The federal government's electricity policy is focused on increasing the share of renewable generation, increasing cross-border interconnection capacity, ensuring security of electricity supply, lowering electricity costs and increasing the competitiveness of electricity markets. In addition, region Contact online >>
The federal government''s electricity policy is focused on increasing the share of renewable generation, increasing cross-border interconnection capacity, ensuring security of electricity supply, lowering electricity costs and increasing the competitiveness of electricity markets. In addition, regional electricity policy focuses on distribution system flexibility and the participation of consumers through smart meters, demand response measures, energy storage and distributed renewables (including self-consumption).
The Belgian electricity sector will undergo major changes in the next decade. The share of renewables in the electricity generation mix is expected to almost double, from an estimated 20.9% in 2020 to more than 37% in 2030. Belgium''s federal Law of 31 January 2003 requires the phase-out of all nuclear electricity generation in the country. In light of the Russian invasion of Ukraine and goals to reduce fossil fuel dependency, the federal government decided in March 2022 to amend the law to extend 2 GW of nuclear capacity by ten years.
Belgium has a well-developed and highly interconnected electricity system serving domestic demand and supporting the European electricity market. Belgium''s electricity network is one of just a few networks in the world to make extensive use of dynamic line rating (DLR), which uses distributed sensors to provide real-time monitoring of high-voltage electricity lines. DLR allows the transmission system operator (TSO) to better determine actual line capacity and improve overall system performance. In 2020, the TSO was using DLR on 28 high-voltage lines and estimated it had increased import and export capacity by around 10%, resolved congestions issues, reduced redispatching costs and aided the development of renewable generation.
Network: transmission and distribution
The private company Elia is Belgium''s electricity TSO. It is owned by the Elia Group, which also owns German TSO 50Hertz. Around 48% of the shares of the Elia Group are held by two public holding companies (Publi-T and Publipart), which are owned by Belgium''s municipalities.
Elia operates the high-voltage electricity transmission network (30-380kilovolts [kV]) that supports transmission of electricity across Belgium and electricity trading via the cross-border interconnectors. The part of the network from 70 kV to 380 kV is regulated by the Commission for Electricity and Gas Regulation and the federal government. The part of the network from 30 kV to 70 kV is regulated by the regional regulators and governments. Most of the electricity supplied by the high‑voltage transmission network is delivered via transformer substations to Belgium''s electricity distribution networks, which serve the majority of consumers. However, the transmission system also directly supplies a large number of heavy industrial consumers.
Belgium''s distribution system is composed of medium- and low-voltage networks (below 30kV) and serves the majority of electricity consumers, with 4825659 connection points in2020. Belgium''s municipalities have a legal monopoly on electricity and gas distribution and own the electricity and gas distribution networks. Nearly all municipalities have transferred responsibility for electricity and gas distribution to inter-municipal companies, which are the distribution system operators (DSOs) for the assigned section of the network. In 2019, there were 16electricity DSOs in Belgium, 10 in Flanders, 5 in Wallonia and 1 (Sibelga) in the Brussels‑Capital Region.
In 2020, Belgium had interconnections to France, Luxembourg and the Netherlands via 12high-voltage alternating current (AC) lines; with the United Kingdom via the Nemo Link HVDC subsea cable; and with Germany via the Aachen Liège Electricity Grid Overlay (ALEGrO) HVDC underground cable. Belgium''s maximum technical interconnection capacity was 6.5GW in 2020. Projects under development will expand Belgium''s interconnection capacity with the Netherlands and increase maximum technical interconnection capacity to 8.4 GW.
Under EU rules, Belgium has binding targets for cross-border electricity interconnection capacity, and Elia operates interconnections with connected countries. Targets are based on the ratio of interconnection import capacity and domestic generation capacity. Belgium met its 2020 target of 24% and has a 2030 target of 33%.
Belgium''s pumped hydro storage (1.31 GW in 2020) plays an important role in system balancing. Belgium has limited battery storage capacity. There are no official consolidated data on battery storage, as this is not yet part of the mandatory energy statistics. A first unverified compilation of operational battery projects used for grid balancing was conducted in September 2021 and estimated capacity around 32.5MW/30MWh. However, the government indicated that this estimate is likely well below the actual capacity of operational battery storage. Belgium''s battery storage capacity is expected to increase, as a 25MW/100MWh system is planned for 2022.
In addition to the EU Risk Preparedness Regulation, the core national legal framework for electricity crisis management in Belgium consists of two key documents:
The Federal Grid Code creates a legal basis for the Ministerial Decree of 3 June 2005 on the establishment of the load-shedding plan, which is embedded in the System Defence Plan developed by Elia. To ensure a level of risk preparedness at the level of the TSO, the federal Minister for Energy is granted approval authority concerning the TSO''s System Defence Plan, the Restoration Plan and the Test Plan, pursuant to the Federal Grid Code.
In line with requirements imposed by the EU Risk Preparedness Regulation, Belgium has developed numerous electricity crisis scenarios to assist in identifying the necessary emergency response measures to deal with electricity shortfalls. The procedures for dealing with very short-term, sudden shortfalls have to be updated in light of structural changes in the crisis management legal framework.
In the event of an emergency situation within the Belgian electricity system, a load‑shedding plan can be activated, with the Decree of 3 June 2005 setting rules on the order for disconnecting and reconnecting consumers.
Belgium''s total electricity generation capacity was 23.85 GW, with two nuclear plants accounting for 25%, followed by natural gas (24%), solar PV (23%), wind (20%), hydro (6%), and small shares from bioenergy and oil. Ownership of Belgium''s generation capacity is highly concentrated. From 2013 to 2020, there was an increase in total installed capacity (+2.9 GW) and a notable shift in the mix of generation assets, with a large increase in wind and solar PV capacity offset by reduced capacity for natural gas, coal, oil and biomass.
Most of Belgium''s generation capacity is composed of large-scale generation assets (centralised plants or large wind and solar PV parks) connected to the electricity transmissions system (around 16 GW). However, a notable share of capacity (around 8 GW) is connected at the distribution level and this capacity has been increasing, especially small-scale distributed solar PV systems connected to the low‑voltage networks.
After a tender process based on rules set by Elia in consultation with the market players, the Commission for Electricity and Gas Regulation (CREG) and the federal government, the volumes and prices of the reserves can be imposed on the selected tenderers for the required period. The remuneration varies, depending on whether the suppliers are offering SGR or SDR. The remuneration for the SGR covers the expenses incurred by the supplier for keeping fuel available and generating the energy at Elia''s request. For the SDR, suppliers are remunerated for the availability of the contracted capacity and for the activation of the SDR.
In recent years, Belgium has taken steps to enhance resilience of the electricity system to cyber-attacks. The central authority for cybersecurity in Belgium is the Centre for Cyber Security Belgium (CCB), which was created by Royal Decree of 10 October 2014, and is under the authority of the Prime Minister.
The main regulatory framework for cybersecurity is the law of 7 April 2019 for the security of network and information systems of general interest for public safety ("NIS law"), which implements the EU NIS Directive (Directive 2016/1148). All entities designated as so-called "operators of essential services" within a range of sectors including the energy sector, must adopt adequate protective measures against cyber-attacks, and are subject to inspections and are required to notify cybersecurity incidents.
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We are moving from a highly-centralized to a more decentralized energy system relying on more distributed generation, energy storage and a more active involvement of consumers through demand response. The present study makes an assessment of the status quo of decentralized energy systems, both in terms of technological developments and the legislative and policy framework. The analysis then discusses the current technical, economic and policy challenges and barriers facing decentralized energy production. Finally recommendations are provided in terms of the EU legislative and policy framework; infrastructure issues; R&D, investments and technological developments; monitoring and coordination of Member States incentive schemes; and SME support measures.
M. Altmann - Ludwig-Bölkow-Systemtechnik ; A. Brenninkmeijer, J.-Ch. Lanoix - HINICIO ; D. Ellison, A. Crisan, A. Hugyecz - College of Europe ; G. Koreneff, S. Hänninen, P. Linares - VTT Technical Research Centre of Finland
The electric power sector in Europe is currently facing different changes and evolutions mainly in response to the three European Union (EU) energy-related challenges – environmental demand. These issues may also represent drivers for the further penetration of Distributed Power Generation (hereinafter simply Distributed Generation, or DG) technologies in Europe. In fact, several EU countries are already recording a gradual and steady upward trend in deploying distributed power sources.
This trend is also triggered by emerging technological solutions for more efficient, environmentally-friendly and small-size generating units. Additionally, to address the growing electricity demand, the traditional approach of adding new large generation and transmission capacity to the system is frequently hindered by social, economic and environmental constraints in building new high capacity infrastructures. These impediments may then contribute to further DG utilisation. It has also to be remarked that the recent new targets for Renewable Energy Sources (RES) penetration in the EU (globally 20% of energy consumption covered by RES by 2020) will foster a rising DG deployment in the EU countries.
The present Report focuses on the potential role of Distributed Generation against the above described background. More specifically, this work aims to investigate the developments related to DG technologies and address the technical issues towards the DG 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 power 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 in some cases heat and cooling via Combined Heat and Power (CHP) technology).
As we all know, the electricity we use is instantaneously balanced, which means that the power plant must generate as much as you use. It''s like a balance, with the consumer at one side and the power plant at the other side, and the support that keeps it balanced is the grid. Power plants are constantly generating electricity every day, and the demand for electricity is always high and low, with more electricity needed during the day and less at night, more in the summer and less in the winter, so power plants can only adjust their own generation according to the current external demand, which can cause uneconomic operation. In recent years, there are growing focus on virtual power plants and smart grids.
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