基于CFD的低温送风冷辐射吊顶空调系统设计研究Research on Air Conditioning System of Ceiling Radiant Cooling Combined with Low Temperature Air Supply Based on CFD Simulation
冯劲梅,唐斐骁,朱倩翎
Feng Jinmei,Tang Feixiao,Zhu Qianling
摘要(Abstract):
低温送风冷辐射吊顶技术在解决冷辐射吊顶易结露、新风不足和供冷能力有限等问题的同时可以实现建筑节能。本文以上海某办公室作为研究对象,建立三维数值模型,采用CFD软件FLUENT 2019 R1对办公室内的温度分布和空气流场进行数值模拟计算,分析低温送风角度对辐射供冷房间的热舒适性影响,模拟11 ℃和13 ℃的低温送风温度下,30°、45°、60°和75° 4种不同顶送风角度的室内温度场、速度场情况,同时对部分工况模拟结果进行试验验证,并根据试验结果进行有效风感温度(EDT)和空气分布特性指标(ADPI)的热舒适性计算。试验数据与模拟结果相符,模拟结果真实可靠。数值计算及试验论证表明,送风温度为13 ℃时,送风角度为75°时,低温送风冷辐射吊顶的室内热舒适性最佳。
Low temperature air supply technology can solve the problems of the risk of condensation on radiant ceiling,lack of fresh air,limited cooling capacity and so on,and achieve building energy efficiency at the same time.In present study,an office in Shanghai was taken as the object of study and a three-dimensional numerical model was established.Computational Fluid Dynamics(CFD) FLUENT 2019 R1 was used to simulate temperature distribution and air flow field of the office,and to analyze the influence of the angle of cold air to radiation cooling room.When the cold air system was under the temperature 11 ℃ and 13 ℃,the temperature distribution and air flow field with four different top air supply angles of 30°,45°,60° and 75° were simulated.Experiments were carried out to verify the simulation results of some working conditions and the thermal comfort indices of EDT and ADPI were calculated based on the experimental results.The experimental data is consistent with the simulation and the simulation are real and reliable.The numerical calculation and experimental demonstration show that the thermal comfort was best when the temperature was 13 ℃ and the angle of air supply was 75°.
关键词(KeyWords):
冷辐射吊顶;低温送风;热舒适;送风角度;CFD
ceiling radiant cooling;low temperature air supply;thermal comfort;air supply angle;CFD
基金项目(Foundation):
作者(Author):
冯劲梅,唐斐骁,朱倩翎
Feng Jinmei,Tang Feixiao,Zhu Qianling
参考文献(References):
- [1]Manuel Andrés-Chicote,Ana Tejero-González,Eloy Velasco-Gómez,et al.Experimental study on the cooling capacity of a radiant cooled ceiling system[J].Energy and Buildings,2012(54):207-214.
- [2]康宁,宣永梅,殷清海.辐射供冷现状及发展趋势[J].建筑节能,2009,37(5):74-76.
- [3]袁旭东,张秀平,贾磊,等.辐射+送风组合末端供冷结露特性研究[J].流体机械,2018,46(1):78-82.
- [4]赵忠超,云龙,訾新立,等.辐射供冷与贴附射流复合空调系统室内空气品质研究[J].流体机械,2015,43(2):70-74.
- [5]孔祥雷,张小松,路诗奎.辐射供冷空调结露问题的研究现状及其对策[J].建筑热能通风空调,2008(1):20-23.
- [6]张瑞,柳建华,张良.低温送风室内气流组织的实验研究[J].制冷技术,2015,35(5):25-30.
- [7]李冬冬,邵飞,卢宏健,等.低温送风温湿度控制数值仿真研究[J].低温与超导,2019,47(3):72-77.
- [8]冀兆良,江建.低温送风空调系统末端送风装置的研究[J].西安建筑科技大学学报(自然科学版),2009,41(1):100-105.
- [9]Markatos.The mathematical modeling of turbulence flows[J].Appl Math Modeling,1986(10):190-220.
- [10]民用建筑供暖通风与空气调节设计规范条文说明[S]:GB 50736-2012.
- [11]张世航,孔婷婷,肖彪,等.増焓热泵供暖系统搭配不同散热末端的试验研究[J].流体机械,2019,47(1):64-69.
- [12]陈孚江,卢旺,陈梦梦,等.基于纤维空气分布系统的置换通风的热舒适性研究[J].流体机械,2018,46(8):32-35.
- [13]刘芳,宫建国,黑宝平,等.核电部件屈曲设计方法的对比分析与案例研究[J].压力容器,2019,36(6):18-26.
- [14]周临风,冷建成,魏立新.基于监测数据的油气管道预警技术[J].压力容器,2019,36(5):55-60.
- [15]张东生,彭彪.低温送风室内气流组织模拟及热舒适评价[J].建筑热能通风空调,2007(6):70-72.