Abstract
District heating systems (DHSs) play an important role for urban areas as they enable an efficient and cost-effective heat supply. Existing DHSs are primarily based on fossil fuel energy and therefore need to be transformed in the coming years to meet the climate goals of the Paris Agreement. Lowering system temperatures is relevant to convert the fossil-based generation to renewable energy sources. However, there is a lack of a systemic methodology that can properly promote the required changes of the system temperatures during operation. This paper contributes a first part to such a methodology: a method to evaluate the average variable costs of heating plants that supply DHSs. The novelty of the approach lies in a systematic way to consider the impact of supply temperature and momentary thermal power on the variable costs of a plant. The method’s requirements, application, results, and conclusions are demonstrated in three case studies of renewable heating plants: a solar thermal, a geothermal and an industrial surplus heating plant. The specific results of these case studies show that different set-points for the supply temperature and for thermal power of each plant have an impact on the variable cost of production. A comparison of the results demonstrates that the method increases the cost transparency in general. It is concluded that the supply temperature should be used as a variable in the operational optimization in DHSs. Further, the method should be part of a more comprehensive methodology for entire DHS infrastructures including storages, the network, and the customers.
Highlights
The goal of the Paris Agreement is to limit global warming preferably to 1.5 ◦C by a drastic reduction of global greenhouse gas emissions [1]
This paper contributes a first part to such a methodology: a method to evaluate the average variable costs of heating plants that supply district heating systems (DHSs)
In modern district heating systems (DHSs), low supply temperatures are key to the integration of renewable heat sources
Summary
The goal of the Paris Agreement is to limit global warming preferably to 1.5 ◦C by a drastic reduction of global greenhouse gas emissions [1]. The International Energy Agency reports that the heating sector contributed one half to the global final energy consumption in 2019 [2]. The share of renewable sources in the heating sector was estimated with 11 % and the still dominant fossil fuels emit 40 % of the global CO2 emissions. The United Nations Environmental Programme described district heating (DH) as “a best practice approach” for an efficient, affordable, and ecologic heat supply in urban areas [3]. The supply for district heating systems (DHSs) must be transformed to renewable heat sources which have to be smoothly integrated into existing systems. Lund et al define four generations of district heating (GDH) [4], whereas the 4th generation (4GDH) is based on renewable heat sources which require low system temperatures. In existing systems of older generations, barriers that come from technical restrictions [5] as well as economical lock-in effects caused by the low cost sensitivity for higher temperatures of the existing conventional technologies [6] hinder the lowering of the systems’ temperatures
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