Energy autonomy in residential buildings: A techno-economic model-based analysis of the scale effects

McKenna, Russell; Merkel, Erik; Fïchtner, Wolf

doi:10.1016/j.apenergy.2016.03.062

Cited by 71 publications

(34 citation statements)

References 20 publications

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“…Community electricity generation and storage systems could consist of one larger installation paid for and utilized by the whole energy community rather than several distributed installations as assumed in this work. Including economies of scale for investments in community‐size, as compared to household‐size, items of equipment is of particular relevance if thermal generation, as exemplified by local combined heat and power plants, is included in the analysis, potentially making electricity self‐sufficiency more beneficial for larger aggregations of residential households, as compared to individual households …”

Section: Discussionmentioning

confidence: 99%

“…To provide frameworks and trajectories with the goal of establishing a more active role for electricity users in the energy system, a better understanding is needed as to what functions self‐consumption and the aggregation of electricity consumers on different scales will have in a future electricity system. 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 .…”

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: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

et al. 2019

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“…Other than to mention that the economic optimization does not necessarily determine the most environmentally optimum configuration, other related weaknesses are not included here. Instead the reader is referred to Merkel et al (2015) and McKenna et al (2016), in which they are discussed at length.…”

Section: B Discussion Of Methodology and Further Workmentioning

confidence: 99%

“…Most of these studies employ optimisation and/or simulation approaches that depict the building's physical and thermal characteristics in detail yet do not differentiate between (types of) households. For a detailed discussion the reader is referred to McKenna et al (2016).…”

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confidence: 99%

Analysing socioeconomic diversity and scaling effects on residential electricity load profiles in the context of low carbon technology uptake

et al. 2016

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Adequately accounting for interactions between Low Carbon Technologies (LCTs) at the building level and the overarching energy system means capturing the granularity associated with decentralised heat and power supply in residential buildings. The approach presented here adds novelty in terms of a realistic socioeconomic differentiation by employing dwelling/household archetypes (DHAs) and neighbourhood clusters at the Output Area (OA) level. These archetypes are combined with a mixed integer linear program (MILP), which is used to generate optimum (minimum cost) technology configurations and operation schedules. Even in the baseline case, i.e. without any LCT penetration, a substantial deviation from the standard load profile (SLP) is encountered, suggesting that for some neighbourhoods this profile is not appropriate. With the application of LCTs this effect is much stronger, including more negative residual load, more variability, and higher ramps with increased LCT penetration, and crucially different between neighbourhood clusters. The main policy implication of the study is the importance of understanding electrical load profiles at the neighbourhood level, because of the consequences they have for investment in the overarching energy system (e.g. transmission and distribution infrastructure, centralised generation plant etc.). Further work should focus on attaining a superior socioeconomic differentiation between households.

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“…A systematic review on the cost of CHP system for Europe, Asia, and the USA has been reported by Staffell et al The study concludes that a long-term target of $300-5000 for 1-2 kW fuel cell micro-CHP system is more realistic and attainable by 2020 [ total turb turbine sys system energy autonomy in residential buildings. A mixed integer linear program is utilized to minimize the system cost over the lifetime of various energy production systems such as micro-CHP, photovoltaic (PV), thermal and electrical storage, and boilers, at five distinct scales and for nine demand cases [22].…”

Section: Introductionmentioning

confidence: 99%

Thermodynamic analysis on the part-load performance of a microturbine system for micro/mini-CHP applications

et al. 2016

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Energy autonomy in residential buildings: A techno-economic model-based analysis of the scale effects

Cited by 71 publications

References 20 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

Analysing socioeconomic diversity and scaling effects on residential electricity load profiles in the context of low carbon technology uptake

Thermodynamic analysis on the part-load performance of a microturbine system for micro/mini-CHP applications

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