中国城市污水处理工程污泥处置技术研究进展

doi:10.11894/iwt.2019-0622

摘要/Abstract

摘要：

随着我国城市化进程的发展，集中污水处理越来越普及，随之而来的是污泥产量的大幅增长。基于我国污泥处置现状，概述了稳定填埋、干化+焚烧+填埋、干化+土地利用、厌氧消化/好氧堆肥+土地利用、干化+热解、烧制+建筑材料等六种处置方法，并分析了各种处置技术的优缺点；最后展望了污泥资源化途径有待深入研究的方面，并提出建设性的意见。

关键词: 城市污泥, 污泥处置, 处置技术, 资源化

Abstract:

As the development of urbanization in China, centralized sewage treatment is becoming popular. At the same time, the sludge production has increased substantially. According to the current status of sludge disposal in China, this review outlined six disposal methods, including stable landfill, desiccation+incineration+landfill, desiccation+land use, anaerobic digestion/aerobic composting+land use, desiccation+pyrolysis, fired+building materials and analyzed the advantages and disadvantages of each disposal technology. Furthermore, some constructive comments were suggested on sludge resource utilization.

Key words: urban sludge, sludge disposal, disposal technology, resource utilization

中图分类号:

X703

谢昆,尹静,陈星. 中国城市污水处理工程污泥处置技术研究进展[J]. 工业水处理, 2020, 40(7): 18-23.

Kun Xie,Jing Yin,Xing Chen. Research progress on sludge treatment technology of urban sewage treatment project in China[J]. Industrial Water Treatment, 2020, 40(7): 18-23.

https://www.iwt.cn/CN/Y2020/V40/I7/18

图/表 4

参考文献 61

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焚烧技术	处理温度	优点	缺点	技术难点
熔渣式回转窑焚烧	1 200~1 430℃	对污泥预处理要求较低。灰渣熔融固化效果好，可作为建筑材料使用，无二次污染	处理量小，对耐火材料要求高。灰渣易黏在炉体内侧，影响出料	能耗高，处理成本高，维护成本高
水泥窑协同焚烧	1 350~1 650℃	热容量大，处理量大。残渣尧重金属被固化在水泥熟料中，二噁英可完全分解	需对投加的污泥成分进行检测，需核算入炉的重金属量	处理温度高，能耗高，处理成本高
独立流化床焚烧	800~950℃	对污泥含水率要求低，焚烧效率高，病原体能实现完全杀灭，设备尺寸相对较小	不能使重金属熔融固化，需要进行二次熔融处理；烟气含尘量多	设备磨损严重，维护成本高
循环流化床焚烧	850℃左右	热稳定性强，含重金属较多的飞灰可以通过旋风分离器再次送回炉内循环焚烧	锅炉体积大，对污泥含水率和掺烧量要求，烟气停留时间短可能产生二噁英	灰渣需要二次熔融处理或填埋

焚烧技术	处理温度	优点	缺点	技术难点
熔渣式回转窑焚烧	1 200~1 430℃	对污泥预处理要求较低。灰渣熔融固化效果好，可作为建筑材料使用，无二次污染	处理量小，对耐火材料要求高。灰渣易黏在炉体内侧，影响出料	能耗高，处理成本高，维护成本高
水泥窑协同焚烧	1 350~1 650℃	热容量大，处理量大。残渣尧重金属被固化在水泥熟料中，二噁英可完全分解	需对投加的污泥成分进行检测，需核算入炉的重金属量	处理温度高，能耗高，处理成本高
独立流化床焚烧	800~950℃	对污泥含水率要求低，焚烧效率高，病原体能实现完全杀灭，设备尺寸相对较小	不能使重金属熔融固化，需要进行二次熔融处理；烟气含尘量多	设备磨损严重，维护成本高
循环流化床焚烧	850℃左右	热稳定性强，含重金属较多的飞灰可以通过旋风分离器再次送回炉内循环焚烧	锅炉体积大，对污泥含水率和掺烧量要求，烟气停留时间短可能产生二噁英	灰渣需要二次熔融处理或填埋

控制项目	污染物限值
控制项目	A级	B级
总镉	＜3	＜15
总汞	＜3	＜15
总铅	＜300	＜1 000
总铬	＜500	＜1 000
总砷	＜30	＜75
总镍	＜100	＜200
总锌	＜1 200	＜3 000
总铜	＜500	＜1 500
矿物油	＜500	＜3 000
苯并(α)芘	＜2	＜3
多环芳烃（PAHs）	＜5	＜6

控制项目	污染物限值
控制项目	A级	B级
总镉	＜3	＜15
总汞	＜3	＜15
总铅	＜300	＜1 000
总铬	＜500	＜1 000
总砷	＜30	＜75
总镍	＜100	＜200
总锌	＜1 200	＜3 000
总铜	＜500	＜1 500
矿物油	＜500	＜3 000
苯并(α)芘	＜2	＜3
多环芳烃（PAHs）	＜5	＜6

处置方式	工艺路线	投资	运行成本
协同焚烧	干化+垃圾焚烧厂协同焚烧	无需新增投资	运输费约10元/t、焚烧费用约30元/t合计增加40元/t（均以80%含水率计）
	干化+电厂协同烧	建设投资费用1 165万元	运输费约10元/t、焚烧费用约120元/t，合计增加130元/t（均以80%含水率计）
土地利用	脱水+简易堆肥+土地利用	土地流转费72万元（按照3 a、8万m²测算）；应急堆场场地建设费500万元	—
建材利用	高干脱水+建材利用	经测算，改造项目总投资约6 300万元，另有建材厂改造费用330万元	高干脱水运行费用150元/t（不采用影响后期利用的脱水药剂）；建材协同处置费用140元/t，合计290元/t

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