WANGBao-gui,LINHong-yong,LIUYu-ting,et al.Analysis of Grit Sediment in a Sewage Treatment Plant and the Prevention Countermeasures[J].China Water & Wastewater,2023,39(18):107-111.
污水处理厂积砂情况分析与防治对策
- Title:
- Analysis of Grit Sediment in a Sewage Treatment Plant and the Prevention Countermeasures
- 摘要:
- 对某污水处理厂积砂情况进行调研,发现在前置缺氧区、厌氧区、出水口下游和内回流廊道转弯处存在明显积砂,且前置缺氧区和厌氧区积砂最为严重。对积砂的粒径分布进行分析表明,前置缺氧区和厌氧区的积砂中粒径>0.2 mm的分别占48%和51%,其他区域为30%左右。曝气沉砂池除砂效率低,导致大量砂粒进入生物系统,这是造成生物系统积砂的直接原因;而生物系统结构设计缺陷、混合功率不足是造成生物系统积砂的重要原因。因此,需要实施曝气沉砂池精细化运维,提升沉砂池的除砂效率;增设搅拌设备和导流设施,减少砂粒沉积。
- Abstract:
- The grit sediment of a sewage treatment plant was investigated, and it is found that there are obvious grit sediments in the pre-anoxic zone, anaerobic zone, downstream of the outlet and the turning point of the internal return corridor, among which most are in the pre-anoxic zone and the anaerobic zone. The analysis of particle size distribution shows that 48% and 51% of grit particles with size over 0.2 mm are in the pre-anoxic zone and anaerobic zone, and about 30% are in other points. The low grit removal efficiency of the aerated grit chamber leads to a large number of grit entering the biological system, which is the direct cause of grit sediment in the biological system. The structural design defects and insufficient mixing power in biological systems are main causes of the grit sediments. Therefore, it is necessary to implement refined operation and maintenance of aerated grit chamber to improve the grit removal capacity, as well as add mixing equipment and diversion facilities to reduce sand deposits.
相似文献/References:
[1]王 亮.马来西亚Pantai地埋式污水厂环网供配电结构设计[J].中国给水排水,2018,34(22):63.
WANG Liang.Power Supply and Distribution Structure Design of Ring Network for Pantai Underground Wastewater Treatment Plantin Malaysia[J].China Water & Wastewater,2018,34(18):63.
[2]侯晓庆,邓 磊,高海英,等.MBR工艺在神定河污水处理厂升级改造工程中的应用[J].中国给水排水,2018,34(22):66.
HOU Xiao-qing,DENG Lei,GAO Hai-ying,et al.Application of MBR Process in the Upgrading and Reconstruction Project of Shending River WastewaterTreatment Plant[J].China Water & Wastewater,2018,34(18):66.
[3]邱明海.北京市垡头污水处理厂改扩建工程设计技术方案[J].中国给水排水,2018,34(20):13.
QIU Ming hai.Reconstruction and Expansion Design Technical Plan of Beijing Fatou Wastewater Treatment Plant[J].China Water & Wastewater,2018,34(18):13.
[4]郝二成,郭毅,刘伟岩,等.基于数学模拟的污水厂运行分析——建模与体检[J].中国给水排水,2020,36(15):23.
HAO Er-cheng,GUO Yi,LIU Wei-yan,et al.Operation Analysis of Wastewater Treatment Plant Based on Mathematical Simulation: Modeling and Examination[J].China Water & Wastewater,2020,36(18):23.
[5]张月,王阳,张宏伟,等.阳泉市污水处理二期工程BARDENPHO工艺设计和运行[J].中国给水排水,2020,36(16):64.
ZHANG Yue,WANG Yang,ZHANG Hong-wei,et al.Design and Operation of BARDENPHO Process in Phase Ⅱ Project of Yangquan Wastewater Treatment Plant[J].China Water & Wastewater,2020,36(18):64.
[6]祝新军,蔡芝斌,姚斌,等.绍兴污水处理厂气浮设备的优化改造[J].中国给水排水,2020,36(16):101.
ZHU Xin-jun,CAI Zhi-bin,YAO Bin,et al.Optimization and Modification of Air Floatation Equipment in Shaoxing Wastewater Treatment Plant[J].China Water & Wastewater,2020,36(18):101.
[7]王文明,杨淇椋,蔡依廷,等.MSBR工艺在高排放标准污水处理厂的应用[J].中国给水排水,2020,36(16):111.
WANG Wen-ming,YANG Qi-liang,CAI Yi-ting,et al.Application of MSBR Process in Wastewater Treatment Plant with Stringent Discharge Standard[J].China Water & Wastewater,2020,36(18):111.
[8]郝二成,郭毅,刘伟岩,等.基于数学模拟的污水厂运行分析——控制与优化[J].中国给水排水,2020,36(17):23.
HAO Er-cheng,GUO Yi,LIU Wei-yan,et al.Operation Analysis of Wastewater Treatment Plant Based on Mathematical Simulation: Control and Optimization[J].China Water & Wastewater,2020,36(18):23.
[9]王阳,张月,王晓康,等.高排放标准下的改良AAO+深度处理工程案例[J].中国给水排水,2020,36(18):56.
WANG Yang,ZHANG Yue,WANG Xiao-kang,et al.Project Case of Modified AAO and Advanced Treatment Process under High Emission Standards[J].China Water & Wastewater,2020,36(18):56.
[10]郑枫,慕杨,孙逊.MBR工艺用于山东省某污水处理厂扩建工程[J].中国给水排水,2020,36(18):81.
ZHENG Feng,MU Yang,SUN Xun.MBR Process Used in Expansion Project of a Sewage Treatment Plant in Shandong Province[J].China Water & Wastewater,2020,36(18):81.