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Abstract
Low voltage network design and planning in the UK operates in accordance with the Electricity Regulations and the Distribution code and has utilised the same general principles for many years. The approach is primarily concerned with providing a secure, good quality supply and relies on the techniques of After Diversity Maximum Demand and the ‘statistical method’ for estimating load demand.
In recent years the prospect of increased levels of low carbon technology such as micro-generation, electric vehicles, electric space/water heating and demand side management has been the focus of studies addressing the impact on existing LV networks and also regulations for new LV network developments. These studies have shown varying levels of voltage and reverse power flow problems arising on case study networks and have used a variety of approaches to LV network modelling and load estimation.
The use of feed-in tariffs for micro-generation, plus policy to shift energy demand to electricity from sectors such as transport and heating, increases the likelihood of significant changes in the LV network operating conditions in the near future and will create a situation that current LV planning approaches are ill-equipped to deal with.
In addition, aggregation (Virtual Power Plants) and active control of demand are areas of significant research with the aim of harnessing the potential contribution of distributed energy resources connected to the LV network. As such, the design and planning of future networks will be required to consider the influence of these schemes.
This paper presents functionality likely to be required by network planners and discusses the key components of a probabilistic planning framework that allows a DNO to analyse the need for, operation of, and value provided by DNO led Demand Side Management.
LV modelling techniques are reviewed and the requirements of an LV modelling tool in the planning framework are examined. Probabilistic approaches to evaluating LV network scenarios are discussed and the required load and generation information are considered, including the use of smart meter data, forecasting, scenarios, stochastic data and time-series profiles. The requirements for data collection, analysis and processing for varying degrees of functionality are weighed against the benefit provided. Possible LV control schemes are considered and methods of presenting the potential network services to planning engineers are investigated. Modelling that allows the planner to assess the impact of these control schemes and include the proposed services in a planning design is also explored.
A probabilistic analysis of a case study LV network with varying penetrations of electric vehicles, electric space and water heating, and supplier-led DSM schemes is used to develop components of the planning framework and inform the discussion areas described above.
In recent years the prospect of increased levels of low carbon technology such as micro-generation, electric vehicles, electric space/water heating and demand side management has been the focus of studies addressing the impact on existing LV networks and also regulations for new LV network developments. These studies have shown varying levels of voltage and reverse power flow problems arising on case study networks and have used a variety of approaches to LV network modelling and load estimation.
The use of feed-in tariffs for micro-generation, plus policy to shift energy demand to electricity from sectors such as transport and heating, increases the likelihood of significant changes in the LV network operating conditions in the near future and will create a situation that current LV planning approaches are ill-equipped to deal with.
In addition, aggregation (Virtual Power Plants) and active control of demand are areas of significant research with the aim of harnessing the potential contribution of distributed energy resources connected to the LV network. As such, the design and planning of future networks will be required to consider the influence of these schemes.
This paper presents functionality likely to be required by network planners and discusses the key components of a probabilistic planning framework that allows a DNO to analyse the need for, operation of, and value provided by DNO led Demand Side Management.
LV modelling techniques are reviewed and the requirements of an LV modelling tool in the planning framework are examined. Probabilistic approaches to evaluating LV network scenarios are discussed and the required load and generation information are considered, including the use of smart meter data, forecasting, scenarios, stochastic data and time-series profiles. The requirements for data collection, analysis and processing for varying degrees of functionality are weighed against the benefit provided. Possible LV control schemes are considered and methods of presenting the potential network services to planning engineers are investigated. Modelling that allows the planner to assess the impact of these control schemes and include the proposed services in a planning design is also explored.
A probabilistic analysis of a case study LV network with varying penetrations of electric vehicles, electric space and water heating, and supplier-led DSM schemes is used to develop components of the planning framework and inform the discussion areas described above.
Original language | English |
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Title of host publication | CIRED 2012 Workshop Integration of Renewables into the Distribution Grid |
Number of pages | 4 |
DOIs | |
Publication status | Published - 30 May 2012 |
Event | CIRED 2012 Workshop - Integration of Renewables into the Distribution Grid - Lisobon, Portugal Duration: 29 May 2012 → 30 May 2012 |
Conference
Conference | CIRED 2012 Workshop - Integration of Renewables into the Distribution Grid |
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Country/Territory | Portugal |
City | Lisobon |
Period | 29/05/12 → 30/05/12 |
Keywords
- demand side management
- power system planning
- low carbon technology
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