Advanced Testing Chain Supporting the Validation of Smart Grid Systems and Technologies

2018 IEEE Workshop on Complexity in Engineering (COMPENG) Pub Date : 2018-10-01 DOI:10.1109/CompEng.2018.8536223

R. Brandl, P. Kotsampopoulos, G. Lauss, Marios Maniatopoulos, M. Nuschke, Juan Montoya, T. Strasser, Diana Strauss-Mincu

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引用次数: 8

Abstract

New testing and development procedures and methods are needed to address topics like power system stability, operation and control in the context of grid integration of rapidly developing smart grid technologies. In this context, individual testing of units and components has to be reconsidered and appropriate testing procedures and methods need to be described and implemented. This paper addresses these needs by proposing a holistic and enhanced testing methodology that integrates simulation/software- and hardware-based testing infrastructure. This approach presents the advantage of a testing environment, which is very close to field testing, includes the grid dynamic behavior feedback and is risks-free for the power system, for the equipment under test and for the personnel executing the tests. Furthermore, this paper gives an overview of successful implementation of the proposed testing approach within different testing infrastructure available at the premises of different research institutes in Europe.

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支持智能电网系统和技术验证的先进测试链

在快速发展的智能电网技术并网的背景下，需要新的测试和开发程序和方法来解决电力系统稳定性、运行和控制等问题。在这种情况下，必须重新考虑单元和部件的单独测试，并需要描述和实施适当的测试程序和方法。本文通过提出一种综合的、增强的测试方法来解决这些需求，该方法集成了基于仿真/软件和硬件的测试基础设施。这种方法的优点是提供了一个非常接近现场测试的测试环境，包括电网动态行为反馈，并且对电力系统、被测设备和执行测试的人员没有风险。此外，本文概述了在欧洲不同研究机构的前提下，在不同的测试基础设施中成功实施所提出的测试方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2018 IEEE Workshop on Complexity in Engineering (COMPENG)

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