參考文獻 |
[1] UNEP, Buildings and Climate Change, Summary for Decision-Makers, UNEP, 2009.
[2] Z. J. Zhai and J. M. Helman, “Implications of climate changes to building energy and design”, Sustain Cities Soc, vol. 44, pp. 511-519, Jan 2019.
[3] Y. Zhang, C. Q. He, B. J. Tang, and Y. M. Wei, “China′s energy consumption in the building sector: A life cycle approach”, Energ Buildings, vol. 94, pp. 240-251, May 1 2015.
[4] H. Doukas, C. Nychtis, and J. Psarras, “Assessing energy-saving measures in buildings through an intelligent decision support model”, Build Environ, vol. 44, no. 2, pp. 290-298, Feb 2009.
[5] Laudon K, Laudon J, “Management information system”, Organization and technology in the networked enterprise. 6th Ed. Prentice-Hall, 2000.
[6] 陳家榮、曾宣婷,「節能績效指標之研究-以成功大學為例」,中華民國能源經濟學會,2010。
[7] 台灣綠色生產力基金會,2020非生產性質行業能源查核年報,經濟部能源局,台北,2020。
[8] Z. M. Tong, Y. J. Chen, A. Malkawi, Z. Liu, and R. B. Freeman, “Energy saving potential of natural ventilation in China: The impact of ambient air pollution.”, Appl Energ, vol. 179, pp. 660-668, Oct 1 2016.
[9] P. Blondeau, M. Sperandio, and F. Allard, “Night ventilation for building cooling in summer”, Sol Energy, vol. 61, no. 5, pp. 327-335, Nov 1997.
[10] J. L. Zhou, G. Q. Zhang, Y. L. Lin, and Y. G. Li, “Coupling of thermal mass and natural ventilation in buildings”, Energ Buildings, vol. 40, no. 6, pp. 979-986, 2008.
[11] T. Ayata, E. Cam, and O. Yildiz, “Adaptive neuro-fuzzy inference systems (ANFIS) application to investigate potential use of natural ventilation in new building designs in Turkey”, Energ Convers Manage, vol. 48, no. 5, pp. 1472-1479, May 2007.
[12] M. Kolokotroni, M. D. A. E. S. Perera, D. Azzi, and G. S. Virk, “An investigation of passive ventilation cooling and control strategies for an educational building”, Appl Therm Eng, vol. 21, no. 2, pp. 183-199, Feb 2001.
[13] M. Haase and A. Amato, “An investigation of the potential for natural ventilation and building orientation to achieve thermal comfort in warm and humid climates”, Sol Energy, vol. 83, no. 3, pp. 389-399, Mar 2009.
[14] F. W. H. Yik and Y. F. Lun, “Energy Saving by Utilizing Natural Ventilation in Public Housing in Hong Kong”, Indoor Built Environ, vol. 19, no. 1, pp. 73-87, Feb 2010.
[15] N. Cardinale, M. Micucci, and F. Ruggiero, “Analysis of energy saving using natural ventilation in a traditional Italian building”, Energ Buildings, vol. 35, no. 2, pp. 153-159, Feb 2003.
[16] J. Laverge, N. Van den Bossche, N. Heijmans, and A. Janssens, “Energy saving potential and repercussions on indoor air quality of demand controlled residential ventilation strategies”, Build Environ, vol. 46, no. 7, pp. 1497-1503, Jul 2011.
[17] 黎益肇,「大型建築物自然通風之分析研究」,內政部建築研究所,台北,2014。
[18] 張尉瑩、洪秋琪、周伯丞、劉國滄,「不同開窗位置對於臥室流場結構影響之模擬比較-以室內床鋪面對門之臥室為例」,樹德科技大學,2006。
[19] 龔鉉傑,「低碳排智慧建築熱流場模擬分析與能源使用決策評估」,國立中央大學,碩士論文,2019。
[20] 吳健賓,「丁壩區之三維流場研究」,國立交通大學,碩士論文,2013。
[21] W. Guo, X. Liu and X. Yuan, “Study on natural ventilation design optimization based on CFD simulation for green buildings”, Procedia Eng, vol. 121, pp. 573-581, 2015.
[22] X. H. Fu and M. Z. Han, “Analysis of natural ventilation performance gap between design stage and actual operation of office buildings”, Web of Conference, vol. 172, 2020.
[23] B. Blocken, W. D. Janssen, and T. van Hooff, “CFD simulation for pedestrian wind comfort and wind safety in urban areas: General decision framework and case study for the Eindhoven University campus”, Environ Modell Softw, vol. 30, pp. 15-34, Apr 2012.
[24] C. G. Popovici, “Numerical simulation of HVAC system functionality in a sociocultural building”, Proc. Technol, vol. 22, pp. 535-542, 2016.
[25] C. G. Popovici, “HVAC system functionality simulation using ANSYS-Fluent”, Energy Procedia, vol. 112, pp. 360-365, 2017.
[26] C. Buratti, D. Palladino and E. Moretti, “Prediction of indoor conditions and thermal comfort using CFD simulations: a case study based on experimental data”, Energy Procedia, vol. 126, pp. 115-122, Sep 2017.
[27] FLUENT 6.3 User’s Guide, Fluent Inc., 2006.
[28] D. S-K. Ting, Basics of engineering turbulence, Academic Press, New York, 2016.
[29] Y. A. Cengel and J. M. Cimbala, Fluid mechanics-fundamentals and applications, McGraw Hill, 2013.
[30] C. Pfeiler and H. Raupenstrauch, “Application of different turbulence models to study the effect of local anisotropy for a non-premixed piloted methane flame”, European Symposium on Computer Aided Process Engineering, 2010.
[31] ASHRAE, ANSI/ASHRAE Standard 55-2004, “Thermal environmental conditions for human occupancy”, Atlanta, American Society of Heating, Refrigerating and Air-Conditioning Engineers, 2004.
[32] W. Li, J. L. Zhang, T. Y. Zhao, and R. B. Liang, “Experimental research of online monitoring and evaluation method of human thermal sensation in different active states based on wristband device”, Energ Buildings, vol. 173, pp. 613-622, Aug 15 2018.
[33] Y. Qi et al., “Large-scale and long-term monitoring of the thermal environments and adaptive behaviors in Chinese urban residential buildings”, Build Environ, vol. 168, Feb 2020.
[34] D. Li, C. C. Menassa, and V. R. Kamat, “Personalized human comfort in indoor building environments under diverse conditioning modes”, Build Environ, vol. 126, pp. 304-317, Dec 2017.
[35] W. Jung and F. Jazizadeh, “Comparative assessment of HVAC control strategies using personal thermal comfort and sensitivity models”, Build Environ, vol. 158, pp. 104-119, Jul 2019.
[36] D. Bienvenido-Huertas, D. Sanchez-Garcia, A. Perez-Fargallo, and C. Rubio-Bellido, “Optimization of energy saving with adaptive setpoint temperatures by calculating the prevailing mean outdoor air temperature”, Build Environ, vol. 170, Mar 2020.
[37] B. Tejedor, M. Casals, M. Gangolells, M. Macarulla, and N. Forcada, “Human comfort modelling for elderly people by infrared thermography: Evaluating the thermoregulation system responses in an indoor environment during winter”, Build Environ, vol. 186, Dec 2020.
[38] ASHRAE, ANSI/ASHRAE Standard 55-2004, “Thermal environmental conditions for human occupancy”, Atlanta, American Society of Heating, Refrigerating and Air-Conditioning Engineers, 2004.
[39] M. Bayoumi, “Energy saving method for improving thermal comfort and air quality in warm humid climates using isothermal high velocity ventilation”, Renew Energ, vol. 114, pp. 502-512, Dec 2017.
[40] B. W. Olesen, “Thermal comfort”, Bruel and Kjaer Technical Review, 1982.
[41] M. E. Fountain and E. A. Arens, “Air Movement and Thermal Comfort”, Ashrae J, vol. 35, no. 8, pp. 26-30, Aug 1993.
[42] J. Khedari, N. Yamtraipat, N. Pratintong, and J. Hirunlabh, “Thailand ventilation comfort chart”, Energ Buildings, vol. 32, no. 3, pp. 245-249, Sep 2000.
[43] E. Arens, S. Turner, H. Zhang, and G. Paliaga, “Moving Air For Comfort”, Ashrae Journal, vol. 51, no. 5, pp. 18-+, May 2009.
[44] S. H. Ho, L. Rosario, and M. M. Rahman, “Thermal comfort enhancement by using a ceiling fan”, Appl Therm Eng, vol. 29, no. 8-9, pp. 1648-1656, Jun 2009.
[45] P. O. Fanger, “Thermal comfort: analysis and applications in environmental engineering”, McGraw-Hill, New York, 1970.
[46] T. Cheung, S. Schiavon, T. Parkinson, P. X. Li, and G. Brager, “Analysis of the accuracy on PMV - PPD model using the ASHRAE Global Thermal Comfort Database II”, Build Environ, vol. 153, pp. 205-217, Apr 15 2019.
[47] ISO, ISO standard 7730, “Ergonomics of the thermal environment - Analytical determination and interpretation of thermal comfort using calculation of the PMV and PPD indices and local thermal comfort criteria”, International Standards Organization”, 2005.
[48] M. H. Hasan, F. Alsaleem, and M. Rafaie, “Sensitivity study for the PMV thermal comfort model and the use of wearable devices biometric data for metabolic rate estimation”, Build Environ, vol. 110, pp. 173-183, Dec 2016.
[49] Simulation Research Group, Lawrence Berkley National Lab, Overview of DOE 2.2, http://ww.doe2.com/
[50] James J. Hirsch & Associates, Introductory Tutorial of eQUEST, version 3.64, 2010.
[51] Y. C. Wang and H. T. Lin, “Energy-saving techniques of full-scale green building analysis research ----- Taiwan’s first zero-carbon green building”, vol. 121-126, pp. 3058-3066, 2012.
[52] J. S. Tang and L. J. Leu, “A study of coupled building energy and CFD simulations”, Proceedings of the 22nd KKCNN Symposium on Civil Engineering, Chiang Mai, Thailand, 2009.
[53] Y. M. Zhu, “Applying computer-based simulation to energy auditing: A case study”, Energ Buildings, vol. 38, no. 5, pp. 421-428, May 2006.
[54] Y. Pan, Z. Huang, G. Wu and C. Chen, “The application of building energy simulation and calibration in two high-rise commercial buildings in Shanghai”, Second National IBPSA-USA Conference, Cambridge, MA, pp. 252-261, Aug 2006.
[55] M. Bojic and F. Yik, “Cooling energy evaluation for high-rise residential buildings in Hong Kong”, Energ Buildings, vol. 37, no. 4, pp. 345-351, Apr 2005.
[56] S. A. Orszag, V. Yakhot, W. S. Flannery, F. Boysan, D. Choudhury, J. Maruzewski, and B. Patel, “Renormalization Group Modeling and Turbulence Simulations”, In International Conference on Near-Wall Turbulent Flows, Tempe, Arizona. 1993.
[57] R. Buccolieri, J. L. Santiago, E. Rivas, and B. Saanchez, “Reprint of: Review on urban tree modelling in CFD simulations: Aerodynamic, deposition and thermal effects”, Urban for Urban Gree, vol. 37, pp. 56-64, Jan 2019.
[58] M. Robitu, M. Musy, C. Inard, and D. Groleau, “Modeling the influence of vegetation and water pond on urban microclimate”, Sol Energy, vol. 80, no. 4, pp. 435-447, 2006.
[59] J. Liu, J. M. Chen, T. A. Black, and M. D. Novak, “E-epsilon modelling of turbulent air flow downwind of a model forest edge”, Bound-Lay Meteorol, vol. 77, no. 1, pp. 21-44, Jan 1996.
[60] S. Coccolo, D. Pearlmutter, J. Kaempf, and J. L. Scartezzini, “Thermal Comfort Maps to estimate the impact of urban greening on the outdoor human comfort”, Urban for Urban Gree, vol. 35, pp. 91-105, Oct 2018.
[61] M. Bruse and H. Fleer, “Simulating surface-plant-air interactions inside urban environments with a three dimensional numerical model”, Environ Modell Softw, vol. 13, no. 3-4, pp. 373-384, 1998.
[62] M. H. Kobayashi, J. C. F. Pereira, and M. B. B. Siqueira, “Numerical Study of the Turbulent-Flow over and in a Model Forest on a 2d Hill”, J Wind Eng Ind Aerod, vol. 53, no. 3, pp. 357-374, Dec 1994.
[63] G. S. Campbell, “An Introduction to environmental biophysics”, Springer, New York, CFD2000 manual, Computational fluid dynamics systems, Pacific Sierra Research Corporation, pp. 159, 1977.
[64] T. R. Oke, “Boundary layer climates”, New York: Methuen, 1987.
[65] B. Blocken, T. Stathopoulos, and J. Carmeliet, “CFD simulation of the atmospheric boundary layer: wall function problems”, Atmos Environ, vol. 41, no. 2, pp. 238-252, Jan 2007.
[66] B. Sidawi and N. Hamza, “CFD modeling as a tool for assessing outdoor thermal comfort conditions in urban settings in hot arid climates”, ITcon, vol. 19, pp. 248-269, 2014.
[67] J. Bouyer, C. Inard, and M. Musy, “Microclimatic coupling as a solution to improve building energy simulation in an urban context”, Energ Buildings, vol. 43, no. 7, pp. 1549-1559, Jul 2011.
[68] 蔣昀祐,「小型低速風洞模擬大氣邊界層形成之研究-以朝陽科技大學風洞為例」,朝陽科技大學,碩士論文,2011。
[69] 周郁汶,「建築物與地形在大氣邊界層中的流場模擬」,國立中央大學,碩士論文,2013。
[70] P. J. Richards, “Computational modelling of wind flows around low rise buildings using PHOENIX”, Report for the ARFC Institute of Engineering Research Wrest Park, Silsoe Research Institute, UK: Bedfordshire, 1989.
[71] R. I. Harris and D. M. Deaves, “The structure of strong winds”, CIRA Conference on Wind Engineering in the Eighties, London, Construction Industry Research and Information Association, pp. 4, 1981.
[72] J. Wieringa, “Updating the davenport roughness classification”, Journal of Wind Engineering and Industrial Aerodynamics, vol. 41-44, pp. 357-68, 1992.
[73] 涂材宏,「使用壓縮空氣噴流分離矽晶片研究」,國立交通大學,碩士論文,2012。
[74] J. P. Vandoormaal and G. D. Raithby, “Enhancements of the SIMPLE method for predicting incompressible fluid flows” Numerical Heat Transfer, vol. 7, pp. 147-163, 1984.
[75] 廖慧燕、呂良正,「建築物耗能評估軟體驗證之研究–既有建築節能改善之效益評估」,內政部建築研究所協同研究報告,2012。
[76] 2009 ASHRAE Handbook: Fundamentals-IP Edition. Atlanta: American Society of Heating, Refrigerating and Air-Conditioning Engineers, 2009.
[77] A. K. Betts and J. H. Ball, “Albedo over the boreal forest”, Journal of Geophysical Research, vol. 102, pp. 28-909, 1997.
[78] W. G. Rees, “Physical principles of remote sensing”, Cambridge, England: Cambridge University Press, pp. 46, 1990.
[79] R. C. Weast, (Ed.). Handbook of Chemistry and Physics, 61st ed. Boca Raton, FL: CRC Press, pp. 398, 1981.
[80] B. Blocken, “Computational Fluid Dynamics for urban physics: Importance, scales, possibilities, limitations and ten tips and tricks towards accurate and reliable simulations”, Build Environ, vol. 91, pp. 219-245, Sep 2015.
[81] 范家魁,「擁擠空間之空氣品質計算」,國立交通大學,碩士論文,2013。
[82] K. M. Almohammadi, D. B. Ingham, L. Ma, and M. Pourkashan, “Computational fluid dynamics (CFD) mesh independency techniques for a straight blade vertical axis wind turbine”, Energy, vol. 58, pp. 483-493, Sep 1 2013.
[83] 劉家安,「國產三軸立式加工中心機主軸頭暫態熱流固耦合分析優化與實機驗證」,國立中興大學,碩士論文,2016。
[84] 姚志廷,「隔熱建材節能效益及綠建材基準研擬之研究」,內政部建築研究所自行研究報告,2015。
[85] W. Feng, L Zou, G. Gao, G. Wu, J. Shen, and W. Li, “Gasochromic smart window: optical and thermal properties, energy simulation and feasibility analysis”, Solar Energy Materials and Solar Cells, vol. 144, pp. 316-323, 2016.
[86] M. T. Ke, C. H. Yeh, and J. T. Jian, “Analysis of building energy consumption parameters and energy savings measurement and verification by applying eQUEST software”, Energ Buildings, vol. 61, pp. 100-107, Jun 2013.
[87] 中華民國衛生福利部統計處,老人狀況調查報告,2005。
[88] Y. Wang, H. Lina, W. Wang, Y. Liu, R. Wennersten, and Q. Sun, “Impacts of climate change on the cooling loads of residential buildings differences between occupants with different age”, 9th International Conference on Applied Energy, Aug 2017.
[89] Y. Agarwal, B. Balaji, R. Gupta, J. Lyles, M. Wei and T. Weng, “Occupancy-driven energy management for smart building automation”, In Proc. of ACM BuildSys, pp. 1-6, 2010.
[90] 陳品纓,「建築物配置對風場影響之研究-以社子島為例」,中國科技大學,碩士論文,2019。
[91] 林憲德,綠色建築,詹氏書局,台北,2006。 |