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| 研究生: |
王鈞廷 Chun-Ting Wang |
|---|---|
| 論文名稱: |
實驗量測地板送風系統供風口特性之研究 An experimental study on characteristics of supply vent of Under-Floor Air Distribution System |
| 指導教授: |
林怡均
Yi-Jiun Lin |
| 口試委員: |
田維欣
Wei-Hsin Tien 趙修武 Shiu-Wu Chau 朱佳仁 none |
| 學位類別: |
碩士 Master |
| 系所名稱: |
工程學院 - 機械工程系 Department of Mechanical Engineering |
| 論文出版年: | 2015 |
| 畢業學年度: | 103 |
| 語文別: | 中文 |
| 論文頁數: | 152 |
| 中文關鍵詞: | 全尺寸實驗 、地板送風系統 、散流蓋 、流場可視化 、地板靜壓箱 、供風角度 |
| 外文關鍵詞: | Full-Scale Experiment, Under-Floor Air Distribution (UFAD) system, Diffuser, Flow Visualization, Plenum, Supply Air Angle |
| 相關次數: | 點閱:195 下載:7 |
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本論文進行全尺寸實驗量測臺灣建築科技中心大樓六樓室內地板供風口特性,在一個擁有地板送風(UFAD)系統的辦公室中,探討空調氣體離開供風口時的風速、風量及出流角度。相較於天花板送風(CBAD)系統,地板送風系統能更有效的利用空調氣體,得到較佳的熱舒適性、空氣品質及耗能表現。在供風口風速及風量量測部分,探討在不同供風條件下,實際的供風風速值及供風風量值。
風速量測及風量量測的實驗結果顯示,使用熱線風速儀與風罩式風量計所量測出來的風量直會有些許的差異。風速量測結果顯示,在供風口上方2 cm的平面所量測到的供風速度並非均勻且最大風速分佈偏向外側方向。因此運用流場可視化的方式研究供風口上方供應流體的出流角度。實驗分別量測供風口左、中及右三個截面,藉由更改不同的供風條件及有或無散流蓋對該截面供風角度的影響。供風角度量測結果顯示,在有散流蓋時,出流流體與地板呈現85度~105度的角度;在沒有散流蓋時,出流流體與地板呈現120度~140度的角度。因此供風角度取決於地板靜壓箱(Plenum)的設計及地板散流蓋的安裝與否。由垂直風速量測結果及供風角度量測結果可得,在無散流蓋時,量測點並非水平於供風方向,僅量測到該噴流的速度分量,當量測點離開供風影響區域時,導致風速值快速下降的現象發生。
This study presents full-size experimental measurements of full-scale air supply vent used in the Under-Floor Air Distribution (UFAD) system. Compared with Ceiling-Based Air Distribution system, UFAD systems is more efficient of utilizing the conditioned air, and improve indoor air quality, thermal comfort and energy performance. This study investigates supply air velocity, supply air flow rate, and supply air direction from the outlet of UFAD system. Experimental results of supply air velocity and supply air flow rate show some variations between them. The results of supply air velocity measurement show that the average velocity distribution at the same level height is uneven. This study uses flow visualization to investigate the supply air flow direction which has an angle to the horizontal.
There are three measurement sections of the supply vent, \^{x}_L, \^{x}_C and \^{x}_R with and without diffuser a diffuser on it for three supply options. The supply air direction results show that the supply air from the outlet with a diffuser is tilting by an angle of 85^o ~ 105^o to the floor; the supply air from the outlet without any diffuser is tilting by an angle of 120^o ~ 140^o to the floor. Therefore, supply air angle depends on the design of the plenum and with a diffuser or not. The results of supply air velocity and angle show that the vertical velocity measurement points are not parallel to the supply air flow direction and the velocity magnitude drops significantly outside the supply air flow.
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