The purpose of this research: (1) To investigate battery temperature during charging using battery
charger and electrolyte weight reduction in Yuasa lead acid battery 12V 5Ah liquid vented type before giving
battery life extender technology (Vitta-Q battery vitamin). (2) To investigate battery temperature during
charging using battery charger and electrolyte weight reduction in Yuasa lead acid battery 12V 5Ah liquid
vented type after giving Vitta-Q battery vitamin.
This research was used experimental method. The experiment was conducted at the Laboratory of
Automotive Mechanical Engineering Education Program, the Laboratory of Mechanical Civil Education
Program, JPTK FKIP UNS Surakarta and the Laboratory of Mathematics and Natural Sciences FMIPA UNS
Surakarta which addressed at Ahmad Yani 200 Kartasura. The instruments which used to test were Delta
DT.115K battery charger, Mettler Toledo digital balance, and Perkin Elmer UV/VIS Spectrometer. The research
population were Yuasa 12V 5Ah battery with code number YB5L-B and the research sample were 6 Yuasa 12V
5Ah batteries with code number YB5L-B with lifetime of approximately 2 years or 20.000 miles. The
comparative study descriptive investigation methode was used to analyse the data.
Based on this research can be concluded: (1) The measurement on Yuasa lead acid battery 12V 5Ah
liquid vented type before giving Vitta-Q battery vitamin during charging using battery charger resulted the
temperature 49 oC and weight of electrolyte 209.5 gr in 230.0 gr electrolytes. (2) The measurement on Yuasa
lead acid battery 12V 5Ah liquid vented type after giving 2 ml of Vitta - Q battery vitamin per cell during
charging using battery charger resulted the lowest temperature 40.3 oC and weight of electrolyte 216.4 gr in
230.0 gr electrolytes. (3) The measurement on Yuasa lead acid battery 12V 5Ah liquid vented type after giving
3.5 ml of Vitta - Q battery vitamin per cell during charging using battery charger resulted the highest
temperature 49.8 oC and weight of electrolyte 208.1 gr in 230.0 gr electrolytes

Anonim. (2013, 1 Maret). Statistic Motorcycle

Production Wholesales Domestic and Exports. Asosiasi Industri Sepeda Motor Indonesia. Di

peroleh 13 Mei 2013, dari http://www.aisi.or.id/.

Arikunto, Suharsimi. (2010). Prosedur Penelitian Suatu Pendekatan Praktik. Jakarta: Rineka Cipta.

Botcolaboratories. (1991). Laboratory Test Report.

Botcolab Test Report. Di peroleh 4 April 2013, dari http://www.vittaq.

com/pdf/botcolabs.pdf.

Catherino, H.A. (2004). Sulfation in Lead–Acid

Batteries. Journal of Power Sources 129 113–120. Di peroleh 17 April 2013, dari

http://ac.els-cdn.com/S0378775303010681/1-s2.0-S0378775303010681-main.pdf.

Dambrowski, Jonny. (2009). About The Challenges

For Charging Techniques With Lead-Acid Batteries in The Automotive Industry. Deutronic

Elektronik GmbH. Di peroleh 3 April 2013, dari http://deutronic.com/ladegeraete/deutroniclader_

e.pdf.

Daryanto. (1987). Pengetahuan Teknik Listrik. Jakarta: Bina Aksara.

Daryanto. (2001). Pengetahuan Baterai Mobil.

Jakarta: Bina Aksara.

Daryanto. (2011a). Dasar-Dasar Kelistrikan Otomotif. Jakarta: Prestasi Pustaka.

Daryanto. (2011b). Sistem Kelistrikan Motor. Bandung: Satu Nusa.

Faqih, M. (2011, 5 April). Mengenal Accu awet dan

Panjang Umur. Republika. Di peroleh 18 Februari 2013, dari

http://www.batteryglobal.com/artikel.php@kat=1&id=2.html.

Grummy Wailanduw, A. Ladiono. (2010). Efektivitas Aki Basah dan aki Kering Terhadap Beban

Listrik pada Kendaraan Bermotor. Surabaya: Program Strata Unesa.

Hafiz, W. A., (2004) Development of Asymmetric Polysulfone Membrane For The Application in

Tropicalized Lead Acid Battery. Malaysia: Program Strata Universitas Teknologi Malaysia.

Hardi, Syam. (1983). Dasar-dasar Teknik Listrik

Aliran Rata I. Jakarta: Bina Aksara.

Kiehne, H. A., (1989). Electrochemical Power Sources. Jerman: Expert Verlag.

Maylani, Yossi, (2003). Revitalisasi Akumulator Bekas. Semarang: Program Strata Unnes.