ENGM031 L2 Introduction to Smart Distribution Networks

Microsoft PowerPoint – ENGM031_L2_Introduction to Smart Distribution Networks

Page – 1 of 42Smart Grids & Sustainable Energy Systems

Prof Peter Crossley

L2: Smart Grids &
Sustainable Energy Systems

Impact of Low Carbon
Technologies on Distribution

Page – 2 of 42Smart Grids & Sustainable Energy Systems

If this is a “typical” regional 24 hour working-day load profile.
How can we use renewables in the future?

Is this the shape of a our future energy demand and if yes how do we ensure
renewables, clean coal and nuclear deliver the energy when we require it

Renewables

Capacity Limit

Methane & CCS
Or Hydrogen

Time of Day – 24hr cycle

Page – 3 of 42Smart Grids & Sustainable Energy Systems

What if renewables generate at wrong times?

Can renewables generate overnight and store the energy?
Can storage then deliver the energy at peak times?

Is this economically viable?

Capacity Limit

Methane + CCS
& Hydrogen

Time of Day – 24hr cycle

Demand Requirements

Page – 4 of 42Smart Grids & Sustainable Energy Systems

Can renewables, coal and gas with carbon capture & storage, nuclear, green hydrogen, storage &
dispersed “clean” generation deliver the energy when we require it at a cost we can afford ?

How do we ensure the lights stay on in 2030 or 2040?

Capacity Limit

Time of Day – 24hr cycle

Dispersed Generation (mainly PV)

Methane & CCS

Demand Profile

Page – 5 of 42Smart Grids & Sustainable Energy Systems

UK Electricity Market Structure

Traditional Power System

Typically 25kV

UK = 400kV or 275kV

UK = 132kV and/or 33kV

UK = called HV by DNO’s and normally 11kV

UK = 400V if 3-phase
or 230V if 1-phase

Page – 6 of 42Smart Grids & Sustainable Energy Systems

What if demand increases above local network capacity?
Does local refer to a region, city, town or the supply to your house?

UK:- expect significant demand growth due to EVs (depends on gasoline prices & CO2
legislation) & domestic electric heating (depends on natural gas prices and government policies)

Capacity Limit

Current Demand

Future Additional

Time of Day – 24hr cycle

How can your local network cope ?

Page – 7 of 42Smart Grids & Sustainable Energy Systems

Dynamic Demand, Storage & DG lowers demand
below feeder/network capacity limit.

Can we shift demand from peaks to troughs?
or can we match demand to availability of low cost, low carbon
energy & capacity of network

Capacity Limit

Time of Day – 24hr cycleD

Future Demand without load shifting

Future Demand with load shifting (demand response)

Page – 8 of 42Smart Grids & Sustainable Energy Systems

Typical UK urban distribution network

Page – 9 of 42Smart Grids & Sustainable Energy Systems

Distribution Network Configurations

Page – 10 of 42Smart Grids & Sustainable Energy Systems

Distribution Network Configurations

Page – 11 of 42Smart Grids & Sustainable Energy Systems

Distribution Network Configurations

Page – 12 of 42Smart Grids & Sustainable Energy Systems

Distribution Network Configurations

Page – 13 of 42Smart Grids & Sustainable Energy Systems

Topology of Urban LV Networks

Page – 14 of 42Smart Grids & Sustainable Energy Systems

Evolution to future
distribution grid

UK transports electricity along 835,740 km of
lines and cable. Cost of replacing UK’s
distribution network is £95.6 billion

Page – 15 of 42Smart Grids & Sustainable Energy Systems

WPD Evolution to future distribution grid

Ofgem encouraged DNOs to innovate by investing in trials; costs are recovered via network price controls.

How do DNOs cope with dispersed
generation, storage, > demand, EVs ?

Page – 16 of 42Smart Grids & Sustainable Energy Systems

Electricity Network Innovation in UK

29 million electricity customers

 UK electricity networks (DNO’s) are adapting to challenges of
decarbonisation
 concern is speed of change

 Expect to deliver energy security and affordability in a low
carbon economy
 concern, kWh carbon intensity in 2030 or 2040?
 Government states this needs to be <70gCO2/kWh by 2030, but Committee for Climate Change wants 50gCO2/kWh  What will the UK achieve?  Since DNO’s and the TSO are natural monopolies, Government and Ofgem’s framework for regulating the DNO’s is critical in ensuring Net-Zero is achieved  concern, will Government and Ofgem stick to its timetable for Net-Zero. National Grid Distribution Page – 17 of 42Smart Grids & Sustainable Energy Systems Ofgem LCNF Tier-1 smart-grid projects (operated 2010 – 2015) Tier-1 projects allowed DNOs to recover proportion of expenditure incurred on small projects. Tier-1 projects had to trial a: • specific piece of new (unproven in Britain) equipment with direct impact on Distribution System • novel application of existing Distribution System equipment • new operational practice for Distribution System • novel commercial arrangement with a Distribution System User Tier-1 projects had to demonstrate they: • accelerate development of low carbon energy sector and provide net financial benefit to customers • have direct impact on DNO’s Distribution System • generate new knowledge that can be shared amongst all DNOs • focus on network methods that are at the trial stage • do not lead to unnecessary duplication with other projects Page – 18 of 42Smart Grids & Sustainable Energy Systems Electricity North West Tier-1 Projects: • 'Bidoyng' Smart Fuse: • install “Smart Fuses” on the Low Voltage (LV) network and determine if they are able to reduce the impact of transient faults. • Voltage Management on Low Voltage Busbars: • deploy and assess range of voltage management technologies and techniques across 15 distribution substations. • Low Voltage Network Solutions: • deploy monitoring equipment to provide greater understanding of the operating characteristics and demands of LV networks. • Low Voltage Integrated Automation: • new integrated solution for voltage control of LV networks. • Low Voltage Protection And Communications: • develop & implement advanced protection & communications to meet the requirements of future LV • Fault Current Active Management: • methods other than network reinforcement to reduce fault levels. Page – 19 of 42Smart Grids & Sustainable Energy Systems ENW Tier-1: Low Voltage Network Solutions: • Project will deploy measurement, sensing and recording equipment to help ENW understand operating and demand characteristics of LV networks. • University of Manchester helped ENW identify meaningful sample of representative LV network feeders. • Activities: • measurement and data collection • network modelling • developing appropriate LV network solutions • validating conclusions of other LCNF LV trials on ENW network Page – 20 of 42Smart Grids & Sustainable Energy Systems 'Bidoyng' Smart Fuses Page – 21 of 42Smart Grids & Sustainable Energy Systems Wide Area Data Monitoring Page – 22 of 42Smart Grids & Sustainable Energy Systems ENW Capacity to Customers (C2C) Demo Project: 2012 - 2015 • Electricity North West awarded £10M to develop C2C, aims to: • release untapped emergency network capacity • customers savings, by changing how electricity is used • prevents infrastructure improvement costs being passed to customers • How ENW will increase capacity: • network operator must plan for the future and invest customers money into the region’s electricity network. • trial smart-grid technology to reduce need for investment • C2C provides more power using existing assets. It could deliver the extra capacity without expanding the network. Page – 23 of 42Smart Grids & Sustainable Energy Systems ENW Capacity to Customers (C2C) Page – 24 of 42Smart Grids & Sustainable Energy Systems C2C = Reconfiguring the network Main findings are: C2C releases extra capacity and delivers economic and carbon Project demonstrated C2C can unlock real benefits for customers such as quicker new network connections at lower cost and cheaper distribution use of system costs. Our industrial and commercial customers are willing to sign up to C2C contracts Customers offered a monthly payment or a reduced new connection charge in exchange for allowing us to manage their connection in the event of a fault. During the project we signed up ten existing customers and ten new connection agreements. Page – 25 of 42Smart Grids & Sustainable Energy Systems UK Government “smart-grid” policies • UK Department of Business, Energy and Industrial Strategy (BEIS) is developing the strategic, regulatory and policy frameworks to ensure “UK’s electricity networks efficiently deliver secure & clean energy that meets UK’s energy security and climate goals” • In recognition of this, Ofgem introduced a new innovation funding streams, beginning with the Low Carbon Network Fund (LCNF) for electricity distribution projects in 2010. • In 2015, this was replaced by Network Innovation Competition (NIC) and Network Innovation Allowances (NIA) under the RIIO-ED1 price control (Revenue = Incentives + Innovation + Outcomes) • RIIO-ED1 will end in 2023, and will be replaced with RIIO-ED2. • RIIO-ED2 price control sets the outputs the 14 electricity Distribution Network Operators (DNOs) need to deliver for their consumers and the revenues they are allowed to collect from 1 April 2023 to 31 March • Success of LCNF and RIIO-ED1 enabled DNO’s to create projects, demonstrating new technologies and working practices that are now being adopted as business-as-usual by companies to deliver savings for customers. Page – 26 of 42Smart Grids & Sustainable Energy Systems FlexDGrid: Advanced Fault Level Management • Western Power Distribution (WPD) received £13.5M from UK energy regulator to revolutionise the power network in Birmingham. • WPD will use new solutions to accommodate more local generation. • connection of generation to urban networks increases fault level Page – 27 of 42Smart Grids & Sustainable Energy Systems FlexDGrid: Advanced Fault Level Management Connection of generation directly to urban electricity networks can increase the fault level. FlexDGrid will investigate: • Enhancing simulation processes to calculate and predict short-circuit currents. • Monitoring the network in a greater level of detail. • Installing new technologies that can limit the flow of short-circuit currents when faults occur in the electricity network. Page – 28 of 42Smart Grids & Sustainable Energy Systems FlexDGrid offered improved solution to the problem of cost- effective integration of customers' generation and demand within urban High Voltage (HV) electricity networks. Project sought to explore benefits arising from trials of three complimentary Methods: (Alpha) Enhanced Fault Level Assessment; (Beta) Real-time Management of Fault Level; & (Gamma) Fault Level Mitigation Technologies. Outcomes for Method Alpha were: - detailed 11kV network models of 15 primary substations and an automated procedure for updating or developing further network models for Fault Level assessments. - user-friendly Excel-based tool for use in primary system design for Fault Level assessments of HV networks of primary substations where FCLs have been installed. Outcomes for Method Beta were: - FLMs allowed Make & Break Fault Level values to be assessed, enabling networks to operate based on these values, increasing network security & facilitating new customer connections. - Fault Level data was fed back into models, allowing updates to planning Fault Levels. - policy documents were developed to assist with connection & operation of FLMs. Outcomes for Method Gamma : - PSCFCL (Pre-Saturated Core Fault Current Limiter) installed at Castle Bromwich 132/11kV Substation - RSFCL (Resistive Superconducting Fault Current Limiter) installed at Chester Street 132/11kV Substation - RSFCL at Bournville 132/11kV Primary Substation Page – 29 of 42Smart Grids & Sustainable Energy Systems The following work was carried out: A sample PSS/E model of a network, representing part of Birmingham’s 11kV network, was considered; The parameters of the sample model were varied within the range given in Table 6-3 within an assumed time to create different operation condition scenarios; and The corresponding Fault Levels of each scenario were calculated. The results were then compared with calculated Fault Levels from the original model to understand the impact of the each network parameter on the network Fault Level. Page – 30 of 42Smart Grids & Sustainable Energy Systems Single line diagram of connection at Elmdon: • 11kV network in Birmingham is supplied from number of 132/11kV substations at strategic locations in and around the city. • Direct transformation from 132kV to 11kV results in lower network impedances due to absence of an intermediate voltage supply level (such as 33kV). • Lower network impedance resulted in very high Fault Levels on the 11kV network. • Operation of the network with Fault Levels exceeding equipment ratings cannot be permitted as the equipment may not be able to sustain / interrupt the resultant current. • Hence, most 11kV busbars at primary substations have to be run in split configuration. • Operating the network in split configuration requires manual or automated sequence switching to quickly restore customers in the event of an upstream fault. Why not build primary substations using 132/11kV transformers with higher leakage reactance? Page – 31 of 42Smart Grids & Sustainable Energy Systems Single line diagram of connection at Elmdon: • Implementation of Method Gamma allowed the 11kV busbars at a primary substation to be connected in parallel by reducing the prospective fault infeed by connecting an FCL across the bus-section or in series with the incoming feeder. • Objective for Method Gamma was that the chosen primary substation shall be able to accommodate additional generation, up to 10% of the firm capacity of that primary substation, without exceeding the equipment ratings following installation of • Method Gamma aimed to reduce network Fault Levels through the installation of Fault Level Mitigation Technologies (FLMTs), otherwise known as Fault Current Limiters (FCLs). • Design and installation of FCLs builds on learning and technologies developed from earlier Innovation Funding Incentive (IFI), Energy Technologies Institute (ETI) and Low Carbon Networks Fund (LCNF) projects to create a system-level approach. • Method involved installing FCLs at five 132/11kV substations in and around the centre of Birmingham to reduce the Fault Level of the surrounding 11kV networks. • Three different FCL technologies were chosen to be developed however; this was reduced to two following issues with the GE Power Electronic technology. Page – 32 of 42Smart Grids & Sustainable Energy Systems FlexDGrid: Advanced Fault Level Management Castle Bromwich Fault Current Limiter, during installation Page – 33 of 42Smart Grids & Sustainable Energy Systems Page – 34 of 42Smart Grids & Sustainable Energy Systems Synchronous generators deliver an AC component of fault current that reduces from a very-high “sub-transient” value to a high “transient” value to a lower “steady state” value, as shown: What happens when a short-circuit fault occurs on the 11kV busbar? If you add the AC & DC components together, you have an offset fault current with a “peak- make” value that is 2 – 3x the “peak-break” value It also delivers a DC component, which is actually an exponential defined by X/R, it can start with a magnitude equal to the peak value of the AC sub-transient current, as shown: Page – 35 of 42Smart Grids & Sustainable Energy Systems Heat maps demonstrate effect of FCLs on Fault Levels at/near Castle Bromwich, Chester Street & Bournville Primary Substations Three network arrangements are considered: Page – 36 of 42Smart Grids & Sustainable Energy Systems • Fault Current Limiters (FCL) allow the 11kV network to operate in parallel (i.e. multiple 132/11kV transformers) and distributed generators supply each 11kV busbar. • Improves reliability & reduces customer minutes lost, i.e. single 132/11kV transformer can trip, without disconnecting load. • However, Fault Current limiters are large and expensive, and simpler solutions are possible. • Probably explains why Fault Current Limiters are not “business as usual” on DNO networks. • I believe fault current monitoring is needed in areas that include synchronous Distributed Generators or where the fault level is close to the breaker “making or breaking” capacity. • Information from fault current monitor could be used to control how a fault is cleared. • If the 3-phase fault current is above breaker capacity, perhaps the busbar could be split, or the DG disconnected, prior to tripping the main breaker. Bournville Resistive Superconducting Fault Current Limiter (Nexan) FlexDGrid: Fault Level Management using Fault Current Limiters Page – 37 of 42Smart Grids & Sustainable Energy Systems Network Innovation Allowance & Competition • Sharing knowledge from innovation projects ensures UK customers benefit from the money invested by network companies. • Electricity Network Association facilitates shared learning through the online Smarter Networks Portal, which is a repository from the findings from LCNF, NIA and NIC projects. • Wealth of information is provided across key themes in transmission and distribution of gas and electricity. • Portal illustrates how different network innovations will contribute to the UK energy future and helps all appreciate why networks are the most dynamic and exciting aspect of our energy industry. • As UK moves forward, continued innovation via the regulatory framework will be crucial if the UK is to build on the strong start that it has made in the development of future • Much has been achieved, but there is still a great deal of opportunity to deliver value and savings to customers as new challenges for network companies evolve in the coming years. Page – 38 of 42Smart Grids & Sustainable Energy Systems Energy Networks Association’s (ENA) Smarter Networks Portal is a central repository for regulation-funded innovation projects and associated outputs, data, knowledge, news and dissemination events. ENA Innovation Portal (energynetworks.org) Smarter Networks Portal: • Provides single location for all Ofgem funded Gas & Electricity Innovation Projects • Provides overview of projects, including scope, location, costs, partners and more • Allows anyone to follow progress and explore outputs • Promotes communication between Networks and Innovators • Facilitates innovators to receive calls for ideas and specific requests from Networks • Provides the opportunity to pitch your innovation ideas directly to ENA and the Network Innovation Managers at • Promotes sharing of information, including datasets from the output of projects • Provides weekly email updates on projects, refined by individuals chosen interest areas Page – 39 of 42Smart Grids & Sustainable Energy Systems 2015 - 2020, Celsius Project (Electricity North West) = £5.5M Celsius is an innovative, cost-effective approach to managing potentially excessive temperatures at distribution substations, which may constrain the connection of low carbon technologies. By delivering new solutions to manage these ‘thermal pinch points’, Celsius releases additional capacity from existing assets, reduces long-term costs for customers and avoids early asset replacement. Page – 40 of 42Smart Grids & Sustainable Energy Systems https://smarter.energynetworks.org/ Page – 41 of 42Smart Grids & Sustainable Energy Systems This project looked to explore the public perception of consultations for large infrastructure projects and address the research problem of underlying public disengagement with this process. The research carried out in this project contributes conceptually, methodologically and empirically to addressing the research problem through a high voltage overhead powerline case study research design in Cumbria. The outcomes from this research are both theoretical and empirical. The conceptual framework and research methods (theoretical) have contributed to a novel academic approach to investigating public engagement with the energy industry and the empirical output will help to inform the development of public engagement strategies in practice. https://smarter.energynetworks.org/ Page – 42 of 42Smart Grids & Sustainable Energy Systems Net-Zero Energy needs secure measurements, control & communications Any Questions?