Abstract
The important focus of the energy strategy of the European Union relies on the concept of zero energy building (ZEB), which is, by definition, a building that roughly produces yearly as much renewable energy as it consumes. This article proposes an enhanced mixed-integer nonlinear programming model for optimal sizing of photovoltaic (PV) and battery energy storage systems to comply with the definition of a ZEB. A salient novel feature of the proposed model is that it factors in the environmental impacts, computed through rigorous life cycle assessment methodology, of buying electricity from the grid and manufacturing battery and PV systems. Furthermore, an adjustable parameter is introduced to make the model adaptive from the perspective of the building owner's willingness-to-pay for environmental impacts. The proposed model is then rigorously reformulated, managing to accumulate its nonlinearity in only one constraint per time interval. Eventually, the reformulated model is linearized to a mixed-integer linear programming model using the McCormick relaxation technique. The case study conducted on archetypal buildings in Luxembourg reveals that the proposed McCormick-based linear model is able to provide high accuracy results with reasonable computational effort.
Highlights
T HE emission of greenhouse gases ( CO2) is an unavoidable consequence of using fossil fuels to produce electricity
The initial mixed-integer nonlinear programming (MINLP) model has been reformulated in an innovative manner so as to accumulate its nonlinearity in a single constraint per time interval
The reformulated model has been linearized to an mixed-integer linear programming (MILP) problem exploiting McCormick relaxation techniques
Summary
T HE emission of greenhouse gases ( CO2) is an unavoidable consequence of using fossil fuels to produce electricity. The literature survey indicates that the most important research gap is to develop a rigorous yet scalable problem formulation for optimally sizing of PV and BES in ZEBs. An aspect neglected in the literature is that both BES and PV systems generate environmental impacts, mostly during their manufacturing. The key new contribution of this article is an enhanced (but scalable to large-scale planning problems) mathematical model for the optimal PV and BES sizing problem fulfilling the definition of ZEBs. A proposed enhancement, with respect to the existing models, is to enforce the priority to store the excess electric power in the battery instead of selling it to the grid.
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