多功能逆变电源的仿真研究
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摘要
本文首先论述了仿真理论在弧焊逆变电源中的应用及其发展趋势,以及仿真时应该注意的一些问题。介绍了常用的一些仿真软件,如Pspice,Saber和MATLAB,综合三种仿真软件的特点和适用范围,选择了MATLAB对多功能逆变电源系统进行仿真。
对多功能逆变电源的工作过程进行了分析,设计了主电路结构,并对电路元件参数进行计算,在此基础上建立了系统的仿真模型,并对外特性进行了仿真;推导了控制电路的传递函数,并进行了稳定性分析。其次,对直流TIG焊、直流脉冲TIG焊、对称的交流方波TIG焊和变极性TIG焊进行了仿真试验。最后,用Tektronix数字存储示波器对多功能逆变电源的各部分波形进行了测试,用静负载测定了电源外特性曲线,与仿真结果进行对比,二者非常相似和接近,验证了所设计的电路参数的准确性,达到了仿真的预期效果。
另外,针对目前硬开关电源的不足(功率开关器件在开、关瞬间承受大的电流应力和电压应力,其开通和关断过程损耗较大),介绍了全桥相移零电压开关变换器(FB-ZVS-PWM)的工作原理,并进行了仿真试验,设计出了较优的谐振电感、电容参数,缩短了后续的软开关电源系统的设计周期。
Firstly, the application and development trend of simulation theory in arc welding inverter power source is expounded, and some questions which should be paid attention to are discussed. Some common simulated software is introduced, such as Pspice, Saber and MATLAB. Taking into account the characteristic and appropriate range of three simulated software, MATLAB is selected to simulate multi-function inverter power source.
The work process of Multi-function inverter power source is analyzed, configuration of the main circuit is designed, and parameters of the circuit component are calculated. Then the simulation model of the system is developed on the basis of that, and the U-I static characteristic is simulated; The transfer function of the control circuit is educed, and the stability of system is analyzed. Second, DC TIG welding, DC pulse TIG welding, AC square-wave TIG welding and variable polarity AC TIG welding are simulated. At last, waveform of multi-function inverter power source is tested using Tektronix data storage oscillograph, and U-I static characteristic curve is measured on static load condition, afterwards, contrasting the former with the result of the simulation, they are very resembled and closed. And the veracity of designed parameters is validated, and expected purpose is obtained.
In addition, aiming at the shortage of the hard-switching power source (the power switching endures circuit stress and voltage stress at the moment of turning on and off, and switching process has great waste), theory of the full bridge phase shifting zero voltage switching inverter (FB-ZVS-PWM) is introduced. Based on MATLAB, the optimal resonant inductance and capacitance parameters are schemed out, and design cycle of soft-switching power source is shorten.
对多功能逆变电源的工作过程进行了分析,设计了主电路结构,并对电路元件参数进行计算,在此基础上建立了系统的仿真模型,并对外特性进行了仿真;推导了控制电路的传递函数,并进行了稳定性分析。其次,对直流TIG焊、直流脉冲TIG焊、对称的交流方波TIG焊和变极性TIG焊进行了仿真试验。最后,用Tektronix数字存储示波器对多功能逆变电源的各部分波形进行了测试,用静负载测定了电源外特性曲线,与仿真结果进行对比,二者非常相似和接近,验证了所设计的电路参数的准确性,达到了仿真的预期效果。
另外,针对目前硬开关电源的不足(功率开关器件在开、关瞬间承受大的电流应力和电压应力,其开通和关断过程损耗较大),介绍了全桥相移零电压开关变换器(FB-ZVS-PWM)的工作原理,并进行了仿真试验,设计出了较优的谐振电感、电容参数,缩短了后续的软开关电源系统的设计周期。
Firstly, the application and development trend of simulation theory in arc welding inverter power source is expounded, and some questions which should be paid attention to are discussed. Some common simulated software is introduced, such as Pspice, Saber and MATLAB. Taking into account the characteristic and appropriate range of three simulated software, MATLAB is selected to simulate multi-function inverter power source.
The work process of Multi-function inverter power source is analyzed, configuration of the main circuit is designed, and parameters of the circuit component are calculated. Then the simulation model of the system is developed on the basis of that, and the U-I static characteristic is simulated; The transfer function of the control circuit is educed, and the stability of system is analyzed. Second, DC TIG welding, DC pulse TIG welding, AC square-wave TIG welding and variable polarity AC TIG welding are simulated. At last, waveform of multi-function inverter power source is tested using Tektronix data storage oscillograph, and U-I static characteristic curve is measured on static load condition, afterwards, contrasting the former with the result of the simulation, they are very resembled and closed. And the veracity of designed parameters is validated, and expected purpose is obtained.
In addition, aiming at the shortage of the hard-switching power source (the power switching endures circuit stress and voltage stress at the moment of turning on and off, and switching process has great waste), theory of the full bridge phase shifting zero voltage switching inverter (FB-ZVS-PWM) is introduced. Based on MATLAB, the optimal resonant inductance and capacitance parameters are schemed out, and design cycle of soft-switching power source is shorten.
引文
[1] 任平平,王清,吴林,计算机仿真技术在逆变焊接电源中的应用,焊接,2002,(5):6~9。
[2] R.D. Middlebrook, S. CUK, A General Unified Approach to Modeling Switching Converter Power Stages, Record of PESC' 1976:1834。
[3] Vatche Vorperian, Simplified analysis of PWM converters using model of PWM switch , IEEE Transacions on Aerospace and Electronic Systems, 1990, 26(3):490~505。
[4] R. Brown, R. D. Middlebrook, Sampled-datamodeling of switching regulators, Record of PESC' 1981:384~369。
[5] 华伟,高频逆变焊机的5种PWM恒流反馈控制模式研究,电焊机,2001,31(3):37~40。
[6] Anunciada V, Silva M, New Constant Frequency Current Mode Control for power converter, Stable for all values of duty ratio, and usable in all four quadrants[J] , IEEE Transaction on Industrial Electronics, 1990, 37(4)。
[7] 林波涛,丘水生,PWM开关变换器的符号分析法.电子学保,1996,24(9):83~87。
[8] 郭大勇等,相移式准谐振弧焊电源的建模与分析,焊接学报,1998,19(8):171~175
[9] 郭丽萍,苏向丰,一种弧焊逆变电源的小信号模型,电焊机,2003,33(2):22~25。
[10] Lauritzen, Peter O, A simple power diode model with reverse recovery, IEEE Transactions on Power Electronics, 1991, 6(2): 188~191。
[11] Ma, Cliff L, A simple power diode model with forward and reverse recovery, IEEE Transactions on Power Electronics, 1993, 8(4): 342~345。
[12] Ma, Cliff L, Modeling of power diodes with the lumped-charge modeling technique, IEEE Transactions on Power Electronics, 1997, 12(3): 398~405。
[13] Strollo, Antonio G, New SPICE subcircuit model of power P-I-N diode, IEEE Transactins on Power Electronics, 1994, 9(3): 553~559。
[14] Hefner, Allen R, An improved understanding for the transient operation of the power insulated gate bipolar transistor(IGBT), IEEE Transactions on Power Electronics, 1990, 5(4): 459~468。
[15] Hefner, Allen R, Jr Diebolt, Daniel M, An experimentally verified IGBT model implemented in the Saber circuit simulator, IEEE Transactions on Power
Electronics, 1994, 9(5): 532~559。
[16] Hefner, Allen R, Modeling buffer layer IGBT' s for circuit simulation, IEEE Transactions on Power Electronics, 1994, 10(2): 111~123。
[17] Mitter, Chang Su , Hefnerm, Allen R, Insulated Gate Bipolar Transistor(IGBT)modeling using IG-Spice, IEEE Transactions on Industry Applications, 1994, 30(1): 1~33。
[18] F.J. Mihalic, K. Krischan, K.M. Rentmeister, IGBT SPICE model, IEEE Transactions on Industrial Electronics, 1995, 42(1): 98~105。
[19] A.F. Petrie, H. Charles, A SPICE model for IGBT' S, .APEC' 95: 147~152。
[20] 姚立真,通用电路模拟技术及软件应用SPICE和PSPICE,电子工业出版社,1994。
[21] D.C. Jiles, J.B. Thoelke , Numerical determination of hysteresis parameters for hysteresis, IEEE Transactions on Magnetics, 1992, 28(1): 27~35。
[22] L. G. Meares, C.E. Hymowitz, Improved spice model simulates transformer's physical processes, EDN 1993, 38(17): 105~113。
[23] Dauhajre, R. D. Middlebrook, Modeling and Estimation of Leakage Phenomena in Magnetic Circuits, Record of PESC' 1986: 213~226。
[24] L.K. Wong, Frank H. Leung, A Simple Large-Signal Nonlinear Modeling Approach for Fast Simulation of Zero-Current-Switch Quasi-Resonant Converters, IEEE Transactions on Power Electronics, 1997, 12(3): 437~442。
[25] 盖志武,彭涌涛等,PWM弧焊逆变电源的MATLAB仿真研究,电焊机,2003,33(1):25~27。
[26] 王伟明,刘嘉,尹树言,基于MATLAB/SIMULINK的数字控制脉冲焊的建模和仿真研究,汽车焊接国际焊接会议论文集,2003:104~108。
[27] 丘联奎,多功能逆变焊机的研制,甘肃工业大学硕士论文,2002。
[28] 孙涵芳等,MCS-51/96系列单片原理及应用,北京:北京航空航天大学出版社,1988。
[29] 潘永雄,刘殊,单片及原理与应用,西安:西安电子科技大学出版社,2000。
[30] 陈嘉庆等,多国单片及实用技术,北京:微电脑信息部,1992。
[31] 赵家瑞,逆变焊接与切割电源,北京:机械工业出版社,1995。
[32] 黄文梅,杨勇,系统仿真分析与设计,长沙:国防科技大学出版社,2001。
[33] 张学红,TIG焊电源控制系统仿真,甘肃工业大学硕士开题报告,2003。
[34] 姚俊,马松辉,SIMULINK建模与仿真,西安:西安电子科技大学出版社,2002。
[35] 戴珂,段善旭,三相电压型整流器/逆变器的功能建模仿真方法,电力电子技术,2002,36(5):60~64。
[36] 李爱文,现代通信基础开关电源的原理和设计,北京:科学出版社,2001。
[37] 鄢景华,自动控制原理,哈尔滨:哈尔滨工业大学出版社,1996。
[38] 陈炳森,计算机辅助焊接技术,北京:机械工业出版社,1999。
[39] 潘际銮,现代弧焊控制,北京:机械工业出版社,2000。
[40] 黄石生,新型弧焊电源及其智能控制,北京:机械工业出版社,2000。
[41] 谢剑英,贾青,微型计算机控制技术,北京:国防工业出版社,2001,9。
[42] 郑大钟,线性系统理论,北京:清华大学出版社,1990,3。
[43] 刘金琨,先进PID控制及其MATLAB仿真,北京:电子工业出版社,2003,1。
[44] MATLAB6.5在线帮助。
[45] 王永军,李景华,数字逻辑与数字系统,北京:电子工业出版社,2002,2。
[46] 韦鲲,微机控制IGBT逆变弧焊电源的研究,甘肃工业大学硕士论文,1998。
[47] 历雅萍,于淑红,数字逻辑电路的Simulink仿真,测控技术,1999,18(2):48~50。
[48] 姜焕中,电弧焊及电渣焊(第二版),北京:机械工业出版社,1980,2。
[49] 杜贵平,黄石生,相移式PWM全桥逆变器软开关技术研究[J],电气自动化,2002,2:15~19。
[50] 尹树言,黄鹏飞,黄勇,软开关弧焊逆变电源的工作机理研究,北京工业大学学报,1998,24(3):55~60。
[51] 陈树君,殷树言,冯雷,软开关弧焊逆变电源的计算机仿真与实验研究,焊接技术,1999,12:26~29(增刊)。
[52] 冯勇,叶斌,IGBT逆变器吸收电路的仿真分析与参数选择,电力机车技术,1999,2:12~14。
[53] www.2lic.com.cn,uc3879芯片资料。
[54] 龙光华,王克争,专用相移芯片在全桥相移零压开关逆变焊机设计中的应用,电焊机,2002,32(5):12~13。
[55] 史悦玲,李时杰,贾俊林,基于UC3879的移相全桥ZVS-PWM逆变器的研究,自动化与仪表,2002(6):21~23。
[2] R.D. Middlebrook, S. CUK, A General Unified Approach to Modeling Switching Converter Power Stages, Record of PESC' 1976:1834。
[3] Vatche Vorperian, Simplified analysis of PWM converters using model of PWM switch , IEEE Transacions on Aerospace and Electronic Systems, 1990, 26(3):490~505。
[4] R. Brown, R. D. Middlebrook, Sampled-datamodeling of switching regulators, Record of PESC' 1981:384~369。
[5] 华伟,高频逆变焊机的5种PWM恒流反馈控制模式研究,电焊机,2001,31(3):37~40。
[6] Anunciada V, Silva M, New Constant Frequency Current Mode Control for power converter, Stable for all values of duty ratio, and usable in all four quadrants[J] , IEEE Transaction on Industrial Electronics, 1990, 37(4)。
[7] 林波涛,丘水生,PWM开关变换器的符号分析法.电子学保,1996,24(9):83~87。
[8] 郭大勇等,相移式准谐振弧焊电源的建模与分析,焊接学报,1998,19(8):171~175
[9] 郭丽萍,苏向丰,一种弧焊逆变电源的小信号模型,电焊机,2003,33(2):22~25。
[10] Lauritzen, Peter O, A simple power diode model with reverse recovery, IEEE Transactions on Power Electronics, 1991, 6(2): 188~191。
[11] Ma, Cliff L, A simple power diode model with forward and reverse recovery, IEEE Transactions on Power Electronics, 1993, 8(4): 342~345。
[12] Ma, Cliff L, Modeling of power diodes with the lumped-charge modeling technique, IEEE Transactions on Power Electronics, 1997, 12(3): 398~405。
[13] Strollo, Antonio G, New SPICE subcircuit model of power P-I-N diode, IEEE Transactins on Power Electronics, 1994, 9(3): 553~559。
[14] Hefner, Allen R, An improved understanding for the transient operation of the power insulated gate bipolar transistor(IGBT), IEEE Transactions on Power Electronics, 1990, 5(4): 459~468。
[15] Hefner, Allen R, Jr Diebolt, Daniel M, An experimentally verified IGBT model implemented in the Saber circuit simulator, IEEE Transactions on Power
Electronics, 1994, 9(5): 532~559。
[16] Hefner, Allen R, Modeling buffer layer IGBT' s for circuit simulation, IEEE Transactions on Power Electronics, 1994, 10(2): 111~123。
[17] Mitter, Chang Su , Hefnerm, Allen R, Insulated Gate Bipolar Transistor(IGBT)modeling using IG-Spice, IEEE Transactions on Industry Applications, 1994, 30(1): 1~33。
[18] F.J. Mihalic, K. Krischan, K.M. Rentmeister, IGBT SPICE model, IEEE Transactions on Industrial Electronics, 1995, 42(1): 98~105。
[19] A.F. Petrie, H. Charles, A SPICE model for IGBT' S, .APEC' 95: 147~152。
[20] 姚立真,通用电路模拟技术及软件应用SPICE和PSPICE,电子工业出版社,1994。
[21] D.C. Jiles, J.B. Thoelke , Numerical determination of hysteresis parameters for hysteresis, IEEE Transactions on Magnetics, 1992, 28(1): 27~35。
[22] L. G. Meares, C.E. Hymowitz, Improved spice model simulates transformer's physical processes, EDN 1993, 38(17): 105~113。
[23] Dauhajre, R. D. Middlebrook, Modeling and Estimation of Leakage Phenomena in Magnetic Circuits, Record of PESC' 1986: 213~226。
[24] L.K. Wong, Frank H. Leung, A Simple Large-Signal Nonlinear Modeling Approach for Fast Simulation of Zero-Current-Switch Quasi-Resonant Converters, IEEE Transactions on Power Electronics, 1997, 12(3): 437~442。
[25] 盖志武,彭涌涛等,PWM弧焊逆变电源的MATLAB仿真研究,电焊机,2003,33(1):25~27。
[26] 王伟明,刘嘉,尹树言,基于MATLAB/SIMULINK的数字控制脉冲焊的建模和仿真研究,汽车焊接国际焊接会议论文集,2003:104~108。
[27] 丘联奎,多功能逆变焊机的研制,甘肃工业大学硕士论文,2002。
[28] 孙涵芳等,MCS-51/96系列单片原理及应用,北京:北京航空航天大学出版社,1988。
[29] 潘永雄,刘殊,单片及原理与应用,西安:西安电子科技大学出版社,2000。
[30] 陈嘉庆等,多国单片及实用技术,北京:微电脑信息部,1992。
[31] 赵家瑞,逆变焊接与切割电源,北京:机械工业出版社,1995。
[32] 黄文梅,杨勇,系统仿真分析与设计,长沙:国防科技大学出版社,2001。
[33] 张学红,TIG焊电源控制系统仿真,甘肃工业大学硕士开题报告,2003。
[34] 姚俊,马松辉,SIMULINK建模与仿真,西安:西安电子科技大学出版社,2002。
[35] 戴珂,段善旭,三相电压型整流器/逆变器的功能建模仿真方法,电力电子技术,2002,36(5):60~64。
[36] 李爱文,现代通信基础开关电源的原理和设计,北京:科学出版社,2001。
[37] 鄢景华,自动控制原理,哈尔滨:哈尔滨工业大学出版社,1996。
[38] 陈炳森,计算机辅助焊接技术,北京:机械工业出版社,1999。
[39] 潘际銮,现代弧焊控制,北京:机械工业出版社,2000。
[40] 黄石生,新型弧焊电源及其智能控制,北京:机械工业出版社,2000。
[41] 谢剑英,贾青,微型计算机控制技术,北京:国防工业出版社,2001,9。
[42] 郑大钟,线性系统理论,北京:清华大学出版社,1990,3。
[43] 刘金琨,先进PID控制及其MATLAB仿真,北京:电子工业出版社,2003,1。
[44] MATLAB6.5在线帮助。
[45] 王永军,李景华,数字逻辑与数字系统,北京:电子工业出版社,2002,2。
[46] 韦鲲,微机控制IGBT逆变弧焊电源的研究,甘肃工业大学硕士论文,1998。
[47] 历雅萍,于淑红,数字逻辑电路的Simulink仿真,测控技术,1999,18(2):48~50。
[48] 姜焕中,电弧焊及电渣焊(第二版),北京:机械工业出版社,1980,2。
[49] 杜贵平,黄石生,相移式PWM全桥逆变器软开关技术研究[J],电气自动化,2002,2:15~19。
[50] 尹树言,黄鹏飞,黄勇,软开关弧焊逆变电源的工作机理研究,北京工业大学学报,1998,24(3):55~60。
[51] 陈树君,殷树言,冯雷,软开关弧焊逆变电源的计算机仿真与实验研究,焊接技术,1999,12:26~29(增刊)。
[52] 冯勇,叶斌,IGBT逆变器吸收电路的仿真分析与参数选择,电力机车技术,1999,2:12~14。
[53] www.2lic.com.cn,uc3879芯片资料。
[54] 龙光华,王克争,专用相移芯片在全桥相移零压开关逆变焊机设计中的应用,电焊机,2002,32(5):12~13。
[55] 史悦玲,李时杰,贾俊林,基于UC3879的移相全桥ZVS-PWM逆变器的研究,自动化与仪表,2002(6):21~23。
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