基于逆向工程与CFD的矿井主扇风机流场分析及仿真研究
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摘要
矿井主扇风机是煤矿安全生产的关键技术装备,矿井主扇风机能否正常运转关系到整个矿井的生产安全。作者所在课题组提出了矿用设备健康维护系统,针对矿井轴流风机进行建模仿真研究,分析其性能以及故障特性。
首先对矿井轴流风机结构进行建模,由于矿井轴流风机的结构参数资料不详,尤其叶轮部分的参数生产厂家无法提供,本文采用了逆向工程方法对风机进行逆向建模,即通过三维扫描获取其点云数据,用建模软件对其数据进行处理,同时对其进行反求建模,进一步对模型进行网格划分,导入到流体仿真软件中进行求解。
采用FLUENT软件对矿井轴流风机正常状态下的流场进行仿真求解,通过对不同工况下的流场进行模拟获得其流场特性曲线,并对其特性进行分析,为矿井轴流风机运行状态下的优化提供参考。本文对矿井轴流风机的典型故障进行流场仿真,分析其故障下的流场特性,以及可能导致故障的原因和故障发展规律,为矿井主扇风机的预知维护提供重要的依据。
The coal is main part of our country energy, mine main fan is the key technology and equipment of safety production in coal mine. Mine fan which can be normal operation is in relation to the whole mine production efficiency and production safety, the author's group put forward the research of mining equipment health maintenance system, as for the equipment simulation part it makes mine axial flow fan model simulation, and analyzes its performance and fault characteristics.
At first it take model of the axial flow fan structure, in view of the mine axial flow fan structure parameter insufficient, especially the impeller part of the parameters unavailable directly from manufactures, in this paper it takes advantage of the reverse engineering method to make reverse fan model. Firstly through3d scanning it get the point cloud data, then make use of modelling software for the data processing, finally take the reverse modelling. Next by obtaining model grid division, it imports the file to fluid simulation software for solving.
The normal state of the flow field in mine axial flow fan is simulated by using FLUENT software, based on the internal flow field simulation of different work condition flow, it get and analyze the performance curve and provides optimization Suggestions for current status of performance of mine axial flow fan. In addition this paper simulates typical fault, and analyzes the flow field characteristic, the cause and law of development of failure, it provides important basis for prescient maintenance of mine fan.
首先对矿井轴流风机结构进行建模,由于矿井轴流风机的结构参数资料不详,尤其叶轮部分的参数生产厂家无法提供,本文采用了逆向工程方法对风机进行逆向建模,即通过三维扫描获取其点云数据,用建模软件对其数据进行处理,同时对其进行反求建模,进一步对模型进行网格划分,导入到流体仿真软件中进行求解。
采用FLUENT软件对矿井轴流风机正常状态下的流场进行仿真求解,通过对不同工况下的流场进行模拟获得其流场特性曲线,并对其特性进行分析,为矿井轴流风机运行状态下的优化提供参考。本文对矿井轴流风机的典型故障进行流场仿真,分析其故障下的流场特性,以及可能导致故障的原因和故障发展规律,为矿井主扇风机的预知维护提供重要的依据。
The coal is main part of our country energy, mine main fan is the key technology and equipment of safety production in coal mine. Mine fan which can be normal operation is in relation to the whole mine production efficiency and production safety, the author's group put forward the research of mining equipment health maintenance system, as for the equipment simulation part it makes mine axial flow fan model simulation, and analyzes its performance and fault characteristics.
At first it take model of the axial flow fan structure, in view of the mine axial flow fan structure parameter insufficient, especially the impeller part of the parameters unavailable directly from manufactures, in this paper it takes advantage of the reverse engineering method to make reverse fan model. Firstly through3d scanning it get the point cloud data, then make use of modelling software for the data processing, finally take the reverse modelling. Next by obtaining model grid division, it imports the file to fluid simulation software for solving.
The normal state of the flow field in mine axial flow fan is simulated by using FLUENT software, based on the internal flow field simulation of different work condition flow, it get and analyze the performance curve and provides optimization Suggestions for current status of performance of mine axial flow fan. In addition this paper simulates typical fault, and analyzes the flow field characteristic, the cause and law of development of failure, it provides important basis for prescient maintenance of mine fan.
引文
[1]况世华,何丽华.矿用通风机发展概述[J].云南冶金,2008,37(6):4-7
[2]张惠忠.我国矿井主扇风机发展概况评述[J].煤矿安全,1994,(06):28
[3]赵涛,吕素荣,戈猛等.基于集成战略的工业维护管理理论体系的构建[J].机械设计,2003,20(9):1-3
[4]Moubray J. Reliability-centred maintenance [M]. New York:Industrial press.2001:19-25
[5]李德刚.设备预知维护的体系理论及支撑技术研究[D].湖南大学博士论文,2006:13-14
[6]李葆文.简明现代设备管理手册[M].北京:机械工业出版社,2004:22-35
[7]伍星,陈进,李如强等.设备远程监测与诊断系统体系结构的研究[J].计算机工程与应用,2005,41(9):192-196.
[8]Zorriassatine F, AshrafB, Notini L, et al. Smarter maintenance through Internet-based condition monitoring with indirect sensing, novelty detection,and XML. Journal of Systems and Control Engineering,2005,219(14):283-293
[9]Rao J S, Zubair M, Rao C. Condition monitoring if power plants through the Internet. Integrated Manufacturing Systems,2003,14(6):508-517
[10]Ong K G, Xiping Y, Mukherjee N, et al. A wireless sensor network for long-term monitoring of aquatic environments:design and implementation. Sensor Letters,2004,291):48-57
[11]Sharke P. Cheaper watches:Research looks at wireless networks to lower the cost of monitoring pant machinery. Mechanical Engineering,2005,127(2):32-35
[12]胡友民,杜润生,杨叔子.智能化状态监测技术研究[J].中国机械工程,2003,14(11):946-950;
[13]吴国忠,滕俊青.设备巡检系统中数据采集软件的开发与应用[J].浙江大学报(工学版).2004,38(4):429-432
[14]严开勇,黄坤平,谢江华等.设备状态点检网络化管理系统[J].中国设备工程,2003,(10):7-9
[15]Tapan K.Saha, Prithwiraj Purkait. Investigation of an expert system for the condition assessment of transformer insulation based on dielectric response measurements [J]. IEEE Transactions on Power Deliveyr.2004,19(3):1127-1134
[16]褚福磊,卢秀文,张伟等.水泵水轮机组状态监测与故障诊断系统[J].水力发电,1999(2):31-33
[17]焦嵩鸣.人工神经网络在系统辨识中的应用与研究[D]:[硕士学位论文].保定:华北电力大学自动化系,2002:5-15
[18]张兆礼,孙圣和.粗神经网络及其在数据融合中的应用[J].控制与决策.2001,16(1):76-79
[19]张西宁.大型回转机械运行状态的智能化在线监测[J].西安交通大学学报,1999,33(7):75-78
[20]Pandey M D. Probabilistic models for condition assessment of oil and gas pipelines [J]. NTD&E international.1998,31(5):349-358
[21]忻建华,叶春,陈汉平,等.300Mw汽轮机高压缸通流部分故障的热参数模糊诊断[J].动力工程.1997,17(3):5-8
[22]马良玉,王兵树,高建强,等.大旁路布置高压给水加热器系统故障模糊知识库及其神经网络的诊断研究[J].动力工程,2002,22(1):1615-1621
[23]刘雁梅,熊诗波.轴承故障模拟台设计[J].重型机械,1999,(4):40-43
[24]陈宇晓.齿轮传动故障模拟试验台的试制[J].长沙电力学院学报(自然科学版),2003,18(1):63-67
[25]邓吟,郑翔,邱列明.故障模拟多功能振动试验台的设计[J].计测技术.2009,29(4):22-23
[26]Y. Li, S. Billington, C. Zhang, T. Kurfess, S. Danyluk and S. Liang. Adaptive Prognostics for Rolling Element Bearing Condition[J]. Mechanical Systems and Signal Processing.1999,13: 103-113
[27]C. Zhang, S.Y. Liang and J. Qiu. Bearing Failure Prognostic Model Based on Damage Mechanics and Vibration Monitoring [J]. Tribology Transactions of STLE.2001,44(4): 603-608
[28]G. J. Kacprzynski, A. Sarlashkar and M.J. Roemer. Predicting Remaining Life By Fusing the Physics of Failure Modeling with Diagnostics [J]. Journal of Metal.2004,56:29-35
[29]吴广辉,马吉胜,曹立军.基于虚拟样机的火炮故障仿真预测技术研究[J].计算机测量与控制,2007,15(9):1203-1205
[30]贾长治,王兴贵,龚烈航.基于虚拟样机技术的火炮故障仿真及应用研究[J].机械工程学报,2004,40(9):89-93
[31]杨高宏.基于虚拟样机技术的采煤机截割减速器故障仿真研究[D].太原理工大学,2009:4-6
[32]白欣,黄博,王立臣.基于虚拟样机的发动机活塞销故障诊断研究[J].汽车技术,2005,(4):21-23.
[33]Song Xiao, Bo Hu Li, Chai Xudong. Research on Key Technologies of Complex Product Virtual Prototype Lifecycle Management (CPVPLM) [J].Simulation Modeling Practice and Theory.2008,16(4):387-398.
[34]柏见涛.基于虚拟样机技术的机床进给传动系统动力学研究[D].长春:吉林大学,2007:5-15
[35]李金玉,勾志践,李媛.基于ADAMS的齿轮啮合过程中齿轮力的动态仿真[J].机械,2005,32(3):15-17.
[36]陈宗基,李伯虎,王行仁等.“仿真科学与技术”学科研究[J].系统仿真学报,2009,9(17):5266
[37]American Association for the Advancement of Science. http://www.sciencemag.org/sciext/125th/. (2005-7-1) [2009-8-20]
[38]吴重光.仿真技术[M].北京:化学工业出版社,2000:20-35.
[39]王行仁.建模与仿真技术的发展和应用[J].机械制造与自动化,2010,(01):22-27.
[40]康凤举.现代仿真技术与应用[M].北京:国防工业出版社,2001,09:15-35.
[41]Martin Gabi, Toni K lemm. Numerical and Experimental Investigations of Cross-Flow Fans [J]. Journal of Computational and Applied.2004,5(2).251-261.
[42]Juicier Fukutom, i Rei Nakamura. Performance and Internal Flow o f Cross-Flow Fan with Inlet Guide Vane[J]. JSME International Journal 2005,48 (4):763-769.
[43]Sorensen, D.N., and Sorensen, J.N. Toward Improved Rotor-Only Axial Fans-Part 1:A Numerically Efficient Aerodynamic Model for Arbitrary Vortex Flow [J], ASMEJ. Fluids Eng.,2000,122(2):318-323
[44]Outa E, Ohta Y, Kato D, et al. Two Dimensional Study on Evolution of Deep Rotating Stall under Uniform Inlet Conditions in an Axial Compressor Cascades [C]. ISABE. Florence, Italy:International Organization,1999:5-10.
[45]He L. Computational Study of Rotating-stall Inception in Axial Compressor [J]. Journal of Propulsion and Power.1997,13(1):31-38.
[46]Gourdain N, Burguburu S, Leboeuf F, et al. Numerical Simulation of Rotating Stall in a Subsonic Compressor [J]. Aerospace Science and Technology,2006,10(1):9-18.
[47]Saxer-Felici H M, Saxer A, P, Inderbitzin A, et al. Numerical and Experimental Study of Rotating Stall in an Axial Compressor Stage [J]. AIAA Journal,2000,38(7):1132-1141
[48]刘长良,刘广生.火电厂轴流风机实时仿真模型的建立和应用[J].华北电力学院学报,1993,(1):98-101
[49]马良玉,安连锁,王松岭,王兵树.大型动(静)叶调节轴流风机通用性能数学模型的建立及工程应用实践[J].动力工程,2000,20(5):900-905
[50]马良玉,安连锁.基于高精度性能模型的轴流通风机喘振故障预报方法[J].风机技术,2003(4):52-56.
[51]马良玉,段巍,安连锁.大型动(静)叶调节轴流通风机性能在线监测的一种新方法[J].风机技术,2000(5):42-46
[52]马良玉,段巍,王兵树,安连锁,王松岭.轴流风机通用数学模型[J].热能动力工程,2001,(3):195-198.
[53]马良玉,王兵树.动(静)页调节轴流风机动态实时仿真模型[J].华北电力大学学报,2000, 27(3):11-16
[54]马仪炜.基于神经网络的轴流风机建模方法研究[D].华北电力大学,2008:5-15
[55]侯军虎,王松岭,安连锁,王大勇,丁千玲.基于神经网络的通风机性能监测组合建模[J].风机技术,2002,(03):29-32.
[56]尤丽静,陈在平.基于自组织神经网络的轴流风机不对中故障诊断研究[J].天津理工大学学报,2010,(01):68-70.
[57]舒服华.基于粗糙集与人工神经网络的风机故障诊断[J].风机技术,2007,(02):81-84.
[58]袁莉.对旋式轴流通风机的仿真[D].西安科技大学硕士论文,2004:5-15
[59]胡俊伟,丁国良,赵立等.贯流风机流场模拟与性能分析[J].机械工程学报,2004,40(4):62-66.
[60]毛君,张莉蓉,丁飞,李蕾.基于FLUENT的叶轮机械内部流场的模拟研究[J].风机技术.2007,5:10
[61]郑小波,罗兴,邬海军.基于CFD分析的轴流式转轮叶片刚强度分析[J].水力发电学报.2006,10(5):121-123
[62]叶学明,李俊,王松岭等.带后导叶轴流式通风机内流特征的数值模拟[J].热能动力工程,2009,24(2):163-166.
[63]高立江.地铁用轴流风机的数值模拟及研究[D].天津大学,2004,I1:10-16.
[64]杨东旭.地铁空调通风节能研究[D].天津大学,2003,12:3-10.
[65]田铖.地铁用轴流风机的CFD模拟及研究[D].天津大学,2003,12:6-14.
[66]伍晨.地铁用轴流风机的CFD模拟[D].天津大学.2007,6:4-19.
[67]杨滁光.基于CFD的空调用轴流风机性能预测及实验对比[J].流体机械.2009(12):5-8
[68]李杨,欧阳华,杜朝辉.低压轴流风机周向弯曲叶片顶部间隙流动的数值模拟[J].动力工程,2006,26(5):707-711.
[69]李杨,欧阳华,杜朝辉.周向弯曲低压轴流风机叶顶泄漏流动数值研究[J].工程热物理学报,2005,26(2):240-242
[70]李杨,,欧阳华,杜朝辉.相同工况下叶片的不同周向弯曲对低压轴流风扇性能影响的对比分析[J].上海交通大学学报,2006,40(12):2101-2105
[71]田斌,席德科,徐燕飞.轴流通风机内部流场数值研究[J].风机技术,2004(3):10-14.
[72]蒋康涛.低速轴流压气机旋转失速的数值模拟研究[D].中国科学院研究生院.2004,6:5-9.
[73]张兴国,刘锋,张陈安.基于CFD技术的叶片颤振分析[J].航空计算技术.2009,7(39):75-78
[74]赵决正,罗雄麟,崔娟娟.基于二维数值模拟的轴流压气机旋转失速研究[J].化工自动化及仪表.2011,12(39):198-202
[75]Sadeghi M, Liu F. Coupled Fluid Structure Simulation for Turbo machinery Blade Rows[R]. AIAA2005-18,2005.
[76]张瑞琴,翁建生.基于流固耦合的叶片颤振分析[J].计算机仿真.2011,3(28):48-50
[77]王明奎,李文英.矿用对旋轴流风机失速与喘振下的数值模拟[J].机械工程与自动化.2006,12(6):70-73
[78]张永超,张永建,贝广霞,李学臣.轴流式通风机动叶振动的数值研究[J].矿山机械.2008,5(36):22-25
[79]毛军,薛琳,王丹,李晓.关于地铁轴流风机叶片发生断裂和出现裂纹的分析[J].中国安全科学学报.2003,5(13):75-78
[80]刘荣娥,尹忠俊,陈兵.基于虚拟样机的风机不平衡故障仿真研究fJ].煤矿机械,2007,28(11):178-180
[81]黄璨.冶金风机叶片磨损故障仿真研究[J].科技创新导报.2010(22):59
[82]李景银,田华,牛子宁.叶片开缝的离心风机流场研究[J].工程热物理学报.2009,12(30):2029-2030
[83]John D. Anderson著.姚朝晖,周强编译.计算流体力学入门[M].2010:165-185
[84]昌泽舟等.轴流式通风机实用手册[M].2005,3:80-85.
[85]蔡增基,龙天渝.流体力学泵与风机[M].2009:170-190
[86]张学昌.逆向建模技术与产品创新设计[M].2009:15-30.
[87]金涛,童水生.逆向工程技术[M].北京:机械工业出版社,2003:22-35.
[88]许智钦,孙长库.3D逆向工程技术[M].北京:中国计量出版社,2002:65-80.
[89]曹晓兴,刘德平.逆向工程软件的选取与模型重构技术[J].工具技术.2012(46):36-38
[90]刘品德,余世浩,叶建红.Pro/E软件的反求工程技术与应用[J].电气技术与自动化.2005,4(2):72-74
[91]Kamran M, Mohammad H S, Amir A. Reverse engineered of turbine blades based on design intent [J].International Journal of Advanced Manufacturing Technology.2007 (32):1009-1020.
[92]商景泰.通风机实用技术手册[M].北京:机械工业出版社,2005:161-165.
[93]纪小刚.增压器叶轮逆向工程中的关键技术研究[D].南京:南京理工大学博士学位论文,2006:10-18
[94]吴秉礼.反求工程技术在HK型轴流通风机叶片上的应用[J].流体机械,1998,2(26):16-19.
[95]金永平,刘德顺,文泽军,岳文辉.矿井轴流通风机叶片三维几何模型反求重构[J].现代制造工程.2011,11:24-27
[96]邓杰,陈锐.水轮机叶片测绘数据的三维CAD绘型[J].水利水电技术2009,11(40):103-106
[97]Lee K H, Woo H, Suk T. Date reduction methods for reverse engineering [J]. International Journal of Advanced Manufacturing Technology,2002(10):735-743.
[98]罗大兵,高明,王培俊.逆向工程中数字化测量与点云数据处理[J].机械设计与制造,2005,9(9):56-58.
[99]刘晓宇Pro/ENGINEER野火版逆向工程设计完全解析[M].中国铁道出版社.2010:60-85
[100]李卫国.逆向工程中的曲面重构技术研究及基于Web的应用系统开发[D].南京航空航天大学.2001:6-13
[101]王福军.计算流体动力学分析-CFD软件原理与应用[M].清华大学出版社.2004.9:2-7
[102]韩占忠FLUENT流体工程仿真与计算实例与应用[M].北京理工大学出版社.2004,6:21-22
[103]李进良,李成曦,胡仁喜等.精通FLUENT6.3流场分析[M].化学工业出版社.2009,9:27-30
[1041 李鹏飞,徐敏义,王飞飞.精通CFD工程仿真与案例实战[M].2011,11:18-22
[105]冷军发,荆双喜,李臻.通风机故障诊断的研究[J].煤矿机电.2003.2:25-27
[106]川电.为电站风机振动故障把脉会诊[N].中国电力报.2004-07-15
[107]雷剑宇,廖明夫,杨伸记.预测风机喘振边界的新方法[J].风机技术.2005(4):52-57
[108]杨林.轴流式通风机喘振预警方法的研究[J].矿业安全与环保.2008,04,10:39-41
[2]张惠忠.我国矿井主扇风机发展概况评述[J].煤矿安全,1994,(06):28
[3]赵涛,吕素荣,戈猛等.基于集成战略的工业维护管理理论体系的构建[J].机械设计,2003,20(9):1-3
[4]Moubray J. Reliability-centred maintenance [M]. New York:Industrial press.2001:19-25
[5]李德刚.设备预知维护的体系理论及支撑技术研究[D].湖南大学博士论文,2006:13-14
[6]李葆文.简明现代设备管理手册[M].北京:机械工业出版社,2004:22-35
[7]伍星,陈进,李如强等.设备远程监测与诊断系统体系结构的研究[J].计算机工程与应用,2005,41(9):192-196.
[8]Zorriassatine F, AshrafB, Notini L, et al. Smarter maintenance through Internet-based condition monitoring with indirect sensing, novelty detection,and XML. Journal of Systems and Control Engineering,2005,219(14):283-293
[9]Rao J S, Zubair M, Rao C. Condition monitoring if power plants through the Internet. Integrated Manufacturing Systems,2003,14(6):508-517
[10]Ong K G, Xiping Y, Mukherjee N, et al. A wireless sensor network for long-term monitoring of aquatic environments:design and implementation. Sensor Letters,2004,291):48-57
[11]Sharke P. Cheaper watches:Research looks at wireless networks to lower the cost of monitoring pant machinery. Mechanical Engineering,2005,127(2):32-35
[12]胡友民,杜润生,杨叔子.智能化状态监测技术研究[J].中国机械工程,2003,14(11):946-950;
[13]吴国忠,滕俊青.设备巡检系统中数据采集软件的开发与应用[J].浙江大学报(工学版).2004,38(4):429-432
[14]严开勇,黄坤平,谢江华等.设备状态点检网络化管理系统[J].中国设备工程,2003,(10):7-9
[15]Tapan K.Saha, Prithwiraj Purkait. Investigation of an expert system for the condition assessment of transformer insulation based on dielectric response measurements [J]. IEEE Transactions on Power Deliveyr.2004,19(3):1127-1134
[16]褚福磊,卢秀文,张伟等.水泵水轮机组状态监测与故障诊断系统[J].水力发电,1999(2):31-33
[17]焦嵩鸣.人工神经网络在系统辨识中的应用与研究[D]:[硕士学位论文].保定:华北电力大学自动化系,2002:5-15
[18]张兆礼,孙圣和.粗神经网络及其在数据融合中的应用[J].控制与决策.2001,16(1):76-79
[19]张西宁.大型回转机械运行状态的智能化在线监测[J].西安交通大学学报,1999,33(7):75-78
[20]Pandey M D. Probabilistic models for condition assessment of oil and gas pipelines [J]. NTD&E international.1998,31(5):349-358
[21]忻建华,叶春,陈汉平,等.300Mw汽轮机高压缸通流部分故障的热参数模糊诊断[J].动力工程.1997,17(3):5-8
[22]马良玉,王兵树,高建强,等.大旁路布置高压给水加热器系统故障模糊知识库及其神经网络的诊断研究[J].动力工程,2002,22(1):1615-1621
[23]刘雁梅,熊诗波.轴承故障模拟台设计[J].重型机械,1999,(4):40-43
[24]陈宇晓.齿轮传动故障模拟试验台的试制[J].长沙电力学院学报(自然科学版),2003,18(1):63-67
[25]邓吟,郑翔,邱列明.故障模拟多功能振动试验台的设计[J].计测技术.2009,29(4):22-23
[26]Y. Li, S. Billington, C. Zhang, T. Kurfess, S. Danyluk and S. Liang. Adaptive Prognostics for Rolling Element Bearing Condition[J]. Mechanical Systems and Signal Processing.1999,13: 103-113
[27]C. Zhang, S.Y. Liang and J. Qiu. Bearing Failure Prognostic Model Based on Damage Mechanics and Vibration Monitoring [J]. Tribology Transactions of STLE.2001,44(4): 603-608
[28]G. J. Kacprzynski, A. Sarlashkar and M.J. Roemer. Predicting Remaining Life By Fusing the Physics of Failure Modeling with Diagnostics [J]. Journal of Metal.2004,56:29-35
[29]吴广辉,马吉胜,曹立军.基于虚拟样机的火炮故障仿真预测技术研究[J].计算机测量与控制,2007,15(9):1203-1205
[30]贾长治,王兴贵,龚烈航.基于虚拟样机技术的火炮故障仿真及应用研究[J].机械工程学报,2004,40(9):89-93
[31]杨高宏.基于虚拟样机技术的采煤机截割减速器故障仿真研究[D].太原理工大学,2009:4-6
[32]白欣,黄博,王立臣.基于虚拟样机的发动机活塞销故障诊断研究[J].汽车技术,2005,(4):21-23.
[33]Song Xiao, Bo Hu Li, Chai Xudong. Research on Key Technologies of Complex Product Virtual Prototype Lifecycle Management (CPVPLM) [J].Simulation Modeling Practice and Theory.2008,16(4):387-398.
[34]柏见涛.基于虚拟样机技术的机床进给传动系统动力学研究[D].长春:吉林大学,2007:5-15
[35]李金玉,勾志践,李媛.基于ADAMS的齿轮啮合过程中齿轮力的动态仿真[J].机械,2005,32(3):15-17.
[36]陈宗基,李伯虎,王行仁等.“仿真科学与技术”学科研究[J].系统仿真学报,2009,9(17):5266
[37]American Association for the Advancement of Science. http://www.sciencemag.org/sciext/125th/. (2005-7-1) [2009-8-20]
[38]吴重光.仿真技术[M].北京:化学工业出版社,2000:20-35.
[39]王行仁.建模与仿真技术的发展和应用[J].机械制造与自动化,2010,(01):22-27.
[40]康凤举.现代仿真技术与应用[M].北京:国防工业出版社,2001,09:15-35.
[41]Martin Gabi, Toni K lemm. Numerical and Experimental Investigations of Cross-Flow Fans [J]. Journal of Computational and Applied.2004,5(2).251-261.
[42]Juicier Fukutom, i Rei Nakamura. Performance and Internal Flow o f Cross-Flow Fan with Inlet Guide Vane[J]. JSME International Journal 2005,48 (4):763-769.
[43]Sorensen, D.N., and Sorensen, J.N. Toward Improved Rotor-Only Axial Fans-Part 1:A Numerically Efficient Aerodynamic Model for Arbitrary Vortex Flow [J], ASMEJ. Fluids Eng.,2000,122(2):318-323
[44]Outa E, Ohta Y, Kato D, et al. Two Dimensional Study on Evolution of Deep Rotating Stall under Uniform Inlet Conditions in an Axial Compressor Cascades [C]. ISABE. Florence, Italy:International Organization,1999:5-10.
[45]He L. Computational Study of Rotating-stall Inception in Axial Compressor [J]. Journal of Propulsion and Power.1997,13(1):31-38.
[46]Gourdain N, Burguburu S, Leboeuf F, et al. Numerical Simulation of Rotating Stall in a Subsonic Compressor [J]. Aerospace Science and Technology,2006,10(1):9-18.
[47]Saxer-Felici H M, Saxer A, P, Inderbitzin A, et al. Numerical and Experimental Study of Rotating Stall in an Axial Compressor Stage [J]. AIAA Journal,2000,38(7):1132-1141
[48]刘长良,刘广生.火电厂轴流风机实时仿真模型的建立和应用[J].华北电力学院学报,1993,(1):98-101
[49]马良玉,安连锁,王松岭,王兵树.大型动(静)叶调节轴流风机通用性能数学模型的建立及工程应用实践[J].动力工程,2000,20(5):900-905
[50]马良玉,安连锁.基于高精度性能模型的轴流通风机喘振故障预报方法[J].风机技术,2003(4):52-56.
[51]马良玉,段巍,安连锁.大型动(静)叶调节轴流通风机性能在线监测的一种新方法[J].风机技术,2000(5):42-46
[52]马良玉,段巍,王兵树,安连锁,王松岭.轴流风机通用数学模型[J].热能动力工程,2001,(3):195-198.
[53]马良玉,王兵树.动(静)页调节轴流风机动态实时仿真模型[J].华北电力大学学报,2000, 27(3):11-16
[54]马仪炜.基于神经网络的轴流风机建模方法研究[D].华北电力大学,2008:5-15
[55]侯军虎,王松岭,安连锁,王大勇,丁千玲.基于神经网络的通风机性能监测组合建模[J].风机技术,2002,(03):29-32.
[56]尤丽静,陈在平.基于自组织神经网络的轴流风机不对中故障诊断研究[J].天津理工大学学报,2010,(01):68-70.
[57]舒服华.基于粗糙集与人工神经网络的风机故障诊断[J].风机技术,2007,(02):81-84.
[58]袁莉.对旋式轴流通风机的仿真[D].西安科技大学硕士论文,2004:5-15
[59]胡俊伟,丁国良,赵立等.贯流风机流场模拟与性能分析[J].机械工程学报,2004,40(4):62-66.
[60]毛君,张莉蓉,丁飞,李蕾.基于FLUENT的叶轮机械内部流场的模拟研究[J].风机技术.2007,5:10
[61]郑小波,罗兴,邬海军.基于CFD分析的轴流式转轮叶片刚强度分析[J].水力发电学报.2006,10(5):121-123
[62]叶学明,李俊,王松岭等.带后导叶轴流式通风机内流特征的数值模拟[J].热能动力工程,2009,24(2):163-166.
[63]高立江.地铁用轴流风机的数值模拟及研究[D].天津大学,2004,I1:10-16.
[64]杨东旭.地铁空调通风节能研究[D].天津大学,2003,12:3-10.
[65]田铖.地铁用轴流风机的CFD模拟及研究[D].天津大学,2003,12:6-14.
[66]伍晨.地铁用轴流风机的CFD模拟[D].天津大学.2007,6:4-19.
[67]杨滁光.基于CFD的空调用轴流风机性能预测及实验对比[J].流体机械.2009(12):5-8
[68]李杨,欧阳华,杜朝辉.低压轴流风机周向弯曲叶片顶部间隙流动的数值模拟[J].动力工程,2006,26(5):707-711.
[69]李杨,欧阳华,杜朝辉.周向弯曲低压轴流风机叶顶泄漏流动数值研究[J].工程热物理学报,2005,26(2):240-242
[70]李杨,,欧阳华,杜朝辉.相同工况下叶片的不同周向弯曲对低压轴流风扇性能影响的对比分析[J].上海交通大学学报,2006,40(12):2101-2105
[71]田斌,席德科,徐燕飞.轴流通风机内部流场数值研究[J].风机技术,2004(3):10-14.
[72]蒋康涛.低速轴流压气机旋转失速的数值模拟研究[D].中国科学院研究生院.2004,6:5-9.
[73]张兴国,刘锋,张陈安.基于CFD技术的叶片颤振分析[J].航空计算技术.2009,7(39):75-78
[74]赵决正,罗雄麟,崔娟娟.基于二维数值模拟的轴流压气机旋转失速研究[J].化工自动化及仪表.2011,12(39):198-202
[75]Sadeghi M, Liu F. Coupled Fluid Structure Simulation for Turbo machinery Blade Rows[R]. AIAA2005-18,2005.
[76]张瑞琴,翁建生.基于流固耦合的叶片颤振分析[J].计算机仿真.2011,3(28):48-50
[77]王明奎,李文英.矿用对旋轴流风机失速与喘振下的数值模拟[J].机械工程与自动化.2006,12(6):70-73
[78]张永超,张永建,贝广霞,李学臣.轴流式通风机动叶振动的数值研究[J].矿山机械.2008,5(36):22-25
[79]毛军,薛琳,王丹,李晓.关于地铁轴流风机叶片发生断裂和出现裂纹的分析[J].中国安全科学学报.2003,5(13):75-78
[80]刘荣娥,尹忠俊,陈兵.基于虚拟样机的风机不平衡故障仿真研究fJ].煤矿机械,2007,28(11):178-180
[81]黄璨.冶金风机叶片磨损故障仿真研究[J].科技创新导报.2010(22):59
[82]李景银,田华,牛子宁.叶片开缝的离心风机流场研究[J].工程热物理学报.2009,12(30):2029-2030
[83]John D. Anderson著.姚朝晖,周强编译.计算流体力学入门[M].2010:165-185
[84]昌泽舟等.轴流式通风机实用手册[M].2005,3:80-85.
[85]蔡增基,龙天渝.流体力学泵与风机[M].2009:170-190
[86]张学昌.逆向建模技术与产品创新设计[M].2009:15-30.
[87]金涛,童水生.逆向工程技术[M].北京:机械工业出版社,2003:22-35.
[88]许智钦,孙长库.3D逆向工程技术[M].北京:中国计量出版社,2002:65-80.
[89]曹晓兴,刘德平.逆向工程软件的选取与模型重构技术[J].工具技术.2012(46):36-38
[90]刘品德,余世浩,叶建红.Pro/E软件的反求工程技术与应用[J].电气技术与自动化.2005,4(2):72-74
[91]Kamran M, Mohammad H S, Amir A. Reverse engineered of turbine blades based on design intent [J].International Journal of Advanced Manufacturing Technology.2007 (32):1009-1020.
[92]商景泰.通风机实用技术手册[M].北京:机械工业出版社,2005:161-165.
[93]纪小刚.增压器叶轮逆向工程中的关键技术研究[D].南京:南京理工大学博士学位论文,2006:10-18
[94]吴秉礼.反求工程技术在HK型轴流通风机叶片上的应用[J].流体机械,1998,2(26):16-19.
[95]金永平,刘德顺,文泽军,岳文辉.矿井轴流通风机叶片三维几何模型反求重构[J].现代制造工程.2011,11:24-27
[96]邓杰,陈锐.水轮机叶片测绘数据的三维CAD绘型[J].水利水电技术2009,11(40):103-106
[97]Lee K H, Woo H, Suk T. Date reduction methods for reverse engineering [J]. International Journal of Advanced Manufacturing Technology,2002(10):735-743.
[98]罗大兵,高明,王培俊.逆向工程中数字化测量与点云数据处理[J].机械设计与制造,2005,9(9):56-58.
[99]刘晓宇Pro/ENGINEER野火版逆向工程设计完全解析[M].中国铁道出版社.2010:60-85
[100]李卫国.逆向工程中的曲面重构技术研究及基于Web的应用系统开发[D].南京航空航天大学.2001:6-13
[101]王福军.计算流体动力学分析-CFD软件原理与应用[M].清华大学出版社.2004.9:2-7
[102]韩占忠FLUENT流体工程仿真与计算实例与应用[M].北京理工大学出版社.2004,6:21-22
[103]李进良,李成曦,胡仁喜等.精通FLUENT6.3流场分析[M].化学工业出版社.2009,9:27-30
[1041 李鹏飞,徐敏义,王飞飞.精通CFD工程仿真与案例实战[M].2011,11:18-22
[105]冷军发,荆双喜,李臻.通风机故障诊断的研究[J].煤矿机电.2003.2:25-27
[106]川电.为电站风机振动故障把脉会诊[N].中国电力报.2004-07-15
[107]雷剑宇,廖明夫,杨伸记.预测风机喘振边界的新方法[J].风机技术.2005(4):52-57
[108]杨林.轴流式通风机喘振预警方法的研究[J].矿业安全与环保.2008,04,10:39-41