Advanced search
Publication Cover
Science and Technology for the Built Environment Volume 29, 2023 - Issue 3
Submit an article Journal homepage
631
Views
0
CrossRef citations to date
0
Altmetric
Articles

Prediction of pressure drop from multivariate polynomial regression for membrane-based air-to-air energy recovery ventilator cores

Hae-Eun Song1 School of Architectural Engineering, Pusan National University, Busan, 46241, KoreaView further author information
,
Yul-Ho Kang2 Research Institute for Future Wind Energy Technology, Pusan National University, Busan, 46241, KoreaView further author information
,
Su-Kwang Yang1 School of Architectural Engineering, Pusan National University, Busan, 46241, KoreaView further author information
&
Young-chull Ahn1 School of Architectural Engineering, Pusan National University, Busan, 46241, KoreaCorrespondence[email protected]
View further author information
Pages 339-346 | Received 08 Jun 2022, Accepted 20 Jan 2023, Published online: 10 Feb 2023

References

  • Armatis, P. D., and B. M. Fronk. 2017. Evaluation of governing heat and mass transfer resistance in membrane-based energy recovery ventilators with internal support structures. Science and Technology for the Built Environment 23 (6):912–22. doi:10.1080/23744731.2017.1325705.
  • Bearg, D. W. 1993. Indoor air quality and HVAC systems. Florida: Lewis Publishers.
  • Busto, J. B., C. M. Gómez, A. Z. Ros, E. Baquero, and R. Mirand. 2017. Performance simulation of heat recovery ventilator cores in cascade connection. Energy and Buildings 134:25–36.
  • Cho, M., S. Oh, and Y. Ahn. 2017. Heat transfer and sterilization characteristics of an ERV element made of Hwang-to paper. Journal of the Korean Society for Power System Engineering 21 (1):50–6.
  • Connor, D., J. Kaiser, S. Calautit, and B. R. Hughes. 2016. A review of heat recovery technology for passive ventilation applications. Renewable and Sustainable Energy Reviews 54:1481–93.
  • Cui, C., X. Zhang, W. Cai, and G. Jing. 2018. A novel online air balancing method for the ventilation duct system via distributed cooperative control. Building and Environment 146:177–89.
  • Daisey, J. M., W. J. Angell, and M. G. Apte. 2003. Indoor air quality, ventilation and health symptoms in schools: An analysis of existing information. Indoor air 13 (1):53–64.
  • Drost, M. K. 1993. Air-to-air heat exchanger performance. Energy and Buildings 19:215–20.
  • Engarnevis, A., R. Huizing, S. Green, and S. Rogak. 2018. Heat and mass transfer modeling in enthalpy exchangers using asymmetric composite membranes. Journal of Membrane Science 556:248–62.
  • Farrance, I., and R. Frenkel. 2012. Uncertainty of measurement: A review of the rules for calculating uncertainty components through functional relationships. The Clinical Biochemist. Reviews 33 (2):49–75.
  • Fisk, W., and I. Turiel. 1983. Residential air-to-air heat exchangers: Performance energy savings, and economics. Energy & Buildings 5 (3):197–211.
  • Gao, H., Z. Li, S. Qiu, B. Yang, S. Li, and Y. Wen. 2021. Energy exchange efficiency prediction from non-linear regression for membrane-based energy-recovery ventilator cores. Applied Thermal Engineering 197:117353.
  • Huizing, R., H. Chen, and F. Wong. 2015. Contaminant transport in membrane based energy recovery ventilators. Science and Technology for the Built Environment 21 (1):54–66.
  • Jan, K., P. Curtiss, and A. Rabl. 2002. Heating and cooling of buildings: Design for efficiency. New York: McGraw-Hill.
  • Kalbasi, R., B. Ruhani, and S. Rostami. 2019. Energetic analysis of an air handling unit combined with enthalpy air‑to‑air heat exchanger. Journal of Thermal Analysis and Calorimetry 139 (2):1–10.
  • Ke, Z., and K. Yanming. 2009. Applicability of air-to-air heat recovery ventilators in China. Applied Thermal Engineering 29 (5–6):830–40.
  • Kim, C. H., and N. Kim. 2018. An experimental study on heat and mass transfer in diagonal flow enthalpy exchangers. Korean Journal of Air-Conditioning and Refrigeration Engineering 30 (6):258–65.
  • Kim, N. 2016. Performance comparison between indirect evaporative cooler and regenerative evaporative cooler made of plastic/paper. Journal of the Korea Academia-Industrial Cooperation Society 17 (1):88–98.
  • Kwak, K., and C. Bai. 2009. A study on performance improvement of corrugated type total heat exchanger considering the structure of flow passage on surface. Journal of Mechanical Science and Technology 23:1528–35.
  • Kwak, K., C. Bai, J. Kim, and E. Chu. 2007. A study on improvement of performance for perforated type total HEX element. Korean Journal of Air-Conditioning and Refrigeration Engineering 19 (7):529–36.
  • Lee, E., J. Lee, H. Sim, and N. Kim. 2012. Modeling and verification of heat and moisture transfer in an enthalpy exchanger made of paper membrane. International Journal of Air-Conditioning and Refrigeration 20 (3):1–13.
  • Lekshminarayanan, G., M. Croal, and J. Maisonneuve. 2020. Recovering latent and sensible energy from building exhaust with membrane-based energy recovery ventilation. Science and Technology for the Built Environment 26 (7):1000–12. doi:10.1080/23744731.2020.1761712.
  • Lim, T., B. Jeon, J. Kim, S. Jung, S. Lee, and Y. Ahn. 2012. A study on performance change of total heat exchanger according to material change of spacer. The Korean Journal of Air-Conditioning and Refrigeration Engineering 24 (3):224–9.
  • Mansur, F. Z., N. A. Keling, J. H. Ang, A. Salehabadi, S. Riffat, Y. Yusup, and M. I. Ahmad. 2021. Thermal performance of a fixed-plate air-to-air energy recovery system for building application in hot and humid environment. International Journal of Energy Research 45 (6):8900–18.
  • Masitah, A., M. I. Ahmad, and Y. M. Yatim. 2015. Heat transfer and effectiveness analysis of a cross-flow heat exchanger for potential energy recovery applications in hot-humid climate. Energy Research Journal 6 (1):7–14.
  • Min, J., and J. Duan. 2016. Comparison of various methods for evaluating the membrane-type total heat exchanger performance. International Journal of Heat and Mass Transfer 100:758–66.
  • Min, J., and M. Su. 2010. Performance analysis of a membrane-based energy recovery ventilator Effects of membrane spacing and thickness on the ventilator performance. Applied Thermal Engineering 30 (8–9):991–7.
  • Papakostas, K. T., and G. C. Kiosis. 2015. Heat recovery in an air-conditioning system with air-to-air heat exchanger. International Journal of Sustainable Energy 34 (3–4):221–31. doi:10.1080/14786451.2013.879139.
  • Qiu, S., S. Li, F. Wang, Y. Wen, Z. Li, Z. Li, and J. Guo. 2019. An energy exchange efficiency prediction approach based on multivariate polynomial regression for membrane-based air-to-air energy recovery ventilator core. Building and Environment 149:490–500.
  • Siegele, D. 2019. Measurement data of an air-to-air membrane enthalpy and a heat exchanger. Data Brief 26:104453.
  • Siegele, D., and F. Ochs. 2019. Effectiveness of a membrane enthalpy heat exchanger. Applied Thermal Engineering 160:114005.
  • Souifi, H., Y. Bouslimani, M. Ghribi, and S. Colin. 2021. Experimental investigation and modeling of a dual-core air-to-air exchanger. Energy and Buildings 231:110600.
  • Souifi, H., Y. Bouslimani, M. Ghribi, and S. Colin. 2021. Modeling of an air-to-air exchanger with dual-core in cascade connection. MethodsX 8:101253.
  • Swiercz, Z. E. A. 2021. Review of heat recovery in ventilation. Energies 14:1759.
  • Waked, R. A., M. S. Nasif, G. Morrison, and M. Behnia. 2013. CFD simulation of air to air enthalpy heat exchanger. Energy Conversion and Management 74:377–85.
  • Waked, R. A., M. S. Nasif, G. Morrison, and M. Behnia. 2015. CFD simulation of air to air enthalpy heat exchanger: Variable membrane moisture resistance. Applied Thermal Engineering 84:301–9.
  • Xiana, Z., X. Tang, and H. Mo. 2018. CFD simulation different inner structure of air heat exchanger. In IOP Conference Series: Earth and Environmental Science. Vol. 199: 052032.
  • Zhang, C., J. Xu, T. Ge, Y. Dai, and R. Wang. 2017. A study on enthalpy exchanger with modified functional layers based on chloride. Science and Technology for the Built Environment 23:72–80.
  • Zhang, L. 2012. Progress on heat and moisture recovery with membranes: From fundamentals to engineering applications. Energy Conversion and Management 63:173–95.
  • Zhang, L. 2016. A reliability-based optimization of membrane-type total heat exchangers under uncertain design parameters. Energy 101:390–401.
  • Zhang, Y., Y. Jiang, L. Zhang, Y. Deng, and Z. Jin. 2000. Analysis of thermal performance and energy savings of membrane based heat recovery ventilator. Energy 25 (6):515–27.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.