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2020 | OriginalPaper | Buchkapitel

Increasing the Operation Efficiency of Air Conditioning System for Integrated Power Plant on the Base of Its Monitoring

verfasst von : Eugeniy Trushliakov, Andrii Radchenko, Serhiy Forduy, Anatolii Zubarev, Artem Hrych

Erschienen in: Integrated Computer Technologies in Mechanical Engineering

Verlag: Springer International Publishing

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Abstract

The efficiency of reciprocating gas engines of integrated energy systems (IES) for combined electricity, heat and refrigeration generation is strictly influenced by their cyclic air temperatures. To evaluate the effect of gas engine cyclic air deep cooling, compared with conventional its cooling, the data on dependence of fuel consumption and power output of gas engine JMS 420 GS-N.L on its inlet air temperature at varying ambient air temperatures at the entrance of the radiator for scavenge air cooling were received. The results of treatment of gas engine efficiency monitoring proved non-effective operation of conventional chilling all the ambient air, coming into the engine room, because of increased air temperature at the inlet of turbocharger (TC), caused by heat influx from surroundings in the engine room. A new method of gas engine inlet air two-stage cooling at increased ambient air temperatures and advanced cyclic air cooling system with absorption lithium-bromide chiller and refrigerant ejector chiller was proposed. With this chilled water from absorption lithium-bromide chiller is used as a coolant in the first high-temperature stage of engine inlet air cooler and boiling refrigerant of ejector chiller in the second low-temperature stage.

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Titel: Increasing the Operation Efficiency of Air Conditioning System for Integrated Power Plant on the Base of Its Monitoring
verfasst von: Eugeniy Trushliakov
Andrii Radchenko
Serhiy Forduy
Anatolii Zubarev
Artem Hrych
Verlag: Springer International Publishing
Buch: Integrated Computer Technologies in Mechanical Engineering
Print ISBN: 978-3-030-37617-8

Electronic ISBN: 978-3-030-37618-5

Copyright-Jahr: 2020
DOI: https://doi.org/10.1007/978-3-030-37618-5_30

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