Low-carbon solutions power system integration

Background and context

The European power system is on the critical path to meet the EU’s climate change and energy policy objectives. The main challenge is the power system integration of very large amounts of variable renewable energy sources, especially wind and solar, while keeping overall system reliability at acceptable levels, in a liberalised context. 

With the unprecedented deployment of low-carbon technologies for electricity generation, storage solutions are expected to play an important role.

Grid connected energy storage systems are regarded as promising solutions for providing ancillary services to electricity networks and to play an important role in the development of smart grids.

Thus far, the more mature battery technologies have been installed in pilot projects and studies have indicated their main advantages and shortcomings. 

Our role

Against this background, we are monitoring the challenges for redesigning the European electricity systems and assessing options for the systemic integration of low-carbon solutions in the European electricity grids. More in detail, we are conducting targeted research on

  • renewable solutions integration into the power systems. We developed a methodology for supporting decision makers in identifying the most suitable spots for offshore wind farm connections.
  • storage solutions integration into new power system architectures. The main concerns for wide adoption are the overall cost, the limited number of charging cycles (or lifetime), the depth of discharge, the low energy density and the sustainability of materials used.
  • renewable, storage and EV solutions integration into new power system architectures.

 

2017 - Multi-criteria selection of offshore wind farms: Case study for the Baltic States

This paper (whose results can be also checked via this interactive map) presents a multi-criteria selection approach for offshore wind sites assessment. The proposed site selection framework takes into consideration the following aspects: electricity network security conditions, economic investments, operation costs and capacity performances relative to each potential site.

The selection decision is made through the Analytic Hierarchy Process, allowing end users to adjust the expected benefits according to their respective and global priorities. The proposed site selection framework is implemented as an interactive case study for three Baltic States in the 2020 time horizon, based on real data and extensive power network models, taking into consideration the foreseen upgrades and network reinforcements.

For each country the optimal offshore wind sites are assessed under multiple weight contribution scenarios, reflecting the characteristics of market design, regulatory aspects or renewable integration targets.

2016 - Support to renewable energy integration in Cyprus

This report describes the main results of the assistance project we carried out (along with DG SRSS and ENER) to support the Cyprus government to assess the current state of the transmission and distribution electricity systems and propose solutions for increasing the amount of Renewable Energy Sources generation that can be fed on the electricity system.

The main objective of the project was to help the Cyprus Government to establish a comprehensive medium- to long-term policy for the optimum penetration of renewable energy in the electricity system until 2030.

The project was divided in four activities which are tightly interlinked and correlated, spanning from system characterisation, to transmission/distribution simulation up to market analyses, with a view to perform an integrated assessment of the Cyprus electricity system (power infrastructure and markets).

 

2016 - Assessment framework for EV and PV synergies in emerging distribution systems

This paper proposes a conceptual architecture and an assessment framework to explore how high penetration scenarios of electric vehicles and intermittent renewable generation can complement each other in emerging distribution networks. We start from the identification of the smart grid functionalities to be implemented in a system with distributed power injections under the need to supervise and coordinate myriads of decentralized and interoperable energy sources and actors. Relying upon the proposed smart grid conceptual architecture, we develop an assessment framework to maximize the renewable electricity and electric vehicle penetration for given electricity and transport systems. The application of the proposed assessment framework to a realistic case study, representing the distribution and mobility systems of a typical mid-size Italian city, illustrates how some of the limitations and constraints of the current electricity network operation and design approaches can be addressed and overcome. We show how integration of substantial amounts of energy production and electric-based transport technologies can be achieved while improving the reliability and sustainability performances of the emerging power systems.

2016 - Smart grid energy storage controller for frequency regulation and peak shaving

This paper presents a model using MATLAB/Simulink, to demonstrate how a Vanadium Redox Flow Battery (VRFB) device can provide multi-ancillary services, focusing on frequency regulation and peak-shaving functions. Vanadium Redox Flow Batteries (VRFB) are a promising option to mitigate many of these shortcomings, and demonstration projects using this technology are being implemented both in Europe and in the USA. The study presents a storage system at a medium voltage substation and considers a small grid load profile, originating from a residential neighbourhood and fast charging stations demand. The model also includes an inverter controller that provides a net power output from the battery system, in order to offer both services simultaneously.

Simulation results show that the VRFB storage device can regulate frequency effectively due to its fast response time, while still performing peak-shaving services. VRFB potential in grid connected systems is discussed to increase awareness of decision makers, while identifying the main challenges for wider implementation of storage systems, particularly related to market structure and standardisation requirements.

2015 - Market Integration Scheme of a Multi-Terminal HVDC Grid in the North Seas

This paper examines the market integration of a centrally dispatched multi-terminalHVDC Grid based on droop control.

The development of a multi-terminal high voltage DC (HVDC) grid based on voltage source converter (VSC) technology has been envisaged as a key development for harnessing the vast offshore wind production potential of the North Seas. 

Particular emphasis is given on the management of onshore imbalance volumes due to offshore wind power forecast errors. The economic importance of the control choices of the operator of such an active transmission grid is highlighted, and regulatory implications are briefly discussed.

The main contribution of the paper is the coherent development of a droop-controlled MT HVDC grid scheme that integrates optimal power flow (OPF) dispatch, and imbalance volume management.

2013 - Characterisation of electrical energy storage technologies

This paper provides a qualitative methodology to select the appropriate technology or mix of technologies for different applications. The multiple comparisons according to different characteristics distinguish this paper from others about energy storage systems. Firstly, the different technologies available for energy storage, as discussed in the literature, are described and compared.

The characteristics of the technologies are explained, including their current availability. In order to gain a better perspective, availability is cross-compared with maturity level. Moreover, information such as ratings, energy density, durability and costs is provided in table and graphic format for a straightforward comparison.

Additionally, the different electric grid applications of energy storage technologies are described and categorised. For each of the categories, we describe the available technologies, both mature and potential. Finally, methods for connecting storage technologies are discussed.

2008 - Distributed Power Generation in Europe: Technical Issues for Further Integration

This report focuses on the potential role of Distributed Generation (DG) in a European perspective. More specifically, this work aims to assess the technical issues and developments related to DG technologies and their integration into the European power systems. As a starting point the concept of Distributed Generation is characterised for the purpose of the study. Distributed Generation, defined as an electric power source connected to the distribution network, serving a customer on-site or providing network support, may offer various benefits to the European electric power systems. DG technologies may consist of small/medium size, modular energy conversion units, which are generally located close to end users and transform primary energy resources into electricity and eventually heat. There are, however, major issues concerning the integration of DG technology into the distribution networks. In fact, the existing distribution networks were not generally designed to operate in presence of DG technologies. Consequently, a sustained increase in the deployment of DG resources may imply several changes in the electric power system architecture in the near future. The present Report on Distributed Generation in Europe, after an overview of the basic elements of electric power systems, introduces the proposed definition and main features of DG. Then, it reviews the state-of-the-art of DG technologies as well as focuses on current DG grid integration issues. Technical solutions towards DG integration in Europe and developments concerning the future distribution systems are also addressed in the study.

 

 

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