Journal of Chinese
            Architecture and Urbanism                                                Cooling energy-saving mechanism



               Padilla-Marcos, M. A., & Meiss, A. (2019). Airtightness   adaptability of exterior envelopes of university teaching-
               of residential buildings in the continental area of Spain.   office buildings under different climates (China) based on
               Building and Environment, 148:299-308.             orthogonal design and EnergyPlus. Heliyon, 8(8):e10056.
            Feng, J. M., Lian, Z. W., Huang, S. B., & Ye, M. J. (2010). The      https://doi.org/10.1016/j.heliyon.2022.e10056
               influence of heat transmission coefficient of office building   Long, E. S. (2005a).  Research on Building Energy Gene Theory
               on air-conditioning load.  Sichuan Building Science,   [Dissertation, Chongqing University].
               36(3):312-315.
                                                               Long, E. S. (2005b). Identifications: The relative variation rates
            Ghahramani, A., Jazizadeh, F., & Becerik-Gerber, B. (2014).   (RVRs) of cooling and heating are approximately the same in
               A  knowledge based approach for selecting energy-aware   different cities with the same increase of shape coefficients.
               and comfort-driven HVAC temperature set points. Energy   Building and Environment, 40:481-488.
               and Buildings, 85:536-548.
                                                               Ministry of Housing and Urban-Rural. (2012). Code for Design of
            Ghahramani, A., Zhang, K. N., Dutta, K., Yang, Z., & Becerik-  Heating, Ventilation and Air Conditioning for Civil Buildings
               Gerber, B. (2016). Energy savings from temperature   GB 50736-2012. Peking: China Building Industry Press.
               setpoints and deadband: Quantifying the influence of
               building and system properties on savings. Applied Energy,   Natephra, W., Yabuki, N., & Fukuda, T. (2018). Optimizing
               165:930-942.                                       the evaluation of building envelope design for thermal
                                                                  performance using a BIM-based overall thermal transfer
            Guo, S. R., Yang, H. Y., Li, Y. R., Zhang, Y., & Long, E. S. (2019).
               Energy saving effect and mechanism of cooling setting   value calculation. Building and Environment, 136:128-145.
               temperature increased by 1 °C for residential buildings in   Office of Energy Efficiency & Renewable Energy, US Department
               different cities. Energy and Buildings, 202:109335.  of Energy. Available from: https://www.energy.gov/eere/
                                                                  office-energy-efficiency-renewable-energy [Last accessed
            Hoyt,  T.,  Arens,  E.,  &  Zhang,  H.  (2015).  Extending  air
               temperature setpoints: Simulated energy savings and design   on 2022 Jan 01].
               considerations for new and retrofit buildings. Building and   Papadopoulos, S., Kontokosta, C. E., Vlachokostas, A., &
               Environment, 88:89-96.                             Azar, E. (2019). Rethinking HVAC temperature setpoints
                                                                  in commercial buildings: The potential for zero-cost energy
            Jin, Z. N., Zheng, Y. H., & Zhang, Y. (2023). A  novel method
               for building air conditioning energy saving potential pre-  savings and comfort improvement in different climates.
               estimation based on thermodynamic perfection index for   Building and Environment, 155:350-359.
               space cooling.  Journal of Asian Architecture and Building   Qi, X. Y., Zhang, Y., & Jin, Z. N. (2023). Building energy efficiency
               Engineering, 22(4):2348-2364.                      for indoor heating temperature set-point: mechanism and
                                                                  case study of mid-rise apartment. Buildings, 13(5):1189.
            Lakeridou, M., Ucci, M., Marmot, A., & Ridley, I. (2012). The
               potential of increasing cooling set-points in air-conditioned   Qian, S. R., Guo, S. R., Zhao, Y., Cheng, Z., & Long, E. S.
               offices in the UK. Applied Energy, 94:338-348.      (2022). Mechanism and influence of different colors of
                                                                  opaque outdoor surfaces on cooling demand of malls.
            Li, Y. L., Han, M. Y., Liu, S. Y., & Chen, G. Q. (2019). Energy
               consumption and  greenhouse gas  emissions  by  buildings:   Journal of Asian Architecture and Building Engineering,
               A  multi-scale perspective.  Building and Environment,   21(6):2545-2563.
               151:240-250.                                    Thomas, A., Menassa, C. C., & Kamat, V. R. (2018). A systems
                                                                  simulation framework to realize net-zero building energy
            Liao, W., Wen, C. F., Luo, Y. M., Peng, J. Q., & Li, N. P. (2022).
               Influence of different building transparent envelopes on   retrofits. Sustainable Cities and Society, 41:405-420.
               energy consumption and thermal environment of radiant      https://doi.org/10.1016/j.scs.2018.05.045
               ceiling heating and cooling systems. Energy and Buildings,   Yu, Z. (2017). The Difference Research on International Building
               255:111702.
                                                                  Energy Consumption and Influencing Factors. Chongqing:
            Liu, Z. A., Hou, J. W., Zhang, L. L., Dewancker, B. J., Meng, X.,   School of Construction Management and  Real Estate of
               &  Hou, C.  P.  (2022).  Research  on  energy-saving  factors   Chongqing University.
















            Volume 5 Issue 2 (2023)                         14                       https://doi.org/10.36922/jcau.0877