Abstract
This paper proposes a new bi-objective optimization model, trading-off cost and environmental impacts, for sizing the key electrical and thermal devices in a zero energy building (ZEB), i.e., a building that roughly generates as much renewable energy as it consumes annually. A salient novel feature is the consideration of the environmental impacts, computed through a rigorous life cycle assessment approach, of buying electricity from the grid and manufacturing devices. Furthermore, an enhancement of the proposed model, as compared to the existing models, is to prioritize storing the ZEB excess of energy rather than selling it to the grid. The proposed solution approach of the initial mixed-integer nonlinear programming model relies on McCormick relaxation linearization to obtain a more tractable mixed-integer linear model. An augmented ϵ-constraint method is applied to solve the obtained bi-objective model. Finally, considering the building owners’ willingness-to-pay for environmental impacts, a decision-making criterion is proposed to select the optimal size of the devices among all non-dominated solutions of the Pareto front.
Highlights
T HE consequence of using fossil fuels to produce electricity is the increase in greenhouse gases emission
This paper has proposed a new bi-objective mathematical model for the optimal sizing of key electrical and thermal devices to fulfill the requirements of zero energy buildings
To break down the computational complexity of the initial mixed-integer nonlinear programming (MINLP) model, we proposed a more tractable mixedinteger linear programming (MILP) model, based on McCormick relaxation linearization
Summary
T HE consequence of using fossil fuels to produce electricity is the increase in greenhouse gases emission. The growing environmental concerns and green conscience of many people make it pertinent to consider further environmental aspects in the ZEB planning problem rather than only satisfying the zero energy constraint This underpins the proposal of this paper, which is in line with approaches from other areas [13], to consider a bi-objective optimization model trading-off an economic goal and an environmental goal. TrhAe mnaeiwn contributions of the paper are as follows: mathematical model and solution approach for the joint optimal electric and thermal device sizing of a ZEB is proposed. The proposed model is enhanced to prioritize storing ZEB excess energy rather than selling it to the grid This is a more realistic approach since the electricity price is usually fixed and it is higher than the feed-in-tariff for residential r buildings.
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