Using building thermal mass energy storage to offset temporary BIPV output reductions due to passing clouds in an office building

Ongoing concerns about electrical grid stability and existing economic interests create unattractive conditions for grid-injection of renewable energy produced in building integrated photovoltaic systems (BIPV). As a result, BIPV often fails to use the full potential of the building envelope and sit...

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Bibliographic Details
Published in:Building and environment 2022-01, Vol.207, p.108504, Article 108504
Main Authors: Bravo Dias, João, Carrilho da Graça, Guilherme
Format: Article
Language:English
Subjects:
Air conditioning
Building envelopes
Climate
Cloud shading
Clouds
Cooling
Demand flexibility
Energy demand
Energy storage
Flexibility
HVAC
HVAC equipment
Low energy buildings
Office buildings
Photovoltaics
Renewable energy
Renewable resources
Shading
Solar photovoltaic energy
Thermal comfort
Thermal energy storage
Thermal mass
Thermal mass storage
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Summary:Ongoing concerns about electrical grid stability and existing economic interests create unattractive conditions for grid-injection of renewable energy produced in building integrated photovoltaic systems (BIPV). As a result, BIPV often fails to use the full potential of the building envelope and site. An effective approach to increase BIPV size is maximizing self-consumption of the generated renewable energy through building demand flexibility and energy storage. Unfortunately, in cooling dominated office buildings with BIPV, shading by passing clouds can increase grid demand as the building maintains its energy demand in a moment when BIPV output is reduced. This paper analyses the effectiveness of turning off the heating ventilation and air conditioning system (HVAC) to offset temporary reductions in BIPV output due to passing clouds. Analysis of cloud duration in different climates shows that, on average, clouds last 20 min and occur predominately in the afternoon. When HVAC is off due to cloud shading, the building thermal mass limits indoor temperature increase to 2 °C in the first 50 min. Simulation based analysis of HVAC control-based energy flexibility shows that it is possible to maintain acceptable thermal comfort while reducing HVAC grid energy demand by 60% during the cooling season. •In these climates passing clouds shade for approximately 20 min.•Experimental measurement of a HVAC off energy flexibility event in an occupied office.•With HVAC off, indoor temperature takes 50 min to increase 2 °C.•Simulation of energy flexibility events (HVAC on/off) trigged by cloud shading of PV.
ISSN:0360-1323
1873-684X
DOI:10.1016/j.buildenv.2021.108504