Abstract
Over the last years, the role of the distribution system operator (DSO) has largely expanded. This is necessitated by the increased penetration of intermittent energy resources at the distribution level, as well as the new, more complex interactions with the transmission system operator (TSO). As such, to properly manage its system and to have an effective joint cooperation with the TSO, the DSO is required to procure and carefully manage flexibility services from distributed energy resources (DER). This paper introduces a thorough framework on optimal operational planning (day-ahead scheduling) and operational management (real-time dispatch) of active distribution systems under uncertainties, to avoid line congestions and voltage limit violations, and efficiently balance the distribution system. A two-stage stochastic programming model based on weighted scenarios is proposed to optimize the multi-period optimal power flow day-ahead scheduling, i.e., scheduled power flows at the TSO-DSO interface and reserved DER flexibility services. Subsequently, the operational management, realized with a predictive real-time dispatch model based on a constantly updated rolling horizon, aims to efficiently activate the available flexibility services to minimize deviations from the committed schedule. Different sources of flexibility are considered, with their respective response times also taken into account at real-time dispatch. The proposed framework is applied on two distribution systems and investigates the DSO’s level of risk exposure while minimizing its total cost (reservation and activation expenses). The results indicate that a less conservative approach at planning stage, despite the potential risk exposure, can lead to significant reduction in total expenses.
Highlights
The ever-increasing integration of renewable distributed energy resources (DER) due to the deregulation of the energy market creates more challenges for the distribution system operator (DSO), as high levels of uncertainty are introduced into the electrical power system, especially at the distribution level
This paper aims to propose a comprehensive framework of flexibility services management for the DSO
PROPOSED FRAMEWORK FOR FLEXIBILITY SERVICES MANAGEMENT This paper proposes a framework for optimal operational planning (DAS stage) and optimal operational management (RTD stage) of active distribution systems by means of congestion management and system balancing, while maximizing the active power injection from RES
Summary
The ever-increasing integration of renewable DER due to the deregulation of the energy market creates more challenges for the DSO, as high levels of uncertainty are introduced into the electrical power system, especially at the distribution level. Apart from the traditional problem of voltage control in passive distribution systems, the issue of congestion management has attracted significant attention. In adhering with the future smart grid vision [1], active distribution systems are expected to host very high shares of renewable technologies, which have been noted to cause substantial thermal issues if left uncontrolled. The DSO can utilize DER flexibility to optimize its system’s voltage profile, manage local congestions [7], and generally optimize the operation of smart distribution networks through ANM schemes [8]
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