Model predictive control of smart districts participating in frequency regulation market: a case study of using heating network storage

Abstract

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Flexibility provided by Combined Heat and Power (CHP) units in district heating networks is an important means to cope with increasing penetration of intermittent renewable energy resources, and various methods have been proposed to exploit thermal storage tanks installed in these networks. This paper studies a novel problem motivated by an example of district heating and cooling networks in Japan, where high-temperature steam is used as the heating medium. In steam-based networks, storage tanks are usually absent, and there is a strong need to utilize thermal inertia of the pipeline network as storage. However, this type of use of a heating network directly affects the operating condition of the network, and assuring safety and supply quality at the use side is an open problem. To address this, we formulate a control problem to utilize CHP units in frequency regulation market while satisfying physical constraints on a steam network described by a nonlinear model capturing dynamics of heat flows and heat accumulation in the network. Furthermore, a Model Predictive Control (MPC) framework is proposed by consistently combining several nonlinear control techniques, and its closed-loop behaviour is analysed through a two-site benchmark example. The proposed MPC controller is computationally efficient and shown to work in real time.

Keywords

• multi-energy systems
• ancillary services
• combined heat and power
• microgrid
• nonlinear dynamical model