1 |
Potential of carbon dioxide transcritical power cycle waste-heat recovery systems for heavy-duty truck engines Li XY, Tian H, Shu GQ, Zhao MR, Markides CN, Hu C Applied Energy, 250, 1581, 2019 |
2 |
Sensitivity analysis of operation parameters on the system performance of organic rankine cycle system using orthogonal experiment Xi H, Zhang HH, He YL, Huang ZH Energy, 172, 435, 2019 |
3 |
Analysis of two-stage waste heat recovery based on natural gas-fired boiler Cui XY, Zhang HY, Guo JF, Huai XL, Xu M International Journal of Energy Research, 43(14), 8898, 2019 |
4 |
Transient response of waste heat recovery system for hydrogen production and other renewable energy utilization Xi H, He YL, Wang JH, Huang ZH International Journal of Hydrogen Energy, 44(30), 15985, 2019 |
5 |
Optimization of organic Rankine cycle used for waste heat recovery of construction equipment engine with additional waste heat of hydraulic oil cooler Negash A, Kim YM, Shin DG, Cho GS Energy, 143, 797, 2018 |
6 |
Utilizing the scavenge air cooling in improving the performance of marine diesel engine waste heat recovery systems Mito MT, Teamah MA, El-Maghlany WM, Shehata AI Energy, 142, 264, 2018 |
7 |
Effects of external perturbations on dynamic performance of carbon dioxide transcritical power cycles for truck engine waste heat recovery Li XY, Tian H, Shu GQ, Hu C, Sun R, Li LG Energy, 163, 920, 2018 |
8 |
Thermo-economic analysis of the transcritical organic Rankine cycle using R1234yf/R32 mixtures as the working fluids for lower-grade waste heat recovery Yang MH, Yeh RH, Hung TC Energy, 140, 818, 2017 |
9 |
Design, empirical modelling and analysis of a waste-heat recovery system coupled to a traditional cooking stove Sakdanuphab R, Sakulkalavek A Energy Conversion and Management, 139, 182, 2017 |
10 |
Single-loop organic Rankine cycles for engine waste heat recovery using both low- and high-temperature heat sources Kim YM, Shin DG, Kim CG, Cho GB Energy, 96, 482, 2016 |