Abstract
Interoperability testing is widely recognized as a key to achieve seamless interoperability of smart grid applications, given the complex nature of modern power systems. In this work, the interoperability testing methodology proposed by the European Commission Joint Research Centre is applied to a specific use case in the context of smart grids. The selected use case examines a flexibility activation mechanism in a power grid system and includes DSO SCADA, Remote Terminal Unit and flexibility source, interacting to support a voltage regulation service. The adopted test bed consists of a real-time power grid simulator, a communication network emulator and use case actors’ models in a hardware-in-the-loop setup. The breakdown of the interoperability testing problem is accomplished by mapping the use case to the SGAM layers, specifying the Basic Application Profiles together with the Basic Application Interoperability Profiles (BAIOPs) and defining the design of experiments to carry out during the laboratory testing. Furthermore, the concepts of inter- and intra-BAIOP testing are formalized to reflect complementary interests of smart grid stakeholders. Experimental results prove the applicability of the methodology for testing the interoperability of large-scale and complex smart grid systems and reveal interesting features and possible pitfalls which should be considered when investigating the parameters responsible for the disruption of a system interoperability.
Highlights
To meet climate change and energy policy objectives, a major transformation of the electricity infrastructure is required
It is noteworthy that these conclusions are bound to the modelling environment and the assumptions used in this use case (UC) in order to set the boundaries for the IOP testing
Given the difficulty of the IOP testing problem, in this research work a lot of attention has been put on the application of methodological aspects formalized in the JRC-Smart Grid Interoperability Laboratory (SGILab) methodology report [10], namely (1) UC creation, (2) Basic Application Profiles (BAPs) and (3) Basic Application Interoperability Profiles (BAIOPs) definition, (4) Design of the Experiments (DoE) procedure, the latter applied in the UC under study since several parameters can change and affect the system functionality under an IOP point of view
Summary
To meet climate change and energy policy objectives, a major transformation of the electricity infrastructure is required. The current energy infrastructure will have to become more flexible, requiring the establishment of data communications among all actors (industrial and end users). In such a case, it is necessary to guarantee that all components work together seamlessly, i.e., they are ‘interoperable’. According to [2], IOP can be defined as the “ability of two or more networks, systems, devices, applications, or components to interwork, to exchange and use information in order to perform required functions”. In this regard, IOP was identified from the very beginning
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