Annual report
SC C6

Active distribution systems and distributed energy resources

by Christine Schwaegerl, Chair and Geza Joos, Secretary

Background and scope of SC C6 activities

Electric power systems are rapidly evolving in part due to increased penetration of distributed energy resources (DER) deployed in distribution systems. DER include generation from renewable energy resources (solar and wind), in addition to conventional distributed generation, electric energy storage systems, mostly connected at the distribution level, and demand response, in the form of integration and management of demand at the distribution level. The growing addition of generation at the distribution level may gradually displace central power generation and require new approaches to managing not only distribution but also transmission systems.

This evolution of electricity grids is also driven by new technologies, including the digitalisation of grid control and management, which brings significant benefits and disrupt conventional approaches, by societal and environmental concerns and pressures, namely decarbonisation and energy sustainability, including the move away from fossil fuel use. In addition, there is a trend towards deregulation of the electricity markets, and requirements for increased resilience and reliability of the energy supply. DER will play a key role in the evolution of power grids, by contributing to the decarbonisation and sustainability agenda, providing flexibility resources to ensure the reliability and resilience of power grids, and by allowing end users to play an increasing role in the operation of the electric gird and participate in electricity markets. Finally, DER deployment can be an approach that will facilitate rural and remote community electrification.

Distributed energy resources and active distribution systems can therefore contribute to key elements of the CIGRE technical directions, which include:

  • innovative solutions for DER and distribution technology deployment;
  • new approaches to configure, plan and operate new distribution systems for enhanced reliability and resilience;
  • rural electrification, islanded power systems and individual customer off-grid systems and solutions.

Distributed energy resources, which include technologies mentioned above, are displayed in Figure 1. These assets and resources are the key drivers for deploying active distribution systems. They are increasingly included in the planning and operation of distribution systems. They make distribution grids more controllable and responsive, enhance the role of the Distribution System Operator (DSO) and enable consumer participation in electricity markets. DER, as it displaces part of the central generation, has an increasing impact on central power generation dispatch and impact the operation of transmission systems.

See a larger image

Figure 1 – Distributed Energy Resources (DER) – scope

Distributed generation, an element in the DER assets, includes generation from renewable energy resources, mostly solar and wind power. These resources are variable and intermittent and need to be balanced to provide dispatchable power. This can be achieved using electricity storage (batteries) and demand response. In addition, distributed generation assets, individually, usually provide small amounts of power. Aggregation of DER is an effective way of managing a large number of DER, including smaller solar panels and battery energy storage systems at the residential and commercial levels. This can be achieved using concepts and tools such as microgrids, virtual power plants (VPP), Figure 2, or software platforms such as distribution management systems (DERMS) that aggregate DER over a wider area.

See a larger image

Figure 2 – DER deployment and aggregation – systems

SC C6 Mission and scope

The activities of SC C6 are mainly concerned with the technology, deployment of distributed energy resources (DER) and the impact on distribution grids. DER include assets shown in Figure 1.

The activities of the SC C6 working groups are structured along the lines shown in Figure 3:

  1. Drivers for DER deployment and integration in distribution systems (areas of attention) – Approaches and solutions to assist different stakeholders involved in distribution systems to make DER more controllable and responsive and support distribution system operations; customer integration and empowerment; active distribution network management (ADMS), microgrids, virtual power plants (VPP), DER management systems (DERMS) and aggregation platforms, DER monitoring and control; rural electrification and off‐grid systems.
  2. Enabling DER technologies (pillars) – Distributed generation including conventional (diesel, gas turbines, CHP), renewable resources (wind and solar) based generation, energy storage systems (battery energy storage, thermal and inertial storage), and demand response (controllable and curtailable loads); innovative equipment and systems for DER technology deployment (inverter interfaces).
  3. Innovative solutions for DER and distribution system technologies and deployment (applications of current interest) – Some of the areas of interest covered in the scope of the past and current working groups are listed and detailed in the section on Current Technical Activities.
See a larger image

Figure 3 – The structure of SC C6 technical activities

Structure and membership

The SC is composed of 24 regular members, 2 additional members, 19 observer members, and a Chair and Secretary. Represented are 43 countries. 

The membership includes stakeholders that have an interest in the topics covered by the Study Committee work: distribution planning and operations engineers and system operators, power system planning consultants, technology providers and manufacturers, applied information and communication technology experts, and researchers from academia and government laboratories.

Most of the Study Committee activities are carried out in Working Groups (WG). These produce Technical Brochures that answer the questions posed in the approved terms of reference (ToR) of the Working Groups, prepare tutorials based on the published brochures, that are offered at CIGRE symposia and sessions, and write summary articles on these brochures that appear in the CIGRE ELECTRA publication.

The Study Committee also collaborates through Joint Working Groups (JWG) with other Study Committees, including SC B4HVDC and power electronics, SC C1System development and economics, SC C2System operation and control, SC C5Electricity markets and regulation, SC C4System technical performance, and SC D2Information systems and telecommunication.

Advisory groups (AG) include:

  • AG C6.02 – Quality check of brochures
  • AG C6.12 – Tutorials
  • AG C6.17 – Rural Electrification, which coordinates CIGRE initiatives in this area.

Current technical activities of SC C6 Working Groups

Current technical activities are addressed in the active Working Groups listed in Table 1. These cover the elements that structure of SC C6 technical activities, namely, and with reference to Figure 3 and the list in the Table 1, the following:

  • Drivers for DER deployment and integration in distribution systems (areas of attention) – covered in WG C6.38 (rural electrification), JWG C6/C2.34 (DER flexibility provision), JWG C1/C6.37/CIRED (investment decision under uncertainty), JWG C1/C6.42 (planning for high levels of DER), WG C6.36 (DER models for impact studies),
  • Enabling DER technologies (pillars for DER) – covered in JWG C6/C1.33 (multi-energy systems, as generation), WG C6.40 (electric vehicles as DER, as storage), JWG D2/C6.47 (consumer resource management, as demand response), WG C6.39 (customer empowerment, as demand response)
  • Innovative solutions for DER and distribution system technologies and deployment (applications) – covered in JWG C6/C1.33 (multi-energy systems), JWG C5/C6.29 (local energy communities participating in markets), WG C6.39 (customer empowerment), WG C6.35 (DER aggregation platforms), JWG C6/B4.37 (medium voltage dc distribution systems)

Table 1 – List of active SC C6 Working Groups

WG Title of the Working Group Approval Convenor
JWG C6/C1.33 Multi-energy system interactions in distribution grids 2018 B. Bak-Jensen (Denmark)
JWG C6/C2.34 Flexibility provision from distributed energy resources 2018 P. Mancarella (Australia)
WG C6.35 DER aggregation platforms for the provision of flexibility services 2018 A. Oudalov (Switzerland)
WG C6.36 Distributed Energy Resource Models for Impact Assessment 2019 J. Taylor (USA)
JWG C6/B4.37 Medium voltage dc distribution systems 2018 J. Vu (UK)
WG C6.38 Rural electrification 2018 K. Dedekind (South Africa)
WG C6.39 Distribution customer empowerment 2018 M. Ross (Canada)
WG C6.40 Electric Vehicles as Distributed Energy Resource (DER) systems 2019 J. P. Lopez (Portugal)
JWG C1/C6.37/CIRED Optimal transmission and distribution investment decisions under increasing energy scenario uncertainty 2018 J.C. Araneda/F. Pilo (Italy)
JWG D2/C6.47 Advanced consumer side energy resource management systems 2018 A. Nebera (Russia)
JWG C1/C6.42 Planning tools and methods for systems facing high levels of distributed energy resources 2019 C. Higgings (UK)
JWG C5/C6.29 New markets, local energy communities 2019 A. Taccoen (France)

 

Scope of active Working and Joint Working Groups

JWG C6/C1.33 – Multi-energy system interactions in distribution grids 

The scope of this WG is to study the configurations, impacts and prospects of multi-energy systems that enable enhanced solutions for intelligent electricity systems, energy storage and demand side management in the electricity grids with an increasing share of distributed energy resources (DER). The JWG will explore opportunities and impacts of multi-energy systems in future electric power systems and review of technologies and systems that integrate multiple sources of energy such as (a) Power-to-Gas (P2G), including electrolyzers, fuels cells, hydrogen storage, injection into gas networks; (b) Combined Heat and Power (CHP); (c) Combined Cooling, Heat and Power (CCHP); (d) Power-to-Heat (P2H), including electric boilers, heat pumps, thermal storage; (e) Power-to-Vehicle (P2V) including vehicle to grid (V2G) services; (f) pumped and compressed air storages. It will explore building, district and city modelling and system modelling, planning, control and operation of electric distribution grids as part of multi-energy systems and networks. Business cases, experiences and case studies of active multi-energy systems as well as guidelines and existing practices, techno-economic challenges and solutions to adopt multi-energy systems will be provided.

JWG C6/C2.34 – Flexibility provision from distributed energy resources 

The scope of the WG is to analyse, assess and promote the role and potential of distributed energy resources (DER) in providing ancillary services, particularly flexibility, and participating in balancing market and whole-system operation. It will review drivers and new requirements for flexibility at different stages of power system planning and operation at different levels of the power system, from the whole-system to the local network, with a focus on DER based on intermittent renewables and compile information on the potential of DER and multi-energy coupling to provide flexibility over different time scales, and in different forms, including generation (inverter interfaced), energy storage (batteries, thermal storage, e-vehicles, gas infrastructure), demand response (industrial installations, individual buildings or district energy systems), and flexible assets (transformer tap changers and voltage regulators, dynamic thermal rating) and operations (active power control of renewable energy, TSO-DSOs coordination). The WG analyses the contribution of DER to operational and planning flexibility in transmission and distribution networks in current and future power systems, taking into account market structures, in providing multiple services of their choice to TSOs or DSOs, facilitated by new actors (aggregators) and grid architectures (interconnections, microgrids, virtual power plants, and energy hubs interlinkage, among which Vehicle to Grid (V2G) and Power to Gas (P2G). It will identify and discuss experiences and case studies and explore new business cases for emerging technologies and new market models. Finally, it will provide recommendations and guidelines regarding commercial, regulatory and policy changes required to exploit the flexibility provided by DER.

WG C6.35 – DER aggregation platforms for the provision of flexibility services

The objectives of this WG are to collect and analyse information on technical, economic and regulatory aspects of DER aggregation and to analyse methods for integrating aggregated resources into network planning and operation. Economically attractive DER aggregation approaches, classified according to contracted customers and services offered, as well as aggregator interaction with other major stakeholders such as participation in ancillary services markets, including frequency regulation, capacity and energy markets, bilateral agreements with distribution network operators. Services covered include voltage support, congestion management, black start and restoration and services to end-users and customers, including backup power. The WG will review of aggregation technologies including DERMS (Distributed energy resource management system), VPP (virtual power plant), and microgrids, considering among others the role of ICT and forecasting, trading and scheduling optimization and analyse the technological improvements that will allow DER aggregation move to the next level of controllability and flexibility. Experiences, case studies, regulatory and business model trends will be analysed providing guidelines and existing practices, techno-economic challenges and solutions for the deployment of DER aggregation platforms.

WG C6.36 – Distributed Energy Resource Models for Impact Assessment

The continued proliferation of DER and the convergence of distribution operations with distribution planning require that the models (both planning and real time models for operations) for these DER and their control systems be aggregated to support requirements for TSO/DSO coordination. With these requirements for advanced distribution planning systems, there is a need to develop benchmark models for different types of distributed resources that will be considered in planning studies. The impact of DER will need to be evaluated in a variety of planning studies and assessments – static load flows, quasi-static time-series assessments, fault analyses, harmonic studies, dynamic studies, electromagnetic transient simulation, and reliability assessments. Different DER models will be needed for different assessments – there is a need for industry coordination around the framework for these models, data needs and actual benchmark models for generic types of DER that can be used at the planning stage. There is also a need to consider emerging assessment methods that can be used to better facilitate DER integration, such as probabilistic load flow, hosting capacity and locational value assessments. Additional drivers for this work include the continued development of local energy community concepts where DER is an integral part of the community energy management, the broad penetration of electric vehicles and the potential for advanced electric vehicle charging management, design of Distributed Energy Resource Management Systems (DERMS) as an integral part of future distribution management, and Common Information Model requirements for inclusion of DER in the different types of distribution simulation studies. The scope of this working group is to present, analyze, assess and describe the need and possible approaches for benchmark DER models that can be used for a variety of distribution systems studies.

WG C6.37 – Medium Voltage DC distribution systems 

The scope of this WG is to present elements of the deployment of MVDC networks as related to DER and distribution systems, and as a replacement for ac distribution systems, and to demonstrate the advantages of the dc approach. The WG will analyse the connection of DER and loads to MVDC networks, the connection of the MVDC system to the transmission grid and the operation of MVDC systems. It will compare Medium Voltage AC (MVAC) and MVDC systems concerning network structures, losses and efficiency. Related topics are the connection between MVDC and Low Voltage DC distribution systems and multi-terminal MVDC grids. Experiences and examples of deployments, case studies, guidelines and existing practices, techno-economic challenges and present and future solutions will be provided.

WG C6.38 – Rural electrification

The scope of this WG is to study the contributions that can be made to rural electrification through the deployment of distributed energy resources (DER), supported by modern control and communication systems, for both grid connected and off-grid electric distribution systems. Political, institutional and societal issues are outside the scope of this report. The WG will explore sources of a secure electric energy supply, including transmission, distribution and LV grids, local generation resources (small hydro, diesel generators), DER, renewable energy resources (solar, wind, small hydro), alternative energy resources (bioenergy, including biogas and biomass), hybrid generation systems, types and role of energy storage and standalone systems. Considerations of interest are sustainability, emissions and GHG, environmental protection and impact, footprint, power quality, reliability and availability of the energy supply, and energy security (short term and long term). The WG will cover ownership, maintenance and operation of DER, including generation, integration, interconnection requirements, grid codes and standards as well as rural electrical loads, with applications in agricultural, industrial, mining and commercial settings. It will consider demand response, energy efficiency, metering for billing, monitoring and control. The WG will review practices and approaches in generation and distribution deployment and rural electric distribution system architecture, and analyse use cases and tools for energy system planning, design and operation. Guidelines and existing practices, techno-economic challenges and present and future solutions will be given.

WG C6.39 – Distribution customer empowerment

The scope of this WG is to study the contributions to the operation of distribution systems that can be made by customers through the deployment of DER on their premises, supported by modern control and communication systems. Customer empowerment approaches include providing them the information required to understand their impact in better managing their consumption and the tools available to implement this management in a manner agreed with the distribution system operator. Load shifting and levelling are some of the tools. The WG will explored and elaborate the general context for customer engagement and empowerment opportunities, distribution utility interests, expectations and requirements in-regard to the consumer. It will analyse the sensing, communication and control infrastructure required,  and the implementation of customer empowerment and interaction with stakeholders. It will perform a review of current and planned practices and approaches to empower customers and the available power, control and communications and analyse experiences and examples of deployments and case studies. Guidelines and existing practices, techno-economic challenges and present and future solutions will be given.

WG C6.40 – Electric Vehicles as Distributed Energy Resource (DER) systems

The electric vehicle (EV) battery and its charging system, with or without the addition of a stationary battery, can therefore be used in almost the same manner and with almost the same potential benefits as any BESS type DER. Some of the benefits include demand response management (load shifting and load smoothing), distribution grid resilience enhancement (building back-up power supply, local grid support, enhanced hosting capacity and stability, contribution for islanding operation and black start in microgrids), renewable energy system balancing (solar PV), and ancillary services to the transmission system, particularly when aggregated, for purposes such as ramping and frequency support. This WG deals with the EV charging systems and infrastructure as a key distribution grid enabling technology. The EV battery and charging system technologies are presented from the distribution grid perspective, and the control systems required to enable the multiple benefits these systems can provide are described.

JWG C1/C6.37/CIRED – Optimal transmission and distribution investment decisions under increasing energy scenario uncertainty

Transmission and distribution investment decisions can no longer be made independently by power system or market executives. This is because environmental, social and political issues are important factors to be taken into account at the moment the investment is subject to its approval. It has meant long lead times to develop transmission infrastructure (longer than the time required for approving and building a new renewable DER based power plant). On the distribution side, populated cities and towns generally imply pushing for the use of underground distribution infrastructure that competes with residential expansion or local requirements. Significant increase in DER integration, interconnection with other grids, and utilization of Smart Grid technologies makes transmission and distribution system planning more challenging than in the past. Users’ measurements and data are available at both TSO and DSO level, including active power exchange measurements, load and generation data and interconnection capability data. Through an appropriate data exchange methodology and Information and communication (IT) architecture it should become possible to determine robust plans with efficient resource allocation.  This working group will summarize learnings from several prior SC C1 and SC C6 WGs which focused on the planning decisions, methodologies and implications derived from the growing integration of DER.

JWG D2/C6.47 – Advanced consumer side energy resource management systems 

Recent advances in Industrial Internet of Things, Blockchain and other new information and communication technologies (ICT), as well as methodology and experience gathered e.g. in Transactive Energy pilot projects, provide a potential platform to deal with the DER control and integration challenge at the consumer level. The scope of this joint working group (JWG) includes an analysis of the current state of new ICT applicable for coordinated or shared control of multiple DER, and the important interactions between control systems of electric power utility, generation or load aggregator and consumer. It will provide guidelines for the selection and use of ICT for various business cases involving utilities, aggregators and consumers.

JWG C5/C6.29 – New electricity markets, Local Energy Communities (LEC)

The WG will provide a worldwide overview of DER technology applied in LEC, the planning and operation of DER, and the development of LEC. The regulatory framework will be addressed. The aim is to understand how members of a LEC can be market actors and how the LEC can be itself a market actor. The following topics are  addressed: (a) definition of LEC (differences to microgrids, virtual power plants or net-zero communities) and of DER technology; (b) role of the regulator, local legislations as well as business cases within the internal organization of the LEC; (c) mechanisms for consumers entering and leaving a LEC; (d) options for an LEC being locally responsible for the balance between generation and demand; (e) interfaces as well as relation and required exchange of data between a LEC and the DSO; (f) competition between suppliers within a LEC.

JWG C1.C6.42 – Planning tools and methods for systems facing high levels of distributed energy resources 

The JWG will identify the impact of a large deployment of DER at the distribution level and repercussions on the transmission grid as well as methods of aggregating DER and of determining the benefits of aggregating DER at the distribution and transmission levels. It will identify the tools required to analyse the impact of individual and aggregated DER on the distribution and the transmission systems and investigate the potential of co-simulation tools allowing the analysis of the impact of DER installed at the distribution level on the transmission grid considering static and dynamic aspects. Planning and operation tools required at the distribution and at the transmission levels to consider the impact of a wide deployment of DER will evaluate the impact on reliability and resilience. The economic aspects associated with the generation of power and increased reliability and resilience will be analysed. A survey for distribution and transmission utilities will provide present practices and additional needs, with a focus on known techniques, valuing DER and customer flexibility; practices and techniques in developing scenarios and tools to adapt to uncertainty, and commonly used tools, methods and data.

WGs led by other SCs – with C6 liaisons and contributions:

  • WG C5.31Wholesale and Retail Electricity Cost Impact of Flexible Demand Response;
  • WG C2.40TSO-DSO Interaction;
  • JWG C1/С4.36Review of Large City & Metropolitan Area power system development trends taking into account new generation, grid and information technologies.

New SC C6 WG ToRs in preparation

  • (a)  Electric Transportation Energy Supply Systems
  • (b)  Technologies for Electrical Railway Distribution Supply Systems

 

CIGRE active Working Groups / Call for experts

Recently published and pending Technical Brochures

TB 782Utilization of data from smart meter system (October 2019, JWG C6/D2.32) – The brochure provides an overview of utilization of data from smart meter systems, to integrate and organize the values, tasks, and approaches to be taken and to make a proposal to the electric power utilities and associated market participants, from technological point of view. Smart meter deployment status and smart meter functions all over the world are sorted out in the Technical Brochure that will be published early 2019. Collected use cases are mapped and categorized on an evolution plane, then similar ICT requirements and constraints are extracted in each category. Candidate technologies depending on ICT requirements and constraints to realize use cases and a general concept of the system architecture are described.

TB 793Medium Voltage Direct Current (MVDC) grid feasibility study (February 2020, WG C6.31) – MVDC grid is seen as a technology for upgrading and modernizing power distribution networks and achieve enhanced reliability, flexibility and efficiency. Challenges and difficulties that need to be addressed in detailed studies are mentioned. MVDC grids are being considered, particularly in Europe and China.  Although the studies for HVDC grids and micro DC grids have been carried out, MVDC grids, which have different features and applications compared to HVDC grids, need to be further studied and developed. The report summarizes the current status of MVDC worldwide.

WG C6.28Hybrid systems for off-grid power supply – Brochure in the editorial and production stages – It covers issues related the electrification of rural areas. It considers current renewable energy technologies which offer enhanced opportunities for off-grid power systems, and include photovoltaic systems, wind turbines, biomass-fuelled combined heat and power units, hybrid systems, storage facilities and fuel cells. The topics addressed include: (a) a review of the state of the art of hybrid facilities including the mini-grids for off-grid power supply to rural and remote areas; (b) a review the various options for power generation including, fossil fuelled facilities, small hydro, photovoltaics, biogas, and wind turbines, (c) a review of storage options and the suitability and field performance of various battery types for hybrid applications, their battery management system.

Closing remarks

Study Committee C6 has sustained, during this reporting year 2019-2020, its efforts to create new WGs and extend its activities to new types of DER and new areas of DER applications. The energy transition away from fossil fuels and the expansion of electrification of a number of processes and systems offers such an opportunity. SC C6 has continued to publish brochures and produce tutorials that focus on knowledge dissemination related to the transition to the future power systems with a high penetration of DER. The preferential topics of the CIGRE symposia and session in which SC C6 is involved reflect these trends and initiatives.

Acknowledgements

The SC C6 Chair would like to acknowledge the active participation, contributions and support of all dedicated individuals that contributed to the achievements of SC C6 in this reporting period, including WG and JWG convenors, special session reporters, and SC members, observers and experts. It also wishes to recognize the contributions and support it received from other SCs in developing and promoting the potential of distributed energy resources.

 

Contact

C6

Active distribution systems and distributed energy resources

SC C6 facilitates and promotes the progress of engineering and the international exchange of information and knowledge in the field of distribution systems and distributed energy resources DER. The experts contribute to the international exchange of information and knowledge by means of synthesizing state of the art practices and developing recommendations.

Learn more
Top of page