新型扩口式布水器大流量小温差释能过程的CFD模拟研究
摘要:聚焦数据中心应急供冷,对采用新型扩口式布水器设计的蓄冷罐在大流量小温差工况下的释能过程进行了数值模拟研究,得到了释能过程的温度场和温度变化曲线,计算了斜温层量纲一厚度和释能效率。并将数值模拟结果与理想模型及实际项目监测数据进行了对比,验证了该新型扩口式布水器的工作性能。
关键词:大流量小温差数据中心应急供冷扩口式布水器斜温层厚度释能效率
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[2] 张乔丹,张华,王子龙,等.相变蓄热球对水箱热分层特性影响的实验研究[J].制冷学报,2020,41 (2):144- 151.
[3] 赵庆珠.蓄冷技术与系统设计[M].北京:中国建筑工业出版社,2012:3- 9.
[4] 殷平.数据中心研究(10):不间断供冷和蓄冷[J].暖通空调,2020,50(2):1- 8.
[5] 王磊,林密.数据中心制冷系统中断期间温升控制策略[J].科学中国人,2016(8):13- 16.
[6] 方贵银.蓄冷空调工程实用新技术[M].北京:人民邮电出版社,2000:136- 149.
[7] 吴喜平.蓄冷技术和蓄热电锅炉在空调中的应用[M].上海:同济大学出版社,2000:125- 137.
[8] OSMAN K,KHAIREED S M N A,ARIFFIN M K,et al.Dynamic modeling of stratification for chilled water storage tank[J].Energy conversion and management,2008,49(11):3270- 3273.
[9] HAN Y M,WANG R Z,DAI Y J.Thermal stratification within the water tank[J].Renewable and sustainable energy reviews,2009,13(5):1014- 1026.
[10] 穆迪,高乃平,朱彤,等.温度分层型水蓄冷槽斜温层的动态特性模拟[J].节能技术,2014,32(5):404- 409.
[11] 胡国霞,于航.自然分层型水蓄冷槽布水器的模拟[J].能源技术,2007,28(4):237- 240.
[12] TANG J L,OUYANG Z R,SHIY Y.Experimental analysis and FLUENT simulation of a stratified chilled water storage system[J].The European physical journal plus,2019,134:118.
[13] 刘璇,郝学军,宋孝春.基于CFD模拟蓄冷水罐分层效果的影响因素分析[J].区域供热,2016(2):11- 16.
[14] NELSON J E B,BALAKRISHNAN A R,MURTHY S S.Experiments on stratified chilled-water tanks[J].International journal of refrigeration,1999,22(3):216- 234.
[15] 唐海宇,蒋华,刘继平,等.径向圆盘布水器斜温层蓄热罐性能优化研究[J].工程热物理学报,2020,41(11):2788- 2794.
[16] 王崇愿,张华,王子龙.一种带有新型分水器的储热水箱分层特性的实验研究[J].制冷学报,2016,37(4):70- 75.
[17] 黄华杰,张华,王子龙,等.多孔进水结构对蓄热水箱热特性的影响[J].制冷学报,2018,39(6):97- 103.
[18] SUN Q,WANG H,DONG K J,et al.Experimental study on the thermal performance of a novel physically separated chilled water storage tank[J].Journal of energy storage,2021,40:1- 9.
[19] 杨常安,盛元红,张新昌,等.一种扩口式布水头:202022809734.8[P].2021-08-10.
[20] FERNÁNDEZ-SEARA J,UHÍA F J,SIERES J.Experimental analysis of a domestic electric hot water storage tank.Part II:dynamic mode of operation[J].Applied thermal engineering,2007,27(1):137- 144.
CFD simulation study on energy discharge process of a new flared type water diffuser under large flow rate and small temperature difference conditions
Abstract: This paper focuses on the emergency cooling of the data center, conducts a numerical simulation study on the energy discharge process of the cold storage tank designed with a new flared type water diffuser under the condition of large flow rate and small temperature difference, obtains the temperature field and temperature variation curve of the energy discharge process, and calculates the dimensionless thermocline thickness and the energy discharge efficiency. The numerical simulation results are compared with those of the ideal model and the actual project monitoring data to verify the working performance of the new flared type water diffuser.
Keywords: large flow rate and small temperature difference; data center; emergency cooling; flared type water diffuser; thermocline thickness; energy discharge efficiency;
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