화학공학소재연구정보센터
Energy and Buildings, Vol.116, 614-621, 2016
Are batteries the optimum PV-coupled energy storage for dwellings? Techno-economic comparison with hot water tanks in the UK
Growing support to decarbonise energy systems together with increasing retail energy prices are converting self-generation into a more attractive energy supply option. At the consumption level, solar PV is the most widespread generation technology due to declining capital costs, modularity and easy maintenance. The intrinsic dependence of solar energy generation on weather patterns and conditions affects the performance, final supply to the local demand load (i.e. local self-consumption) and final revenue. Energy storage is an available technological option to increase the value of local PV generation by increasing the self-consumption of PV-generated electricity. Therefore, understanding the performance, cost, value and optimum energy storage technology for managing PV generation is a key aspect for current and new customers with rooftop PV installations. In this study, energy storage for single homes is optimised by quantifying the performance, levelised cost, levelised value and profitability of hot water tanks (supplying domestic hot water), lead-acid batteries and lithium-ion batteries (supplying electricity). Although the assumed storage medium cost for Li-ion batteries (350 pound/kWh) was 2.5 times higher than that of PbA batteries (140 pound/kWh), Li-ion technology's greater round trip efficiency and cycling capability resulted in lower levelised cost (0.37 pound/kWh) and higher levelised value (0.15 pound/kWh) than PbA technology. The best economic case was for hot water tanks with a size ranging between 1001 and 2001 which were able to achieve internal rate of return values higher than the assumed discount factor (4%), especially when the property already had a hot water tank and domestic hot water was previously met by using retail electricity. (C) 2016 Elsevier B.V. All rights reserved.