2018
DOI: 10.1016/j.apenergy.2018.06.022
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Thermodynamic optimisation of a high-electrical efficiency integrated internal combustion engine – Organic Rankine cycle combined heat and power system

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Cited by 68 publications
(31 citation statements)
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“…Chatzopoulou and Markides thermodynamically optimized an ORC-assisted internal combustion engine using R245fa. As a result of the optimization, thermal and exergy efficiencies of the ORC was calculated as 14% and 33%, respectively [62]. In the present study, at the same turbine inlet temperature and pressure, the net power production per mass flow rate, thermal and exergy efficiencies were calculated as 36.25 kJ/kg, 15.78% and 27.17%.…”
Section: Subcritical Rorcmentioning
confidence: 67%
“…Chatzopoulou and Markides thermodynamically optimized an ORC-assisted internal combustion engine using R245fa. As a result of the optimization, thermal and exergy efficiencies of the ORC was calculated as 14% and 33%, respectively [62]. In the present study, at the same turbine inlet temperature and pressure, the net power production per mass flow rate, thermal and exergy efficiencies were calculated as 36.25 kJ/kg, 15.78% and 27.17%.…”
Section: Subcritical Rorcmentioning
confidence: 67%
“…where m denotes a mass flow rate; h a specific enthalpy; T and P are temperatures and pressures, respectively; Qe and Qc are the heat duty of the evaporator and the condenser, respectively; Wp, We and Wnet are the pump power consumption, the expansion power output and the net power output from the system, respectively; ηp and ηe are the (fixed [15,17]) isentropic efficiencies of the pump and the expander; cp is a specific heat capacity. Furthermore, subscripts '1'-'6' denote thermodynamic states; 'f', 'g' and 'cw' refer to the working fluid, exhaust gas and cooling water, respectively; 'in' and 'out' to the inlet and outlet; and 's' signifies an isentropic process.…”
Section: Orc Thermodynamic Modelmentioning
confidence: 99%
“…Investigations on ORC technology for converting recovered waste-heat from ICEs have been conducted both computationally and experimentally [9,10], including on configuration design [11][12][13] and system optimization [14][15][16], working fluid selection by traditional pre-selection (including pure fluids [17,18] and mixtures [19,20]) and by new computer-aided molecular design methods [21][22][23] integrated into cycle optimization [24,25], expander selection and design [26,27] (including piston [28][29][30], screw [31][32][33] and rotary-vane [34] expanders), and off-design performance [35,36]. These excellent studies have enabled significant progress with the performance of ORC technology towards through careful considerations of the working fluid, key components and system parameters.…”
Section: Introductionmentioning
confidence: 99%
“…Baidya et al [37] described the implementation of ORC for waste heat recovery of Diesel generators in off-the-grid locations. Chatzopoulou et al [38] performed a whole system optimization of an integrated Diesel generator and ORC for combined heat and power, and then investigated the off-design conditions with varying conditions of the engine [39].…”
Section: Orc For Ic Engine Whrmentioning
confidence: 99%
“…ORC direct evaporation from exhaust gases is certainly conceptually much simpler. Therefore, it is very often considered as the option in the literature studies at system level [38], [58], [115] and component level [116].…”
Section: Direct Vs Indirect Evaporationmentioning
confidence: 99%