Thermoelectric topping cycles for power plants to eliminate cooling water consumption

[Display omitted] •Complete system analysis of a thermoelectric topping generator in a power plant.•Topping application does not require high-ZT thermoelectrics to be effective.•The improved efficiency can be used to replace water cooling with air cooling.•The topping generator is superior to flue g...

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Published in:Energy conversion and management 2014-08, Vol.84 (C), p.244-252
Main Authors: Yazawa, Kazuaki, Hao, Menglong, Wu, Bin, Silaen, Armin K., Zhou, Chenn Qian, Fisher, Timothy S., Shakouri, Ali
Format: Article
Language:English
Subjects:
Applied sciences
Boiler
Construction costs
Cooling
Energy
ENERGY CONSERVATION, CONSUMPTION, AND UTILIZATION
Exact sciences and technology
Generators
Power generator
Rankine cycle
Steam electric power generation
Steam temperature
Thermoelectric
Thermoelectricity
Topping cycle
Tubes
Walls
Waste heat recovery
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cited_by cdi_FETCH-LOGICAL-c542t-216cef3fe6416b4b70e314995be0ed7acbba78f3b91c09b52b7b5a2a137fd4603
cites cdi_FETCH-LOGICAL-c542t-216cef3fe6416b4b70e314995be0ed7acbba78f3b91c09b52b7b5a2a137fd4603
container_end_page 252
container_issue C
container_start_page 244
container_title Energy conversion and management
container_volume 84
creator Yazawa, Kazuaki
Hao, Menglong
Wu, Bin
Silaen, Armin K.
Zhou, Chenn Qian
Fisher, Timothy S.
Shakouri, Ali
description [Display omitted] •Complete system analysis of a thermoelectric topping generator in a power plant.•Topping application does not require high-ZT thermoelectrics to be effective.•The improved efficiency can be used to replace water cooling with air cooling.•The topping generator is superior to flue gas waste heat recovery in efficiency and less materials. This work shows that thermoelectric (TE) topping generators can add 4–6% to the overall system efficiency for advanced supercritical steam turbines (Rankine cycle) that nominally generate power with 40–42% efficiency. The analysis then considers how this incremental topping energy can replace cooling water flow with air-cooled condensers (ACC) while maintaining current power output and plant efficiency levels with commensurate economic benefit ($/kWh). The simulated TE modules are located inside a coal-fired boiler wall constructed of wet steam tubes. The topping TE generator employs non-toxic and readily available materials with a realistic figure-of-merit range (ZT=0.5–1.0). Detailed heat transfer and thermal analyses are included for this high-temperature TE application (e.g., 800K for the cold side reservoir). With the tube surface enhanced by fins, the TE elements are designed to perform optimally through a distributed configuration along the wall-embedded steam tubes that are more than 20m high. The distribution of the gas temperature in the furnace along the wall height is predicted by thermo-fluid dynamic analysis. This foundational design and analysis study produces overall realistic efficiency predictions in accordance with temperature–entropy analysis for superheated Rankine cycles. Lastly, the approach also allows for the addition of waste heat recovery from the flue gas. The analysis shows that the power output from the topping TE generator is significantly larger, compared to that from the waste heat recovery, due to the larger available temperature difference.
doi_str_mv 10.1016/j.enconman.2014.04.031
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source ScienceDirect Freedom Collection
subjects Applied sciences
Boiler
Construction costs
Cooling
Energy
ENERGY CONSERVATION, CONSUMPTION, AND UTILIZATION
Exact sciences and technology
Generators
Power generator
Rankine cycle
Steam electric power generation
Steam temperature
Thermoelectric
Thermoelectricity
Topping cycle
Tubes
Walls
Waste heat recovery
title Thermoelectric topping cycles for power plants to eliminate cooling water consumption
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