大空间建筑喷口侧送风分层空调负荷特性研究
摘要:采用CFD模拟和缩尺模型实验,对大空间建筑喷口侧送风分层空调的竖直空气温度分布和负荷特性进行了研究。分析了建筑顶部排风比对空调负荷的影响,增大排风比可降低非空调区向空调区的对流转移负荷,而对辐射转移负荷影响较小。利用模拟结果绘制了不同排风比下的分层空调对流转移负荷线算图,并与设计手册中的对流转移负荷线算图进行了对比,给出了符合设计需要的线算图。
关键词:大空间建筑分层空调喷口送风空调负荷排风比对流转移负荷线算图缩尺模型实验
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参考文献参考文献
[1] 黄晨,李美玲.大空间建筑室内垂直温度分布的研究[J].暖通空调,1999,29(5):28-33.
[2] 范存养.大空间建筑空调设计及工程实录[M].北京:中国建筑工业出版社,2001:4-15.
[3] 邹月琴,王师白,彭荣,等.分层空调热转移负荷计算方法的研究[J].建筑技术通讯(暖通空调),1983(3):3.
[4] 吴照,黄晨,王丽慧.大空间分层空调热转移负荷特性分析[J].制冷空调与电力机械,2008,29(5):5-8.
[5] 黄晨,张会娟,白天宇.基于分区建模的大空间分层空调负荷随分层高度变化的研究[J].能源研究与信息,2015,31(2):69-72.
[6] 陆耀庆.实用供热空调设计手册[M].2版.北京:中国建筑工业出版社,2008:1716-1734.
[7] HUANG C,WANG X.Discussion of design method and optimization on airflow distribution in a large-space building with stratified air-conditioning system[G]//ASHRAE.ASHRAE Transaction 2009:part 2.Atlanta:ASHRAE Inc.,2009:345-350.
[8] 朱柏山,赵蕾,陈岗锋,等.某圆柱形高大空间分层空调气流组织数值研究[J].建筑热能通风空调,2010,29(6):101-104.
[9] 李晓冬,高军,许世杰.大空间建筑侧送分层气流组织数值模拟与探讨[J].建筑热能通风空调,2004,23(2):64-66.
[10] 龚光彩.CFD技术在暖通空调制冷工程中的应用[J].暖通空调,1999,29(6):25-27.
[11] 徐挺.相似方法及其应用[M].北京:机械工业出版社,1995:13-39.
[12] 雷敏.模型试验相似理论研究[J].企业技术开发(下旬刊),2014,33(9):154.
[13] 杨昕琦,王海东,胡浩.大空间建筑分层空调两种典型送风系统区域间换热特性研究[J].暖通空调,2022,52(3):126-131.
[14] 蔡宁.基于同步求解模型的大空间分层空调垂直温度分布特性研究[D].上海:上海理工大学,2011:20-27.
[15] 叶李飞.大空间喷口送风分层空调系统对流热转移负荷缩尺模型实验研究[D].上海:上海理工大学,2016:29-32.
[16] TOGARI S,ARAI Y,MIURA K.A simplified model for predicting vertical temperature distribution in a large space[G]//ASHRAE.ASHRAE Transaction 1993:part 1.Atlanta:ASHRAE Inc.,1993:84-90.
[17] WALTERS D K,COKLJAT D.A three-equation eddy-viscosity model for Reynolds-averaged Navier–Stokes simulations of transitional flow[J].Journal of fluids engineering,2008,130(12):121401.
[18] LAU J,NIU J L.Measurement and CFD simulation of the temperature stratification in an atrium using a floor level air supply method[J].Indoor and built environment,2003,12(4):265-280.
[19] 董玉平,由世俊,汪洪军,等.高大空间建筑空调气流CFD模拟研究[J].河北建筑科技学院学报,2003,20(3):23-27.
[20] 王龙阁.不同高大空间建筑气流组织设计优化研究[D].重庆:重庆大学,2015:31-35.
[21] CHEN C J,JAW S Y.Fundamentals of turbulence modeling[M].Washington D C:Taylor and Francis,1998:135-140.
[1] 黄晨,李美玲.大空间建筑室内垂直温度分布的研究[J].暖通空调,1999,29(5):28-33.
[2] 范存养.大空间建筑空调设计及工程实录[M].北京:中国建筑工业出版社,2001:4-15.
[3] 邹月琴,王师白,彭荣,等.分层空调热转移负荷计算方法的研究[J].建筑技术通讯(暖通空调),1983(3):3.
[4] 吴照,黄晨,王丽慧.大空间分层空调热转移负荷特性分析[J].制冷空调与电力机械,2008,29(5):5-8.
[5] 黄晨,张会娟,白天宇.基于分区建模的大空间分层空调负荷随分层高度变化的研究[J].能源研究与信息,2015,31(2):69-72.
[6] 陆耀庆.实用供热空调设计手册[M].2版.北京:中国建筑工业出版社,2008:1716-1734.
[7] HUANG C,WANG X.Discussion of design method and optimization on airflow distribution in a large-space building with stratified air-conditioning system[G]//ASHRAE.ASHRAE Transaction 2009:part 2.Atlanta:ASHRAE Inc.,2009:345-350.
[8] 朱柏山,赵蕾,陈岗锋,等.某圆柱形高大空间分层空调气流组织数值研究[J].建筑热能通风空调,2010,29(6):101-104.
[9] 李晓冬,高军,许世杰.大空间建筑侧送分层气流组织数值模拟与探讨[J].建筑热能通风空调,2004,23(2):64-66.
[10] 龚光彩.CFD技术在暖通空调制冷工程中的应用[J].暖通空调,1999,29(6):25-27.
[11] 徐挺.相似方法及其应用[M].北京:机械工业出版社,1995:13-39.
[12] 雷敏.模型试验相似理论研究[J].企业技术开发(下旬刊),2014,33(9):154.
[13] 杨昕琦,王海东,胡浩.大空间建筑分层空调两种典型送风系统区域间换热特性研究[J].暖通空调,2022,52(3):126-131.
[14] 蔡宁.基于同步求解模型的大空间分层空调垂直温度分布特性研究[D].上海:上海理工大学,2011:20-27.
[15] 叶李飞.大空间喷口送风分层空调系统对流热转移负荷缩尺模型实验研究[D].上海:上海理工大学,2016:29-32.
[16] TOGARI S,ARAI Y,MIURA K.A simplified model for predicting vertical temperature distribution in a large space[G]//ASHRAE.ASHRAE Transaction 1993:part 1.Atlanta:ASHRAE Inc.,1993:84-90.
[17] WALTERS D K,COKLJAT D.A three-equation eddy-viscosity model for Reynolds-averaged Navier–Stokes simulations of transitional flow[J].Journal of fluids engineering,2008,130(12):121401.
[18] LAU J,NIU J L.Measurement and CFD simulation of the temperature stratification in an atrium using a floor level air supply method[J].Indoor and built environment,2003,12(4):265-280.
[19] 董玉平,由世俊,汪洪军,等.高大空间建筑空调气流CFD模拟研究[J].河北建筑科技学院学报,2003,20(3):23-27.
[20] 王龙阁.不同高大空间建筑气流组织设计优化研究[D].重庆:重庆大学,2015:31-35.
[21] CHEN C J,JAW S Y.Fundamentals of turbulence modeling[M].Washington D C:Taylor and Francis,1998:135-140.
Load characteristics of stratified air conditioning systems with nozzle air supply in large space buildings
Abstract: This study uses CFD simulation and scale model experiment to study the vertical air temperature distribution and load characteristics of the stratified air conditioning system with the nozzle air supply in large space buildings. The influence of the exhaust airflow ratio at the top of the building on the air conditioning load is analysed. Increasing the exhaust airflow ratio can reduce the convective transfer load from the non-air-conditioned area to the air-conditioned area, but has less effect on the radiation transfer load.Based on the simulation results, the convective transfer load nomographs of stratified air conditioning under different exhaust airflow ratios are drawn, and compared with that in the design manual. The nomograph that meets the design requirements is given.
Keywords: large space building; stratified air conditioning; nozzle air supply; air conditioning load; exhaust airflow ratio; convective transfer load; nomograph; scale model experiment;
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