Grid Technologies(网格技术)研究综述
Grid Technologies 网格技术 - This study will help in building local manufacturing facilities and enhance rural electrification through off-grid technologies. [1] EVs have been gradually commercially viable and considerable focus has been paid to vehicle-to-grid technologies. [2] The findings of the research show that: in Thailand, the desired microgrid technologies are compatible with 1) inputs of potential local renewable energy resources of solar, wind, biomass, and mini-hydro, and 2) small gaps of human resource capabilities to deal with the technology utilization. [3] Objectives The aim of the MEDIGRID project is to explore the use of the GRID technologies for tackling the processing of huge medical image databases available in the hospitals today. [4] Broadly, this research finds that public power utilities with microgrid technologies have taken an incremental design approach that has not typically started with an explicit plan to island the system. [5] The pressure of climate change and the need to adopt renewable energy sources (RES) have led to an increased development of microgrid technologies. [6] The concepts and technologies from computer science to handle these large amounts of data include (a) grid technologies for compute parallelization while making more efficient use of existing low-cost infrastructure; (b) graphics cards for increased compute power and (c) graph databases for large data volume storage and advanced methods for analyses. [7]这项研究将有助于建设当地制造设施,并通过离网技术加强农村电气化。 [1] 电动汽车已逐渐在商业上可行,并且相当重视车辆到电网技术。 [2] 研究结果表明:在泰国,所需的微电网技术与 1) 太阳能、风能、生物质能和小型水电等当地潜在可再生能源的投入兼容,以及 2) 人力资源能力的小差距随着技术的运用。 [3] 目标 MEDIGRID 项目的目的是探索使用 GRID 技术来处理当今医院可用的庞大医学图像数据库的处理。 [4] 总的来说,这项研究发现,采用微电网技术的公共电力公司采取了渐进式设计方法,这种设计方法通常不是从明确的系统孤岛计划开始的。 [5] 气候变化的压力和采用可再生能源 (RES) 的需求导致了微电网技术的不断发展。 [6] 处理这些大量数据的计算机科学的概念和技术包括 (a) 用于计算并行化的网格技术,同时更有效地利用现有的低成本基础设施; (b) 用于提高计算能力的图形卡和 (c) 用于大数据量存储和高级分析方法的图形数据库。 [7]
Smart Grid Technologies 智能电网技术
Transmitting electricity through the air gap for charging using electromagnetic waves as one of the smart grid technologies called Wireless Power Transfer (WPT), or Inductive Power Transfer. [1] The global experience shows that the best potential outcome from smart grid technologies largely relies on the customers’ readiness and adoption. [2] Current imaginaries of urban smart grid technologies are painting attractive pictures of the kinds of energy futures that are desirable and attainable in cities. [3] This market is expected to grow in the development of smart grid technologies, renewable energy generation and initiatives to modernize the transmission and distribution system. [4] The goal is to develop a methodology for modeling electric power supply systems for railways equipped with a complex of devices implemented using smart grid technologies. [5] According to future renewable electric energy distribution and management (FREEDM) system, solid state transformers play an important role in smart grid technologies. [6] Modern power grid is experiencing an increased influx of smart grid technologies in enhancing the reliability of its operations, by providing improved communication and real-time control capabilities. [7] Smart grid technologies can integrate multiple renewable energy technologies, which possess significant potential in reducing carbon emissions. [8] The growing participation of distributed generation in the electricity supply along with the advances in smart grid technologies have emphasized the active role of distribution systems and their more complex interaction with the transmission system. [9] With the development of smart grid technologies an increasing number of new devices and participants have joined modern energy systems and are inevitably making them more complicated and interdependent than ever. [10] Also, excursions and site visits to real-life visits of some of the smart grid technologies are organized, as well as internships for some of the students. [11] Emerging smart grid technologies and increased penetration of renewable energy sources (RESs) direct the power sector to focus on RESs as an alternative to meet both baseload and peak load demands in a cost-efficient way. [12] Although smart grid technologies bring about valuable economic, social, and environmental benefits, testing the combination of heterogeneous and co-existing Cyber-Physical-Smart Grids (CP-SGs) with conventional technologies presents many challenges. [13] An increasing deployment of smart grid technologies and demand response programs has enabled demands to be more elastic in response to electricity prices, actively contributing to power system operation. [14] Nowadays, the electrical utilities are concentrating more on smart grid technologies in order to attain reliable, secure and profitable power system operation. [15] In contrast, we compare two waves of survey data on the social acceptance of smart grid technologies, the first (n = 609) prior to a local rollout of a smart grid program in upstate New York and the second (n = 533) two years after the same rollout. [16] Advances in intelligent transportation systems and smart grid technologies offer great promise to widely popularize electric vehicles, and have the potential to revolutionize urban transportation systems and power systems. [17] Smart grid technologies is the key to use energy resources efficiently distributed. [18] In this review paper mostly discusses Smart grid technologies nowadays' phasor measurement units (PMUs) uses and its role in the modern power grid increases. [19] This paper discusses select lessons learned from the power blackout and presents future opportunities to improve power system reliability and resilience for the grids in Amapá, and other similar Brazilian states, with a special focus on the increasingly important role of of distributed energy resources and smart grid technologies. [20] An analysis is carried out in the use of renewable and non- traditional energy sources using smart grid technologies. [21] Optimisation and modelling can reveal viable pathways to a sustainable energy system, aiding strategic planning for upgrades and policy-making for accelerated integration of renewable energy generation and smart grid technologies such as battery storage in Africa. [22] Potential implementation of smart grid technologies has been given wide attention for modernization of electrical power systems. [23] Home Energy Management Systems (HEMSs) are expected to become an inevitable part of the future smart grid technologies. [24] This paper concentrates on the organizational and communication aspects of development of the smart grid technologies. [25] In recent years, the development of lithium-ion batteries (LIBs) with high energy density has become one of the important research directions to fulfill the needs of electric vehicles and smart grid technologies. [26] With the advent of smart grid technologies, modern Distribution Management Systems (DMSs) enable the real-time operation of advanced automation functions such as Coordinated Volt/VAr Control (CVVC). [27] Battery technology is a key component in current electric vehicle applications and an important building block for upcoming smart grid technologies. [28] So that, many smart grid technologies have been proposed to overcome these problems. [29] This paper introduces current smart grid technologies and their impacts on the efficiency increment in a power system. [30] the EU Clean Energy Package) that state the rights and obligations of Local Energy Communities (LECs), time had come for smart grid technologies to show that they can comply with the complexity of the new regulatory environment when optimising LEC energy exchanges. [31] This paper investigates how the strategic decisions of innovative firms to collaborate with other firms in research and development projects shape the early evolution of smart grid technologies as an emerging technological system across Europe. [32] Recent advances in smart grid technologies bring opportunities to better control the modern and complex power grids with renewable integration. [33] First, we show how organisations’ existing roles, rules, norms, and beliefs are being challenged (or not) through the rise of smart grid technologies and what contestations have arisen within the smart grid field. [34] In this paper, MOR techniques are applied to quantify relevant reliability metrics of power distribution systems and the impact associated with the integration of different smart grid technologies. [35] Thanks to Smart Grid technologies, specifically to the Advance Metering Infrastructure at secondary distribution network, this impact can be evaluated even at the customer level. [36] ), new smart grid technologies are being deployed over distribution networks. [37] Emerging smart grid technologies pose new challenges and opportunities. [38] Distributed generation of electric energy using renewable sources requires connection to Smart Grid technologies for integration into the electric network. [39] The massive and unprecedented deployment of smart grid technologies, new business models, and involvement of new stakeholders enable NMGs to be a conceptual operation paradigm for future distribution systems. [40] Load forecasting is the main exploration field in the smart grid technologies. [41] Smart grid technologies are deepening the interdependence of electric power and communication systems, but that interdependence is difficult to quantify. [42] 6 billion in state-of-the-art smart grid technologies to prepare the grid to mitigate and adapt to emerging climate change. [43] These drivers are advancing the growth of distributed energy resources, application of smart grid technologies, and the deployment of renewable and natural gas-fired generation that challenges the future of nuclear generation. [44] With the proliferation of enabling smart grid technologies, industries are increasingly looking to reduce their electricity costs through the adoption of renewable energy sources and efficient load management strategies. [45] Smart grid technologies have attracted the attention of industry and academia in the last few years. [46] Much remains uncertain about the social relations and practices emerging around novel smart grid technologies and their contribution to sustainability. [47] The continued rise of renewable energy sources (RES) and distributed generation (DG) necessitate and support the invention of smart grid technologies, among which communication and remote control are keystone features. [48] The latest development of smart grid technologies gives rise to big load data and requires load pattern categorization (LPC). [49] Smart grid technologies, such as distributed energy resources (DERs) and microgrids, provide both opportunities and challenges for distribution system restoration. [50]通过气隙传输电力以使用电磁波进行充电,这是一种智能电网技术,称为无线电力传输 (WPT) 或感应式电力传输。 [1] 全球经验表明,智能电网技术的最佳潜在成果在很大程度上取决于客户的准备情况和采用情况。 [2] 当前对城市智能电网技术的想象正在描绘城市中理想和可实现的各种能源未来的有吸引力的画面。 [3] 预计该市场将随着智能电网技术、可再生能源发电和输配电系统现代化举措的发展而增长。 [4] 目标是开发一种方法,用于为配备了使用智能电网技术实现的复杂设备的铁路供电系统建模。 [5] 根据未来可再生电能分配和管理(FREEDM)系统,固态变压器在智能电网技术中发挥着重要作用。 [6] 现代电网正在经历越来越多的智能电网技术,通过提供改进的通信和实时控制能力来提高其运行的可靠性。 [7] 智能电网技术可以整合多种可再生能源技术,在减少碳排放方面具有巨大潜力。 [8] 随着智能电网技术的进步,分布式发电越来越多地参与电力供应,强调了配电系统的积极作用及其与输电系统的更复杂的相互作用。 [9] 随着智能电网技术的发展,越来越多的新设备和参与者加入了现代能源系统,并且不可避免地使它们比以往任何时候都更加复杂和相互依赖。 [10] 此外,还组织了一些智能电网技术的短途旅行和实地考察,以及一些学生的实习。 [11] 新兴的智能电网技术和可再生能源 (RES) 的日益普及使电力部门将重点放在可再生能源上,作为以具有成本效益的方式满足基本负荷和峰值负荷需求的替代方案。 [12] 尽管智能电网技术带来了宝贵的经济、社会和环境效益,但测试异构和共存的网络-物理-智能电网 (CP-SG) 与传统技术的组合带来了许多挑战。 [13] 智能电网技术和需求响应计划的日益部署使需求对电价的响应更具弹性,为电力系统的运行做出了积极贡献。 [14] 如今,电力公司越来越关注智能电网技术,以实现可靠、安全和有利可图的电力系统运行。 [15] 相比之下,我们比较了两波关于智能电网技术社会接受度的调查数据,第一波 (n = 609) 在纽约州北部本地推出智能电网计划之前,第二波 (n = 533) 两年在相同的推出之后。 [16] 智能交通系统和智能电网技术的进步为电动汽车的广泛普及提供了广阔的前景,并有可能彻底改变城市交通系统和电力系统。 [17] 智能电网技术是高效利用分布式能源的关键。 [18] 在这篇评论文章中,主要讨论了当今智能电网技术的相量测量单元 (PMU) 的使用及其在现代电网中的作用增加。 [19] 本文讨论了从停电中吸取的一些经验教训,并提出了提高阿马帕和其他巴西类似州电网的电力系统可靠性和弹性的未来机会,特别关注分布式能源和智能电网的日益重要的作用技术。 [20] 使用智能电网技术对可再生能源和非传统能源的使用进行了分析。 [21] 优化和建模可以揭示可持续能源系统的可行途径,有助于升级战略规划和加速整合可再生能源发电和智能电网技术(如非洲电池存储)的政策制定。 [22] 对于电力系统的现代化,智能电网技术的潜在实施已受到广泛关注。 [23] 家庭能源管理系统 (HEMS) 有望成为未来智能电网技术的必然组成部分。 [24] 本文集中于智能电网技术发展的组织和通信方面。 [25] 近年来,开发高能量密度锂离子电池(LIBs)已成为满足电动汽车和智能电网技术需求的重要研究方向之一。 [26] 随着智能电网技术的出现,现代配电管理系统 (DMS) 能够实时运行高级自动化功能,例如协调电压/无功控制 (CVVC)。 [27] 电池技术是当前电动汽车应用的关键组成部分,也是即将推出的智能电网技术的重要组成部分。 [28] 因此,已经提出了许多智能电网技术来克服这些问题。 [29] 本文介绍了当前的智能电网技术及其对电力系统效率增量的影响。 [30] 欧盟清洁能源一揽子计划)规定了地方能源社区 (LEC) 的权利和义务,现在是时候让智能电网技术证明它们在优化 LEC 能源交换时能够遵守新监管环境的复杂性。 [31] 本文研究了创新公司与其他公司在研发项目中合作的战略决策如何塑造智能电网技术作为欧洲新兴技术系统的早期发展。 [32] 智能电网技术的最新进展为通过可再生能源整合更好地控制现代复杂电网带来了机会。 [33] 首先,我们展示了组织的现有角色、规则、规范和信念如何通过智能电网技术的兴起受到挑战(或不受挑战),以及智能电网领域出现了哪些争论。 [34] 在本文中,MOR 技术用于量化配电系统的相关可靠性指标以及与不同智能电网技术集成相关的影响。 [35] 由于智能电网技术,特别是二次配电网络的高级计量基础设施,这种影响甚至可以在客户层面进行评估。 [36] ),新的智能电网技术正在配电网络上部署。 [37] 新兴的智能电网技术带来了新的挑战和机遇。 [38] nan [39] nan [40] nan [41] nan [42] nan [43] 这些驱动因素正在推动分布式能源资源的增长、智能电网技术的应用,以及对核能发电未来构成挑战的可再生能源和天然气发电的部署。 [44] 随着智能电网技术的普及,各行业越来越希望通过采用可再生能源和高效的负载管理策略来降低电力成本。 [45] 智能电网技术在过去几年引起了工业界和学术界的关注。 [46] 对于围绕新型智能电网技术出现的社会关系和实践及其对可持续性的贡献,仍有很多不确定性。 [47] 可再生能源 (RES) 和分布式发电 (DG) 的持续兴起需要并支持智能电网技术的发明,其中通信和远程控制是其关键特征。 [48] 智能电网技术的最新发展产生了大负荷数据,需要负荷模式分类(LPC)。 [49] 分布式能源 (DER) 和微电网等智能电网技术为配电系统恢复提供了机遇和挑战。 [50]
Future Grid Technologies
As a power network isolated from neighboring countries, the electricity infrastructure in South Korea (also called the Republic of Korea) requires a high level of preparation for adopting future grid technologies. [1] With the rapid development of future grid technologies such as smart grid and energy internet, power electronic transformers with various functions such as voltage transformation, electrical isolation, power regulation and control, and renewable energy access can be realized. [2]作为与邻国隔离的电网,韩国(也称为大韩民国)的电力基础设施需要为采用未来的电网技术做好高水平的准备。 [1] 随着智能电网、能源互联网等未来电网技术的快速发展,可以实现具有变压、电气隔离、电力调控、可再生能源接入等多种功能的电力电子变压器。 [2]
Power Grid Technologies
The characteristics of various power grid technologies and grid communication business models in China are analyzed. [1] As power grid technologies evolve in conjunction with measurement and communication technologies, this results in unprecedented amount of heterogeneous big data. [2]分析了我国各种电网技术和电网通信商业模式的特点。 [1] nan [2]
grid technologies provide
Traditional meter inspection techniques are not effective in detecting NTL, while the wide adoption of smart meters and smart grid technologies provide new opportunities for solving the problem. [1] Nowadays, novel smart grid technologies provide more flexible ways for the power system operation. [2] Smart grid technologies provide an effective utilization of customer load profiles. [3]传统的电表检测技术在检测 NTL 方面效果不佳,而智能电表和智能电网技术的广泛采用为解决这一问题提供了新的机会。 [1] 如今,新型智能电网技术为电力系统运行提供了更加灵活的方式。 [2] nan [3]
grid technologies without
It also examines the best way to make the transition from the present rural distribution network to a new electric operational framework by using Smart Grid technologies without losing sight of the corresponding associated new business concepts and being respectful with the environment. [1] Owing to its great flexibility and ease of implementation, BEB has been extended to home M2M communication such as wireless sensor networks and smart grid technologies without relying on wide area communication. [2]它还研究了通过使用智能电网技术从当前的农村配电网络过渡到新的电力运营框架的最佳方式,同时又不忽视相应的相关新业务概念并尊重环境。 [1] 由于具有极大的灵活性和易于实施的特点,BEB已经扩展到家庭M2M通信,例如无线传感器网络和智能电网技术,而不依赖于广域通信。 [2]
grid technologies bring 网格技术带来
Although smart grid technologies bring about valuable economic, social, and environmental benefits, testing the combination of heterogeneous and co-existing Cyber-Physical-Smart Grids (CP-SGs) with conventional technologies presents many challenges. [1] Recent advances in smart grid technologies bring opportunities to better control the modern and complex power grids with renewable integration. [2]尽管智能电网技术带来了宝贵的经济、社会和环境效益,但测试异构和共存的网络-物理-智能电网 (CP-SG) 与传统技术的组合带来了许多挑战。 [1] 智能电网技术的最新进展为通过可再生能源整合更好地控制现代复杂电网带来了机会。 [2]