Strategic Capacity Withholding by Energy Storage in Electricity Markets
File(s)
Author(s)
Ye, Y
Papadaskalopoulos
Moreira
strbac
Type
Conference Paper
Abstract
Abstract:
Although previous work has demonstrated the ability of large energy storage (ES) units to exercise market power by withholding their capacity, it has adopted modeling approaches exhibiting certain limitations and has not analyzed the dependency of the extent of exercised market power on ES operating properties. In this paper, the decision making process of strategic ES is modeled through a bi-level optimization problem; the upper level determines the optimal extent of capacity withholding at different time periods, maximizing the ES profit, while the lower level represents endogenously the market clearing process. This problem is solved after converting it to a Mathematical Program with Equilibrium Constraints (MPEC) and linearizing the latter through suitable techniques. Case studies on a test market quantitatively analyze the extent of capacity withholding and its impact on ES profit and social welfare for different scenarios regarding the power and energy capacity of ES.
Although previous work has demonstrated the ability of large energy storage (ES) units to exercise market power by withholding their capacity, it has adopted modeling approaches exhibiting certain limitations and has not analyzed the dependency of the extent of exercised market power on ES operating properties. In this paper, the decision making process of strategic ES is modeled through a bi-level optimization problem; the upper level determines the optimal extent of capacity withholding at different time periods, maximizing the ES profit, while the lower level represents endogenously the market clearing process. This problem is solved after converting it to a Mathematical Program with Equilibrium Constraints (MPEC) and linearizing the latter through suitable techniques. Case studies on a test market quantitatively analyze the extent of capacity withholding and its impact on ES profit and social welfare for different scenarios regarding the power and energy capacity of ES.
Date Issued
2017-07-20
Date Acceptance
2017-04-07
Citation
2017 IEEE Manchester PowerTech, 2017
Publisher
IEEE
Journal / Book Title
2017 IEEE Manchester PowerTech
Copyright Statement
© 2017 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting/republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other works.
Source
12th IEEE PES PowerTech Conference
Subjects
Science & Technology
Technology
Engineering, Electrical & Electronic
Engineering
Electricity markets
energy storage
market power
mathematical program with equilibrium constraints
SYSTEMS
WELFARE
Publication Status
Published
Start Date
2017-06-18
Finish Date
2017-06-22
Coverage Spatial
Manchester, UK