Metal-air fuel cell battery system employing hydrostatic forces to enable simultaneous transport of metal-fuel tape, movable cathode structure, and ionically-conductive medium therethrough during system operation

Abstract

In an air-metal fuel cell battery (FCB) system, wherein a movable cathode structure is mounted within a housing through which metal-fuel tape is transported along a predetermined path while an ionically-conductive medium is disposed between the metal-fuel tape and the movable cathode structure. In illustrative embodiments, the movable cathode structure is realized as a rotatable cathode cylinder, and a transportable cathode belt. The ionically-conductive medium is realized as a solid-state ionically-conductive film applied to the cathode structures and/or metal-fuel tape, as well as ionically-conductive belt structures. During system operation, the metal-fuel tape and/or the ionically-conductive medium are wetted in order create sufficient surface tension, and thus sufficient hydrostatic forces, between the metal-fuel tape and ionically-conductive medium and between the ionically-conductive medium and the movable cathode structure, to enable the movable cathode structure, ionically-conductive medium and metal-fuel tape to move at substantially the same velocity at points of contact therebetween while only one or these three moving system components are being actively driven by a transport mechanism. By virtue of the present invention, it is possible to transport the moving components of the FCB system using a various types of low power devices including, for example, miniature electrical and spring-driven motors, while substantially reducing the likelihood of damage thereto during system operation.