使用锌-铜电极和铝-铜电极的盐水电解电池性能比较

Larry Angelo R. Cañete
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引用次数: 0

摘要

在由电化学电池组成的电解池电池中,电能被用来驱动非自发的氧化还原反应。通过电解分解化合物的过程经常被使用,它源于希腊语 lysis,意思是分解。电解池由电解质、两个电极(一个阴极和一个阳极)以及其他三个部件组成。水或其他溶剂通常用来制作电解质,电解质是一种含有溶解离子的溶液。本研究的目的是利用各种电解溶液、盐水浓度以及燃料电池和电极的整合,测试、分析和构建电解电池。研究设计为实验性,依靠描述性分析进行评估。设计的重点是找到仅限于锌、铜和铝(苏打罐)的电极、不同的电解液、燃料电池的连接类型以及所使用的不同浓度的盐水的最佳组合,以提供最佳的能量输出。根据收集和分析的数据,锌铜电极每个电池产生的平均电压为 0.705 V。盐水电解液的成本效益最高。当盐水溶液浓度为 30% 时,可达到最佳电压输出,燃料电池串联时性能最佳。利用这一参数,构建的 20 个燃料电池可在无任何负载的情况下产生 14.10 V 的电压。当连接到 12V 电源的直流照明负载时,电压为 7.57 V,电流为 1.1 A。
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A Comparison of the Performance of Saltwater Electrolytic Cell Battery with Zinc-Copper and Aluminum-copper Electrodes
Electrical energy is used to drive a non-spontaneous redox reaction in an electrolytic cell battery, which is composed of an electrochemical cell. The process of breaking down chemical compounds through electrolysis is frequently utilized, and it is derived from the Greek word lysis, which means to disintegrate. The electrolytic cell is composed of an electrolyte, two electrodes (one cathode and one anode), and three other components. Water or other solvents are typically used to make an electrolyte, which is a solution that contains dissolved ions. The purpose of this study is to test, analyze, and construct an electrolytic cell battery using various electrolytic solutions, salt-water concentrations, and the integration of fuel cells and electrodes. The research is designed to be experimental and relies on descriptive analysis to assess it. The design focused on the finding the optimal combination of electrode limited to zinc, copper, and aluminum (soda can), different electrolyte, type of connection of the fuel cells and the different concentration of saline solution used in order to provide optimum energy output. According to the data gathered and analyzed, the Zinc-Copper electrode produces an average voltage of 0.705 V per cell. Saltwater electrolyte produces the most effective results based on its cost effectiveness. When saline solution is 30% concentrated, the optimal voltage output is achieved, and fuel cells perform their best when connected in series. Using this parameter, twenty fuel cells are constructed that can produce 14.10 V without any load. The voltage was 7.57 V and the current was 1.1 A when connected to a DC lighting load that has a 12V power supply.
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