A装配图
35t/h锅炉热管回收排烟余热系统的设计
摘要随着社会的发展,科技在不断地进步,人们对能源的需求也越来越大。我国是进过改革开放30年各行各业突飞猛进,对能源的需求也进一步加大。热能是在所需能源中占比最高的一类能源。科技进步了就需要更多的热能,现在已经进入21世纪,国家倡导低碳环保,不能一味的增加锅炉来满足需求。我们需要降低锅炉排烟温度,提高锅炉的效率。这样既能增加热能,又能保护环境。
这次设计是通过热管式换热器来降低小型锅炉的排烟温度。热管作为一门新的技术,已经逐渐被广大的工程技术人员熟悉和重视。热管可用于航天、原子反应堆、电子器件、电器、电机、太阳能利用、轻工、化工等领域。热管自1964年首次由美国的洛斯阿拉莫斯科学实验室提出来后,对他的研究和应用发展的很快。特别是在我国号召节能减排,热管技术在工业锅炉、窑炉上节能的应用越来越多。本次设计使用的是重力热管,设计中对热管的阻力、传热量、需用应力都进行了校核,并取得了设计要求的效果。
本次设计共分成五章,第一第二章主要介绍了换热器的种类和应用,后面几章主要介绍了热管换热器的设计和运用。
关键词:余热回收换热器热管热管设计
Abstract With the fast development of modern society, our technology continues to progress, human race needs more and more energy. China’s reform and opening-up policy has made great progress in many fields in the past 30 years, by the same time our demand for energy has grown up. Heat energy occupied the most percentage of the energy we used. Most of heat was made by the combustion of fossil fuels, this process will produce greenhouse gases, and it will influence our environment. At the beginning of the 21th, Chinese government advocate for low-carbon environment, it is not a good idea for blindly burning large amounts of fossil fuels to meet our demand for heat energy. We need to increase the efficiency of thermal energy, make full use of heat by quality. So that we can get enough energy by the same time we need less fossil fuels.
My design targets on the recovery of boil waste heat, through the heat pipe heat exchanger to reduce the small boiler flue gas temperature. As a new technology, Heat Pipe was widely acknowledged by engineers in many fields, and take great importance on this technology. Heat pipe can be used in aerospace, atomic reactors, electronics, appliances, motors, solar energy, light industry, chemical industry and other fields. The concept of the heat pipe was firstly proposed by Los Alamos Scientific Laboratory in America. It was widely discovered and used since we proposed the concept. Especially in the society of China, we call for energy conservation. Heat pipe technology was widely used in industry such as industrial boilers, kilns. I designed a gravity Heat Pipe, and I have carried out a check for the resistance of heat transfer and the amount of heat transfer together with the allowable stress. It meets well to the design requirments.
The design is divided into five chapters, The first and second chapter introduces heat exchanger types and applications, followed chapters introduces the heat pipe exchanger design and use.
Key words Waste heat recovery heat exchanger Heat pipe Heat pipe design
目录
第一章换热器1
1.1换热器的分类1
1.2冷水塔1
1.3回转型蓄热式热交换器2
第二章热管4
2.1热管的结构4
2.1.1管壳5
2.2.2吸液芯5
2.2.3蒸汽空间5
2.2.4翅片5
2.2热管的工作原理6
2.3热管的工作极限6
2.3.1黏性极限7
2.3.2音速极限7
2.3.3携带极限8
2.3. 4毛细极限8
2.3.5沸腾极限9
2.4热管换热器的分类9
2.4.1气气热管换热器9
2.4.2气液热管换热器9
2.4.3气汽热管换热器9
第三章热管的设计10
3.1给定参数10
3.2热管的基本选择10
3.2.1工质的选择10
3.2.2管材的选择11
3.2.3管子的布置11
3.3机构设计12
3.3.1入口流速的选择12
3.3.2经济长度比的选择12
3.3.3气体侧的迎风面积13
3.3.4换热系数的选择13
3.3.5平均温差14
3.3.6传热面积的计算14
3.4精确计算14
第四章热管计算15
4.1烟气与水15
4.2热管的基本选择16
4.3热管的安装17
4.4管径和扩展面的选择17
4.5端盖厚度19
4.6烟气入口质量流速的选择19
4.7迎风面积和传热面积19
第五章传热计算21
5.1基础数据21
5.2热管外壁的传热系数21
5.2.1蒸发段传热系数21
5.2.2冷凝段传热系数23
5.2.3经济长度比的计算23
5.3热管内的传热系数23
5.4积灰热阻的计算24
5.5对数平均温度25
5.6估算传热面积25
5.7管子的数目及排列方式25
5.8水侧管程的计算26
5.9管箱和分层隔板的设计27
第六章校核计算28
6.1烟气侧阻力计算28
6.2水侧的阻力计算28
6.3壁温计算28
6.4热管强度28
总结30
致谢31
参考文献: 32
上箱体法兰
冷凝段端盖
凸台
出气口法兰
塞子
字数
新热管
热管管壳
目录
端盖
设计所包含文件
进水口法兰
隔板
摘要
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