Abstract
This chapter describes a framework to synthesize provably stable local Volt/Var controllers for distributed energy resources (DERs) in power distribution grids (DGs). The goal is to control the reactive power injections of DERs to improve the system performance as quantified by a generic optimal reactive power flow (ORPF) problem. To achieve this, we jointly design for each DER the control function, which prescribes the reactive power update rule, and the equilibrium function, which approximates the ORPF solutions from local measurements of voltages and powers. We provide conditions on the equilibrium functions and the control parameters ensuring the stability of the closed-loop system. In particular, we discuss the trade-offs between each set of conditions accounting for practical considerations, like fully exploiting the DERs' generation capabilities and reducing the optimality gap. These conditions are then translated into learning constraints on the neural networks' parameters that are enforced in the training phase. We validate our framework with numerical simulations on the IEEE 37-bus network and through a comparison with an optimized version of standard piece wise linear control rules.
Original language | American English |
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Title of host publication | Big Data Application in Power Systems, Second Edition |
Editors | R. Arghandeh, Y. Zhou |
Pages | 135-159 |
DOIs | |
State | Published - 2024 |
NREL Publication Number
- NREL/CH-5D00-89146
Keywords
- closed-loop asymptotic stability
- distributed energy resources
- distribution grids
- local Volt/Var control
- machine learning