【講座題目】模塊化多電平變換器的建模與控制
【時(shí) 間】2023年11月22日 下午:14:00-15:20
【地 點(diǎn)】北京校區(qū) 主樓D260會(huì)議室
【主講人】李澤元,美國(guó)國(guó)家工程院院士、中國(guó)工程院外籍院士
【主講人簡(jiǎn)介】
李澤元教授(Fred C. Lee)于1968年在臺(tái)灣國(guó)立成功大學(xué)獲得電氣工程學(xué)士學(xué)位,隨后于1972年和1974年分別在杜克大學(xué)獲得電氣工程碩士和博士學(xué)位。李澤元教授是弗吉尼亞理工大學(xué)的名譽(yù)特聘教授,也是弗吉尼亞理工大學(xué)電力電子研究中心(CPES)的創(chuàng)始人和名譽(yù)主任。作為CPES的學(xué)術(shù)帶頭人,李教授主持了一系列項(xiàng)目,涵蓋了研究、技術(shù)開(kāi)發(fā)、教育推廣、產(chǎn)業(yè)合作和技術(shù)轉(zhuǎn)移。CPES致力于滿足行業(yè)需求,推動(dòng)其研究和成果應(yīng)用于產(chǎn)業(yè)。迄今為止,全球超過(guò)250家公司受益于該研究中心的產(chǎn)業(yè)合作項(xiàng)目。由于其在產(chǎn)業(yè)合作、技術(shù)轉(zhuǎn)移、教育和推廣等方面的貢獻(xiàn),CPES被美國(guó)國(guó)家科學(xué)基金會(huì)(NSF)評(píng)為模范工程研究中心(ERC)。李教授的研究方向?yàn)楦哳l功率變換、磁性和電磁干擾、分布式電力系統(tǒng)、可再生能源、電能質(zhì)量、以及高密度電子封裝、集成、建模和控制。李教授擁有107項(xiàng)美國(guó)專利,并發(fā)表了超過(guò)340篇期刊論文和790多篇經(jīng)過(guò)評(píng)審的技術(shù)論文。在弗吉尼亞理工大學(xué)任職期間,李教授指導(dǎo)了90名博士和94名碩士學(xué)生完成學(xué)業(yè)。李教授是美國(guó)國(guó)家工程院院士、中國(guó)工程院外籍院士。根據(jù)Research.com網(wǎng)站上的D-Index排名,李教授是電子與電氣工程學(xué)科的世界頂尖學(xué)者之一。
Fred C. Lee received his B.S. degree in electrical engineering from the National Cheng Kung University in Taiwan in 1968, and his M.S. and Ph.D. degrees in electrical engineering from Duke University in 1972 and 1974, respectively.Dr. Lee is a University Distinguished Professor Emeritus and Founder and Director Emeritus of CPES, a preeminent academic center in power electronics research at Virginia Tech. As CPES Director, Dr. Lee led a program that encompasses research, technology development, educational outreach, industry collaboration, and technology transfer. CPES focuses its research on meeting industry needs and allows industry to benefit from the Center's research and outputs. To date, more than 250 companies worldwide have benefited from the industry partnership program. The center has been cited by NSF as a model ERC for its industry collaboration and technology transfer, education, and outreach programs.Dr. Lee's research interests include high-frequency power conversion, magnetics and EMI, distributed power systems, renewable energy, power quality, high-density electronics packaging and integration, and modeling and control.Dr. Lee holds 107 U.S. patents and has published over 340 journal articles and over 790 refereed technical papers. During his tenure at Virginia Tech, Dr. Lee has supervised to completion 90 Ph.D. and 94 Master's students.Dr. Lee is a member of the U.S. National Academy of Engineering, and a foreign member of the Chinese Academy of Engineering in the People’s Republic of China. According to Research.com D-Index ranking, Dr. Lee is among the world’s top scholars within the discipline of Electronics and Electrical Engineering.
【報(bào)告內(nèi)容簡(jiǎn)介】
模塊化多電平變換器(MMC)被認(rèn)為是可再生能源與現(xiàn)有公用事業(yè)電網(wǎng)之間的關(guān)鍵接口技術(shù),然而當(dāng)前MMC控制復(fù)雜且不直觀。由于MMC系統(tǒng)狀態(tài)量遠(yuǎn)大于控制量,為最小化其內(nèi)部環(huán)流而拓展的控制模糊不清。若沒(méi)有對(duì)MMC進(jìn)行合適的建模和控制,MMC在運(yùn)行時(shí)會(huì)產(chǎn)生大量環(huán)流,導(dǎo)致大體積儲(chǔ)能電容器被過(guò)度使用。采用狀態(tài)平面分析技術(shù),以圖形方式給出了MMC兩種類型的環(huán)流,一種與MMC輸入和輸出能量交換有關(guān),另一種與MMC內(nèi)上下橋臂能量交換有關(guān)。此外,兩個(gè)功率流本質(zhì)上是正交的,這意味著各個(gè)功率路徑上的控制獨(dú)立。因此,采用坐標(biāo)轉(zhuǎn)換,建立了解耦的等效電路模型,獨(dú)立控制管理各個(gè)功率流,明確了消除環(huán)流的方法。
Modular multilevel converter is deemed the key interface technology between renewable energy sources and the existing utility power grids. However, the interface control currently deployed is rather complicated and counterintuitive. Since the systems states are far greater than the means of control, the extend of control to minimize the circulating energy was rather ambiguous. Without proper modeling and control, this system is often operated with large circulating energy, resulting in excessive use of the bulky energy storage capacitors.
Employing state-plane analysis techniques, two types of circulating energies are delineated graphically, one related to the energy exchange between input and output, and the other related to the energy swapping between upper arm and lower arm. Furthermore, these two power flows are orthogonal in nature, implying that the means of control for each power flow path are independent. Consequently, a coordinate transformation is employed, leading to a decoupled equivalent circuit model. Each power flow path is governed by it’s own control law. Methods of eliminating circulating energy are clearly identified.