基于DSP的有源电力滤波器的开发研究
|
摘要
理想的电力系统要求以频率和幅值稳定的正弦电压进行供电;对于三相交流电力系统,各相电压和电流应处于幅值大小相等、相位互差120°的正序对称状态。但是,由于电力系统元件运行的非理想线性或非完全对称、负载的性质各异且随机变化、调控手段的不完善以及错误操作、外来干扰和各种故障的存在,供电网中的电流(电压)发生畸变,产生大量谐波。这些谐波对电网造成污染,给用电设备带来危害,引起设备过热、产生振动和噪声,并使绝缘老化,严重时还会损坏设备。谐波污染已成为供电系统不容忽视的问题,正在引起人们的关注。
抑制谐波的方法主要有无源滤波技术和有源电力滤波器技术。有源电力滤波技术与无源滤波技术相比,具有受电网阻抗影响小、能够动态补偿等优点,在治理谐波污染方面发挥重要作用。有关有源电力滤波器的研究主要集中在主电路结构形式(串联、并联和串并联)、谐波电流检测方法和补偿电流的控制方法等方面。本论文重点研究了基于不同谐波电流补偿方法的滤波器的设计。
有源电力滤波器对谐波的补偿控制主要有数字补偿控制和模拟补偿控制两种。数字补偿控制的优点是可以对电网谐波的补偿达到很精确的程度,不容易受运行环境改变的影响,但是要求运算速度很高的实时数字信号处理芯片,因此造价较高;模拟补偿控制对硬件的要求比较严格。滤波器的设计无论对于有源电力滤波器数字实现还是模拟实现都是至关重要的一环。本论文以三相三线制电网为研究对象,以数字信号处理滤波器设计理论为基础,使用MATLAB仿真软件进行了有源电力滤波器的实时动态仿真,仿真结果表明了谐波电量检测方法和补偿控制方案的正确性;最后设计了一套实验室样机系统。
The ideal power system needs to be supplied with sine voltage whose frequency and amplitude are both stable. To three-phase AC power system, the currents and voltages must be equal of amplitude and the phase-shift between each other should be 120 of positive order. Because of the elements which run under nonideal linearity and unentire symmetry in the power system, the loads which are different and change randomly, the methods which adjust and control the system faultily and operate improperly, the disturbance and the malfunction which happen somewhere, the current and voltage in the supply system are distorted seriously and thus large amount of harmonics are produced. Those harmonics pollute the supply system, harm devices which may be over-hot, noisy, vibrant and that may be destroyed in the worst instance. The harmonics compensation has become today's hot topic in Power Engineering.
Passive filter and active power filter (APF) are the two primary approaches for eliminating harmonics. Comparing with passive filter, APF has many advantages, which is insensitive to system impedance and can be used to compensate harmonics. APF plays an important role in eliminating harmonic. Most researches on APF are focused on main circuit configurations (series-type, shunt-type, compound-type), harmonic current detection approaches and control strategies to compensate current ,etc. This paper mainly deals with the design of APF based on harmonic current compensating approaches.
APF control realization can be either digital or analogical. The advantage of digital compensating control(DCC) is that it can compensate harmonics to a precision level and is independent of the surrounding environment. But DCC needs high-speed real-time chips to deal with digital signal processing, so has high price; analog compensating control(ACC) demands hardware very rigidly. The design of APF is very important to both ACC and DCC. The dissertation, reseaching on three-phase-three-line power-network, based on the theory of digital signal processing(DSP), has done the real-time dynamic simulation of APF using the software of MATLAB, and the result shows that the method of harmonics detecting and the scheme of current controlling are both pratical and effective. An experimental laboratory prototype scheme is proposed.
抑制谐波的方法主要有无源滤波技术和有源电力滤波器技术。有源电力滤波技术与无源滤波技术相比,具有受电网阻抗影响小、能够动态补偿等优点,在治理谐波污染方面发挥重要作用。有关有源电力滤波器的研究主要集中在主电路结构形式(串联、并联和串并联)、谐波电流检测方法和补偿电流的控制方法等方面。本论文重点研究了基于不同谐波电流补偿方法的滤波器的设计。
有源电力滤波器对谐波的补偿控制主要有数字补偿控制和模拟补偿控制两种。数字补偿控制的优点是可以对电网谐波的补偿达到很精确的程度,不容易受运行环境改变的影响,但是要求运算速度很高的实时数字信号处理芯片,因此造价较高;模拟补偿控制对硬件的要求比较严格。滤波器的设计无论对于有源电力滤波器数字实现还是模拟实现都是至关重要的一环。本论文以三相三线制电网为研究对象,以数字信号处理滤波器设计理论为基础,使用MATLAB仿真软件进行了有源电力滤波器的实时动态仿真,仿真结果表明了谐波电量检测方法和补偿控制方案的正确性;最后设计了一套实验室样机系统。
The ideal power system needs to be supplied with sine voltage whose frequency and amplitude are both stable. To three-phase AC power system, the currents and voltages must be equal of amplitude and the phase-shift between each other should be 120 of positive order. Because of the elements which run under nonideal linearity and unentire symmetry in the power system, the loads which are different and change randomly, the methods which adjust and control the system faultily and operate improperly, the disturbance and the malfunction which happen somewhere, the current and voltage in the supply system are distorted seriously and thus large amount of harmonics are produced. Those harmonics pollute the supply system, harm devices which may be over-hot, noisy, vibrant and that may be destroyed in the worst instance. The harmonics compensation has become today's hot topic in Power Engineering.
Passive filter and active power filter (APF) are the two primary approaches for eliminating harmonics. Comparing with passive filter, APF has many advantages, which is insensitive to system impedance and can be used to compensate harmonics. APF plays an important role in eliminating harmonic. Most researches on APF are focused on main circuit configurations (series-type, shunt-type, compound-type), harmonic current detection approaches and control strategies to compensate current ,etc. This paper mainly deals with the design of APF based on harmonic current compensating approaches.
APF control realization can be either digital or analogical. The advantage of digital compensating control(DCC) is that it can compensate harmonics to a precision level and is independent of the surrounding environment. But DCC needs high-speed real-time chips to deal with digital signal processing, so has high price; analog compensating control(ACC) demands hardware very rigidly. The design of APF is very important to both ACC and DCC. The dissertation, reseaching on three-phase-three-line power-network, based on the theory of digital signal processing(DSP), has done the real-time dynamic simulation of APF using the software of MATLAB, and the result shows that the method of harmonics detecting and the scheme of current controlling are both pratical and effective. An experimental laboratory prototype scheme is proposed.
引文
1. Bollen M H J. Understanding power quality problems, voltagesags and interruptions[M]. IEEE PRESS, 2000年
2. 林雪海.现代电能质量的基本问题.电网技术,2001年,第二十五卷.(第十期)
3. 吴竞昌、孙树勤、宋文南等.电力系统谐波.北京:水利电力出版社,1988年
4. 王兆安、杨君、刘进军.谐波抑制和无功功率补偿.北京:机械工业出版社,1998年
5. 张建诚、陈志业、梁志瑞.现代电力电子技术在电力系统中的应用.电力情报,1999年,第三期
6. 张力.现代电力电子技术基础.北京:高等教育出版社,1999年
7. 吕庆敏.浅谈电力电子技术领域中若干的研究热点.电力电子技术,2001年,第一期
8. 张雄伟、曹铁勇.DSP芯片的原理与开发应用.第二版.北京:电子工业出版社,2000年
9. 钱照明、叶忠明、董伯藩.谐波抑制技术.电力系统自动化,1997年,第二十一卷(第十期)
10. H Akagi, Y Kanazawa, A Nabae. Instantaneous Reactive Power Compensator Comprising Switching Devices Without Energy Storage Components. IEEE Trans on Ind Appl, 1984
11. 卓放、杨君、王兆安等.用于三相四线制系统的有源电力滤波器研究.西安交通大学学报,2000年,第三十四卷(第三期)
12. 唐中琦、谢运祥.有源滤波器补偿电流的检测与控制.电工电能新技术,1998年,第四期
13. 张雄伟、陈亮、徐光辉.DSP集成开发和应用实例.北京:电子工业出版社,2002年
14. 黄俊、王兆安.电力电子变流技术.第三版.北京:机械工业出版社,1994年
15. 王幸之、王雷、翟成等.单片机应用系统抗干扰技术.第三版.北京:北京航空航天大学出版社,2000年
16. TI. TMS320F240 DSP Controllers Evaluation Module Technical Reference. SPRU248B, Jul 1999
17. TI. TMS320F/C24x DSP Controllers CPU and Instruction Set. SPRU160C, Jun 1999
18. TI. TMS320LF/LC240x DSP Controllers System and Peripherals. SPRU357, Jan 2000
19. TI. TMS320LF2407, TMS320LF2406, TMS320LF2402 DSP Controllers. SPRS094G, Aug 2001
20. 和众达电子. block_lf2407.gif, http://www.seeddsp.com/product/dsp/dsp/c2000.php. 2002年5月
21. SGS-THOMSON MICROELECTRONICS. 74AC14 HEX INVERTER, Mar 1998
22. Cypress Semiconductor Corporation. CY7C1021V 64K×16 Static RAM. Oct 1999
23. TI. TPS7333Q Low-Dropout Voltage Regulator. Jan 1997
24. Analog Devices. Precision Micropower, Low Dropout, Voltage References REF19x Series. REV. C
25. Mitsubishi Semiconductors. Using Intelligent Power Modules. Sep 1998
26. 张义和.Protel PCB 99设计与应用技巧.北京:科学出版社,2000年
27. 吴湘淇.信号、系统与信号处理(下).北京:电子科技出版社,1996年
28. 郑君里、应启珩、杨为理.信号与系统(下).第二版.北京:高等教育出版社,2000年
29. 楼顺天、李博菡.基于MATLAB的系统分析与设计.西安:西安电子科技大学出版社,1998年
30. 张宜华.精通MATLAB5.北京:清华大学出版社,1999年
31. 范影乐、杨胜天、李秩.MATLAB仿真应用祥解.北京:人民邮电出版社,2001年
32. 陈在平、杜太行.控制系统计算机仿真CAD——MATLAB语言应用.天津:天津大学出版社,2001年
33. Hydro-Québec TEQSIM International .Power System Blockset For Use with Simulink. Version2, Math Works,2001
34. 杨君、王兆安.并联型电力有源滤波器控制方式的研究.西安交通大学学报,1995年,第二十九卷(第三期)
35.王长永、金陶陶、张仲超.统一模型下单相电路谐波及无功电流检测的研究.电力电子技术,2001年,第二期
36.肖湘宁、徐永海.电能质量问题剖析.电网技术,2001年,第二十五卷(第三期)
37. Bird B M, Marsh J F, McLellan P R. Harmonic reduction in multiple converters by triple-frequeny current injection.Proc IEE, 1969
38. Sasaki H, Machida T. A method to eliminate ac harmonic currents by magnetic compensation consideration on basic design. IEEE ,Trans Power App & Syst, 1971
39. Gyugyi L, Strycula E C. Active ac power filters. In: Proc of IEEE/IAS Annual Meeting, 1976
2. 林雪海.现代电能质量的基本问题.电网技术,2001年,第二十五卷.(第十期)
3. 吴竞昌、孙树勤、宋文南等.电力系统谐波.北京:水利电力出版社,1988年
4. 王兆安、杨君、刘进军.谐波抑制和无功功率补偿.北京:机械工业出版社,1998年
5. 张建诚、陈志业、梁志瑞.现代电力电子技术在电力系统中的应用.电力情报,1999年,第三期
6. 张力.现代电力电子技术基础.北京:高等教育出版社,1999年
7. 吕庆敏.浅谈电力电子技术领域中若干的研究热点.电力电子技术,2001年,第一期
8. 张雄伟、曹铁勇.DSP芯片的原理与开发应用.第二版.北京:电子工业出版社,2000年
9. 钱照明、叶忠明、董伯藩.谐波抑制技术.电力系统自动化,1997年,第二十一卷(第十期)
10. H Akagi, Y Kanazawa, A Nabae. Instantaneous Reactive Power Compensator Comprising Switching Devices Without Energy Storage Components. IEEE Trans on Ind Appl, 1984
11. 卓放、杨君、王兆安等.用于三相四线制系统的有源电力滤波器研究.西安交通大学学报,2000年,第三十四卷(第三期)
12. 唐中琦、谢运祥.有源滤波器补偿电流的检测与控制.电工电能新技术,1998年,第四期
13. 张雄伟、陈亮、徐光辉.DSP集成开发和应用实例.北京:电子工业出版社,2002年
14. 黄俊、王兆安.电力电子变流技术.第三版.北京:机械工业出版社,1994年
15. 王幸之、王雷、翟成等.单片机应用系统抗干扰技术.第三版.北京:北京航空航天大学出版社,2000年
16. TI. TMS320F240 DSP Controllers Evaluation Module Technical Reference. SPRU248B, Jul 1999
17. TI. TMS320F/C24x DSP Controllers CPU and Instruction Set. SPRU160C, Jun 1999
18. TI. TMS320LF/LC240x DSP Controllers System and Peripherals. SPRU357, Jan 2000
19. TI. TMS320LF2407, TMS320LF2406, TMS320LF2402 DSP Controllers. SPRS094G, Aug 2001
20. 和众达电子. block_lf2407.gif, http://www.seeddsp.com/product/dsp/dsp/c2000.php. 2002年5月
21. SGS-THOMSON MICROELECTRONICS. 74AC14 HEX INVERTER, Mar 1998
22. Cypress Semiconductor Corporation. CY7C1021V 64K×16 Static RAM. Oct 1999
23. TI. TPS7333Q Low-Dropout Voltage Regulator. Jan 1997
24. Analog Devices. Precision Micropower, Low Dropout, Voltage References REF19x Series. REV. C
25. Mitsubishi Semiconductors. Using Intelligent Power Modules. Sep 1998
26. 张义和.Protel PCB 99设计与应用技巧.北京:科学出版社,2000年
27. 吴湘淇.信号、系统与信号处理(下).北京:电子科技出版社,1996年
28. 郑君里、应启珩、杨为理.信号与系统(下).第二版.北京:高等教育出版社,2000年
29. 楼顺天、李博菡.基于MATLAB的系统分析与设计.西安:西安电子科技大学出版社,1998年
30. 张宜华.精通MATLAB5.北京:清华大学出版社,1999年
31. 范影乐、杨胜天、李秩.MATLAB仿真应用祥解.北京:人民邮电出版社,2001年
32. 陈在平、杜太行.控制系统计算机仿真CAD——MATLAB语言应用.天津:天津大学出版社,2001年
33. Hydro-Québec TEQSIM International .Power System Blockset For Use with Simulink. Version2, Math Works,2001
34. 杨君、王兆安.并联型电力有源滤波器控制方式的研究.西安交通大学学报,1995年,第二十九卷(第三期)
35.王长永、金陶陶、张仲超.统一模型下单相电路谐波及无功电流检测的研究.电力电子技术,2001年,第二期
36.肖湘宁、徐永海.电能质量问题剖析.电网技术,2001年,第二十五卷(第三期)
37. Bird B M, Marsh J F, McLellan P R. Harmonic reduction in multiple converters by triple-frequeny current injection.Proc IEE, 1969
38. Sasaki H, Machida T. A method to eliminate ac harmonic currents by magnetic compensation consideration on basic design. IEEE ,Trans Power App & Syst, 1971
39. Gyugyi L, Strycula E C. Active ac power filters. In: Proc of IEEE/IAS Annual Meeting, 1976
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |