燃煤电厂水平衡模型与节水分析

doi:10.11930/j.issn.1004-9649.202103028

中国电力 ›› 2022, Vol. 55 ›› Issue (4): 221-228.DOI: 10.11930/j.issn.1004-9649.202103028

• 发电 • 上一篇

燃煤电厂水平衡模型与节水分析

刘广建¹, 岳凤站¹, 周硕¹, 王琳¹, 干雪²

1. 华北电力大学能源动力与机械工程学院，北京 102206;
2. 公诚管理咨询有限公司，北京 510610

收稿日期:2021-03-10 修回日期:2022-02-21 出版日期:2022-04-28 发布日期:2022-04-24
作者简介:刘广建（1977—），男，博士，副教授，通信作者，从事洁净煤技术，热力系统建模等研究，E-mail：liugj@ncepu.edu.cn
基金资助:
国家重点研发计划资助项目（燃煤机组水分回收与处理过程热质分布规律与能效评价,2018YFB0604301）

Water Balance Model and Water-Saving Analysis for Coal-fired Power Plants

LIU Guangjian¹, YUE Fengzhan¹, ZHOU Shuo¹, WANG Lin¹, GAN Xue²

1. School of Energy, Power and Mechanical Engineering, North China Electric Power University, Beijing 102206, China;
2. Gongcheng Management Consulting Co., Ltd., Beijing 510610, China

Received:2021-03-10 Revised:2022-02-21 Online:2022-04-28 Published:2022-04-24
Supported by:
This work is supported by National Key R&D Program of China (Heat and Mass Distribution Law and Energy Efficiency Evaluation in Water Recovery and Treatment Process of Coal-fired Power Plants, No.2018 YFB0604301).

摘要/Abstract

摘要： 随着水资源的日益短缺和火电装机容量的持续增加，应用节水技术是目前火电行业可持续发展的重要途径。基于煤种、气象条件和电厂性能参数，提出了电厂水平衡模型，绘制了电厂水流图，直观体现了进入和离开电厂的水平衡关系，辨析系统节水的关键环节。定量分析了烟气余热及水分回收系统的节能和节水效果。以燃烟煤的超临界机组为例，在离开电厂的水流中，冷却塔蒸发、风吹损失占60%，冷却塔排污占20%，排烟中水分占15%。火电厂节水的重点在于冷却系统、废水排放和排烟水分回收。针对火电厂余热和水分回收的系统，理论计算表明：对于湿冷机组，如果烟气水分回收60%，则超临界机组单位供电量耗水量下降19.2%；对于空冷机组，如果烟气水分回收60%，则电厂的取水量为零；如果同时采用半干法或干法脱硫系统，则电厂可以成为供水方。

关键词: 水平衡, 水流图, 深度节水, 水耗指标, 烟气水分回收

Abstract: With the increasing shortage of water resources and the continuous increase of thermal power installed capacity, the application of water-saving technology is an essential issue for the sustainable development of the thermal power industry. The water balance model and water flow diagram is proposed based on coal type, meteorological conditions, and power plant performance parameters. From the water flow diagram, the water balance relationship is intuitively reflected between entering and leaving streams. The key processes to reduce system water use were identified. The energy and water-saving effects of flue gas waste heat and water recovery system are quantitatively analyzed. For supercritical power plant burning bituminous coal, about 60% water losses come from cooling tower evaporation and wind blowing, while cooling tower blowdown accounts for 20%. The moisture content in exhaust fluegas accounts for 15%. The critical points of water saving in thermal power plants are cooling systems, wastewater discharge, and moisture recovery from flue gas. This paper presents a waste heat and moisture recovery from flue gas system. The preliminary analysis shows that, for wet-cooled units, the water consumption per MW·h will drop by 19.2% with flue gas moisture recovered by 60%. For air-cooled units, if the flue gas moisture is recovered by 60%, the water withdraw of the power plant will be zero. If the semi-dry or dry desulfurization system is adopted at the same time, the power plant can become the water supplier.

Key words: water balance, water flow chart, deepwater conservation, water consumption index, flue gas moisture recovery

刘广建, 岳凤站, 周硕, 王琳, 干雪. 燃煤电厂水平衡模型与节水分析[J]. 中国电力, 2022, 55(4): 221-228.

LIU Guangjian, YUE Fengzhan, ZHOU Shuo, WANG Lin, GAN Xue. Water Balance Model and Water-Saving Analysis for Coal-fired Power Plants[J]. Electric Power, 2022, 55(4): 221-228.

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燃煤电厂水平衡模型与节水分析

Water Balance Model and Water-Saving Analysis for Coal-fired Power Plants

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Water Balance Model and Water-Saving Analysis for Coal-fired Power Plants

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