| 1 |
Comparison of hybrid recurrent neural networks anddual-polarizationmodels of valve regulated lead acid battery
Chmielewski A, Mozaryn J, Piorkowski P, Dybala J
International Journal of Energy Research, 45(2), 2560, 2021 |
| 2 |
VRLA 배터리의 충/방전 거동과 노화 예측 모델링
이명규, 조재성, 신치범, 류기선
Korean Chemical Engineering Research, 56(6), 779, 2018 |
| 3 |
Modeling of the cranking and charging processes of conventional valve regulated lead acid (VRLA) batteries in micro-hybrid applications
Gou J, Lee A, Pyko J
Journal of Power Sources, 263, 186, 2014 |
| 4 |
The testing of batteries linked to supercapacitors with electrochemical impedance spectroscopy: A comparison between Li-ion and valve regulated lead acid batteries
Ferg E, Rossouw C, Loyson P
Journal of Power Sources, 226, 299, 2013 |
| 5 |
Effect of discharge rate on charging a lead-acid battery simulated by mathematical model
Cugnet M, Liaw BY
Journal of Power Sources, 196(7), 3414, 2011 |
| 6 |
Valve Regulated Lead Acid battery float service life estimation using a Kalman filter
Burgess WL
Journal of Power Sources, 191(1), 16, 2009 |
| 7 |
Comparative study of lead-acid batteries for photovoltaic stand-alone lighting systems
Hariprakash B, Martha SK, Ambalavanan S, Gaffoor SA, Shukla AK
Journal of Applied Electrochemistry, 38(1), 77, 2008 |
| 8 |
Remote monitoring of VRLA batteries for telecommunications systems
Tsujikawa T, Matsushima T
Journal of Power Sources, 168(1), 99, 2007 |
| 9 |
Effects of lead-foam grids on performance of VRLA battery
Dai CS, Yi TF, Wang DL, Hu XG
Journal of Power Sources, 158(2), 885, 2006 |
| 10 |
Influence of the charge regulator strategy on state of charge and lifetime of VRLA battery in household photovoltaic systems
Yang H, Wang H, Chen GD, Wu GM
Solar Energy, 80(3), 281, 2006 |
