Lead–acid batteries coupled with photovoltaics for increased electricity self-sufficiency in households

Significance Statement

Today, the use of solar panels and energy storage in homes is a much discussed subject. As countries push for renewables and new technologies such as solar panels or electric cars become ever more accessible, it seems as if the house of the future is set to be self-sufficient, independent from the grid, feeding its inhabitants’ needs with green energy from the sun. At the Université Libre de Bruxelles, researchers have been focusing on the problematic of home energy self-sufficiency for a long time and have come up with interesting results, recently published on the Applied Energy journal under the title “Lead-acid batteries coupled with photovoltaics for increased electricity self-sufficiency in households”.

They started by crunching up-to date Belgian data from the Royal Meteorological Institute, energy suppliers and installers and then ran these numbers through their simulation models. The conclusion is that energy self-sufficiency in homes with solar panels and batteries may come with an expensive price tag and that there may be better solutions out there to go green. The problem starts with the bad timing of solar energy and energy consumption: while the sun shines at its maximum around midday, most homes consume the most in the morning and in the evening. Add to that the fact that in many countries most of the solar energy is available in the summer months and you’re set for dark times. No matter how many solar panels are added up, the maximum attainable self-sufficiency will be around 40%. The good news is that 40% self-sufficiency is achievable at prices close to the grid ones, given the recent strong reduction in the cost of solar panels and their long lifetime.

To go beyond 40% self-sufficiency, energy storage seems the natural answer. The researchers coupled the solar panels with lead-acid batteries and the results are striking: all of a sudden, the energy consumed becomes really expensive. Trying to reach a self-sufficiency of 60% can easily cost twice as much as using the grid. And the batteries’ short lifetime and high price are not the only ones to blame: installation costs and extra required electrical equipment also play an important role. The lack of a long term energy policy keeps homeowners and installers cautious, afraid to invest and bear all the risks, a problem that recently granted Belgium a public reprimand from the International Energy Agency.

The researchers also took a look at the impact on the power grid of solar panels and home energy storage and the results seem grim. Homes equipped with such systems place a greater strain on the power grid. Also, power plants will need to be able to answer to quicker variations in demand. All this will impact power grid prices, a field where research is still lacking.

Fortunately, all is not lost. The paper points out that a hybrid approach must be taken for a sustainable energy use. Using several energy sources helps to balance out each one’s disadvantages. Consumption can also be adapted through intelligent appliances that can adjust to the conditions available, as can the energy storage system work in a more intelligent way. Recent energy storage technologies, such as li-ion batteries, continue to enjoy strong price reductions while the share of electric vehicles continues to increase. The field is evolving fast and research continues but, in the meanwhile, there is no magic bullet, the best option is to keep some solar panels and continue to play along with the grid.

 

Lead–acid batteries coupled with photovoltaics for increased electricity self-sufficiency in households. Renewable Energy Global Innovations

About the author

Professor Patrick Hendrick is the Head of Aero-Thermo-Mechanics Department at ULB (Université libre de Bruxelles) in Belgium.

He is active in research fields related to renewable energy and more particularly to energy storage, with projects on battery energy storage, pumped hydro energy storage, CAES or “green” hydrogen for seasonal storage with PEMFCs

 

About the author

Guilherme de Oliveira e Silva is a researcher at the Université Libre de Bruxelles in Belgium where he has been studying the electric power industry, namely the impact of market liberalisation and the increased share of renewable energy sources and storage. ResearchGate, LinkedInGoogle Scholar.  

Journal Reference

Guilherme de Oliveira e Silva, Patrick Hendrick. Lead-acid batteries coupled with photovoltaics for increased electricity self-sufficiency in householdsApplied Energy, Volume 178,  2016, Pages 856–867.

Aero-Thermo-Mechanics Dept. (ATM), École Polytechnique, Université Libre de Bruxelles (ULB), Belgium.

 

 

Go To Applied Energy

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