[From the U.S. Government Printing Office, www.gpo.gov]
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Ocean Thermal Energy Conversion
Report to Congress: Fiscal Year 1981
U.S. DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration
Office of Ocean Minerals and Energy
February 1982
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V UNITED STATES DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration
Nrl of Washington, D.C. 20230
THE ADMINISTRATOR
FEB 1 d 1982
Honorable George H. Bush
President of the Senate
Washington, D.C. 20510
Dear Mr. President:
It is my honor to transmit the Ocean Thermal Energy Conversion
Report of the National Oceanic and Atmospheric Administration (NOAA)
to the Congress pursuant to Section 405 of the Ocean Thermal Energy
Conversion Act of 1980 (P.L. 96-320).
This report describes NOAA's progress in implementing the Act,
and our continued development of the OTEC program in a legally
sound and environmentally sensitive manner. Also discussed are
NOAA's involvement in developwent of OTEC technology, and our
outlook for the future of OTEC.
Sincerely,
John Byj&e
Enclosure
U DEPARTMENT OF COMMERCE NOAA
COASTAL SERVICES CENTER
2234 SOUTH H(j6SON AVENUE
CHARLESTON SC 29405-2413
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UNITED STATES DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration
Washington, D.C. 20230
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THE ADMINISTRATOR
Honorable Thomas P. O'Neill, Jr.
Speaker of the House of Representatives
Washington, D.C. 20515
Dear Mr. Speaker:
It is my honor to transmit the Ocean Thermal Energy Conversion
Report of the National Oceanic and Atmospheric Administration (NOAA)
to the Congress pursuant to Section 405 of the Ocean Thermal Energy
Conversion Act of 1980 (P.L. 96-320).
This report describes NOAA's progress in implementing the Act,
and our continued development of the OTEC program in a legally
sound and environmentally sensitive manner. Also discussed are
NOAA's involvement in development of OTEC technology, and our
outlook for the future of OTEC.
Sincerely,
o n V. B e
Enclosure
1 n re'Ly
V.
@ohn B@ re
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'Vil OF CO
"@4, Ocean Thermal Energy
Conversion Report to
S 7, E's- 0 Congress: Fiscal Year 1981
Public Law 96-320
Prepared by:
Office of Ocean Minerals and Energy
2001 Wisconsin Avenue, N.W.
Washington, D.C. 20235
February 1982
U. S. DEPARTMENT OF COMMERCE
Malcolm Baldrige, Secretary
National Oceanic and Atmospheric Administration
John V. Byrne, Administrator
Office of Minerals and Energy
James P. Lawless, Acting Director
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TABLE OF CONTENTS
Chapter I Background ................ I................
The Resource
The National Interest
Nature of the Industry
Chapter 11 - OTEC Technologyo..*..**.**.*.oo.ooo.oo.oo.oooo.so. 7
How OTEC Works
Technology Development
Ocean Engineering Research and Development Program
Chapter III - The Legal Regime.ooo.o .... o ...... o..o ......... o ... 16
The Ocean Thermal Energy Conversion Act of 1980
OTEC Licensing Regulations
The Licensing Process
Chapter IV - Environmental Considerationso..o..ooooo..ooooo.o.- 26
OTEC Environmental Issues Discussion Paper
Environmental Impact Statement (E'IS)
Technical Guidance Document
Environmental Research Plan
Chapter V - International Impact and Future of OTECo..oo .... o. 32
International Trade
International Law
Recommendations for Amending the OTEC Act
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Chapter I
Background
The Resource
In 1881, the French physicist Arsene d'Arsonval published a theoretical article
describing a method by which electricity could be generated from the temperature
differences between warm and cold water. D'Arsonval suggested that his process
could use the temperature differences between water from hot springs and a cold
river, or- between the warm surface waters and cold deep waters of the ocean.
The efficiency of d'Arsonval's process, now called ocean thermal energy
conversion (OTEC), increases greatly with even a small increase in the available
temperature difference. Although the process can work at temperature differences
of less than 20*C (36*F), that temperature difference is usually used as a
minimum standard for the OTEC resource. Deep waters are almost uniformly
cold throughout the world's oceans Thus, the best ocean temperature differences
for OTEC are found near the Equator where the surface waters receive the
greatest amount of heat from the sun.
Temperature differences of at least 20*C at depths of 1000 meters or less
are found in large areas of the ocean between latitudes 30* north and 250
south (Figures 1 and 2). Estimates of the total ocean thermal energy base
range from 100 million to 10 billion megawatts. Current electric consumption
in the U.S. is about 230 thousand megawatts.
An excellent OTEC resource exists in the Western Pacific Ocean, the
Caribbean, the tropical west and southeastern coasts of the Americas, the
Indian Ocean, and near both coasts of Africa. This resource lies within 200
miles of the coasts of more than 90 nations and territories.
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17'
16
17'
15,
100*00, W 80*00, 60*00' 40*00' 20*00' 0100,
1000 m deep
*Contours indicate temperature differential (*C) between surface and 1000 m depth
Figure 1. The OTEC Thermal Resource Area (Atlantic)
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17'
18 . .............
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........ 15o ------
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120*00'E 140'00' 160'00' 180'00' 160'00' 140*00' 120*00' 100 *00,
< 1000 m deep
*Contours indicate temperature differential M) between surface and 1000 m depth
Figure 2. The OTEC Thermal Resource Area (Pacific)
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Potential OTEC areas for the United States include Guam, the Northern
Marianas, other Western Pacific islands,, Hawaii, Puerto Rico, the U.S. Virgin
Islands, and the Gulf of Mexico. The total ocean thermal resource within
200 miles of the United States has been estimated as about equal to total
present U.S. energy usage.
The National Interest
Development of a commercial OTEC industry by the U.S. private sector would
provide the United States with: (a) increased energy self-sufficiency,
(b) major new international trade opportunities, (c) reduced annual balance
of payments deficits, (d) increased investment in manufacturing, construction,
and energy-intensive industries, (e) increased regional employment, and
(f) continued leadership in new ocean technologies.
The potential power generation market in which U.S.-built OTEC plants
could compete has been estimated for approximately seventy of the ninety
countries and territories with access to the OTEC resource. The added electric
power generation needs of these countries, many of which are lesser developed
countries now dependent on imported oil, is large enough to accommodate on
the order of 100 1OMW OTEC plants, 500 40MW plants, 1100 lOOMW plants, and
1100 40OMW plants (a total of more than 570 thousand MW) between the years
1990 and 2010. Even if U.S. companies are able to supply only ten percent
of this potential market, a conservative projection, U.S. exports of OTEC
plants would increase U.S. export trade by about $171 billion in 1980
dollars. This would result in major benefits to U.S. employment, industrial
activity, and balance of payments.
Meeting a goal of 10,000 megawatts of U.S. OTEC capacity in place by
1999 would free Hawaii, Puerto Rico, and other U.S. islands from dependence
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on imported oil for their baseload electricity generation, and would reduce U.S.
needs for imported oil by approximately 360,000 barrels a day. The cumulative
displacement of imported oil by 1999 would amount to a savings of $18 billion.
The combination of savings from imported oil and payments for U.S. OTEC plants
sold to other countries could result in an improvement in U.S. balance of
payments by $5 billion to $7 billion a year during the 1990s.
Because OTEC plants use components and skills from a wide variety of
industries, industrial investment and activity would be increased in diverse
areas of the U.S. economy, including shipyards, heavy construction, and the
manufacturing of concrete, aluminum, turbines, pumps, heat exchangers, and
offshore services. It has been estimated that domestic use of OTEC (without
counting the additional effects of international trade) by 1997 will increase
annual employment by 144,000 workers., personal income by $3.9 billion, retail
sales by $1.2 billion, and will generate tax revenues of dn additional $600
million to the federal government and $180 million to states and localities.
Commercial OTEC operations will involve extensions and new applications
of existing technology. If the OTEC industry emerges strongly in the United
States, it will help extend the nation's ability to develop ocean resources
in general and will help assure a continuing U.S. role as a leader in ocean
engineering and a supplier of high technologies.
Nature of the Industry
A large number of U.S. corporations, varying in size, are involved in
development of OTEC technology as potential owners, operators, builders,
designers, or pa r;s suppliers. Approxim ately eight consortia comprising these
corporations were formed to bid on a Department of Energy procurement for cost-
shared OTEC pilot plants. Another consortium of corporations based in Maryland
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is exploring the Potential for constructing commercial OTEC plants in
Maryland for deployment in the Caribbean. In addition, the U.S. Territory
of Guam signed a contract in 1980 for construction of a land-based commercial
OTEC plant, although work has not yet started. Companies in other countries,
principally Japan, France, and Sweden, are also engaged in OTEC development
with varying degrees of assistance from their governments.
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Chapter 11
OTEC Technology
How OTEC Works
Ocean thermal energy conversion is a process for using solar energy
stored in the warm surface waters of the tropical and subtropical oceans
to perform useful work, either generating electricity for domestic and
industrial consumption or providing energy for industrial refining and
manufacturing. Several different techniques have been considered as the
basis for OTEC power generation. Most experts agree that two of these,
closed cycle and open cycle, are the most economically sound and technically
feasible in the foreseeable future.
The closed cycle technique (Figure 3) employs a working fluid (most
likely ammonia or Freon") enclosed in a system of piping. This fluid is
pumped through a heat exhanger where it is heated by oceanic surface
waters that have been warmed by the sun. This vaporizes the working
fluid causing it to pass through and drive a gas turbine. The turbine
is used to run an electric generator and produce electricity for distri-
bution to industrial and residential users on land or for use directly on
site for energy-intensive processing or manufacturing. After passing
through the turbine, the working fluid, at this point still a gas, is
condensed to a liquid by exposure in another heat exchanger to cold water
drawn from the deep ocean. The working fluid is then revaporized by being
pumped back through the warm water heat exchanger and the cycle is repeated.
This means of power generation does not use any fuel. The system is
based on the repeated vaporization and condensation of the working fluid
made possible by taking advantage of the temperature difference between the
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Electric Power
Warm Output
Water
Intake
High Pressure Low Pressure
NH3 Vapor NH3 Vapor
25*C
Turbine
Generator
20*C 20T 7*C
60 Evaporator Condenser
1O*c 10T
Liquid
Pressurizer ST
23*C High Pressure Low Pressure
NH3 Liquid NH3 Liquid
Warm Cold Cold
Water Water Water
Exhaust Intake Exhaust
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P su
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Figure 3. Schematic Diagram of a Closed-Cycle Power System
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sun-heated surface waters and the perpetually cold deep waters of the
tropical oceans. Even the pumps used to draw in the warm and cold water
do not need conventional fuel. They are powered by a part of the energy
produced by the process itself.
The open cycle system is, in most ways, quite similar to the closed
cycle system. However, in the open cycle system seawater itself is the
working fluid. Warm surface water is pumped into an evaporator in which
the pressure is reduced to the point where the seawater boils. This produces
steam that passes through and drives a low-pressure turbine to generate
electricity, like the closed system. After leaving the turbine,
the steam is cooled and condensed by exposure to cold, deep water in a
heat exchanger. The open cycle technique has the advantage that the
dissolved salts do not accompany the surface water when it forms steam.
Thus, a valuable byproduct, fresh water, results when this steam condenses.
The earliest commercial applications of the OTEC principle are expected
to use the closed cycle process. There is also, however, considerable
interest in open cycle applications because of the additional benefit of
its fresh water production.
Generation of electricity is expected to be the first commercial
application of the OTEC process, with early commercial plants beginning
operation by the mid-1980s. The facilities will probably be moored to
or mounted directly on the ocean floor, or located partly on land with
their intake and discharge pipes extending out into the ocean. The
electricity from moored or bottom-mounted facilities will be brought to
shore by submarine electrical transmission cables. Land-based OTEC
facilities would be in areas where deep water is found very close to
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shore. Such sites exist in Hawaii, Guam, and other U.S. islands. OTEC
facilities are expected to vary in size from about 10 megawatts (a size
suitable for small islands) to about 400 megawatts (about the size of a
conventional plant serving approximately 60,000 households).
Another possibility for implementation of the OTEC process is to use
the electricity directly on the site for production of energy-intensive
products such as hydrogen, ammonia or methanol.. or for energy-intensive
activities, such as aluminum smelting.
Such onsite manufacturing or processing could take place on facilities
situated on or close to shore, or on roving plantships. For the facilities
near shore, the product would be moved ashore by a product pipeline or by
vessels. Self-contained plantships that would use OTEC techniques to
obtain the energy needed to run onboard manufacturing or processing
activities could float unmoored or move slowly under their own power as
they sought out optimum thermal gradient conditions. Vessels would be
used to transport OTEC plantship products to their destinations.
Such plantships are expected to employ closed cycle systems.
Technology Development
The first experimental application of d'Arsonvalls OTEC theory was by
one of his students, Georges Claude, who in 1930 built a plant at Matanzas
Bay, Cuba. The facility, destroyed by a storm shortly after its completion,
actually consumed more electricity than it produced. Because other
sources of energy were still viewed as unlimited and inexpensive, Claude's
accomplishment was regarded at the time as more of a scientific curiosity
than the early development of a major source of renewable energy.
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Renewed interest in OTEC as an energy source came about in the 1970's as
a result of fossil fuel shortages and the increasing uncertainty associated
with foreign sources of supply. In 1972 the National Science Foundation
began work on OTEC technology. As this work continued, it was transferred
to the Energy Research and Development Administration (ERDA) and then to
the Department of Energy. In the United States, particular interest in
OTEC developed in Hawaii, Puerto Rico and Guam due to their almost total
dependence on imported oil for electrical power.
While Department of Energy efforts to develop large-scale commercial
technology continued, private industry and the State of Hawaii undertook
a small-scale demonstration of the at-sea feasibility of the OTEC principle.
This effort was initiated independently of the federal technology develop-
ment program and was financed largely by Hawaii, Lockheed Missiles and
Space Company, and the Dillingham Corporation. Their activities resulted
in deployment and successful operation of Mini-OTEC, a 50-kilowatt gross
output plant, off the Kona Coast of the island of Hawaii in 1979. Mini-
OTEC produced a net power output of more than 10 kilowatts, exceeding
design expectations. The Mini-OTEC project was the world's first actual
demonstration that OTEC technology could produce net electrical energy.
Since late 1976 NOAA has been providing ocean engineering and technical
management assistance to the Department of Energy's OTEC research and de-
velopment program. This work has been conducted by NOAA?s Office of Ocean
Technology and Engineering Services (OTES). The program's major accomplish-
ments during FY 1981 are described in the next section.
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Ocean Engineering Research and Development Program
NOAA's OTES office has supported the Department of Energy in developing
a number of concepts and components for OTEC plants including systems
relating to platforms, cold water pipes, sea water, anchoring, mooring,
and foundations. Most of the effort before 1981 emphasized floating OTEC
systems. However, in the past year interest in shelf-mounted systems has
accelerated. Some of the significant factors associated with shelf-mounted
systems are:
� Installation and protection of bottom-mounted pipes;
� Greater loading forces due to the structuret cold water pipe, and
power plant components;
o Slope stability and associated foundation design and installation;
and
� Influence of near-shore circulation on discharge pipe design and
installation.
.The FY 1981 ocean engineering program managed by NOAA was redirected in
mid-year to emphasize technology related to the pilot plant or "proof of
concept experiment" conceptual designs while maintaining a well balanced
approach toward satisfying the technical problems of floating systems and
the newly introduced-shelf-mounted systems.
Plantship Vessels and Offshore Platform Systems
Prior to FY 1981 OTEC engineering was concentrated on floating vessel
concepts--either moored barges or spars with an electrical cable leading
to shore, or mobile, "grazing" vessels producing energy-intensive products
such as ammonia. Studies of alternative concepts using fixed-tower
technol-ogy-.developed by the offshore oil industry were begun in late FY
1980 and are.continuing..
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NOAA ocean engineering findings in. 1981 concerned with plantship
and offshore platform technology are described below:
6 Model basin tests and other studies have shown that seakeeping
characteristics of OTEC barge-type vessels can be significantly
improved using standard naval architecture techniques.
o Marine concrete is a practical material for plantships.
o Attachment of the cold water pipe directly to a plantship compli-
cates the vessel's motion in a seaway and makes survival difficult
during severe weather. A moored pipe that decouples the motion
of the vessel and the cold water pipe and also permits detachment
of the plantship.from the pipe during.severe storms was found to
be feasible.
0 Design, installation, deployment, inspection, maintenance, and
repair of shelf-mounted platforms and cold water pipes have been
analyzed. Conceptual designs are being developed to identify
tower and platform arrangements for model basin tests.
o Preliminary classification-and technical r.eq.uirements- for the
inspection, maintenance, and repair of plantships, cold water
pipes, and mooring systems were developed. These studies showed
4
that it is possible to optimize both initial and long-term costs,
and thus minimize lost income from operational downtime, without
compromising safetyO
o Baseline designs for a 40 MW OTEC-pilot plant were found,to be
feasible and in general agreement with ship class:ification society
regulations.
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Cold Water Pipe and Seawater Systems
The cold water pipe draws cold water from a depth of about 1,000 meters
(3,300 feet) to the power plant condenser. A suspended cold water pipe
for a 40 MW floating plantship would be about 1000 meters long and 9
meters (30 feet) in diameter. The cold water pipe for a shelf-mounted
platform would lie on the.sloped ocean bottom. During FY 1981,
several important tests on cold water pipes were conducted. They included:
� A 1/50 scale test to collect valuable design data on the stress
associated with towing and deploying cold water pipes during
installation. Results indicate that a system in which the pipe
is towed. to the plant location and then "flipped" into its vertical
position is feasible.
� A 1/110 scale mooring test of a platform and cold water pipe
showed that the pipe was sufficiently strong during severe weather.
Fiberglass reinforced plastic, cable-reinforced elastomer, and
articulated steel cold water pipes were tested.
� Two analytic models of the dynamic and structural behavior of the
cold water pipe, platform, and moorings were developed. These
computer programs will be used in subsequent design and development
efforts.
� A 1/3 scale cold water pipe test program was started in FY 1981. This
program will produce information on the performance of fiberglass-
reinforced plastic pipes; establish design and construction procedures;
quantify dynamic response during deployment and exposure to environ-
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mental loads in both normal and severe sea conditions; and help
validate the analytic models.
0 An analytical computer program that integrates dynamic and thermal-
hydraulic responses of the flow of water in piping systems was
developed and evaluated.
Mooring and Foundation Systems
The mooring system comprises the wires, chains, lines, anchors,
hardware, and deck handling equipment. Foundations are the footings for
tower structures,, slope-mounted pipes, and anchor pilings for mooring
systems.
A study to evaluate the performance of various anchoring systems on a
sloping sea floor showed that gravity and embedment anchors are ineffective
on slopes over 15 degrees. The study also showed that at a Hawaiian site
the best anchoring systems would use drilled and grouted anchor piles. At
a Puerto Rico site, gravity embedment anchors could be used in deep water
where heavy sediment exists. However, drilling and grouting of anchor
piles would be required near shore where the bottom is mostly rock.
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Chapter III
The Legal.Regime
The Ocean Thermal Energy Conversion Act of 1980
The successful, Mini-OTEC demonstration'off Hawaii in 1979 captured the
imagination of executives at industrial concerns and of lawmakers, thus setting
the stage for legislation to encourage development of a commercial OTEC industry.
Private industry and utility companies believed some kind of federal law was
necessary to remove legal and regulatory barriers that would otherwise prevent
U.S. companies from building and operating commercial OTEC plants. These barriers
consisted largely of legal and regulatory uncertainties, which, if left
unresolved, could have deterred potential investors. These uncertainties
consisted primarily of:
o Lack of any clear statement that OTEC activities are legal under
national or international law;
o., Lack of any law or regulation assuring continued access to the
ocean thermal resource being used by a particular OTEC plant;
� Lack of clarity as to whether admiralty, land-based, or some other
body of residual and common law would apply to activities on OTEC
platforms located on the high seas beyond the normal coverage of
national laws;
o Uncertainty about whether OTEC operat-ions.might be declared illegal
or partially restricted in the future; and
� Lack of clarity as to which federal agency regulations might apply to
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OTEC operations in U.S. waters, and how those existing regulations
would be interpreted when applied to OTEC operations.
The overall effect of those uncertainties, if not dealt with by clear
legislation, would have been to make finanacing and insuring of commercial
OTEC operations essentially impossible.
The first formal response to these uncertainties was the introduction of
H.R. 6154, the Ocean Thermal Energy Conversion Act of 1980, on December 14,
1979. A similar Senate bill, S. 2492, was introduced on March 27, 1980.
Committee action on this legislation began early in the second session of
the 96th Congress. Extensive hearings on both bills were held, with thirty-six
witnesses appearing during three days of hearings on H.R. 6154 during January
and February 1980 before the Oceanography Subcommittee of the House Committee
on Merchant Marine and Fisheries. Hearings on S. 2492 were held in Honolulu
and Washington, D.C., in April and May 1980 by the Senate Committee on
Commerce, Science and Transportation. During these hearings, witnesses
representing private industry, utility companies, state governments, and
private citizens reiterated the need for federal legislation to clear the
way for commercial OTEC development.
S. 2492 was reported by the Senate Commerce Committee an May 15 and
passed the Senate on July 2, 1980. The Merchant Marine and Fisheries
Committee reported H. R. 6154 on May 16. There were only minor technical
differences between the two bills. As a result, after passing H.R. 6154 on
July 21, the House of Representatives vacated passage of that bill and passed
S. 2492. On August 3, 1980, the Ocean Thermal Energy Conversion Act of 1980
(Public Law 96-320) was signed into law.
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The principal provisions of the Act were:
� Establishment of United States jurisdiction over (a) OTEC
facilities located in the U.S. territorial sea or connected to
the United States by pipeline,or cable, (b) OTEC plantships
owned or operated by U.S. citizens, and (c) OTEC facilities or
plantships documented under U.S. law;
� Specification of which federal and state laws are to apply to
OTEC facilities and plantships under U.S. jurisdiction; and
� Creation of a fair and expeditious licensing system to assure
compliance by U.S. OTEC facilities and plantships with both U.S.
and international law.
The license processing system in the Act is designed to yield a single
federal decision representing all involved departments and agencies without
the protracted delays that can occur in other governmental licensing processes.
The overall licensing system is administered by the National Oceanic and
Atmospheric Administration. The Act required promulgation of final licensing
regulations by August 3, 1981. The Act also contains several provisions related
to financing of OTEC plants, to be implemented by. the Transportation Department's
Maritime Administration.
OTEC Licensing Regulations
NOAA immediately took action to respond to the Act's mandate for OTEC
licensing regulations. Proposed regulations were issued on March 30, 1981,
just six months after the Act became law. Final regulations governing the
licensing process were published in the Federal Register on July 31, 1981.
These regulations carry out the purposes of the statute by eliminating legal
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uncertainties and providing for a coordinated, efficient licensing process.
They are flexible enough to allow the experimentation and.innovation required
for OTEC to advance from the developmental stages into a commercial reality.
The regulations are designed to be readily usable by those seeking a
federal OTEC l'icense and include a voluntary review process to ensure more
rapid processing of an application than is required by the Act. The regulations
described:
1. Who is required to apply for an OTEC license and the procedures for
submitting an application.
2. Procedures for conducting optional pre-application consultations with NOAA
prior to actual submission of an application.
3. The financial, technical and environmental information that must be
submitted with an application to enable NOAA and other federal
agencies to make licensing decisions.
4. An explanation of the Act's requirements for processing an OTEC
license application and of special processing procedures available
at the applicant's request.
5. The criteria for approval or denial of an application, and the terms
and conditions that may be included in a license.
6. Procedures for formal hearings on a license application, should they.
become necessary.
7. The post-licensing enforcement procedures.
There was general agreement during development of the regulations
that site evaluation and preconstruction testing regulations were unnecessary
at present. Thus, the final regulations did not address these matters. At
was also apparent that current'scientific understanding and projected develop-
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ment schedules did not justify immediate establishment of upper limits on the
number or total capacity of OTEC facilities and plantships to be licensed.
Accordingly, that issue was reserved for future rulemaking, should establish-
ment of such limits become necessary.
As part of the process of developing the licensing regulations, NOAA
prepared a regulatory impact analysis. The possible approaches to a licensing
regime fell into three categories: detailed, moderate, and minimum regulation
of OTEC activities.
In considering which of these alternatives would be most appropriate,
NOAA was guided by the principle that maximum flexibility should be allowed
for development of a domestic OTEC industry while providing a degree of certainty
sufficient to encourage private financing of commercial OTEC projects. The
choices involved the following considerations:
1. Detailed regulation of OTEC activities
This general approach would involve regulations containing detailed
provisions specifying the design of OTEC plant components and requiring use
of specific operating procedures. The information required to make application
for a license would of necessity be voluminous, and detailed design of the
plant would have to be completed prior to making application.
Because adoption of this alternative would yield a low probability of
obtaining the benefits to society that would accrue from OTEC development
and would impose high costs on both potential OTEC owners and on the government,
it was not seriously considered.
2. Moderate regulation of OTEC activities
Under the moderate approach, regulations would not contain detailed provisions
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specifying design of OTEC plant components or plant operating procedures.
The regulations would, however, contain detailed guidelines and performance
standards applicable to all OTEC facilities and plantships in order to ensure
adherence to overall regulatory goals. A license applicant would be required
to prove that the intended plant design and approach met each of the detailed
guidelines and performance standards included in the regulations.
The use of specific guidelines and performance standards is a common
approach to regulation of relatively mature and.stable industries where many
facilities al,ready exist and the nature of the technology used and its impacts
are well known'. However, when applied to a nascent industry such as OTEC,
this approach would limit the design and technical flexibility needed to
evolve systems that best meet the combined goals of sound engineering and
economics and of protection of societal values. For this reason, this
alternative was not selected for the licensing regime.
3. Minimum regulation of OTEC activities
Under the minimum regulation alternative, NOAA would include in the
licensing regulations only the general guidelines and performance standards
specified in the Acto Detailed guidelines and specifications would not
be provided in advance in the regulations. They would be introduced if
deemed necessary on a site-specific, case-by-case basis to prevent significant
adverse effects on the environment or to prevent other results contrary to
law. The information submitted to NOAA with an application would include
details of the proposed site, descriptions of the operating features of the
plant, and assessments of the potential impacts of construction and operation.
Thus, application for a license could be made before detailed design of the
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OTEC plant was completed. NOAA would examine the applicant's assessments of
the nature and potential magnitude of the impacts from construction and operation
of the proposed project, and analyze in detail only those impacts that appeared
to pose significant problems.
Under this approach, the incremental administrative costs to NOAA
to process each application would be relatively modest, on the order of
two to three person-years and $250,000. Maximum design flexibility would be
afforded OTEC project sponsors, consistent with reasonable protection of
societal values.
Most persons who commented on the proposed OTEC licensing regulations
favored the minimum regulation alternative. NOAA's detailed analysis of
potential regulatory impacts of various licensing regimes, prepared as part
of the regulation development process, confirmed that the minimum regulation
approach was the most cost-effective one that would satisfy the stated goals
of the Act. Accordingly, it was adopted as the basis for the final licensing
regulations issued by NOAA.
The Licensing Process
NOAA?s regulations establish the procedures for applying for and processing
OTEC licenses. In addition,, they make specific provision for consultations
between NOAA and potential applicants in advance of actual submission. This
arrangement fosters early and productive dialogue between NOAA and potential
OTEC license applicants and can save potential applicants from wasting effort
gathering information that NOAA will not need.
Reflecting requirements of the OTEC Act itself, NOAA's licensing
regulations provide that the application to NOAA constitutes application for
all necessary federal agency actions, other than Coast Guard inspections and
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approvals. Provisions are made in the regulations for insuring that all
involved federal and state agencies receive copies of an application in
timely fashion. Provision is also made for NOAA to prepare an environmental
impact statement on the application, to cover all federal agency actions
relating to OTEC project. Extensive provisions are made in the regulations
for public involvement in the application review process.
The regulations impose rigid time constraints on the OTEC license
application review process, as required by the Act itself. An initial
determination as to the completeness of the application must be made within
21 days after its receipt. Review of the application for anti-trust impli-
cations must be completed by the Attorney General within 90'days after
receipt of a copy of the application by the Justice Department. NOAA must
issue a draft environmental impact statement not later than 180 days after
giving notice of receipt of a complete application. Public hearings on the
application must be completed not later than 240 days after notice of its
receipt in complete form.
Other involved federal agencies must complete reviews within their areas
of responsibilities and make their recommendations to NOAA regarding approval
or denial not later than 45 days after completion of public hearings.
Finally, NOAA must make a final decision on approval or denial of the
license application not later than 90 days after completion of public hearings.
Thus, under the deadlines imposed by the Act and NOAA's implementing regulations,
the entire license application review process will be completed in slightly
less than one year after receipt of an application.
Early in the process of developing regulations to govern OTEC licensing,
NOAA recognized the need to provide applicants with the option of a more
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coordinated, efficient review process than the minimum required by the Act.
A model exists for such a coordinated approach to multiple agency licensing
and permitting decisions on a single project in the form of the Joint Review
Process developed by the Colorado's Department of Natural, Resources for use
in federal and state permitting of major energy and natural resource develop-
ment projects. Drawing heavily on the concepts used in the Colorado process,
NOAA developed the Consolidated Application Review (CAR) process provided
for in the licensing regulations. The process involves early designation
of federal, state, and local government members to,serve,,wi-th the applicant,
on a CAR team for the application.,- NOAA will chair the CAR team, and its
primary responsibility will*be to coordinate the scheduli.ng of each government
agency's review process for the application, including necessary hearings
and decision points, so that a prompt and unified decision can be reached on,
the application.
The CAR process is intended to assure early and continuous coordination
among all involved federal, state and local agencies and to provide a focal
point for applicants in their dealings with all involved agencies. Parti-
cipation in the CAR process is voluntary on the part of an applicant and the
agencies other than NOAA, because the Act does not explicitly require use of
this degree of integration in th-e review process.
In developing the CAR process, NOAA has had extensive discussions with
the other pertinent federal agencies, and all have made a commitment in
principle to use the CAR process if requested to by an applicant. NOAA is
now identifying information requirements and decision schedules related to
811 other government authorizations and permits necessary for location,
construction, and operation of OTEC facilities and plantships. If an applicant
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chooses not to use the CAR process, NOAA will still provide the information
on other agency procedures and information requirements to assist the applicant
An direct interact-ions with those agencies. In any case, the extensive
ongoing consultations that NOAA is conducting with the U.S. Army Corps of
Engineers, Coast Guard, Department,of the Interior, Environmental Protection
Agency, and Department of Justice, among others, will create a sensitivity
and commitment among the involved agencies that*will benefit an OTEC license
applicant whether or not the CAR process is used.
The licensing process developed by NOAA and specified in the final
regulations is intended to provide the orderly, timely, and efficient review
of OTEC proposals envisioned by the drafters of the Act. As the licensing
process is implemented, NOAA will monitor it carefully, and make adjustments
where necessary to assure that it in fact contributes to early development
of a U.S. commercial OTEC industry.
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Chapter IV
Environmental Considerations
OTEC Environmental Issues Discussion Paper
To provide for an early and open process to determine the scope of the
environmental issues associated with development of OTEC licensing regulations,
NOAA published a paper addressing environmental issues within a month of the
signing of the OTEC Act. The discussion paper described the Act and OTEC
in general, gave several OTEC commercial development scenarios, and highlighted
environmental issues associated with OTEC development.
The discussion paper was not a draft environmental impact statement, but
rather a brief introduction to OTEC so that interested parties could better
work with NOAA in identifying the environmental issues and the more significant
questions to be answered in the process of formulating regulations to implement
the OTEC Act.
Environmental Impact Statement (EIS)
NOAA prepared an Environmental Impact Statement analyzing the environ-
mental consequences of OTEC development up to the year 2000 under the
legal regime established by the OTEC Act. The EIS also evaluated regulatory
alternatives for mitigating adverse environmental impacts associated with
construction, deployment, and operation of commercial OTEC plants.
The EIS concluded that although commercial OTEC development might have
some affect on the atmosphere, the terrestrial environmental, the marine
ecosystem, and various human activities in the vicinity of deployment and
operation sites, the net environmental impact from OTEC development would
be minimal compared to the impacts from fossil fuel and nuclear power
production. However, the uncertainties associated with the redistribution
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of intake waters must be better assessed. The EIS also concluded that
minimal regulation of OTEC activities, an approach that depends primarily
upon existing regulatory provisions, is the preferred strategy for licensing
OTEC plants.
Potential effects from commercial OTEC plants, although less than those
from equivalent fossil fuel plants, include climatic disturbances resulting
from releasing carbon dioxide and cooling the sea surface. Significant
atmospheric effects are not expected as a result of single-plant deployments.
However, large scale deployment could result in carbon dioxide releases
and sea-surface cooling of a magnitude that may affect climate. Local
air quality is not expected to be significantly affected by emissions
from industrial OTEC plants producing energy-intensive products such as
aluminum or ammonia. Building land-based OTEC plants, like any heavy
industrial construction, may destroy terrestrial habitats and increase
noise levels and air pollution locally.
The majority of environmental effects caused by OTEC development center
on the marine ecosystem, since it is the source of evaporating and condensing
waters and the receiver of effluent waters used by the plant. The effects
can be put in three categories: (1) major (those that might cause significant
environmental impacts), (2) minor (those causing insignificant environmental
disturbances), and (3) potential (those occurring only during accidents).
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Source Potential Major Effect
� Platform presence o Biota attraction
� Withdrawal of surface o Organism entrainment and
and deep ocean waters impingement
� Discharge of waters o Nutrient redistributi.on
resulting in increased
productivity
� Release of biocide o Toxic to marine life
Source Potential Minor Effect
� Release of protective o Toxicity and bloaccumulation
hull-coating of hull-coating constituents
� Power cycle erosion and o Toxicity and bioaccumulation
corrosion of released metals
� Installation of cold water o Habitat destruction and
pipe and transmission cable turbidity during dredging
� Production of low-frequency 0 Interference with marine life
sound
� Discharge of surfactants o Toxic to marine life
� Operation of open-cycle plant o Alteration of oxygen and
salt concentrations in
downstream waters
Source Potential effects from Accidents
� Release of working fluid o Toxic to marine life
from spills and leaks
� Releases of oil o Toxic to marine life
Nekton populations (i.e., free-swimming organisms) will increase near the
plant because they are attracted to the structure itself and its lights.
Populations may decrease in downstream areas, as a result of entrainment of
eggs and larvae and impingement of juveniles and adults. Plankton populations
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(i.e., floating organisms) may also be reduced immediately downstream of
OTEC plants, because of entrainment and release of biocides. However,
these effects may be offset by the redistribution of nutrient-rich deep
water into the photic zone., stimulating plankton productivity and ultimately
increasing plankton populations and the numbers of fish that feed on the
plankton. Benthic community effects will center primarily on their planktonic
larval stages, possibly reducing recruitment stocks and adult benthic
populations downstream of the plant. The cumulative effect of OTEC development
near islands may significantly affect threatened and endangered species at
some sites However, this effect is not expected to be a problem for
commercial OTEC plant.operation in open ocean regions.
Thp magnitude of potentially adverse impacts can be reduced by changing
the plant's location'or its equipment. Siting OTEC plants away from commercially
important, ecologically sensitive, and biologically productive areas will reduce
the effects of biota attraction, organism impingement and entrainment, and
biocide release. Organism attraction to OTEC plants can be minimized by
reducing lights and noise on the platform. Organism impingement and
entrainment may be reduced by locating intake structures where the least
number of organisms are'found or by inducing horizontal intake flows which
fish tend to avoid. Adverse environmental effects resulting from biocide
release, sea-surface temperature alterations, and nutrient redistribution
may be reduced by discharging the effluent waters below about 250 feet.
Employing alternate biocide concentrations,- alternate biofbuling control
measures,,and.release sch(E@dules will minimize the effects of biocide
release.,.
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Technical Guidance Document
NOAA published a Technical Guidance Document in September 1981 to
help industry meet the environmental requirements of the regulations for
licensing commercial OTEC plants. To a large degree,. these environmental
requirements are based on those developed by the Department of Energy
(DOE) for OTEC pilot plant proposals. In spite Pf the similarities,
however, NOAA believed that there may be other valid approaches to meeting
the requirements. Accordingly, NOAA recommended that potential applicants
avail themselves of the pre-application consultations provided for in
the regulations so that the specifics of the environmental assessment
needs can be discussed and resolved for site-specific situations.
As NOAA gains experience with OTEC operations, and as information
is developed through environmental research, NOAA will provide additional
guidance to license applicants.
Environmental Research Plan
Section 107 of the OTEC Act requires NOAA to initiate a program to
assess:
(1) any short-term and long-term effects on the environment which may
occur as a result of the operation of ocean thermal energy conversion
facilities and plantships;
(2) the nature and magnitude of any oceanographic, atmospheric, weather,
climatic, or biological changes in the environment which may occur as
a result of deployment and operation of large numbers of ocean thermal
energy conversion facilities and plantships;
(3) the nature and magnitude of any oceanographic, biological or other
changes in the environment which may occur as a result of the oper-
ation of electric transmission cables and equipment in the water
column or on or in the seabed, including the hazards of accidentally
severed transmission cables; and
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(4) whether the magnitude of one or more of the cumulative environ-
mental effects of deployment and operation of large numbers of ocean
thermal energy conversion facilities and plantships requires that an
upper limit be placed on the number or total capacity of such facilit-
ies or plantships to be licensed under this Act for simultaneous oper-
ation, either overall or within specific geographic areas.
Furthermore, a plan must be prepared and submitted to Congress for carrying
out this program.
NOAA and DOE both have mandates to assure the environmental compati-
bility of OTEC technologies. However, NOAA's responsibilities focus on
licensing and facilitating commercial development of OTEC, whereas DOE's
responsibilities focus on development of the technology. Although these
responsibilities are clearly distinguishable from each other, the environ-
mental research that is required under each is not so clearly differentiated.
Thus the plan by NOAA for OTEC-related environmental research is designed
to complement ongoing and planned DOE studies so that the two programs
together will meet their respective needs most cost-effectively. The
plan stresses the following research areas critical to NOAA's licensing
decisions:
o Interference of one OTEC plant with another,
o Effects of entrainment and impingement,
o Long-term cumulative and interactive effects (including biocide effects),
and
0 Monitoring environmental effects.
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Chapter V
International Impact and Future of OTEC
International Trade
While OTEC can play a major role in the generation of electricity
and the manufacture of energy-intensive products in the United States,
OTEC's potential for generating new international trade is even greater.
Over 90 countries and territories are located within the OTEC resource
area, that is, within 200 miles of waters with a 20*C. temperature difference.
Many of them have little or no domestic oil, coal, or hydropower for
baseload electricity generation, and as a result depend on imported oil. The
total electricity need of a large number of these countries and territories
is too small for use of commercial-sized nuclear plants. For those countries,
OTEC is the technology most likely to be chosen for generating baseload
electricity to meet future increases in electrical demand and, in some cases,
to replace existing, costly plants.
Development of an active OTEC plant export business by U.S. private
industry would serve to open up substantial international trade relation-
ships with countries that are not now major U.S. trading partners.
Initiation of trade relationships through OTEC could broaden accessability
of foreign markets for U.S. manufactured and consumer goods, and strengthen
economic and political relationships with countries that are sources of
strategic and non-strategic raw materials.
Unlike the United States, foreign countries have concentrated their
efforts in the export market because they have relatively few domestic
sites for OTEC plants. However, U.S. industry still has a technological
lead on the foreign competition. Once U.S. companies have built initial
commercial OTEC plants, they are expected to begin more aggressive pursuit
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of exp ort markets.
The major competition for OTEC export markets is from Japan, Sweden,
and France. In 1979 the Pacific island republic of Nauru signed a contract
with Japanese interests for OTEC development. A demonstration test of
a 100 kilowatt net land-based OTEC plant on Nauru began in October 1981. The
pilot plant was built by the Tokyo Electric Power Company. Most of the
equipment was supplied by Toshiba. The plan is to operate the pilot
plant in a testing mode for one year to gain information on technical
problems, and then to build a small commercial plant to supply baseload
power for the island. The pilot plant is subsidized by the Japanese
government.
A Swedish OTEC group, which consists, of several Swedish companies with
government support, is performing site evaluations in Jamaica prior to
construction of an OTEC pilot plant. The reported plans are for a pilot
plant approximately 1 megawatt in size, followed by a commercial plant.
France was involved in the post-World War 11 period in OTEC work
in the Ivory Coast and Guadeloupe, although both projects were apparently
dropped before they produced commercial power. More recently, a French
engineering company is performing OTEC studies for the Government of the
Ivory Coast. The Centre National pour I'Exploitation des Oceans (CNEXO),
which is owned by the French government, is performing site studies in
Tahiti that are expected to lead to construction of a small, land-based
commercial OTEC plant.
International Law
The Ocean Thermal Energy Conversion Act of 1980 is firmly grounded on
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concepts of national jurisdiction that are widely recognized in international
law, and the Act requires U.S. OTEC licensees to abide by the provisions of
international treaties to which the United States is a party. The draft
treaty currently under consideration at the Third United Nations Conference
on the Law of the Sea is not expected to raise any new barriers to OTEC
development by U.S. corporations. In fact, the draft text confirms each
coastal nation's jurisdiction over OTEC activities within 200 miles of
its coastline. Consequently, the domestic and international legal regimes
under which OTEC development can take place in a secure investment climate
already exist, and international law does not pose a barrier to the OTEC
industry.
The only gap in international legal arrangements that might cause
difficulty for OTEC development is the lack of stated rules to prevent
one moving OTEC plantship from interfering with the thermal resource
being used by another moving plantship. The U.S. law contains provisions
for handling this situation between plantships licensed by the United
States, so the potential conflict could arise only between an OTEC plantship
licensed by the United States and a plantshi.p licensed by another country.
At the present time, the United States is the only nation considering
development of OTEC plantships. Therefore, this problem is not likely
to arise in practice in the next ten to fifteen years. If another country
does begin development of OTEC plantships, bilateral arrangements to
prevent this problem could be initiated at that time.
Recommendations for Amending the OTEC Act
At the current time no amendments to the Act are recommended. NOAA is
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analyzing several areas in which technical amendments would clarify the
original intent of the Act. The most significant of these relates to the
specific requirements for issuance of OTEC licenses for facilities that
are located partly on land and partly in ocean waters. This type of
facility is often called a "land-based" OTEC facility.
NOAA believes it is clear that the OTEC Act requires a license from
NOAA for ownership, construction, or operation of a land-based OTEC
facility whose input or discharge pipes are located in the territorial
sea of the United States. Section 101(c)(7) of the Act prevents NOAA
from issuing an OTEC license if the OTEC facility or plantship will not
be documented under the laws of the United States. This provides protection
against operation of OTEC facilities and plantships under foreign flags
of convenience. However, the specific wording of section 101(c)(7)
causes a problem that may, if not corrected, prevent issuance of licenses
for land-based OTEC facilities because of the difficulty of documenting
these facilities under existing U.S. vessel documentation laws administered
by the Coast Guard. This problem was discussed in the preamble to NOAA1.s
publication of final rules for Licensing Ocean Thermal Energy Conversion
Facilities and Plantships (46 Federal Register 39388, July 31, 1981).
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