摘要
Electric energy generation from falling droplets has seen a hundred-fold rise in efficiency over the past few years.However,even these newest devices can only extract a small portion of the droplet energy.In this paper,we theoretically investigate the contributions of hydrodynamic and electric losses in limiting the efficiency of droplet electricity generators(DEG).We restrict our analysis to cases where the droplet contacts the electrode at maximum spread,which was observed to maximize the DEG efficiency.Herein,the electro-mechanical energy conversion occurs during the recoil that immediately follows droplet impact.We then identify three limits on existing droplet electric generators:(i)the impingement velocity is limited in order to maintain the droplet integrity;(ii)much of droplet mechanical energy is squandered in overcoming viscous shear force with the substrate;(iii)insufficient electrical charge of the substrate.Of all these effects,we found that up to 83%of the total energy available was lost by viscous dissipation during spreading.Minimizing this loss by using cascaded DEG devices to reduce the droplet kinetic energy may increase future devices efficiency beyond 10%.
基金
This work was supported by the National Natural Science Foundation of China with Grant nos.12004078,51950410582,61874033 and 61674043
the Science Foundation of Shanghai Municipal Government with Grant no.18ZR1402600
the State Key Lab of ASIC and System,Fudan University with Grant nos.2018MS003 and 2020KF006
We also acknowledge the financial support from the National Natural Science Foundation of China(No.51975502)
Guangdong-Hong Kong Technology Cooperation Funding Scheme(GHP/021/19SZ)
Innovation&Technology Fund(9440248)to Z.W.
