A Comparison Study of Performance Efficiency of Lead-Acid Batteries Available in the Iraqi Markets.

 
 
 
  • Abstract
  • Keywords
  • References
  • PDF
  • Abstract


    Batteries consider the major important devices for energy storage based on converting the chemical energy to electrical energy. Different types of batteries are available working in different efficiencies. In this work the performance efficiency of five types of batteries available in the Iraqi were assessed. Different operating variables such as Battery Type (Akko, Raggie, Aswar, Terminator, and Hongdeng), Temperature (20, 25, 35, 45, 55, and 65˚C), and Charging Time (24, 48, and 72 hr) were studied the impact of these on the performance efficiency of each battery type. According to the results obtained in this study, maximum performance efficiency achieved was 7.2 V at optimum operating variables are (temperature 20˚C), and (charging time 48 hr). Furthermore, a computer was used with Data Logger to be connected with batteries. Finally, the most stable type and resistance to operating conditions was Aswar type in the first rank and Hongdeng type in the last rank.

     

     


  • Keywords


    Lead-acid battery, Battery Performance, Charge Time, Temperature effect.

  • References


      [1] Bukhari, S. M. A. S., Maqsood, J., Baig, M. Q., Ashraf, S., & Khan, T. A. (2015, March). Comparison of Characteristics--Lead Acid, Nickel Based, Lead Crystal and Lithium Based Batteries. In Modelling and Simulation (UKSim), 17th UKSim-AMSS International Conference on (pp. 444-450). IEEE.‏

      [2] Czerwiński, A., Rogulski, Z., Obrębowski, S., Lach, J., Wróbel, K., & Wróbel, J. (2014). Positive plate for carbon lead-acid battery. International Journal of Electrochemical Science, 9, 4826-4839.‏

      [3] Gauri, M.; Singh, B.; Pant, C., and Gairola, R. (2018). Effect Of Temperature On Flooded Lead-Acid Battery Performance. International Journal Of Advanced Science And Research, 3, 27-29.

      [4] Gençten, M., Dönmez, K., & Şahin, Y. (2016). Investigation of the temperature effect on electrochemical behaviors of TiO2 for gel type valve regulated lead-acid batteries. Anadolu Üniversitesi Bilim Ve Teknoloji Dergisi A-Uygulamalı Bilimler ve Mühendislik, 17(5), 882-894.‏

      [5] Hutchinson, R. (2004). Temperature effects on sealed lead acid batteries and charging techniques to prolong cycle life (No. SAND2004-3149). Sandia National Laboratories.

      [6] Kadiran, M. S. (2012). Charging and discharging methods of lead acid battery (Doctoral dissertation, UMP).‏

      [7] Plangklang, B., & Pornharuthai, P. (2013). Mathematical model and experiment of temperature effect on discharge of lead-acid battery for PV systems in tropical area.‏ Energy And Power Engineering, 5, 43-49.

      [8] Samolyk, M., & Sobczak, J. (2013). Development of an algorithm for estimating Lead-Acid Battery State of Charge and State of Health.‏ PhD Thesis. Blekinge Institute of Technology.

      [9] Vutetakis, G., David, (2001). Douglas Battery. The Handbook Of Batteries & Fuel Cells, Chapter: 10 David Linden, Third Edition.

      [10] Author,”Title of the Paper”, Journal name, Vol.X, No.X, (200X), pp.XX-XX, available online: http://xxx, last visit:28.02.2013


 

View

Download

Article ID: 24091
 
DOI: 10.14419/ijet.v7i4.37.24091




Copyright © 2012-2015 Science Publishing Corporation Inc. All rights reserved.