污水处理厂设计布局

污水处理工程设计方案模板一、项目概况本项目位于某市某区，为某工业区污水处理厂二期工程，总设计处理规模为XXX，主要包括XXX。

二、设计依据1. 地方环保部门相关规定2. 国家环保标准3. 现有污水处理工艺4. 地方市政规划三、设计原则1. 绿色环保2. 经济合理3. 可持续发展4. 安全稳定四、设计方案1. 排水系统1.1 新建管网设计新建XXX直径的排水管网，整体布局合理，尽量缩短管道长度，减少管道转弯，减小管道摩擦力，提高排水效率。

1.2 排水泵站设计新建XXX泵站，采用XXX型号泵，并配备备用泵，以应对突发情况。

2. 水质分析2.1 污水样本采集与分析2.2 水质监测点设置3. 污水处理工艺3.1 初预处理设计设置格栅除污系统，去除大颗粒杂质，预处理泵进行水体加压供给。

3.2 沉淀池设计设置XXX立方米沉淀池，用于沉淀悬浮颗粒和一部分废水分离。

3.3 曝气池设计设置XXX立方米曝气池，配备XXX型曝气器。

进行高效曝气，加速废水中的有机物与氧的氧化反应。

3.4 活性污泥法设计设置XXX立方米活性污泥接触氧化塔，进行污水的好氧生化处理。

3.5 终沉池设计设置XXX立方米终沉池，对处理后的污水进行沉淀分离和澄清。

3.6 滤池设计设置XXX立方米滤池，配备XXX型过滤设备，进行污水的深度过滤。

4. 配套设施4.1 系统自动控制设计设置PLC自动控制系统，实现对整个污水处理过程的自动监测和控制。

4.2 供电系统设计设置污水处理厂独立供电系统，并配备发电机组备用。

4.3 维护管理设计设置厂内维护管理运营中心，配备专业维护人员和必要维护设备。

5. 防撞安全5.1 根据工艺布局和周边环境情况，设计设置围栏、安全标识、安全装置等。

5.2 设计安全漂移系统，提前警示应急事件，并采取相应措施。

5.3 设计防洪安全设施，保障工程的安全稳定运行。

五、工程设施1. 土建工程1.1 厂区布局设计布局污水处理设施、办公区、维护区、生活区等功能区域，合理规划土地利用。

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）。

污水处理厂设计_毕业设计一、引言水是生命之源，对于人类的生存和发展至关重要。

然而，随着工业化和城市化的快速推进，大量的污水产生，如果未经有效处理直接排放，将对环境和人类健康造成严重威胁。

因此，污水处理厂的建设成为了保护环境、保障公众健康的重要举措。

本次毕业设计旨在设计一座高效、经济、环保的污水处理厂，以满足特定区域的污水处理需求。

二、设计任务与要求（一）设计规模根据给定的区域人口、工业用水等数据，确定污水处理厂的设计规模，包括日处理水量、最大时处理水量等。

（二）进水水质分析进水的主要污染物指标，如化学需氧量（COD）、生化需氧量（BOD₅）、悬浮物（SS）、氮、磷等的浓度范围。

（三）出水水质根据国家和地方的相关排放标准，确定处理后的出水水质要求，确保达标排放。

（四）工艺流程选择综合考虑污水的性质、处理效果、运行成本、占地面积等因素，选择合适的污水处理工艺流程。

（五）主要构筑物设计对污水处理厂的各个构筑物，如格栅、沉砂池、初沉池、生物处理池、二沉池、消毒池等进行详细设计，包括尺寸、结构、设备选型等。

（六）平面布置与高程布置合理规划污水处理厂的平面布局，使各构筑物之间的连接顺畅，便于操作和管理；同时进行高程布置，确保污水在处理过程中能够自流，降低能耗。

三、工艺流程确定（一）常见工艺流程介绍目前，常用的污水处理工艺流程包括传统活性污泥法、氧化沟法、A²/O 法、SBR 法等。

传统活性污泥法工艺成熟，但占地面积较大，运行费用较高；氧化沟法具有较好的脱氮除磷效果，运行稳定；A²/O 法同时具备去除有机物、氮和磷的功能，效果显著；SBR 法工艺灵活，可适应水质水量的变化。

（二）本设计工艺流程选择经过对各种工艺流程的对比分析，并结合本设计的进水水质和出水要求，最终选择 A²/O 工艺流程。

该工艺能够有效地去除有机物、氮和磷，且具有运行稳定、管理方便等优点。

四、主要构筑物设计（一）格栅格栅是污水处理厂的第一道处理工序，用于去除污水中的较大悬浮物和漂浮物。

污水处理厂的选址和布局
1、污水处理厂应设在地势较低处，便于城市污水自流入厂内,厂址选择应与排水管道系统布置统一考虑，充分考虑城市地形的影响。

2、污水厂宜设在水体附近，便于处理后的污水近排入水体，尽量无提升，合理布置出水口。

排入的水体应有足够环境容量，减少处理水对水域的影响。

3、厂址必须位于集中给水水源的下游，并应设在城市、工厂厂区及居住的下游和夏季主导风向的下方。

厂址与城市、工厂和生活区应有300m以上距离，并设卫生防护带。

4、厂址尽可能少占或不占农田，但宜在地质条件较好的地段，便于施工、降低造价。

充分利用地形，选择有适当坡度的地段，以满足污水在处理流程上的自流要求。

5、结合污水的出路，考虑污水回用于工业、城市和农业的可能，厂址应尽可能与回用处理后污水的主要用户靠近。

6、厂址不宜设在雨季易受水淹的低洼处。

靠近水体的污水处理厂要考虑不受洪水的威胁。

7、污水处理厂选址应考虑污泥的运输和处置，宜近公路和河流。

厂址处要有良好的水电供应，最好是双电源。

8、选址应注意城市近、远期发展问题，近期合适位置与远期合适位置往往不一致，应结合城市总体规划，并考虑扩建的可能。

城镇污水工程系统规划方案引言城镇污水处理工程系统的规划对于城市的可持续发展和环境保护至关重要。

本文将提出一个城镇污水工程系统的规划方案，旨在解决城镇污水排放、水资源利用和环境保护等问题，为城市的可持续发展提供技术支持与指导。

1. 规划目标本规划方案的目标是建立一个完善的城镇污水处理工程系统，实现以下目标：- 实现城镇污水全面收集、处理和回用；- 优化sewage 管网布局，提高污水收集、输送和处理的效率；- 提高污水处理工艺和技术水平，确保处理水质符合相关标准；- 推动污水回用，提高水资源的利用效率；- 减少污水排放对周边环境的影响，改善环境质量。

2. 规划内容2.1 污水收集系统- 建立综合管网，实现城镇所有居民和企事业单位的污水收集；- 对城市的污水管网进行修缮和扩建，确保污水收集的全面覆盖；- 引入先进的管道监控系统，实时监测管道的运行情况，及时发现并修复泄漏和堵塞。

2.2 污水处理系统- 采用多级处理工艺，包括粗格栅、中格栅和细格栅过滤、沉淀池、曝气池、生物滤池和消毒等环节；- 引入先进的污水处理设备和技术，提高处理效率和水质。

2.3 污水回用系统- 建立污水回用系统，将经过处理的污水用于工业生产、城市绿化和农田灌溉等领域，提高水资源利用效率；- 单独设置污水回用管网，与其他供水管网隔离，确保回用水不与饮用水混合。

2.4 管理与监测系统- 建立完善的污水处理管理与监测系统，包括污水处理厂和管网的实时监测与管理、水质检测、运行数据采集等；- 通过数据分析和智能化监测，提前发现潜在问题，及时进行维修和调整。

3. 实施计划3.1 初步阶段- 建立污水工程规划小组，负责项目的协调和推进；- 通过调研和论证，确定污水处理厂和管网建设的优先级和规模；- 制定项目的投资计划和时间节点；- 开展环境影响评估，确保项目的可行性和可持续性。

3.2 设计阶段- 招标并选定设计单位，进行污水处理厂和管网的详细设计；- 设计工作包括管网布局、处理工艺流程、污水处理设备选择等；- 设计过程中，考虑运行安全、功耗低、维护便捷等因素。

污水处理厂平面布置及高程布置污水处理厂平面布置及高程布置是指在建设污水处理厂时，为保证厂区内的设施和设备能够合理布置，从而提高污水处理效率和处理质量，需要进行的平面和高程方面的规划和布置工作。

下面从平面和高程两个方面来详细介绍。

平面布置方案污水处理厂的平面布置方案需要围绕着设施和设备的建设展开，以保证各项工作的有序进行。

具体来讲，平面布置方案需考虑以下几个方面：1. 厂区规划：厂区规划是平面布置方案的基础，它包括厂区的总体布局、厂房建设、管道网建设等。

在设计过程中，应以尽可能利用厂区内部面积，方便实施维护和管理为原则，可采用“L”字型、直线形、T字形、环状布置等不同形式。

2. 处理工艺设备的布置：处理工艺设备布置要考虑到污水处理的各个阶段，通常包括初次处理、生物处理、二次处理等。

各处理阶段的设备应按照处理工艺流程来布置，保证各个环节处理得当，使处理效率更高、质量更优。

3. 管线布置：管线系统是污水处理厂的重要组成部分，它主要用于输送、收集和排放污水。

系统中应包括进水管线、出水管线、通风管道、排泥管道等，其布置应保证科学合理。

通常情况下，应沿着最短距离布置管道，同时考虑到管道的通风、防腐、维修等。

4. 办公区：除了处理污水的工作区域需要布置外，污水处理厂的办公区也是至关重要的。

它要包括管理办公、技术质量检测、设备维修等区域，为了方便员工工作和管理，该区域应布置在离设备和设施比较近的地方。

污水处理厂的高程布置是指在建设中对厂区内的各个设施和设备安排高度的布置方案，其目的是为了保证各个设施设备的高度关系协调，避免因高度差异造成零散操作的麻烦，影响污水处理效率。

具体来讲，高程布置方案需考虑以下几个方面：1. 处理池的高度：处理池是污水处理厂的重要组成部分，一般包括沉淀池、生化池、沼气池等。

其高度应考虑到接口高度和出水口的高度以及泥层等因素。

2. 管道高度：管道的高度安排要考虑到管道是否易于维修和清洗、与相邻设施的高度位置关系等问题，可通过包红线来确认各个管道的高度。