Abstract:SUMMARY
The analysis of heat pump cycles with and without an internal heat exchanger (IHE) is carried out in the paper, in which HFC125/HCs binary mixtures are used as the alternative refrigerants. And the cycle performance under different operation conditions is also compared. The results show that when the mass fraction of HFC125 ranges from 10 to 20%, the coefficient of performance (COP) for HFC125/HC290 (M1) mixtures is 0.92 and 1.01% lower than that of HCFC22 and HFC134a, respectively. For HFC125/HC600 (M… Show more
“…There are few studies on the flow heat transfer characteristics of the two-stage spiral casing heat exchanger connected by straight pipe sections. The effect of structural parameters on the flow heat transfer performance of heat exchangers, the effect of structural parameters and inner and outer tube flow rates on the overall heat transfer coefficients, ε-NTU, pump work and pressure drop, combined thermohydraulic performance factors and inner and outer tube Nusselt number were previously discussed by this group [14] , and the preliminary experimental studies showed that this structure heat exchanger has better heat transfer efficiency [15,16] . This study aims to further reveal the influence of flow parameters on the heat transfer performance of a two-stage spiral casing heat exchanger, and the results will provide theoretical guidance for efficient heat exchanger operation in heat pump systems.…”
The study of the performance of high-efficiency heat pump systems has been a hot issue of general interest in the field of heat pump air conditioning. For the designed and developed two-stage casing tandem heat exchanger of heat pump system, the 3D finite volume method and the realizable k-ε model are used to numerically analyze the influence law of inlet fluid temperature and flow velocity on the overall heat transfer coefficient as well as the Nussle number of inner and outer tubes. The results show that decreasing the inlet water temperature or increasing the inlet refrigerant temperature can improve the overall heat transfer performance; Nuin increases with the increase of water and refrigerant flow rates, while Nuout increases with the increase of water flow rate but decreases with the increase of refrigerant flow rate; Nuin and Nuout both increase with the decrease of water temperature or refrigerant temperature increases.
“…There are few studies on the flow heat transfer characteristics of the two-stage spiral casing heat exchanger connected by straight pipe sections. The effect of structural parameters on the flow heat transfer performance of heat exchangers, the effect of structural parameters and inner and outer tube flow rates on the overall heat transfer coefficients, ε-NTU, pump work and pressure drop, combined thermohydraulic performance factors and inner and outer tube Nusselt number were previously discussed by this group [14] , and the preliminary experimental studies showed that this structure heat exchanger has better heat transfer efficiency [15,16] . This study aims to further reveal the influence of flow parameters on the heat transfer performance of a two-stage spiral casing heat exchanger, and the results will provide theoretical guidance for efficient heat exchanger operation in heat pump systems.…”
The study of the performance of high-efficiency heat pump systems has been a hot issue of general interest in the field of heat pump air conditioning. For the designed and developed two-stage casing tandem heat exchanger of heat pump system, the 3D finite volume method and the realizable k-ε model are used to numerically analyze the influence law of inlet fluid temperature and flow velocity on the overall heat transfer coefficient as well as the Nussle number of inner and outer tubes. The results show that decreasing the inlet water temperature or increasing the inlet refrigerant temperature can improve the overall heat transfer performance; Nuin increases with the increase of water and refrigerant flow rates, while Nuout increases with the increase of water flow rate but decreases with the increase of refrigerant flow rate; Nuin and Nuout both increase with the decrease of water temperature or refrigerant temperature increases.
“…66 Therefore, in order to compare the performance of various refrigerant blends, average (mean) evaporating (t e,m ) and condensing temperatures (t k,m ) are defined and they are expressed as follows. 66–68 Figure 3.P-h chart for zeotropic refrigerants.…”
Section: Methodsmentioning
confidence: 99%
“…Referring to Figure 4, various process and losses that take place in actual VCR cycle are stated as follows: 63–70 Superheating of vapour refrigerant in the evaporator (1j-1i), heat gain across suction line (1i-1 h), pressure drop in the suction line (1 h-1 g), pressure loss in the suction valve (1 g-1), actual compression work (1-2), pressure loss in the discharge valve (2-2 g), pressure drop in the delivery line (2 g-2 h), desuperheating and heat loss of refrigerant in the delivery line (2 h-2i), pressure drop across condenser (2 h-3), subcooling of liquid refrigerant through condenser (3-3 g), heat gain of refrigerant in liquid line (3 g-3 h), expansion process (3 h-4) and pressure drop across evaporator (4-1j), respectively.…”
Section: Methodsmentioning
confidence: 99%
“…Referring to Figure 4, various process and losses that take place in actual VCR cycle are stated as follows: [63][64][65][66][67][68][69][70] Superheating of vapour refrigerant in the evaporator (1j-1i), heat gain across suction line (1i-1 h), pressure drop in the suction line (1 h-1 g), pressure loss in the suction valve (1 g-1), actual compression work (1-2), pressure loss in the discharge valve (2-2 g), pressure drop in the delivery line (2 g-2 h), desuperheating and heat loss of refrigerant In this work, several losses considered while computing performance analysis of actual VCR cycle operating with various R22 alternative refrigerants were taken from the literature and they are given in the Performance calculations for practical vapour compression cycle (Actual VCR cycle) section. 27,33,64,[69][70][71][72][73][74] In this thermodynamic analysis, the necessary thermophysical and thermodynamic properties of various considered R22 alternatives are taken from the NIST REFPROP 9.1.…”
This study focuses on energy performance investigation and environmental impact analysis of various new ecofriendly refrigerant blends as alternatives to high global warming potential refrigerant R22 theoretically. In this study, 23 refrigerants were considered at various composition. The present work considered the practical vapour compression refrigeration cycle for the performance assessment of various R22 alternatives. Essential studies such as toxicity, flammability, and total equivalent warming index of various novel refrigerants were also conducted in this study. Results obtained from practical vapour compression refrigeration cycle revealed that the energy efficiency ratio of refrigerants such as R1270 (2.860) and RB03 (R290/R152a of 60/40 in mass %) (2.854) was closer to the energy efficiency ratio of R22 (2.940). Volumetric refrigeration capacity (VRC) of R1270 (3293 kJ/m3) was similar to that of R22 (3297 kJ/m3) whereas VRC of RB03 (2908 kJ/m3) was almost similar to that of R407C (2925 kJ/m3) which was an alternative to R22. Compressor discharge temperature of RB03 was 15.78 ℃ lower when compared to R22. Flammability study revealed that all the new refrigerant blends (RB01 to RB04) were classified into weakly flammable (A2) and flammable (A3) category refrigerants whereas toxicity study revealed that all the investigated refrigerants were classified into non-toxic group (A). Refrigerant blend RB03 was less flammable compared to R1270. Total equivalent warming index analysis revealed that the environmental impact of R422A was 27.88% higher than R22 whereas RB03 has 4.97% lower environmental impact compared to R22. Overall, performance of refrigerant blend RB03 was better compared to 23 investigated refrigerants and it was very nearer to the performance of R22 and hence, it could be considered as an ecofriendly alternative to replace high global warming potential refrigerant R22 used in air conditioners.
“…Zeotropic refrigerants will evaporate and condense through a range of temperatures due to its temperature glide and also temperature glide causes the change in composition during evaporation and condensation phase change processes as shown in Figure 4. Therefore, in order to compare the performance of various refrigerant mixtures, average (mean) evaporating (t e,m ) and condensing temperature (t k,m ) are defined and they are as follows 46–48 where te,m is the mean evaporating temperature (℃), te″ is the dew point temperature at the evaporation process (℃), te1 is temperature at entry of the evaporation process (℃), tk,m is the mean condensing temperature (℃), tk' is the bubble point temperature at the condensation process (℃), and tk″ is the dew point temperature at the condensation process (℃). Pressure–enthalpy (P-h) chart for zeotropic refrigerants is different from pure and azeotropic refrigerants and it is shown in Figure 4.…”
The present investigation focuses on theoretical performance of various new environment-friendly refrigerant mixtures as substitutes to high global warming potential refrigerant R22. In this investigation, 34 refrigerants were considered at various composition. In this work, both complex vapor compression cycle (actual cycle) and standard vapor compression cycle (ideal cycle) was considered for the performance assessment of refrigerants. Vital studies such as flammability, toxicity, and environmental impact of various novel refrigerants were also carried out in this study. Results obtained from actual cycle showed that the coefficient of performance of refrigerant mixture RM40 (R1270/R134a 90/10 in mass %) (2.728) was the greatest among 34 investigated alternatives and it was closer to the coefficient of performance of R22 (2.770). Compressor discharge temperature of RM40 was 13.36 ℃ lower when compared with R22. Volumetric refrigeration capacity of RM40 (3335 kJ/m3) was slightly higher than that of R22 (3297 kJ/m3). Power spent per ton of refrigeration of RM40 (1.288 kW/TR) was marginally higher than that of R22 (1.269 kW/TR). Global warming potential (GWP100) of RM40 (133) was very low compared to the GWP100 of R22 (1760). Total equivalent warming index (environmental impact) of RM40 was 5.61% lower than R22. However, performance results obtained from standard cycle for various investigated refrigerants were better than actual cycle, since various losses occur were neglected in the standard cycle. Overall, thermodynamic performance of refrigerant mixture RM40 (R1270/R134a 90/10 in mass %) obtained from both actual and standard cycle was the highest among 34 investigated refrigerants and it was very closer to the performance of R22 and hence, it could be considered as an environment-friendly alternative to replace high GWP refrigerant R22 used in refrigeration systems.
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