一回路主止回阀结构优化及流体力学分析
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摘要
船用核动力装置与民用核动力装置相比,由于其特殊的工作环境和性能要求,所以在结构上有所不同。为了保证船用核动力装置在特殊情况下工作的稳定性,其一回路设计有备用回路。备用回路和主回路之间通过止回阀进行连接,它们之间可以互相切换工作。在切换的过程中,不但要求阀门能够稳定可靠的工作,而且还要求它不能完全关死。否则不工作的回路会因为水温过低而影响反应堆的稳定性。这就对止回阀的性能提出了更多的要求。
本文所要研究的止回阀就是针对上述问题设计制造的。它有别于传统意义上的止回阀,由于其对冲原理可以大大减小阀的水击作用。本文的研究是在前人研究的基础上,针对对冲式止回阀原理样机在实验中出现低流量关不上关不严的问题,对主止回阀的结构提出了改进。应用AutoCAD和Pro/E对止回阀改进结构的流道进行建模,并且用GAMBIT划分完网格,最后用CFD软件FLUENT对阀的关闭过程进行数值模拟。计算出阀门在关闭过程中压力变化云图、速度变化云图、阀头阀座的受力变化曲线以及速度变化曲线,通过这些参数来判断阀门的工作状态,找出止回阀存在的问题的根源并加以解决。最后通过实验验证理论分析的结果,对比理论值与实际值之间的差距并分析原因。
通过动态模拟得到了阀头阀座的受力曲线、速度曲线以及流量变化曲线。计算的结果表明,在各种工况下阀门都能够自动关闭,阀座的受力和运动速度都明显大于阀头的。阀头阀座的受力和运动速度都是随着时间的增大而增大。逆流压差的大小直接影响回流量的大小和阀门的关闭速度以及阀头阀座的受力。压差越大,阀头阀座的受力和运动速度越大,回流量越大。
Compared with the Civil Nuclear Power Plant (CNPP), the Marine Nuclear Power Plant (MNPP) is very different from that in structure due to its special work environment and performance requirement. It is necessary to equip with the spare loop in MNPP to ensure its stability under special circumstances. The spare loop and primary loop, which are connected by the check valve, can be switched to work. When it was switched to another circuit, the valve, on one hand, should work stably, on the other hand, should not be closed tightly or else the other non-working loop will influence the stability of the nuclear reactors because of the lower temperature. Therefore, more requirements are needed for the performance of the check valve.
In the paper, the valve is designed to solve the problems mentioned above. It is distinguished with the traditional valve for the hedging principle adopted can deduce the water hammer pressure to the valve. On the basis of the previous research, the structure of the primary valve is to be improved aiming to deal with the inner leakage problem of the low-flowing prototype under the reverse check valve principle. By adoption of AutoCAD and Pro/E, the flow channel of the improved check valve is modeled; mesh is generated by GAMBIT, and the check valve closure process is numerically simulated by CFD software. Thus, the pressure changes contours of the closure process, velocity changes contours, the force changes curve and the velocity changes curve can be obtained. Based on these parameters, the work statement of the valve can be determined as well as the existing problem can be found and solved. To testify the theoretically analyzed results, experiments must be resorted and the differences between the theoretical results and the practical ones should be analyzed.
By dynamic simulation, the time dependent graphs of the forces on valve head and seat, velocity and flow rate variation can be obtained. The results show that the new-type check valve can close automatically under different operating conditions. The force and velocity on the valve seat are significantly greater than those on the valve head. As the time increases, the force and velocity are increasing. The pressure difference of counter flow will influence the reflux flow, the velocity of closing and the force on valve head and seat directly. The larger pressure difference is, the greater the valve head force and the motion speed will be, the greater the valve seat force and the motion speed are as well as back to more flux.
本文所要研究的止回阀就是针对上述问题设计制造的。它有别于传统意义上的止回阀,由于其对冲原理可以大大减小阀的水击作用。本文的研究是在前人研究的基础上,针对对冲式止回阀原理样机在实验中出现低流量关不上关不严的问题,对主止回阀的结构提出了改进。应用AutoCAD和Pro/E对止回阀改进结构的流道进行建模,并且用GAMBIT划分完网格,最后用CFD软件FLUENT对阀的关闭过程进行数值模拟。计算出阀门在关闭过程中压力变化云图、速度变化云图、阀头阀座的受力变化曲线以及速度变化曲线,通过这些参数来判断阀门的工作状态,找出止回阀存在的问题的根源并加以解决。最后通过实验验证理论分析的结果,对比理论值与实际值之间的差距并分析原因。
通过动态模拟得到了阀头阀座的受力曲线、速度曲线以及流量变化曲线。计算的结果表明,在各种工况下阀门都能够自动关闭,阀座的受力和运动速度都明显大于阀头的。阀头阀座的受力和运动速度都是随着时间的增大而增大。逆流压差的大小直接影响回流量的大小和阀门的关闭速度以及阀头阀座的受力。压差越大,阀头阀座的受力和运动速度越大,回流量越大。
Compared with the Civil Nuclear Power Plant (CNPP), the Marine Nuclear Power Plant (MNPP) is very different from that in structure due to its special work environment and performance requirement. It is necessary to equip with the spare loop in MNPP to ensure its stability under special circumstances. The spare loop and primary loop, which are connected by the check valve, can be switched to work. When it was switched to another circuit, the valve, on one hand, should work stably, on the other hand, should not be closed tightly or else the other non-working loop will influence the stability of the nuclear reactors because of the lower temperature. Therefore, more requirements are needed for the performance of the check valve.
In the paper, the valve is designed to solve the problems mentioned above. It is distinguished with the traditional valve for the hedging principle adopted can deduce the water hammer pressure to the valve. On the basis of the previous research, the structure of the primary valve is to be improved aiming to deal with the inner leakage problem of the low-flowing prototype under the reverse check valve principle. By adoption of AutoCAD and Pro/E, the flow channel of the improved check valve is modeled; mesh is generated by GAMBIT, and the check valve closure process is numerically simulated by CFD software. Thus, the pressure changes contours of the closure process, velocity changes contours, the force changes curve and the velocity changes curve can be obtained. Based on these parameters, the work statement of the valve can be determined as well as the existing problem can be found and solved. To testify the theoretically analyzed results, experiments must be resorted and the differences between the theoretical results and the practical ones should be analyzed.
By dynamic simulation, the time dependent graphs of the forces on valve head and seat, velocity and flow rate variation can be obtained. The results show that the new-type check valve can close automatically under different operating conditions. The force and velocity on the valve seat are significantly greater than those on the valve head. As the time increases, the force and velocity are increasing. The pressure difference of counter flow will influence the reflux flow, the velocity of closing and the force on valve head and seat directly. The larger pressure difference is, the greater the valve head force and the motion speed will be, the greater the valve seat force and the motion speed are as well as back to more flux.
引文
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[2]哥本哈根气候大会报告.2009.
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[8]冯章俊.对冲式止回阀动态特性分析.哈尔滨工程大学硕士学位论文.2009:1-3页.
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[10]姜礼斌.阀致水击PID控制研究.昆明理工大学硕士学位论文.2005:4-6页.
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[25]刘霞光.新型止回阀稳态与瞬态流场数值模拟.西安交通大学硕士学位论文.2009:17页.
[26]江春波,张永良,丁则平.计算流体力学.第1版.中国电力出版社,2007:2,11,44,85页
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[29]陶文铨.数值传热学.第2版.西安交通大学出版社,2001:52页.
[30]王福军.计算流体动力学分析—CFD软件原理与应用.第1版.清华大学出版社2004:5页.
[31]王瑞金,张凯,王刚FLUENT技术基础与应用实例.第1版.清华大学出版社,2007:1页.
[32]付祥钊.计算流体力学.第1版.重庆大学出版社,2007:10-11页.
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[35]Batina JT. Implicit flux-split Euler schemes for unsteady aerodynamic analysis involving unstructured dynamic meshes. N91-10918,1990.
[36]王军利,白俊强,詹浩.非结构网格在三维可动边界问题中的应用研究.航空计算技术.2005,第35卷,第3期:2页.
[37]Dynamic Mesh Model FLUENT v6.1.FLUENT User Services Center.March 2003.5-8页.
[38]FLUENT UDF中文教程.2007:1页.
[39]冯进,张慢来,黄天成.安全阀水动力特性的CFD模拟和研究.核动力工程.2007,28(5):2-3页.
[40]谭平,王斌.核电厂安全阀排汽激振分析.核动力工程,2005,26(3):277-279页.
[41]谭浩强.C语言程序设计.第2版.清华大学出版社,1999:38,45,173页.
[42]于勇FLUENT入门与进阶教程.第1版.北京理工大学出版社,2008:22页.
[43]王松岭.流体力学.第1版.中国电力出版社,2006:44页.
[44]阎超.计算流体力学的方法及应用.第1版.北京航空航天大学出版社,2006:157页.
[45]FLUENT全攻略.第1版.2005:6-7页.
[46]韩占忠,王敬FLUENT流体工程仿真计算实例与应用.第1版.北京理工大学出版社.2004:5-6页.
[47]赵春芳,严晓敏.基于PLC的变频器控制在茶叶揉捻机中的应用.机床电器.2010,PLC变频器:1-2页.
[48]刘春雨,韩伟实.基于LabVIEW的反应堆启动数据采集系统.微计算机信息.2009(4):74页.
[49]赵麦群,雷阿丽.金属的腐蚀与防护.第1版.国防工业出版社,2002:1页.
[50]徐瑾,杨小林.一种不锈钢用固体除锈剂.腐蚀与防护.2005,26(7):303,304页.
[51]李强.缓蚀剂ETA在核电站二回路水处理中的应用.哈尔滨工程大学硕士学位论文.2006:30-31页.
[52]张开.粘合与密封材料.第1版.化学工业出版社.1996:347页.
[2]哥本哈根气候大会报告.2009.
[3]国家发展和改革委员会.核电中长期发展规划.2007.
[4]阎昌琪.核反应堆工程.第1版.哈尔滨工程大学出版社,2007:1页.
[5]张云龙.核电站用阀门.阀门.2004,第1期:22-23页.
[6]朱继洲.核反应堆安全分析.第1版.西安交通大学出版社、原子能出版社,2007:41-42页
[7]谢仲生.核反应堆物理分析(修订本).第1版.西安交通大学出版社、原子能出版社,2005:99页.
[8]冯章俊.对冲式止回阀动态特性分析.哈尔滨工程大学硕士学位论文.2009:1-3页.
[9]洪勉成.阀门设计计算手册.北京:中国标准出版社,1994.
[10]姜礼斌.阀致水击PID控制研究.昆明理工大学硕士学位论文.2005:4-6页.
[11]《国外阀门基本情况》编写组编.阀门.北京:第一机械工业部科技情报所.1982.
[12]黄海,张相彬,曹宏涛,李杨.核电阀门的技术现状及发展方向.阀门.2005,第3期:15-16页.
[13]韩旭,周羽.对冲式止回阀的原理及启闭特性分析.核动力工程.2006,27(1):1页.
[14]Wilkinson D H, Dartnell L M. Water Hammer Phenomena in Thermal Power Station Feed Water System. Proc.Inst. of Mech. Eng., Vol.194, Jan.1980.
[15]雍歧卫,瞿德刚.止回阀水力特性分析及水击计算.阀门.2003,第5期:1页.
[16]机械工业信息研究院编.阀门产品供应目录.北京:机械工业出版社,2002.
[17]吴永进,林美樱AutoCAD 2007中文版实用教程-基础篇.第1版.人民邮电出版社,2008:1-3页.
[18]孙小捞,邱玉江Pro/ENGINEER Wildfire 4.0中文版教程.第2版.人民邮电出版社,2010:3-5页.
[19]GAMBIT user's guide. FLUENT Inc.2000.
[20]傅德薰,马延文.计算流体力学.第1版.高等教育出版社,2002:148页.
[21]FLUENT user's guide. FLUENT Inc.2006.
[22]莫乃榕.工程流体力学.第2版.华中科技大学出版社.2009:74-75页.
[23]温正,石良,辰任毅如.第1版FLUENT流体计算应用教程.清华大学出版社,2009:11,59页.
[24]蔡增基,龙天渝.计算流体力学.第1版.重庆大学出版社.2007:30-33页.
[25]刘霞光.新型止回阀稳态与瞬态流场数值模拟.西安交通大学硕士学位论文.2009:17页.
[26]江春波,张永良,丁则平.计算流体力学.第1版.中国电力出版社,2007:2,11,44,85页
[27]刘国俊.计算流体力学的地位、发展情况和发展趋势.航空计算技术.1994,第1卷:15-21页.
[28]魏淑贤,沈跃,黄延军.计算流体力学的发展及应用.河北理工学院学报.2005,第27卷,第2期:2页.
[29]陶文铨.数值传热学.第2版.西安交通大学出版社,2001:52页.
[30]王福军.计算流体动力学分析—CFD软件原理与应用.第1版.清华大学出版社2004:5页.
[31]王瑞金,张凯,王刚FLUENT技术基础与应用实例.第1版.清华大学出版社,2007:1页.
[32]付祥钊.计算流体力学.第1版.重庆大学出版社,2007:10-11页.
[33]陈汉平.计算流体力学.第1版.水利电离出版社,1995:1-7页.
[34]刘明侯.FLUENT简明教程.第1版.中国科技大学出版社,2005:5页.
[35]Batina JT. Implicit flux-split Euler schemes for unsteady aerodynamic analysis involving unstructured dynamic meshes. N91-10918,1990.
[36]王军利,白俊强,詹浩.非结构网格在三维可动边界问题中的应用研究.航空计算技术.2005,第35卷,第3期:2页.
[37]Dynamic Mesh Model FLUENT v6.1.FLUENT User Services Center.March 2003.5-8页.
[38]FLUENT UDF中文教程.2007:1页.
[39]冯进,张慢来,黄天成.安全阀水动力特性的CFD模拟和研究.核动力工程.2007,28(5):2-3页.
[40]谭平,王斌.核电厂安全阀排汽激振分析.核动力工程,2005,26(3):277-279页.
[41]谭浩强.C语言程序设计.第2版.清华大学出版社,1999:38,45,173页.
[42]于勇FLUENT入门与进阶教程.第1版.北京理工大学出版社,2008:22页.
[43]王松岭.流体力学.第1版.中国电力出版社,2006:44页.
[44]阎超.计算流体力学的方法及应用.第1版.北京航空航天大学出版社,2006:157页.
[45]FLUENT全攻略.第1版.2005:6-7页.
[46]韩占忠,王敬FLUENT流体工程仿真计算实例与应用.第1版.北京理工大学出版社.2004:5-6页.
[47]赵春芳,严晓敏.基于PLC的变频器控制在茶叶揉捻机中的应用.机床电器.2010,PLC变频器:1-2页.
[48]刘春雨,韩伟实.基于LabVIEW的反应堆启动数据采集系统.微计算机信息.2009(4):74页.
[49]赵麦群,雷阿丽.金属的腐蚀与防护.第1版.国防工业出版社,2002:1页.
[50]徐瑾,杨小林.一种不锈钢用固体除锈剂.腐蚀与防护.2005,26(7):303,304页.
[51]李强.缓蚀剂ETA在核电站二回路水处理中的应用.哈尔滨工程大学硕士学位论文.2006:30-31页.
[52]张开.粘合与密封材料.第1版.化学工业出版社.1996:347页.