Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
7161312 | Energy Conversion and Management | 2016 | 17 Pages |
Abstract
This paper shows the Part A - evaluations of the C-ORC, focusing on indexes including recovered waste heat, net power output, thermal efficiencies and exergy efficiencies. First of all, distributions of the engine's multi-grade waste heat were studied to reveal the characteristics and utilization potential of waste energy. The comparison and screening of working fluids were carried out next to find the best fluids for the HT-Loop and LT-Loop respectively based on the rated engine condition. Toluene, decane, cyclohexane and D4 were four proper alternatives for the HT-Loop while R143a, R125, R218 and R41 were four proper alternatives for the LT-Loop. Comparisons indicated that toluene and R143a made the perfect match for the C-ORC with the highest net power output (33.9 kW), thermal efficiency (9.9%) and exergy efficiency (39.1%). The rankings of the two groups of alternate fluids based on their thermodynamic performance were: toluene > decane > cyclohexane > D4 and R143a > R125 > R218 > R41. Finally, the C-ORC's performance was evaluated based on the engine's practical operating conditions. Results indicated that, the engine's waste heat was only able to drive the C-ORC system when the engine torque was higher than 917 N m. The maximal recovered heat of the EG, EGR, CA and JW were 153.0 kW, 9.1 kW, 37.5 kW and 267.0 kW under available conditions; the highest net power output, thermal efficiency and exergy efficiency were 38.2 kW, 11.3%, 38.7% respectively; and the largest efficiency increment to the original engine was up to 16.0%. Summarily, thermodynamic evaluations from Part A - reveal that the proposed C-ORC has significant heat-recovery capacities and efficiency-promotion potential.
Keywords
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Physical Sciences and Engineering
Energy
Energy (General)
Authors
Gequn Shu, Guopeng Yu, Hua Tian, Haiqiao Wei, Xingyu Liang, Zhiyong Huang,