介绍分布式测试基础设施,以便在多个远程实验室进行联合实验,大力开发新的区域供热概念

IF 5.4 Q2 ENERGY & FUELS Smart Energy Pub Date : 2024-08-01 DOI:10.1016/j.segy.2024.100152
Lilli Frison , Urs Gumbel , Simone Steiger , Herbert Sinnesbichler , Benedikt Ahrens , Dennis Lottis , Matthias Wecker , Anna Marie Cadenbach
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引用次数: 0

摘要

第四代区域供热网络面临着众多挑战,例如整合分散的可再生能源、双向热传递、新的存储概念、低温运行、定制供热、数据管理和先进的控制策略。实验室和硬件在环测试为测试和验证这些创新提供了一个安全、经济高效的环境。本文介绍了在多个远程实验室进行联合实验的框架,以加强对区域供热系统组件的测试。这种分布式测试平台通过利用各实验室的现有设备和专业知识,提高了测试效率,从而降低了成本和时间,并允许对更多场景进行测试。它以制造商、电网运营商和研究机构为目标,促进实验室合作,在实地部署前进行技术测试。这种方法允许采用不同的测试场景,在没有相同硬件或软件的情况下考虑不同地点的组件互动。该框架的功效体现在四个弗劳恩霍夫研究所的低温区域供热网络的概念验证中。最初的实验将测试楼和地源热泵与区域供热网络和地热源的仿真模型连接起来,测试楼和地源热泵实际存在于不同的实验室中。为期三周的运行结果验证了该框架的性能。
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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Presentation of a distributed testing infrastructure for joint experiments across multiple remote laboratories for robust development of new district heating concepts

4th-generation district heating networks confront numerous challenges such as integrating decentralized renewable energy sources, bidirectional heat transfer, new storage concepts, low-temperature operation, custom heat supply, data management, and advanced control strategies. Laboratory and hardware-in-the-loop testing offer a safe, cost-effective environment for testing and validating these innovations. This paper presents a framework for joint experiments in multiple remote laboratories, enhancing the testing of district heating system components. This distributed testbed enhances the efficiency of testing by utilizing existing equipment and expertise from various laboratories, thereby reducing costs and time and allowing for more scenarios to test. It targets manufacturers, grid operators, and research institutions, facilitating collaborative lab work for technology testing before field deployment. This approach allows for diverse test scenarios, considering component interactions across different locations without identical hardware or software. The framework's efficacy is shown in a proof-of-concept with a low-temperature district heating network integrated across four Fraunhofer Institutes. An initial experiment connects a test building and a ground-source heat pump physically existing in different labs with emulated models of a district heating network and a geothermal source. Results from a three-week operation validate the framework's performance.

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来源期刊
Smart Energy
Smart Energy Engineering-Mechanical Engineering
CiteScore
9.20
自引率
0.00%
发文量
29
审稿时长
73 days
期刊最新文献
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