The Material Preparation, Characterization and Cell Assembly for Zinc-Air Cell

碩士 === 國立中正大學 === 化學工程所 === 97 === This study focused on the fabrication and characteristics analysis of the air-cathode and the zinc anode, in order to increase the performance of zinc-air battery. We used manganese oxidation nanomaterials as the catalysts, which have high activity and good chemica...

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Main Authors: Yueh-en Liu, 劉悅恩
Other Authors: Yuan-yao Li
Format: Others
Language:zh-TW
Published: 2009
Online Access:http://ndltd.ncl.edu.tw/handle/84227987962627988272
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spelling ndltd-TW-097CCU050630322016-05-04T04:26:07Z http://ndltd.ncl.edu.tw/handle/84227987962627988272 The Material Preparation, Characterization and Cell Assembly for Zinc-Air Cell 鋅-空氣電池之材料製備、特性分析及其組裝 Yueh-en Liu 劉悅恩 碩士 國立中正大學 化學工程所 97 This study focused on the fabrication and characteristics analysis of the air-cathode and the zinc anode, in order to increase the performance of zinc-air battery. We used manganese oxidation nanomaterials as the catalysts, which have high activity and good chemical stability. Compare with commercial manganese dioxide, nanoscale manganese oxidations are better in its catalytic ability. Through the research of the functions of the air-cathode and the zinc anode, the efficiency and the lifetime of the battery have been increased. The structure of the zinc-air battery can be categorized into three main parts, namely: the air-cathode, the zinc anode and the electrolyte. By finding the most active nanoscale manganese oxidation catalyst and by using material and electrochemical analyses, we have obtained the best operation conditions for the air-cathode. The influence of the contents of the binder and carbon source in the gas-diffusion layer is especially explored. This exploration prevents polarization on the surface of the electrode during high current density discharging, while promoting the rate of the electronic transmission of the air-cathode to increase the overall performance of the battery. The optimal composition for the gas-diffusion layer is 60wt% carbon nanocapsules (CNC) and 40wt% PTFE. In regard to the zinc anode, CNC with high specific surface area is added into the zinc powder to prevent passivation of the zinc anode in the electrolyte, so that the decrease in battery performance can be avoided. On the operational level, a single zinc-air battery that is able to provide sufficient power to mobilize an electric fan has been successfully constructed. The structure of the air-cathode allows air to enter, while the other end of the air-cathode comes into contact with the electrolyte to form a solid, a liquid and a gas interface. These interfaces allow the gas to go through the process of oxygen reduction reaction. For such an exchangeable zinc-air battery, if the zinc anode should corrode or be reshaped, it can be conveniently replaced. Yuan-yao Li 李元堯 2009 學位論文 ; thesis 157 zh-TW
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language zh-TW
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description 碩士 === 國立中正大學 === 化學工程所 === 97 === This study focused on the fabrication and characteristics analysis of the air-cathode and the zinc anode, in order to increase the performance of zinc-air battery. We used manganese oxidation nanomaterials as the catalysts, which have high activity and good chemical stability. Compare with commercial manganese dioxide, nanoscale manganese oxidations are better in its catalytic ability. Through the research of the functions of the air-cathode and the zinc anode, the efficiency and the lifetime of the battery have been increased. The structure of the zinc-air battery can be categorized into three main parts, namely: the air-cathode, the zinc anode and the electrolyte. By finding the most active nanoscale manganese oxidation catalyst and by using material and electrochemical analyses, we have obtained the best operation conditions for the air-cathode. The influence of the contents of the binder and carbon source in the gas-diffusion layer is especially explored. This exploration prevents polarization on the surface of the electrode during high current density discharging, while promoting the rate of the electronic transmission of the air-cathode to increase the overall performance of the battery. The optimal composition for the gas-diffusion layer is 60wt% carbon nanocapsules (CNC) and 40wt% PTFE. In regard to the zinc anode, CNC with high specific surface area is added into the zinc powder to prevent passivation of the zinc anode in the electrolyte, so that the decrease in battery performance can be avoided. On the operational level, a single zinc-air battery that is able to provide sufficient power to mobilize an electric fan has been successfully constructed. The structure of the air-cathode allows air to enter, while the other end of the air-cathode comes into contact with the electrolyte to form a solid, a liquid and a gas interface. These interfaces allow the gas to go through the process of oxygen reduction reaction. For such an exchangeable zinc-air battery, if the zinc anode should corrode or be reshaped, it can be conveniently replaced.
author2 Yuan-yao Li
author_facet Yuan-yao Li
Yueh-en Liu
劉悅恩
author Yueh-en Liu
劉悅恩
spellingShingle Yueh-en Liu
劉悅恩
The Material Preparation, Characterization and Cell Assembly for Zinc-Air Cell
author_sort Yueh-en Liu
title The Material Preparation, Characterization and Cell Assembly for Zinc-Air Cell
title_short The Material Preparation, Characterization and Cell Assembly for Zinc-Air Cell
title_full The Material Preparation, Characterization and Cell Assembly for Zinc-Air Cell
title_fullStr The Material Preparation, Characterization and Cell Assembly for Zinc-Air Cell
title_full_unstemmed The Material Preparation, Characterization and Cell Assembly for Zinc-Air Cell
title_sort material preparation, characterization and cell assembly for zinc-air cell
publishDate 2009
url http://ndltd.ncl.edu.tw/handle/84227987962627988272
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