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論文中文名稱:無機礦粉披覆材料於建築物外殼隔熱效能與節能效益之研究 [以論文名稱查詢館藏系統]
論文英文名稱:A Study on Thermal Insulation Efficiency and Energy Saving Benefit of Inorganic Mineral Powder Coating Materials in Buildings [以論文名稱查詢館藏系統]
院校名稱:臺北科技大學
學院名稱:工程學院
系所名稱:土木工程系土木與防災碩士班
畢業學年度:106
畢業學期:第二學期
出版年度:107
中文姓名:范植憲
英文姓名:Jhih-Shen Fan
研究生學號:105428010
學位類別:碩士
語文別:中文
口試日期:2018/06/30
論文頁數:90
指導教授中文名:李有豐
指導教授英文名:Yeou-Fong Li
口試委員中文名:陳清泉;黃志弘;鄭大偉
口試委員英文名:Chern Ching-Chuan;Haung Chih-Hong;Cheng Ta-Wui
中文關鍵詞:無機礦粉反射率熱通量建築外殼隔熱綠建築
英文關鍵詞:Inorganic mineral powderreflectivityheat fluxthermal insulation of building shellgreen building
論文中文摘要:本文採無機礦粉披覆材料加水攪拌混合,作為一般建築物外殼(含屋頂與外牆)之隔熱塗料。此無機礦粉披覆塗料功能在反射並阻隔室外可見光與紅外線之熱量透過建築物外殼傳入室內,以減少熱量儲存建築物外殼中。藉由熱傳導儀器量測無機礦粉材料熱傳導係數;及方格法測試其附著力。試驗結果顯示,此披覆塗料之熱傳導係數低於0.35 W/m·K,且方格法試驗其附著性良好。透過可見光與紅外線照射混凝土版及鋼板試體,進行上下部熱通量、表面溫度量測,探討其隔熱效果。試驗結果顯示此無機礦粉披覆材料對於太陽輻射傳熱的主要光譜可見光、紅外線,均有極佳的阻隔能力。借由兩貨櫃屋模擬鋼板建築物,有塗布此隔熱塗料之貨櫃屋室內溫度較未塗布貨櫃屋可降低攝氏15度左右。透過上述熱通量實驗數據與綠建築技術規範所訂定之公式計算出塗布完成試體之熱傳透率,而塗布完成試體之熱傳透率均低於裸混凝土試體。最後由測得之熱通量數據,模擬一封閉鋼板建築物,進行節能效益分析,在不考慮熱量散失的情況之下,塗布此塗料之建築物每月能節省39.3%左右之用電。
論文英文摘要:In this thesis,the inorganic mineral powder material mixing with water was used as the building exterior insulation coating. The function of the inorganic slag powder coating was to reflect and block outdoor heat of visible light and infrared light from entering the room through the building shell, and to reduce heat storage in the building shell. The thermal conductivity of inorganic mineral powder was measured by heat conduction instrument; and the checkered test was used to test its adhesion. The test results show that the thermal conductivity of the coating is lower than 0.35 W/m·K, and the checkered test shows good adhesion. Through the visible light and infrared radiation concrete plate and steel plate test, the upper and lower heat flux, surface temperature were measured to explore the insulation effect. The test results show that the inorganic mineral powder coating material has excellent ability to block the visible light and infrared light of solar radiation heat. In this study,in the temperatures of the two containers,one is benchmark and the other one was coated with the inorganic insulation coating,were measured. The temperature in the interior of a container coated with this insulation coating can be reduced by about 15 degrees Celecius compared with that of the benchmark container. Through the above-mentioned heat flux experimental data and the formula set by the Green Building Technical Specification, the heat transmission rate of the coated specimen was calculated. The heat transmission rate of the coated sample is lower than that of the bare concrete sample. Finally, from the measured heat flux data, a steel plate building was simulated to conduct energy-saving benefit analysis. Assuming without heat loss, the buildings, which applied the coating, could save about 58.9% of the electricity consumption.
論文目次:摘要 i
ABSTRACT ii
誌謝 iv
目錄 v
表目錄 vii
圖目錄 x
第一章 緒論 1
1.1 研究背景 1
1.2 研究動機 2
1.3 研究目的及內容 4
第二章 文獻回顧 6
2.1 隔熱塗料之物理性能相關研究 6
2.2 隔熱塗料之反射性能相關研究 9
2.3 熱傳透率與節能效益相關研究 13
第三章 材料物理性能測試 18
3.1 試驗塗料介紹 18
3.2 反射率測試 20
3.3 熱傳導係數測試 21
3.3.1 試驗原理與試體製作 21
3.4 耐酸鹼測試 24
3.5 附著性測試 25
3.5.1試驗規劃 25
3.5.2測試結果 27
第四章 材料隔熱性能試驗 28
4.1 隔熱試驗規劃 28
4.1.1試驗設備及試體 28
4.1.2試驗規劃 33
4.2 熱通量及表面溫度試驗 35
4.2.1 鋼板隔熱試驗 35
4.2.2 混凝土版隔熱試驗 41
4.3 貨櫃屋試驗 58
4.4 小結 60
第五章 壁體塗料層反射控制方程式 62
5.1混凝土壁體U值計算 62
5.1.1 熱傳遞行為 62
5.1.2 理論與方法 69
5.2 實測結果 72
第六章 節能效益計算 77
6.1綠建築簡介 77
6.2建築節能設計 78
6.3建築物負荷評估 79
6.4無機礦粉披覆材料之節能效益 80
第七章 結論 86
參考文獻 88
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