Entropy, Entransy and Exergy Analysis of a Dual-Loop Organic Rankine Cycle (DORC) Using Mixture Working Fluids for Engine Waste Heat Recovery
Abstract
:1. Introduction
2. Modeling
2.1. System Description of DORC
2.2. Working Fluids Selection
2.3. Mathematical Modeling
- The whole system operates in a steady state.
- Ignoring the pressure drop loss and thermal radiation in heat exchangers.
- The components and thermodynamic properties of mixtures do not vary with pressure or temperature.
- The isentropic efficiency of expanders and pumps are 0.8.
- The ambient temperature is set to be 10 °C.
2.3.1. Energy Modeling
2.3.2. Exergy Modeling
2.3.3. Entropy Modeling
2.3.4. Entransy Modeling
3. Results and Discussion
3.1. Effects of Evaporation Temperature and Condensation Temperature of HT Loop
3.2. Effect of Evaporation Temperature and Condensation Temperature of LT Loop
3.3. Effect of Superheating Degree and PPTD of HT Loop
3.4. Effects of Working Fluid Mixture Component
4. Conclusions
- Hexane/toluene, cyclopentane/toluene, and R123/toluene are selected as high-temperature working fluids, and detailed analysis are proceeded under constant heat source condition. When the evaporator inlet temperature and condenser outlet temperature change, although the optimal evaporation temperature and maximum output power is different, the variation characteristics of entropy generation rate, entransy loss rate, entransy efficiency, and exergy loss are similar. Hence, the effects of operation temperature on these objects do not matter whatever the working fluid.
- The system net power output and entransy loss rate both increase first and then decrease as the HT evaporation temperature increases, while decrease as the HT or LT condensation temperature increases. The entropy generation rate and entransy efficiency show opposite variation.
- The curve characteristic of entransy loss rate is same as that of system power output, while the entropy generation rate yields a reverse trend to the entransy efficiency. The proposed method of the entropy and entransy analysis could be used for system optimization. Whereas the exergy analysis could be only utilized under fixed stream conditions.
- The entransy loss rate decreases with the increase of both superheating degree and PPTD. The entropy generation rate increases as superheating degree increases while PPTD has no effect on it. The entransy loss rate for hexane/toluene keeps dropping with the rising mass fraction of toluene, but that for cyclopentane/toluene and R123/toluene it decreases first and then increases. R123/toluene owns the lowest entransy loss rate and the highest entransy loss rate is obtained by hexane/toluene under same mass fraction. The entropy generation for three mixtures show a reverse trend with entransy loss rate.
Author Contributions
Funding
Conflicts of Interest
Nomenclature
specific heat capacity, J/kg·K | |
specific exergy, J/kg | |
exergy loss, W | |
entransy loss rate, W·K | |
specific enthalpy, J/kg | |
mass flow rate, kg/s | |
heat quantity, J | |
entropy generation rate, W/K | |
entropy flow rate, W/K | |
entropy change rate, W/K | |
temperature, K | |
power, W | |
Efficiency | |
Hi | heat exchanger with number i, i = 1,2,3,4 |
HT | high temperature |
LT | low temperature |
Pi | pump with number i, i = 1,2 |
Ti | expander with number i, i = 1,2 |
subscripts | |
b | parameters in LT cycle |
con | condensation |
dis | dissipation |
eva | evaporation |
glide | temperature slip |
g, c | heat, cold source |
op | optimal |
p | pump |
r | working fluid |
sub | Supercooling |
sup | Superheating |
sys | System |
t | expander |
1-17 | state point of T-s graph |
2s,6s | Corresponding isentropic point |
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Fluids | Molar Mass (g/mol) | Triple Point Temperature (K) | Standard Boiling Point (K) | Critical Temperature (K) | Critical Pressure (MPa) |
---|---|---|---|---|---|
hexane | 86.18 | 177.83 | 341.86 | 507.82 | 3.03 |
toluene | 92.14 | 178 | 383.75 | 591.75 | 4.13 |
cyclopentane | 70.13 | 179.72 | 322.4 | 511.69 | 4.51 |
pentane | 72.15 | 143.47 | 309.21 | 469.7 | 3.37 |
R123 | 152.93 | 166 | 300.97 | 456.83 | 3.66 |
R245fa | 134.05 | 171.05 | 288.3 | 427.2 | 3.65 |
Property | Power (kW) | Rotation Rate (r/min) | Torque (N·m) | Exhaust Temperature(K) | Exhaust Gas Mass Flow Rate (kg/s) |
---|---|---|---|---|---|
Value | 1000 | 1500 | 6350 | 623 | 1 |
Parameter | Sign | Value |
---|---|---|
Environment temperature | T0 | 283.15 (K) |
Cold stream temperature | Tc | 288.15 (K) |
Superheating degree | ΔTsup, ΔTsup,b | 5 (K) |
Supercooling degree | ΔTsub, ΔTsub,b | 0 (K) |
Expander total efficiency | % | 80 |
Pump total efficiency | % | 80 |
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Wang, S.; Zhang, W.; Feng, Y.-Q.; Wang, X.; Wang, Q.; Liu, Y.-Z.; Wang, Y.; Yao, L. Entropy, Entransy and Exergy Analysis of a Dual-Loop Organic Rankine Cycle (DORC) Using Mixture Working Fluids for Engine Waste Heat Recovery. Energies 2020, 13, 1301. https://doi.org/10.3390/en13061301
Wang S, Zhang W, Feng Y-Q, Wang X, Wang Q, Liu Y-Z, Wang Y, Yao L. Entropy, Entransy and Exergy Analysis of a Dual-Loop Organic Rankine Cycle (DORC) Using Mixture Working Fluids for Engine Waste Heat Recovery. Energies. 2020; 13(6):1301. https://doi.org/10.3390/en13061301
Chicago/Turabian StyleWang, Shuang, Wei Zhang, Yong-Qiang Feng, Xin Wang, Qian Wang, Yu-Zhuang Liu, Yu Wang, and Lin Yao. 2020. "Entropy, Entransy and Exergy Analysis of a Dual-Loop Organic Rankine Cycle (DORC) Using Mixture Working Fluids for Engine Waste Heat Recovery" Energies 13, no. 6: 1301. https://doi.org/10.3390/en13061301
APA StyleWang, S., Zhang, W., Feng, Y. -Q., Wang, X., Wang, Q., Liu, Y. -Z., Wang, Y., & Yao, L. (2020). Entropy, Entransy and Exergy Analysis of a Dual-Loop Organic Rankine Cycle (DORC) Using Mixture Working Fluids for Engine Waste Heat Recovery. Energies, 13(6), 1301. https://doi.org/10.3390/en13061301