储能科学与技术 ›› 2021, Vol. 10 ›› Issue (6): 2090-2096.doi: 10.19799/j.cnki.2095-4239.2021.0224

• 储能材料与器件 • 上一篇    下一篇

无溶剂制备锌空气电极及电池性能

胡铭昌1(), 周雪晴1, 黄雪妍2, 薛建军1   

  1. 1.广州鹏辉能源科技股份有限公司,广东 广州 511483
    2.中山大学材料科学与工程学院,广东 广州 510000
  • 收稿日期:2021-05-22 修回日期:2021-06-15 出版日期:2021-11-05 发布日期:2021-11-03
  • 通讯作者: 胡铭昌 E-mail:mchu@greatpower.net
  • 作者简介:胡铭昌(1987—),男,博士,主要研究方向为金属空气电池的商业化工作,E-mail:mchu@greatpower.net
  • 基金资助:
    佛山市核心技术攻关项目(192001001421)

Solvent-free fabrication of zinc-air electrodes and their battery performance

Mingchang HU1(), Xueqing ZHOU1, Xueyan HUANG2, Jianjun XUE1   

  1. 1.Guangzhou Great Power Energy & Technology Co. Ltd, Guangzhou 511483, Guangdong, China
    2.School of Materials Science and Engineering, Sun Yat-sen University, Guangzhou 510000, Guangdong, China
  • Received:2021-05-22 Revised:2021-06-15 Online:2021-11-05 Published:2021-11-03
  • Contact: Mingchang HU E-mail:mchu@greatpower.net

摘要:

锌空气电池具有高安全、大容量、低成本和低自放电等特性,因此获得广泛关注,尤其被广泛用作助听器电池。目前商业化空气电极的制作过程中,催化粉料的处理往往涉及湿法工艺,制造过程复杂,且烘干溶剂过程能源消耗大。利用转速为3000 r/min的高速切割机器进行造粒处理,过程中不使用溶剂,然后经过12目筛网进行过筛处理即得可自由流动的无溶剂处理催化粉料,借助扫描电子显微技术(SEM)进一步观察到催化粉料中大量黏结剂完全纤维化的现象,这种纤维束有利于维持住粉料与粉料之间的紧密结合状态。用自制对辊机器将上述催化粉料压成卷对卷的催化层,再把集流体镍网、防水透气膜与之辊压复合一起,即得无溶剂处理的商业化锌空气电极。作为对比,使用了传统湿法方式制作催化粉料和空气电极,发现无溶剂处理空气电极制得的电池容量高于传统湿法的5%。另外,研究了不同空气极片压实密度和厚度、不同的防水透气膜等对锌空气电池性能的影响,分析表明低密度1.15 g/cm3的空气电极拥有更好的容量储存性能,厚度为0.52 mm空气电极所制电池拥有更高的功率密度,纯聚四氟乙烯(PTFE)膜作为防水透气膜可使锌空气电池拥有更好的防漏液性能。综上所述,这种无溶剂制备空气电极工艺简单方便、环保节能,更适合金属空气电池的商业化应用。

关键词: 锌空气电池, 空气电极, 无溶剂制备, 卷对卷, 商业化应用

Abstract:

Zinc-air batteries have gained popularity due to their high capacity, low cost, and low self-discharge performance. Zinc-air button batteries are the preferred power source for hearing aids, particularly in the medical field. German company Varta, American company Rayovac, and Chinese company ZeniPower are the main manufacturers of zinc-air hearing-aid button cells. The commercial air electrodes of zinc-air batteries are frequently manufactured using a wet process that involves preparing catalyst powders, which is time-consuming and energy-intensive. This study introduced a novel method using a 3000 rpm high-speed cutting machine without adding any solvent for the granulating process. Then after being treated by 12 mesh sieve, highly free-flowing dry catalyst powders were obtained for further treatment. Scanning electron microscope shows that the polytetrafluoroethylene (PTFE) binders in the catalyst powders are widely and completely fibrillated, which is beneficial to binding the catalyst powders together tightly even in the long term of storage. The above catalyst powders were then pressed into a roll-to-roll catalyst layer by self-made rollers and relevant machines. The current collector, waterproof and air permeable films, and the catalyst layer were pressed together to obtain the solvent-free fabrication of commercial zinc-air electrodes. A traditional commercial wet process was utilized to prepare the catalyst powders and air electrodes to make a comparison. It demonstrates that the discharge capacity of zinc-air batteries using solvent-free electrodes is 5% higher than the wet method, which could be attributed to the solvent-free fabrication process's widespread and complete formation of strong fibrillated PTFE fibers. Different electrode densities and thicknesses, as well as different waterproof and air permeable films, were also investigated. It shows that electrodes with a low density of 1.15 g·cm-3 have better capacity performance after storage, possibly because there is higher bonding strength between the catalyst layer and PTFE film in the air electrode. Electrodes with larger thicknesses as 0.52 mm contribute to higher power density resulting from more three-phase active sites in the catalyst layer. Because of the high strength of carbon-fluorine bonds, pure PTFE film functioned as waterproof and air permeable films with better anti-leakage performance. To summarize, this solvent-free process is simple, energy-efficient, and appropriate for commercializing metal-air batteries. More applications in various types of metal-air batteries, such as large-size, solid-state, flexible, and secondary batteries, could benefit from this commercialized technology in the future.

Key words: zinc-air batteries, air electrodes, solvent-free fabrication, roll to roll, commercial application

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