- منابع
[1] M. Santamouris, Innovating to Zero the Building Sector in Europe: Minimising the Energy Consumption, Eradication of the Energy Poverty and Mitigating the Local Climate Change, Solar Energy, Vol. 128, pp. 61-94, 2016; Doi: https://doi.org/10.1016/j.solener.2016.01.021.
[2] K. K. W. Wan, D. H. W. Li, W. Pan, and J. C. Lam, Impact of Climate Change on Building Energy Use in Different Climate Zones and Mitigation and Adaptation Implications, Applied Energy, Vol. 97, pp. 274–282, 2012.
[3] E. Solgi, S. Memarian, and G. Nemati Moud, Financial Viability of PCMs in Countries with Low Energy Cost: A Case Study of Different Climates in Iran,
Energy and Buildings, Vol. 173, pp. 128-137, 2018; Doi:
https://doi.org/10.1016/j.enbuild.2018.05.028.
[4] B. Dudley, Statistical Review of World Energy, BP, Statistical Review, 67th Edition, London: UK, 2018.
[5] Sh. Avazalipour Haqiqatparast, Y. Taghizadeh, and H. Zbihi, Designing a Native Pattern in Arid Climate to Reduce Energy Consumption in Housing Sector (Case Study: Yazd), Environmental Science and Technology, Vol. 21 , No.3, pp. 227-236, 2019. (in Persian)
[6] H. Zhang, K. Hewage, H. Karunathilake, H. Feng, and R. Sadiq, Research on Policy Strategies for Implementing Energy Retrofits in the Residential Buildings, Journal of Building Engineering, Vol. 43, p. 103161, 2021.
[7] E. Parliament, Report on the Proposal for a Directive of the European Parliament and of the Council Amending Directive 2010/31/EU on the Energy Performance of Buildings, 2017.
[8] M. Tahsildoost, and Z. S. Zomorodian, Energy Retrofit Techniques: An Experimental Study of Two Typical School Buildings in Tehran,
Energy and Buildings, Vol. 104, pp. 65-72, 2015; Doi:
10.1016/j.enbuild.2015.06.079.
[9] J. Laustsen, Energy Efficiency Requirements in Building Codes, Energy Efficiency Policies for New Buildings, IEA Information Paper, International Energy Agency, OECD/IEA, Communication and Information Office, Paris, 2008.
[10] H. Jang, L. Jones, and J. Kang, Prioritisation of Old Apartment Buildings for Energy-Efficient Refurbishment based on the Effects of Building Features on Energy Consumption in South Korea, Energy and Buildings, Vol. 96, pp. 319-328, 2015.
[11] P. Jie, F. Zhang, Z. Fang, H. Wang, and Y. Zhao, Optimizing the Insulation Thickness of Walls and Roofs of Existing Buildings based on Primary Energy Consumption, Global Cost and Pollutant Emissions, Energy, Vol. 159, pp. 1132-1147, 2018.
[12] A. Ford, Architecture of Modern Schools, (Translators: Mojtabi Dolatkhah and Fateme Taghizadeh). Bakhtar Publishing House, Tehran, 2009. (in Persian)
[13] Technical and Research Office - Green Management Steering Center, and Organization of Renovation, Development and Equipping of the Country's Schools, Guidelines for Green Management in Educational, Training and Sports Spaces, First Edition, Tehran, 2017. (in Persian)
[14] Green Management Steering Center, and Organization of Renovation, Development and Equipping of the Country's Schools, Getting to Know Green School, Tehran, 2018. (in Persian)
[15] Environmental Protection Organization, Charter of Comprehensive Environmental Schools - Theoretical Foundations and Implementation Plan, C, 2015.
[16] B. G. Tasci, Sustainability Education by Sustainable School Design, Procedia - Social and Behavioral Sciences, Vol. 186, pp. 868 – 873, 2015; Doi:10.1016/j.sbspro.2015.04.199.
[17] G. I. Earthman, Planning Education Facilities, USA: Rowman and Littlefield Education, Third Edition, 2009.
[18] X. Shi, Z. Tian, W. Chen, B. Si, and X. Jin, A Review on Building Energy-Efficient Design. Optimization from the Perspective of Architects, Renewable and Sustainable Energy Reviews, pp. 872-884, 2016.
[19] M. Yousefi Tazakor, A. Azam Anhar, and V. Ghorbani, Zero Energy Buildings, Ivan Chaharso Journal, Vol. 2, No. 5, 2019. (in Persian)
[20] B. Edward, Guides to Sustainable Architecture, Second Edition, Translator: Shahroz Tehrani, Iraj, Mehrazan, Tehran, 2009. (in Persian)
[21] M. Joshghani, Cooling and Heating Energy Consumption in School Buildings, New School, Vol. 26, pp. 18-20, 2001. (in Persian)
[22] M. Mahdavinejad, A. Zia, A. N. Larki, S. Ghanavati, and N. Elmi, Dilemma of Green and Pseudo Green Architecture based on LEED Norms in case of Developing Countries, International Journal of Sustainable Built Environment, Vol. 3, No. 2, pp. 235-246, 2014.
[23] F. Heidari, M. Mahdavinejad, and S. H. Sotodeh, Renewable Energy and Smart Hybird Strategies for High Performance Architecture and Planning in case of Tehran, Iran, IOP Conference Series: Earth and Environmental Science, Vol. 159, pp.1-10, 2018; Doi :10.1088/1755-1315/159/1/012030.
[24] F. Habib, Z. Barzegar, and M. Cheshmeh Ghasabani, Prioritization of Effective Building Energy Consumer Parameters by AHP Deployment, Naqshejahan, Vol. 4, No. 2, pp. 47-53, 2014. (in Persian)
[25] F. Babich, G. Torriani, J. Corona, and I. Lara-Ibeas, Comparison of Indoor Air Quality and Thermal Comfort Standards and Variations in Exceedance for School Buildings,
Journal of Building Engineering, Vol. 71, p. 106405, 2023; Doi:
https://doi.org/10.1016/j.jobe.2023.106405.
[26] CA. Erdmann, KC. Steiner, and MG. Apte, Indoor Carbon Dioxide Concentrations and Sick Building Syndrome Symptoms in the Base Study Revisited: Analyses of the 100 Building Dataset, Berkeley: Lawrence Berkeley National Laborator, 2002.
[27] A. Menaam, Environmental Comfort in Urban Open Spaces (Evaluation of Thermal Comfort in Selected Parks in Tehran), Ph.D. Thesis, Faculty of Architecture and Urban Planning, Tehran University of Science and Technology, 2019.
[28] Q. Al-Yasiri, and M. Szabó, Experimental Study of PCM-Enhanced Building Envelope towards Energy-Saving and Decarbonisation in a Severe Hot Climate,
Energy and Buildings, Vol. 279, p. 112680, 2023; Doi:
https://doi.org/10.1016/j.enbuild.2022.112680.
[29] P. O. Akadiri, E. A. Chinyio, and P. O. Olomolaiye, Design of a Sustainable Building: A Conceptual Framework for Implementing Sustainability in the Building Sector, Buildings, Vol. 2, No. 2, pp. 126-152, 2012; Doi:10.3390/Buildings2020126.
[30] A. Nouri Makaram, Optimizing Energy Consumption and Providing Solutions to Save Energy in Buildings, The Second National Conference on Climate, Building and Optimization of Energy Consumption, Esfahan, Iran, pp. 80-86, 2013. (in Persian)
[31] V. Yellamraju, Evaluation and Design of Double Skin Façade for Office Building in Hot Climates, Ms Diss, Texas A&M University, 2004.
[32] M. Valitabar, M. Mahdavinejad, and P. P. Henry Skates, Data-Driven Design of Adaptive Façades: View, Glare, Daylighting, and Energy Efficiency, Architecture in the Age of Disruptive Technologies – Transformation and Challenges Conference, 2021.
[33] P. Bakmohammadi, and E. Noorzai, Optimization of the Design of the Primary School Classrooms in terms of Energy and Daylight Performance Considering Occupants’ Thermal and Visual Comfort, Energy Reports, No. 6, pp. 1590–1607, 2020; Doi: https://doi. org/10.1016/j.egyr.2020.06.008.
[34] A. Senel Solmaz, FH. Halicioglu, and S. Gunhan, An Approach for Making Optimal Decisions in Building Energy Efficiency Retrofit Projects,
Indoor and Built Environment, Vol. 27, No. 3, pp. 348–368, 2018; Doi:
https://doi.org/10.1177/1420326x16674764.
[35] A. Zhang, R. Bokel, A.V. D. Dobbelsteen, Y. Sun, Q. Huang, and Q. Zhang, Optimization of Thermal and Daylight Performance of School Buildings based on a Multi-Objective Genetic Algorithm in the Cold Climate of China, Energy Build, No. 139, pp. 371–384, 2017.
[36] X. Chen, Y. Wang, and H. Yang, Parametric Study of Passive Design Strategies for Highrise Residential Buildings in Hot and Humid Climates: Miscellaneous Impact Factors, Renewable and Sustainable Energy Reviews, Vol. 69, pp. 442-460, 2017.
[37] X. Chen, K. Sun, and H. Yang, A Holistic Passive Design Approach to Optimize Indoor Environmental Quality of a Typical Residential Building in Hong Kong, Energy and Buildings, Vol. 113, pp. 267-281, 2016.
[38] O. Alshamrani, K. Galal, and A. Alkass, Integrated LCA LEED Sustainability Assessment Model for Structure and Envelope Systems of School Buildings,
Building and Environment, Vol. 80, pp. 61-70, 2014; Doi:
https://doi.org/10.1016/j.buildenv.2014.05.021.
[39] L. De Santoli, F. Fraticelli, F. Fornari, and C. Calice, Energy Performance Assessment and a Retrofit Strategy in Public School Buildings in Rome,
Energy and Buildings, Vol. 68, pp. 196-202, 2014; Doi:
https://doi.org/10.1016/j.enbuild.2013.08.028.
[40] Y. Yousefi, S. Yousefi, and Y. Yousefi, Energy Efficiency in Educational Buildings in Iran: Analysis and Measures, in Proceedings of BS2015: 14th Conference of International Building Performance Simulation Association, pp. 169-174, 2015.
[41] P. Keshtkārān, K. Movahed, and Z. Barzegar Marvasti, Retrofitting School Building Envelope in order to Enhance Sustainable School Architecture: Case Study of Shiraz City, Educational Innovations, Vol. 16, No. 2, pp. 7-24, 2017. (in Persian)
[42] M. Madahi, and F. Tavanaiee, Optimization of Thermal Performance of External Walls of Residential Building in Cold and Dry Climate by Utilizing the Energy Simulation Software (A Case Study: Mashhad, Iran), Energy Engineering and Management, Vol. 9, No. 3, pp. 108-121, 2019; Doi: 10.22052/9.3.108. (in Persian)
[43] S. M. Madahi, and M. Abbasi, Thermal Behavior Analysis of the External Shell of Buildings Constructed with Traditional and Modern Materials and Execution Technologies for Energy Consumption Optimization; Case Study: Residential Buildings in Mashhad City, Armanshahr Architecture & Urban Development, Vol. 12, No. 29, pp. 167-183, 2020; Doi: 10.22034/aaud.2020.102374. (in Persian)
[44] F. Allahyari, A. Behbahaninia, H. Rahami, M. Farahani, and S. Khadivi, Optimizing Energy Consumption in the Building Sector Using Neural Network and PSO Algorithms (Case Study: Bandar Abbas City), Environmental Science and Technology Quarterly, Vol. 23, No. 10, pp. 1-17, 2021; Doi: 10.30495/jest.2021.53494.5103. (in Persian)
[45] Z. Abbaszadeh, M. Haghlesan, and H. Ebrahimi Asl, Simulation of Residential Buildings with Different Architectural Components in order to Optimize Energy Consumption in Tehran (Case Study of Zone 1), Geography (Regional Planning), Vol. 12, No. 49, pp. 430-448, 2022; Doi: 10.22034/jgeoq.2021.162869. (in Persian)
[46] S. E. Sadati, N. Rahbar, and H. Kargarsharifabad, Energy Assessment, Economic Analysis, and Environmental Study of an Iranian Building: The Effect of Wall Materials and Climatic Conditions, Sustainable Energy Technologies and Assessments, Vol. 56, p. 103093, 2023; Doi: https://doi.org/10.1016/j.seta.2023.103093.
[47] V. Gupta., and C. Deb, Envelope Design for Low-Energy Buildings in the Tropics: A Review, Renewable and Sustainable Energy Reviews, Vol. 186, p. 113650, 2023.
[48] A. Yari Nezhad, and A. Mahravan, Investigating the Effect of Optimizing External Skins and Translucent Walls on Reducing Energy Consumption and Investment Return Time of Educational Buildings in a Temperate Climate with Dry and Very Hot Summers, Journal of Applied and Computational Sciences in Mechanics, Vol. 36, No. 1, pp. 41-60, 2024; Doi: 10.22067/jacsm.2023.81531.1175. (in Persian)
[49] ASHRAE, ASHRAE Standard 55–2010, Thermal, 2012.
[50] H. Mohammadi, Applied Meteorology, Tehran University Press, 2005.
[51] Simulation Performance Energy Building of Capabilities of University, Strathclyde of University, Energy of Department US .Wisconsin.
[52] S. Shafaqhi, Geography of Isfahan, First Edition, Isfahan University Press, Isfahan, 2008. (in Persian)
[53] Isfahan Municipality's Deputy Directorate for Planning, Research and Information Technology, B: Isfahan City Statistics, General Environmental Features Section, 2014. (in Persian)
[54] Climatic Profile of East Isfahan, East Isfahan Meteorological Department (Shahid Beheshti Airport), 2015. (in Persian)
[55] General Directorate of Meteorology of Isfahan Province, Isfahan Climate Profile, 2014. (in Persian)
[56] OECD, CO2 Emissions from Fuel Combustion, OECD Publishing, 2017.
[57] Vice President of Electricity and Energy Affairs, Electricity and Energy Macro Planning Office,
Energy Balance Sheet of Iran for 2016, 2018; Available from:
http://pep.moe.gov.ir. (in Persian)
[58] Y. Zhou, L. Clarke, J. Eom, P. Kyle, P. Patel, and S. H. Kim, Modeling the Effect of Climate Change on US State-Level Buildings Energy Demands in an Integrated Assessment Framework, Applied Energy, Vol. 113, pp. 1077–1088, 2014.
[59] R. Looman, Climate-Responsive Design: A Framework for an Energy Concept Design-Decision Support Tool for Architects Using Principles of Climate-Responsive Design, PhD Dissertation. TU Delft, Architecture and the Built Environment, 2017.
[60] O. L. Frank, S. A. Omer, S. B. Riffat, and B. Mempouo, The Indispensability of Good Operation & Maintenance (O&M) Manuals in the Operation and Maintenance of Low Carbon Buildings, Sustainable Cities and Society, Vol. 14, pp. e1-e9, 2015.
[61] S. Cho, and C. Chae, A Study on Life Cycle CO2 Emissions of Low-Carbon Building in South Korea, Sustainability, Vol. 8, No. 6, p. 579, 2016.
[62] N. Abolhasani, R. Fayaz, A. Mostaghni, and S. Ghasab Sattari, Assessment of Design-Effective Low-Carbon Building Criteria in Iran, Journal of Architecture and Urban Planning, Vol.16, No. 40, pp. 5-25, 2023; Doi: 10.30480/aup.2022.2913.1585. (in Persian)
