Power Conversion, Pulse With Modulation, and Integration Techniques for All Electric Vehicles

适用于所有电动汽车的功率转换、脉冲调制和集成技术

• 批准号: RGPIN-2017-06770
• 负责人: Rathore, Akshay
• 金额: $ 2.7万
• 依托单位: Concordia University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=686996
• 关键词: Power; Conversion; Pulse; Modulation; Integration

The proposal focuses on designing and developing innovative power electronics topologies and novel modulation techniques for marine electrification and more electric aircraft (MEA).******Marine Electrification (Sea transportation) and MEA (air transportation) are two heavy electric transportation systems and of different categories than ground transportation. Significant research on power electronics and drives for ground electric vehicles has been done and is at saturation now. However, power electronics research for marine and MEA is not mature yet. There are different challenges for power electronics for these two applications. Several industries are investigating on power electronics for these marine and MEA due to their different and specific requirements. Research program on marine and MEA is lacking in Canadian Universities. Therefore, the aim of this research proposal is to establish a research program on power electronics for marine and MEA. ******Power electronics is key enabling technology for electrifying the conventional transportation systems. Modulation schemes to control the switching states of the semiconductor devices of power electronics are important to meet the specific requirements and realize the desired attributes such as volume, weight, efficiency, etc. Marine and MEA involve MG power processing. ******To achieve high efficiency for higher power marine system, Medium Voltage (MV) solutions have been proposed and industries are adopting it. However, existing devices have limitation on their blocking voltage. Therefore, Modular Multilevel Converters (MMCs) are proposed for MV high power applications. To limit device switching losses at MV, it is better to modulate the devices at low switching frequency. However, it compromises on total harmonic distortion (THD) of inverter output currents. Therefore, this research program aims at developing Medium Voltage DC (MVDC) MMCs and optimal low frequency modulation for MVDC marine propulsion systems to reduce switching loses while not compromising on THD. ***Power electronic solutions such as matrix converter based direct ac-ac conversion without dc link and Active-Front-End rectifier with dc link will be investigated to eliminate bulky phase-shifting transformer.******For MEA, power electronic solutions to develop ac/dc converter with variable frequency of 360 to 800 Hz will be investigated with minim THD.***The proposed research program will strategize to implement high switching frequency modulation to limit the cost and volume of the magnetics, and filters. Wide bandgap devices, Silicon Carbide (SiC) and Gallium Nitride (GaN) and magnetic materials, Nano Crystalline will be investigated to develop more efficient power converters with low thermal requirements. ***The proposal will also investigate current-fed power electronics solutions owing to their current limiting, voltage gain, and short circuit protection features.

该提案的重点是为船舶电气化和多电动飞机（MEA）设计和开发创新的电力电子拓扑和新型调制技术。******海上电气化（海上运输）和MEA（空中运输）是两种重型电力运输系统，与地面运输不同。对地面电动汽车的电力电子和驱动系统进行了大量的研究，目前已处于饱和状态。然而，船舶和MEA的电力电子研究还不成熟。对于这两种应用，电力电子器件面临着不同的挑战。由于其不同和特定的要求，一些行业正在研究这些船舶和MEA的电力电子设备。加拿大大学缺乏对海洋和环境影响因素的研究项目。因此，本研究计划的目的是建立一个用于海洋和MEA的电力电子研究计划。******电力电子技术是实现传统交通系统电气化的关键技术。控制电力电子半导体器件开关状态的调制方案对于满足特定要求和实现所需的体积、重量、效率等属性非常重要。船舶和MEA涉及MG功率处理。******为了实现更高功率船舶系统的高效率，中压（MV）解决方案已经被提出并被工业采用。然而，现有的器件对其阻断电压有限制。因此，模块化多电平变换器（MMCs）被提出用于中压高功率应用。为了将器件的开关损耗限制在毫伏，最好将器件调制在低开关频率。然而，它损害了逆变器输出电流的总谐波失真（THD）。因此，本研究计划旨在开发中压直流（MVDC） mmc和MVDC船舶推进系统的最佳低频调制，以减少开关损失，同时不影响THD。***将研究基于矩阵变换器的无直流链路直接ac-ac转换和带直流链路的有源前端整流器等电力电子解决方案，以消除笨重的移相变压器。******对于MEA，将研究以最小THD开发360至800 Hz变频ac/dc转换器的电力电子解决方案。***提议的研究计划将制定策略来实现高开关频率调制，以限制磁性和滤波器的成本和体积。宽带隙器件、碳化硅（SiC）和氮化镓（GaN）以及磁性材料、纳米晶体将被研究以开发更高效、低热要求的功率转换器。该提案还将研究电流馈电电力电子解决方案，因为它们具有限流、电压增益和短路保护功能。