HEV BATTERIES. PROBLEMS AND SOLUTIONS
The function of carbon in the negative plates of VRLA batteries exposed to high-rate partial-state-of-charge operation
P.T. Moseley, International Lead Zinc Research Organization, Durham, North Carolina, USA
Negative plate additives for improving HRPSoC operation of lead-acid batteries
P. Nikolov, G. Petkova, T. Rogachev, D. Pavlov, Institute of Electrochemistry and Energy Systems, Bulgarian Academy of Sciences, Sofia, Bulgaria
Study of graphite addition to negative active material of VRLA batteries to improve life under high-rate partial-state-of-charge working conditions
M. Fernandez, J. Valenciano, J.M. Lacadena, L. Sanz, F. Trinidad, R&D Centre, Exide Technologies Transportation Europe, Azuqueca de Henares, Spain
Lead-acid batteries for partial-state-of-charge applications
B. Hariprakash, Solid State and Structural Chemistry Unit, Indian Institute of Science, Bangalore, India
S.A. Gaffoor, NED Energy Ltd., Hyderabad, India
A.K. Shukla, Central Electrochemical Research Institute, Karaikudi, India
Thin plate pure lead VRLA designs for fast charge motive power and HEV applications
R. Kurian, EnerSys, Newport, UK
Influence of graphite and carbon foams used in Firefly Energy 3D® negative plates on the charge-discharge processes
B. Monahov, K. Kelley, R. McDuff, Firefly Energy Inc., Peoria, IL, USA
Simulation of the current distribution in lead-acid batteries to investigate the dynamic charge acceptance in SLI batteries
J. Kowal, E. Karden, D. U. Sauer, ISEA,RWTH, Aachen, Germany
NEW TECHNOLOGY FOR LEAD-ACID BATTERY GRID PRODUCTION
New continuous processes and alloys for production of positive grids
R.D. Prengaman, T. Ellis, RSR Technologies, Inc. Dallas, TX USA
Electrochemical behavior of thin layer of lead deposited on neutral matrix
A. Czerwiński, I. Paleska, M. Bodziachowska, J. Kotowski, Sz. Obrębowski, Warsaw University, Department of Chemistry, Warsaw, Poland
Z. Rogulski, Industrial Chemistry Research Institute, Warsaw, Poland
Cutting lead cost by direct use of scrap for grid making
T. Hofmann, H. Warlimont, DSL Dresden Material-Innovation GmbH, Dresden, Germany
High corrosion resistance and electrochemical characteristics of film lead negative electrode of lead-acid battery
L. Yolshina, Institute of High-Temperature Electrochemistry, Urals Branch of Russian Academy of Sciences, Yekaterinburg, Russia
A.N. Yolshin, Leader-LAB. Ltd, Yekaterinburg, Russia
Study on the microstructure of different sites of cast ingot of lead calcium alloys
W. Guo, H. Chen, School of Chemistry and Environment, South China Normal University, Guangzhou, China
M. Tang, H. Zhou, H. Wang, S. Peng, W. Wei, Zhuzhou Smelter Group Co. Ltd, Zhuzhou Hunan, China
A study on corrosion of cast-on-strap alloy
A. Li, H. Chen, School of Chemistry and Environment, South China Normal University, Guangzhou, China
C. Dou, G. Xiao, S. Peng, W. Wei, H. Wang, W. Zhang, S. Chen, Zhuzhou Smelter Group Co. ,Ltd. , Zhuzhou, Hunan, China
Y. Zhao, Shenyang Jugu Equipment Manufacturing Co. , Ltd. , Shenyang, Liaoning, China
Anodic behavior of lead alloys in sulphate electrolytes
Ts. Dobrev, Y. Stefanov, Rostislav Kaischev Institute of Physical Chemistry, Bulgarian Academy of Sciences, Sofia, Bulgaria
Iv. Valchanova, Sn. Magaeva, University of Plovdiv „Paisii Hilendarski”, Plovdiv, Bulgaria
New methods of lead and lead-antimony alloys refining
A.I. Rusin, L. D. Khegay, MUP „RUMA”, Komsomolsk-na-Amure, Russia
NEW TECHNOLOGICAL PROCESSES
FOR LEAD-ACID BATTERY PRODUCTION
Influence of H2SO4/(Pb3O4 + leady oxide) ratio on the phase composition, structure and performance parameters of lead-acid battery positive plates
G. Papazov, D. Pavlov, Institute of Electrochemistry and Energy Systems, Bulgarian Academy of Sciences, Sofia, Bulgaria
Plates soaking prior formation and its influence on PAM phase composition and battery performance
M. Foudia, L. Zerroual, Laboratoire d’Energétique et Electrochimie du Solide, Université Ferhat ABBAS Sétif, Algeria
M. Matrakova, Institute of Electrochemistry and Energy Systems, Bulgarian Academy of Sciences, Sofia, Bulgaria
Preparation and characterization of thin electrodes using nanometric materials for VRLA prototype batteries
A. Caballero, M. Cruz, L. Hernan, J. Morales, Dpto QuimicaInorganica e Ingenieria Quimica, Edificio Marie Curie, Universidad de Córdoba, Cordoba, Spain
J. Valenciano, Exide Technologies, Research and Innovation, Azuqueca de Henares, Spain
Tetrabasic crystal seeding – a successful and maturing technology
D. Hardy, Penox GmbH, Engineering Dept. , Cologne, Germany
Mechanism of micro/nanoporosity formation in lead acid negative plates
C.V. D’Alkaine, G.A. de O. Brito, Group of Electrochemistry and Polymers, DQ-UFSCar, Sao Carlos, Brazil
Formation systems with acid recirculation technology – the Inbatec design
C. Papmahl, Inbatec GmbH, Hagen, Germany
Charge tracking, complete process control
R. Jonach , BM Battery Machines, Austria
Reliability of the lead acid batteries: impact of the manufacturing process
J.M. Lasserre, Serma Technologies, Pessac, France
Small to medium sized lead-acid battery recycling plants: Tilting Rotary Furnaces as reduction units
J. Simpson, Dross Engineering, France
Numerical simulation of electrolyte particle trajectory to investigate battery cover design characteristics
V. Esfahanian, H.M. Darian, H. Babazadeh, Vehicle, Fuel and Environment Research Institute, University of Tehran, Iran
Pro-Ox curing technology
C. Catelli, Roma, Italy
Development of China’s lead and lead-acid battery industry
H. Chen, School of Chemistry and Environment, South China Normal University, Guangzhou, China
CHARGE AND DISCHARGE PROCESSES. SOC AND SOH.
BATTERY TESTS
New fast charging methods based on real time battery acceptance measurements allowing charge and destratification simultaneously
K. Mamadou, P. N’Guyen, Ch. Glaize, Institut d’Électronique du Sud – GEM, Université Montpellier II, Montpellier, France
J. Alzieu, Électricité De France R&D, Moret-sur-Loing, France
Study of the “coup de fouet” phenomena occurring in the start of discharges and charges of lead-acid batteries. Experimental analysis
A. Delaille, M. Perin, INES Research, Development and Innoviation, Laboratorie of Solar Energy, Le Bourget-du-Lac, France
F. Huet, UPRIS du CNRS, Pierre and Marie University, Paris, France
Automatic device for continuous measurement of current distribution and acid stratification in flooded lead-acid batteries
D. Schulte, T. Sanders, W. Waag, J. Schiffer, D.U. Sauer, ISEA,RWTH, Aachen, Germany
VRLA battery float service life estimation using a Kalman filter
W.L. Burgess, Eaton Powerware, Raleigh, USA
Advancements In Power Storage Testing For HEV Development
R. Schaefer, Bitrode Corporation, Fenton, USA
Development of battery health monitoring system for standby lead-acid batteries
S. Joshi, Lalit Consulting Services, Bangalore, India
R. Jakkli, Y. Kulkarni, Associated Powercon Equipment India Pvt. Ltd. , Pune, India
12V Battery – SOH degradation in the field. Analysis of 300 samples coming from Renault Clio II.
C. Hiron, W. Bogel, T. Vu Mai, Electrical and Electric Systems Engineering – Electrical Energy Storage Group, Renault Technocentre, Guyancourt, France
Recovery of discharged sulfated lead-acid batteries
H. Karami, Payame-Noor University, Abhar, Iran
FUNDAMENTAL STUDY OF THE LAB PROCESSES
Thermal behaviour of small battery during closed oxygen cycle
D. Valkovska, T. Todorov, M. Dimitrov, D. Pavlov, Institute of Electrochemistry and Energy Systems, Bulgarian Academy of Sciences, Sofia, Bulgaria
Critical analysis of experimental plate impedance
P.R. Impinnisi, C. M. Garcia, P. Mengarda, Battery Laboratory, Institute of Technology for Development - LACTEC, Curitiba (PR)-Brazil.
C.V. D’Alkaine, Group of Electrochemistry and Polymers, Chemistry Department, Federal University of Sao Carlos, Sao Carlos (SP) Brazil
Macroporosity and impedance in lead-acid plates
C.M. Garcia, P. R. Impinnisi, Battery Laboratory, Institute of Technology for Development - LACTEC, Curitiba, (PR)-Brazil
C.V. D’Alkaine, G. A. O. Brito, Group of Electrochemistry and Polymers, Chemistry Department, Federal University of Sao Carlos, Sao Carlos, (SP) Brazil
Kinetics of PbO2 electrodeposition from methanesulfonic solutions
A.B. Velichenko, R. Amadelli, E. V. Gruzdeva, T.V. Luk’yanenko, F.I. Danilov, Department of Physical Chemistry, Ukrainian State University of Chemical Technology, Dnepropetrovsk, Ukraine
PbO2 electrodeposition from methanesulfonic electrolytes and physicochemical properties of the resulting oxides
R. Amadelli, E.V. Gruzdeva, T.V. Luk’yanenko, A.B. Velichenko, Department of Physical Chemistry, Ukrainian State University of Chemical Technology, Dnepropetrovsk, Ukraine
Electrochemical study of the mechanism of the pulse charge of the lead acid battery negative plates for PV applications
A. Kirchev, F. Mattera, E. Lemaire, A. Delaille, Laboratoire des Systemes Solaires, INES, DRI, Le Bourget du Lac, France
Failure modes of valve-regulated lead-acid batteries in electric bicycle application
Y. Guo, College of Chemistry and Chemical Engineering, Fuzhou University, Fuzhou, China
Influence of Mg, Al, Co, Sn and Sb on the electrical performance of doped βPbO2
N. Chahmana, L. Zerroual, Laboratoire d’Energétique et Electrochimie du Solide (LEES), Université Ferhat ABBAS, Sétif, Algeria
M. Matrakova, Institute of Electrochemistry and Energy Systems, Bulgarian Academy of Sciences, Sofia, Bulgaria
Influence of Mg, Al, Co, Sn and Sb on the structure of doped βPbO2
M. Matrakova, D. Pavlov, Institute of Electrochemistry and Energy Systems, Bulgarian Academy of Sciences, Sofia, Bulgaria
N. Chahmana, L. Zerroual, Laboratoire d’Energétique et Electrochimie du Solide (LEES), Université Ferhat ABBAS Sétif, Algeria
Behavior of lignosulfonate on electrochemical reaction on lead electrode in sulfuric acid solution
N. Hirai, Department of Material and Manufacturing Science, Osaka University, Osaka, Japan
Lead-acid battery industry in China
Z. Wang, Beijing University of Science and Technology, Beijing, China
MODELING OF LAB PROCESSES
Prediction of starter lead-acid battery performance using Artificial Neural Network
S.M. Rezaei niya, M. Hejabi, Research and Development Center, Niru Battery Manufacturing Company, Tehran, Iran
Visual modeling of electrochemical processes
M. Semenenko, Bauman Moscow State Technical University, Kaluga Branch, Kaluga, Russia
Mixed model of lead-acid battery
K. Untener, Institute for Engineering and Materials Science, University of Szeged, Szeged, Hungary
Numerical simulation of acid stratification in lead-acid batteries
V. Esfahanian, F. Torabi, Vehicle, Fuel and Environment Research Institute, University of Tehran, Iran
SOME NEW IDEAS FOR LEAD-ACID BATTERIES
New sources of energy on the base of polyelectrolyte hydrogels
I. E. Suleimenov, E. N. Suleimenov, Institute of Ionosphere, Almaty, Kazakhstan
Flexible hybrid supercapacitor power system
M. Mladenov, Institute of Electrochemistry and Energy Systems, Bulgarian Academy of Sciences, Sofia, Bulgaria
D. Kovacheva, Institute of General and Inorganic Chemistry, Bulgarian Academy of Sciences, Sofia, Bulgaria
K. Belov, V. Trenev, Central Laboratory of Mechatronics and Instrumentation, Bulgarian Academy of Sciences, Sofia, Bulgaria
Advanced car battery design based on aesthetic elements
A. Faraji, Department of Industrial Design, University College of Fine Arts, University of Tehran, Tehran, Iran
A. H. Tehrani, Department of Industrial Design, University College of Fine Arts, University of Tehran, Tehran, Iran
Transport ion battery in the present of current
F. Coupan, Renewable energy research laboratory, Cayenne, French Guiana
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