Community energy storage: A smart choice for the smart grid?

Barbour, Edward; Parra, David; Awwad, Zeyad; González, Marta C.

doi:10.1016/j.apenergy.2017.12.056

Cited by 208 publications

(91 citation statements)

References 41 publications

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“…The present study optimizes prosumer PV battery investments and operation so as to minimize the cost for the prosumer. Analyzing a case with a fixed share of solar PV that is already installed (instead of joint optimization of PV and battery capacities as in our study), Barbour et al have shown that less storage capacity is required for a prosumer community energy storage system than for individual household storage systems, which is in line with the results of our study. In this work the incentive to avoid taxes and fees on bought electricity through local self‐consumption of electricity has a greater impact on the optimization and operation of PV battery investments than do the peaks and lows in the hourly electricity price.…”

Section: Discussionsupporting

confidence: 89%

“…Research has been conducted on the topics of energy autarky and self‐consumption on different scales, from individual buildings to neighborhoods and districts, as well as on the clustering of prosumers to optimize power grid operation and reduce costs . Community energy storage has been investigated in terms of economic benefits and possibilities to integrate renewable energy sources and demand‐side management . There have also been studies on the interactions that occur on local markets, the different energy carriers in a local energy community or energy hub, and the effects of different load curves on neighborhood clusters …”

Section: Introductionmentioning

confidence: 99%

“…23,24 Community energy storage has been investigated in terms of economic benefits and possibilities to integrate renewable energy sources and demand-side management. [25][26][27][28] There have also been studies on the interactions that occur on local markets, [29][30][31] the different energy carriers in a local energy community or energy hub, 32,33 and the effects of different load curves on neighborhood clusters. 34 The present study adds to the understanding of local grouping of residential prosumers of electricity through direct comparisons of investment and hourly operation of PV plus battery systems for (i) individual prosumers and (ii) prosumers acting as part of an electricity trading community, which has not been provided by studies cited above.…”

Section: Introductionmentioning

confidence: 99%

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Organizing prosumers into electricity trading communities: Costs to attain electricity transfer limitations and self‐sufficiency goals

et al. 2019

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Summary Among household electricity end users, there is growing interest in local renewable electricity generation and energy independence. Community‐based and neighborhood energy projects, where consumers and prosumers of electricity trade their energy locally in a peer‐to‐peer system, have started to emerge in different parts of the world. This study investigates and compares the costs incurred by individual households and households organized in electricity trading communities in seeking to attain greater independence from the centralized electricity system. This independence is investigated with respect to: (i) the potential to reduce the electricity transfer capacity to and from the centralized system and (ii) the potential to increase self‐sufficiency. An optimization model is designed to analyze the investment and operation of residential photovoltaic battery systems. The model is then applied to different cases in a region of southern Sweden for year 2030. Utilizing measured electricity demand data for Swedish households, we show that with a reduced electricity transfer capacity to the centralized system, already a community of five residential prosumers can supply the household demand at lower cost than can prosumers acting individually. Grouping of residential prosumers in an electricity trading community confers greater benefits under conditions with a reduced electricity transfer capacity than when the goal is to become electricity self‐sufficient. It is important to consider the local utilization of photovoltaic‐generated electricity and its effect on the net trading pattern (to and from the centralized system) when discussing the impact on the electricity system of a high percentage of prosumers.

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Section: Discussionsupporting

confidence: 89%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Organizing prosumers into electricity trading communities: Costs to attain electricity transfer limitations and self‐sufficiency goals

et al. 2019

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“…In the literature, a common way to describe renewable energy communities is as 'those projects where communities (of place or interest) exhibit a high degree of ownership and control in renewable energy production as well as benefiting collectively from the outcomes' [23]. Such communities for example consist of local energy cooperatives that develop collective energy practices [24], such as collectively generating solar energy for local use.…”

Section: New Collective Materials Practicesmentioning

confidence: 99%

Technologies of Engagement: How Battery Storage Technologies Shape Householder Participation in Energy Transitions

2019

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The transition to a low-carbon energy system goes along with changing roles for citizens in energy production and consumption. In this paper we focus on how residential energy storage technologies can enable householders to contribute to the energy transition. Drawing on literature that understands energy systems as sociotechnical configurations and the theory of ‘material participation’, we examine how the introduction of home batteries affords new roles and energy practices for householders. We present qualitative findings from interviews with householders and other key stakeholders engaged in using or implementing battery storage at household and community level. Our results point to five emerging storage modes in which householders can play a role: individual energy autonomy; local energy community; smart grid integration; virtual energy community; and electricity market integration. We argue that for householders, these storage modes facilitate new energy practices such as providing grid services, trading, self-consumption, and sharing of energy. Several of the storage modes enable the formation of prosumer collectives and change relationships with other actors in the energy system. We conclude by discussing how householders also face new dependencies on information technologies and intermediary actors to organize the multi-directional energy flows which battery systems unleash. With energy storage projects currently being provider-driven, we argue that more space should be given to experimentation with (mixed modes of) energy storage that both empower householders and communities in the pursuit of their own sustainability aspirations and serve the needs of emerging renewable energy-based energy systems.

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“…The effects of different factors are analyzed for a deeper understanding. More specifically, using the historical data of the Pecan Street smart community 8 and the corresponding weather information, a BPNN-based prediction has been conducted. The performances under different time resolutions, hourly, daily, weekly, and monthly, are investigated.…”

Section: Introductionmentioning

confidence: 99%

Electricity consumption forecasting for smart grid using the multi-factor back-propagation neural network

Song

Zhou

et al. 2019

Sensors and Systems for Space Applications XII

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With the development of modern information technology (IT), a smart grid has become one of the major components of smart cities. To take full advantage of the smart grid, the capability of intelligent scheduling and planning of electricity delivery is essential. In practice, many factors have an impact on electricity consumption, which necessitates information fusion technologies for a thorough understanding. For this purpose, researchers have investigated methodologies for collecting electricity consumption related information and variant multi-factor power consumption forecasting models. In addition, conducting a comprehensive analysis and obtaining an accurate evaluation of power consumption are the premise and basis for a more robust and efficient power grid design and transformation. Therefore, it is meaningful to explore forecasting models that are able to reflect the power consumption changes and internal relations within fusional information effectively. Making electricity consumption forecasting based on the neural network has been a popular research topic in recent years, and the back-propagation neural network (BPNN) algorithm has been recognized as a mature and effective method. In this paper, BPNN is adopted to forecast the electricity consumption using Pecan Street, a community with a relatively large-scale smart grid, as a case study, and takes multiple factors into account, such as weather condition, weekend and holidays. The influences of each factor have been evaluated for a deeper insight. We hope this work will inspire more discussion and further study to guide the design of future smart grids.

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Community energy storage: A smart choice for the smart grid?

Cited by 208 publications

References 41 publications

Organizing prosumers into electricity trading communities: Costs to attain electricity transfer limitations and self‐sufficiency goals

Organizing prosumers into electricity trading communities: Costs to attain electricity transfer limitations and self‐sufficiency goals

Technologies of Engagement: How Battery Storage Technologies Shape Householder Participation in Energy Transitions

Electricity consumption forecasting for smart grid using the multi-factor back-propagation neural network

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