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A stochastic MPEC approach for grid tariff design with demand-side flexibility

Abstract

As the end-users increasingly can provide fexibility to the power system, it is
important to consider how this fexibility can be activated as a resource for the grid.
Electricity network tarifs is one option that can be used to activate this fexibility.
Therefore, by designing efcient grid tarifs, it might be possible to reduce the total
costs in the power system by incentivizing a change in consumption patterns. This
paper provides a methodology for optimal grid tarif design under decentralized
decision-making and uncertainty in demand, power prices, and renewable generation. A bilevel model is formulated to adequately describe the interaction between
the end-users and a distribution system operator. In addition, a centralized decisionmaking model is provided for benchmarking purposes. The bilevel model is reformulated as a mixed-integer linear problem solvable by branch-and-cut techniques.
Results based on both deterministic and stochastic settings are presented and discussed. The fndings suggest how electricity grid tarifs should be designed to provide an efcient price signal for reducing aggregate network peaks.
Keywords Bilevel problem · Grid tarifs · Mathematical program with equilibrium
constraints (MPEC) · Uncertainty
© The Author(s) 2020
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Category

Academic article

Client

  • Research Council of Norway (RCN) / 272398
  • Research Council of Norway (RCN) / 257660

Language

English

Author(s)

Affiliation

  • Norwegian University of Science and Technology
  • SINTEF Energy Research / Energisystemer
  • Technical University Berlin
  • German Institute for Economic Research
  • University of Maryland

Year

2020

Published in

Energy Systems, Springer Verlag

ISSN

1868-3967

Publisher

Springer

Volume

14

Page(s)

707 - 729

View this publication at Cristin