Experimental study on HHO electrolyzer efficiency – influence of the number of plates and their distance
The present paper explores the factors influencing the efficiency of an HHO-gas-electrolyzer. The experiments were held in the respective laboratory at the Technical University of Varna with a principal focus on two of these factors –i.e., distance between the plates and the number of plates in a wet electrolyzer. The scientific tests were performed with all the remaining conditions being held constant and the appropriate results were obtained and visualized to disclose the most efficient electrolyzer setups.
Al-Rousan, A. & Musma, S. (2018). Effect of anodes-cathodes inter-distances of HHO fuel cell on gasoline engine performance operating by a blend of HHO. International Journal of Hydrogen Energy, 43(41), 19213-19221.
Choodum, N., Sangwichien, C. & Yamsaengsung, R. (2019). Optimization of a Closed-Loop HHO Production System for Vehicles and Houses. Environmental Progress & Sustainable Energy, 38(1), 268 - 277.
Enshasy, H, Al-Haija, Q., Al-Amri, H., Al-Nashri, M., Al-Muhaisen, S. & Al-Tarayrah, M. (2020a). A Comprehensive Construction of Hydrogen-Hydrogen-Oxygen (HHO) Cell as Renewable Energy Storage. WSEAS TRANSACTIONS ON SYSTEMS, 19, 121-132.
Enshasy, H, Al-Haija, Q., Al-Amri, H., Al-Nashri, M., Al-Muhaisen, S. & Al-Tarayrah, M. (2020b). Elaborated Mathematical Model for Hydrogen-Hydrogen-Oxygen Energy Storage Cell. WSEAS TRANSACTIONS ON CIRCUITS AND SYSTEMS. 19, 116-128.
European Union. (2021). Proposal for DIRECTIVE OF THE EUROPEAN PARLIAMENT AND OF THE COUNCIL (2021) amending Directive (EU) 2018/2001 of the European Parliament and of the Council, Regulation (EU) 2018/1999 of the European Parliament and of the Council and Directive 98/70/EC of the European Parliament and of the Council as regards the promotion of energy from renewable sources, and repealing Council Directive (EU) 2015/652.
Neukirchner, L., Görbe, P., Magyar, A. & Attila, G. (2014). Measurement-based modeling and simulation of a hydrogen generating dry cell for complex domestic renewable energy systems. Hungarian Journal of Industry and Chemistry, 42(2), 85–89.
Streblau, M., Aprahamian, B., Simov, M, Dimova, T. (2014). The influence of the electrolyte parameters on the efficiency of the oxyhydrogen (HHO) generator. 18th International Symposium on Electrical Apparatus and Technologies (SIELA), (pp. 1-4). IEEE.
Subramanian, B. & Thangavel, V. (2020). Analysis of onsite HHO gas generation system. International Journal of Hydrogen Energy, 45(28), 14218-14231.
Sudrajat ,A., Handayani, E., Tamaldin, N. & Yamin, A. (2018). Principle of generator HHO hybrid multistack type production technologies to increase HHO gas volume. In SHS Web of Conferences, 49, p.02016. EDP Sciences.
Vasilev, R. & Nedelchev, I. (2011). Electrolytic cells for oxyhydrogen productions. Effects of circulation of the electrolyte and the electrode gap on the effectiveness. Annual of the Technical University of Varna, 1, pp. 91-95.
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