8 350OW No 2 0 0 10 1 0 0 0
NEWC 1982 31E2 1000 500 6 6 5000W 200 5 1 0 10 1 0 0 0
NWTN 1972 33El 1000 750 5 4 No No 0 1 40 0 0 0 1 0
NWTN 1977 33E2 1250 750 5 4 No No 0 1 0 40 0 0 1 0
PORT 1988 40E1 1500 500 6 6 Yes No 2 1 5 0 0 1 0 0
PORT 1987 40E2 1500 500 6 6 Yes No 2 1 5 0 0 1 0 0
PORT 1974 40E3 1500 500 6 6 Yes No 2 1 5 0 0 1 0 0
PORT 1983 40E4 1000 500 6 6 Yes NO 2 1 5 0 0 1 0 0
FORT 1967 40E5 750 500 2 2 No No 0 0 0 0 0 0 0 0
RYE 1969 42E2 1000 500 4 4 5000W No 3 1 5 0 0 Yes 0 0
RYE 1976 42E4 750 500 5 5 350OW No 3 1 0 5 0 Yes 0 0
Tanker RYE 1969 42TI 300 1200 0 0 No 100 0 0 5 5 0 Yes 0 0
Ladder arm 1986 33L1 1500 250 5 4 1500W No 2 1 0 0 0 1 0 0
Pumper
utility NEWC 1988 31U1
NWTN 1974 33U 2 0 350OW No 3 0 0 0 0 0 0 0
Hose NEWC 1979 31H1
Wagon
Command NWTN 1986 33Carl
Vehicle
Boats ELOT None Length 14', Row Boat
NWTN Boat-1 Length 17', 70 HP Outboard
NWTN Boat-2 Length 14', 18 UP Outboard
�
�
Appendix 22 Page 15
Portsmuth Harbgr MFCP May 1988
Stored Equipment Quantities At Fire Stations
ELOT NEWC NWTN PORT RYE
1. Intl. Shore Connections:
2. 15 Min. Emerg. Escpe Pcks: 2
3. 30 Minute Air Packs: 9
4. 60 Minute Air Packs:
5. 30 Minute Spare Tanks: 8 2 10
6. 60 Minute Spare Tanks:
7. Cascade System:
8. 2500# Air Tank Compressor:
90 4500# Air Tank Compressor:
10. Explosimeters:
11. Port. Pumps #/Capacity: 1-250 1-200 1-250 1-100
12. Port. Pumps #/Capacity: 1-1-5 1-150. 1-50
13. Submer Pump #/Capacity:
14. Submer Pump #/Capacity:
15. Port. AC Gen. Capacity: 1-500W
16. Port. AC Gen. Capacity:
17. Port. DC Gen. Capacitys
18. Portable AC Light Units: 2
19. Portable DC Light Units:
20. Smoke Ejectors: 2
21. Foam In-line Eductors: 1 3
22. Foam Pick-up Tubes:
23. Foam Nozzles 1 1/2":
24. Foam Nozzles 2 1/2":
25. 3% Protein Foam:
26. 6% Protein Foam:
27. 3% Fluroprotein Foam:
28. 6% Fluroprotein Foam: -
29. 3% AFFF: 15 175 20 30
30. 6% AFFF: 10
31. 3% Jet-X Hi-Ex Foam:
32. 6% Jet-X Hi-Ex Foam: 65
33. Diving Equip:
34. Thermocouples:
35. Infrared Heat Detectors: 1
36. C02 Transfer Equip:
37. Explosion-proof Equip:
38. Other Equip or Foams: NWTN 75 gallons of alcohol type AFFF
�
Appendix 23 Page la
PORTSM011 ARBOR MARINE FTRF-FTGHTTM CONTTim" NCY PI-AN
VESSEL TNVENTinRY AND SURVEY
(For Vessels over 25 Feet in Length)
May, 1988
A. General Vennel Information
1. Vessel Name-----M/V EUGENIA MORAN 7. Type Tug
2. Nationality us 8. Reg. Length_107 Ft.
3. Type Propulsion Power - Diesel 9. Reg. Beam- 33 Ft.
4. Rated Horsepower 2860 10. Max. Draft-16 Ft.
S. Puel(s) Used Diesel 11. Gross Wt.-282 Ton
6. Thruster(s) -0 12. Max. Speed _ 12 Kts.
B. ernonnel Tnfotmatton
1. Maximum number of passengers permitted 0
2. Minimum number of crew permitted-- 4
3. Normal number of crew 4
4. Basic language(s) of Officers -US
5. Basic language(s) of Crew S
6. Number of personnel in Vessel Fire Contingent 0.
7. Is Engine Room continuously staffed while in Portsmouth?-No
8. If Not when staffed? _ 0800-1500, or underway
9. Master's/Captain's Name _ S. H. Holt
10. Master's/Captain's Name
11. Owner's Name Portsmouth Navigation
Address -PO Box 472 Portsmouth
Workday Phones 436-1209
Nights/Weekends Phones Same
12. Operator's Name Portsmouth Navigation Div.
Address 34 Ceres St., Portsmouth
Workday Phones 436-1209
Nights/Weekends Phones Same
C., Voice CoMmunications within Vessel
1. Handheld Portables -None
2. Base Station Location(s)
(To Above Portables) None
3. Sound Powered Telephones? .................................. No
4. Electric Telephones? ...................................... Yes
5. Talkback/Intercom System? .................................. No
6. Public Address System? ..................................... No
D. yoice Communications Between Vessel and shore
1. Radio Call Sign
2. FM Fire Radios None
3. Marine Radios Handheld Base With Base Without
(Radiotelephone) Battery BackUp Battery
3a. # of Units: -2-Synsize_
3b. Locations:
3c. Channels:
4. Normally Guarded Marine Channels in Portsmouth: None
5. Normal Marine Channels Worked in Portsmouth:_7, 13, 16p 77
el Firefighting Equipment
1. Compressed Air Breathing Apparatus N/A
2. Hydrants threads or couplings? Threads
3. Diameters/Type threads 2 1/2 NPT, @ 1/2 IPT
4. Nozzle Type(s) All Purpose
5. Intl. Shore Connection Locations None
6. Fire Control Plan Tube Locations (Please attach one copy for
Portsmouth Harbor Inventory purposes) None
�
Appendix 23 Page lb
F. Alarm and Indicator Panel Locations N/A
G. Emergency Stops Locations
1. Fuel Pumps None
2. Fuel Pumps _None
3. Cargo Pumps -None
4. Cargo Pumps None
5. Vapor Compressors - None
6. Inert Gas Blower -----None
7. Ventilation Pans -None
8. Ventilation Fans - None
H. Vessel Electrical Generators
1. Emergency Location Output(KW or KVA) Prime Mover
la.__NA
lb.
1c.
2. Non-Emergency Location Qutput(KW or KVA) Prime Mover
2a. 60 KW Diesel
2b. 30 KW Diesel
2c.
2d.
3. Comments
I. Vessel fire Pumps
1. Emergency Fire Pumps (If not electric, list PM under 'Motor')
Location Capacity (GPM) Motor Size (KW or KVA)
la.
lb.
1c.
2. Non-Emergency Fire Pumps
Location Capacity (GPM). Prime Mover
2a._ER 100 Electric Motor
2b.
2c.
2d.
2e.
3. Comments--
J. Vessel Fixed Dewatering Pumps
1. Emergency Dewatering Pumps (Will run off emergncy generators)
Location Capacity (GPM) Motor Size (KW or KVA)
la.N/A
2a
3a.
2. Non-Emergency Devatering Pumps
Location Capacity (GPM) Prime Mover
2a.N/A
2b.
2c.
2d.
2e.
K. Vessel Fixed Extinguishing Systems (Please list only remote
release control locations--assuming local release at bottles)
1. Carbon Dioxide (C02) Fixed Bottles
la. Spaces Protected-ER
lb. Release Locations-ER,
1c. # of Bottles- 2 -Capacity Each-100 lbs
Id. Bottle Locations-ER
�
Appendix 23 Page 2a
PORTSMOUTH HMBOR MARINE FIREFIQHTTNG CONTINGENCY PLAN
VESSEL INVENTORY AND SURVRV
(For Vessels over 25 Feet in Length)
May, 1988
A. Ggnegal Vessel Information
1. Vessel Name M/V NANCY MORAN 7. Type Tug
2. Nationality us 8. Reg. Length-100 Ft.
3. Type Propulsion Power Diesel 9. Reg. Beam_ 25 Ft.
4. Rated Horsepower 1600 10. Max. Draft_13 Ft.
5. Fuel(s) Used -Diesel 11. Gross Wt._228 Ton
6. Thruster(s) 0 12. Max. Speed 11 Kts.
B. Pgrsonnel Informatiq
1. Maximum number of passengers permitted 0
2. Minimum number of crew permitted ___4
3. Normal number of crew 3
4. Basic language(s) of Officers us
5. Basic language(s) of Crew us
6. Number of personnel in Vessel Fire Contingent 0
7. Is Engine Room continuously staffed while in Portsmouth?-No
8. If Not when staffed?- Vessel Underway
9. Master's/Captain's Name__---R. C. Holt
10. Master's/Captain's Name
11. Owner's Name -Portsmouth Navigation
Address PO Box 472 Portsmouth
Workday Phones 436-1209
Nights/Weekends Phones - Same
12. Operator's Name Portsmouth Navigation Div.
Address 34 Ceres St. Portsmouth
Workday Phones 436-1209
Nights/Weekends Phones-Same
C. ygice communicationg Within Vessel
1. Handheld Portables None
2. Base Station Location(s)
-(To Above Portables) None
3. Sound Powered Telephones? .................................. No
4. Electric Telephones? ...................................... Yes
5. Talkback/Intercom System? .................................. No
6. Public Address System? ..................................... No
D. Voice Communications Between ssel and Shore
1. Radio Call Sign
2. FM Fire Radios None
3. Marine Radios Handheld Base With Base Without
(Radiotelephone) Battery Backup Battery
3a. # of Units: -2
3b. Locations:
3c. Channels:
4. Normally Guarded Marine Channels in Portsmouth: None
5. Normal Marine Channels Worked in Portsmouth:-7, 13, 16, 77
E. Vessgl Firefighting ngui=ent
1. Compressed Air Breathing Apparatus N/A
2. Hydrants threads or couplings? - Threads
3. Diameters/Type threads 2 1/2 NPT, 1 1/2 NPT
4. Nozzle Type(s) All'Purpose
5. Intl. Shore Connection Locations one
6. Fire Control Plan Tube Locations (Please attach one copy for
Portsmouth Harbor Inventory purposes) - None
�
Appendix 23 Page 2b
F. Alarm and Indicator Panel Locations N/A
G. Emergengy StoRs Locations
1. Fuel Pumps None
2. Fuel Pumps None
3. Cargo Pumps None
4. Cargo Pumps _None
5. Vapor Compressors None
6. Inert Gas Blower None
7. Ventilation Fans one
8. Ventilation Fans --None
H. Vessel Electrical Generators
1. Emergency Location Output(KW or KVA) Prime Mover
la.-N/A
lb.
1c.
2. Non-Emergency Location OUtput(KW or KVA) Prime Mover
2a. ER 30 KW -Diesel
2b.
2c.
2d.
3. Comments
I. Vessel Fire P=Rs
1. Emergency Fire Pumps (If not electricr list PM under 'Motor')
Location CaRgcity (GPM) Motor Size (KW or KVAJ
la.
lb.
1c.
2. Non-Emergency Fire Pumps
Location CaRacity (GPM) Prime Mover
2a.- ER 100 Diesel
2b.
2c.
2d.
2e.
3. Comments
J. Vessel Fixed Devatering Pumps
1. Emergency Dewatering Pumps (Will run off emergncy generators)
Location CapAcity (GPM) Motor Size (KW or KVAI
la.-NIA,
2a
3a.
2. Non-Emergency Dewatering Pumps
Location CaRacity (GPM) Prime Mover
2a. NI
2b.
2c.
2d.
2e.
K. Vessel Fixed Extinguishing Systems (Please list only remote
release control locations--assuming local release at bottles)
1. Carbon Dioxide (C02) Fixed Bottles
la Spaces Protected-ER
lb: Release Locations - ER
1c. # of Bottles - 2 capacity Each-100 lbs
ld. Bottle Locations-ER
�
Appendix 23 Page 3a
PORTSMOUTH HAUOR--MARINE FIREFIGHTING CONTINGENCX PLAN
VESSEL INVENTORY-AND SURVEY
(For Vessels over 25 Feet in Length)
May, 1988
A.-General Vessel Information
1. Vessel Name- M/V E.F. Moran Jr. 7. Type Tug
2. Nationality us 8. Reg. Length-103 Ft.
3. Type Propulsion Power Diesel 9. Reg. Beam_ 27 Ft.
4. Rated Horsepower 1600 10. Max. Draft-12 Ft.
5. Fuel(s) Used Diesel 11. Gross Wt._226 Ton
6. Thruster(s) 0 12. Max. Speed - 10 Kts.
B.- Personnel Informatio
1. Maximum number of passengers permitted -0
2. Minimum number of crew permitted, 4
3. Normal number of crew 4
4. Basic language(s) of Officers us
5. Basic language(s) of Crew S
6. Number of personnel in Vessel Fire Contingent 0
7. Is Engine Room continuously staffed while in Portsmouth?-No
S. If No, when staffed? underway
9. Master's/Captain's Name _ M. L. Cote
10. Master's/Captain's Name
11. Owner's Name Portsmouth Navigation
Address PO Box 472 Portsmouth
Workday Phones 436-1209
Nights/Weekends Phones-Same
12. Operator's Name Portsmouth Navigation Div.
Address 34 Ceres St. Portsmouth
Workday Phones 436-1209
Nights/Weekends Phones - Same
C. Voice Communications Within Vessel
1. Handheld Portables
2. Base Station Location(s) to above portables
3. Sound Powered Telephonea? .............................. Yes/No
4. Electric Telephones? ................................... Yes/No
5. Talkback/Intercom System? .............................. Yes/No
6. Public Address System? ......... oee ......... * ....*... ...Yes/No
7. Comments -Voice tube Wheelhouse to Engine Room
D. voice Communicationg Be-t-ween Y-Casel ana Shore
1. Radio Call Sign
2. FM Fire Radios None
3. Marine Radios Handheld Base With Base Without
(Radiotelephone) Battery BackuR Battery
3a. # of Units: 2
3b. Locations:
3c. Channels:
4. Normally Guarded Marine Channels in Portsmouth:
5. Normal Marine Channels Worked in Portsmouth:-7, 13, 16t 77
E. Vessel Firefighting EquiMent
1. Compressed Air Breathing Apparatus - N/A
2. Hydrants threads or couplings? -Threads
3. Diameters/Type threads -2 1/2 NSTy 1 1/2 NST
4. Nozzle Type(s) - one 1 1/2" Multipur ose
5. Intl. shore Connection Locations Eone
6. Fire Control Plan Tube Locations (Please attach one copy for
Portsmouth Harbor Inventory purposes) --None
�
Appendix 23 Page 3b
F. Alarm and Indicator Panel Locations _N/A
G. Emergengy-StoRs Locations
1. Fuel Pumps None
2. Fuel Pumps _None
3. Cargo Pumps _None
4. Cargo-Pumps --None
5. Vapor Compressors -None
6. Inert Gas Blower _ None
7. Ventilation Fans - 1 Fan foward Engine Room - No shutoff
8. Ventilation Fans - 1 Pan foward crew quarters - No shutoff
H. Vessel Electrical Gemrators
1. Emergency Location Output(KW or KVA) Prime Moy_eL
la.-N/A
lb.
1c.
2. Non-Emergency Location Output(KW or KVA) Prime Mover
2a. ER 30 KK- Diesel-
2b. ER 30 KW Diesel
2c. (GM 3-71)
2d.
3. Comments 125 Volts DC 200A located in Engine Room-
I. Vessel Firg ftns
1. Emergency Fire Pumps (If not electric, list PM under 'Motor')
Location CaRacity (GPM) Motor Rime (KW or
la. _N/A
lb.
1c.
2. Non-Emergency Fire Pumps
Location CUacity (GPM) Prime Mover
2a. ER 150- Diesel
2b.
2c.
2d.
2e.
3. Comments - 3-71 Power Take-off
J. Vessel Fixed Damatering Puns
1. Emergency Dewatering Pumps (Will run off emergncy generators)
Location CaRacity (GPM) Motor Size (KW or KVAI
la.
2a
3a.
2. Non-Emergency Dewatering Pumps
Location CapAcity (GPM) Prime Mover
2a.-ER 50 ___ ---Diesel
2b._ ER .1600@:GPH 1/2 HP Motor
2c.
2d.
Comments _ Diesel is 3-71 Power Take-off
K. Vessel Fixed Extinguishing Systems (Please list only remote
release control locations--assuming local release at bottles)
1. Carbon Dioxide (C02) Fixed Bottles
la Spaces Protected_ER
lb: Release Locations-ER
1c. # of Bottles .1 capacity Each_100 lbs
ld. Bottle Locations-ER
�
J 2 1 ne lve@@mpshtre Fort liandbook The New Ha
,_,..Hi1.tori State,Pa.rk
136 U u. fi NY VT NH
nc
DOVER FIT. Concord
3*-FT. TURNING BASIN 0
GEN. SULLIVAN ELIOT Portsmo
BRIDGE
Q0
NEW iNGTON 3S-FT. CHANNEL
MA
Bost n
1. Sprague Energy
2. New England Tank & is-FT. TURNING
Fuel Storage Corp. BASIN C:T Rl
3. Gulf Oil Co. ME. 95 Pro@idenc
4. Belcher New England
KITTERY
S. Sea-3, Inc.
r S
haf SPAU F CREEK
master Fish Go... MLING ROCK
7. Simplex Wire&
Cable Co. HIG04WAV BRIDGE
a. Public Service Oo. of ME NH BRIDGE (LIFT)
NH (Newington Station) South TOWN OF KITTERY
9. Public Service Co., of N.H. / PORT AUTHORITY
NH (Schiller Station) EMORIAL BRIDGE (LIFT)
10. Northeast Petroleum
it 7
ii. Gold Bond (National Gypsum) rth
ACK CHANNEL
Cha
Bridge Radio 12. NH PORT /mbe, of comm6rce
Frequencies: Channel 13 AUTHORITY
13. Viking Sun SEAVEYISA PEPPEAREL
BRIDGE CLEARANCES 14. Granite State
Minerals to 21. Dion's
MEMORIAL BRIDGE (LIFT) 15. Heritage Cruises FT1,CHAHNELi!`: Yacht Yard
HOR. 260 FT. 603-436-3830 16. Portsmouth
VERT. 150 FT.
Navigation Co.
ME.-N.H. BRIDGE (LIFT) 603-436-2432 17. Prescott Park HAPLEIGH IS
HOR. 200 FT 18. State Fish Pier
VERT. 135 FT. 19. Portsmouth Naval 4z:;PV NEW CASTLE IS
1-95 HIGHWAY BRIDGE (FIXED) Shipyard, (Kittery, 2)
HOR. 440 FT, 20. U.S. Coast Guard NEW CASTLE PORT
VERT. 135 FT. (New Castle Statin PORTSMOUTH ..AT BRIDGE PISCI
GENERAL SULLIVAN BRIDGE (FIXED)
HOR, 100 FT. Pierce Is.- LOCAT
Latitud
VERT. 46 FT. Boat Launch Longitu
Distanc
LITTLE HARBOR
NEW CASTLE HIGHWAY BRIDGE (BASCULE)
HOR, 29 FT. SCALE IN
I
VERT. 12 FT.
Contact: Bob Allard, ME, NH Bridge Authority 603-436-3500 ALL DEP
�
Appendix 24 Page 2
Directions for--RespQnders
M smouth Harbor Terminals
NOTE: These are directions for those responding to the
waterfront sites. Staging Areas for mutual aid
equipment/personnel may be different locations.
Newington:
Sprague: Spaulding Tnpk north to Exit #4--River Road.
If going south on Spaulding Tnpk from Dover, take
reverse loop after GS Bridge and get to right.
Turn right off ramp 300 yds to Sprague gate--left.
Sea-3 LPG: Old Dover Road north just past Country Curtains to
River Road exit on right as going down hill-go
straight onto Patterson Lane 1/2 mi downhill
to entrance and gate on right.
If Spaulding Tnpk north, take Exit #4--River Road-
Turn right off ramp onto River Road-1/2 mi to
left turning curve onto Patterson Lane-continue
1/2 mi to entrance and gate on right.
If Spaulding Tpk south, take reverse loop after GS
Bridge to Exit #4 and follow directions above.
Simplex: Old Dover Road to entrance across from Filene's at
Fox Run Mall.
PortsmoUth:
PSNH Gosling Road east at Sundeen's AV Warehouse to end
Schiller: at River-gate on right.
PSNH Gosling Road east at Sundeen's AV Warehouse 1/2 mi
Mobil: to paved entrance on right opposite Mobil tanks-
go up hill past brick building-continue and bear
next left down hill-pavement rough.
Gold Bond Market Street to Cutts Road to end--through gate &
Gypsum: turn right--go around building to dirt access.
NH Port Market Street to steel scrap piles-through gate at
Authority: traffic light-around shed building.
Isles of Market Street next to steel scrap pile and across
Shoals Stmshp: from the new Sheraton.
Granite Market Street across from new Sheraton and usually
State Minrls: has salt piles in terminal.
Portsmouth Tugs located at Ceres Street facility 50 yds. east
Navigation of Granite State Minerals.
New Castle:
USCG Route 1B to Fort Constitution. Follow signs to
Station USCG Facility.
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Appendix 24 Page 3
US Army Corps of Engineers Facility and Pier Information
PIERS, WHARVES, AND DOCKS
Portsmouth, New Hampshire. right bank, Piscataua River
Corps of Engineers Port Code No. 00600
REFERENCE NUMBER ON MAP 7 Dock Code No. 785 8 Dock Code No. 783 9 Dock Code No.770
NAME Portsmouth Navigation Corp. Wharf. Oar House Dock. Granite State Minerals Dock.
LOCATION ON WATERFRONT Approximately 1.200 feet above Approximately 1.400 feet above Above Memorial Bridge (U.S. Highway 1)
Memorial Bridge (U.S. Highway 1) foot Memorial Bridge (U.S. Highway 1) between foot of Russell and Deer Streets
of Hanover Street extended, extended.
Cares Street 64 Cares Street 227 Market Street
OWNED BY Portsmouth Navigation Corp.. division Society of Colonial Dawal New Hamp- Granite State Minerals. Inc.
of Central Wharf Tow Boat Co.. Inc. shire Division .
OPERATED BY do. Oar House, Inc. and Gallant do.
Industries, Inc.
PURPOSE FOR WHICH USED Mooring company-owned tugs and harbor Mooring excursion vessels and Receipt of salt: receipt and shipment
pilot boats. miscellaneous craft. of various dry bulk commodities and
heavy lift items.
TYPE OF CONSTRUCTION Masonary stone bulkhead, solid fill, Steel sheat pile bulkhead with Steel sheet pile bulkhead with solid with timber pile, timber-decked asphalt-surfaced, solid fill fronted
with timber pile, timber-decked asphalt-surfaced, solid fill fronted fill fronted by steel pile, timber-
extendsion one 40-foot,timber, mooring by 6-foot wide timber float. decked, asphalt-surfaced extension.
float located at lower end of wharf
DESCRIPTION Face Lower side Face Sides Face Lower side Upper side
Dimensions (Feet) 125+40 18 100 31 300 32 50
Depth Alongside at MLW Do: 16-17 - 12 32
Breasting Distance Do: 165 100 300
Total Berthing Space Do: 3 abreast 100 300
Width of Apron Do: Open and 33 25 32
Height of Deck Above HLW Do: 10 1. float. 18
Load capacity (Lbs. per sq. Ft. lighted. Partly lighted
Lighted or unlighted Lighted. One 130-ton, electric, pedestal-mounted,
MECHANICAL HANDLING FACILITIES None revolving crane with 100-foot boom
equipped with 6-cubic yard clamsbell
bucket for unloading salt into storage
area at rear. One 6-cubic yard, diesel,
front-end loader for reclaiming salt receiving
from storage into a portable receiving
hopper with gasoline-operated, inclined,
diesel. crawler cranes, each with 85-foot
boom, equipped with 4-cubic yard bucket o12edtvichilt-cubic: yard bucket
capable of 20-ton lifts at 35-foot
radius when working in tandem.
RAILWAY CONNECTIONS None. None. one surface track in rear of upper end
of wharf serves open-storage areas con-
nects with Boston and Mains, Railroad.
HIGHWAY CONNECTIONS Via Ceres street. asphalt. 20 feet Same as Ref. No. 7. Via Market Street, asphalt, 50 feet
wide,from Bow street, asphalt 25 wide, from Interstate Highway 95. w ':pholt. 50 feet
feet wide
WATER SUPPLY Through one 1 1/2 inch line None. Through one 2-inch line.
(Available to Vessels)
ELECTRIC CURRENT A.C., 110/220 volts. A.C., 110/22O Volts. A.C., 110/220 volts
(Available to Vessels)
FIREPROTECTION water line, hose, hand extinguishers Hand extinguishers water line, hose, and watchmen.
(Other than City) and watchmen.
REMARKS Tug dispatch and Portsmouth Pilots Portsmouth Harbor Cruises operates Approximately 2 acres of open storage
offices located at rear. excursion vessels from wharf. area fir 50,000 tons of material
at wharf, and approximately 8 acres of
additional, company-owned, open storage wharf. and approximately 8 acres of
area for 100,000 tons at Boston and
Maine Portsmouth rail yard located
on east shore of North Mill Pond,
approximately 1,500 feet in rear.
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Appendix 24 Page 4
PIERS. WHARVES. AND DOCKS
Portsmouth, New Hampshire, right bank, Piscataqua River
Corp of Engineers Port Code No. 00600 00610
REFEREBCE NUMBER ON MAP 10 Dock Code No. 765 11 Dock Code No. 735 12 Dock Code No. 900
NAME Viking,wharf. New Hampshire State Port Authority, National Gypsum Co., Portsmouth Plan-
Marine Terminal Wharf. Wharf.
LOCATION ON WATERFRONT Approximately 1,500 feet below Maine- Below Maine-New Hampshire Interstate Approximately 1,000 feet below Inter-
New Hampshire Interstate Bridge below Bridge on Nobles Island. state 95 Highway Bridge.
Nobles Island.
315 Market Street Freeman's Point
OWNED BY Viking of Yarmouth, Inc. New Hampshire State Port Authority. Cold Bond Building Products. division
of National Gypsum Co.
OPERATED BY do. New Hampshire State Port Authority Gold Bond Building Products, division
and John T. Clark & Son of New of National Gypsum Co. and Northeast
Hampshire, Inc. Petroleum Corpuf New Hampshire.
PURPOSE FOR WHICH USED Mooring and landing for excursion Receipt and shipment of containerized Receipt of gypsum rock b self-unloading
boats to Isles of Shoals. and conventional general cargo in vessels receipt of petroleum products.
foreign and domestic trade; shipment
of scrap metal and miscellaneous
bulk materials.
TYPE OF CONSTRUCTION Timber pile, timber-decked offshore Concrete-filled, steel pipe pile. Steel sheet pile bulkhead with solid
wharf. with 60- by 9-foot timber concrete-decked. part offshore wharf fill fronted by 3 steel sheet pile,
approach from bank at east end. and fronted by rubber fender system. with cellular breascing dolphins.
50- by 3-foot timber approach from a 45- by 36-foot, concrete, roadway,
bank at west end; inclined timber bridge approach at lover and.
ramp to 20- by 8-foot timber float at
east end.
DESCRIPTION Face of
Face East side West aide Face Lower side Upper side bulkhead Lower side Upper side
Dimensions (Feet) 135+20 12 12 578 92 75 300 30 30
Depth Alongside Do. 15 15 8 35 - - 34-35 - -
Breasting Distance Do. 135+20 - - 578 - - 265 dolphs - - Total Berthing Space Do. 180 578 - - 450 - -
Width of Apron DO. 12 476122 Open
Height of Deck Above MLW Do. 11 14 14 & 16
Load Capacity (Lbs.per sq ft) - 600 -
lighted or unlighted Lighted. Lighted Lighted
TRANSIT SHEDS None. Two - steel frame, clearspan,metal- None.
Number and Description covered. concrete floors.
Length and Width (feet) 350 by 60 240 by 120
height inside Do. 18 17
Floor Area for cargo (sq.ft.) 18,000 25,000
Load Capacity per sq.ft. (Lbs.) 600 600
Cargo Doors (feet) Shipside: two 15x14 -
Rear: three24x14-15 - Sides: one 24x14 four 20 & 16x14
Truck Dock: - two 12x14
MECHANICAL HANDLING FACILITIES None. John T. Clark& Son of New Hampshire: Steel cover with hinged-cantilevered
5 diesel crawler cranes: boom on 50- by 25-foot, steel pile.
concrete-decked platform located at
NO. CAPACITY BOOM LENGTH lower side: hopper at outer end of
(TONS) (FEET) boom receives gypsum from self-unloading
1 165 110 vessels. serves inclined. 52-inch,
2 50 65 electric, belt-conveyor system extend-
1 30 65 ing to open storage area at rear: one
1 15 50 hosehandling tower located on center
breasting dolphin for unloading
One 15-, ten 4- and twenty 2 1/2-ton petroleum products. Material is
forklift trucks. reclaimed via bulldozer with ripper
Additional stevedore equipment is loading a level hopper served by a 15-
available as required. inch conveyor belt extending to plant.
RAILWAY CONNECTIONS None. one surface track serves open storage One surface track serves plant at rear
area in rear; connects with Boston connects with Boston and Maine Rail-
and Maine Railroad. road.
HIGHWAY CONNECTIONS Via Market Street. asphalt, 50 feet Same as Ref. No. 10 Via Cutts Avenue. asphalt, 20 feet
wide, from Interstate Highway 95. wide, from Market Street extension and
Interstate Highway 95.
WATER SUPPLY None. Through 3-inch line. None.
(available to Vessels
ELECTRIC CURRENT A.C., 110/220 volts. A.C., 110 volts. None.
(Available to Vessels)
FIRE PROTECTION Hydrants. hose, and hand extinguish- Hydrants. hose. hand extinguishers, Water line and watchman.
(Other than City) ers and pumps and hose an excursion and sprinkler system in one transit
boats. shed.
REMARKS "MV Viking Sun" moors at wharf. Approximately 10 acres of partly- open storage area at rear of wharf for
paved. open storage area at rear. approximately 200,000 tons of gypsum
rock. Gypsum wallboard manufacturing
plant at rear.
Northeast Petroleum Corp:One 12 and
one 10-inch, pipelines extend from
wharf to 5 steel storage tanks at rear,
total capacotu N
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Appendix 24 Page 5
PIERS, WHARVES, AND DOCKS
Portsmouth, New Hampshire. right bank, Pascataqua River
Corps of Engineers Port Code No.
REFERENCE NUMBER ON MAP 13 Dock Code No. - 14 Dock Code No. 870 15 Dock Code No. 864
NAME Public servicer C0. of New Hampshire, Mobil Oil Corp, Portsmouth Terminal C. H. Sprague & Son Co. Wharf.
Schiller Station Mooring. Wharf
LOCATI0N ON WATERFRONT Approximately 0.7 mile above Inter- Approximately 0.8 mile above inter- Approximately 0.9 mile above Interstate
state Highway 95 Bridge. state Highway 95 Bridge. Highway 95 Bridge.
Public Service Co. of New Hampshire. Public Service CO. of New Hampshire Public Service Co. of New Hampshire
OPERATED BY Not operated. Mobil Oil Corp. C.H. Sprague & Son Co.
PURPOSE FOR WHICH USED Not used. Receipt of petroleum products; occa- Receipt of coal and fuel oil.
sional bunkering of vessels.
TYPE OF CONSTRUCTION Two 30-foot-diameter, steel sheet Steel pile, concrete-decked. offshore Concrete pile, steel beam, concrete-
pile, cellular breasting dolphins 200 wharf with one walkway and one pipe- decked, offshore wharf with 100- by 20-
feet apart with 8O- by 15-foot timber line approaches; 3 steel sheet pile. foot approach; one steel sheet pile,
approach to lower dolphin. cellular mooring dolphins in line with cellular mooring dolphin, located
face and connected by catwalks. approximately 100 feet below and to
rear of face, wharf is fronted by
rubber-cushioned fender system.
DESCRIPTION Dolphins Face Lower side Upper side Face Lower side Upper side
Dimensions (feet) 230 37 60 30 405 40 40
Depth Alongside at RtW DO. 23 37 - - 37 - -
Breasting Distance DO. 230 250 - - 400 - -
Total Berthing Space, DO. 230 250 - - 700 - -
Width of Apron DO. 30 30 Open
Height of Deck Above MLW DO. 10 10 11
Load Capacity (Lbs. per Sq Ft.) - - 500
Lighted or Unlighted Unlighted. Lighted. Lighted.
TRANSIT SHEDS None. None. None.
Number and Description
Length and Width (Feet)
Height Inside DO.
Floor Area for Cargo (Sq. Ft)
d Capicity per Sq. Ft. (Lbs.)
Cargo Doors
MECHANICAL HANDLING FACILITIES None One hosehandling tower on wharf. One electric, traveling, gantry. 16-inch
auger unloader with maximum 78-foot out-
board reach travels 380 feet along
wharf, unloads onto a 48-inch longitudi-
nal. thence transverse, belt conveyor
extending to open storage, area atop high
bank in rear, rate 1,000 tons per hour.
One mast-and-boom derrick with 35-foot
boom for handling hose.
RAILWAY CONNECTIONS None. None. One 500-foot surface track serves tank
carloading rocks at rear of wharf; con-
nects with tracks of Boston and Maine
Corporation.
HIGHWAY CONNECTIONS Via plant road, asphalt. 15-20 feet Same as Ref. No. 13. Via plant road, paved, 15 feet wide.
wide. from Gosling Road, asphalt. from foot of Gosling Road, asphalt,
30 feet wide. 30 feet wide.
WATER SUPPLY Through 3-inch line. None. Through 21/2-inch lines.
(Available to Vessels
ELECTRIC CURRENT None. A.C., 220/440 volts. None.
(Available to Vessels)
FIRE PROTECTION None. Chemical carts and hand extinguishers. Heat sensors and sprinkler system on
(Other than City) conveyor, foam system at tanks, hose,
hand extinguishers, and security patrol.
REMARKS Facility was formerly used for mooring Mobil Oil Corp.: Two 14-, two 12-, Schiller Steam Electric Generating
afloating power plant. and one 10-inch pipelines extend from Station located at rear of wharf. Open
One 8-inch pipeline extends to wharf wharf to 14 steel storage tanks storage area atop bank has capacity for
from one 30,000-barrel fuel oil stor- terminal an opposite side of Gosling 53,000 tons. One 16-inch pipeline
age tank at rear not in use at time Road, total capacity 550,000 barrels. extends from wharf to 8 steel storage
of survey. C. H. Sprague & Son Co. maintains a tanks at C. H. Sprague & Son Co. terminal
10-inch pipeline connection to wharf in rear, total capacity 577,000 barrels;
for bunkering purposes, not in use at one 20-inch pipeline extends from wharf
time of survey (1984). to 2 steel storage tanks serving
Newington Power Plant approximately
1/4 mile upstream, total capacity 566,000
barrels.
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Appendix 24 Page 6
PIERS, WHARVES, AND DOCKS
Newington, New Hampshire, right bank, Piscataqua River
Corps of Engineers Port Code No. 00610
REFERENCE NUMBER ON MAP 16 Dock Code No. 855 17 Dock Code No. 18 Dock Code NO. 847
NAME
Simplex Wire and Cable Co. Wharf. American Trawler Co. Dock. Defense Fuel Support Point. Newington
Dock,
LOCATION ON WATERFRONT Approximately 1.5 miles above Approximately 1.8 miles above Approximately 2 miles above Interstate
Interstate Highway 95 Bridge. Interstate Highway 95 Bridge. Highway 95 Bridge.
2073 Woodbury Avenue Old Dover Road Foot of Patterson Lane
OWNED BY Simplex Wire and Cable Co. Richard Bruno. U.S. Government, Department of Defense
Logistics Agency
OPERATED BY Simplex Wire and Cable Co. Sub- American Trawler Co.. Inc. New England Tank Industries of New
marine Cable Division. Hampshire. Inc.
PURPOSE FOR WHICH USED Shipment of wire and submarine Receipt of fish and seafood; fueling Occasional receipt of petroleum products
cable; receipt of submarine cable to fishing vessels, by tanker; shipment of petroleum
be refurbished. products by barge.
TYPE OF CONSTRUCTION Concrete-filled, steel pipe pile, Steel pile. concrete-decked. L-shaped Offshore wharf: Row of four steel
steel beam, concrete-decked, off- pier. sheet pile. cellular breasting dolphins
shore wharf with 250- by 15-foot connected by catwalk extending to bank
approach; 4 steel breasting dolphins from upper dolphin. Two middle dolphins
below, and one 30-foot square steel connected by timber deck.
pile, concrete-decked breasting
dolphin above, all in line with face.
DESCRIPT10N
Rear of Lower Upper
Face Lower side Upper side Face face side side Face
Dimensions (Feet) 130 30 30 210 185 25+250 275 344
Depth Alongside at MLW Do. 30 - - 21 10-11 10-11 10-21 32
Breasting Distance 690w/dolphs. - - 210 185 25+250 275 344
Total Berthing Space Do. 690 - - 210 185 25 250 275 300
Width of Apron Do. Open. 25 275 40
Height of Deck Above MLW Do. 15 15 15
Load Capacity (Lbs. per Sq.Ft.) - - -
Lighted or Unlighted Lighted. Lighted. Lighted.
TRANSIT SHEDS None. None. None.
Number and Description
Length and Width (Feet)
Height Inside Do.
Floor Area for Cargo (Sq.Ft.)
Load Capicity per Sq.Ft. (Lbs.)
Cargo Doors
MECHANICAL HANDLING FACILITIES Electric, portable. cable-pulling Two electric mast-and-boom derricks: Timber platform on middle calls has
machines move continuous lengths of One 0.6-ton with 30-foot boom and one unused electric. steel, stiff-leg
cable over covered, inclined, roller One 0.4-ton with 20-foot boom. derrick with 40-foot boom.
system extending to wharf from plant
at rear.
RAILWAY CONNECTIONS One surface track serving plant ac None. None.
rear connects with Boston and Maine
Railroad.
HIGHWAY CONNECTIONS Via private driveway. part asphalt Via driveway and Old Dover Road. each Via driveway, asphalt. 20 feet wide
and part unpaved, 18 to 20 feet wide, asphalt, 20 feet wide, from Woodbury from Patterson Lane. asphalt, 15 to
from Woodbury Avenue. asphalt. dual Avenue, asphalt, dual lane. 20 feet wide. from Dover Road U.S.
lane. Highway 4 and State Highway 16.
asphalt, dual lane.
WATER SUPPLY Through 2-inch line with 1 1/2-inch con- Through 1-inch Line. None.
(Available to Vessels) nection.
ELECTRIC CURRENT A.C., 110/208/440 volts. A.C., 110/220 volts. A.C., 110/220/240 volts.
(Available to Vessels)
FIRE PROTECTION Water line, hose, hand extinguishers. Hose and hand extinguishers. Chemical cart. hand extinguishers, and
(Other than City) and watchmen. security patrol.
REMARKS Special ocean cable-laying vessels One 3-inch salt water pipeline serves One 16- and one 8-inch pipelines ex-
berth and load cable at wharf. pier. tend from wharf to 6 storage tanks at
Processing plant at rear has freezer rear. total caps capacity 360.000 barrels,
storage for 750.000 pounds and re- and one 10- and one 8-inch pipelines
frigerated storage for 300,000 pounds extend from tank farm to two steel
storage tanks at Pense Air Force Base.
total capacity ll0,000 barrels.
25
15
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Appendix 24 Page 7
PIERS, WHARVES, AND DOCKS
Corps of Engineers Port Code No. 00610 Piscataqua River, New Hampshire
REFERENCE NUMBER ON MAP 19 Dock Code No. 845 20 Dock Code No. 80 21
NAME Storage Tank Development Corp. Dock. Sprague Energy Newington Terminal Dock Code, No. 260
Wharf Badger's Island Marine Services Wharf.
feet above Memorial
south side of
of Badger Island, Kittery,
Foot Of Patteson Lane deep-draft navigation.
OWNED BY 126 River Road Maine. 68 Thorners Lane
Storage Tank Development Corp. C.H. Sprague & Son Co. Charles C. Patten.
OPERATED BY do. do. Badger's Island Marine-Services, Inc.
PURPOSE FOR WHICH USED Receipt and shipment of petroleum Receipt and shipment Of petroleum Mooring fishing boats and other small
Products; receipt of asphalt. No. 6 products. asphalt, tallow and caustic vessels for repair; mooring miscellane-
fuel oils, liquefied petroleum gas soda. ous vessels.
and methyl-methacrylate. (See
Remarks. )
TYPE OF CONSTRUCTION Offshore wharf: row of 3 steel sheet Steel pile, concrete-decked, offshore wharf Timber pile. timber-decked, offshore wharf.
pile. cellular breasting dolphins with 300- by 10-foot steel pile timber- with 65- by 10- and 80- by 12-foot approaches.
connected by steel pile, timber- decked approach; One steel sheet pile, cellu- fronted by a perminently moored timber barge
decked catwalk with 160- by 4-foot lar breasting dolphin an each side, in line and 4 parallel Limber floats spaced 36 feet
approach of same construction to with face. Timber and steel catwalks extend apart connected by a commonn 5-foot wide float
lower dolphin. from wharf to breasting dolphins. and con- approach from barge.
tinue at angle to 2 steel and concrete moor-
ing dolphins an upper and One an lower sides.
DESCRIPTION Four Parallel Floats Barge
Face Face Lower side Upper side Outer Center Piers Inner
Dimensions (Feet) 250 -5 30 30 240x5 190x5 150x5 110x5 110x30
Depth alongside at MLW Do. 38 35 30-35 - 11 10 9 8 8
Breating Distance Do. 250 225w/dolphs.- - 475 375 295 215 105
780 780 - - 475 375 295 215 105
Total berthing Space 700
Width of Apron Do. 50&30 Open. 5 5 5 5 30
Height of Deck Above MWL Do. 14 14 2 2 2 2 12
Load capacity (Lbs. per Sq.Ft.) - - -
Lighted or unlighted Lighted. Lighted. Lighted.
TRANSIT SHEDS None. None. None.
Number and Description
Length and Width (Feet)
Height Inside Do.
Indoor Area for Cargo (Sq.Ft.)
Load Capacity per Sq.Ft. (Lbs.)
Cargo Doors
MECHANICAL HANDLING FACILITIES- One 50-foot-long electric telescopic Steel framework on platform equipped One 4-ton, Gasoline-hydraulic. mobile
boom mounted on tower on center with electric hoist and one 20-foot crane.
dolphin. rotating boom for handling hose.
RAILWAY CONNECTIONS One 2-car-capacity surface track One surface track with capacity for None.
serves terminal in rear connects with 3 cars serves terminal in rear
Boston and Maine Railroad. connects with Boston and Koine
Railroad.
RICHWAY CONNECTIONS Via driveway asphalt, 20 feet wide, Via private road, asphalt. 25 feet Via Thorners Lane, asphalt. 20 feet
from Pattern Lane asphalt, 15-18
wide, from River Road, asphalt, 20 wide, from U.S. Highway 1.
feet wide, from Spaulding Turnpike foot wide from Spoulding Turnpike.
(U.S. Highway 4) State Highway 16).
WATER SUPPLY None. Through 2-inch line. Through 3/4-inch line.
(Available to Vessels)
ELECTRIC CURRENT A.C. 110/220 volts. None. A.C.. 110/220 volts.
(Available to Vessels)
FIRE PROTECTION Hydrants, hose, pump, 4-inch fire Water line, hydrant. hose. hand Water line. hose, and hand extinguishers.
(Other than City) water line. hand extinguishers. and extinguisher,and security patrol.
security patrol.
REMARKS Storage Tank Development Corp.: Four One 16-. one 14-, four 10-, and one Two 30-ton marine railways located on
16- and one 12-inch pipelines extend 8 1/2 -inch pipelines extend from wharf upscream side of floats.
from wharf to 6 asphalt storage tanks, to 3 asphalt storage tanks. total
total capacity 159,000 barrels; one capacity 65.000 barrels, and 6
150,000 barrel storage tank for No. 6 petroleum products storage conks,
fuel oil; 4 storage tanks for other total capacity 593.000 barrels.
petroleum products. total capacity One 10-inch pipeline extends to 2
174,000; and one 15,000-barrel caustic soda storage tanks. total
methyl-methacrylate storage tank. capacity 30.000 barrels and to 6
At time of survey (1984), methyl- tallow tanks, total capacity 54,000
methacrylate was being received only barrels.
by rail.
Dorchester Sea-3 Products, Inc.:
One 18-inch pipeline extends from
wharf to one 400,000 barrel liquefied
petroleum gas storage tank.
New England Tank Industries of New
Hampshire: One 18-inch pipeline
on wharf connects with pipelines and
tankage described under Ref. No. 18.
�
�
Appendix 24 Page 8
uscG waterfront Facility Information
On the Piscataqua River Basin
302 Transfer; Storage and Processing Facilities
301.1 Purpose and Objectives. This section describes the bulk storage
facilities and lists various companies involved in transporting of petroleum
products and hazardous substances.
302.2 Bulk Storage Facilities
302.2-1 Piscataqua River Basin
Facility Name and Address Product Amount Stored (bbl)
Northeast Patroleum Corp. Kerosene 549,660
Preble Way Diesel
Portsmouth, NH 03801 Fuel Oil #2
(603) 436-5147
Mobil Oil Corp. Gasoline 509,246
Gosling Road Fuel Oil
Portsmouth, NH 03802 Kerosene
(603) 436-7887 Diesel
C. H. Sprague and Company #6 Fuel Oil 342,000
290 Gosling Road #4 Fuel Oil
Portsmouth, KH 03802
(603)436-4120
Newington Station 560,000
Schiller Station 205,000
Fuel Storage Corp. #6 Oil
Patterson Lane Asphalt 700,000
Newington, NH 03801 Fuel Oil
(603)436-1551 Kerosene
JP4
Methyl Methacrylate 15,000
Defense Fuel Support Point Jet Fuel, JP-4 360,000
Patterson Lane
Newington, NH 03801
(603)431-6885
Sea-3 Products LPG 400,000
P.O. Box 1410
Newington, NH 03801
(603)431-5990/2/3
C. H. Sprague and Company Asphalt
P.O. Box 1288 Gasoline 1,046,500
Old Dover Road Fuel Oil #2,#4,#6
Newington, NH 03801 Kerosene
(603)431-5131 Diesel
Tallow 54,000
Caustic Soda 22,500
�
Appendix 24 Page 9
USCG Waterfront Facility Information
On the Piscataqua River Basin
Facility Name and Address Product Amount Stored (bbl)
Whale Co. Oil Heating Oil 71
3000 Lafayett RD
Portsmouth, NH 03801
(603)436-1110
U.S. Navy Gasoline 352,000
Kittery, ME Diesel
(207)438-1000 Heavy fuel oils
Ext. 1898 Main Office
Ext. 1835 Fuel Plant
(207)438-1898 Tom Gillory Oil Spill Coordinator
302.2-2 Saco River Basin
Brooks Wollen No. 6* 40,000
Sanford, ME
(207)324-3080
302.2-3 Presumpscot River-Casco Bay Basin
Central Main Power Co. No. 2 61,000
Cape Elizabeth Station
So. Portland, ME
(207)799-7561
Central Maine Power Co. Bunker C 953,000
W. F. Wyman Station #2 Oil
RR #1, P,O, Box 2268
Yarmouth, Maine 04096
(207)846-9055
British Petroleum Corp. Gasoline 660,000
59 Main Street Fuel Oil
So. Portland,.ME 04106 Kerosene
(207)799-8586 -
Gulf Oil Co. Gasoline 875,000
175 Front Street Heating Oil
So. Portland, ME 04106 Kerosene
(207)799-5561 Bunker C
Northeast Petroleum Corp Kerosene 482,000
1 Clark Road Fuel Oil
So. Portland, ME 04106 6 Oil
(207)799-4504
Getty Refining Gasoline 299,100
Marketing CO Fuel Oil #2
P.O. Box 1590
So. Portland, ME 04106
(207)799-8518
�
Appendix 24 Page 10
USCG Vessel and Cargo Information
MONTHLY TRAFFIC SUMMARY FOR
THE MONTH OF DECEMBER 1987
PORTSMOUTH:
TANKERS: BARGES:
LAGOVEN GUANOCO 20 ' 000 B. NO. 65 20,000
POMEROL 152,000 E-57 55,000
CHABLIS 210,000 B. No. 85 62,000
PACIFICA 216,000 E-57 54,000
PORT BLANC 231,000 B. No. 35 18,000
OMI CHARGER 100,000
FOSSARINIA 175,000. TOTAL NUMBER OF BARGES 5
POMELLA 145,000 TOTAL CARGO AMOUNT 209,000
TOTAL NUMBER OF TANKERS 8
TOTAL CARGO AMOUNT 1,249,000
CARGO:
ARCTURUS 2,000 MT TALLOW
YANKEE CLIPPER CONTAINERS
GOLD BOND TRAILBLAZER 28,268 MT GYPSUM ROCK
JUVENTIA 10,000 MT COAL
ISLAND GEM 9,000 MT SCRAP IRON
YANKEE CLIPPER CONTAINERS
HAVMANN 7,000 MT LPG
YANKEE CLIPPER CONTAINERS
HAPPY VALLEY 470 MT STEEL COILS
ZUES CABLE
YANKEE CLIPPER CONTAINERS
STOLT AQUAMARINE 4,000 MT CAUSTIC SODA
ISOMERIA 14,400 MT LPG
MITHILDA DEGAGNES. 6,500 MT SALT
MARTHA A 2,000 MT TALLOW
GOLD BOND TRAILBLAZER 28,600 MT GYPSUM ROCK
WOENSDRECT 31,500 MT SALT
TOTAL NUMBER OF CARGO VESSEL 17
TOTAL CARGO AMOUNT 143,738 MT PLUS
�
Appendix 25
Vessel Stability
Concepts and Definitions
Introduction. The intent of this section is to provide a basic
understanding of vessel stability to Portsmouth Harbor fire
personnel who must comprehend and base decisions upon expert
advice that should be available during an incident. It is not
intended to supply the knowledge that is gained only through
specialized education and many years of experience.
Vessel Stability and Equilibrium. Stability is the tendency of
a floating vessel to return to an upright position when inclined
from the vertical by an external force. If the vessel returns
to or remains at rest af ter being acted upon, it is either in
stable or neutral equilibrium. If it continues to move
unchecked in reaction to the external force, it is in unstable
equil ibr ium. An unstable vessel therefore, is one that after
being inclined, continues to incline, possibly until it
capsizes. Throughout an incident, it is desirable to maintain
vessel stability and minimize list.
Initial Stability. The ability of the vessel to initially
resist heeling from the upright position is determined by its
initial stability. The vessel's initial stability
characteristics hold true only for relatively small angles of
inclination. At larger angles, defined as those over 10
degrees, the ability of the vessel to resist inclining moments
is determined by its overall stability characteristics.
Typical Vessel Conditions. This section will generally address
stability matters concerning vessels in the following two
conditions: (1) floating -410 (2) whose hulls are intact.
Usually, these conditions will exist during the beginning stages
of an incident. Stability and weight distribution considerations
are relatively uncomplicated when these two criteria are met.
If, for instance, an explosion has ruptured the hull or the
vessel has contacted the bottom, considerations will be more
involved. These more complex situations may occur singly or in
combination and include vessels:
� Aground
� Damaged (holed) with free communication
� Underway with extensive free surface
� In dry dock, graving dock, synchrolift, etc.
Unquestionably, expert advice should be obtained anytime the
stability of the vessel is in doubt. A complete list of
consulting resources, including those for vessel stability,
should be compiled and maintained. The vessel's crew, who
is should be most familiar with the vessel's stability situation,
may not always be available or able to provide adequate
situation assessment.
�
Appendix 25 Page 2
Center of Gravity. The center of gravity of an intact vessel
is the location of the point where the sum of all the weights in
the vessel is equal to zero with respect to any axis through
this point. The vertical downward force of gravity acts through
this point. The center of gravity and its relationship with the
vessel's center of buoyancy and righting arm are key factors to
understand when determining and controlling vessel stability.
The illustration on Page 3 shows this relationship.
The concept of center of gravity, whether for a vessel or other
mobile equipment such as an aerial ladder or snorkel, is
essentially the same. In essence, the weight of the particular
piece of equipment is considered to be concentrated at that
point. As an aerial ladder is raised, the unit's center of
gravity rises and is counteracted by the inherent weight of the
vehicle and its supporting outriggers. Similarly, a vessel's
center of gravity also rises as weight is placed higher in the
vessel. It differs in that it is unable to provide external
support mechanisms (i.e. outriggers) due to the water around it.
Vessels, will therefore suffer a loss of stability as water
utilized in firefighting is accumulated above the original
center of gravity. This is particularly significant in regard
to vessels with large superstructures such as passenger ships
and car carriers. The higher the weight, the more detrimental
the effect. If this vulnerability is not properly understood
and controlled, the consequences may severely impact all
firefighting efforts. It is an integral part of overall
strategy.
Free Surface Effect. Free surface, for firefighting
considerations, is the tendency of liquid within a compartment
to remain level as the vessel is transversely inclined or heeled
pro'viding the compartment is : (1) intact, (2) partially full,
and (3) allowing the liquid to move unimpeded from side to side.
The free surface effect of loose water anywhere in the vessel
will impair stability by raising the center of gravity in an
apparent or virtual sense.
Free Surface Critical Factors. If the vessel is listing or
develops a list, the liquid will flow to the low side of the
compartment and result in an athwartship shifting of weight.
This movement causes the apparent height of the center of
gravity to rise, impairing stability. The critical factors of
free surface are the surface area of the liquid and the breadth
of the compartment. The length of the compartment is much less
a factor as it varies in direct ratio with the cube of the
compartment's beam. The depth of the liquid and its location in
the vessel have little relation to the free surface effect for
firefighting considerations. Whether the liquid is high or low,
on or off centerline, forward or aft, the reduction in stability
0 due to free surface will be the same.
�
Appendix 25 Page 3
Free Surface Reduction. Pocketing is the effect of the liquid
contacting the top of the compartment or exposing the bottom of
the compartment. It will reduce the breadth of the free surface
area and therefore will have a beneficial effect on stability.
Similarly, solid objects projecting through the surface will
impede the liquid's movement and be of some benefit. Since the
positive effects of pocketing and surface permeability are
difficult to determine, they should be considered an extra
margin of safety in free surface stability assessments.
Combined Effects. The strongest threat to vessel stability from
water-induced firefighting efforts it encountered when the water
is (1) conf ined high in the vessel and (2) is free to travel
significant distances across the beam. The consequences of
these combined effects may be devastating. Unfortunately, they
sometimes trigger other serious problems. once the vessel begins
to heell this 'domino effect' may quickly compound an already
aggravated situation. These concerns will be addressed in the
next section.
Center of Buoyancy. If the water that is displaced by the
vessel were considered as one homogeneous unit, the center of
the displaced volume of water would be considered the location
of the vessel's center of buoyancy. It is the geometric center
of the underwater form of the vessel. The vertical upward force
of buoyancy acts through this point.
Righting Arm. The perpendicular distance between the force of
gravity (through the center of gravity) and the force of
buoyancy (through the center of buoyancy) is termed the righting
arm or righting lever. It is generally calculated at 10 degree
intervals of list for several different load conditions of the
vessel.
Metacentric Height. The true measure of a vessel's initial
stability is called the metacentric height or GM of the vessel
(below). It is simply a geometric relationship between the
center of gravity (G) , the center of buoyancy (B) , and the
vessel's righting arm (GZ) for a given angle of inclination.
Z = Righting Arm Perpendicular
0 = Angle of Inclination/List
M = Metacentric Height
G = Center of Gravity
B = Center of Buoyancy
Bl= New Cntr. Buoyancy
131
Stability
Relationship s
�
Appendix 25 Page 4
Metacentric Hej_0-t (continued)
If M is above G, the metacentric height (GM) is positive. If M
is below G, then metacentric height (GM) is negative. A
positive GM indicates the vessel will tend to float upright and
will offer resistance to an applied outside force. A negative
GM indicates the vessel to be initially unstable and will cease
to float upright when even the smallest outside force is
applied. An initially unstable vessel may only list at some
particular angle and come to rest in a state of stable
equilibrium. If the negative GM is large enough, the vessel
will not come to rest before capsizing.
This relationship of the vessel's stability and GM is only
accurate at small angles of heel (below 10 degrees). As list
increases, the overall stability of the vessel is the
determining criteria. This can be interpreted through the
vessel's stability curves usually found in the vessel's Trim
and Stability Booklet.
Stability Curves. The graphic curves depicting the vessel's
calculated righting arms at incremental angles of heel are
termed the vessel's stability curves. These curves reveal the
overall stability characteristics of the vessel. They are
extremely important since they quickly reveal the maximum
righting arms for the vessel at different conditions of lading
(different values of GM). The maximum righting armi, and more
importantly, the angle of inclination at which it occurs, is the
primary danger indicator when the stability of the vessel is in
serious doubt. A fictitious example, of a partially loaded
vessel with a +2 ft. GM is depicted in the stability curve
below. Maximum
Angle @ 36
S/S BIG TROUBLE Degrees
GM +2.0 Feet
3-
Righting
Arm
(Feet) 2 -
0 1
0 5 10 20 3o 4o 50 60 @O
Angle of Inclination (Degrees)
Note the maximum righting arm attained in this condition is at
an approximate inclination angle of 36 degrees. Generally, this
maximum angle indicates the point at which the edge of the
weather deck becomes submerged. At this point stability drops
of f rapidly. A vessel suffering a permanent list would be in
imminent danger of capsizing long before this angle was reached.
�
Appendix 25 Page 5
Vessel-Stability Concerns
General. The most important concern regarding vessel stability
is control of the vessel's list. The inability to maintain the
vessel at a reasonable degree of transverse levelness will
seriously impact all firefighting operations.
I
Firefighting Factors Affecting Stability. The introduction of
large amounts of water into the vessel as a result of
firefighting operations will probably be the most critical
factor affecting vessel list. other factors include:
o intentional flooding of compartments
o personnel/equipment movement through watertight doors
Stability Factors Affecting Firefighting. As a vessel's list
increases, so do the concerns related to firefighting
activities. As the vessel heels, poor footing on slippery decks
can slow or stop fire combat teams. It may be difficult to
apply and maintain a foam blanket. Other concerns include:
� increased chance of flammable liquids spilling
� possible closure problems with automatic fire doors
� strain and possible failure of mooring lines
o restriction and loss of vessel access/egress
� damage or injury from loose objects shifting
� problems with fixed dewatering drains and suctions
� loss of vessel machinery due to excessive sustained list
Vessel Factors Affecting Initial Stability. The stability of the
vessel is described as its ability to resist heeling from the
upright position at small angles of inclination. This ability,
which is a function of the vessel's GM, may diminish rapidly as
the incident progresses and will depend on current vessel
factors such as:
o the free surface status of all liquids aboard
o whether or not the hull is intact
� if contacting groundf flatness of hull bottom
� whether double bottoms are empty or full
� if flooding, intactness of watertight boundaries
Instability Factors Affecting overall Stability. As the vessel
destabilizes and list increases to larger angles of inclination,
other factors may aggravate the vessel's worsening condition.
These include:
o shifting of loose, bulk dry.cargo such as grain or coal
o flooding from unsecured hull openings like portholes
o movement of unsecured cargo, machinery, stores, etc.
�
Appendix 25 Page 6
Instability Factors Affecting Underway Operations. The
self-propelled movement of a destablized vessel within a
confined waterway may be hampered by operational difficulties.
If suffering a large list, trimmed by the bow, or drawing too
tight a draft for the available water, operational concerns
would include:
� steering system may function improperly
� vessel machinery may not function at large lists
� loss of maneuvering control due to proximity to bottom
� if poor visibility, needed radar aid may be reduced
� free surface may cause vessel to flop from side to side
External Factors Affecting Stability. If external factors are
anticipated, then it is more likely that negative impacts will
be lessened and positive impacts used to their full advantage.
External factors would include:
� adjacent structures such as piers and wharves
� mooring lines if vessel is listing away from structure
� range of tide may cause vessel to contact bottom
� contour of bottom beneath vessel if contact occurs
� bottom composition beneath vessel such as mud or rock
� precipitation accumulations of snow or ice on high areas
� sea state of surrounding water
� action of passing vessels (waker suction effect, etc.)
� unusually intense high winds if significant 'sail' area
Basic Stability Information and ggsources
Stability Resources, An Incident Commander with a basic
understanding of stability I should be able to make decisions
with appropriate consultation. A review of information gathered
prior to the incident and during the incident are necessary to
the best decision making. Information resources are divided into
consulting personnel and documentation. Stability equipment
resources are discussed under 'Dewatering'.
Consulting Personnel. Prior to an incident, a regional
inventory of stability advisors should be compiled. The list of
these agencies and individuals will include the USCG COTP and
the Marine Safety office (MSO) located in Portland, Maine. The
COTP or representative wil be on-scene to provide assistance and
stability advice. The COTP can also help access and coordinate
various federal resources and agencies should additional
expertise and/or equipment be necessary. Stability advice may
also be obtained from other personnel including:
� vessel's officers - Master, Chief Mate and Chief Engineer
� vessel operator/owner representative such as Port Captain
� Portsmouth Navigation Pilots
� N.H. Port Authority Director
� Portsmouth Naval Shipyard Staff
� salvage masters
� officers from other vessels
o marine consultants
� naval architects
� maritime academies
� marine firefighting schools
�
Appendix 25 Page 7
Documentation. It is prudent to maintain vessel information.
This should include information on regularly and occasionally
visiting vessels. Since it may be difficult to gather
information during an incident, gather information as possible.
General information and copies of vessel documents may be
available from the owner or operator if you should need
information during an incident. In an emergency though, some
firms may be able to send information via facsimile. The
preferred approach is to be familiar with the vessel's onboard
documentation prior to an event. Documentation and other
information which may be helpful with stability considerations
include:
� vessel trim and stability booklet or similar document
� vessel tons per inch immersion factor (T.P.I.)
� vessel general arrangement plan
� vessel capacity plan
� vessel fire control plan
� vessel docking plan
� vessel cargo plan
� slide rule used to calculate trim and stress factors
� computer or loadmaster used for stability calculations
Obtain Primary Stability Information. Basic stability data
should be gathered during the initial stages of an incident.
The methods or sources used to obtain the data often affect
accuracy. Always endeavor to verify information.
Vessel Drafts. Most large vessels have draft marks as vertical
scales on both sides of the hull at the bow and the stern. They
are usually incremented in either feet or meters with the bottom
of the number being the 'zero' line. Large ships and barges
also have draft marks midships on both sides. All drafts should
be visually read as soon as possible in order to establish a
baseline for future reference. For various reasons, automatic
draft gauges for obtaining draft readings remotely should be
suspected as inaccurate. If possible avoid using an automatic
reading as the primary source of draft information. Consider
such readouts a good double check for visual hull observations.
Vessel List. The angle of transverse inclination is normally
obtained aboard by reading the vessel's inclinometer. Most
vessels have one in the wheelhouse on the bridge deck. Some
vessels, particularly large ones, may have additional
inclinometers at other locations including the: engine room
control flat, cargo control room, Master's office, Chief Mate's
office, Chief Engineer's office, or at a prominent centerline
location on the main deck. Similar to the drafts, establish a
baseline reading as soon as possible for monitoring purposes.
Vessel Status. Determine tank and cargo status. If cargo
operations were in progress, the vessel may be considerably more
vulnerable to stability problems. This is especially true of
bulk carriers and even more so of liquid bulk carriers due to
the free surface effect. The location and status of any flooded
corppartments within the vessel should also be ascertained at
this point.
�
Appendix 25 Page 8
Available Depth of Water. Determine the minimum depth of water
at the shallowest location beneath the vessel. Subtract the
vessel's present deep draft from the water depth to obtain the
vertical distance between the vessel and the bottom. Tidal
changes should also be incorporated if applicable.
Type of Bottom Material. If the vessel contacts the bottom, the
nature of the bottom can be a very critical factor. For
example, the difference between a mud or rock bottom is
extremely significant. Vessel aground considerations apply. As
abovef determine this as soon as possible and insure accuracy.
Secondary Stability Information. If the stability situation is
in doubt, the initial assessment should be immediately followed
by a secondary assessment. If the vessel's stability is under
control and not serious, the following secondary information may
be gathered time permitting.
Hull Openings. Assess all direct hull openings, such as
portholes or cargo loading doors which may allow water to pour
aboard in the event a serious list occurs.
Water Flow. Calculate the amounts of water being introduced
throughout the vessel and those anticipated in the coming hours.
It may be convenient to determine rates in 'tons per hour' since
stability calculations will probably be worked in tons.
Dewatering Capacity. Determine the vessel's fixed dewatering
capacity and power supply potentials. As above, it will
probably be beneficial to convert all rates to 'tons per hour'.
Watertight Potentials. Determine watertight areas and
capabilities of vessel with regard to flooding resistance. Give
special attention to watertight doors and closing mechanisms.
Mooring Potentials. Assess the possible dangers to personnel
should mooring lines fail as a result of severe strain from the
vessel listing away from the pier or wharf. Fiber lines may be
subject to melting or burning. Learn what alternatives may be
available with the vessel's mooring system and be sure
consequences are understood.
Vessel Aground. If the vessel is aground or is in danger of
contacting the bottom, other information will be necessary and
may include:
� slope of ground beneath vessel
� shape of vessel's hull bottom
� proximity of passing deep-draft traffic
� sea state forecasts
o hull stress considerations
�
Appendix 25 Page 9
Dewsiteri
Water Weight. Aboard most large vessels weight is measured in
long tons of 2240 pounds. A gallon of salt water weighs about
8.5 pounds while fresh water weighs slightly less. This equates
to about 264 gallons per long ton. Note that these figures
apply to US gallons. Imperial gallons may be used aboard
British, Canadian or other vessels and should be adjusted for
accordingly.
Water Flow. A 2 1/2 inch hose with an approximate 1 inch
nozzle outlet under 100 lbs./sq. in. pressure delivers about 250
gallons per minute. Roughlyr this means that a 2 1/2 inch hose
delivers about 1 ton of water per minute. At one ton per
minuter 60 tons of water weight is added to the vessel each hour
a 2 1/2 inch line is in use. A 1 1/2 inch line can be
figured at roughly half or about 1/2 ton per minute. These are
minimal flow rates and vary significantly with pressure.
Vessel Fixed Pumps. Vessels will usually have bilge pump
capability for most machinery spaces and large compartments that
are situated in the lower parts of the vessel. Some of these
spaces may include:
� cargo holds
Is o main engine room
� boiler room
� shaft alley area
� cargo pumprooms
� thruster rooms
� forward machinery space
Fixed Pump Suctions. Vessel bilge pumps are usually attached to
fixed piping and will therefore have no flexibility regarding
movement and positioning of the pumps' suctions. Howeverr these
pumps often have the flexibility to ncrossover" and draw from a
varied number of fixed suctions. Consequently, the fixed system
is limited to pumping only water that settles into the lower
areas of the vessel. Water that accumulates in upper spaces
must be removed by some alternate means.
Fixed Pump Power. Some older steam vessels may have steam
reciprocating bilge pumps,, but most will have electric bilge
pumps that are powered by the vessel's generators. If the
vessel's main generators fail, the pumps will most probably be
unusable. Emergency generators may often be unable to supply
sufficient power to operate separate fire and bilge pumps
simultaneously, in addition to the normal emergency load.
Vessel Portable Pumps. Although some vessels may have a few
small portable diaphragm pumps that run on compressed air, most
vessels will provide limited portable pump capability.
�
Appendix 25 Page 10
Dewatgring (continued)
Vessel Drainage System. Drains located onboard most vessels are
designed to gravity drain most spaces that are above the
vessel's normal waterline through the hull into the sea. Spaces
that are at or below the water line are often drained into the
vessel 's bilges. Whether they drain overboard or into the
bilge, these drains (called "scuppers") are generally small in
diameter making them vulnerable to blockage by debris that would
almost certainly be present throughout the firefighting efforts.
Swimming pools should have their own drain system. In
accommodation areas, removal of plumbing fixtures at the deck
level may also assist in drainage.
Portable Pumps Brought Onboard. Dewatering arrangements should
be made without delay. Moving portable pumps onboard will
require hoisting equipment and numerous personnel to assist with
positioning. Dewatering considerations should be automatic and
must be addressed without delay if the fire is not quickly
suppressed. Sources of portable pumps in addition to those of
the municipal fire departments may include:
� USCG COTP
� Portsmouth Naval Shipyard
o pollution cleanup contractors
� industrial pump suppliers
� salvage companies
� USCG Strike Teams
Portable Pump Types. Pumps may be powered by a variety of
methods including electricity, air, gasoline and water. Of all,
the water eductor or ejector pump is probably one of the most
efficient devices to position within the vessel. It works on
the syphoning principle of a venturi and has no moving parts.
These units are extremely lightweight and require no supervision
once they are operational.
Cutting Holes. In areas of the superstructure, where the metal
is relatively thin, it may be preferable to cut holes to allow
water to run out. Do not violate the hull's integrity as a
serious list may allow water' to pour in the hole rather than
out.
Stability Analysis and Monitoring
Critical Angle of List. Once the vessel status is determined
as part of primary information , have the vessel's GM computed
for its present condition. Use the GM in conjunction with the
vessel's Trim and Stability Booklet to determine the maximum
righting arm for the vessel's current condition. One half of
the maximum righting arm angle is a good reference point as a
critical angle of list. If this angle is reached, the vessel is
in imminent danger of capsizing.
�
Appendix 25 Page 11
Stability-Analysis an-d-Mpnitoring (continued)
Vessel Drafts. Drafts should be monitored at least every half
hour. If the vessel is listing, the drafts on the low side of
the vessel will be greater than those on the high side. For
this reason, it would be prudent to take the average of the two
sides. Also, the midship draft should be exactly halfway
between the forward and after drafts. If it is more than 6
inches off of this halfway point, it may be an indication that
the hull is being subjected to severe stress. Continue to
monitor the vessel's drafts and list for at least 4 hours after
discontinuing waterflow into the vessel.
Tons per Inch Immersion. Large vessels' Trim and Stability
Booklets generally include a hydrostatic table that describes
the vessels' tons per inch immersion (T.P.I.) factors for
various drafts. These figures represent the weight, in tons,
necessary to sink the vessel one inch. Since this refers to the
vessels' mean sinkage, each inch of sinkage will correspond
directly with each inch of draft midships. This fact should be
used to visually confirm the calculated weight of water being
placed aboard the vessel.
Vessel Listing at Pier. Generally, it will be preferred to have
the vessel list away from the pier or wharf so that list may be
monitored as it progresses. This may require slacking the
mooring lines and adjusting vessel access ramps. The
alternative, to allow the vessel to lean against the structure,
would not only interfere with the list monitoring,, but could
also lead to damage to both the vessel and the adjacent
structure. The vessel's draft will probably increase on the
side of the list. This fact combined with the generally deeper
water away from the pier, also suggests a list away if possible.
Increase of Draft Due to List. Due to the relative flatness of
most vessels' bottoms, the draft will increase as the vessel
lists. An approximate value of the increase is equal to half
the vessel's breadth times the sine of the angle of list. The
formula is as follows:
increase in draft = beam/2 x sine angle of list
Example: Vessel with 92 1 beam listing at angle of 8 degrees
92/2 x sin 8 degrees =
46 x .1392 = 6.41 increase in draft
Original vessel draft = 36.01
Increase due to list = 6.41
Vessel deepest draft = 42.41
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Appendix 25 Page 12
Stability Tactics
Vessel List. Generally, the prime stability concern of an
Incident Commander is to minimize the vessel's list. Control of
the list may be accomplished through a variety of tactics and
will depend on the cause(s) of the list and the particular
circumstances involved.
Causes of List. As discussed, the two basic causes of vessel
list are: (1) a negative GM or (2) an off center position of the
vessel's center of gravity. The list may be the result of either
one of the causes, or both causes in combination. If negative
GM is the causer any transfers of weight within the vessel
should be avoided. It is very possible that a transverse
shifting of weight to correct list due to negative GM will
result in a worse situation.
List Correction. If the list is due solely to the accumulation
of water through firefighting efforts, then the preferred tactic
for corrective action is to remove the water. Corrective
measures are more complex for other list causing factors such as
progressive flooding or large weight shifts.
The following outline is a sequence of actions to help limit and
improve an impaired stability situation, and, the list
accompanying it.
(1) Determine and establish flooding boundaries.
(2) Remove water from partially flooded areas (remove free
surface first).
(3) Remove water from solidly flooded areas.
(4) Transfer weight as appropriate (usually liquids).
(5) Add weight as appropriate (counterflooding).
Establishing Flooding Boundaries. Boundaries should be
established to enclose the area subject to flooding. Vertical
as well as lateral perimeters should be planned. Action should
be swift and efficient.
Free Surface Reduction. There are two basic ways to reduce free
surface: (1) completely fill the flooded compartment or (2)
completely empty the flooded compartment. Filling may be a
faster, more convenient approach but increases the vessel's
weight, draft and possibly increases list. Emptying the
compartment is much more desirable.
�
Appendix 25 Page 13
Stability Tactics (continued)
Weight Removal. Removal of liquid and solid weights from
higher locations should lower the center of gravity,, improve
stability and help improve the list.
Weight Transfer. Weight transfer is normally accomplished with
liquids since the movement of large amounts of solid objects
will probably be impractical. Methods of transfer may include
sluicing, pumping and gravitating.
Weight Addition. Similar to transfer, weight addition of
liquids will usually be most practicable. This will probably be
accomplished through counterflooding the compartment(s) with
seawater.
NEVER counterflogd-if free suj;face is th!g cause gf the list.
The result may be an even greater list to the opposite side.
Always start with the lowest spaces available such as the double
bottoms or low water tanks. The inherent free surface effect and
the additional weight induced by counterflooding or
counterballasting make it a "last resort".
Scuttling or Beaching. If it becomes apparent that the vessel
is going to be lost due to capsizing or from the fire being too
extensive to control, it may be necessary to sink or scuttle the
vessel. Under these two circumstances,, it may be necessary to
sink the vessel at the pier by overall flooding. If time
permits,, and it is preferable, the vessel may be moved to a
suitable beaching ground. There, it may be sunk awash without
damage to the hull from a rocky bottom and where the vessel will
not create an obstruction to normal shipping.
However, the strong currents of the Piscataqua and the harbor's
narrow lift bridges may significantly impact the risk of safely
removing a large vessel from its berth. This decision will rest
primarily with the COTP.
�
Appendix 26
TABLE A - COMMON EQUIVALENTS
FOR PORTSMOUTH HARBOR MFCP
leresh Water:
(S.G. 1.000) 1 Long Ton (2240 lbs.) 35.84 Cu. Ft.
1 Long Ton (2240 lbs.) 6.413 US Barrels
1 Long Ton (2240 lbs.) 268.9 US Gallons
1 US Gallon 8.33 lbs.
1 Cu. Ft. 62.35 lbs.
Salt Water:
(S.G. 1.025) 1 Long Ton (2240 Lbs.) 35.00 Cu. Ft.
1 Long Ton (2240 Lbs.) 6.236 US Barrels
1 Long Ton (2240 Lbs.) 262.6 US Gallons
1 US Gallon 8.53 Lbs.
1 Cu. Ft. 64.00 Lbs.
1 US Gallon = 0.0238 US Barrels
= 0.8327 Imperial Gallons
= 0.1337 Cu. Ft.
= 3.7853 Liters
1 US Barrel 42.00 US Gallons
= 34.973 Imperial Gallons
= 5.6146 Cubic Feet
= 158.98 Liters
1 Cubic Foot = 7.4805 US Gallons
= 0.1781 US Barrels
= 28.316 Liters
1 Long Ton = 2240 Lbs. 1 Short Ton = 2000 Lbs.
= 1.0161 Metric Tons = 0.9072 Metric Tons
= 1.12 Short Tons = 0.8929 Long Tons
NAUTICAL EQUIVALENTS CONVERSION FACTORS
1 Fathom = 6 Feet Cubic Feet x 7.4805 = US Gallons
1 Shot (Shackle) 15 Fathoms Diameter x 3.1416 = Circumference
1 Nautical Mile 6,080 Feet Metric Tons x 0.9842 = Long Tons
1 Statute Mile 5,280 Feet Long Tons x 1.0163 = Metric Tons
1 Knot = 1.152 Miles Per Hour Meters x 0.3048 = Feet
1 Atmosphere = 14.7 Lbs./Sq. In. Feet x 3.2802 = Meters
1 Atmos. Pressure = 34 Feet Water Liters x 3.7853 = US Gallons
PRESSURE
Metric
1 Kilogram/Sq. Centimeter = 14.233 Lbs/Sq. Inch
1 Kilogram/Sq. Meter = 0.2048 Lbs./Sq. Foot
United States
1 Pound/Sq. Inch = 0.0703 Kilogram/Sq. Centimeter.
1 Pound/Sq. Foot = 4.8824 Kilograms/Sq. Meter
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Appendix 26 Page 2
DETERMINING WATER FLOW THROUGH HOLES
(In Gallons per Minute - GPM)
HOLE HEAO OF WATER IN FEET
DIA. IN
INCHES 2 4 6 8 10 1 .12 14 16 18 1 20 24. 1 28 32
1 28 40 49 56 63 69 74 79 84 89 97 105 112
2 ill 157 192 222 248 272 294 314 333 351 384 415 444
3 250 :154 433 500 559 6121 661 707 760 790 866 935 1000
4 445 629 770 889 994 10891 1176 1257 1333 1405 1540 1663 1778
5 695 982 1203 1389 1553 1701 1 1837 1964 2083 2196 2406 2598 2778
6 1000 1414 1732 2000 2-236 24491 2646 2828 30001 3162 3464 3741 4000
7 1361 1925 2357 2722 3043 33331 3601 3849 4083 4303 4714 5092 -5444
8 1777 2514 3078 3555 13974 43541 4702 5027 5332 5620 6157 6650 7109
9 2249 3181 3896 4499 5030 5510 5951 6362 6748 7113 7792 8416 8997
10 2777 3927 4809 5553 62M 6802 7347 7854 8330 8781 9619 10390 11107
11 3360 4752 1 5820 6720 7514 8231 8890 9504 100801 10626 11640 112573 13441 1
12 4000 5655 6926 7997 8941 9795 10579 11310 11996 12645 13852 14961 15995
13 4693 r.Z37 8129 1 9386 10494 11496 12417 13274 14079 14841 16257 117560 18772
14 5443 7697 9426 1 10885 1 144001 15394 16327 17210 18853 20364 21770
15 6246 8834 1082OT12494 13969 153021 165281 17667 18740, 1975.4 21640 23374 24988
16 7106 10051 12310 14214 1-5892T174091 188041 20102 213221 22475 24620 26593 28429
17 8024 11347 13897 16047 117942 196541 212291 22694 24071 25373 27795 30022 32095
18 8996 12722 15582 17992 120116 22035 238021 25445 25988 28448 31164 33660 35985
19 10024 14177 17363 20049 122416 245551 265231 28354 30073 31700 34726 37408 40098
20 11110 15710 19241 22218 124840 127211 1 293927 31421 333261 35129 38483 41566 44436
21 12244 -17316 21208 24488 127379 129992 323961 34632 36732 38719 42416 45814 48977
22 13439 19008 2:3280 26881 30054 1329231 355611 38016 40322 42503 46560 50290 53763
23 14688 20772 25441T29376 32844 1359781 388611 41544 44064 46447 1 50881 54958 58753
24 15995 22622 27707 31993 35769 139183 423231 45245 47989 50585 55414 59853 63986
25 17356 24545 30061 34711 138809 142513 45920 1 49090 52067 54883 60122 64939 69424
26 18770 26546 32513 37542 41974 45980 49664 53093 56313 159359 65025 70235 75085
27 20242 28627 35061 40485 45264 49584 53557 57254 60727 64012 70122 75740 80971
28 21770 30787 37707 43539 48679 533251 57598 61574 65309 68842 75413 81455 87080
29 23353 33026 40449 46706 152220 57203 61787 66053 70059 73849 80898 87380 93414
30 24992 35345 43289 49985 155885 61219 661251 70690 1 74977 79033 86577 93514 99971
31 1 26683 37735 46216 53365 59665 65359 70597 75470 180048 84378 92432 99838 106732
32 28434 1 40212 149250 56868 63581 69649 75231 80424 85302 189916 1 98499 1106391 113738
�
GALLONS PER CUBIC FOOT
STATIC HEAD PRESSURES Clllj'c Gallons Cubic Gallons Cubic Gadlons
Feet Feet Feet
Ifeud Prcss. Ilead Prem. ITe1wl Prevs. 0.1 0.75 so 374.0 8,000 59.844.2
0.2 1.50 (;0 448.8 9.000 67.324.7
in in Us. in in Lbs. in in His. 0.3 2.24 70 523.0 10,000 74,805.2
Fect per Sq. In. Feet per Sq. In. Feet per Sit. In. 0.4 2.90 go 598.4 20,000 149010.4
1. .431 35. 15. 1 DO 69. 20.040 0.5 3.74 00 673.2 30,000 224:4 1 5.6
2. .868 30. 15.624 70. 30-390
1 1.302 37. 16.0158 71. 30.814 0.6 4.49 too 749.0 40,000 299.2-20.8
0.7 6.24 200 1,496.1 50.000 37.1,025.0
4. 1.73G 38. 16.492 72. 31.248 0.8 5.08 300 2,244.2 60,000 448.831.1
5. 2.170 39. 10.026 73. 31.682 0.9 6.73 400 2,992.2 70,000 523,630.3
6. 2.Gat 40. 17.3GO 74. 32.116 1 7.49 SOO 3.740.3 8(),000 598,441.5
7. 3.038 41. 17.704 75. 3 3. 55 0 --
H. 3.472 42. 18.223 7B. 32.11M 2 14.DG 600 4,48R.3 00.0()0 673.240.7
9. 3.!" 43. 18.GG2 77. 33.418 3 22.44 700 5.236.4 1()0,000 748.051.0
10. 4.310 44. 19.006 78. 33.8.52 4 20.92 800 200.000 1,498,103.8
5 37.40 000 6,732.5 300,000 2,244,155.7
H. 4.774 45. 10.530 79. 34.298 6 44.98 1,000 7,480.5 400,0W 2,992,207.6
12. 5.208 46. 19.064 80. 34.720
13. 5.612 47. 20.308 81. 35.151 7 52.3G 2,000 14.061 @O 500.OW 3.740,259.5
IA. 6.076 48. 20.1332 82. 35.538 8 59.R4 3,000 22,441.6 600,000 4.4a8.311.4
15. 6.510 49. 21.266 83. 36.022 9 G7.32 4.000 20,922.1 .700,000 5.2.3G.3G.1.3 0)
16. 6.914 50. 21.700 81. 36. 4 ri G to -74.80 5.0(9) 37.462.6 800,000 5,084,4 15.2 1-4
17. 7.378 51. 22.13.1 85. 3G.8w 20 140.G 6,(X)() 44 A83 1 900,000 6,732,4G7.1 @-j
18. TF12 52. 22.568 80. :17.324 0
30 22-1.4 7,000 52,30.6 1,000,000 7.4110.519.0 :3
19. 8.246 53. 23.002 87. 37.7rog 40 290.2 to
20. R.6m 5 4. 2:1.131; R8. :18.102 1 1 1 i
9.114 515. 23.870 89. 3H.626 -
22. 9.518 56. 24.301 Im. 39.111,10 CUBIC FEET PER GALLON
23. 9.982 57. 2-1.738 91. 39.49-1
24. 10.416 58. 25.172 92. 39.928
25. 10.850 so. 2 5. 606 93. -10.31,12 C11110113 CAAAC Gallons Cubic GvJlons CtIhic >
26. 11.231 cla 26.0 10 91 -10.790 Feet Fee t Feet to
- - 733 681 1.(m,000 (D
27. 11.718 61. 20.47.1 95. .11.1230 .134 1,000 133.W.6
28. 12.152 62. 26.008 DG. 4 1.6G4 2 .267 2,000 2G7.361 2,000,000 267,361.1 :3
29. 12.586 63. 27.3-12 97. .12.008 3 .401 3.000 401.042 3,000.000 4 0 I.M 1.7 tv Qj
30. 13.020 64. 27.77,11 08. 42.532 .1 .535 4.0(X) 534.722 4.000,000 53-1.722.2 P.
31. 13.4.54 65. 28,210 09. 42.066 5 .668 5'(100 G68.403 5.000.000 UG8.402.9 x
32. 13.898 66. 28.0-14 100. 43.400 - --
6 .802 6,00() 802.083 0.000,000 802.083.3
33. 14.322 67. 29.078 7 .03B 7,(X)O 935.7G4 7,(X)O,IXX) 935,7G3.9
34. 14.756 68. 20.512 9 1.069 8,000 1,00.444 8.000,000 1,060.44 4.4
0 1.203 0.000 1,203.125 0,000,(VM 1,2G:1,125.Q 0)
10 1.337 10,000 1,330.800 10,000,000 1,336,905.0 La
(D
�
Appendix 27
0
intentionally Left Blank.
0
0
�
Appendix 28
0
Intentionally Left Blank.
0
0
�
Appendix 29
GLOSSARY
abaft: A term used to describe the relative position of an
object which is farther aft than another.
abeam: At right angles to the keel.
accommodation ladder: A stairway hung alongside the vessel for
boarding and disembarking.
aft: Toward, at or near the stern or rear of a vessel.
aftermost: Nearest the stern.
afterpart: Ship's hull, aft of midships section.
afterpeak: The compartment in the narrow part of the stern, aft
of the last watertight bulkhead.
ahead: The direction forward of the bow.
amidships: At or near the midship section of the ship.
anchor ball: As soon as the anchor is "let go" a black ball 2
feet in diameter is hoisted on the forestay to indicate the
vessel is at anchor.
astern: The direction abaft the stern.
athwart: Same as abeam.
athwartships: Across the ship at right angle to the center line
ballast: Any weight (usually sea water) used to control the
draft of a vessel or to improve the stability of a vessel.
barrel: 42 U.S. gallons; 34.973 Imperial Gallons
beam: The extreme width of the ship.
between (1tween) decks: Cargo space between the lower hold and
main deck, divided by bulkheads which are usually watertight
and fire resistant.
bilge: Generally space in the lower part of the ship's hold
where waste water collects and in which bilge suctions are
placed for pumping out.
bitt: A post, usually in pairs, around which mooring or other
lines may be made fast.
boat deck: A deck on which lifeboats and auxiliary boats are
kept.
bollard: A single or double cast steel post secured to a pier
and used for mooring vessels.
bow: The front end of the vessel.
bow stopper: An appliance on the forepart of the windlass, over
which the anchor cable runs. It is designed to secure the
cable when the windlass brake is slackened off.
bridge, navigating or flying: The uppermost deck from which the
ship is navigated.
bulkhead: A vertical partition corresponding to the wall of a
room extending athwartships or fore and aft with the length
of the ship.
chain locker: A compartment in the forward portion of a ship,
usually near the hawse pipes in which anchor chain is
stowed.
chartroom: A small room adjacent to the pilot house in which
charts and navigating instruments are located.
chock: A heavy saddle of wood or metal through which ropes or
hawsers may be led.
cofferdam: A small space left open between two bulkheads as an
air ece, to protect another bulkhead from heat, fire
sN or collision.
hazar
crew: Vessel personnel. (see diagram page 19)
�
Appendix 29 Page 2
GLOSSARY
davit: A crane arm used in handling small boats, stores, gear,
anchor, etc.
deadweight: The total weight of the vessel including cargo,
fuel, stores, passengers, etc.
fathom: Six linear feet
forecastle (fo'c'sle): The upper deck forward of the foremast
and included in the bow area.
free communication: Term describing a rupture in a vessel's
exterior boundary (usually the hull) which allows water
to flow freely into and out of the damaged compartment.
free surface: The tendency of a liquid which only partially
fills a compartment to remain horizontal.
freeboard: The vertical distance between water line and main
deck.
froth: European word for firefighting foam.
gangway: The opening in the bulwarks of a vessel through which
persons come onboard or disembark.
halogenated extinguishing agents: Halon;made up of carbon and
one or more of the halogen elements: flourine, chlorine,
bromine and iodine
hatchways: openings in the deck giving access to holdst bunker
spaces and storerooms.
hawse hole: A hole in the bow through which a cable or chain
passes.
heel: Term used to describe a vessel's transverse tilt or list.
high-expansion foam: A foam that expands in ratios of over 100:1
when mixed with water; it is designed for fires in confined
spaces.
hold: The cargo space of a ship's hull.
LNG (liquefied natural gas): A natural gas, a hydrocarbon of
fossil fuel, consisting mainly of methane stored as a liquid
and vaporized and burned as gas.
LPG (liquefied petroleum gas): Any one of several petroleum
products such as "butane" or "propane" stored under
pressure as a liquid and vaporized and burned as gas.
monitor(sentinel): a large stream nozzle, normally found on
tankers, fixed in various locations above the main deck.
They are operated by gear-driven wheels or handles and have
a 360 arc. Can deliver a stream of water or foam onto a deck
type fire.
port side: The left side of a ship, looking forward.
scupper: Any opening or tube leading from the waterway through
the ship's side, to carry water from the deck.
shot: Also known as shackle, represents 15 fathoms. Designated
by a mark (usually painted white) close to a shackle to
indicate the length of anchor line let out.
starboard: The right side of a ship, looking forward.
superstructure, ship: That portion of a ship located above
the main deck.
winch: A hoisting or pulling machine fitted with a horizontal
single or double drum.
windlass: An apparatus in which horizontal or vertical drums or
gypsies and wildcats are operated by means of a steam engine
or motor for the purpose of handling heavy anchor chains,
hawsers, etc.
�
Appendix 30
ACRONYMS AND ABBREVIATIONS
for
Portsmouth Harbor Marine Firefighting Contingency Plan
AFFF Aqueous Film Forming Foam
CFR Code of Federal Regulations (US)
CG Coast Guard (US)
CO Commanding Officer
C02 Carbon Dioxide
COTP Captain of the Port (USCG)
CP Command Post
DFSP Defense Fuel Supply Point
DOD Department of Defense (US)
EOC Emergency Operating Center
FAA Federal Aviation Administration
FHA Fire Hazard Assessment
GPM Gallons Per Minute
HAZMAT Hazardous Materials
IC Incident Command, Incident Commander
IFO Incident Field Office (Seabrook)
ISC International Shore Connection
LPG Liquified Petroleum Gas
MARAD Maritime Administration (US)
Medi-Vac Medical Evacuation
U memorandum of Understanding
SC military Sealift Command
MSD Marine Safety Detachment (USCG)
MSO Marine Safety Office (USCG)
NFPA National Fire Protection Association
NHCD New Hampshire Civil Defense
NHPA New Hampshire Port Authority
NHWSPCC New Hampshire Water Supply & Pollution Control Commission
NRC Nuclear Regulatory Commission
NRT National Response Team
NTSB National Transportation Safety Board
0CMI Officer in Charge, Marine Inspection (USCG)
OEM Office of Emergency Management (NH)
0SC On Scene Coordinator (Federal)
PAFB Pease Air Force Base
PHMFCP Portsmouth Harbor Marine Firefighting Contingency Plan
PNSY Portsmouth Naval Shipyard
POP-VOP Port of Portsmouth - Vessel Orientation Program
PSNH Public Service Company of New Hampshire
R & R Roles & Responsibilities
REMIS Regional Emergency Medical Information System
SAR Search and Rescue
SCBA Self-Contained Breathing Apparatus
SOP Standard Operating Procedure
TFRs Temporary Flight Restrictions
W
SCG -United States Coast Guard
OP vessel Orientation Program
�
Appendix 31
BIBLIOGRAPHY
Dutton's Naviciation and Piloting. Dunlap and Shufeldt; U.S.
Naval Institute, Maryland, 1969.
Deepwater Port Inspection Methods and Procedures. Science
Applications, Inc.; U.S. Department of Transportation,
Washington, D. C., 1978.
Deepwater Ports Approach/Exit Hazard and Risk Assesment.
Planning Research Company; Department of Transportation,
Washington D.C., 1979.
Developing Tanker Casualty and Tanker Traffic Databases for
1269-1977. Science Applications, Inc.; Department for
Transportation, Washington, D.C., 1979.
Evaluation of Deepwater Ports Mooring Load Monitoring and
Prediction Systems. Barr, Tebay Loeser; U.S. Department of
Transportation, Washington, D.C., 1978.
Fire-Aboard. Frank Rushbrook; Brown Son & Furguson, Ltd.,
Scotland, 1979.
Fireboats, Ship and Pier Fires. Andrew C. Casper; San Francisco
Fire Department Division of Training, Califoria, 1976.
Fire Fighting Manual For Tank Vessels-CG 329, Department of
Transportation; Washington, D.C. 1974.
Fundamentals of Construction and Stability of Naval Ships
Thomas C. Gilmer; United States Naval Institute, Maryland, 1959.
Guide for Investigating Marine Casualties. Robert H. Nicholas,
Jr.; EXXON Shipping, Company, Texas, 1985.
Hazardous Materials Emergency Planning Guide, National Response
Team; Washington D.C., 1987.
Marine Cargo 0perations. Captain Charles L. Sauerbier; John
Wiley & Sons, New York, 1956.
Marine Fire Prevention, Firefighting and Fire Safety. Maritime
Administration; Washington D.C., U.S. Government Printing
Office.
Marine Safety Manual, Vol.1 and Vol 6. USCG Department of
Transportation, Washington, D.C
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Appendix 31 Page 2
BIBLOGRAPHY
MARITECH Facility Checklist. MARITECH, Newmarket, New
Hampshire, 1988.
MARPOL 73/78-Regulation for the Prevention of Pollution by Oil
(Annex I) . U.S. Coast Guard; Department of Transportion,
Washington D.C., 1978.
Merchant Marine Officers Handbook. Edward A. Turpin and William
A. MacEwen; Cornell Maritime Press, Maryland, 1965.
New Hampshire Port Handbook. Greater Portsmouth Chamber of
Commerce and New Hampshire Port Authority; New,.Hampshire 1987
Perspectives on oil Refineries and Offshore Uploading Facilities
Proceedings. Mary Louise Hunter, Editor; Durham, N.H., 1974
Port Administation and Legislation Handbook. U.A. Tarasca;
United Nations New York, 1969.
Ports of Portland and Searsport, Maine, and Portsmout, New
Hampshire. Port Series No. 1. U.S. Army Corps of Engineers; U.S.
Government Printing-office, Washington, D.C. 1985.
Ports of the World-13th Edition. CIGNA P&C Companies, 1988.
Potentials for a Delaware Deepwater Port. Gladstone, Associates;
Washington D.C., 1970.
Public Involvement in Maritime Facility Development. Committee
on Impact of Maritime Services on Local Populations; Maritime
Transportation Research Board, Washington, D.C., 1979.
Radio Frequency Plan. Department of Transportation, Washington,
D.C., 1980.
Tanker Practice. G.A.B.King; Stanford Maritime Ltd., Great
Britain 1974.
Texas A & M Shipboard Training for Shorebased Firefighters. John
R. Burns Jr.; Texas A & M, Texas, 1988.
The Boatswains Manual. H.F. Chase; Brown Ferguson & Son Ltd.,
Glasgow, 1968.
'Washington Public Ports Association Safety Committee':
Publications, Washington, 1988.
Wharves and Piers. Carleton Greene; McGraw-Hill, New York, 1917.
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