Energy from the ocean

doi:10.1098/rsta.1982.0119

Cited by 13 publications

(2 citation statements)

References 14 publications

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“…However, a detailed and realistic economic analysis is to be performed to select finally an optimal medium for the system of this type. [5,6,10,16,17,19] ASHARE medium number …”

Section: Results Of Calculations For Arctic Otec Cycle and Their Evalmentioning

confidence: 99%

Design analysis of ORC micro-turbines making use of thermal energy of oceans

Piwowarski¹

2013

Polish Maritime Research

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“…However, a detailed and realistic economic analysis is to be performed to select finally an optimal medium for the system of this type. [5,6,10,16,17,19] ASHARE medium number …”

Section: Results Of Calculations For Arctic Otec Cycle and Their Evalmentioning

confidence: 99%

Design analysis of ORC micro-turbines making use of thermal energy of oceans

Piwowarski¹

2013

Polish Maritime Research

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“…Energies 2024, 17, 2181 2 of 21 -OTEC-1 MW (1980) was deployed on a US Navy tanker anchored off Kawaihae, on the coast of Kona, Hawaii. It was used to test heat exchangers and other components of a closed cycle plant, and for research into environmental effects on the ocean [6]. -OTEC-CC 100 kW (1981), the first land-based system, was installed in the Republic of Nauru in Micronesia, by Toshiba, TEPCO, and Tokyo Electric Power Services [7].…”

Section: Introductionmentioning

confidence: 99%

Choosing the Most Suitable Working Fluid for a CTEC

Achkienasi,

Silva,

Mendoza

et al. 2024

Energies

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This study aims to explore additional fluids beneficial for coastal thermal energy converter (CTEC) operation. Ammonia’s thermodynamic properties, characterized by higher condensation temperatures and pressures, demand significantly elevated operating pressures, resulting in a substantial energy load for efficient operation. Thus, exploring alternatives such as R134a becomes crucial, particularly considering its potential as a better working fluid for power generation in a Rankine cycle. The research methodology involves employing computational fluid dynamics (CFD) simulations alongside experimental investigations to examine the performance of an axial turbine concept under different working fluids. The results obtained indicate that R134a is the most appropriate working fluid for an axial turbine within a CTEC, outperforming ammonia, thereby implying significantly better operational efficiency.

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Ocean Thermal Energy Conversion: Heat Exchanger Evaluation and Selection

Laboy¹,

Ruiz

Marti³

2010

Ceramic Transactions Series

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This study summarizes available data on heat exchanger requirements for closed-cycle OTEC power systems obtained during over thirty years of R&D work and technology demonstration programs, and presents how these requirements can be met using commercially-available heat exchangers used today in other applications by a variety of industries. The study focuses on the following design criteria: configuration (shell-and-tube, compact-type, and others), process performance, surface enhancement, corrosion resistance, biofouling control, manufacturability, ease of operation and maintenance, and over-all cost-effectiveness. Selection of the appropriate working fluid will also be discussed. Data evaluated include previously developed power system designs such as those completed during the I970's and 1980's by GE, JHU/APL, ANL, and engineering reports from OTEC technology demonstration programs such as the Nauru, Mini-OTEC and OTEC-1 test projects. A critical performance assessment is made between the use of stainless-steel plate heat exchangers and aluminum-brazed plate-fin heat exchangers in the context of present day technology. Alternatives to mitigate and control the adverse effects of biofouling are discussed. INTRODUCTIONOcean thermal energy conversion (OTEC) is a base-load renewable energy source that uses the temperature difference between the warm surface ocean water and the cold deep ocean water to generate electricity. OTEC is applicable to most parts of the world's deep oceans between 20° North and 20° South latitude including the Caribbean and Gulf of Mexico, the Pacific, Atlantic and Indian Oceans, and the Arabian Sea, where the temperature difference between the warm surface ocean water and the cold deep ocean water is equal or greater than 20 °C. In essence, OTEC recovers part of the solar energy continuously absorbed by the ocean and converts it into electric power. OTEC does not utilize any fuel. The electricity generated has a fixed cost, thus, it is not susceptible to the volatility resulting from world market fluctuations that affects other energy sources such as petroleum, coal and natural gas. Moreover, environmental impacts are less than those of conventional sources of energy since no products of combustion and no solid or toxic wastes are generated during the power production process. In addition, effluents are essentially similar to receiving waters. All of these aspects have caused a revival of interest in OTEC*". An OTEC power system consists of a heat engine cycle that converts thermal energy into mechanical work through the temperature difference between a "heat source" and a "heat sink". Although this temperature difference is relatively small compared to a steam engine, the principle is the same (Rankine thermodynamic cycle). OTEC technology is divided into three major categories: closed, open and hybrid cycles. In the closed-cycle, the temperature difference is used to vaporize (and

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Energy from the ocean

Cited by 13 publications

References 14 publications

Design analysis of ORC micro-turbines making use of thermal energy of oceans

Design analysis of ORC micro-turbines making use of thermal energy of oceans

Choosing the Most Suitable Working Fluid for a CTEC

Ocean Thermal Energy Conversion: Heat Exchanger Evaluation and Selection

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