Abstract
Power system operators must schedule the available generation resources required to achieve an economical, reliable, and secure energy production in power systems. This is usually achieved by solving a security-constrained unit commitment (SCUC) problem. Through a SCUC the System Operator determines which generation units must be on and off-line over a time horizon of typically 24 h. The SCUC is a challenging problem that features high computational cost due to the amount and nature of the variables involved. This paper presents an alternative formulation to the SCUC problem aimed at reducing its computational cost using sensitivity factors and user cuts. Power Transfer Distribution Factors (PTDF) and Line Outage Distribution Factors (LODF) sensitivity factors allow a fast computation of power flows (in normal operative conditions and under contingencies), while the implementation of user cuts reduces computational burden by considering only biding N-1 security constraints. Several tests were performed with the IEEE RTS-96 power system showing the applicability and effectiveness of the proposed modelling approach. It was found that the use of Linear Sensitivity Factors (LSF) together with user cuts as proposed in this paper, reduces the computation time of the SCUC problem up to 97% when compared with its classical formulation. Furthermore, the proposed modelling allows a straightforward identification of the most critical lines in terms of the overloads they produce in other elements after an outage, and the number of times they are overloaded by a fault. Such information is valuable to system planners when deciding future network expansion projects.
Highlights
The electric power sector is currently facing rapid changes, mostly related to the integration of renewable energy resources and the new trend of smart grids
When post-contingency constraints are included in the unit commitment (UC) formulation, this one is turned into a security-constrained unit commitment (SCUC) problem
To show the applicability of the proposed modelling approach several tests were performed using the IEEE RTS-96 for a time horizon of 24 h. This power system is made of 73 buses, 120 transmission lines, 96 thermal generators, and 51 loads that add up a maximum demand of 7539 MW
Summary
The electric power sector is currently facing rapid changes, mostly related to the integration of renewable energy resources and the new trend of smart grids. A method for estimating these sensitivity factors based on near-real-time measurements and their applications can be found in [42] Despite advantages of these linear factors, ref [43] proposes a new formulation to reduce the number of variables and constraints to speed up the SCUC solution in large-scale power systems, using. The user cuts approach proposed in this paper serves as umbrella constraints which results in a considerable computational burden reduction when considering N-1 security constraints This is because most of the N-1 contingency constraints are superfluous and do not set up the feasibility space of the SCUC problem [9].
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