Methodology for optimal energy system design of Zero Energy Buildings using mixed-integer linear programming

•The cost-optimal choice of energy technologies in a ZEB is determined.•Simultaneous optimisation of investments and hourly operation is performed.•How policies influence the energy technology choice, can be investigated.•By dividing the lifetime into periods, future changes are taken into account.•...

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Bibliographic Details
Published inEnergy and buildings Vol. 127; pp. 194 - 205
Main Authors Lindberg, Karen Byskov, Doorman, Gerard, Fischer, David, Korpås, Magnus, Ånestad, Astrid, Sartori, Igor
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.09.2016
Subjects
Demand side management (DSM)
Feed-in-tariffs (FiT)
Grid interaction
Load profiles
Self-consumption
Solar thermal
Storage
Load profiles
Feed-in-tariffs (FiT)
Storage
PV
Grid interaction
Self-consumption
Solar thermal
Demand side management (DSM)
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Summary:•The cost-optimal choice of energy technologies in a ZEB is determined.•Simultaneous optimisation of investments and hourly operation is performed.•How policies influence the energy technology choice, can be investigated.•By dividing the lifetime into periods, future changes are taken into account.•The ZEB’s grid interaction is analysed through the hourly net electric load profile. According to EU’s Energy Performance of Buildings Directive (EPBD), all new buildings shall be nearly Zero Energy Buildings (ZEB) from 2018/2020. How the ZEB requirement is defined has large implications for the choice of energy technology when considering both cost and environmental issues. This paper presents a methodology for determining ZEB buildings’ cost optimal energy system design seen from the building owner’s perspective. The added value of this work is the inclusion of peak load tariffs and feed-in-tariffs, the facilitation of load shifting by use of a thermal storage, along with the integrated optimisation of the investment and operation of the energy technologies. The model allows for detailed understanding of the hourly operation of the building, and how the ZEB interacts with the electricity grid through the characteristics of its net electric load profile. The modelling framework can be adapted to fit individual countries' ZEB definitions. The findings are important for policy makers as they identify how subsidies and EPBD’s regulations influence the preferred energy technology choice, which subsequently determines its grid interaction. A case study of a Norwegian school building shows that the heat technology is altered from HP to bio boiler when the ZEB requirement is applied.
ISSN:0378-7788
1872-6178
DOI:10.1016/j.enbuild.2016.05.039