| 1 |
Reverse electrodialysis heat engine with multi-effect distillation: Exergy analysis and perspectives
Ortega-Delgado B, Giacalone F, Catrini P, Cipollina A, Piacentino A, Tamburini A, Micale G
Energy Conversion and Management, 194, 140, 2019 |
| 2 |
Effect of varying fuel types on oxy-combustion performance
Ozsari I, Ust Y
International Journal of Energy Research, 43(14), 8684, 2019 |
| 3 |
A critical evaluation on chemical exergy and its correlation with high heating value for single and multi-component typical plastic wastes
Huang YW, Chen MQ, Li QH, Xing W
Energy, 156, 548, 2018 |
| 4 |
Assessing the exergy degradation of the natural capital: From Szargut's updated reference environment to the new thermoecological-cost methodology
Valero A, Valero A, Stanek W
Energy, 163, 1140, 2018 |
| 5 |
Standard molar chemical exergy: A new accurate model
Gharagheizi F, Ilani-Kashkouli P, Hedden RC
Energy, 158, 924, 2018 |
| 6 |
Exergy analysis of reverse electrodialysis
Giacalone F, Catrini P, Tamburini A, Cipollina A, Piacentino A, Micale G
Energy Conversion and Management, 164, 588, 2018 |
| 7 |
Prediction of chemical exergy of organic substances using artificial neural network-multi layer perceptron
Shan J, Wang YY, Gao W
Energy Sources Part A-recovery Utilization and Environmental Effects, 40(15), 1826, 2018 |
| 8 |
Low-energy-penalty principles of CO2 capture in polygeneration systems
Wu HD, Gao L, Jin HG, Li S
Applied Energy, 203, 571, 2017 |
| 9 |
Prediction models for chemical exergy of biomass on dry basis from ultimate analysis using available electron concepts
Qian HL, Zhu WW, Fan SD, Liu C, Lu XH, Wang ZX, Huang DC, Chen W
Energy, 131, 251, 2017 |
| 10 |
On the prediction of chemical exergy of organic substances using least square support vector machine
Wu H, Yu YM, Fu HL, Zhang LX
Energy Sources Part A-recovery Utilization and Environmental Effects, 39(24), 2210, 2017 |
