The Potential of Solid Electrolyte from Fish Waste for Battery Application
DOI:
https://doi.org/10.46754/umtjur.v2i1.99Keywords:
Filtering and soaking, number of cell layer, quantity of fish, solid electrolyte, voltageAbstract
This experiment was conducted to study the potential of solid electrolyte from the fish waste of Clarias gariepinus for battery application. The battery was one of the important components that supplies electrical energy to users throughout the world, and it strongly contributed to technology development in the economic sector, transportation, residential as well as agriculture. The presence of ammonia in organic fish waste could produce renewable energy and helped to reduce the use of lithium-ion batteries in modern industries. Two different parameters were being observed in this study, which was the quantity of fish and the number of the cell layer. The process of collecting the fish waste was carried out in the hatchery at Universiti Malaysia Terengganu using two methods, which were filtering and soaking. The result showed that the highest value of energy output was 0.430V from waste filtering of 50 fish and 0.207V from soaking in waste of 50 fish. Meanwhile, the lowest energy output was from the tank that contained ten fish with an energy output of 0.177V for filtering and 0.101V for soaking. Besides, for a different number of the cell layer, the highest value of energy output was 0.414V at 25 layers, and the lowest voltage was 0.175V at five layers. Thus, from the study was observed that the produced voltage was dependent on the quantity of fish and the number of the cell layer, when the quantity of fish and number of cell layer increases, the output energy was also increased.
References
Altinok, I., and Grizzle, J. M. (2004). Excretion of ammonia and urea by phylogenetically diverse fish species in low salinities, 238, 499–507. https://doi.org/10.1016/j.aquaculture.2004.06.020
Brunner, P. H., & Rechberger, H. (2015). Waste to energy – key element for sustainable waste management. Waste Management, 37, 3–12. https://doi.org/10.1016/j.wasman.2014.02.003
Durborow, R. M., Crosby, D. M., & Brunson, M. W. (1997). Ammonia in Fish Ponds, (463).
Greggio, N., Carlini, C., Contin, A., Soldano, M., and Marazza, D. (2018). Exploitable fish waste and stranded beach debris in the Emilia-Romagna Region ( Italy ). Waste Management, 78, 566–575. https://doi.org/10.1016/j.wasman.2018.06.034.
Kumar, A., & Samadder, S. R. (2017). A review on technological options of waste to energy for effective management of municipal solid waste. Waste Management, 69, 407–422. https://doi.org/10.1016/j.wasman.2017.08.046
Lazaroiu, G., Pană, C., Mihaescu, L., Cernat, A., Negurescu, N., Mocanu, R., & Negreanu, G. (2017). Solutions for energy recovery of animal waste from leather industry. Energy Conversion and Management, 149, 1085–1095. https://doi.org/10.1016/j.enconman.2017.06.042
Olabi, A. G. (2016). Hydrogen and Fuel Cell developments: An introduction to the special issue on “The 8th International Conference on Sustainable Energy and Environmental Protection (SEEP 2015), 11–14 August 2015, Paisley, Scotland, UK.” International Journal of Hydrogen Energy, 41(37), 16323–16329. https://doi.org/10.1016/j.ijhydene.2016.07.235
Olabi, A. G. (2017). Renewable energy and energy storage systems. Energy, 136, 1–6. https://doi.org/10.1016/j.energy.2017.07.054
Pavlas, M., Fusek, M., Klimek, P., and Touš, M. (n.d.). Waste-to-Energy Systems Modelling Using In-House Developed Software, 1–6.
Unit, A., River, C., and Development, B. (2018). GSJ : Volume 6 , Issue 9 , September 2018, Online : ISSN 2320-9186. 6(9), 589–612.
Zhang, J., Zhao, J., Yue, L., Wang, Q., Chai, J., Liu, Z., … Chen, L. (2015). Safety-Reinforced Poly(Propylene Carbonate)-Based All-Solid-State Polymer Electrolyte for Ambient-Temperature Solid Polymer Lithium Batteries. Advanced Energy Materials, 5(24), 1–10. https://doi.org/10.1002/aenm.201501082