{"title":"矿山电气化与电力电子:宽带隙器件的作用","authors":"Nesimi Ertuğrul","doi":"10.1109/MELE.2023.3348254","DOIUrl":null,"url":null,"abstract":"In the rugged terrains of traditional mining, a revolutionary shift is taking place, driven by the desire to achieve net-zero targets and respond to multiple challenges, primarily health issues and operational inefficiencies. The electrification of mining operations depends upon the integration of advanced power electronics (PEs) and wide-bandgap (WBG) devices, which serve as the enabling technology by efficiently converting and controlling electrical power, ensuring not only energy savings and reduced emissions but also robust, reliable systems. In the meantime, the mining sector is evolving into a key player in grid modernization, driven by an increase in distributed energy resources (DERs), the need for energy efficiency, and the growing interconnectedness and digitization of power systems. This modernization is critical for ensuring grid resiliency and security, particularly in the face of potential cyberthreats. As mining operations move toward full electrification, elements such as renewable energy, energy storage, microgrids, electric mobility, and digitization play a central role, with autonomous dc microgrids emerging as a viable solution to ensure reliability and safety in both the power grid and mining sites. Therefore, WBG device-based PEs are pivotal in mining transition by offering advanced control, energy management, and protection required for efficient grids, devices, and machineries. In addition, WBG devices’ exceptional characteristics, such as high-efficiency, high-power, and high-frequency capabilities and higher temperature tolerance are ideal for mining applications, specifically in large-scale mining machinery that demands significant electric energy. The outcome is reduced energy consumption, enhanced reliability, and the development of more compact machinery designs with less waste heat, diminishing the need for extensive cooling systems.","PeriodicalId":45277,"journal":{"name":"IEEE Electrification Magazine","volume":null,"pages":null},"PeriodicalIF":2.5000,"publicationDate":"2024-03-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Mine Electrification and Power Electronics: The roles of wide-bandgap devices\",\"authors\":\"Nesimi Ertuğrul\",\"doi\":\"10.1109/MELE.2023.3348254\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"In the rugged terrains of traditional mining, a revolutionary shift is taking place, driven by the desire to achieve net-zero targets and respond to multiple challenges, primarily health issues and operational inefficiencies. 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引用次数: 0
摘要
在传统采矿业的崎岖地形中,正在发生一场革命性的转变,其驱动力是实现净零目标和应对多重挑战,主要是健康问题和运营效率低下。采矿作业的电气化取决于先进的电力电子设备(PE)和宽带隙设备(WBG)的集成,这些设备通过有效地转换和控制电能,成为使能技术,不仅能确保节能减排,还能确保系统稳健可靠。与此同时,在分布式能源资源(DER)增加、能源效率需求以及电力系统互联化和数字化程度不断提高的推动下,采矿业正逐渐成为电网现代化的重要参与者。这种现代化对于确保电网的弹性和安全性至关重要,尤其是在面对潜在的网络威胁时。随着采矿作业朝着全面电气化的方向发展,可再生能源、储能、微电网、电动移动性和数字化等要素发挥着核心作用,其中自主直流微电网已成为确保电网和采矿现场可靠性和安全性的可行解决方案。因此,基于 WBG 设备的 PE 可提供高效电网、设备和机械所需的先进控制、能源管理和保护功能,在采矿业转型过程中具有举足轻重的作用。此外,WBG 设备还具有高效率、高功率、高频率和更高的温度耐受性等优异特性,非常适合采矿应用,尤其是需要大量电能的大型采矿机械。其结果是降低了能耗,提高了可靠性,并开发出了废热更少、结构更紧凑的机械设计,从而减少了对大量冷却系统的需求。
Mine Electrification and Power Electronics: The roles of wide-bandgap devices
In the rugged terrains of traditional mining, a revolutionary shift is taking place, driven by the desire to achieve net-zero targets and respond to multiple challenges, primarily health issues and operational inefficiencies. The electrification of mining operations depends upon the integration of advanced power electronics (PEs) and wide-bandgap (WBG) devices, which serve as the enabling technology by efficiently converting and controlling electrical power, ensuring not only energy savings and reduced emissions but also robust, reliable systems. In the meantime, the mining sector is evolving into a key player in grid modernization, driven by an increase in distributed energy resources (DERs), the need for energy efficiency, and the growing interconnectedness and digitization of power systems. This modernization is critical for ensuring grid resiliency and security, particularly in the face of potential cyberthreats. As mining operations move toward full electrification, elements such as renewable energy, energy storage, microgrids, electric mobility, and digitization play a central role, with autonomous dc microgrids emerging as a viable solution to ensure reliability and safety in both the power grid and mining sites. Therefore, WBG device-based PEs are pivotal in mining transition by offering advanced control, energy management, and protection required for efficient grids, devices, and machineries. In addition, WBG devices’ exceptional characteristics, such as high-efficiency, high-power, and high-frequency capabilities and higher temperature tolerance are ideal for mining applications, specifically in large-scale mining machinery that demands significant electric energy. The outcome is reduced energy consumption, enhanced reliability, and the development of more compact machinery designs with less waste heat, diminishing the need for extensive cooling systems.
期刊介绍:
IEEE Electrification Magazine is dedicated to disseminating information on all matters related to microgrids onboard electric vehicles, ships, trains, planes, and off-grid applications. Microgrids refer to an electric network in a car, a ship, a plane or an electric train, which has a limited number of sources and multiple loads. Off-grid applications include small scale electricity supply in areas away from high voltage power networks. Feature articles focus on advanced concepts, technologies, and practices associated with all aspects of electrification in the transportation and off-grid sectors from a technical perspective in synergy with nontechnical areas such as business, environmental, and social concerns.