An Enhanced Optimal PV and Battery Sizing Model for Zero Energy Buildings Considering Environmental Impacts

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.

[1]  Sanna Syri,et al.  Electrical energy storage systems: A comparative life cycle cost analysis , 2015 .

[2]  Sergei Vassilvitskii,et al.  k-means++: the advantages of careful seeding , 2007, SODA '07.

[3]  Alexander Mitsos,et al.  Multivariate McCormick relaxations , 2014, J. Glob. Optim..

[4]  Lokeshgupta Bhamidi,et al.  Optimal Sizing of Smart Home Renewable Energy Resources and Battery Under Prosumer-Based Energy Management , 2020, IEEE Systems Journal.

[5]  Anibal T. de Almeida,et al.  Energy storage system for self-consumption of photovoltaic energy in residential zero energy buildings , 2017 .

[6]  Gregor Wernet,et al.  The ecoinvent database version 3 (part I): overview and methodology , 2016, The International Journal of Life Cycle Assessment.

[7]  Gerard Doorman,et al.  Cost-optimal energy system design in Zero Energy Buildings with resulting grid impact: A case study of a German multi-family house , 2016 .

[8]  Amin Kargarian,et al.  Chance-Constrained Microgrid Energy Management with Flexibility Constraints Provided by Battery Storage , 2019, 2019 IEEE Texas Power and Energy Conference (TPEC).

[9]  Edgar G. Hertwich,et al.  Life cycle assessment demonstrates environmental co-benefits and trade-offs of low-carbon electricity supply options , 2017 .

[10]  P. C. Tabares-Velasco,et al.  A simulation approach to sizing batteries for integration with net-zero energy residential buildings , 2019, Renewable Energy.

[11]  E. Hertwich,et al.  Health benefits, ecological threats of low-carbon electricity , 2017 .

[12]  Florin Capitanescu,et al.  An Efficient Mixed-Integer Linear Programming Model for Optimal Sizing of Battery Energy Storage in Smart Sustainable Buildings , 2020, 2020 IEEE Texas Power and Energy Conference (TPEC).

[13]  E. Hertwich,et al.  Environmental co-benefits and adverse side-effects of alternative power sector decarbonization strategies , 2019, Nature Communications.

[14]  V. Rallabandi,et al.  Dynamic Modeling and Optimal Design for Net Zero Energy Houses Including Hybrid Electric and Thermal Energy Storage , 2020, IEEE Transactions on Industry Applications.

[15]  C. Silva,et al.  Techno-economic analysis of utility-scale energy storage in island settings , 2019, Journal of Energy Storage.

[16]  Victor M. Zavala,et al.  Multiscale model predictive control of battery systems for frequency regulation markets using physics-based models , 2020, Journal of Process Control.

[17]  Amin Kargarian,et al.  Data-Driven Nonparametric Chance-Constrained Optimization for Microgrid Energy Management , 2020, IEEE Transactions on Industrial Informatics.

[18]  M. H. Haque,et al.  Energy cost minimization for net zero energy homes through optimal sizing of battery storage system , 2019, Renewable Energy.

[19]  Anders,et al.  Holistic energy system modeling combining multi- objective optimization and life cycle assessment , 2017 .

[20]  Mushfiqur R. Sarker,et al.  Optimal investment strategy in photovoltaics and energy storage for commercial buildings , 2015, 2015 IEEE Power & Energy Society General Meeting.

[21]  Vinod John,et al.  Dynamic Modeling and Analysis of Buck Converter based Solar PV Charge Controller for Improved MPPT Performance , 2018, 2018 IEEE International Conference on Power Electronics, Drives and Energy Systems (PEDES).

[22]  Amin Kargarian,et al.  Non-Parametric Joint Chance Constraints for Economic Dispatch Problem with Solar Generation , 2019, 2019 IEEE Texas Power and Energy Conference (TPEC).

[23]  Iqbal Husain,et al.  Energy Storage Management Strategy Based on Dynamic Programming and Optimal Sizing of PV Panel-Storage Capacity for a Residential System , 2018, 2018 IEEE/PES Transmission and Distribution Conference and Exposition (T&D).

[24]  F. Capitanescu,et al.  Optimal Operation of Nearly Zero Energy Buildings using Mixed Integer Linear Programming , 2019, 2019 International Conference on Smart Energy Systems and Technologies (SEST).

[25]  Per Heiselberg,et al.  Zero energy buildings and mismatch compensation factors , 2011 .