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Effects of various parameters on the efficiency of a CO2 heat pump: a statistical approach

Year 2015, Volume: 1 Issue: 4, 236 - 278, 01.04.2015
https://doi.org/10.18186/thermal.228874

Abstract

The influence of variables such as; refrigerant amount, chilling and cooling water temperature, throttle valve opening, cooling and chilling water flow rates, on the efficiency (coefficient of performance – COP) of a water to water carbon dioxide heat pump was investigated. Design of experiments was done using design-expert® 6 software for regression analysis. A response surface method known as central cubic design was used to provide optimum results with minimum experiments. Through multiple regression analysis, an empirical equation relating the COP to the variables was derived. Analysis of variance revealed that these regressions are statistically significant at 95% confidence level compounded with a very low standard deviation and a high adequate precision. The close relationship between the predicted COP values and the actual values further proves the worthiness of the empirical equation. It was observed that cooling water temperature had the highest influence followed by the chilling water temperature. Surprisingly, the amount of the refrigerant was third followed by the throttle valve opening. Understandably, chilling water flow rate had the least effect on the COP. Through response surface diagrams, the interactive influence of the variables were also observed. The COP values arrived at varied from 1.545 to 6.914 although if the variables were optimized fully within the scope of this study, a value of up to 11.8 could be achieved. Still, if the variables range is increased further, higher COP could be achieved. Finally, a discussion was done in a bid to explain these results

References

  • ADRIANSYAH, W. 2001. Combined air conditioning and tap water heating plant using CO2 as refrigerant for Indonesian climate condition. Doctor of Engineering Doctorate, Norwegian University of Science and Technology.
  • AGRAWAL, N. & BHATTACHARYYA, S. 2008. Performance evaluation of a non-adiabatic capillary tube in a transcritical CO2 heat pump cycle. International Journal of Thermal Sciences, 47, 423-430.
  • AGRAWAL, N. & BHATTACHARYYA, S. 2009. Exergy assessment of an optimized capillary tube-based transcritical CO2 heat pump system. International Journal of Energy Research, 33, 1278-1289.
  • ATIK, K. & AKTAŞ, A. 2011. An experimental investigation of the effect of refrigerant charge level on an automotive air conditioning system. Journal of Thermal Science and Technology, 31, 11-17.
  • BENSAFI, A. & THONON, B. 2007. Transcritical R744 (CO2) heat pumps. Technician's Manual. Villeurbanne Cedex - France: Centre Technique Des Industries Aérauliques Et Thermiques.
  • BHATIA, A. RE: Selection Tips for Environmentally Safe Refrigerants. Type to CONTINUING EDUCATION AND DEVELOPMENT, I.
  • CALM, J. M. 2008. The next generation of refrigerants – Historical review, considerations, and outlook. International Journal of Refrigeration, 31, 1123-1133.
  • CALM, J. M. & DIDION, D. A. 1998. Trade-offs in refrigerant selections: past, present, and future. International Journal of Refrigeration, 21, 308-321.
  • CHEN, Y., LUNDQVIST, P. & WORKIE, A. B. Second Law Analysis of a Carbon Dioxide Transcritical Power System in Low-grade Heat Source Recovery.
  • CHO, H., RYU, C. & KIM, Y. 2007. Cooling performance of a variable speed CO2 cycle with an electronic expansion valve and internal heat exchanger. International Journal of Refrigeration, 30, 664-671.
  • CHO, H., RYU, C., KIM, Y. & KIM, H. Y. 2005. Effects of refrigerant charge amount on the performance of a transcritical CO2 heat pump. International Journal of Refrigeration, 28, 1266-1273.
  • CHRISTENSEN, Ø. 2009. Reversible R744 (CO2) heat pumps applied in public trains in Norway. Master of Science in Energy and Environment, Norwegian University of Science and Technology.
  • DIPIPPO, R. 2004. Second Law assessment of binary plants generating power from low-temperature geothermal fluids. Geothermics, 33, 565-586.
  • DUDDUMPUDI, V. S. 2010. Transcritical CO2 Air Source Heat Pump for Average UK Domestic Housing with High Temperature Hydronic Heat Distribution System. Master of Science, University of Strathclyde.
  • FERNANDEZ, N., HWANG, Y. & RADERMACHER, R. 2010. Comparison of CO2 heat pump water heater performance with baseline cycle and two high COP cycles. International Journal of Refrigeration, 33, 635-644.
  • FRONK, B. M. 2007. Modeling and Testing of Water-Coupled Microchannel Gas Coolers for Natural Refrigerant Heat Pumps. Master of Science, Georgia Institute of Technology.
  • FRONK, B. M. & GARIMELLA, S. 2011. Water-coupled carbon dioxide microchannel gas cooler for heat pump water heaters: Part II – Model development and validation. International Journal of Refrigeration, 34, 17-28.
  • GUPTA, D. K. & DASGUPTA, M. S. 2014. Simulation and performance optimization of finned tube gas cooler for trans- critical CO2 refrigeration system in Indian context. International Journal of Refrigeration, 38, 153-167.
  • HASHIMOTO, K. 2006. Technology and Market Development of CO2 Heat Pump Water Heaters (ECO CUTE) in Japan. Topical article. Japan: IEA Heat Pump Centre Newsletter.
  • HWANG, Y. & RADERMACHER, R. 1998. Theoretical Evaluation of Carbon Dioxide Refrigeration Cycle. HVAC&R Research, 4, 245-263.
  • JIANG, P.-X., ZHAO, C.-R., SHI, R.-F., CHEN, Y. & AMBROSINI, W. 2009. Experimental and numerical study of convection heat transfer of CO2 at super-critical pressures during cooling in small vertical tube. International Journal of Heat and Mass Transfer, 52, 4748-4756.
  • KIM, M.-H., PETTERSEN, J. & BULLARD, C. W. 2004. Fundamental process and system design issues in CO2 vapor compression systems. Progress in Energy and Combustion Science, 30, 119-174.
  • KIM, S. C., KIM, M. S., HWANG, I. C. & LIM, T. W. 2007. Heating performance enhancement of a CO2 heat pump system recovering stack exhaust thermal energy in fuel cell vehicles. International Journal of Refrigeration, 30, 1215-1226.
  • KIM, S. G., KIM, Y. J., LEE, G. & KIM, M. S. 2005. The performance of a transcritical CO2 cycle with an internal heat exchanger for hot water heating. International Journal of Refrigeration, 28, 1064-1072.
  • LORENTZEN, G. 1994. Revival of carbon dioxide as a refrigerant. International Journal of Refrigeration, 17, 292-301. MOLINA, M. J. & ROWLAND, F. S. 1974. Stratospheric sink for chlorofluoromethanes: chlorine atomc-atalysed destruction of ozone. Nature, 249, 810-812.
  • NEKSÅ, P. 2002. CO2 heat pump systems. International Journal of Refrigeration, 25, 421-427.
  • NEKSÅ, P., REKSTAD, H., ZAKERI, G. R. & SCHIEFLOE, P. A. 1998. CO2-heat pump water heater: characteristics, system design and experimental results. International Journal of Refrigeration, 21, 172-179.
  • REULENS, W. 2009. Natural Refrigerant CO2. Diepenbeek: Katholieke Hogeschool Limburg.
  • RIEBERER, R. 1998. CO2 as working fluid for heat pumps. Doctor of Technology, Graz University of Technology.
  • SARKAR, J. 2005. Transcritical Carbon Dioxide Heat Pumps for Simultaneous Cooling and Heating. Doctor of Philosophy, Indian Institute of Technology.
  • SARKAR, J., BHATTACHARYYA, S. & GOPAL, M. R. 2004. Optimization of a transcritical CO2 heat pump cycle for simultaneous cooling and heating applications. International Journal of Refrigeration, 27, 830-838.
  • SARKAR, J., BHATTACHARYYA, S. & RAM GOPAL, M. 2007. Natural refrigerant-based subcritical and transcritical cycles for high temperature heating. International Journal of Refrigeration, 30, 3-10.
  • SARKAR, J., BHATTACHARYYA, S. & RAM GOPAL, M. 2009. Irreversibility minimization of heat exchangers for transcritical CO2 systems. International Journal of Thermal Sciences, 48, 146-153.
  • SARKAR, J., BHATTACHARYYA, S. & RAMGOPAL, M. 2010. Performance of a Transcritical CO2 Heat Pump for Simultaneous Water Cooling and Heating. International Journal of Applied Science, Engineering and Technology, 6, 57-63.
  • SAWALHA, S. 2008. Carbon Dioxide in Supermarket Refrigeration. Doctoral, Royal Institute of Technology.
  • SKAUGEN, G. 2002. Investigation of transcritical CO2 vapour compression systems by simulation and laboratory experiments. Doctor of Engineering Doctorate, Norwegian University of Science and Technology.
  • STAT-EASE INC. 2002. Design-Expert 6.0.6 ed. Minneapolis, Minessota: Stat-Ease Inc.
  • STENE, J. 2004. Residential CO2 Heat Pump System for Combined Space Heating and Hot Water Heating. Doctoral Degree, Norwegian University of Science and Technology.
  • STENE, J. 2007. Integrated CO2 Heat Pump Systems for Space Heating and Hot Water Heating in Low-Energy Houses and Passive Houses. International Energy Agency (IEA) Heat Pump Programme
  • International Energy Agency.
  • UNITED NATIONS 1987. Montreal Protocol on Substances that Deplete the Ozone Layer Montreal United Nations.
  • UNITED NATIONS 1998. Kyoto protocol to the united nations framework Convention on climate change. Kyoto.
  • UNITED NATIONS ENVIRONMENT PROGRAMME 2007. UNEP 2006 Report Of The Technology and Economic Assessment Panel. In: KUIJPERS, L. (ed.) Montreal Protocol On Substances that Deplete the Ozone Layer. Nairobi: UNEP
  • WANG, J., SUN, Z., DAI, Y. & MA, S. 2010. Parametric optimization design for supercritical CO2 power cycle using genetic algorithm and artificial neural network. Applied Energy, 87, 1317-1324.
  • WANG, S. K. 2000. Handbook of Air Conditioning and Refrigeration, New York, McGraw-HiII.

Effects of various parameters on the efficiency of a CO2 heat pump: a statistical approach

Year 2015, Volume: 1 Issue: 4, 236 - 278, 01.04.2015
https://doi.org/10.18186/thermal.228874

Abstract

References

  • ADRIANSYAH, W. 2001. Combined air conditioning and tap water heating plant using CO2 as refrigerant for Indonesian climate condition. Doctor of Engineering Doctorate, Norwegian University of Science and Technology.
  • AGRAWAL, N. & BHATTACHARYYA, S. 2008. Performance evaluation of a non-adiabatic capillary tube in a transcritical CO2 heat pump cycle. International Journal of Thermal Sciences, 47, 423-430.
  • AGRAWAL, N. & BHATTACHARYYA, S. 2009. Exergy assessment of an optimized capillary tube-based transcritical CO2 heat pump system. International Journal of Energy Research, 33, 1278-1289.
  • ATIK, K. & AKTAŞ, A. 2011. An experimental investigation of the effect of refrigerant charge level on an automotive air conditioning system. Journal of Thermal Science and Technology, 31, 11-17.
  • BENSAFI, A. & THONON, B. 2007. Transcritical R744 (CO2) heat pumps. Technician's Manual. Villeurbanne Cedex - France: Centre Technique Des Industries Aérauliques Et Thermiques.
  • BHATIA, A. RE: Selection Tips for Environmentally Safe Refrigerants. Type to CONTINUING EDUCATION AND DEVELOPMENT, I.
  • CALM, J. M. 2008. The next generation of refrigerants – Historical review, considerations, and outlook. International Journal of Refrigeration, 31, 1123-1133.
  • CALM, J. M. & DIDION, D. A. 1998. Trade-offs in refrigerant selections: past, present, and future. International Journal of Refrigeration, 21, 308-321.
  • CHEN, Y., LUNDQVIST, P. & WORKIE, A. B. Second Law Analysis of a Carbon Dioxide Transcritical Power System in Low-grade Heat Source Recovery.
  • CHO, H., RYU, C. & KIM, Y. 2007. Cooling performance of a variable speed CO2 cycle with an electronic expansion valve and internal heat exchanger. International Journal of Refrigeration, 30, 664-671.
  • CHO, H., RYU, C., KIM, Y. & KIM, H. Y. 2005. Effects of refrigerant charge amount on the performance of a transcritical CO2 heat pump. International Journal of Refrigeration, 28, 1266-1273.
  • CHRISTENSEN, Ø. 2009. Reversible R744 (CO2) heat pumps applied in public trains in Norway. Master of Science in Energy and Environment, Norwegian University of Science and Technology.
  • DIPIPPO, R. 2004. Second Law assessment of binary plants generating power from low-temperature geothermal fluids. Geothermics, 33, 565-586.
  • DUDDUMPUDI, V. S. 2010. Transcritical CO2 Air Source Heat Pump for Average UK Domestic Housing with High Temperature Hydronic Heat Distribution System. Master of Science, University of Strathclyde.
  • FERNANDEZ, N., HWANG, Y. & RADERMACHER, R. 2010. Comparison of CO2 heat pump water heater performance with baseline cycle and two high COP cycles. International Journal of Refrigeration, 33, 635-644.
  • FRONK, B. M. 2007. Modeling and Testing of Water-Coupled Microchannel Gas Coolers for Natural Refrigerant Heat Pumps. Master of Science, Georgia Institute of Technology.
  • FRONK, B. M. & GARIMELLA, S. 2011. Water-coupled carbon dioxide microchannel gas cooler for heat pump water heaters: Part II – Model development and validation. International Journal of Refrigeration, 34, 17-28.
  • GUPTA, D. K. & DASGUPTA, M. S. 2014. Simulation and performance optimization of finned tube gas cooler for trans- critical CO2 refrigeration system in Indian context. International Journal of Refrigeration, 38, 153-167.
  • HASHIMOTO, K. 2006. Technology and Market Development of CO2 Heat Pump Water Heaters (ECO CUTE) in Japan. Topical article. Japan: IEA Heat Pump Centre Newsletter.
  • HWANG, Y. & RADERMACHER, R. 1998. Theoretical Evaluation of Carbon Dioxide Refrigeration Cycle. HVAC&R Research, 4, 245-263.
  • JIANG, P.-X., ZHAO, C.-R., SHI, R.-F., CHEN, Y. & AMBROSINI, W. 2009. Experimental and numerical study of convection heat transfer of CO2 at super-critical pressures during cooling in small vertical tube. International Journal of Heat and Mass Transfer, 52, 4748-4756.
  • KIM, M.-H., PETTERSEN, J. & BULLARD, C. W. 2004. Fundamental process and system design issues in CO2 vapor compression systems. Progress in Energy and Combustion Science, 30, 119-174.
  • KIM, S. C., KIM, M. S., HWANG, I. C. & LIM, T. W. 2007. Heating performance enhancement of a CO2 heat pump system recovering stack exhaust thermal energy in fuel cell vehicles. International Journal of Refrigeration, 30, 1215-1226.
  • KIM, S. G., KIM, Y. J., LEE, G. & KIM, M. S. 2005. The performance of a transcritical CO2 cycle with an internal heat exchanger for hot water heating. International Journal of Refrigeration, 28, 1064-1072.
  • LORENTZEN, G. 1994. Revival of carbon dioxide as a refrigerant. International Journal of Refrigeration, 17, 292-301. MOLINA, M. J. & ROWLAND, F. S. 1974. Stratospheric sink for chlorofluoromethanes: chlorine atomc-atalysed destruction of ozone. Nature, 249, 810-812.
  • NEKSÅ, P. 2002. CO2 heat pump systems. International Journal of Refrigeration, 25, 421-427.
  • NEKSÅ, P., REKSTAD, H., ZAKERI, G. R. & SCHIEFLOE, P. A. 1998. CO2-heat pump water heater: characteristics, system design and experimental results. International Journal of Refrigeration, 21, 172-179.
  • REULENS, W. 2009. Natural Refrigerant CO2. Diepenbeek: Katholieke Hogeschool Limburg.
  • RIEBERER, R. 1998. CO2 as working fluid for heat pumps. Doctor of Technology, Graz University of Technology.
  • SARKAR, J. 2005. Transcritical Carbon Dioxide Heat Pumps for Simultaneous Cooling and Heating. Doctor of Philosophy, Indian Institute of Technology.
  • SARKAR, J., BHATTACHARYYA, S. & GOPAL, M. R. 2004. Optimization of a transcritical CO2 heat pump cycle for simultaneous cooling and heating applications. International Journal of Refrigeration, 27, 830-838.
  • SARKAR, J., BHATTACHARYYA, S. & RAM GOPAL, M. 2007. Natural refrigerant-based subcritical and transcritical cycles for high temperature heating. International Journal of Refrigeration, 30, 3-10.
  • SARKAR, J., BHATTACHARYYA, S. & RAM GOPAL, M. 2009. Irreversibility minimization of heat exchangers for transcritical CO2 systems. International Journal of Thermal Sciences, 48, 146-153.
  • SARKAR, J., BHATTACHARYYA, S. & RAMGOPAL, M. 2010. Performance of a Transcritical CO2 Heat Pump for Simultaneous Water Cooling and Heating. International Journal of Applied Science, Engineering and Technology, 6, 57-63.
  • SAWALHA, S. 2008. Carbon Dioxide in Supermarket Refrigeration. Doctoral, Royal Institute of Technology.
  • SKAUGEN, G. 2002. Investigation of transcritical CO2 vapour compression systems by simulation and laboratory experiments. Doctor of Engineering Doctorate, Norwegian University of Science and Technology.
  • STAT-EASE INC. 2002. Design-Expert 6.0.6 ed. Minneapolis, Minessota: Stat-Ease Inc.
  • STENE, J. 2004. Residential CO2 Heat Pump System for Combined Space Heating and Hot Water Heating. Doctoral Degree, Norwegian University of Science and Technology.
  • STENE, J. 2007. Integrated CO2 Heat Pump Systems for Space Heating and Hot Water Heating in Low-Energy Houses and Passive Houses. International Energy Agency (IEA) Heat Pump Programme
  • International Energy Agency.
  • UNITED NATIONS 1987. Montreal Protocol on Substances that Deplete the Ozone Layer Montreal United Nations.
  • UNITED NATIONS 1998. Kyoto protocol to the united nations framework Convention on climate change. Kyoto.
  • UNITED NATIONS ENVIRONMENT PROGRAMME 2007. UNEP 2006 Report Of The Technology and Economic Assessment Panel. In: KUIJPERS, L. (ed.) Montreal Protocol On Substances that Deplete the Ozone Layer. Nairobi: UNEP
  • WANG, J., SUN, Z., DAI, Y. & MA, S. 2010. Parametric optimization design for supercritical CO2 power cycle using genetic algorithm and artificial neural network. Applied Energy, 87, 1317-1324.
  • WANG, S. K. 2000. Handbook of Air Conditioning and Refrigeration, New York, McGraw-HiII.
There are 45 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Paul Maina This is me

Zongjie Huan This is me

Publication Date April 1, 2015
Submission Date May 14, 2015
Published in Issue Year 2015 Volume: 1 Issue: 4

Cite

APA Maina, P., & Huan, Z. (2015). Effects of various parameters on the efficiency of a CO2 heat pump: a statistical approach. Journal of Thermal Engineering, 1(4), 236-278. https://doi.org/10.18186/thermal.228874
AMA Maina P, Huan Z. Effects of various parameters on the efficiency of a CO2 heat pump: a statistical approach. Journal of Thermal Engineering. April 2015;1(4):236-278. doi:10.18186/thermal.228874
Chicago Maina, Paul, and Zongjie Huan. “Effects of Various Parameters on the Efficiency of a CO2 Heat Pump: A Statistical Approach”. Journal of Thermal Engineering 1, no. 4 (April 2015): 236-78. https://doi.org/10.18186/thermal.228874.
EndNote Maina P, Huan Z (April 1, 2015) Effects of various parameters on the efficiency of a CO2 heat pump: a statistical approach. Journal of Thermal Engineering 1 4 236–278.
IEEE P. Maina and Z. Huan, “Effects of various parameters on the efficiency of a CO2 heat pump: a statistical approach”, Journal of Thermal Engineering, vol. 1, no. 4, pp. 236–278, 2015, doi: 10.18186/thermal.228874.
ISNAD Maina, Paul - Huan, Zongjie. “Effects of Various Parameters on the Efficiency of a CO2 Heat Pump: A Statistical Approach”. Journal of Thermal Engineering 1/4 (April 2015), 236-278. https://doi.org/10.18186/thermal.228874.
JAMA Maina P, Huan Z. Effects of various parameters on the efficiency of a CO2 heat pump: a statistical approach. Journal of Thermal Engineering. 2015;1:236–278.
MLA Maina, Paul and Zongjie Huan. “Effects of Various Parameters on the Efficiency of a CO2 Heat Pump: A Statistical Approach”. Journal of Thermal Engineering, vol. 1, no. 4, 2015, pp. 236-78, doi:10.18186/thermal.228874.
Vancouver Maina P, Huan Z. Effects of various parameters on the efficiency of a CO2 heat pump: a statistical approach. Journal of Thermal Engineering. 2015;1(4):236-78.

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