Interfacing Next-Generation Grid-Scale Storage to the Electrical Power Network (Inter-Storage)

Lead Research Organisation: University of Manchester
Department Name: Electrical and Electronic Engineering

Abstract

Next generation storage technologies have a key role to play in the future electrical power system, making up the difference between what low-carbon sustainable generation can provide, and what the grid needs. This is both in terms of longer term events (shifting energy from when it is generated to when it is used several hours later) and shorter terms events (providing grid support services to 'keep the lights on'). The UK electrical grid is a legacy system - it has been designed under the assumption that grid support services and second-by-second power balancing is undertaken by large central generating units, typically several hundred megawatts in size. However future energy storage units like flywheels will not be one 500 MW flywheel connected at one point: the storage will be something like 500 individual units each of 1MW, connected individually or in clusters of a small number of units. In order for such systems to interface to, and work to support the legacy grid, the interface system (power electronics and control) must be designed to work with the new dynamics of the storage unit and the legacy requirements of the electrical grid. This means that some form of supervisory control is required to modify the local interface control of each storage unit to enable the combined system to behave as a coordinated cohesive system. A local unit would not have an oversight of how the wider network is performing or the other units are behaving and thus the overall system performance would be at best sub-optimal, and at worst individual units could end up fighting with each other - applying contradictory control effort to the system. The dynamics of the control at the point of use would need to be fast to both enable the tight control of current required by modern power electronics, and to enable the fast response required in new systems with large amounts of power electronic interfaced generation and low inertia.

This project will investigate the design of the power electronics interface and its local control, considering both flywheel and compressed air energy storage. It will examine the supervisory control and telecommunications requirements needed to coordinate such systems, the required innovations in grid support services, and will formulate new methodologies to provide the required services. And it will investigate the practical constraints of implementing such a system using a real-time digital simulator (RTDS) coupled to a supervisory control system, network emulation and local controller system units.

Publications

10 25 50
 
Description The award intends to model and determine the behaviour of different sources of distributed energy storage and means to coordinate them. So far modelling of the storage units has been undertaken and partly transferred to a real-time digital simulator. Test use cases have also been identified. Supervisory control and its implementation is being examined.
Exploitation Route The work will of use to academics and industry involved with electrical utility power systems with multiple large power electronic interfaced energy sources, specifically examining ways to coordinate multiple inverter based resources.
Sectors Energy

 
Description Participation at Green Together (Manchester) 2024 
Form Of Engagement Activity Participation in an activity, workshop or similar
Part Of Official Scheme? No
Geographic Reach Regional
Primary Audience Public/other audiences
Results and Impact Green together is a public event held at Manchester Central Library from Feb 22 to 24th. Members of the research team attended on the Saturday and undertook demonstration activity to show how energy storage can support the power network, as well as some hands on 'make your own electrical machine drive' activity.
Year(s) Of Engagement Activity 2024
 
Description Talk "Development of a custom induction machine component for computationally efficient flywheel energy storage simulation" at RTDS User Group 
Form Of Engagement Activity A talk or presentation
Part Of Official Scheme? No
Geographic Reach International
Primary Audience Professional Practitioners
Results and Impact This was a dissemination of best-practice to the RTDS industry European User Group Sept. 2022- 2023 in Nuremburg Germany by a talk given by a PDRA on the project. This forum is a technical group which swaps cutting-edge developments in the field of real-time modelling.
Year(s) Of Engagement Activity 2023