NaOH 浓度和平板表面纹理对 HHO 发生器性能的影响

IF 0.6 Q3 MULTIDISCIPLINARY SCIENCES

Pertanika Journal of Science and Technology Pub Date : 2024-04-01 DOI:10.47836/pjst.32.3.08

Asmawi Marullah Ridwan, M. R. Mansor, N. Tamaldin, Fahamsyah Hamdan Latief, Viktor Vekky Ronald Repi

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引用次数: 0

摘要

需要清洁能源作为替代能源是不可避免的。最近，HHO 气体受到了广泛关注。除了电解液浓度外，采用不同电极表面纹理方法进行突破的研究还不多。因此，本研究旨在确定 NaOH 浓度和电极板表面纹理对 HHO 发生器性能的影响。总的来说，电解液浓度的增加与表面纹理的结合会导致输出电流、HHO 气体产量和输出温度的增加。至于不同表面纹理的外加电压变化，输出电流、HHO 气体产量和输出温度也出现了增加，这与 NaOH 浓度增加的情况类似。无论是电解质浓度的增加还是外加电压的增加，都会加快离子移动，从而导致电导率增加，从而有效地帮助电解水。在输出电流和 HHO 气体产生量方面，在 NaOH 浓度增加或施加电压变化的情况下，纹理表面的数值远高于普通表面。然而，根据 R2 结果，线形表面与输出电流和 HHO 气体产量的关系比十字表面更密切。在输出温度方面，线性表面略低于十字表面。这可能是由于电解质溶液中的杂质污染了电极表面，导致线性表面的输出温度较低。

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Effects of NaOH Concentration and Plate Surface Texture on the Performance of the HHO Generator

The need for clean energy as an alternative is inevitable. HHO gas has received much attention lately. In addition to electrolyte concentration, the breakthrough with a diverse electrode surface texture approach has not been extensively performed. Therefore, this study aims to determine the effects of NaOH concentration and plate surface texture on the performance of the HHO generator. In general, the increase in electrolyte concentration combined with surface texture caused an increase in output current, HHO gas production, and output temperature. As for the applied voltage variation with various surface textures, the increase in output current, HHO gas production, and output temperature also took place, similar to the case of increasing NaOH concentration. Either an increase in electrolyte concentration or an increase in applied voltage triggers faster ion movement, leading to an increase in conductivity, thus effectively assisting the electrolysis of water. Regarding the output current and HHO gas production, the textured surface had a much higher value than the plain surface in terms of increasing NaOH concentration or applied voltage variations. However, according to the R2 results, the linear surface has a stronger relationship with the output current and HHO gas production than the cross surface. In the case of the output temperature, the linear surface was slightly lower than the cross surface. It is possibly due to impurities in the electrolyte solution that contaminate the electrode surface, resulting in a lower output temperature on the linear surface.

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来源期刊

Pertanika Journal of Science and Technology MULTIDISCIPLINARY SCIENCES-

CiteScore

1.50

自引率

16.70%

发文量

178

期刊介绍： Pertanika Journal of Science and Technology aims to provide a forum for high quality research related to science and engineering research. Areas relevant to the scope of the journal include: bioinformatics, bioscience, biotechnology and bio-molecular sciences, chemistry, computer science, ecology, engineering, engineering design, environmental control and management, mathematics and statistics, medicine and health sciences, nanotechnology, physics, safety and emergency management, and related fields of study.