Optimization of renewable energy for buildings with energy storages and 15-minute power balance

When planning renewable hybrid energy solutions in buildings, it is important to consider both investment and operating costs. This study develops a novel building optimization model based on the coming 15 min power balance settlement. It utilizes multiple energy storages, including hot water tank a...

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Bibliographic Details
Published in:Energy (Oxford) 2022-03, Vol.243, p.123046, Article 123046
Main Authors: Savolainen, Rebecka, Lahdelma, Risto
Format: Article
Language:English
Subjects:
15min power balance
Batteries
Buildings
Cost control
District heating
Energy
Energy conservation
Energy consumption
Energy costs
Energy storage
Ground source heat pump
Heat exchangers
Heat pumps
Heat storage
Integer programming
Lead acid batteries
Linear programming
Mixed integer
Office buildings
Operating costs
Optimization models
Photovoltaic cells
Photovoltaics
Power consumption
Power storage
Rechargeable batteries
Renewable energy
Renewable energy optimization in buildings
Residential areas
Residential buildings
Retrofitting
Water tanks
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Summary:When planning renewable hybrid energy solutions in buildings, it is important to consider both investment and operating costs. This study develops a novel building optimization model based on the coming 15 min power balance settlement. It utilizes multiple energy storages, including hot water tank and flow and lead-acid batteries. We apply the model to plan the retrofitting of an office building in Helsinki and a residential building in Tallinn, with photovoltaics and a ground source heat pump. The model is a large dynamic linear or mixed-integer linear programming model (LP/MILP) for an entire year. The results determine both the optimal dimensioning and the optimal operation of the different production and storage technologies for each building. The optimized configurations caused significant savings in energy costs for both buildings while reducing non-renewable primary energy consumption. Heat storage is highly cost-efficient, but power storages are not. Photovoltaics is cost-efficient in the Helsinki building but slightly unprofitable in the Tallinn building. Power and heat storages do not interact strongly, even in the presence of the ground source heat pump. The heat storage operates in concert with district heating and the ground source heat pump, while power storages operate together with photovoltaics and power trade. •Novel model to optimize building energy based on 15 min power balance settlement.•Hybrid renewable heat and power model with photovoltaics, heat pump and storages.•Assessment of cost-efficiency of different types of power storages.•Optimize operation of multiple energy storages together.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2021.123046