Abstract
District heating systems become more distributed with the integration of prosumers, including excess heat producers and active consumers. This calls for suitable heat market mechanisms that optimally integrate these actors, while minimizing and allocating operational costs. We argue for the inclusion of network constraints to ensure network feasibility and incentivize loss reductions. We propose a network-aware heat market as a Quadratic Program (QP), which determines the optimal dispatch and a set of nodal marginal prices. While heat network dynamics are generally represented by non-convex constraints, we convexify this formulation by fixing temperature variables and neglecting pumping power. The resulting variable flow heating network model leaves the sign and size of the nodal heat injections flexible, which is important for the integration of prosumers. The market is based on peer-to-peer trades to which we add explicit loss terms. This allows us to trace network losses back to the producer and consumer of these losses. Through a dual analysis we reveal loss components of nodal prices, as well as relations between nodal prices and between seller and buyer prices. A case study illustrates the advantages of the network-aware market by comparison to our proposed loss-agnostic benchmark. We show that the network-aware market mechanism effectively promotes local heat consumption and thereby reduces losses and total cost. We conclude that the proposed loss-aware market mechanism can help reduce operating costs in district heating networks while integrating prosumers.
Highlights
District heating is expected to play an important role in future carbon neutral energy systems, especially in urban areas [1]
District heating systems become more distributed with the integration of prosumers, including excess heat producers and active consumers
This calls for suitable heat market mechanisms that optimally integrate these actors, while minimizing and allocating operational costs
Summary
District heating is expected to play an important role in future carbon neutral energy systems, especially in urban areas [1]. Through a district heating network, excess heat from industrial processes can be distributed to households, thereby facilitating the decarbonization of heat generation. Example sources of excess heat include supermarkets and data centers that produce heat as a by-product of their refrigeration or cooling system. Studies show that households can provide such flexibility, among others using the virtual heat storage of buildings [2]. The presence of excess heat producers and active consumers marks the rise of the prosumer in heating systems, a new market participant that has already gained interest in power systems. Prosumers are defined as proactive consumers that may possess assets for local energy generation, conversion and/or storage [3]. For instance, heat accumulators, heat pumps, and solar collectors
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