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1、 本科毕业论文 1m3电镀污水处理器结构设计 姓 名 学 院 专 业过程装备与控制工程 指导教师 完成日期 全日制本科生毕业设计(论文)承诺书本人郑重承诺:所呈交的毕业设计(论文)1m3电镀污水处理器结构设计 是在导师的指导下,严格按照学校和学院的有关规定由本人独立完成。文中所引用的观点和参考资料均已标注并加以注释。论文研究过程中不存在抄袭他人研究成果和伪造相关数据等行为。如若出现任何侵犯他人知识产权等问题,本人愿意承担相关法律责任。 承诺人(签名): 日 期: 1m3电镀污水处理器结构设计摘要据了解,我国的电镀工厂大约有一万多家,每年排放的电镀废水约40亿m2.含Cr(VI)废水是电镀行业的
2、主要废水来源之一。Cr(VI)具有强毒性,是国际抗癌眼睛中心和美国毒理学组织公布的致癌物,具有明显的致癌作用,Cr(VI)化合物在自然界不能被微生物分解,具渗透前移性较强,对人体有强烈的致敏作用。因此,对含Cr(VI)电镀废水的妥善处理,是电镀行业中一个必须解决的环境问题。电镀行业是通用性强、使用面广、跨行业、跨部门的重要加工工业和工艺性生产技术。由于电镀行业使用了大量强酸、强碱、重金属溶液,甚至包括镉、氰化物、铬酐等有毒有害化学品,在工艺过程中排放了污染环境和危害人类健康的废水、废气和废渣,已成为一个重污染行业。本次设计采用可以迅速将废水中金属离子完全去除的离子交换树脂,在常温下与废水中的金
3、属离子迅速反应,生成水不溶性的絮状沉淀,从而达到去除金属离子的目的。离子交换法处理废水具有广阔的前景,近年来进展很快。近年来各种新型离子交换树脂和吸附树脂不断推陈出新,为国内离子交换树脂工业的发展奠定了基础并且起了巨大的推动作用。与此同时,国外的离子交换树脂也迅猛发展,据统计,美国离子交换树脂的用量正以每年5.8的速度增长,仅1998年就有1.32亿磅的离子交换树脂应用于水处理、金属回收、化工处理等领域。本设计中设备容量为1m3。废水的进水水量水质为:废水中含Cr2+ 浓度为,平均每小时排放量1.0 m3。综合考虑废水水质水量特点,决定通过离子交换法来处理废水,选用大孔弱酸性阳离子交换树脂11
4、6,去除废水中的Ni2+离子,使其发生离子交换反应,生成不溶于水的沉淀,从而达到分离有害离子的目的,以保证达到排放标准。关键词:电镀废水、镍、离子交换树脂 ARCHITECTURE DESIGN OF 1m3 ELECTROPLATING WASTEWATER PROCESSOR ABSTRACTIt is understood that the electroplating factories in China, there are about 10,000 enterprises, electroplating wastewater emissions from each year of
5、about 4 billion m2. Cr (VI) waste-water is one of the major sources of waste water in electroplating industry. Cr (VI) with strong toxicity, international cancer eye Center and United States Organization the toxicology of carcinogens, with distinct carcinogenesis, Cr (VI) compounds in nature cannot
6、be microbial decomposition, osmosis moves forward more, and have a strong allergenic effect to the human body. Therefore, on Cr (VI) proper disposal of electroplating waste water, is an environmental issues that must be addressed in the electroplating industry. Electroplating industry is a versatile
7、, use widely important processing industries, cross-industry, cross-sector and technological production technology. Due to the plating industry uses a large amount of strong acid, strong base, heavy metal solution, including cadmium, cyanide, toxic and hazardous chemicals such as chromic anhydride,
8、environmental pollution by emissions in the process and of waste water, waste gas, and waste residue risks to human health, has become a heavily polluting industries.This design can quickly complete removal of metal ions in wastewater by ion-exchange resin, at room temperature and metal ions in wast
9、ewater by rapid response, generate flocks of water insoluble, so as to achieve the purpose of the removal of metal ions. Ion-exchange method in wastewater has broad prospects, so fast in recent years. In recent years new types of ion exchange and adsorption resins constantly, laid the Foundation for
10、 development of ion-exchange resin industry in China and played a great role in promoting. Meanwhile, the rapid development of the ion exchange resins are also abroad, according to the statistics, United States ion exchange resin consumption is growing at an annual rate of 5.8%, 132 million pounds i
11、n 1998 alone the ion exchange resin is applied to water treatment, metal recovery, chemical processing and other fields.The devices in a design capacity of up to 1 m3. Water quantity and quality of waste water: wastewater containing Cr2+ : concentrations of average emissions of 1.0 m3 per hour. Comb
12、ination of wastewater characteristics of water quality and quantity, decides to handle wastewater by ion-exchange method, selection of 116 macroporous weak acid cation exchange resin, removal from waste water by Ni2+ ions, Ion Exchange reaction so that it generated precipitation that does not dissol
13、ve in water, so as to achieve the purpose of separating harmful ions to ensure meeting emissions standards.Keywords: electroplating wastewater , nickel, ion exchange resin 目录第一章 前 言111电镀废水的来源112电镀废水的危害1第二章 绪 论22.1电镀污水的特性22.2化工设备设计的基本要求2第三章 物料计算43.1 污水的物理化学处理43.1.1 萃取43.1.2 电解43.1.3 吸附43.1.4 离子交换法53.
14、2 离子交换法的相关工艺及计算53.2.1 离子交换树脂的结构53.2.2 树脂的分类及性质63.2.3 离子交换反应原理73.2.4 离子交换操作过程7离子交换设备的分类及特点7电镀污水数据8树脂用量计算8第四章 设计计算94.1 设计数据94.2 材料及构件的选择94.2.1 材料的选择94.2.2 构件的选择94.3 设计计算内容114.3.1 筒体的设计114.3.2 封头的设计114.3.3 压力试验144.3.4 人孔的设计14容器载荷计算:18支座的设计18焊接接头设计:20第五章 鞍座的校核225.1 鞍式支座选用及配置225.2 支反力计算225.3 筒体轴向弯矩计算225.
15、4 筒体轴向弯曲应力校核235.5 鞍座处筒体切向剪应力校核255.6 鞍座处筒体周向应力校核255.7 鞍座腹板强度校核26第六章设备检验27第七章 电镀废水处理技术的发展与展望28参 考 文 献致 谢附 录第一章 前 言电镀是利用化学或电化学的方法对金属和非金属表面进行装饰、防护及获取某些新性能的一种工艺过程,在工业上通用性强,使用面广,几乎所有的工业部门(如机械、机电、交通、电子、仪表、纺织、轻工等)都有电镀厂(车间)。但由于电镀厂分散而面广,镀件功能要求各异,镀种、镀液组分、操作方式及工艺条件等种类繁多,相应带入电镀废水中的污染物也就变得较为复杂,电镀废水水质成分不易控制,常见的铬、铜、镍、锌、锡、铅、镉及铁
