Towards the Integration of Modern Power Systems into a Cyber–Physical Framework

George C Konstantopoulos,Panos C Papageorgiou,Antonio T Alexandridis

doi:10.3390/en13092169

George C Konstantopoulos, Panos C Papageorgiou + Show 1 more

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https://doi.org/10.3390/en13092169

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Journal: Energies	Publication Date: May 1, 2020
Citations: 18	License type: CC BY 4.0

Affiliation: University of Patras, University of Sheffield

Abstract

The cyber–physical system (CPS) architecture provides a novel framework for analyzing and expanding research and innovation results that are essential in managing, controlling and operating complex, large scale, industrial systems under a holistic insight. Power systems constitute such characteristically large industrial structures. The main challenge in deploying a power system as a CPS lies on how to combine and incorporate multi-disciplinary, core, and advanced technologies into the specific for this case, social, environmental, economic and engineering aspects. In order to substantially contribute towards this target, in this paper, a specific CPS scheme that clearly describes how a dedicated cyber layer is deployed to manage and interact with comprehensive multiple physical layers, like those found in a large-scale modern power system architecture, is proposed. In particular, the measurement, communication, computation, control mechanisms, and tools installed at different hierarchical frames that are required to consider and modulate the social/environmental necessities, as well as the electricity market management, the regulation of the electric grid, and the power injection/absorption of the controlled main devices and distributed energy resources, are all incorporated in a common CPS framework. Furthermore, a methodology for investigating and analyzing the dynamics of different levels of the CPS architecture (including physical devices, electricity and communication networks to market, and environmental and social mechanisms) is provided together with the necessary modelling tools and assumptions made in order to close the loop between the physical and the cyber layers. An example of a real-world industrial micro-grid that describes the main aspects of the proposed CPS-based design for modern electricity grids is also presented at the end of the paper to further explain and visualize the proposed framework.

Highlights

The transition from the conventional electricity grid towards the ‘smart grid’ has introduced continuous advancements in the electrical network infrastructure and the constant deployment of new emerging monitoring, communication, computation, and control technologies in order to enhance grid stability, reliability, resilience, and efficiency
Due to the integration of multiple heterogeneous players and factors within the smart grid architecture, government bodies and policy-regulation authorities have expressed an interest in a whole-system approach in modern power networks in order to capture the complex interaction across different layers
It can capture the dynamic interactions between heterogeneous components within a given layer, e.g., between different structures and operating principles introduced by distributed energy resources (DERs), as well as the cross-layer interactions between the different components, systems, and architectures, i.e., linking the physical system units with the control and communication mechanisms

Summary

Introduction

The transition from the conventional electricity grid towards the ‘smart grid’ has introduced continuous advancements in the electrical network infrastructure (e.g., the large integration of distributed generation units, new grid interconnections, and energy islands) and the constant deployment of new emerging monitoring, communication, computation, and control technologies in order to enhance grid stability, reliability, resilience, and efficiency. Government’s Clean Growth Strategy and National Grid have highlighted how a whole system view of the electricity industry can significantly increase the consumer and societal value [9] In this framework, the CPS perspective in smart grids can be utilized to analyze how a change/modification or a decision made in the physical world affects the operation of the cyber world and vice versa. The CPS perspective in smart grids can be utilized to analyze how a change/modification or a decision made in the physical world affects the operation of the cyber world and vice versa It can capture the dynamic interactions between heterogeneous components within a given layer, e.g., between different structures and operating principles introduced by distributed energy resources (DERs), as well as the cross-layer interactions between the different components, systems, and architectures, i.e., linking the physical system units with the control and communication mechanisms. In local energy systems or micro-grids, a CPS-based approach has been proposed to investigate intelligent micro-grid modelling and control aspects [11,12,13], micro-grid system security and resilience [14,15], and the development of real-time co-simulation testbeds [16,17]

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