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Science and Technology for the Built Environment Volume 21, 2015 - Issue 7
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Topical Section: Variable Refrigerant Flow Systems

A review of recent development in variable refrigerant flow systems

Xiaojie LinCenter for Environmental Energy Engineering, University of Maryland, 4164 Glenn L. Martin Hall Bldg., College Park, 20742, MD, USA
,
Hoseong LeeCenter for Environmental Energy Engineering, University of Maryland, 4164 Glenn L. Martin Hall Bldg., College Park, 20742, MD, USA
,
Yunho HwangCenter for Environmental Energy Engineering, University of Maryland, 4164 Glenn L. Martin Hall Bldg., College Park, 20742, MD, USACorrespondence[email protected]
&
Reinhard RadermacherCenter for Environmental Energy Engineering, University of Maryland, 4164 Glenn L. Martin Hall Bldg., College Park, 20742, MD, USA
Pages 917-933 | Received 27 Mar 2015, Accepted 16 Jun 2015, Published online: 14 Sep 2015

References

  • ANSI/AHRI. 2010. 2010 Standard for Performance Rating of Variable Refrigerant Flow (VRF) Multi-split Air-conditioning and Heat Pump Equipment, Arlington, VA: AHRI
  • Aynur, T., Y. Hwang, and R. Radermacher. 2008. Simulation evaluation of the ventilation effect on the performance of a VRV system in cooling mode—Part II, simulation evaluation. Science and Technology for the Built Environment 14(5):783–95.
  • Aynur, T.N. 2010. Variable refrigerant flow systems: A review. Energy and Buildings 42(7):1106–12.
  • Cheung, H., and J.E. Braun. 2014. Component-based, gray-box modeling of ductless multi-split heat pump systems. International Journal of Refrigeration 38:30–45.
  • Elliott, M.S., C. Estrada, and B.P. Rasmussen. 2011. Cascaded superheat control with a multiple evaporator refrigeration system. Proceedings of the 2011 American Control Conference, San Francisco, CA, June 29 - July 1, 2011, pp. 2065–70.
  • Elliott, M.S., and B.P. Rasmussen. 2009. A model-based predictive supervisory controller for multi-evaporator HVAC systems. 2009 American Control Conference, St. Louis, MO, June 10-12, 2009, pp. 3669–74.
  • Elliott, M.S., and B.P. Rasmussen. 2013. Decentralized model predictive control of a multi-evaporator air conditioning system. Control Engineering Practice 21(12):1665–77.
  • Fujimoto, I., K. Takemura, K. Ueno, K. Saito, and K. Ohno. 2011a. Performance evaluation of VRF systems using refrigerant enthalpy method. International Congress of Refrigeration, Prague, August 21–26, 2011.
  • Fujimoto, I., K. Ueno, K. Saito, K. Ohno, H. Murata, and H. Nakamura. 2011b. Performance evaluation of VRF systems. International Congress of Refrigeration, Prague, August 21–26, 2011.
  • Gordon, B.W., S. Liu, and H.H. Asada. 1999. Dynamic modeling of multiple-zone vapor compression cycies using variable order representations. Proceedings of the 1999 American Control Conference, San Diego, CA, June 2–4, 1999, pp. 3765–9.
  • He, X. 1996. Dynamic modeling and multivariable control of vapor compression cycles in air conditioning systems. PhD, Massachusetts Institute of Technology, Boston, MA.
  • He, X., and H.H. Asada. 2003. A new feedback linearization approach to advanced control of multi-unit HVAC systems. Proceedings of the 2003 American Control Conference 3:2311–6.
  • He, X., S. Liu, and H.H. Asada. 1997. Modeling of vapor compression cycles for multivariable feedback control of HVAC systems. Journal of Dynamic Systems, Measurement, and Control 14:183–90.
  • He, X.D., S. Liu, H. Asada, and H. Itoh. 1998. Multivariable control of vapor compression systems. Science and Technology for the Built Environment 4(3):205–30.
  • Hong, T. 2014. A new model to simulate energy performance of VRF systems. ASHRAE Summer Conference, Seattle, WA, June 29–July 2, 2014.
  • Jiang, Y., T. Ge, and R. Wang. 2013. Performance simulation of a joint solid desiccant heat pump and variable refrigerant flow air conditioning system in EnergyPlus. Energy and Buildings 65:220–30.
  • Jiang, Y., T. Ge, and R. Wang. 2014a. Comparison study of a novel solid desiccant heat pump system with EnergyPlus. Building Simulation 7(5):467–76.
  • Jiang, Y., T.S. Ge, R.Z. Wang, and Y. Huang. 2014b. Experimental investigation on a novel temperature and humidity independent control air conditioning system—Part I: Cooling condition. Applied Thermal Engineering 73(1):782–91.
  • Jiang, Y., T.S. Ge, R.Z. Wang, and Y. Huang. 2014c. Experimental investigation on a novel temperature and humidity independent control air conditioning system—Part II: Heating condition. Applied Thermal Engineering 73(1):773–81.
  • Joo, Y., H. Kang, J.H. Ahn, M. Lee, and Y. Kim. 2011. Performance characteristics of a simultaneous cooling and heating multi-heat pump at partial load conditions. International Journal of Refrigeration 34(4):893–901.
  • Kang, H., Y. Joo, H. Chung, Y. Kim, and J. Choi. 2009. Experimental study on the performance of a simultaneous heating and cooling multi-heat pump with the variation of operation mode. International Journal of Refrigeration 32(6):1452–9.
  • Karunakaran, R., S. Iniyan, and R. Goic. 2010. Energy efficient fuzzy based combined variable refrigerant volume and variable air volume air conditioning system for buildings. Applied Energy 87(4):1158–75.
  • Kim, H.S., and M.K. Cho. 2012. Experimental study on fault detection algorithm using regression method for plural indoor units faults of multi-heat pump system under heating mode. International Refrigeration and Air Conditioning Conference, West Lafayette, IN, July 16–19, 2012.
  • Kwon, L. 2013. Experimental evaluation of a multifunctional variable refrigerant flow system in an educational office building. MS, University of Maryland, College Park, MD.
  • Kwon, L., Y. Hwang, and R. Radermacher. 2012a. Field performance measurements of VRF system with subcooling heat exchanger. International Refrigeration and Air Conditioning Conference, West Lafayette, IN, July 16–19, 2012.
  • Kwon, L., Y. Hwang, R. Radermacher, and B. Kim. 2012b. Field performance measurements of a VRF system with sub-cooler in educational offices for the cooling season. Energy & Buildings 49:300–5.
  • Kwon, L., H. Lee, Y. Hwang, R. Radermacher, and B. Kim. 2014. Experimental investigation of multifunctional VRF system in heating and shoulder seasons. Applied Thermal Engineering 66(1–2):355–64.
  • Li, C., Y. Li, W. Cai, Y. Hu, H. Chen, and J. Yan. 2014. Analysis on performance characteristics of ejector with variable area-ratio for multi-evaporator refrigeration system based on experimental data. Applied Thermal Engineering 68(1–2):125–32.
  • Li, Y.M., and J.Y. Wu. 2010. Energy simulation and analysis of the heat recovery variable refrigerant flow system in winter. Energy and Buildings 42(7):1093–9.
  • Li, Y.M., J.Y. Wu, and S. Shiochi. 2010. Experimental validation of the simulation module of the water-cooled variable refrigerant flow system under cooling operation. Applied Energy 87(5):1513–21.
  • Lin, C., W. Cai, Y. Li, J. Yan, and Y. Hu. 2012a. Pressure recovery ratio in a variable cooling loads ejector-based multi-evaporator refrigeration system. Energy 44(1):649–56.
  • Lin, C., W. Cai, Y. Li, J. Yan, and Y. Hu. 2012b. The characteristics of pressure recovery in an adjustable ejector multi-evaporator refrigeration system. Energy, 46 (1), 148–155.
  • Lin, C., W. Cai, Y. Li, J. Yan, Y. Hu, and K. Giridharan. 2013a. Numerical investigation of geometry parameters for pressure recovery of an adjustable ejector in multi-evaporator refrigeration system. Applied Thermal Engineering 61(2):649–56.
  • Lin, C., Y. Li, W. Cai, J. Yan, and Y. Hu. 2013b. Experimental investigation of the adjustable ejector in a multi-evaporator refrigeration system. Applied Thermal Engineering 61(2):2–10.
  • Lin, J.-L., and T.-J. Yeh. 2007. Identification and control of multi-evaporator air-conditioning systems. International Journal of Refrigeration 30(8):1374–85.
  • Lin, J.-L., and T.-J. Yeh. 2009. Control of multi-evaporator air-conditioning systems for flow distribution. Energy Conversion and Management 50(6):1529–41.
  • Lin, X., H. Lee, Y. Hwang, R. Radermacher, and S. Oh. 2014. Experimental investigation of multi-functional variable refrigerant flow system. International Refrigeration and Air Conditioning Conference, West Lafayette, IN, July 14–17, 2014.
  • Ling, J., O. Kuwabara, Y. Hwang, and R. Radermacher. 2011. Experimental evaluation and performance enhancement prediction of desiccant assisted separate sensible and latent cooling air-conditioning system. International Journal of Refrigeration 34(4):946–57.
  • Liu, X., and T. Hong. 2010. Comparison of energy efficiency between variable refrigerant flow systems and ground source heat pump systems. Energy and Buildings 42(5):584–9.
  • Nigusse, B., and R. Raustad. 2013. Verification of a VRF heat pump computer model in EnergyPlus. In: ASHRAE Annual Conference, Denver, June 22–26, 2013.
  • Pan, Y., X. Xu, L. Xia, and S. Deng. 2012. A modeling study on the effects of refrigerant pipeline length on the operational performance of a dual-evaporator air conditioning system. Applied Thermal Engineering 39:15–25.
  • Parameshwaran, R., R. Karunakaran, C.V.R. Kumar, and S. Iniyan. 2010. Energy conservative building air conditioning system controlled and optimized using fuzzy-genetic algorithm. Energy and Buildings 42(5):745–62.
  • Rasmussen, B.P., and A.G. Alleyne. 2004. Control-oriented modeling of transcritical vapor compression systems. Journal of Dynamic Systems, Measurement, and Control 126(1):54–64.
  • Raustad, R. 2013. A variable refrigerant flow heat pump computer model in EnergyPlus. ASHRAE Transactions 119:299–308.
  • Raustad, R., B. Nigusse, C., Sharma, J. Cummings, R. Domitrovic, and H. Upadhye. 2013. Technical Subtopic 2.1: Modeling Variable Refrigerant Flow Heat Pump and Heat Recovery Equipment in EnergyPlus, Florida Solar Energy Center, FSEC-CR-1968-13.
  • Shah, R., A.G. Alleyne, and C.W. Bullard. 2003. Dynamic Modeling And Control of Single and Multi-Evaporator Subcritical Vapor Compression Systems, Air Conditioning and Refrigeration Center, ACRC TR-216.
  • Shah, R., A.G. Alleyne, and C.W. Bullard. 2004. Dynamic modeling and control of multi-evaporator air-conditioning systems. ASHRAE Transactions 110(1):109–119.
  • Shao, S., H. Xu, and C. Tian. 2012. Dynamic simulation of multi-unit air conditioners based on two-phase fluid network model. Applied Thermal Engineering 40:378–88.
  • Sharma, C., and R. Raustad. 2013. Compare energy use in variable refrigerant flow heat pumps field. ASHRAE Annual Conference, Denver, CO, June 22--26, 2013.
  • Shen, B., and C.K. Rice. 2012. Multiple-zone variable refrigerant flow system modeling and equipment performance mapping. 2012 ASHRAE Winter Conference, Chicago, IL, January 21--25, 2012.
  • Shen, B., C.K. Rice, T.P. Mcdowell, and V.D. Baxter. 2013. Energy simulation of integrated multiple- zone variable refrigerant flow system. 2013 ASHARE Annual Conference, Denver, CO, June 22--26, 2013.
  • Shi, W., S. Shao, and X. Li. 2003. A network model to simulate performance of variable refrigerant volume refrigeration systems. ASHRAE Transactions 109:61--68.
  • Shi, W., and B. Wang. 2010. Performance domain of multiple-split air conditioning system. International Refrigeration and Air Conditioning Conference, West Lafayette, IN, July 12--15, 2010.
  • Shin, Y., S. Woo, and S. Young. 2013. Indoor unit fault detector for a multi-split VRF system in heating mode. International Journal of Refrigeration 40:152–60.
  • Stack, A., and D.P. Finn. 2002. Modeling and validation of a multi-evaporator vapor compression cycle subject to non- uniform loading in transport refrigeration applications. International Refrigeration and Air Conditioning Conference, West Lafayette, IN, July 16--19, 2002.
  • Tu, Q., Z. Feng, S. Mao, K. Dong, R. Xiao, and W. Song. 2010. Heating control strategy for variable refrigerant flow air conditioning system with multi-module outdoor units. Energy Build., 42(11):2021–2027.
  • Tu, Q., K. Dong, D. Zou, and Y. Lin. 2011. Experimental study on multi-split air conditioner with digital scroll compressor. Applied Thermal Engineering 31(14–15):2449–57.
  • Tu, Q., J. Xu, Y. Feng, S. Mao, D. Guo, and J. He. 2012. Determination criterion of defrosting condition for variable refrigerant flow air conditioning system. Energy and Buildings 48:61–70.
  • Wang, S. 2014. Energy modeling of ground source heat pump vs. variable refrigerant flow systems in representative US climate zones. Energy and Buildings 72:222–8.
  • Wu, C., Z. Xingxi, and D. Shiming. 2005. Development of control method and dynamic model for multi-evaporator air conditioners (MEAC). Energy Conversion and Management 46(3):451–65.
  • Xu, X., Y. Pan, S. Deng, L. Xia, and M. Chan. 2013. Experimental study of a novel capacity control algorithm for a multi-evaporator air conditioning system. Applied Thermal Engineering 50(1):975–84.
  • Zhang, D., X. Zhang, and N. Cai, 2014. Study on energy saving possibility of digital variable multiple air conditioning system in three office buildings in Shanghai. Energy and Buildings 75:23–8.
  • Zhang, D., X. Zhang, and J. Liu. 2011. Experimental study of performance of digital variable multiple air conditioning system under part load conditions. Energy and Buildings 43(6):1175–78.
  • Zhou, Y., J. Wu, R. Wang, and S. Shiochi. 2006. Module development and simulation of the variable refrigerant flow air conditioning system under cooling conditions in EnergyPlus. International Conference for Enhanced Building Operations, Shenzhen, November 6--9, 2006.
  • Zhou, Y.P., J.Y. Wu, R.Z. Wang, and S. Shiochi. 2007. Energy simulation in the variable refrigerant flow air-conditioning system under cooling conditions. Energy and Buildings 39(2):212–20.
  • Zhou, Y.P., J.Y. Wu, R.Z. Wang, S. Shiochi, and Y.M. Li. 2008. Simulation and experimental validation of the variable-refrigerant-volume (VRV) air-conditioning system in EnergyPlus. Energy and Buildings 40(6):1041–7.
  • Zhu, Y., X. Jin, Z. Du, B. Fan, and X. Fang. 2014a. Simulation of variable refrigerant flow air conditioning system in heating mode combined with outdoor air processing unit. Energy and Buildings 68:571–9.
  • Zhu, Y., X. Jin, Z. Du, B. Fan, and S. Fu. 2013. Generic simulation model of multi-evaporator variable refrigerant flow air conditioning system for control analysis. International Journal of Refrigeration 36(6):1602–15.
  • Zhu, Y., X. Jin, Z. Du, X. Fang, and B. Fan. 2014b. Control and energy simulation of variable refrigerant flow air conditioning system combined with outdoor air processing unit. Applied Thermal Engineering 64(1–2):385–95.
  • Zhu, Y., X. Jin, X. Fang, and Z. Du. 2014c. Optimal control of combined air conditioning system with variable refrigerant flow and variable air volume for energy saving. International Journal of Refrigeration 42:14–25.

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