| 1 - 1 |
Preface for 8ELBC proceedings
Wilson D |
| 2 - 3 |
Prospects for lead-acid batteries in the new millenium
Razelli E |
| 4 - 7 |
The Italian contribution to battery science and technology
Scrosati B |
| 8 - 13 |
Lead-acid battery research and development - a vital key to winning new business
Bullock KR |
| 14 - 22 |
The impact of the new 36 V lead-acid battery systems on lead consumption
Prengaman RD |
| 23 - 31 |
Changing patterns in global lead supply and demand
Roberts H |
| 32 - 39 |
The Asian battery market - a decade of change
Eckfeld S, Manders JE, Stevenson MW |
| 40 - 46 |
Development of a novel synthetic loaded separator paper for VRLA batteries
Clement N, Kurian R |
| 47 - 52 |
Benefit of increasing the organic expander dosage on the high temperature performance of the negative electrode of lead-acid batteries
McNally T, Klang J |
| 53 - 60 |
Silver-silver sulfate reference electrodes for use in lead-acid batteries
Ruetschi P |
| 61 - 72 |
Development of high power VRLA batteries using novel materials and processes
Soria ML, Valenciano J, Ojeda A, Raybaut G, Ihmels K, Deiters J, Clement N, Morales J, Sanchez L |
| 73 - 78 |
International standard for future automotive 42 V supply voltages (PowerNet)
Bremer W |
| 79 - 98 |
Battery Monitoring and Electrical Energy Management - Precondition for future vehicle electric power systems
Meissner E, Richter G |
| 99 - 104 |
42-V battery requirements - lead-acid at its limits
Spier B, Gutmann G |
| 105 - 109 |
Development of 36-V valve-regulated lead-acid battery
Ohmae T, Hayashi T, Inoue N |
| 110 - 117 |
Early results from a systems approach to improving the performance and lifetime of lead acid batteries
Kellaway MJ, Jennings P, Stone D, Crowe E, Cooper A |
| 118 - 127 |
Assessment of high power HEV lead-acid battery advancements by comparative benchmarking with a European test procedure
Conte M, Pede G, Sglavo V, Macerata D |
| 128 - 140 |
The VRLA modular wound design for 42 V mild hybrid systems
Trinidad F, Gimeno C, Gutierrez J, Ruiz R, Sainz J, Valenciano J |
| 141 - 144 |
Separator requirements for 36-/42-V lead-acid batteries
Whear JK, Bohnstedt W |
| 145 - 150 |
AGM separator for 36 V batteries
Matsunami Y, Endo H, Sugiyama S |
| 151 - 159 |
Test requirements for 42 V battery systems
Weighall MJ |
| 160 - 168 |
Advanced separator construction for long life valve-regulated lead-acid batteries
Stevenson PR |
| 169 - 173 |
Optimization of ratio of active masses in VRLA battery
Kamenev Y, Chunts N, Ostapenko E |
| 174 - 184 |
Impedance modeling of intermediate size lead-acid batteries
Salkind AJ, Singh P, Cannone A, Atwater T, Wang XQ, Reisner D |
| 185 - 192 |
New lead alloys for high-performance lead-acid batteries
Jullian E, Albert L, Caillerie JL |
| 193 - 202 |
A study of current and potential distributions on tubular positive plate
Guo YL, Li WZ, Zhao L |
| 203 - 210 |
Pasted positive plate of lead-acid battery - General analysis of discharge process
D'Alkaine CV, Impinnisi RP, Rocha JR |
| 211 - 218 |
The influence of the pickling and curing processes in the manufacturing of positive tubular electrodes on the performance of lead-acid batteries
Ferg EE, Geyer L, Poorun A |
| 219 - 231 |
Techniques for jar formation of valve-regulated lead-acid batteries
Weighall MJ |
| 232 - 235 |
The changing world of standby batteries in telecoms applications
Harrison AI |
| 236 - 242 |
High integrity VRLA batteries for telecommunications service
May G, Lodi G |
| 243 - 247 |
Installation and operation of a large scale RAPS system in Peru
Cole JF |
| 248 - 256 |
Irreversible sulphation in photovoltaic batteries
Mattera F, Benchetrite D, Desmettre D, Martin JL, Potteau E |
| 257 - 262 |
Performance of a VRLA battery in an arctic environment
Haring P, Giess H |
| 263 - 282 |
Development of a valve-regulated lead-acid battery with thin tubular positive plates for improved specific energy and optimization for low charge-factor operation
Dyson I, Griffin P |
