Abstract
Renewable distributed generation will be a key component of future power distribution networks. In order to control the voltage conditions for distribution networks integrated with distributed generation (DG) units, it is vital to quantify the impacts of control variables on voltage magnitudes under consumption and generation uncertainties. To do so, we need to run, for each control action, several power flow simulations for various consumption and generation realizations. This is computationally infeasible for systems with many uncertain inputs. In this work, we address this challenge by developing surrogates, or metamodels, that analytically estimate the random voltage as a function of input variables which include random parameters (consumption and generation levels) and control actions (power factors). Specifically, we propose a model reduction method for building these surrogates, which reduces the number of simulations needed for training. This method identifies and includes only the consumption and generation variables that are influential on the voltage at a given bus. Using this `reduced' surrogate, we then develop a sensitivity-based approach for probabilistic voltage control. We demonstrate the computational efficacy of the control approach on a IEEE 69-bus system with a large number of correlated input parameters. The highlights of computational efficiency in this case study include (1) accurate probabilistic power flow analysis using surrogates constructed by only 500 training simulations for a system with more than 150 random parameters, and (2) successful surrogate-based voltage control approach which only requires 150 additional simulation samples, as opposed to the conventional perturb-and-observe voltage control which needs more than 500,000 samples.
Highlights
In the future, power distribution will involve large penetration of renewable distributed generation (DG) units, due to shortages of fossil fuel shortage, greenhouse gas emissions from fossil fuels, technology development, cost reduction, and government incentives [1]
We focus on the voltage control problem and introduce a surrogate-based sensitivity analysis framework that efficiently evaluates how changes in active and reactive power of DGs will impact the voltage profile of the network
1) GENERATION UNCERTAINTY In this work, we consider small units of DGs that operate at a constant power factor as the uncontrollable DGs, for which the reactive power cannot be controlled
Summary
Power distribution will involve large penetration of renewable distributed generation (DG) units, due to shortages of fossil fuel shortage, greenhouse gas emissions from fossil fuels, technology development, cost reduction, and government incentives [1]. The penetration of DG units can result in an increase in power supply capacity and a reduction in transmission loss [3]. Despite the advantages of DG integration, they pose major planning and operation challenges. The main operation challenges are voltage control, grid protection and fault level [4]. We focus on the voltage control problem and introduce a surrogate-based sensitivity analysis framework that efficiently evaluates how changes in active and reactive power of DGs will impact the voltage profile of the network
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