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[使用固体聚合物电解质进行水电解的某些方面]

[Some aspects of water electrolysis with the use of a solid polymer electrolyte].

作者信息

Zorina N G

出版信息

Aviakosm Ekolog Med. 2006 Nov-Dec;40(6):37-44.

PMID:17405280
Abstract

Electrochemical process in cells with a solid polymer electrolyte is dependent on catalyst durability in harsh environments and catalyst sputtering technology to ensure efficient power consumption. Active polymer electrolytes will permit to reduce substantially non-productive layouts and design a cost-effective, compact and safe system generator of high-purity oxygen and hydrogen. The existing designs of combined oxide systems integrating rear-earth and earth metals with a structure of Ln3+x Me2+1-x CoO3 containing perofskites were shown to be active catalysts in cells with a solid polymer electrolyte, and the sputtering technology was proven to reduce non-productive layouts in 2 or 2.5 times.

摘要

具有固体聚合物电解质的电池中的电化学过程取决于催化剂在恶劣环境中的耐久性以及催化剂溅射技术,以确保高效的功率消耗。活性聚合物电解质将允许大幅减少非生产性布局,并设计出一种具有成本效益、紧凑且安全的高纯度氧气和氢气系统发生器。将稀土和碱土金属与含钙钛矿结构的Ln3+x Me2+1-x CoO3整合在一起的复合氧化物系统的现有设计被证明是具有固体聚合物电解质的电池中的活性催化剂,并且溅射技术被证明可将非生产性布局减少2倍或2.5倍。

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