发布时间:2024-08-14 14:30:14 人气:
并网逆变器的电流是如何产生的?
我感觉你对逆变器输出电流和并网电流这两个概念不理解。逆变器输出电流是逆变器输出的电流;并网电流是电网侧的电流;中间有个LC或者LCL滤波器,你可以认为是线路阻抗,它能改善波形质量。一般逆变器并网是电压型并网逆变器,电压型并网逆变器用电流实现控制。首先电网电压和逆变器输出电流是同相位的(用锁相环锁相就能实现)。逆变器电流经过线路阻抗必定会有个延迟,因为线路阻抗一般呈感性,所以电网电流和电网电压不同相位。你从电网侧往逆变器侧看:相当于电网电压接了一个非线性电阻,那么电网电压和电网电流当然不同步了。
不知道有没有给你说清楚。
高峰的科研成果
1. P. C. Loh, S. W. Lim, F. Gao and F. Blaabjerg, Three-level Z-source inverters using a single LC impedance network, IEEE Trans. Power Electron., vol. 22, no. 2, pp. 706-711, Mar. 2007.2. Poh Chiang Loh, Feng Gao, Frede Blaabjerg, Shi Yun Feng and Jamies Soon, Pulsewidth Modulated Z-Source Neutral-Point-Clamped Inverter, IEEE Trans. Ind. Applicat., vol. 43, no. 5, pp. 1295-1308, Sep./Oct. 2007.
3. Feng Gao, Poh Chiang Loh, Frede Blaabjerg and D. Mahinda Vilathgamuwa, Dual Z-source Inverter with Three-Level Reduced Common Mode Switching, IEEE Trans. Ind. Applicat., vol. 43, no. 6, pp. 1579-1608, Nov/Dec. 2007.
4. Poh Chiang Loh, Feng Gao and Frede Blaabjerg, Topological and Modulation Design of Three-Level Z-Source Inverters, IEEE Trans. Power Electron., Vol. 23, no. 5, pp. 2268-2277, Sep. 2008.
5. P. C. Loh, F. Blaabjerg, F. Gao, A. Baby and A. C. Tan, Pulse-Width-Modulation of Neutral-Point-Clamped Indirect Matrix Converter, IEEE Trans. Ind. Applicat., vol. 44, no. 6, pp. 1805-1814, Nov./Dec. 2008.
6. F. Gao, C. Liang, P. C. Loh and F. Blaabjerg, Buck-Boost Current Source Inverters with Diode-Inductor Network, IEEE Trans. Ind. Applicat., vol. 45, no. 2, pp. 794-804, Mar./Apr. 2009.
7. F. Gao, P. C. Loh, F. Blaabjerg and D. M. Vilathgamuwa Performance Evaluation of Three-Level Z-Source Inverters Under Semiconductor Failure Conditions, IEEE Trans. Ind. Applicat., vol. 45, no. 3, pp. 971-981, May/Jun. 2009.
8. Feng Gao, Poh Chiang Loh, Remus Teodorescu, Frede Blaabjerg and D Mahinda Vilathgamuwa, Topological Design and Modulation Strategy for Buck-Boost Three-Level Inverters, IEEE Trans. Power Electron., vol. 24, no. 7, pp. 1722-1732, Jul. 2009.
9. Poh Chiang Loh, Feng Gao, Frede Blaabjerg and Sok Wei Lim, Operational Analysis and Modulation Control of Three-Level Z-Source Inverters with Enhanced Output Waveform Quality, IEEE Trans. Power Electron., vol. 24, no. 7, pp. 1767-1775, Jul. 2009.
10. Poh Chiang Loh, Feng Gao, Pee Chin Tan and Frede Blaabjerg, Three-Level AC-DC-AC Z-Source Converter Using Reduced Passive Component Count, IEEE Trans. Power Electron., vol. 24, no. 7, pp. 1671-1681, Jul. 2009.
11. Feng Gao, Poh Chiang Loh, Remus Teodorescu and Frede Blaabjerg, Diode-Assisted Buck-Boost Voltage Source Inverters, IEEE Trans. Power Electron., vol. 24, no. 9, pp. 2057-2064, Sep. 2009.
12. Poh Chiang Loh, Feng Gao and Frede Blaabjerg, Embedded EZ-Source Inverters, IEEE Trans. Ind. Applicat., vol. 46, no.1, pp. 256-267, Jan./Feb. 2010.
13. Kuan Khoon Tan, Feng Gao, Poh Chiang Loh and Frede Blaabjerg, Enhanced buck-boost neutral-point-clamped inverters with self capacitive voltage balancing, IEEE Trans. Ind. Applicat., vol. 46, no. 3, pp. 1021-1033, May/Jun. 2010..
14. Feng Gao, Poh Chiang Loh, Frede Blaabjerg and D. Mahinda Vilathgamuwa, Five-Level Current Source Inverters with Buck-Boost and Inductive Current Balancing Capabilities, IEEE Trans. Ind. Electron., vol. 57, no. 8, pp. 2613-2622, Aug. 2010.
15. Feng Gao, Poh Chiang Loh, Frede Blaabjerg and Remus Teodorescu, D Mahinda Vilathgamuwa, Five-Level Z-Source Diode-Clamped Inverter, IET Power Electron., vol. 3, no. 4, pp. 500-510, 2010.
16. Feng Gao, Lei Zhang, Ding Li, Poh Chiang Loh, Yi Tang and Houlei Gao, Optimal Pulsewidth Modulation of Nine-Switch Converter, IEEE Trans. Power Electron., vol. 25, no. 9, pp. 2331-2343, Sep. 2010.
17. Feng Gao, Ding Li, Poh Chiang Loh and Frede Blaabjerg, Asymmetrical and Symmetrical Embedded Z-Source Inverters, IET Power Electron., in press.
18. Ding Li, Feng Gao, Poh Chiang Loh, Miao Zhu and Frede Blaabjerg, Hybrid-Source Impedance Networks: Layouts and Generalized Cascading Concepts, IEEE Trans. Power Electron., in press.
19. Lei Zhang, Poh Chiang Loh and Feng Gao, An Integrated Nine-Switch Power Conditioner, IEEE Trans. Power Electron., accepted.
20. Yi Tang, Poh Chiang Loh, Peng Wang, Fook Hoong Choo and Feng Gao, Exploring Inherent Damping Characteristic of LCL-Filters for Three-Phase Grid-Connected Voltage Source Inverters, IEEE Trans. Power Electron., accepted.
21. Ding Li, Feng Gao, Poh Chiang Loh, Yi Tang and Peng Wang, “Indirect DC-Link Voltage Control of Two-Stage Single-Phase Grid-Tied Photovoltaic Inverter,” IEEE Trans. Power Electron., Accepted.
22. 袁建华,高厚磊,高峰等.两级三相并网逆变器直流链电压间接控制策略[J].电力系统自动化,2010,34(23):82-86.
其它国际会议论文近40篇。
学术成果及奖励:
2007 年获得由IEEE Industry Applications Society Power Converter Committee 颁发的优秀论文奖。
简述逆变器的选型
光伏并网逆变器的常见类型
目前我国光伏电站采用的逆变器结构主要有:集中式光伏逆变器系统、组串式光伏逆变器系统、集散式光伏逆变器系统以及微型逆变器等。下面简单介绍一下集中式逆变器和组串式逆变器的的特点(后期会陆续介绍其他类型的逆变器):
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1.1集中式光伏逆变器
集中式光伏逆变系统是大型光伏电站普遍采用的电能变换装置,也是目前最为成熟的技术方案之一。集中式光伏逆变系统采用一路最大功率点跟踪(MPPT)输入,集中MPPT寻优、集中逆变输出,
集中式逆变器是将很多光伏组串经过汇流后连接到逆变器直流输入端,集中完成将直流电转换为交流电的设备。集中式逆变器通常使用单级两电平三相全桥拓扑结构,大功率IGBT和SVPWM调制算法,通过DSP控制IGBT发出两电平方波,通过LCL或LC滤波器滤波后输出满足标准要求的正弦波。
集中式逆变器常见的输出功率为500kW、630kW,以500kW集中式逆变器应用业绩最多,集中式逆变器转换效率通常>98.3%,中国效率>97.5%,每台逆变器具有1路MPPT,MPPT电压跟踪范围为500V~850V,2台逆变器组成1MW方阵,通过一个双分裂绕组变压器升压后接入35kV中压电网。
目前国内还有最新的直流1500V集中式逆变器,单价功率1.25~3.125MW,采用逆变升压一体结构,组成2.5MW~6.4MW的发电系统,适合目前平价电站的建设。
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集中式逆变器的优点:
1、安装相对简单,更方便维护。
2、该逆变系统采用单级式控制方式,控制相对简洁,相关技术比较成熟,单位系统造价低。
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集中式逆变器的缺点:
单台集中式光伏逆变器仅具备一路MPPT路数,针对光伏电池板组件之间存在的匹配偏差,无法做到对每一光伏电池板组串精确地跟踪控制,造成电池板利用效率降低。特别是山地电站的大规模涌现,其应用场景受地形限制,无法保证所有组串朝向、倾角按照最优方式配置,单路MPPT方案的集中式光伏逆变器很难满足现场应用要求。
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1.2组串式光伏逆变器
组串式光伏逆变系统最初是针对屋顶光伏等小型光伏发电系统设计的,可直接接入低压电网,不需要隔离变压器或升压变压器,特别适合于低压并网的分布式光伏发电。
为了更好地解决光伏电池板组件“失配”造成的发电量的损失,在大型光伏电站中也出现了以小功率组串式光伏逆变器组成的光伏逆变系统,通过对光伏电池板组件子方阵的分散MPPT优化,交流汇接并联后集中升压并网,从而较好的解决了大型光伏电站因光伏电池板组件“失配”导致的发电量损失。
组串式逆变器是基于模块化的概念,将光伏方阵中的每个光伏组串连接至指定逆变器的直流输入端,各自完成将直流电转换为交流电的设备。组串式逆变器通常使用两级三电平三相全桥拓扑结构,选用中小功率IGBT和SVPWM调制算法,通过DSP控制IGBT发出三电平方波,通过LCL或LC滤波器滤波后输出满足标准的正弦波。
组串式逆变器常见的输出功率为1~10kW、20kW~40kW、50kW~80kW,逆变器的最大转换效率为98%以上,中国效率高达98.4%以上,每台逆变器具有多路的MPPT,MPPT电压范围通常为200V~1000V(1~5kW小功率逆变器的MPPT范围一般是80V~500V,直接接入用户电网侧),通过交流汇流后经双绕组变压器接入35kV中压电网。
湖北仙童科技有限公司 高端电力电源全面方案供应商 江生 13997866467
