某城市污水处理厂毕业设计含图纸

某城市污水处理厂二级处理工艺设计第一节设计任务及要求一、课程设计题目某城市污水处理厂二级处理工艺设计三、课程设计基础资料某城市污水处理厂二级处理工艺设计（附件1）四、课程设计内容和要求（一）设计内容：根据任务书给定资料，完成一个小型污水处理厂的工艺设计。

2、设计图纸图纸右下角为设计图签，注明图名、比例、学生班级、姓名等。

（1）污水处理厂总平面布置图1张（A3 CAD图）。

①要求以计算或选定尺寸按一定比例绘出全部处理构筑物、及附属建筑物、道路、绿化、厂界。

厂区内构筑物布置要合理，可按功能划分成几个区域（如：污水处理区、污泥处理区、办公及辅助区等）。

标注构筑物外形尺寸、平面位置（可用相对坐标（x, y）表示，以某点的相对坐标为零点）；②绘出各种管渠、阀门、检查井等（例如：污水管、排泥管、回流污泥管、超越管、总事故管、空气管、上清液管、沼气管等）。

标注管径、渠道尺寸、长度和坡度；③在右上角绘出指北针；④绘制管线等图例；⑤列表说明图中构（建）筑物的名称、数量和尺寸；⑥图纸布局要美观。

（3）污水处理厂高程布置图1张（A3 CAD图）。

①在污水与污泥处理流程中，要求沿污水、污泥在处理厂中流动的最长路程绘制流程中各处理构筑物、连接管渠的剖面展开图（从污水进厂的粗格栅起，至处理后的排水渠）；②图中要画出设计地面线、构筑物中水面线及标高，标注各构筑物的顶部、底部及水面线标高，标注构筑物名称；1③图纸布局要美观。

第二章污水处理工艺流程说明第一节设计规模的确定1.1 设计题目某城市污水处理厂二级处理工艺设计1.2 设计资料（1）设计水量：100 000 Td；（2）水质：表1-1 设计水质表（3）处理要求：出水水质达到城镇污水处理厂污染物排放标准（GB18918-2002）中的二级标准。

表1-2 排放水质表（4）厂区条件：①地势平坦，为300×300㎡一方形厂区；②气象条件：常年平均气温13℃；③工程地质：厂址周围工程地质良好，适合于修建城市污水处理厂，厂区平均海拔高程450m。

目录引言................................................. 错误!未定义书签。

1 设计任务及概况 (6)1.1设计任务及依据 (6)1.1.1 设计任务 (6)1.1.2 设计依据及原则 (6)1.1.3设计围 (7)1.2设计水量及水质 (7)1.2.1设计水量 (7)1.2.2设计水质 (7)1.3.3设计人口 (7)2 工艺设计方案的确定 (8)2.1方案确定的原则 (8)2.2污水处理工艺流程的确定 (8)2.2.1厂址及地形资料 (8)2.2.2气象及水文资料 (9)2.2.3可行性方案的确定 (9)2.2.4工艺流程方案的确定 (10)2.2.5污泥处理工艺流程 (12)2.3主要构筑物的选择 (12)2.3.1格栅 (12)2.3.2泵房 (13)2.3.3沉砂池 (13)2.3.4初沉池、二沉池 (14)2.3.5曝气池 (14)2.3.6接触池 (15)2.3.7计量槽 (16)2.3.8浓缩池 (16)2.3.9消化池 (16)2.3.10污泥脱水 (17)3污水处理系统工艺设计 (17)3.1格栅的计算 (17)3.1.1粗格栅 (17)3.1.2格栅的计算 (18)3.1.3选型 (21)3.2泵房 (21)3.2.1泵房的选择 (21)3.2.2泵的选择及集水池的计算 (21)3.2.3扬程估算 (22)3.3细格栅 (22)3.3.1细格栅的计算： (22)3.3.2格栅的计算 (23)3.3.3选型 (25)3.4沉砂池的计算 (26)3.4.1池体计算 (26)3.4.2沉砂室尺寸计算 (27)3.4.3排砂 (29)3.4.4出水水质 (30)3.5初沉池 (30)3.5.1池体尺寸计算 (30)3.5.2中心管计算 (33)3.5.3出水堰的计算 (34)3.5.4集配水井计算 (35)3.5.5出水水质 (35)3.5.6选型 (36)3.6曝气池 (36)3.6.1池体计算 (36)3.6.2曝气系统设计与计算 (39)3.6.3供气量 (40)3.6.4空气管道系统计算 (43)3.6.5空压机的选择 (46)3.6.6污泥回流系统 (46)3.7二沉池 (47)3.7.1池体尺寸计算 (47)3.7.2中心管计算 (50)3.7.3出水堰的计算 (51)3.7.4集配水井计算 (51)3.7.5出水水质 (53)3.7.6选型 (53)3.8接触池 (53)3.8.1接触池尺寸计算 (53)3.8.2加氯间 (54)3.9计量槽 (55)4 污泥的处理与处置 (55)4.1污泥浓缩池 (55)4.2污泥消化池 (59)4.2.1 一级消化池池体部分计算 (59)4.2.2 一级消化池池体各部分表面积计算 (61)4.2.3二级消化池 (62)4.3贮气柜 (62)4.4污泥控制室 (63)4.4.1污泥投配泵的选择 (63)4.4.2污泥循环泵 (64)4.4.3污泥控制室布局 (65)4.5脱水机房 (65)4.5.1采用带式压滤机除水 (65)4.5.2选型 (66)4.6事故干化场 (66)4.7压缩机房 (67)5 污水处理厂总体布置 (67)5.1平面布置 (67)5.1.1平面布置的一般原则 (67)5.1.2 平面布置 (67)5.2污水处理厂高程布置 (68)5.2.1高程布置原则 (68)5.2.2污水污泥处理系统高程布置 (69)总结 (70)参考文献 (72)致 ................................................... 错误!未定义书签。

本设计污水处理厂综合设计包括15个图纸，十分全面，具体详见报告后附图。

本报告附图全面详细。

图纸内容如下：A2O池，初沉池，幅流式二沉池，隔栅，工艺简单图，工艺流程图（高程图），回转耙式格栅除污机图，平面布置图，污泥浓缩池，厌氧消化池，钟式沉砂池等。

全为CAD制图。

下载后复制放大或打印可看清！题目20000m3/d城市污水处理厂综合设计专业: 环境工程年级: 2005级学号: 3105001286姓名: 莫笑伟指导教师:2008年12 月摘要我国水体污染主要来自两方面，一是工业发展超标排放工业废水，二是城市化中由于城市污水排放和集中处理设施严重缺乏，大量生活污水未经处理直接进入水体造成环境污染。

工业废水近年来经过治理虽有所减少，但城市生活污水有增无减，占水质污染的51%以上。

我国水体污染主要来自两方面，一是工业发展超标排放工业废水，二是城市化中由于城市污水排放和集中处理设施严重缺乏，大量生活污水未经处理直接进入水体造成环境污染。

工业废水近年来经过治理虽有所减少，但城市生活污水有增无减，占水质污染的51%以上。

本设计要求处理水量为20000m3/d的城市生活污水，设计方案针对已运行稳定有效的A2/O活性污泥法工艺处理城市生活污水。

A2O工艺由于不同环境条件，不同功能的微）能生物群落的有机配合，加之厌氧、缺氧条件下，部分不可生物降解的有机物（CODNB被开环或断链，使得N、P、有机碳被同时去除，并提高对COD的去除效果。

它可以同NB－－时完成有机物的去除，硝化脱氮、磷的过量摄取而被去除等功能，脱氮的前提是NH3N应完全硝化，好氧池能完成这一功能，缺氧池则完成脱氮功能。

厌氧池和好氧池联合完成除磷功能。

关键词：城市生活污水，活性污泥，A2/O目录摘要 (III)目录 (IV)第一章设计概述 ······································································- 7 -1设计任务 ······································································- 7 - 2设计原则 ······································································- 7 - 3设计依据 ······································································- 8 - 第二章工艺流程及说明 ·····························································- 8 -1工艺方案分析 ································································- 8 - 2工艺流程 ······································································- 9 - 3流程各结构介绍 ·····························································- 9 -3.1格栅······························································································· - 9 -3.2沉砂池··························································································- 10 -3.3初沉池··························································································- 10 -3.4生物化反应池··············································································- 10 -3.5二沉池··························································································- 12 -3.6浓缩池··························································································- 12 - 第三章构筑物设计计算 ··························································· - 12 -1格栅 ·········································································· - 12 -1.1设计说明······················································································- 12 -1.2设计计算······················································································- 13 -2沉砂池 ······································································· - 16 -2.1设计说明······················································································- 16 - 3初沉池 ······································································· - 17 -3.1设计说明······················································································- 17 -3.2设计计算······················································································- 17 - 4生化池 ······································································· - 19 -4.1设计说明······················································································- 19 -4.2设计计算······················································································- 19 - 5二沉池 ······································································· - 26 -5.1设计说明······················································································- 26 -5.2设计计算······················································································- 26 - 6液氯消毒 ···································································· - 29 -6.1设计说明······················································································- 29 -6.2设计计算······················································································- 29 - 7污泥浓缩池 ································································· - 30 -7.1设计说明······················································································- 30 -7.2设计计算······················································································- 30 -8 污泥消化池 ································································· - 31 -8.1设计说明······················································································- 31 -8.2设计计算······················································································- 32 - 9浓缩污泥提升泵房 ························································ - 38 -9.1设计选型······················································································- 38 -9.2提升泵房······················································································- 38 -9.3污泥回流泵站··············································································- 38 -10污泥脱水间 ······························································· - 39 -10.1设计说明······················································································- 39 -11鼓风机房 ·································································· - 39 - 12恶臭处理系统 ···························································· - 39 -12.1设计说明······················································································- 39 -12.2设计计算······················································································- 39 -12.3风机选型······················································································- 40 - 第四章污水处理厂总体布置 ····················································· - 41 -1总平面布置 ································································· - 41 -1.1总平面布置原则··········································································- 41 -1.2总平面布置结果··········································································- 41 -2高程布置································································································- 42 -2.1高程布置原则··············································································- 42 - 第五章参考文献 ···································································· - 42 -第一章设计概述1设计任务本次课程设计的主要任务是完成某城市污水厂的A2/O工艺设计处理生活污水，处理水量为20000m3/d，按近期规划人口10万人计算（自定）。

毕业设计相关材料题目: 城市污水处理厂初步设计（完全混合流态生物工艺）院(系)：化工与环境工程学院专业：环境工程学生：班级：环境07-1摘要当今，随着经济的快速发展，人民生活水平的不断提高，环境污染日趋严重，加大城市生活污水治理力度势在必行。

现拟建一座城市生活污水处理厂，处理规模为100000m3/d。

进水水质为COD Cr：250mg/L，BOD5 ：150mg/L，SS：200mg/L，NH3-N：40mg/L，NO3-N：10mg/L，pH=7.0~8.5,出水水质为COD Cr≤100mg/L，BOD5≤30mg/L，SS≤30mg/L，NH3-N ≤25mg/L，pH=6~9。

根据进出水水质，本设计拟采用完全混合液态的生物工艺，经比选，确定采用周期循环曝气活性污泥（CASS）工艺。

CASS工艺污水呈完全混合液态，对进水水质、水量、PH和有毒有害物质起到较好的缓冲作用，具有较强的耐冲击负荷能力，同时对丝状菌的生长起到抑制作用，可有效防止污泥膨胀。

此工艺具有投资省，处理效果好，运行管理方便等优点，适用于大中型污水处理厂使用。

本设计包含污水处理工艺流程的确定，工艺流程中各单元的计算，图纸的绘制等。

本工程的实施将显著改善受纳水体水质，同时间接产生经济效益，促进经济可持续发展。

关键词：污水处理厂；完全混合；CASS工艺AbstractNowadays, with rapid economic development, improve living standards, environmental pollution is worsening, and increase efforts to municipal sewage treatment is imperative.Now proposed a city sewage treatment plant for treating scale 100000m3 / d. The ram water quality is COD Cr, BOD5, SS, NH3-N, NO3-N,and pH keep at 250mg / L,150mg / L,200mg / L,40mg / L,10mg / L, and 7.0 ~ 8.5, respectively.The treated water quality is COD Cr, BOD5, SS, NH3-N, NO3-N,and pH keep at 100mg / L, 30mg / L, 30mg / L, 25mg / L,ant pH 6 ~ 9, respectively. According to the treated water quality, the design plans to use the completely mixed biotechnology, by comparison, determine to use of cyclic activated sludge system (CASS) process. sawage of CASS process is completely mixed, on water quality, water quantity, PH, toxic and hazardous substances have buffer role effect, with a strong resistance to shock loading capacity, meanwhile growth of filamentous bacteria is be inhibition to be prevent sludge bulking. This process has the advantage of good Less investment, good effect, easy operation and management .Applicable to large or medium sized sewage treatment plants. The design includes the determination of sewage treatment process, process in the calculation of each unit and drawing the construction drawings. The implementation of this project will significantly improve the water quality of receiving water, and indirect economic benefits and promote sustainable economic development.Key word: sewage treatment plants; Completely Mixing; CASS process目录摘要 (I)Abstract (III)目录 (IV)第一章前言 (1)1.1 设计的目的及意义 (1)1.2 设计指导思想 (1)1.3设计的容及要求 (1)1.3.1主要容 (1)1.3.2要求 (2)1.4 国外发展概况 (2)1.5 设计依据及原则 (2)1.5.1 设计依据 (2)1.5.2 设计原则 (3)1.6设计原始资料 (3)1.6.1 设计规模 (3)1.6.2 水质指标 (3)1.6.3气象资料 (3)1.6.4污水排水接纳河流资料 (4)1.6.5厂址及场地现状 (4)第二章污水处理厂工艺方案的选择 (4)2.1设计方案论证 (4)2.2.1活性污泥法处理系统有效运行的基本条件是： (4)2.2.2环境因素对微生物生长的影响 (4)2.2 原污水可生化性分析 (5)2.3 污水处理程度的确定 (6)2.3.1 水质情况 (6)2.3.2处理程度计算 (6)2.4污水处理厂工艺方案比选 (7)2.4.1 A2/O工艺 (7)2.4.2 奥贝尔（Orbal）氧化沟 (8)2.4.3 CASS工艺 (9)2.4.4 工艺方案选择 (12)2.4 处理程度计算 (12)2.4.1 CODcr的处理程度 (12)2.4.2 溶解性BOD5的处理程度 (12)2.4.3 SS的处理程度 (12)2.4.4 NH3-N的处理程度 (13)第三章单元构筑物的设计计算 (14)3.1粗格栅设计计算 (14)3.1.1 设计说明 (14)3.1.2 栅前明渠宽度 (14)3.1.3 栅条的间隙数 (15)3.1.4 栅槽宽度 (15)3.1.5 进水渠道渐宽部分的长度 (16)3.1.6 栅槽与出水渠道连接处的渐窄部分长度 (16)3.1.7 过栅水头损失 (16)3.1.8 栅后槽总高度 (17)3.1.9 栅槽总长度 (17)3.1.10 每日栅渣量计算W (17)3.2 泵站的设计计算 (17)3.2.1 泵房规要求 (17)3.2.2 污水泵计算 (18)3.2.3 集水池 (19)3.3细格栅设计计算 (19)3.3.1 设计说明 (19)3.3.4 栅条的间隙数 (20)3.3.3 栅槽宽度 (20)3.3.4 进水渠道渐宽部分的长度 (21)3.3.5 栅槽与出水渠道连接处的渐窄部分长度 (21)3.3.6 过栅水头损失 (21)3.3.7 栅后槽总高度 (22)3.3.8 栅槽总长度 (22)3.3.9 每日栅渣量计算W (22)3.4 沉砂池的设计计算 (22)3.4.1 沉砂池的选择 (22)3.4.2 沉砂池设计计算一般规定 (23)3.4.3 设计参数 (23)3.4.4 设计计算 (23)3.5 CASS池设计计算 (25)3.5.1 基本设计参数 (25)3.5.2 BOD5去除率的计算 (26)3.5.3 污泥负荷率 (26)3.5.4 曝气时间 (26)3.5.5 沉淀时间T S (26)3.5.6 排水时间T D (27)3.5.7 周期数的确定 (27)3.5.8 进水时间TF (27)3.5.9 CASS池运行模式 (27)3.5.10 CASS池容积及构造尺寸 (28)3.5.11 复核出水溶解性BOD5 (29)3.5.12 潜水搅拌器 (30)3.5.13 曝气系统设计计算 (30)3.5.14供气量的计算 (31)3.5.14 进出水管路计算 (33)3.6紫外消毒渠道 (34)3.6.1 紫外消毒渠道的功能 (34)3.6.2紫外消毒渠道设计计算 (34)3.7污水计量设备 (35)3.8 产泥量及排泥系统 (36)3.8.1产泥量 (36)3.8.2排泥系统 (36)3.8污泥回流 (37)3.8.1设计说明 (37)3.8.2回流污泥泵设计选型 (37)3.9 重力浓缩池设计计算 (38)3.9.1设计参数 (38)3.9.2设计与计算 (38)3.10 贮泥池 (40)3.11消化池 (40)3.11.1消化池容积计算 (41)3.11.2消化池各部分表面积计算 (41)3.11.3消化池热工计算 (42)3.11.4沼气混合搅拌计算 (43)3.11.5产气量及贮气柜 (43)3.12污泥脱水设备 (44)3.13附属构筑物 (44)第四章污水处理厂配套工程设计 (45)4.1 厂区平面设计 (45)4.1.1 平面布置原则 (45)4.1.2 平面布置 (46)4.2 厂区高程设计 (46)4.2.1 高程布置注意事项 (46)4.2.2 高程计算 (47)第五章环境保护及劳动卫生 (51)5.1 项目施工期对环境影响及对策 (51)5.1.1 项目施工期对环境的影响 (51)5.1.2 施工期对环境影响的对策 (52)5.2 项目运营期对环境影响及对策 (53)5.2.1 项目运营期对环境的影响 (53)5.2.2 运营期环境影响的对策 (53)5.3 劳动保护与安全生产 (54)第六章工程投资估算及效益分析 (55)6.1投资估算 (55)6.1.1．估算围 (55)6.1.2.编制依据 (55)6.1.3投资估算 (55)6.2 运行成本估算 (57)6.2.1 成本估算的有关单价 (57)6.2.3运行成本估算 (57)6.2.4 运行成本核算 (58)6.3效益分析 (58)6.3.1 环境效益 (58)6.3.2 社会效益 (58)结论 (59)致 (60)参考文献 (61)第一章前言1.1 设计的目的及意义随着我国社会和经济的高速发展,水环境日益恶化，2007年，我国600多个城市有400多个城市缺水，缺水原因主要不在于水量不足，而在于水质污染严重，属于水质性缺水。

本设计污水处理厂综合设计包括15个图纸，十分全面，具体详见报告后附图。

本报告附图全面详细。

图纸内容如下：A2O池，初沉池，幅流式二沉池，隔栅，工艺简单图，工艺流程图（高程图），回转耙式格栅除污机图，平面布置图，污泥浓缩池，厌氧消化池，钟式沉砂池等。

全为CAD制图。

下载后复制放大或打印可看清！题目20000m3/d城市污水处理厂综合设计专业: 环境工程年级: 2005级学号: 3105001286姓名: 莫笑伟指导教师:2008年12 月摘要我国水体污染主要来自两方面，一是工业发展超标排放工业废水，二是城市化中由于城市污水排放和集中处理设施严重缺乏，大量生活污水未经处理直接进入水体造成环境污染。

工业废水近年来经过治理虽有所减少，但城市生活污水有增无减，占水质污染的51%以上。

我国水体污染主要来自两方面，一是工业发展超标排放工业废水，二是城市化中由于城市污水排放和集中处理设施严重缺乏，大量生活污水未经处理直接进入水体造成环境污染。

工业废水近年来经过治理虽有所减少，但城市生活污水有增无减，占水质污染的51%以上。

本设计要求处理水量为20000m3/d的城市生活污水，设计方案针对已运行稳定有效的A2/O活性污泥法工艺处理城市生活污水。

A2O工艺由于不同环境条件，不同功能的微）能生物群落的有机配合，加之厌氧、缺氧条件下，部分不可生物降解的有机物（CODNB被开环或断链，使得N、P、有机碳被同时去除，并提高对COD的去除效果。

它可以同NB－－时完成有机物的去除，硝化脱氮、磷的过量摄取而被去除等功能，脱氮的前提是NH3N应完全硝化，好氧池能完成这一功能，缺氧池则完成脱氮功能。

厌氧池和好氧池联合完成除磷功能。

关键词：城市生活污水，活性污泥，A2/O目录摘要 (III)目录 (IV)第一章设计概述 ······································································- 7 -1设计任务 ······································································- 7 - 2设计原则 ······································································- 7 - 3设计依据 ······································································- 8 - 第二章工艺流程及说明 ·····························································- 8 -1工艺方案分析 ································································- 8 - 2工艺流程 ······································································- 9 - 3流程各结构介绍 ·····························································- 9 -3.1格栅······························································································· - 9 -3.2沉砂池··························································································- 10 -3.3初沉池··························································································- 10 -3.4生物化反应池··············································································- 10 -3.5二沉池··························································································- 12 -3.6浓缩池··························································································- 12 - 第三章构筑物设计计算 ··························································· - 12 -1格栅 ·········································································· - 12 -1.1设计说明······················································································- 12 -1.2设计计算······················································································- 13 -2沉砂池 ······································································· - 16 -2.1设计说明······················································································- 16 - 3初沉池 ······································································· - 17 -3.1设计说明······················································································- 17 -3.2设计计算······················································································- 17 - 4生化池 ······································································· - 19 -4.1设计说明······················································································- 19 -4.2设计计算······················································································- 19 - 5二沉池 ······································································· - 26 -5.1设计说明······················································································- 26 -5.2设计计算······················································································- 26 - 6液氯消毒 ···································································· - 29 -6.1设计说明······················································································- 29 -6.2设计计算······················································································- 29 - 7污泥浓缩池 ································································· - 30 -7.1设计说明······················································································- 30 -7.2设计计算······················································································- 30 -8 污泥消化池 ································································· - 31 -8.1设计说明······················································································- 31 -8.2设计计算······················································································- 32 - 9浓缩污泥提升泵房 ························································ - 38 -9.1设计选型······················································································- 38 -9.2提升泵房······················································································- 38 -9.3污泥回流泵站··············································································- 38 -10污泥脱水间 ······························································· - 39 -10.1设计说明······················································································- 39 -11鼓风机房 ·································································· - 39 - 12恶臭处理系统 ···························································· - 39 -12.1设计说明······················································································- 39 -12.2设计计算······················································································- 39 -12.3风机选型······················································································- 40 - 第四章污水处理厂总体布置 ····················································· - 41 -1总平面布置 ································································· - 41 -1.1总平面布置原则··········································································- 41 -1.2总平面布置结果··········································································- 41 -2高程布置································································································- 42 -2.1高程布置原则··············································································- 42 - 第五章参考文献 ···································································· - 42 -第一章设计概述1设计任务本次课程设计的主要任务是完成某城市污水厂的A2/O工艺设计处理生活污水，处理水量为20000m3/d，按近期规划人口10万人计算（自定）。

辽宁省WF市排水工程规划及污水处理厂设计第一章设计任务与内容1.1 前言在我国城市和工业飞速发展的今天，污水排放量与日俱增。

据统计，我国城市污水年排放量达400多亿立方米，现已有一批城市兴建了污水处理厂，一大批工业企业建设了工业废水处理厂，更多的城市和工业企业在规划、筹划和设计污水处理厂。

但这些污水处理厂几乎全在近100个大城市中。

近几十年来，污水处理技术无论在理论研究方面还是在应用方面，都取得了一定的进步，新工艺、新技术大量涌现，氧化沟系统和高效低耗的污水处理技术，如各种类型的稳定塘,AB法工艺,间歇式（序列式）活性污泥法,脱氮、脱磷的A-O系统，湿地系统都取得了长足的进步和应用。

这些新工艺、新技术已成为水污染防治领域的热门研究课题。

在国家科委、建设部、国家环境保护局的组织和领导下，广泛、深入地开展了这些课题的科学研究工作，取得了一批令人瞩目的研究成果。

不应回避，我国水资源严重短缺，我国人均水资源为世界人均水资源的四分之一，在我国北方一些城市人民生活水平的提高和工农业生产的发展已受到水资源不足的制约。

城市污水和工业废水回用，以城市污水作为第二水源的趋势，不久将成为必然。

这就是我国污水事业面临的现实。

作为给水排水工程专业的学生，就更应该深刻地了解这种形势，掌握并发展污水处理的新工艺、新技术，成为跨世纪的工程技术人才，将我国的污水处理技术达到世界领先水平。

1.2 设计说明1.2.1 设计题目辽宁省WF市排水工程规划及污水处理厂设计1.2.2 设计任务与内容(1) 排水管网规划设计，含两个以上的方案比较；(2) 污水泵站工艺设计，含部分工艺施工图设计；(3) 污水处理工艺设计，含部分单体构筑物的工艺施工图设计；(4) 污泥水处理工艺设计，含部分单体构筑物的工艺施工图设计；(5) 排水管网与污水处理厂的工程概算；(6) 有条件的同学还可以在教师指导下自选一个专题进行深入研究或设计。

1.2.3 基本要求1.2.3.1 排水工程毕业设计的要求(1) 完成排水管网和雨水管道的定线，至少应对两个排水管网定线方案（也可以是局部变化的方案）进行技术经济比较，从中选优。

辽宁省WF市排水工程规划及污水处理厂设计第一章设计任务与内容前言在我国城市和工业飞速发展的今天，污水排放量与日俱增。

据统计，我国城市污水年排放量达400多亿立方米，现已有一批城市兴建了污水处理厂，一大批工业企业建设了工业废水处理厂，更多的城市和工业企业在规划、筹划和设计污水处理厂。

但这些污水处理厂几乎全在近100个大城市中。

近几十年来，污水处理技术无论在理论研究方面还是在应用方面，都取得了一定的进步，新工艺、新技术大量涌现，氧化沟系统和高效低耗的污水处理技术，如各种类型的稳定塘,AB法工艺,间歇式（序列式）活性污泥法,脱氮、脱磷的A-O系统，湿地系统都取得了长足的进步和应用。

这些新工艺、新技术已成为水污染防治领域的热门研究课题。

在国家科委、建设部、国家环境保护局的组织和领导下，广泛、深入地开展了这些课题的科学研究工作，取得了一批令人瞩目的研究成果。

不应回避，我国水资源严重短缺，我国人均水资源为世界人均水资源的四分之一，在我国北方一些城市人民生活水平的提高和工农业生产的发展已受到水资源不足的制约。

城市污水和工业废水回用，以城市污水作为第二水源的趋势，不久将成为必然。

这就是我国污水事业面临的现实。

作为给水排水工程专业的学生，就更应该深刻地了解这种形势，掌握并发展污水处理的新工艺、新技术，成为跨世纪的工程技术人才，将我国的污水处理技术达到世界领先水平。

设计说明1.2.1 设计题目辽宁省WF市排水工程规划及污水处理厂设计1.2.2 设计任务与内容(1) 排水管网规划设计，含两个以上的方案比较；(2) 污水泵站工艺设计，含部分工艺施工图设计；(3) 污水处理工艺设计，含部分单体构筑物的工艺施工图设计；(4) 污泥水处理工艺设计，含部分单体构筑物的工艺施工图设计；(5) 排水管网与污水处理厂的工程概算；(6) 有条件的同学还可以在教师指导下自选一个专题进行深入研究或设计。

1.2.3 基本要求1.2.3.1 排水工程毕业设计的要求(1) 完成排水管网和雨水管道的定线，至少应对两个排水管网定线方案（也可以是局部变化的方案）进行技术经济比较，从中选优。

辽宁省WF市排水工程规划及污水处理厂设计第一章设计任务与内容1.1 前言在我国城市和工业飞速发展的今天，污水排放量与日俱增。

据统计，我国城市污水年排放量达400多亿立方米，现已有一批城市兴建了污水处理厂，一大批工业企业建设了工业废水处理厂，更多的城市和工业企业在规划、筹划和设计污水处理厂。

但这些污水处理厂几乎全在近100个大城市中。

近几十年来，污水处理技术无论在理论研究方面还是在应用方面，都取得了一定的进步，新工艺、新技术大量涌现，氧化沟系统和高效低耗的污水处理技术，如各种类型的稳定塘,AB法工艺,间歇式（序列式）活性污泥法,脱氮、脱磷的A-O系统，湿地系统都取得了长足的进步和应用。

这些新工艺、新技术已成为水污染防治领域的热门研究课题。

在国家科委、建设部、国家环境保护局的组织和领导下，广泛、深入地开展了这些课题的科学研究工作，取得了一批令人瞩目的研究成果。

不应回避，我国水资源严重短缺，我国人均水资源为世界人均水资源的四分之一，在我国北方一些城市人民生活水平的提高和工农业生产的发展已受到水资源不足的制约。

城市污水和工业废水回用，以城市污水作为第二水源的趋势，不久将成为必然。

这就是我国污水事业面临的现实。

作为给水排水工程专业的学生，就更应该深刻地了解这种形势，掌握并发展污水处理的新工艺、新技术，成为跨世纪的工程技术人才，将我国的污水处理技术达到世界领先水平。

1.2 设计说明1.2.1 设计题目辽宁省WF市排水工程规划及污水处理厂设计1.2.2 设计任务与内容(1) 排水管网规划设计，含两个以上的方案比较；(2) 污水泵站工艺设计，含部分工艺施工图设计；(3) 污水处理工艺设计，含部分单体构筑物的工艺施工图设计；(4) 污泥水处理工艺设计，含部分单体构筑物的工艺施工图设计；(5) 排水管网与污水处理厂的工程概算；(6) 有条件的同学还可以在教师指导下自选一个专题进行深入研究或设计。

1.2.3 基本要求1.2.3.1 排水工程毕业设计的要求(1) 完成排水管网和雨水管道的定线，至少应对两个排水管网定线方案（也可以是局部变化的方案）进行技术经济比较，从中选优。

设计说明书一、环境条件见设计任务书的设计资料一栏。

二、处理工艺的选择该城镇污水处理厂主要是用于处理城区生活污水和部分工业废水,且对氮磷的去除有一定要求。

按《城市污水处理和污染防治技术政策》要求推荐，对脱磷脱氮有要求的城市，应采用二级强化处理,如A2 /O 工艺,A/O工艺，SBR 及其改良工艺,氧化沟工艺，以及水解好氧工艺，生物滤池工艺等。

故该设计应选取二级强化处理.鉴于SBR 工艺具有以下特点：（1) 工艺流程简单、管理方便、造价低。

SBR 工艺只有一个反应器，不需要二沉池，不需要污泥回流设备，一般情况下也不需要调节池,因此要比传统活性污泥工艺节省基建投资30%以上,而且布置紧凑，节省用地.由于科技进步,目前自动控制已相当成熟、配套。

这就使得运行管理变得十分方便、灵活,很适合小城市采用.（2) 处理效果好。

SBR 工艺反应过程是不连续的,是典型的非稳态过程，但在曝气阶段其底物和微生物浓度变化是连续的（尽管是处于完全混合状态中）,随时间的延续而逐渐降低。

反应器内活性污泥处于一种交替的吸附、吸收及生物降解和活化的变化过程之中，因此处理效果好.(3）有较好的除磷脱氮效果。

SBR 工艺可以很容易地交替实现好氧、缺氧、厌氧的环境,并可以通过改变曝气量、反应时间等方面来创造条件提高除磷脱氮效率。

(4）污泥沉降性能好。

SBR 工艺具有的特殊运行环境抑制了污泥中丝状菌的生长，减少了污泥膨胀的可能。

同时由于SBR 工艺的沉淀阶段是在静止的状态下进行的,因此沉淀效果更好。

（5）SBR 工艺独特的运行工况决定了它能很好的适应进水水量、水质波动。

均适用于本设计,故选取SBR工艺作为本设计的水处理工艺。

三、污水厂的主要工艺流程四、设计说明1、格栅和提升泵房设置方式:粗格栅→泵房→细格栅格栅的主要作用是将污水中的大块污物拦截，以免其对后续处理单元的机泵或工艺管线造成损害。

由于直棒式格栅运行可靠,布局简洁,易于安装维护，本工艺选用选择GH型回转格栅。

目录引言 ......................................................................... 错误！未定义书签。

1设计任务及概况. (6)1.1设计任务及依据 (6)1.1.1设计任务 (6)1.1.2设计依据及原则 (6)1.222.12.22.32.3.3沉砂池 (13)2.3.4初沉池、二沉池 (14)2.3.5曝气池 (14)2.3.6接触池 (15)2.3.7计量槽 (16)2.3.8浓缩池 (16)污泥脱水 (17)3污水处理系统工艺设计 (17)3.1格栅的计算 (17)3.1.1粗格栅 (17)3.1.2格栅的计算 (18)3.1.3选型 (21)3.23.33.43.53.5.4集配水井计算 (35)3.5.5出水水质 (35)3.5.6选型 (36)3.6曝气池 (36)3.6.1池体计算 (36)3.6.2曝气系统设计与计算 (39)3.6.4空气管道系统计算 (43)3.6.5空压机的选择 (46)3.6.6污泥回流系统 (46)3.7二沉池 (47)3.7.1池体尺寸计算 (47)3.7.2中心管计算 (50)3.7.3出水堰的计算 (51)3.83.944.14.2污泥消化池 (59)4.2.1一级消化池池体部分计算4.34.44.4.2污泥循环泵 (64)4.4.3污泥控制室布局 (65)4.5脱水机房 (65)4.5.1采用带式压滤机除水 (65)4.5.2选型 (66)4.6事故干化场 (66)5污水处理厂总体布置 (67)5.1平面布置 (67)5.1.1平面布置的一般原则 (67)5.1.2平面布置 (67)5.2污水处理厂高程布置 (68)5.2.1高程布置原则 (68)总结致谢附录11.11.1.130万吨城市污水处理厂初步设计1.1.2设计依据及原则设计依据《给水排水工程快速设计手册》手册》《三废设计手册废水卷》(1)执行国家关于环境保护的政策，符合国家地方的有关法规、规范和标准；(2)采用先进可靠的处理工艺，确保经过处理后的污水能达到排放标准；(3)采用成熟、高效、优质的设备，并设计较好的自控水平，以方便运行管理；(4)全面规划、合理布局、整体协调，使污水处理工程与周围环境协调一致；(5)妥善处理污水净化过程中产生的污泥固体物，以免造成二次污染；(6)综合考虑环境、经济和社会效益，在保证出水达标的前提下，尽量减少工程投资和运行费用。

辽宁省WF市排水工程规划及污水处理厂设计第一章设计任务与内容1.1 前言在我国城市和工业飞速发展的今天，污水排放量与日俱增。

据统计，我国城市污水年排放量达400多亿立方米，现已有一批城市兴建了污水处理厂，一大批工业企业建设了工业废水处理厂，更多的城市和工业企业在规划、筹划和设计污水处理厂。

但这些污水处理厂几乎全在近100个大城市中。

近几十年来，污水处理技术无论在理论研究方面还是在应用方面，都取得了一定的进步，新工艺、新技术大量涌现，氧化沟系统和高效低耗的污水处理技术，如各种类型的稳定塘,AB法工艺,间歇式（序列式）活性污泥法,脱氮、脱磷的A-O系统，湿地系统都取得了长足的进步和应用。

这些新工艺、新技术已成为水污染防治领域的热门研究课题。

在国家科委、建设部、国家环境保护局的组织和领导下，广泛、深入地开展了这些课题的科学研究工作，取得了一批令人瞩目的研究成果。

不应回避，我国水资源严重短缺，我国人均水资源为世界人均水资源的四分之一，在我国北方一些城市人民生活水平的提高和工农业生产的发展已受到水资源不足的制约。

城市污水和工业废水回用，以城市污水作为第二水源的趋势，不久将成为必然。

这就是我国污水事业面临的现实。

作为给水排水工程专业的学生，就更应该深刻地了解这种形势，掌握并发展污水处理的新工艺、新技术，成为跨世纪的工程技术人才，将我国的污水处理技术达到世界领先水平。

1.2 设计说明1.2.1 设计题目辽宁省WF市排水工程规划及污水处理厂设计1.2.2 设计任务与内容(1) 排水管网规划设计，含两个以上的方案比较；(2) 污水泵站工艺设计，含部分工艺施工图设计；(3) 污水处理工艺设计，含部分单体构筑物的工艺施工图设计；(4) 污泥水处理工艺设计，含部分单体构筑物的工艺施工图设计；(5) 排水管网与污水处理厂的工程概算；(6) 有条件的同学还可以在教师指导下自选一个专题进行深入研究或设计。

1.2.3 基本要求1.2.3.1 排水工程毕业设计的要求(1) 完成排水管网和雨水管道的定线，至少应对两个排水管网定线方案（也可以是局部变化的方案）进行技术经济比较，从中选优。

氧化沟法城市污水处理本设计中需要处理的城市污水水质条件为:=470mg/L, ＝260mg/L, SS=200mg/L, -N=25mg/L处理规模: 25万/d处理后出水水质：<100mg/L, <30mg/L, SS<30mg/L, -N<8mg/L主要工艺流程图:主要构筑物作用:１.粗格栅: 粗格栅为污水厂第1道预处理设施,用于去除污水中大的悬浮物和漂浮物,保证后续处理设施的正常运行。

２.提升泵房: 提升泵房用于将入流污水提升至设计高度,以便自流进入各后续处理单元。

３.细格栅：细格栅可进一步去除污水中的悬浮物和漂浮物,保证后续设备和工艺的正常运行。

细格栅采用连续运行方式,栅渣由一台无轴螺旋压实输送机收集脱水后运往厂外填埋。

为了方便管理和维护,细格栅间与沉砂池合建,细格栅间出水直接进入沉砂池.４.旋流沉砂池: 沉砂池的作用是将污水中物理、化学及生物性质不同的无机颗粒和有机颗粒(悬浮物)进行分离,以便于分别最终处置５.选择池: 该选择池分为两格,进水与从二沉池回流的活性污泥快速混合、接触,利用活性污泥中的厌氧菌对污水中的溶解态和胶态可生物降解有机物进行吸附,促进该部分微生物的增长和繁殖,选择有利于沉淀的菌胶团微生物,抑制污泥膨胀。

同时,选择池出水采用可调堰板,作为后继的氧化沟的配水设施。

６.二沉池: 二沉池的作用是对氧化沟排出的混合液进行泥水分离,保证出水水质和回流污泥的浓度。

本设计中二沉池采用中心进水周边出水圆形辐流式沉淀池,连续运行,池内设单周边传动刮泥机７.接触池消毒池: 生物处理后的出水在此投加消毒剂,经充分混合和接触(维持足够的接触时间),杀灭出水中的致病菌,保证最终排水的卫生安全。

消毒剂采用液氯,由加氯间制备８.鼓风机房: 鼓风机房分为机房、进风室和值班室。

风机出口管上均设有止回阀、安全阀、消声器、压力开关和温度开关等。

鼓风机采用连续运行方式,并由PLC自动控制,PLC主控制器将保持系统主风管中的压力恒定,并通过调节各氧化沟的空气控制阀来调节溶解氧含量。