COMPARATIVEPERFORMANCEANALYSISOFSELECTEDWORKINGFLUIDS INALOWTEMPERATUREORGANICRANKINE CYCLE FOR WASTE HEAT RECOVERY APPLICATION.
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Abstract
Comparative Performance analysis of Selected Working Fluids in a low temperature organic RankineCycle forWasteHeatrecoveryApplication. The global imperative to improve energy efficiency necessitates the effective recovery of low- gradewast heat,achallengeperfectlyaddressedbytheorganicRankineCycle (ORC)technology. This project undertakes a comprehensive comparative analysis of selected candidate organic
working fluids – including Ethanol, Toluene, Cyclopentane, R245fa, R1233zd(E) and R152a, drawn fromthe categories ofdry,wet andisentropic fluids,withina low temperatureORCsystem designed for industrial waste heat recovery. The primary goal isto identify the optimal fluid that maximizesthermodynamic performance under a specified heatsource temperature (e.g 206 0Cto 123.70C). A thermodynamic model was developed to simulate the cycle’s performance. The selected fluids areevaluatedagainstkeymetricssuchasnetworkandthermal efficiency. Initial simulation results reveal significant variability in cycle performance, depending on the fluid’s criticaltemperature,boilingpointandcondensationtemperatures andpressures. The findings provide a data driven basisforselecting aworking fluid that not only achieves higher power generation but also minimizes system’s complexity and investment cost, thereby acceleratingthedeploymentofsustainablelowtemperaturewasteheatrecoverysystems
working fluids – including Ethanol, Toluene, Cyclopentane, R245fa, R1233zd(E) and R152a, drawn fromthe categories ofdry,wet andisentropic fluids,withina low temperatureORCsystem designed for industrial waste heat recovery. The primary goal isto identify the optimal fluid that maximizesthermodynamic performance under a specified heatsource temperature (e.g 206 0Cto 123.70C). A thermodynamic model was developed to simulate the cycle’s performance. The selected fluids areevaluatedagainstkeymetricssuchasnetworkandthermal efficiency. Initial simulation results reveal significant variability in cycle performance, depending on the fluid’s criticaltemperature,boilingpointandcondensationtemperatures andpressures. The findings provide a data driven basisforselecting aworking fluid that not only achieves higher power generation but also minimizes system’s complexity and investment cost, thereby acceleratingthedeploymentofsustainablelowtemperaturewasteheatrecoverysystems
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