RESEARCH PROGRESS ON POLLUTION AND CONTROL OF SEWAGE SOURCE HEAT PUMP HEAT EXCHANGER

WANG Kaihan; YANG Qing; LIU Xiuhong; WANG Jingfan

doi:10.13205/j.hjgc.202408009

Volume 42 Issue 8

Aug. 2024

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Article Navigation > ENVIRONMENTAL ENGINEERING > 2024 > 42(8): 72-77

WANG Kaihan, YANG Qing, LIU Xiuhong, WANG Jingfan. RESEARCH PROGRESS ON POLLUTION AND CONTROL OF SEWAGE SOURCE HEAT PUMP HEAT EXCHANGER[J]. ENVIRONMENTAL ENGINEERING , 2024, 42(8): 72-77. doi: 10.13205/j.hjgc.202408009

Citation:

WANG Kaihan, YANG Qing, LIU Xiuhong, WANG Jingfan. RESEARCH PROGRESS ON POLLUTION AND CONTROL OF SEWAGE SOURCE HEAT PUMP HEAT EXCHANGER[J]. ENVIRONMENTAL ENGINEERING , 2024, 42(8): 72-77. doi: 10.13205/j.hjgc.202408009

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RESEARCH PROGRESS ON POLLUTION AND CONTROL OF SEWAGE SOURCE HEAT PUMP HEAT EXCHANGER

doi: 10.13205/j.hjgc.202408009

National Engineering Laboratory for Advanced Municipal Wastewater Treatment and Reuse Technology, Beijing University of Technology, Beijing 100124, China

Received Date: 2023-07-08
Available Online: 2024-12-02

Abstract

Abstract

Sewage contains abundant heat energy. Recycling heat energy in sewage is an important research direction in the field of energy conservation. Sewage source heat pump technology is an important technical means for recycling sewage heat energy. However, the long-term operation of sewage source heat pump in sewage will cause its heat exchanger affected by corrosion and scaling, thereby reducing the conversion efficiency of sewage heat energy and the resource utilization rate of sewage treatment plants. Therefore, taking the water source heat pump heat exchanger of urban sewage treatment plant as the research object, the key water quality factors affecting its heat transfer performance are deeply explored, and the effect of protective measures taken under complex water quality conditions is comprehensively evaluated. This study provides a reference for solving the long-term pollution problems of water source heat pump heat exchanger in the sewage treatment process with high efficiency and low cost, helps achieve the goal of carbon neutralization operation of sewage treatment.
- sewage source heat pump,
- heat exchanger,
- corrosion,
- conservatory measure,
- wastewater treatment,
- carbon neutral

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References

[1]	GAUR A S, FITIWI D Z, CURTIS J. Heat pumps and our low-carbon future: a comprehensive review[J]. Energy Research & Social Science, 2021,71: 101764.
[2]	戴晓虎, 张辰, 章林伟, 等. 碳中和背景下污泥处理处置与资源化发展方向思考[J]. 给水排水, 2021,57(3): 1-5.
[3]	HUANG R, XU J, XIE L, et al. Energy neutrality potential of wastewater treatment plants: a novel evaluation framework integrating energy efficiency and recovery[J]. Frontiers of Environmental Science & Engineering, 2022,16(9): 117.
[4]	HAO X, LI J, LOOSDRECHT M V, et al. Energy recovery from wastewater: heat over organics[J]. Water Research, 2019,161: 74-77.
[5]	LYU S, WANG C, ZHANG C, et al. Experimental characterization of a novel soft polymer heat exchanger for wastewater heat recovery[J]. International Journal of Heat and Mass Transfer, 2020,161: 120256.
[6]	田梦然. 水源热泵用换热设备常用金属的腐蚀性能研究[D]. 青岛: 青岛大学, 2016.
[7]	孟凡凯, 马世成. 换热管缝隙腐蚀的失效分析[J]. 化工装备技术, 2021,42(1): 34-38.
[8]	LIU X, ZHU H, YU C, et al. Analysis on the corrosion failure of U-tube heat exchanger in hydrogenation unit[J]. Engineering Failure Analysis, 2021,125: 105448.
[9]	ROMANOVSKI V, HEDBERG Y S, PASPELAU A, et al. Corrosion failure of titanium tubes of a heat exchanger for the heating of dissolving lye[J]. Engineering Failure Analysis, 2021,129: 105722.
[10]	REZAEI M, MAHIDASHTI Z, EFTEKHARI S, et al. A corrosion failure analysis of heat exchanger tubes operating in petrochemical refinery[J]. Engineering Failure Analysis, 2021,119: 105011.
[11]	HE Z, GUAN K, JIANG T, et al. Localized cavitation corrosion on heat exchange tubes in a reboiler: design and operation causes[J]. Engineering Failure Analysis, 2021,130: 105773.
[12]	PANAHI H, ESLAMI A, GOLOZAR M A, et al. An investigation on corrosion failure of a shell-and-tube heat exchanger in a natural gas treating plant[J]. Engineering Failure Analysis, 2020,118: 104918.
[13]	YANG X, GONG Y, YANG Z. Failure analysis on abnormal leakage between tubes and tubesheet of spiral-wound heat exchanger for nuclear power plant[J]. Engineering Failure Analysis, 2020,118: 104900.
[14]	AGUILERA J J, MEESENBURG W, OMMEN T, et al. A review of common faults in large-scale heat pumps[J]. Renewable and Sustainable Energy Reviews, 2022,168: 112826.
[15]	QIAO L J, GAO K W, VOLINSKY A A, et al. Discontinuous surface cracks during stress corrosion cracking of stainless steel single crystal[J]. Corrosion Science, 2011,53(11): 3509-3514.
[16]	FERREIRA M G S, DAWSON J L. Electrochemical studies of the passive film on 316 stainless steel in chloride media[J]. Journal of the Electrochemical Society, 1985,132(4): 760-765.
[17]	卫炳森, 陈峰, 高炬. 循环水系统结垢、腐蚀原因及处理措施[J]. 化学工程与装备, 2022(4): 168-169.
[18]	庄兆意, 徐君, 王光斌, 等. 污垢对两种污水源热泵系统供热性能影响研究[J]. 山东建筑大学学报, 2021,36(4): 20-26.
[19]	赵国栋, 侯岩, 郭志军, 等. 焊接板式换热器腐蚀现状及防腐涂层对策浅析[J]. 材料保护, 2022,55(8): 51-56.
[20]	聂明成. 换热器腐蚀与防护的现状与展望分析[J]. 化工管理, 2018(31): 138.
[21]	石泽鑫, 张学伟, 盖东兴. 塑料换热器在污染介质余热回收中的应用[J]. 山东化工, 2022,51(13): 85-88.
[22]	邹山梅, 赵丽丽. 金属冶炼设备常见腐蚀原因及防腐措施[J]. 世界有色金属, 2022(3): 25-27.
[23]	刘正东. 炼油厂换热器应力腐蚀失效机理及防护措施研究[J]. 石化技术, 2022,29(3): 27-28.
[24]	朱立军, 刘尚铭. 炼油厂污水处理设备管线腐蚀分析及防治措施[J]. 化学工程师, 2022,36(8): 85-88.
[25]	CHOUDHURY M R, HSIEH M, VIDIC R D, et al. Corrosion management in power plant cooling systems using tertiary-treated municipal wastewater as makeup water[J]. Corrosion Science, 2012,61: 231-241.
[26]	徐丽英, 何彦霏, 奚昊敏. 氧化淀粉水处理剂的研究[J]. 净水技术, 2001(2): 27-29.
[27]	王庆生, 阎寒冰, 赵爱民, 等. 城市生活污水处理后回用作热电厂循环冷却水的可行性研究[J]. 环境污染治理技术与设备, 2006(1): 68-71.
[28]	肖遥, 郭稚弧, 谭晓明, 等. 天然单宁改性水处理剂的制备及应用[J]. 工业水处理, 1998(3): 22-24.
[29]	王伟. 化工机械设备腐蚀成因及防腐策略[J]. 化学工程与装备, 2021(8): 196-197.
[30]	白丽萍, 孟宪级, 陈嘉兴. 耐地热水防蚀涂层的研究[J]. 腐蚀与防护, 1998(2): 61-63.
[31]	姚天奇, 刘亚茹, 陈志军, 等. 含醇污水处理装置冷换设备防腐及修复技术[J]. 石油化工设备, 2012,41(2): 125-128.
[32]	魏金伯, 李至秦, 付率, 等. 耐温疏水型碳钢管束防腐涂料的制备及研究[J]. 中国涂料, 2017,32(10): 34-36.

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