DC Converter Experiment on Cu-Zn Seawater Battery for Fishing Lamp Energy Source of Lift Net Fisheries

Adi Susanto, Mulyono Baskoro, Sugeng Hari Wisudo, Mochammad Riyanto, Fis Purwangka

Abstract


Light fihing activities developed rapidly after the invention of electric lights. The innovation of Light Emitting Diode (LED) as energy saving lamp has a great opportunity to be used in fishing activities. LED lamps require low voltage and current, so that it can be combined with renewable energy sources to encourage more environmentally friendly of fishing capture activity. This study aims to determine the design and construction of an optimal DC converter using Cu-Zn seawater battery as an early stage of LED lamp development with seawater energy source for fixed lift net fishery. The research was conducted at Fishing Technology Laboratory, Department of Fisheries Resources Utilization, FPIK-IPB in August 2017. The treatments were number of windings (30:50, 50:80) and number of toroid (single, double) that was used in DC converter circuit. The energy source used comes from a single seawater battery cell with a zinc anode (Zn) and a copper cathode (Cu) with a size of 40x36 cm, inserted into a 3-inch diameter PVC tube. The voltage was measured by a digital oscilloscope (Iwatsu DS 5102), the current was measured using a multimeter (Sanwa CD 771) and the light intensity was measured using a lux meter. Differences in the number of windings and toroid have a significant effect on the value of inductance. Single Toroid with 80 loops produces the largest inductance value (143.1 mH) compared to other treatments. The use of DC converter with dual toroid and 50:80 winding provides better performance than other treatments with maximum voltage, current and intensity respectively 2.12 V; 121,80 mA and 128 lux

Keywords


air laut; bagan tancap; DC converter; lampu LED

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References


Yu K, H-Q Xiong, L Wen, Y-L. Dai, S-H Yang, S-F Fan, F Teng, X-Y Qiao. 2015. Discharge Behavior and Electrochemical Properties of Mg-Al-Sn Alloy Anode for Seawater Activated Battery. Transactiono of Nonferrous Metals Society of China. 25: 1234-1240.

Mandal B, A Sirkar, A Shau, P De, P Ray. 2012. Effects of Geometry of Electrodes and Pulsating DC Input on Water Splitting for Production of Hydrogen. International Journal of Renewable Energy Research. 2: 99-102.

Susanto A., M. S. Baskoro , S. H. Wisudo, M. Riyanto, F. Purwangka. 2017. Performance of Zn-Cu and Al-Cu Electrodes in Seawater Battery at Different Distance and Surface Area. International Journal of Renewable Energy Research. 7: 288-303.

Hongyang Z, B Pei, J Dongying. 2009. Electrochemical Performance of Magnesium Alloy and Its Application on The Sea Water Battery. Journal of Environmental Sciences. Supplement: S88–S91.

Lai MF, ND G Anh, JZ Gao, HY Ma, HY Lee. 2015. Design of Multi Segmented Freeform Lens for LED Fishing/Working Lamp with High Efficiency. Applied Optics. 54: 69-74.

McHenry MP, D Doepel, BO Onyango, UL Opara. 2014. Small-Scale Portable Photovoltaic Battery-LED Systems with Submersible LED Units to Replace Kerosene-Based Artisanal Fishing Lamps for sub-Saharan African Lakes. Renewable Energy. 62:276-284.

de Souza JPI, W Vielstich. 2010. Seawater Alluminium/Air Cells in Handbook Of Fuel Cells –Fundamentals, Technology AND Applications. Edited by Wolf Vielstich, Hubert A. Gasteiger, Arnold Lamm and Harumi YokokawaJohn Wiley & Sons, Ltd. pp 1-7. Ch 1.

Mursyidah, Susanto A dan Isnaeni BS. 2013. The utilization of sea water in a especially designed battery (sabrine swall battery). ASEAN J of System Engineering. 1(1):1-7.

Mourant A. 2016. Next Generation Batteries will Power Up The Energy Storage Industry. Renewable Energy Focus. 17(1): 41-43. DOI:10.1016/j.ref.2015.11.004.

Park S, B SenthilKumar, K Kim, SM Hwang, Y Kim. 2016. Saltwater as The Energy Source for Low Cost, Safe Rechargeable Batteries. Journal Material Chemistery A. 4(19):7207-7213.

Liu Z, Lee H. 2015, Design of High-Performance Integrated Dimmable LED Driver for High-Brightness Solid-State Lighting Applications. International Journal of Analog Integrated Circuits and Signal Processing. 82(3): 519–532.

Budisusila EN, Arifin B. 2017. Joule-Thief Circuit Performance for Electricity Energy Saving of Emergency Lamps. IOP Conf. Series: Materials Science and Engineering 190: 1-6.

Garshol T, Hasvold O.. 1995. Galvanic Seawater Cell. US Patent 5,427,871, Juny 27.

Rehman Z, I Al-Bahadly, S Mukhopadhyay. 2015. Multiinput DC–DC Converters in Renewable Energy Applications - An Overview. Renewable and Sustainable Energy Reviews: 14: 521–539.

Oekerman JB. 1969. Seawater Battery Having Magnesium or Zinc Anode and Manganese Dioxide Cathode. US Patent 3,433,678, March 18.

Hasvold O. 1995. Seawater Cell with Increased Efficiency. U.S. Patent 5 405 717, Apr. 11.

Kobashi H, Oshitani M. 2013. Seawater Activated Batteries: Magnesium. Encyclopedia of Electrochemical Power Sources: 156-163.




DOI: http://dx.doi.org/10.33512/jpk.v8i1.3680

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