Author:

Keywords:

Building stock, Heat pump, Active Demand Response, Electricity generation, Integrated model, CO2-abatement cost, Science & Technology, Technology, Energy & Fuels, Engineering, Chemical, Engineering, Active demand response, WIND POWER INTEGRATION, CO2 EMISSIONS, ENERGY, SYSTEMS, ELECTRICITY, STORAGE, GENERATION, BUILDINGS, ABATEMENT, EXCESS, 09 Engineering, 14 Economics, Energy, 33 Built environment and design, 38 Economics, 40 Engineering

Abstract:

Heat pumps are widely recognized as a key technology to reduce CO2 emissions in the residential building sector, especially when the electricity-generation system is to decarbonize by means of large-scale introduction of renewable electric power generation sources. If heat pumps would be installed in large numbers in the future, the question arises whether all building types show equal benefits and thus should be given the same priority for deployment. This paper aims at answering this question by determining the CO2-abatement cost of installing a heat pump instead of a condensing gas boiler for residential space heating and domestic hot-water production. The electricity system, as well as the building types, are based on a possible future Belgian setting in 2030 with high RES penetration at the electricity-generation side. The added value of this work compared to the current scientific literature lies in the integrated approach, taking both the electricity-generation system and a bottom up building stock model into account. Furthermore, this paper analyzes the possible benefits of active demand response in this framework. The results show that the main drivers for determining the CO2-abatement cost are the renovation level of the building and the type of heat pump installed. For thoroughly insulated buildings, an air coupled heat pump combined with poor heating is the most economic heating system in terms of CO2-abatement cost. Finally, performing active demand response shows clear benefits in reducing costs. Substantial peak shaving can be achieved, making peak capacity at the electricity generation side superfluous, hence lowering the overall CO2-abatement cost.