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Battery separators silver-zinc

The first practical silver—zinc battery was developed more then 60 years ago. Since then, primary and secondary silver—zinc batteries have attracted a variety of applications due to their high specific energy, proven reliability and safety, and the highest power output per unit weight and volume of all commercially available batteries. However, they find very limited use in commercial applications, because of their high price and limited cycle life. Development of a battery separator which will improve the performance and life of zinc based alkaline cells has been... [Pg.213]

For battery separators, regenerated cellulose is placed on the surface of nonwoven so that the nonwoven is available to promote the wicking of the electrolyte. The nonwovens should not allow the penetration of viscose into itself. Suitable nonwovens are made from polypropylene, poly(vinyl alcohol), and hardwood hemps. Regenerated cellulose films are commonly used in alkaline manganese cells, both primary and secondary, in NiCd industrial batteries, as well as in silver—zinc batteries. [Pg.215]

The nickel—zinc (NiZn) system is attractive as a secondary cell because of its high energy density and low material cost and the low level of potential pollutants contained. The widespread use of nickel-zinc batteries, particularly as electric vehicle power sources, would be strongly enhanced by significantly extending the deep-discharge cycle life beyond the current level of 100—300 cycles. Considerable work has been done in the past to develop a suitable separator for nickel— and silver—zinc batteries. 272 An excellent discussion of separator development is contained in a comprehensive review. 2 ... [Pg.215]

Lewis, H. Henderson, S. Danko, T. Separator composition evaluation in model rechargeable silver zinc cells. Proceedings of the 16th Annual Battery Conference on Applications Advances-, PEE-. New York, 2001. [Pg.223]

The study on the characterization of alkaline silver-zinc cells and composite electrodes for such cells was carried out [349, 350]. The improved silver-zinc battery with new developments in additives (Bi203) to the negative electrode and separator coatings for underwater... [Pg.750]

By test examinations of the membranes it was found that separation abilities in alkaline silver/zinc batteries are shown only by those in which the amount of g-PAA ranges from about 20 to 30 volume percent, The corresponding experimental data are presented in Table 1,... [Pg.258]

Zinc chloride battery separators Polyethylene, ultrahigh m.w. bearing metal Antimony Silver bearing metals/alloys Lead bearings... [Pg.4894]

Mercury and Silver (Button) Batteries Both mercury and silver batteries use a zinc container as the anode (reducing agent) in a basic medium. The mercury battery employs HgO as the oxidizing agent, the silver uses Ag20, and both use a steel can around the cathode. The sohd reactants are compacted with KOH and separated with moist paper. The half-reactions are... [Pg.714]

With the development of new separators and improved zinc electrodes, the nickel-zinc battery has now become competitive with the more familiar battery systems. It has a good cycle life and has load-voltage characteristics higher than those of the silver-zinc system. The energy per unit of weight and volume are slightly lower than those of the silver-cadmium system. Good capacity retention (up to 6 months) has made the nickel-zinc battery a more direct competitor of the silver-zinc and silver-cadmium systems. Nickel-zinc batteries aie not yet available in a sealed form. [Pg.98]

Zinc-silver oxide batteries as primary cells are known both as button cells, e.g., for hearing aids, watches, or cameras, and for military applications, usually as reserve batteries. Since the latter after activation have only a very short life (a few seconds to some minutes), a separation by cellulo-sic paper is generally sufficient. [Pg.286]

J.J. Lander, R. D. Weaver, A.J. Salkind, J.J. Kelley in Characteristics of Separators for Alkaline Silver Oxide Zinc Secondary Batteries. Screening Methods (Eds. J.E. Cooper, A. Fleischer), NASA Technical Report NAS 5-2860,1964. [Pg.564]

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See also in sourсe #XX -- [ Pg.65 ]



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