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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 黃國倉 | |
dc.contributor.author | Meng-Chieh Tung | en |
dc.contributor.author | 董孟杰 | zh_TW |
dc.date.accessioned | 2021-06-15T16:34:28Z | - |
dc.date.available | 2020-08-28 | |
dc.date.copyright | 2015-08-28 | |
dc.date.issued | 2015 | |
dc.date.submitted | 2015-08-12 | |
dc.identifier.citation | 1. ASHARE standard 55, A.-s. (2004). 'Thermal Environmental Conditions For Human Occupancy.' 2. 7730:2005, E.-E. I. (2006). '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.' EESTI STANDARD 3. Abreu-Harbich L, L. L., Matzarakis A, (2014). 'Thermal bioclimate in idealized urban street canyons in Campinas, Brazil. .' Theor Appl Climatol 115: 333-340. 4. Ali-Toudert, F. and H. Mayer (2006). 'Numerical study on the effects of aspect ratio and orientation of an urban street canyon on outdoor thermal comfort in hot and dry climate.' Building and Environment 41(2): 94-108. 5. Ali-Toudert, F. and H. Mayer (2007). 'Effects of asymmetry, galleries, overhanging fa ccedil;ades and vegetation on thermal comfort in urban street canyons.' Solar Energy 81(6): 742-754. 6. Bowler, D. E., L. Buyung-Ali, T. M. Knight and A. S. Pullin (2010). 'Urban greening to cool towns and cities: A systematic review of the empirical evidence.' Landscape and Urban Planning 97(3): 147-155. 7. Bruse, M. and H. Fleer (1998). 'Simulating surface–plant–air interactions inside urban environments with a three dimensional numerical model.' Environmental Modelling Software 13(3–4): 373-384. 8. Chen, L. and E. Ng (2012). 'Outdoor thermal comfort and outdoor activities: A review of research in the past decade.' Cities 29(2): 118-125. 9. Dong, Y. Z. L. (2015). 'Thermal human biometeorological conditions and subjective thermal sensation in pedestrian streets in Chengdu, China.' Int J Biometeorol 59: 99-108. 10. Eliasson, I., I. Knez, U. Westerberg, S. Thorsson and F. Lindberg (2007). 'Climate and behaviour in a Nordic city.' Landscape and Urban Planning 82(1–2): 72-84. 11. Fahmy, M., S. Sharples and M. Yahiya (2010). 'LAI based trees selection for mid latitude urban developments: A microclimatic study in Cairo, Egypt.' Building and Environment 45(2): 345-357. 12. G oacute;mez, F., A. P. Cueva, M. Valcuende and A. Matzarakis (2013). 'Research on ecological design to enhance comfort in open spaces of a city (Valencia, Spain). Utility of the physiological equivalent temperature (PET).' Ecological Engineering 57(0): 27-39. 13. Gago, E. J., J. Roldan, R. Pacheco-Torres and J. Ord oacute; ntilde;ez (2013). 'The city and urban heat islands: A review of strategies to mitigate adverse effects.' Renewable and Sustainable Energy Reviews 25(0): 749-758. 14. Hong, B. and B. Lin (2015). 'Numerical studies of the outdoor wind environment and thermal comfort at pedestrian level in housing blocks with different building layout patterns and trees arrangement.' Renewable Energy 73(0): 18-27. 15. Hwang, R.-L., T.-P. Lin and A. Matzarakis (2011). 'Seasonal effects of urban street shading on long-term outdoor thermal comfort.' Building and Environment 46(4): 863-870. 16. Johansson E, E. R. (2006). 'The influence of urban design on outdoor thermal comfort in the hot, humid city of Colombo, Sri Lanka.' Int J Biometeorol 51: 119-133. 17. Johansson, E., S. Thorsson, R. Emmanuel and E. Kr uuml;ger (2014). 'Instruments and methods in outdoor thermal comfort studies – The need for standardization.' Urban Climate 10, Part 2(0): 346-366. 18. L. Shashua-Bar , M. E. H. (2000). 'Vegetation as a climatic component in the design of an urban street An empirical model for predicting the cooling effect of urban green areas with trees.' Energy and Buildings 31: 221–235. 19. Lin, B., X. Li, Y. Zhu and Y. Qin (2008). 'Numerical simulation studies of the different vegetation patterns’ effects on outdoor pedestrian thermal comfort.' Journal of Wind Engineering and Industrial Aerodynamics 96(10–11): 1707-1718. 20. Lin, C. H., T. P. Lin and R. L. Hwang (2013). 'Thermal Comfort for Urban Parks in Subtropics: Understanding Visitor's Perceptions, Behavior and Attendance.' Advances in Meteorology: 8. 21. Lin Hsien-Te, L. K.-P., Chen Kuan-Ting, Lin Lee-Jen, Kuo Hsiao-Ching, Chen Tzu-Chien (1999). 'Experimental Analyses of Urban Heat Island Effects of the Four Metropolitan Cities in Taiwan (I) - The Comparison of the Heat Island Intensities between Taiwan and the World Cities.' Journal of Architecture 31: 51-73. 22. Lin, T.-P. (2009). 'Thermal perception, adaptation and attendance in a public square in hot and humid regions.' Building and Environment 44(10): 2017-2026. 23. Lin, T.-P., K.-T. Tsai, R.-L. Hwang and A. Matzarakis (2012). 'Quantification of the effect of thermal indices and sky view factor on park attendance.' Landscape and Urban Planning 107(2): 137-146. 24. Mahmoud, A. H. A. (2011). 'Analysis of the microclimatic and human comfort conditions in an urban park in hot and arid regions.' Building and Environment 46(12): 2641-2656. 25. Matzarakis, T.-P. L. A. (2008). 'Tourism climate and thermal comfort in Sun Moon Lake, Taiwan.' Int J Biometeorol 52:281 –290. 26. Mayer, A. M. F. R. H. (2010). 'Modelling radiation fluxes in simple and complex environments: basics of the RayMan model.' Int J Biometeorol 54: 131-139. 27. Nikolopoulou, M., N. Baker and K. Steemers (2001). 'Thermal comfort in outdoor urban spaces: understanding the human parameter.' Solar Energy 70(3): 227-235. 28. Nikolopoulou, M. and S. Lykoudis (2007). 'Use of outdoor spaces and microclimate in a Mediterranean urban area.' Building and Environment 42(10): 3691-3707. 29. Pearlmutter, D., P. Berliner and E. Shaviv (2007). 'Integrated modeling of pedestrian energy exchange and thermal comfort in urban street canyons.' Building and Environment 42(6): 2396-2409. 30. R. Giridharan, S. S. Y. L., S. Ganesan, B. Givoni (2008). ' Lowering the outdoor temperature in high-rise high-density residential developments of costal Hong Kong: the vegetation in fluence.' Build Environ 43 (10): 1583–1595. 31. Robert E. Dickinson, M. S., Ross Bryant and Lisa Graumlich (1998). 'Interactive canopies for a climate model.' J.Climate 11: 2823-2836. 32. S. D. Gedzelman, S. A., R. Cermak, N. Stefano, S. Partridge, S. Quesenberry and D. A. Robinson (2003). 'Mesoscale aspects of the urban heat island around New York City.' Theoretical and Applied Climatology 75(1-2): 29-42. 33. Shashua-Bar, L., D. Pearlmutter and E. Erell (2009). 'The cooling efficiency of urban landscape strategies in a hot dry climate.' Landscape and Urban Planning 92(3–4): 179-186. 34. Shashua-Bar, L., I. X. Tsiros and M. Hoffman (2012). 'Passive cooling design options to ameliorate thermal comfort in urban streets of a Mediterranean climate (Athens) under hot summer conditions.' Building and Environment 57: 110-119. 35. Shashua-Bar, L., I. X. Tsiros and M. E. Hoffman (2010). 'A modeling study for evaluating passive cooling scenarios in urban streets with trees. Case study: Athens, Greece.' Building and Environment 45(12): 2798-2807. 36. Spagnolo, J. and R. de Dear (2003). 'A field study of thermal comfort in outdoor and semi-outdoor environments in subtropical Sydney Australia.' Building and Environment 38(5): 721-738. 37. Tseliou, A., I. X. Tsiros, S. Lykoudis and M. Nikolopoulou (2010). 'An evaluation of three biometeorological indices for human thermal comfort in urban outdoor areas under real climatic conditions.' Building and Environment 45(5): 1346-1352. 38. Villadiego, K. and M. A. Velay-Dabat (2014). 'Outdoor thermal comfort in a hot and humid climate of Colombia: A field study in Barranquilla.' Building and Environment 75(0): 142-152. 39. Wang, Q., J. Tenhunen, N. Q. Dinh, M. Reichstein, D. Otieno, A. Granier and K. Pilegarrd (2005). 'Evaluation of seasonal variation of MODIS derived leaf area index at two European deciduous broadleaf forest sites.' Remote Sensing of Environment 96(3–4): 475-484. 40. Yang, F., S. S. Y. Lau and F. Qian (2011). 'Urban design to lower summertime outdoor temperatures: An empirical study on high-rise housing in Shanghai.' Building and Environment 46(3): 769-785. 41. 何明錦 and 黃國倉 (2013). 臺灣建築能源模擬解析用逐時標準氣象資料TMY3之建置與研究. 台北, 內政部建築研究所. 42. 吳芋菁 (2011). '都市綠園道環境熱舒適與使用者調適行為之研究-以台中市經國綠園道為例.',中興大學園藝學系所碩士論文 43. 李建鋒 (2008). '校園戶外環境熱舒適之研究-以大學、小學為例.',逢甲大學建築所碩士論文 44. 方瀅喬 (2008). '都市公園微氣候對使用者熱舒適度影響之研究.',台灣大學園藝學研究所碩士論文 45. 黃柔嫚 (1999). '台北都市氣候特徵及其熱舒適度評估--以士林、萬華、古亭、松山為例.',台灣大學園藝學研究所碩士論文 46. 劉肇沛 (2012). '熱舒適性對鄰里公園活動行為之影響.',國立聯合大學建築所碩士論文 47. 鄭明仁 (2009). '大學校園戶外環境熱舒適性之實測調查研究.' Journal of Architecture No. 69: pp.1~16. 48. 嚴仕傑 (2009). '學生在校園戶外環境熱舒適實測研究以-台中市中學為例.',逢甲大學建築所碩士論文 | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/52928 | - |
dc.description.abstract | 隨著都市規模不斷擴張,都市熱島效應日益加劇,而都市中的綠地具有調節微氣候之功能,在大都市中,除森林公園外,也常見密植樹木的綠園道,是遊客和居民重要的活動空間,更被視為有效減緩都市熱島效應之手段,因此,確保都市中的綠地能提供良好的戶外舒適性相當重要。都市內透過喬木、植栽的綠化,在戶外環境中藉由植被提供遮蔭,阻隔輻射而達到降溫效果,可以有效的提升戶外之熱舒適性。本研究探討在濕熱氣候環境下,都市內綠園道之植栽對戶外熱環境舒適性的影響,利用葉面積指數反映植栽的結構和數量特徵,作為判斷阻擋之輻射量的依據,參考林妝鴻的研究得到屏蔽效應迴歸公式,計算出不同葉面積指數時的輻射量,加上台中氣象年TMY3中之溫度、相對濕度、風速、雲覆率四項資料,計算出全年不同葉面積指數下的生理等效溫度;以台灣戶外舒適範圍探討熱季的5∼10月間,各葉面積指數下之過熱時數以及過熱強度,並以單月PET>34°C之過熱時數為戶外過熱之評判標準,計算出不同過熱危險率所對應之最低葉面積指數設計值,而要將全年中最熱的七月份之過熱危險率控制在2.5%,所需提供之葉面積指數為2.64;過熱危險率控制在5%時,葉面積指數需達到2.19。最後,實際測量台灣綠園道規劃最完整的台中,四段最主要之綠園道上植栽的葉面積指數,對現有綠園道診斷並提供改善方向,選擇美術園道中一段遮蔭較不足的人行空間,利用微氣候模擬軟體ENVI-met模擬4種程度的遮蔭改善方式,希望藉由本研究之結果,找到促進都市戶外環境夏季熱舒適之樹木葉面積指數範圍,提供都市綠地規劃時,最佳的葉面積指數設計值,做為都市規劃的參考。 | zh_TW |
dc.description.abstract | With the widespread of urban living area and due to the urban heat island effect, people in urban outdoors is experiencing more severe heat stress than in rural area during summer period. Street trees can enhance pedestrians’ thermal comfort mainly by providing sun shade via its leaf canopy to reduce human body’s solar radiant exposure. Urban greenway is an important greening strategies in fighting with urban heat island effect in Taiwanese major metropolitan area and has been promoting for years. It is a consecutive urban open space allocated alongside the street with tree greening to serve as recreation purpose. However, tree planting location and tree selection would significantly influence the space users’ thermal perception. As the density of a tree’s leaf would crucially affect the amount of radiation received underneath, this study aimed to identify the minimum required leaf density in terms of leaf area index (LAI) for tree planting selection to provide pedestrian sufficient thermal comfort in summer under hot and humid climate context of Taiwan. Correlation model of solar radiation reduction rate with LAI had been established and was used for calculating radiation received underneath tree’s canopy. In assessing hourly thermal condition, local typical meteorological year (TMY3) data containing hourly weather elements including total horizontal radiation, dry bulb temperature, relative humidity, wind velocity, and cloud cover, was used as outdoor climate conditions. These weather data together with the model estimated reduced solar radiation by trees were afterwards used for estimating the physiological equivalent temperature (PET). The outdoor thermal comfort PET range of Taiwan suggested by T.P. Lin was adopted as criteria in assessing overheating occurrence frequencies and overheating severities under various LAI values, thus to reversely identify the appropriate monthly LAI needed for ensuring thermal comfort. The results show that a minimum of LAI 2.19 is required to maintain outdoor thermal comfort in hottest July to ensure the overheating occurrence probability less than 5%. Other suggested values of minimum required LAI in June, August, and September are 1.52, 1.97, and 1.67, respectively. In the second part, this study measured leaf area index planting of greenway in Taichung. Trying to diagnose and provide improvement of the urban greenways. Then select Art Park Greenway, which was lack of shading, to improve thermal comfort by micro-climate modeling software ENVI-met. These results could be serve as a tree selection reference in planning or designing urban greenways in the viewpoint of outdoor thermal comfort. | en |
dc.description.provenance | Made available in DSpace on 2021-06-15T16:34:28Z (GMT). No. of bitstreams: 1 ntu-104-R02622021-1.pdf: 5060110 bytes, checksum: 4fd1577c87bcc23c5f19eb2c8330f716 (MD5) Previous issue date: 2015 | en |
dc.description.tableofcontents | 摘要 ii 目錄 vi 表目錄 ix 圖目錄 xi 第一章 序論 1 1-1研究動機 1 1-2文獻回顧 3 1-2.1 人行徒步區熱舒適研究 3 1-2.2戶外人行空間及植栽遮蔭 5 1-3 研究目的 8 1-4研究流程 8 第二章 研究方法 11 2-1 熱平衡相關理論 11 2-1.1人體熱適應模式 11 2-1.2熱舒適指標 11 2-2 熱舒適指標計算 15 2-2.1 葉面積指數及遮蔽效應 15 2-2.2 生理等效溫度之戶外舒適範圍 16 第三章 結果與討論 19 3-1過熱比例分析 21 3-2過熱強度分析 22 3-3舒適溫度範圍 23 3-4戶外熱舒適分析 24 第四章 綠園道實測及改善模擬 27 4-1台中綠園道現況 27 4-1.1實測方式 28 4-1.2過熱危險度分析 30 4-2微氣候模擬軟體驗證 35 4-2.1ENVI-met 簡介 35 4-2.2研究目的 36 4-2.3驗證方法 37 4-2.4 ENVI-met V3.1模擬 38 4-2.5結果與討論 41 4-2.6小結 50 4-3綠園道改善模擬 50 4-3.1改善模型之建立 50 4-3.2美術園道模擬之改善方式 53 4-3.3綠園道改善模擬之結果分析 54 第五章 結論與建議 59 5-1熱舒適指標與葉面積指數 59 5-2研究建議 60 參考文獻 61 | |
dc.language.iso | zh-TW | |
dc.title | 都市綠園道戶外熱舒適評估之研究 –– 以台中市為例 | zh_TW |
dc.title | A study on the assessment method of outdoor thermal comfort of urban greenway: A case of Taichung | en |
dc.type | Thesis | |
dc.date.schoolyear | 103-2 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 黃瑞隆,林子平,王仁俊 | |
dc.subject.keyword | 都市綠園道,戶外熱舒適,生理等效溫度,葉面積指數,ENVI-met, | zh_TW |
dc.subject.keyword | Urban greenways,PET,outdoor thermal comfort,leaf area index,ENVI-met, | en |
dc.relation.page | 64 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2015-08-12 | |
dc.contributor.author-college | 生物資源暨農學院 | zh_TW |
dc.contributor.author-dept | 生物環境系統工程學研究所 | zh_TW |
顯示於系所單位: | 生物環境系統工程學系 |
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