Abstract: A liquid reserve battery including: a collapsible storage unit having a liquid electrolyte stored therein; a battery cell in communication with an outlet of the collapsible storage unit, the battery cell having gaps dispersed therein; a first pyrotechnic material partially disposed adjacent the collapsible storage unit such that initiation of the first pyrotechnic material provides pressure to collapse the collapsible storage unit to heat and force the liquid electrolyte through the outlet and into the gaps; and a tube disposed in the battery cell, wherein second pyrotechnic material is disposed in the tube, the tube being one of formed of an electrically non-conductive material or covered with an electrically non-conductive material.

Abstract: A method for producing power from a liquid reserve battery. The method including heating a liquid electrolyte and forcing the heated liquid electrolyte into gaps dispersed in a battery cell.

Abstract: A method for creating a formed-in-place seal on a fuel cell plate is disclosed. The method includes first dispensing a flowable seal material along a first sealing area of a fuel cell plate requiring the seal material. Next, a preformed template is located adjacent to at least a portion of the fuel cell plate, the template including predetermined apertures corresponding with a second sealing area of the plate, such that the apertures are coextensive with at least a portion of the first sealing area. Flowable seal material is applied into the apertures, and is then cured to a non-flowable state.

Abstract: An inertial igniter including: a body having a base; a striker release element rotatably disposed on the body, the striker release element having a first surface; a first biasing element for biasing the striker release element away from the base; a striker mass rotatably disposed on the base along a second axis, the striker mass having a second surface corresponding to the first surface of the striker release element, the first surface obstructing rotation of the striker mass; and a second biasing element for biasing the striker mass such that the second surface is biased towards the first surface; wherein when the body experiences an acceleration profile of a predetermined magnitude and duration, the striker release element rotates towards the base to release an engagement between the first and second surfaces and allow the striker mass to rotate under a biasing force of the second biasing element.

Abstract: A slow-burn thermal battery includes a cathode, an anode, and a meltable electrolyte disposed between the cathode and the anode. The slow-burn thermal battery further includes a burnable fuse operably associated with the meltable electrolyte for melting the electrolyte.

Abstract: A micro fuel cell comprises at least a substrate provided with front and rear faces. The front face of the substrate supports a successive stacking of a first electrode, a substantially flat electrolytic membrane and a second electrode. The electrolytic membrane comprises at least one anchoring element salient substantially perpendicularly to a main plane of said membrane. The anchoring element is arranged in a complementary part of an anchoring recess formed in the substrate. The substrate can also comprise a plurality of microchannels, substantially perpendicular to the main plane of the membrane. The anchoring recess can then be formed by one of the microchannels whereas the other microchannels enable supply of the first electrode with reactive fluid. Such a micro fuel cell is able to operate when a pressure difference exists between the two sides of the stacking.

Abstract: A conformable battery wherein the outer casing has an upper face plate, a lower face plate, and at least one perimetric wall, and an interior of the battery comprising a grid of walls extending from the upper face plate to the lower face plate and connecting to the at least one perimetric wall, thereby dividing the interior of the battery into at least two compartments and increasing the battery's structural stiffness and ability to sustain increased internal pressure. Each compartment contains an electrochemically active plate stack, and a network of electrical conductors provides electrical connection between the plate stacks in each of the compartment. The battery may further comprise a reservoir containing an acid additive which, when released into each of the compartments, shifts the battery from a low power mode into a high power mode.

Abstract: A thermal battery is housed in a chamber that utilizes micro-electromechanical systems (MEMS)-based technology to offer superior chemical stability and advantageous mechanical and thermal properties. The thermal battery of the present invention is activated by heat, for example heat generated by a pyrotechnic charge, for example thermite, for immediate and thorough activation of the electrolyte. The anode, cathode and electrolyte of the battery are formed of pellets having a curved interface for increased current density. The electrolyte preferably comprises a three-component eutectic salt mixture. In this manner, the thermal battery of the present invention is well suited for applications that require highly integrated thermal batteries that are relatively small in physical size, yet are capable of reliable performance over a wide range of operating conditions.

Abstract: A battery has an outer casing, an electrolyte located within the outer casing, an additive located within the outer casing and separated from the electrolyte, and a power mode increasing device located within the outer casing. The battery operates in a low power mode. The power mode increasing device combines the electrolyte and the additive causing the battery to operate in a high power mode. The power generated by the battery operating in the high power mode is greater than the power generated by the battery operating in the low power mode.

Abstract: A novel apparatus and method for constructing a stress resistant battery which allows the use low modulus materials through end wall rib reinforcements and a cover having a plurality of integral bosses which vertically project and connect to cast on straps. A plurality of baffles adapted to snap fit into the inner bottom portion of the cover and augment stress resistance through rigid contact against the battery plates. A plurality of cast on straps welded back to back in pairs through each of said electrochemical cell walls each having a seating boss so as to connect with each of the cover bosses.The battery of the present invention also includes means of affixing terminal connectors in a scalloped configuration thereby preventing over-torquing and failure of the cover during electrical-mechanical connection.

Abstract: A porous substrate of a fuel cell electrode assembly is formed by producing a fibrous carbon precursor web by means of a conventional wet paper-making process. The precursor web is then dried and saturated with a wet resinous binder which will carbonize when heated. Substantially the entirety of all of the carbon fibers in the web are thus coated with the binder, and substantially all of the inter-fiber junctures in the web will also be coated with the binder. The saturated web is then dried, and heat treated to convert the binder to a glassy carbon which exhibits superior resistance to corrosion.

Abstract: An electrolyte matrix is integrated with at least one electrode catalyst layer, namely, catalyst layers which can be independent from an electrode substrate. Therefore, the permeation of catalyst to the substrate can be prevented, the amount of catalyst used can be reduced, and an electrode of uniform thickness and composition can be produced and used.

Abstract: A multi-option, multi-cell, vacuum activated, deferred action battery which consists of a non-frangible vial which can be punctured allowing a vacuum pressure in a battery cell assembly to draw said battery fluid into said battery cells thus activating the device. This activation can occur with or without external forces such as spin or setback.

Abstract: A battery in accordance with the invention comprises: p1 an electrochemical block (3) constituted by a large number of electrochemical couples; p1 a network for irrigating said electrochemical couples with electrolyte; p1 a heat exchanger (7) for externally dumping the heat evolved during discharge; p1 a pump (5) for causing the electrolyte (10) to circulate through the irrigation network and said heat exchanger; and p1 a device (2) for storing electrolyte and transferring it to said electrochemical block (3) on activation, said device including a supply of electrolyte connected to a gas generator and also to an inlet to said pump.

Abstract: A multi-option deferred action battery which consists of an electrolyte filled ampule which can be broken to activate the battery. This activation can occur with or without external forces such as spin or set-back.

Abstract: A reserve cell has cylindrical electrodes surrounding a cell component container, all in a cylindrical housing. A shim has a circular groove accepting one end of an electrode and a socket holding one end of the container. The outer edge of the shim abuts the inner wall of the housing. This arrangement maintains spatial relationships of the cell.

Abstract: An electrochemical reserve cell includes a cylindrical housing a concentric arrangement of a liquid cell component container, a metal anode, a porous separator, and a porous carbon element. The metal anode is cylindrical with a spiral slot extending between its ends and is pressed into a perforated anode support cylinder having adjacent edges welded together. The anode and anode support structure are interlocked together.

Abstract: A reserve cell has a cylindrical housing with a closed end. A cylindrical battery stack is located within the housing, surrounding a cell component container and separated from the closed end by a channeled ring. A disc is located with the ring for transmitting pressure from the closed end of the container.

Abstract: The invention relates to an activateable battery (1) comprising a container of electrolyte (2) which when activated is pressed down over a tap (11) adapted to the container. During the moving of the container down over the tap (11) electrolyte (21) is pressed out of the container (2) and via cell openings (14) into cells (13). The container tightens the cell openings (14) in its lower end position. The battery is enclosed under vacuum. According to the invention an activateable battery is obtained which not need any rotation and which may contain several separate battery cells. Such a battery is useable within the ammunition field and especially in grenade thrower ammunition and ammunition which is controlled in its final phase (FIG. 1).

Abstract: A system for activating reserve batteries pyrotechnically, including silicone rubber for conducting the force of detonation from a primer to the ends of the batteries to deform them smoothly and uniformly, and to insulate their casings from metal fragments or combustion products resulting from the detonation.

Abstract: A centrally-activated deferred-action silver-zinc battery has a central well defined by a stack of electrodes and separators each having a central hole. Isolating washers are placed around the central holes of each metal sheet and include recesses which provide curved channels for conveying electrolyte from the well towards the electrodes. The restricted cross-section and extended length of these channels ensure a greater electrical resistance to leakage currents which flow between couples via the electrolyte during activation. Pyrotechnic means are provided to activate the battery by rupturing a fragible partition and rapidly forcing electrolyte from an isolated compartment via the rupture in the partition into the well and from thence via the curved channels to spaces provided between electrodes of opposite polarity.

Abstract: A fuel cell having good resistance to compressive creep includes electrodes having a superstructure of porous electrically conductive foam with surface sections adjacent to opposing surfaces of an electrolyte matrix impregnated with electrode catalyst materials. The catalyst materials are affixed in sections contiguous to an inner major surface by sinter bonding, electrochemical bonding or restrictive interstitial spacing. The outer sections of the porous plaque thickness are reserved for gas distribution to the electrode catalyst. Oxidant and fuel gases can be separately manifolded into alternate sides of a fuel cell stack by sealing opposing edges of the porous plaques containing the anode material in one set of opposing side surfaces and sealing opposing edges of the porous plaque containing cathode material in alternate side surfaces of the stack.