Technical and economic comparison of grid supportive vanadium redox flow batteries for primary control reserve and community electricity storage in Germany

Resch, Matthias; Bühler, Jochen; Schachler, Birgit; Kunert, Rita; Meier, Andreas; Sumper, Andreas

doi:10.1002/er.4269

Cited by 38 publications

(21 citation statements)

References 40 publications

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“…For the grid losses, 64 EUR/MWh are agreed with the DSO of the pilot region. The cost for the additional energy required to provide reactive power control is set to 56 EUR/MWh for the large scale BSS [15].…”

Section: B Economic Comparison Of the Flexibility Optionsmentioning

confidence: 99%

“…This study is based on an extensive review of operation strategies for PCR and self-consumption maximisation of the same authors [2], [13], [14]. Derived from these reviews, the two technically and economically most promising system/ grid supportive operation strategies for PCR and CES were applied and analysed for the VRFB prototype [15]. In this paper, the impact of these two operation strategies on distribution grid planning are compared along with cosϕ(P)-control and Q(V)control of PV systems and RES.…”

Section: Introductionmentioning

confidence: 99%

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Techno-Economic Assessment of Flexibility Options Versus Grid Expansion in Distribution Grids

Resch

Bühler

Schachler

et al. 2021

IEEE Trans. Power Syst.

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In this paper five different flexibility options are analysed from a techno-economic perspective as alternatives to traditional grid expansion for a specific distribution grid in Germany. The options are: two reactive power control strategies with photovoltaic inverters (as a function of the power feed-in, or of the voltage at the connection point), one residential and two large scale battery storage applications (primary control reserve with autonomous reactive power control or self consumption maximisation strategy with autonomous reactive power control). For the pilot grid located in Southern Germany a photovoltaic expansion pathway is determined. The main goal of this work is to quantify the grid expansion actions that can be avoided by applying these five flexibility options for the assumed expansion pathway, focusing on large scale battery storages. It is shown that the five flexibility options increase the hosting capacity for PV systems, compared to a scenario without, by up to 45 %. Furthermore, the results of the economic assessment indicate that the analysed flexibility options might be a viable alternative to traditional grid expansion as all of them show a cost reduction potential for the pilot region. These results could encourage DSOs to consider the integration of additional PV and battery storage systems not as a problem which triggers grid expansion, but as part of the solution reducing future grid expansion costs.

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Section: B Economic Comparison Of the Flexibility Optionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Techno-Economic Assessment of Flexibility Options Versus Grid Expansion in Distribution Grids

Resch

Bühler

Schachler

et al. 2021

IEEE Trans. Power Syst.

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“…[13] presents an analysis of operating central storage units directly connected to mediumvoltage grids to provide power system services. [14] compares the technical service provision to self-consumption maximization service using a centralised battery at distribution level. However, [13], [14] do not consider distributed batteries at prosumer level which can change their operation with an economic incentive mechanism.…”

Section: B Aggregated Flexibility Servicesmentioning

confidence: 99%

Centralised and Distributed Optimization for Aggregated Flexibility Services Provision

Olivella‐Rosell

Rul⋅lan

Lloret-Gallego

et al. 2020

IEEE Trans. Smart Grid

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The recent deployment of distributed battery units in prosumer premises offer new opportunities for providing aggregated flexibility services to both distribution system operators and balance responsible parties. The optimization problem presented in this paper is formulated with an objective of cost minimization which includes energy and battery degradation cost to provide flexibility services. A decomposed solution approach with the alternating direction method of multipliers (ADMM) is used instead of commonly adopted centralised optimization to reduce the computational burden and time, and then reduce scalability limitations. In this work we apply a modified version of ADMM that includes two new features with respect to the original algorithm: first, the primal variables are updated concurrently, which reduces significantly the computational cost when we have a large number of involved prosumers; second, it includes a regularization term named Proximal Jacobian (PJ) that ensures the stability of the solution. A case study is presented for optimal battery operation of 100 prosumer sites with real-life data. The proposed method finds a solution which is equivalent to the centralised optimization problem and is computed between 5 and 12 times faster. Thus, aggregators or large-scale energy communities can use this scalable algorithm to provide flexibility services.

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“…Techno-economic feasibility models have been recently reviewed [40]; most of them centre on capital cost, stressing the significant role of vanadium reactants, and revealing wide variability in the assumed prices of membranes and ancillary equipment. Recently, two models for grid-level energy storage, one in Germany [41], and the other in the USA [42], concluded that RFB investment costs should be reduced by 20-30%, in order to remain competitive. Notably, a model for the implementation of large-area electrodes has estimated potential cost reductions of about 25% [43], while new models could establish up-to-date cost and financing targets by taking into account new electrolyte leasing schemes [6].…”

Section: Mathematical Modellingmentioning

confidence: 99%

Redox flow batteries for energy storage: their promise, achievements and challenges

Arenas

León

Walsh

2019

Current Opinion in Electrochemistry

151

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Redox flow batteries continue to be developed for utility-scale energy storage applications. Progress on standardisation, safety and recycling regulations as well as financing has helped to improve their commercialisation. The technical progress of redox flow batteries has not considered adequately the significance of electrolyte flow velocity, mass transfer and plug flow reactor modelling, despite steps in the right direction. 3D simulations of fluid flow, pressure drop, current distribution and mechanical resistance using commercial software are becoming more common, but satisfactory validation by experiments is still unusual. The majority of research tends to report short term studies on small electrodes, often in poorly defined flow channels; long term evaluation of electrode and membrane durability on a pilot scale is needed. Digital imaging of electrode structure using X-ray computed tomography is increasingly being used. Much activity is directed to organic and non-aqueous systems. However, scale-up and high, sustained charge capacity using electrolytes of moderate cost which are environmentally acceptable to source, store, transport and handle require considerable attention. Recommendations for future work are discussed.

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Technical and economic comparison of grid supportive vanadium redox flow batteries for primary control reserve and community electricity storage in Germany

Cited by 38 publications

References 40 publications

Techno-Economic Assessment of Flexibility Options Versus Grid Expansion in Distribution Grids

Techno-Economic Assessment of Flexibility Options Versus Grid Expansion in Distribution Grids

Centralised and Distributed Optimization for Aggregated Flexibility Services Provision

Redox flow batteries for energy storage: their promise, achievements and challenges

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