Highly-efficient and smart Power Electronics Systems for long-lasting energy storage Systems in smart grid applications

用于智能电网应用中持久储能系统的高效智能电力电子系统

• 批准号: RGPIN-2016-06519
• 负责人: Bakhshai, Alireza
• 金额: $ 2.99万
• 依托单位: Queen's University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=644508
• 关键词: Highly; efficient; smart; Power; Electronics

Electricity and transportation sectors are accountable for producing the largest amount of greenhouse gas (GHG) emissions. Although Canada generates the cleanest worldwide electricity, emission from transportation is the largest contributor to Canada's GHG emissions, representing 24% of overall GHGs. ***Current worldwide incentives have spurred the development of Electric Vehicles (EVs). It is expected that the number of such vehicles will grow exponentially, to 30 million annually by 2040. Electric Vehicles are more efficient and have few direct emissions. However, they all rely on energy generated by the electricity sector. This implies that the GHG emission from transportation is moved to the electricity sector. To truly reduce this emission, more electricity should be produced from renewable energy sources such as wind and solar. ***A major problem in integrating more renewables into the power grid is the intermittent nature of solar and wind energies that reduces the performance of the power grid. Energy storage will provide flexibility to a relatively inflexible grid and will enable a larger scale deployment of renewable energies, without threatening the grid stability or power quality. Due to a push in producing EVs and a premeditated grow in the number of these vehicles, on-board traction batteries of EVs are the most promising means for energy storage. ***This research proposal aims to introduce and design innovative highly-efficient power electronics systems and the invention of next-generation devices for distributed energy storage and energy conversion based on EV technology for both utility scale and Vehicle to Grid (V2G) energy storage systems. These power electronics and control systems will mostly rely on local parameters and need no communication link. This will be a very important achievement since it has been a challenging issue in microgids and smart grid applications. ***The proposed research will be advantageous for multiple research streams in the rapidly growing areas of energy integration, renewable generation, and converter enabled microgrids It is expected that industry and scientists, specifically electricity and transportation sectors will benefit from the outcome of this project. People and policymakers will benefit economically due to an improvement in the efficient use of energy. Because of significant GHE reductions, all Canadians can benefit from the improved air quality, and as a result, a better quality of life.***The proposed research will directly support the training of 5 graduate students. In addition, 2-3 senior undergraduate students (4th year) will be trained annually on various aspect of this project. The participating students will develop research skills in advanced design of power electronics circuits, control systems, power electronics simulation tools, and FPGA based digital control techniques.

电力和运输行业是温室气体 (GHG) 排放量最大的行业。 尽管加拿大生产的电力是全球最清洁的，但交通运输排放是加拿大温室气体排放的最大来源，占温室气体排放总量的 24%。 ***当前全球的激励措施刺激了电动汽车（EV）的发展。预计此类车辆的数量将呈指数增长，到 2040 年每年达到 3000 万辆。电动汽车效率更高，直接排放很少。然而，它们都依赖于电力部门产生的能源。这意味着交通运输的温室气体排放转移到了电力部门。 为了真正减少这种排放，应该利用风能和太阳能等可再生能源生产更多的电力。 ***将更多可再生能源并入电网的一个主要问题是太阳能和风能的间歇性，这会降低电网的性能。储能将为相对不灵活的电网提供灵活性，并使可再生能源更大规模地部署，而不会威胁电网稳定性或电能质量。由于电动汽车生产的推动以及此类车辆数量的有计划的增长，电动汽车的车载动力电池是最有前途的储能方式。 ***该研究计划旨在引入和设计创新的高效电力电子系统，以及基于电动汽车技术的分布式储能和能量转换的下一代设备的发明，用于公用事业规模和车辆到电网（V2G）储能系统。这些电力电子和控制系统主要依赖于本地参数，不需要通信链路。这将是一项非常重要的成就，因为它一直是微电网和智能电网应用中的一个具有挑战性的问题。 ***拟议的研究将有利于能源整合、可再生能源发电和转换器支持的微电网等快速增长领域的多个研究领域预计工业界和科学家，特别是电力和运输部门将从该项目的成果中受益。由于能源利用效率的提高，人民和政策制定者将在经济上受益。由于 GHE 显着减少，所有加拿大人都可以从改善的空气质量中受益，从而获得更好的生活质量。***拟议的研究将直接支持 5 名研究生的培训。此外，每年还将有 2-3 名高年级本科生（四年级）接受该项目各个方面的培训。参与的学生将培养电力电子电路、控制系统、电力电子仿真工具和基于 FPGA 的数字控制技术的高级设计的研究技能。