Abstract
Ocean thermal energy conversion (OTEC) harvests the power from the thermal energy in the ocean, which is reserved in the ocean as the temperature difference between warm surface and cold deep seawaters. In the energy conversion, the heat exchangers transfer the thermal energy to the heat engine, which converts it into power. The pressure drops yielded by piping, valve and heat exchangers cause pump loads, which show significant negative power with respect to net power in OTEC. The heat transfer performance and the pressure drop in heat exchanger depend on the types and shapes of each heat transfer area. Generally, heat exchangers with higher friction factors yield higher heat transfer performance and vice versa. However, heat transfer performance and pressure drop are separately evaluated and there is no comprehensive performance evaluation index for OTEC power take-off. Therefore, this research proposes a new simplified overall performance evaluation method for heat exchangers, which can be comprehensively and easily applied and takes into consideration the heat transfer performance and the pressure drop. The evaluation results on plate-type heat exchangers show that the overall performance in each heat exchanger are elucidated and are quantitatively compared.
Highlights
Renewable energy represents an indispensable power supply for the sustainable development of infrastructure
The performance of existing plate-type heat exchangers applied to ocean thermal energy conversion (OTEC) are evaluated by the proposed performance evaluation method and the procedure using six different plate type heat exchangers [24,31,32,33,34]
For the purpose of the development of a comprehensive performance evaluation method for OTEC heat exchangers, it is derived that the theoretical relationship between the heat transfer performance of heat exchangers including the pressure drop and power output from the reversible heat engine
Summary
Renewable energy represents an indispensable power supply for the sustainable development of infrastructure. To achieve effective development of the available power output of an OTEC system, a conflict requirement is necessary that the significant enhancement of heat exchanger performances with reducing the pressure drop. The result of the optimum design method is a balance between the heat transfer performance of all the heat exchangers, including evaporators and condensers, and the required seawater intake pump power. This study describes the theoretical relationship between the heat transfer performance of heat exchangers, including the pressure drop and power output from the heat engine of OTEC, and proposes a comprehensive performance evaluation index. This method will be applied to the existing plate-type heat exchangers
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