锅炉管壁金属温度计算和软件开发
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摘要
换热部件中超温爆管现象是锅炉运行中最常见的事故之一。随着锅炉容量的日益增大,锅炉的结构更趋复杂,锅炉中超温爆管事故也不断增加。壁温计算即通过迭代求解锅炉高温区部件中关键位置处的管壁金属温度,以保证锅炉部件的安全,从而为确定部件的制造材料提供基础数据。本文在浙江大学化工机械研究所与无锡华光锅炉集团的合作项目“锅炉设计计算集成系统开发”的研究工作的基础上,根据锅炉设计安全校核的需求,针对国内锅炉厂用户使用的习惯,开发了一套针对各类型锅炉都适用的壁温计算子系统。本文的主要研究内容如下:
总结了国内锅炉行业集成系统开发的现状,分析了锅炉管壁温度因为流量分配和热力分配造成超温爆管现象的原因。归纳了壁温计算的算法原理:经验算法、数值计算算法,并对算法进行了扩充和总结。给出了壁温计算子系统开发的物理模型。
采用面向对象技术对工程信息图形化标注系统进行需求分析,使用统一建模语言UML给出系统的软件模型。根据系统实际功能的需要,将其分为“总控包”、“计算包”、“计算结果处理包”三个主要功能模块。
分析壁温计算子系统内部各数据结构之间的关系,将系统内部数据分为“计算点类对象”、“算法类对象”、“部件类对象”三种类型,并使用集合类的方式分别对其进行管理,同时给出管理行为的具体算法。
使用了大量的迭代算法完成了壁温计算校核过程;运用OLE技术实现了壁温计算工程计算书的输出:以MFC库中CDC类为基类,实现了结果曲线绘制功能;使用多种软件界面技术实现系统的各种人机交互。
建立了系统与锅炉设计计算集成系统之间的集成,共同完成整个锅炉设计工作。实现了各子系统间的数据交换,函数共享。该系统已经在国内几家大型锅炉厂使用,进行了大量的实例运算,验证了系统的准确性。
With the increase capability and complex structure of boiler, the frequency of tube explosion of heat exchange components in super high temperature circumstance grows dramatically, and becomes one of the most frequently happened accidents. Temperature of tube wall, through iterative calculation of tube wall temperature in the key location of high temperature area of the boiler, is computed to guarantee the safety of boiler components and provide basic data to choose the raw material of these components.
Based on the cooperative project between the Institute of Process Equipment and Control Engineering in Zhejiang University and Wuxi HuaGuang Boiler Co., Ltd , "Boiler Engineering Simulation System", this dissertation explores the System of Tube Wall Temperature Calculation. This system used to make sure the boiler's tube wall temperature in safe during the boiler running. The main content of the dissertation is present as follows:
Summarized the present integration software explore technology status in China. Analyzed the reasons cause tube wall temperature exceed, which is the flux distribute asymmetry and the thermal distribute asymmetry. Presented the physical model of Tube Wall System, using the methods of experience arithmetic and numerical arithmetic.
Using the Object-Oriented technology to analyze the requirement of Engineering Information Graphic Marking System, introducing Unified Modeling Language to describe the system model. According the system functions requirement, decomposing the model to three main modules: "Main Command Package", "Calculation Package", "Calculation results Treatment Package".
Analyzing the relationship between the system member data, disintegrating all the data to three types: "Calculation point Class Object", "Calculation methods Class Object", "Parts Object". After that, building the actual aggregation classes to manage these member data, then, providing the concrete algorithm of management behavior of an aggregation class.
Used lots of iterative arithmetic to complete tube wall temperature calculation. Used the OLE technology to generate engineering computing results list. Used class CDC of MFC library as a base class to realize results curve plot. At the same time, with the help of software interface technologies, realizing human-computer interactions of the system.
Building the integration between the system and the Boiler Engineering Simulation System to complete boiler design assignment together. Each subsystem in this integration System can share the data and function. This system has been used in several boiler factories. With large instances tested, system proved veracity.
总结了国内锅炉行业集成系统开发的现状,分析了锅炉管壁温度因为流量分配和热力分配造成超温爆管现象的原因。归纳了壁温计算的算法原理:经验算法、数值计算算法,并对算法进行了扩充和总结。给出了壁温计算子系统开发的物理模型。
采用面向对象技术对工程信息图形化标注系统进行需求分析,使用统一建模语言UML给出系统的软件模型。根据系统实际功能的需要,将其分为“总控包”、“计算包”、“计算结果处理包”三个主要功能模块。
分析壁温计算子系统内部各数据结构之间的关系,将系统内部数据分为“计算点类对象”、“算法类对象”、“部件类对象”三种类型,并使用集合类的方式分别对其进行管理,同时给出管理行为的具体算法。
使用了大量的迭代算法完成了壁温计算校核过程;运用OLE技术实现了壁温计算工程计算书的输出:以MFC库中CDC类为基类,实现了结果曲线绘制功能;使用多种软件界面技术实现系统的各种人机交互。
建立了系统与锅炉设计计算集成系统之间的集成,共同完成整个锅炉设计工作。实现了各子系统间的数据交换,函数共享。该系统已经在国内几家大型锅炉厂使用,进行了大量的实例运算,验证了系统的准确性。
With the increase capability and complex structure of boiler, the frequency of tube explosion of heat exchange components in super high temperature circumstance grows dramatically, and becomes one of the most frequently happened accidents. Temperature of tube wall, through iterative calculation of tube wall temperature in the key location of high temperature area of the boiler, is computed to guarantee the safety of boiler components and provide basic data to choose the raw material of these components.
Based on the cooperative project between the Institute of Process Equipment and Control Engineering in Zhejiang University and Wuxi HuaGuang Boiler Co., Ltd , "Boiler Engineering Simulation System", this dissertation explores the System of Tube Wall Temperature Calculation. This system used to make sure the boiler's tube wall temperature in safe during the boiler running. The main content of the dissertation is present as follows:
Summarized the present integration software explore technology status in China. Analyzed the reasons cause tube wall temperature exceed, which is the flux distribute asymmetry and the thermal distribute asymmetry. Presented the physical model of Tube Wall System, using the methods of experience arithmetic and numerical arithmetic.
Using the Object-Oriented technology to analyze the requirement of Engineering Information Graphic Marking System, introducing Unified Modeling Language to describe the system model. According the system functions requirement, decomposing the model to three main modules: "Main Command Package", "Calculation Package", "Calculation results Treatment Package".
Analyzing the relationship between the system member data, disintegrating all the data to three types: "Calculation point Class Object", "Calculation methods Class Object", "Parts Object". After that, building the actual aggregation classes to manage these member data, then, providing the concrete algorithm of management behavior of an aggregation class.
Used lots of iterative arithmetic to complete tube wall temperature calculation. Used the OLE technology to generate engineering computing results list. Used class CDC of MFC library as a base class to realize results curve plot. At the same time, with the help of software interface technologies, realizing human-computer interactions of the system.
Building the integration between the system and the Boiler Engineering Simulation System to complete boiler design assignment together. Each subsystem in this integration System can share the data and function. This system has been used in several boiler factories. With large instances tested, system proved veracity.
引文
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[5] 朱成章.当前国际电力工业的发展趋势[J].中国能源,1999,10:35-37.
[6] 林伟明.加入WTO对我国锅炉压力容器等特种设备行业的影响及对策[J].中国锅炉压力容器安全,2003(2):9-13,2003(3):1-7.
[7] 吴磊.1025t/h锅炉高温过热器爆管原因分析与寿命预测[D].武汉大学工程硕士学位论文,2004.
[8] 胡文森.电站锅炉屏式过热器超温、爆管的研究与技术应用[D].华北电力大学硕士学位论文,2000.
[9] 李鑫.莱城电厂1025t/h锅炉再热器爆管研究与实践[D].华北电力大学硕士学位论文,2006.
[10] 张新生,熊力红,唐必光.过热器壁温计算模型及寿命估算[J].电力建设,1999,10:15-18.
[11] 余艳芝,唐必光,李树雷.高温过热器壁温测试及计算[J].热能动力工程,2003,18(1):71-72.
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[14] A.M.古尔维奇,H.B.库兹涅佐夫.锅炉机组热力计算标准方法[M].北京:机械工业出版社,1973.
[15] 花景明,吴明.用数值方法计算加热器管壁温度[J].当代化工,2004,4:96-98.
[16] 刘清芝.化学化工软件集成技术研究[D].中国海洋大学硕士学位论文,2004.
[17] 廖莉.“行波管CAD集成环境”软件的研发[D].电子科技大学硕士学位论文,2006.
[18] 王瑗珲,陈铁军,何文斌.郑州锅炉厂信息化集成系统总体方案[J]。制造业自动化,2003,11:14-16.
[19] 赵丰宇,蒋红宇,宗晓杰.PDM在哈尔滨锅炉厂的应用前景[J].农机所研究,2003,7(3):15-18.
[20] 周玉清等.ERP理论、方法与实践[M].北京:电子工业出版社.2006.
[21] 彭祖成.面向ERP集成的产品结构与配置管理的研究[J].成组技术与生产现代化,2006,23(4):45-47.
[22] 钟崴,许跃敏,童水光.通用锅炉热力计算算法研究[J].华东电力,2000,6:18-21.
[23] 许跃敏.锅炉设计的通用热力计算模型[J].工程设计,1997,3:72-76.
[24] 钟崴.锅炉智能CAD的技术、方法和模型研究[D].浙江大学博士学位论文,2002.
[25] 周鸿波,钟崴,徐阳.通用工业锅炉热力计算系统的研究与开发[J].化工机械,2006,5.
[26] 薄玉林.SHL20-25/400-A型锅炉集箱破裂事故分析[J].中国特种设备安全,2005,21(6):50-52.
[27] 王恩禄,张海燕,罗永浩等.电站锅炉分配集箱静压分布参数的确定[J]。上海交通大学学报,2004,38(7):1185-1187.
[28] 张蓉媛.大型电站锅炉过热器系统热偏差计算与壁温特性研究[D].华北电力大学硕士学位论文,2000.
[29] 邓广发,曹常龙.高温过热器超温爆管分析及处理[J].江苏机电工程,2003,22(4):43-45.
[30] 施鸿飞,赵发明等.300MW锅炉过热器超温爆管问题的试验研究[J].发电设备,2003,5:6-8.
[31] N.L. Gel'perin, K.N. Solopenkov and A.Kh. Ujunov, Experimental Investigation of Heat Transfer during the Boiling of Liquids. Internat. Chem. Engrg. 9 (1969), pp. 627-630.
[32] F.R. Steward and Y.S. Kocaefe, Methods for determining the radiative transfer in a furnace chamber using the fundamental equations of motion and transport of heat and mass. In: Proc. Seventh Int. Heat Transfer
[33] 郑昌浩,徐旭常.电站锅炉对流过热器和在热器壁温数值计算方法的研究[J].动力工程,2000,20(4):730-734.
[34] 赵星海,魏春明,辛国华.电站锅炉屏式过热器管壁温度的数值分析方法[J].锅炉技术,2004,35(6):14-17.
[35] 绍维忠,杨芙清.面向对象的系统分析[M].北京:清华大学出版社,2004.
[36] Stanley B.Lippman,Josee Lajoie著.潘爱民,张丽译.C++Primer(第三版)[M].中国电力出版社,2002.
[37] 侯俊杰.深入浅出MFC第2版[M].华中科技大学出版社,2001.
[38] 范玉顺,曹军威.复杂系统的面向对象建模、分析与设计[M].清华大学出版社.2000.
[39] 宋波,刘杰,杜庆东.UML面向对象技术与实践[M].北京:科学出版设,2006.
[40] Grandy Booch,James Rumbaugh,Ivar Jacobson著.绍维忠,麻志毅,张文娟等译.UML用户指南[M].北京:机械工业出版社,2001.
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