Potential for Domestic Dynamic Demand-Side Management in the UK

Infield, David; Short, John A.; Home, C.; Freris, L.L.

doi:10.1109/pes.2007.385696

Cited by 46 publications

(30 citation statements)

References 4 publications

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“…Hot water can be stored in a cylinder at 60°C but the daily space heating requirement of a dwelling far exceeds the storage capacity of a hot water cylinder of reasonable size, space heating demand being larger than water heating demand, (Infield et al 2007, Kalogirou 2004) Phase-change heat stores are promising, but may or may not the technology improvement required to make them attractive.…”

Section: Real and Virtual Energy Stores And Their Operationmentioning

confidence: 99%

The evolution of electricity demand and the role for demand side participation, in buildings and transport

Barton

Huang²,

Infield³

et al. 2013

Energy Policy

119

112

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This paper explores the possible evolution of UK electricity demand as we move along three potential transition pathways to a low carbon economy in 2050.The shift away from fossil fuels through the electrification of demand is discussed, particularly through the uptake of heat pumps and electric vehicles in the domestic and passenger transport sectors. Developments in the way people and institutions may use energy along each of the pathways are also considered and provide a rationale for the quantification of future annual electricity demands in various broad sectors.The paper then presents detailed modelling of hourly balancing of these demands in the context of potential low carbon generation mixes associated with the three pathways. In all cases, hourly balancing is shown to be a significant challenge. To minimise the need for conventional generation to operate with very low capacity factors, a variety of demand side participation measures are modelled and shown to provide significant benefits. Lastly, projections of greenhouse gas emissions from the UK and the imports of fossil fuels to the UK for each of the three pathways are presented.

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Section: Real and Virtual Energy Stores And Their Operationmentioning

confidence: 99%

The evolution of electricity demand and the role for demand side participation, in buildings and transport

Barton

Huang²,

Infield³

et al. 2013

Energy Policy

119

112

View full text Add to dashboard Cite

show abstract

“…Demand side management approaches are generally based on information on the appliance level (e.g. [13,14] modelling approach is therefore a logical choice for the assessment of demand side management (since the bottom-up approach allows for the shifting of individual appliances). Different value propositions exist for demand side management of residential loads, based on the self-consumption, electricity price or network loading.…”

Section: Introductionmentioning

confidence: 99%

Bottom-up Markov Chain Monte Carlo approach for scenario based residential load modelling with publicly available data

Nijhuis

Gibescu

Cobben

2016

Energy and Buildings

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“…In contrast, in the environment of a smart grid, the increasing employment of smart meters, intelligent appliances, and other intelligent terminal equipment provides abundant dynamic information to secure and stabilize the power grid, thereby enabling the power loads to actively participate in more advanced applications (especially in load shifting [6,7] and frequency regulation [8][9][10][11][12]) in response to a price signal or an event trigger. Because all of the existing applications of active load control are performed over a relatively long time scale (at least at the minute level), there is widespread interest discovering whether these power loads can actively participate in handling the emergency situations of a power system, such as the frequency stability issue at the second or millisecond level.…”

Section: Introductionmentioning

confidence: 99%

Coordinated Scheme of Under-Frequency Load Shedding with Intelligent Appliances in a Cyber Physical Power System

et al. 2016

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Abstract:The construction of a cyber physical system in a power grid provides more potential control strategies for the power grid. With the rapid employment of intelligent terminal equipment (e.g., smart meters and intelligent appliances) in the environment of a smart grid, abundant dynamic response information could be introduced to support a secure and stable power system. Combining demand response technology with the traditional under-frequency load shedding (UFLS) scheme, a new UFLS strategy-determining method involving intelligent appliances is put forward to achieve the coordinated control of quick response resources and the traditional control resources. Based on this method, intelligent appliances can be used to meet the regulatory requirements of system operation in advance and prevent significant frequency drop, thereby improving the flexibility and stability of the system. Time-domain simulation verifies the effectiveness of the scheme, which is able to mitigate frequency drop and reduce the amount of load shedding.

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Potential for Domestic Dynamic Demand-Side Management in the UK

Cited by 46 publications

References 4 publications

The evolution of electricity demand and the role for demand side participation, in buildings and transport

The evolution of electricity demand and the role for demand side participation, in buildings and transport

Bottom-up Markov Chain Monte Carlo approach for scenario based residential load modelling with publicly available data

Coordinated Scheme of Under-Frequency Load Shedding with Intelligent Appliances in a Cyber Physical Power System

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