冷凝式消雾节水冷却塔消雾节水性能试验研究

doi:10.11930/j.issn.1004-9649.201902050

中国电力 ›› 2020, Vol. 53 ›› Issue (2): 180-184.DOI: 10.11930/j.issn.1004-9649.201902050

• 节能与环保 • 上一篇

冷凝式消雾节水冷却塔消雾节水性能试验研究

贾明晓, 胡三季, 李昊, 王斌

西安西热节能技术有限公司, 陕西西安 710054

收稿日期:2019-02-15 修回日期:2019-04-20 出版日期:2020-02-05 发布日期:2020-02-05
作者简介:贾明晓(1985-),男,硕士,工程师,从事冷却塔性能及节能研究,E-mail:jiamingxiao@tpri.com.cn

Experimental Study on Performance of Plume Abatement and Water-saving Cooling Tower with Condensate Method

JIA Mingxiao, HU Sanji, LI Hao, WANG Bin

Xi'an TPRI Energy Conservation Technology Co.,Ltd., Xi'an 710054, China

Received:2019-02-15 Revised:2019-04-20 Online:2020-02-05 Published:2020-02-05

摘要/Abstract

摘要： 冷凝式消雾节水冷却塔近年来在中国开始应用。为获得冷凝式消雾节水冷却塔的消雾节水性能，对某设计循环水量为4 000 m³/h的冷凝式消雾节水冷却塔的出塔空气参数及节水率进行了试验研究。在循环水流量接近设计值时，冬季消雾模式开启工况下，试验得到了出塔空气干、湿球温度及风速分布。试验结果表明：冷凝式消雾节水冷却塔出口，靠近风筒壁面的空气流速要高于塔中心处的空气流速；出塔空气参数经加权平均后相对湿度为64.2%，出塔空气的羽雾稀释曲线始终处于不饱和区，不易形成雾气团；在试验工况下该冷却塔的冷凝回收水量为11.357 m³/h，蒸发损失水量为45.440 m³/h，节水率为25%。

关键词: 循环水, 消雾节水冷却塔, 出塔空气参数, 消雾性能, 节水性能

Abstract: The condensate cooling towers for plume abatement and water-saving have been installed and applied in China in the recent years. To assess its plume abatement and water-saving performance, related experimental studies were conducted on a cooling tower with designed circulating water rate of 4 000 m³/h, where the outlet air parameters and water saving rate of this cooling tower were tested. When the circulation water volume was close to the design value, the outlet air dry-wet bulb temperature and velocity distribution were presented with the winter plume abatement mode turned on. The testing result shows that at the exit of the condensate cooling tower, the air flow velocity is higher around the wall surface than at the tower center. The average weighted air relative humidity was 64.2% such that no visible plume will form since the outlet air plume dilution line always lies in the unsaturated region. The amount of condensate water recollected was 11.357 m³/h and the mass of water loss was 45.440 m³/h due to evaporation. The water-saving rate of this cooling tower was 25% under testing conditions. The results can provide beneficial reference for the performance research of plume abatement and water-saving cooling towers.

Key words: circulating water, plume abatement and water-saving cooling tower, outlet air parameters, plume abatement performance, water-saving performance

贾明晓, 胡三季, 李昊, 王斌. 冷凝式消雾节水冷却塔消雾节水性能试验研究[J]. 中国电力, 2020, 53(2): 180-184.

JIA Mingxiao, HU Sanji, LI Hao, WANG Bin. Experimental Study on Performance of Plume Abatement and Water-saving Cooling Tower with Condensate Method[J]. Electric Power, 2020, 53(2): 180-184.

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https://www.electricpower.com.cn/CN/Y2020/V53/I2/180

参考文献

[1] HOOMAN K. Theoretical prediction with numerical and experimental verification to predict crosswind effects on the performance of cooling towers[J]. Heat Transfer Engineering, 2015, 36(5):480-487.
[2] 贾明晓, 胡三季, 樊志军, 等. 1000 MW机组大型海水冷却塔热力性能试验研究[J]. 中国电力, 2016, 49(10):28-32 JIA Mingxiao, HU Sanji, FAN Zhijun, et al. Experimental research on thermal performance of large seawater cooling tower used in 1000-MW power unit[J]. Electric Power, 2016, 49(10):28-32
[3] 齐慧卿, 高德申, 韩强, 等. 冷却塔内冷却水特性三维数值模拟研究[J]. 中国电力, 2017, 50(3):88-91 QI Huiqing, GAO Deshen, HAN Qiang, et al. Three-dimensional numerical simulation of cooling water characteristics[J]. Electric Power, 2017, 50(3):88-91
[4] 费全昌, 梁超. 火力发电厂湿式冷却系统节能分析[J]. 中国电力, 2012, 45(9):68-71 FEI Quanchang, LIANG Chao. Analysis on energy saving for water cooling system in thermal power plants[J]. Electric Power, 2012, 45(9):68-71
[5] 田小兵. 火力发电厂超大型高位收水冷却塔仪表与控制设计研究[J]. 中国电力, 2016, 49(7):113-117 TIAN Xiaobing. Study on design of the instrument and control of super high-level water collecting natural draft cooling towers for fossil fuel power plants[J]. Electric Power, 2016, 49(7):113-117
[6] 胡三季, 陈玉玲, 王明勇. 干-湿式机力通风冷却塔试验研究[J]. 工业用水与废水, 2010, 41(1):82-84 HU Sanji, CHEN Yuling, WANG Mingyong. Experimental study on dry-wet mechanical draft cooling tower[J]. Industrial Water & Wastewater, 2010, 41(1):82-84
[7] 吴晓敏, 姚奇, 王维城. 环保节水冷却塔的研究[J]. 工程热物理学报, 2007, 28(3):502-504 WU Xiaomin, YAO Qi, WANG Weicheng. Studies of environment-friendly water-saving cooling tower[J]. Journal of Engineering Thermophysics, 2007, 28(3):502-504
[8] 王晓静, 冯璟, 赵顺安. 机械通风冷却塔羽雾的形成机理及防治措施[J]. 电力建设, 2012, 33(3):52-55 WANG Xiaojing, FENG Jing, ZHAO Shunan. Mechanism of plume formation and its prevention method for mechanical-draft cooling tower[J]. Electric Power Construction, 2012, 33(3):52-55
[9] 赵顺安.冷却塔工艺原理[M]. 北京:中国建筑工业出版社, 2015:372-378.
[10] 王为术, 张斌, 赵鹏飞, 等. 机械通风冷却塔水蒸气冷凝回收方法[J]. 低温与超导, 2015, 43(6):76-78 WANG Weishu, ZHANG Bin, ZHAO Pengfei, et al. A condensate recovery method for water vapor in mechanical wet cooling tower[J]. Cryogenics & Superconductivity, 2015, 43(6):76-78
[11] Acceptance test procedure for wet-dry plume abatement cooling towers:ATC-150[S]. 2011.
[12] 赵振国. 冷却塔[M]. 2版. 北京:中国水利水电出版社, 2001:214-216.
[13] 机械通风冷却塔工艺设计规范:GB/T 50392-2016[S]. 2016.

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冷凝式消雾节水冷却塔消雾节水性能试验研究

Experimental Study on Performance of Plume Abatement and Water-saving Cooling Tower with Condensate Method

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冷凝式消雾节水冷却塔消雾节水性能试验研究

Experimental Study on Performance of Plume Abatement and Water-saving Cooling Tower with Condensate Method

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