1 |
Enabling high compression ratio in boosted spark ignition engines: Thermodynamic trajectory and fuel chemistry effects on knock Chuahy FD, Splitter D, Boronat V, Wagnon SW Combustion and Flame, 222, 446, 2020 |
2 |
Thermodynamic analysis and experimental validation of multi-composition ammonia liquor absorption engine cycle for power generation Satpute SR, Takalkar G, Mali N, Bhagwat S International Journal of Energy Research, 44(15), 12430, 2020 |
3 |
Thermodynamic and economic optimization of a double-pressure organic Rankine cycle driven by low-temperature heat source Sun QX, Wang YX, Cheng ZY, Wang JF, Zhao P, Dai YP Renewable Energy, 147, 2822, 2020 |
4 |
Heat recovery in energy production from low temperature heat sources Brogioli D, La Mantia F AIChE Journal, 65(3), 980, 2019 |
5 |
Experimental investigation of modern ORC working fluids R1224yd(Z) and R1233zd(E) as replacements for R245fa Eyerer S, Dawo F, Kaindl J, Wieland C, Spliethoff HM Applied Energy, 240, 946, 2019 |
6 |
A review of low-temperature heat recovery technologies for industry processes Xia L, Liu RM, Zeng YT, Zhou P, Liu JJ, Cao XR, Xiang SG Chinese Journal of Chemical Engineering, 27(10), 2227, 2019 |
7 |
Assessment of a combination of three heat sources for heat pumps to supply district heating Pieper H, Ommen T, Elmegaard B, Markussen WB Energy, 176, 156, 2019 |
8 |
Thermo-economic analysis of transcritical CO2 power cycle and comparison with Kalina cycle and ORC for a low-temperature heat source Meng FX, Wang EH, Zhang B, Zhang FJ, Zhao CL Energy Conversion and Management, 195, 1295, 2019 |
9 |
Low-temperature thermodynamic properties of Al(C5HF6O2)(3) Bespyatov MA, Kuzin TM Journal of Chemical Thermodynamics, 138, 98, 2019 |
10 |
Redetermination of low-temperature heat capacity of Cu(C5H7O2) Bespyatov MA Journal of Chemical Thermodynamics, 137, 1, 2019 |