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[1]汤连生,周展朋,郑邓衡,等.聚乙二醇溶液渗析联合真空的污泥脱水研究[J].中国给水排水,2023,39(9):78-82.
TANGLian-sheng,ZHOUZhan-peng,ZHENGDeng-heng,et al.Sludge Dewatering Performance of Polyethylene Glycol Solution Dialysis Combined with Vacuum Pressure[J].China Water & Wastewater,2023,39(9):78-82.点击复制
聚乙二醇溶液渗析联合真空的污泥脱水研究
中国给水排水[ISSN:1000-4062/CN:12-1073/TU] 卷: 第39卷 期数: 2023年第9期 页码: 78-82 栏目: 出版日期: 2023-05-01
Title:Sludge Dewatering Performance of Polyethylene Glycol Solution Dialysis Combined with Vacuum Pressure
作者:汤连生1,2,3, 周展朋1,3,4, 郑邓衡1,3,4, 孙银磊1,3,4, 王玉玺1,3,4, 廖宇1,3,4(1.中山大学 地球科学与工程学院,广东 珠海 519082;2.广州理工学院 建筑工程学院,广东 广州 510540;3.南方海洋科学与工程广东省实验室<珠海>,广东 珠海 519082;4.广东省地球动力作用与地质灾害重点实验室,广东 珠海 519082)
Author(s):TANG Lian-sheng1,2,3, ZHOU Zhan-peng1,3,4, ZHENG Deng-heng1,3,4, SUN Yin-lei1,3,4, WANG Yu-xi1,3,4, LIAO Yu1,3,4(1. School of Earth Sciences and Engineering, Sun Yat-sen University, Zhuhai 519082, China; 2. School of Civil Engineering and Architecture, Guangzhou Institute of Science and Technology, Guangzhou 510540, China; 3. Southern Marine Science and Engineering Guangdong Laboratory, Zhuhai 519082, China; 4. Guangdong Provincial Key Lab of Geodynamics and Geohazards, Zhuhai 519082, China)
关键词:污泥脱水; 聚乙二醇溶液渗析; 真空压力; 有效影响距离; 脱水机理
Keywords:sludge dewatering; polyethylene glycol solution dialysis; vacuum pressure; effective influence distance; dewatering mechanism
摘要:聚乙二醇溶液渗析能够有效脱出污泥中的水分,可达到深度脱水的目的,但其有效脱水范围有限,难以直接应用于污泥的工业化脱水中。为此,进一步设计了聚乙二醇溶液渗析联合真空压力的污泥脱水试验,以分析多场联合作用下规模化的污泥脱水效果。试验结果表明,真空压力的作用能够显著提高聚乙二醇溶液渗析的有效脱水范围,在80 kPa真空压力作用下,聚乙二醇溶液渗析的有效影响距离可达到15.2 cm,与无真空压力作用相比提高了约181%。对脱水后的污泥进行扫描电镜及光学显微镜观察发现,真空压力可以压密污泥结构,阻碍聚乙二醇溶液渗析脱水过程中裂隙的形成,有利于排水通道的畅通,从而提高聚乙二醇溶液渗析的脱水效果及其有效性。
Abstract:Polyethylene glycol solution dialysis can effectively remove the water in the sludge and achieve deep dewatering. However, its effective dewatering range is limited, and it is difficult to be directly applied to the industrial dewatering of sludge. Therefore, the experiment of polyethylene glycol solution dialysis combined with vacuum pressure for sludge dewatering was further designed to analyze the large-scale sludge dewatering performance under the combined action of multiple fields. The vacuum pressure significantly improved the effective dewatering range of polyethylene glycol solution dialysis. When the vacuum pressure was 80 kPa, the effective influence distance of polyethylene glycol solution dialysis was increased to 15.2 cm, which was 181% higher than that without vacuum pressure. The dewatered sludge was observed by scanning electron microscope and optical microscope. Vacuum pressure compacted the sludge structure and hindered the formation of cracks during the dewatering process of polyethylene glycol solution dialysis, which was beneficial to the smooth flow of the drainage channel and improve the dewatering performance and effectiveness.
相似文献/References:
[1]马慧峰,钱志军,熊仁久,等.生物沥浸+厢式隔膜板框压滤机用于城镇污泥脱水[J].中国给水排水,2018,34(20):112.
MA Hui feng,QIAN Zhi jun,XIONG Ren jiu,et al.Application of Bioleaching and Chamber Diaphragm Plate Filter Press System in Sludge Dewatering Process[J].China Water & Wastewater,2018,34(9):112.
[2]赵林辉,林莉峰,朱运涛.大型污泥焚烧项目的污泥脱水运行优化研究[J].中国给水排水,2021,37(12):145.
ZHAO Lin-hui,LIN Li-feng,ZHU Yun-tao.Study on Operation Optimization of Sludge Dewatering in Large Scale Sludge Incineration Project[J].China Water & Wastewater,2021,37(9):145.
[3]郑松超,张彦平,李添添,等.紫外协同零价铁活化过硫酸盐调理污泥脱水研究[J].中国给水排水,2023,39(11):15.
ZHENGSong-chao,ZHANGYan-ping,LITian-tian,et al.Ultraviolet Coupled with Zero-valent Iron to Activate Persulfate for Improving Sludge Dewaterability[J].China Water & Wastewater,2023,39(9):15.
[4]张彦平,郑松超,孙雪萌,等.热改性给水污泥联合酸提液调理促进剩余污泥脱水[J].中国给水排水,2023,39(13):39.
ZHANGYan-ping,ZHENGSong-chao,SUNXue-meng,et al.Heat Modified Sludge from Waterworks Combined with Its Acid Extract Conditioning to Promote Excess Sludge Dewatering[J].China Water & Wastewater,2023,39(9):39.
[5]何妙琳,张彦平,李一兵.电解耦合Fe2+活化过硫酸盐强化污泥脱水及其机理[J].中国给水排水,2023,39(15):15.
HEMiao-lin,ZHANGYan-ping,LIYi-bing.Enhancement and Mechnism of Electrolysis Coupled Fe2+-activated Persulfate Oxidation for Excess Sludge Dewatering[J].China Water & Wastewater,2023,39(9):15.
[6]蓝梅,应媛媛,罗海慧,等.典型污水处理工艺的污泥调理机制研究[J].中国给水排水,2023,39(15):94.
LAN Mei,YING Yuan-yuan,LUO Hai-hui,et al.Sludge Conditioning Mechanism of Typical Wastewater Treatment Processes[J].China Water & Wastewater,2023,39(9):94.
更新日期/Last Update: 2023-05-01
[1]汤连生,周展朋,郑邓衡,等.聚乙二醇溶液渗析联合真空的污泥脱水研究[J].中国给水排水,2023,39(9):78-82.
TANGLian-sheng,ZHOUZhan-peng,ZHENGDeng-heng,et al.Sludge Dewatering Performance of Polyethylene Glycol Solution Dialysis Combined with Vacuum Pressure[J].China Water & Wastewater,2023,39(9):78-82.
点击复制
TANGLian-sheng,ZHOUZhan-peng,ZHENGDeng-heng,et al.Sludge Dewatering Performance of Polyethylene Glycol Solution Dialysis Combined with Vacuum Pressure[J].China Water & Wastewater,2023,39(9):78-82.
聚乙二醇溶液渗析联合真空的污泥脱水研究
中国给水排水[ISSN:1000-4062/CN:12-1073/TU] 卷: 第39卷 期数: 2023年第9期 页码: 78-82 栏目: 出版日期: 2023-05-01
- Title:
- Sludge Dewatering Performance of Polyethylene Glycol Solution Dialysis Combined with Vacuum Pressure
- Keywords:
- sludge dewatering; polyethylene glycol solution dialysis; vacuum pressure; effective influence distance; dewatering mechanism
摘要:- 聚乙二醇溶液渗析能够有效脱出污泥中的水分,可达到深度脱水的目的,但其有效脱水范围有限,难以直接应用于污泥的工业化脱水中。为此,进一步设计了聚乙二醇溶液渗析联合真空压力的污泥脱水试验,以分析多场联合作用下规模化的污泥脱水效果。试验结果表明,真空压力的作用能够显著提高聚乙二醇溶液渗析的有效脱水范围,在80 kPa真空压力作用下,聚乙二醇溶液渗析的有效影响距离可达到15.2 cm,与无真空压力作用相比提高了约181%。对脱水后的污泥进行扫描电镜及光学显微镜观察发现,真空压力可以压密污泥结构,阻碍聚乙二醇溶液渗析脱水过程中裂隙的形成,有利于排水通道的畅通,从而提高聚乙二醇溶液渗析的脱水效果及其有效性。
Abstract:- Polyethylene glycol solution dialysis can effectively remove the water in the sludge and achieve deep dewatering. However, its effective dewatering range is limited, and it is difficult to be directly applied to the industrial dewatering of sludge. Therefore, the experiment of polyethylene glycol solution dialysis combined with vacuum pressure for sludge dewatering was further designed to analyze the large-scale sludge dewatering performance under the combined action of multiple fields. The vacuum pressure significantly improved the effective dewatering range of polyethylene glycol solution dialysis. When the vacuum pressure was 80 kPa, the effective influence distance of polyethylene glycol solution dialysis was increased to 15.2 cm, which was 181% higher than that without vacuum pressure. The dewatered sludge was observed by scanning electron microscope and optical microscope. Vacuum pressure compacted the sludge structure and hindered the formation of cracks during the dewatering process of polyethylene glycol solution dialysis, which was beneficial to the smooth flow of the drainage channel and improve the dewatering performance and effectiveness.
相似文献/References:
[1]马慧峰,钱志军,熊仁久,等.生物沥浸+厢式隔膜板框压滤机用于城镇污泥脱水[J].中国给水排水,2018,34(20):112.
MA Hui feng,QIAN Zhi jun,XIONG Ren jiu,et al.Application of Bioleaching and Chamber Diaphragm Plate Filter Press System in Sludge Dewatering Process[J].China Water & Wastewater,2018,34(9):112.
[2]赵林辉,林莉峰,朱运涛.大型污泥焚烧项目的污泥脱水运行优化研究[J].中国给水排水,2021,37(12):145.
ZHAO Lin-hui,LIN Li-feng,ZHU Yun-tao.Study on Operation Optimization of Sludge Dewatering in Large Scale Sludge Incineration Project[J].China Water & Wastewater,2021,37(9):145.
[3]郑松超,张彦平,李添添,等.紫外协同零价铁活化过硫酸盐调理污泥脱水研究[J].中国给水排水,2023,39(11):15.
ZHENGSong-chao,ZHANGYan-ping,LITian-tian,et al.Ultraviolet Coupled with Zero-valent Iron to Activate Persulfate for Improving Sludge Dewaterability[J].China Water & Wastewater,2023,39(9):15.
[4]张彦平,郑松超,孙雪萌,等.热改性给水污泥联合酸提液调理促进剩余污泥脱水[J].中国给水排水,2023,39(13):39.
ZHANGYan-ping,ZHENGSong-chao,SUNXue-meng,et al.Heat Modified Sludge from Waterworks Combined with Its Acid Extract Conditioning to Promote Excess Sludge Dewatering[J].China Water & Wastewater,2023,39(9):39.
[5]何妙琳,张彦平,李一兵.电解耦合Fe2+活化过硫酸盐强化污泥脱水及其机理[J].中国给水排水,2023,39(15):15.
HEMiao-lin,ZHANGYan-ping,LIYi-bing.Enhancement and Mechnism of Electrolysis Coupled Fe2+-activated Persulfate Oxidation for Excess Sludge Dewatering[J].China Water & Wastewater,2023,39(9):15.
[6]蓝梅,应媛媛,罗海慧,等.典型污水处理工艺的污泥调理机制研究[J].中国给水排水,2023,39(15):94.
LAN Mei,YING Yuan-yuan,LUO Hai-hui,et al.Sludge Conditioning Mechanism of Typical Wastewater Treatment Processes[J].China Water & Wastewater,2023,39(9):94.
更新日期/Last Update: 2023-05-01
