A reserve battery is provided. The reserve battery includes a housing; a battery inside the housing, the battery including an anode, a cathode and a solid electrolyte between the anode and the cathode; and a movable piece for sliding within the housing to compress the battery such that sufficient heat is generated within the battery to activate the solid electrolyte. Methods of activating a reserve battery are also provided.

A reserve battery is provided. The reserve battery includes a housing; a battery inside the housing, the battery including an anode, a cathode and a solid electrolyte between the anode and the cathode; and a movable piece for sliding within the housing to compress the battery such that sufficient heat is generated within the battery to activate the solid electrolyte. Methods of activating a reserve battery are also provided.

A reserve batter is provided. The reserve battery includes a housing; a battery inside the housing, the battery including an anode, a cathode and a solid electrolyte between the anode and the cathode; and a movable piece for sliding within the housing to compress the battery such that sufficient heat is generated within the battery to activate the solid electrolyte. Methods of activating a reserve battery are also provided.

A reserve batter is provided. The reserve battery includes a housing; a battery inside the housing, the battery including an anode, a cathode and a solid electrolyte between the anode and the cathode; and a movable piece for sliding within the housing to compress the battery such that sufficient heat is generated within the battery to activate the solid electrolyte. Methods of activating a reserve battery are also provided.

An electrochemical system can include transition metal nanoparticles as a promoter for an electrode. The transition metal nanoparticles can include molybdenum (Mo), chromium (Cr), and/or the oxides thereof, which can lower recharge potentials and enhance the efficiency. These promoters promote especially the generation of oxygen and this for several cycles of usage of the electrochemical system which is, as a result, rechargeable.

An electronic device includes: a casing; a through hole which penetrates a bottom plate of the casing; a pin inserted into the through hole; a battery mounted on the pin inside the casing, wherein the battery includes a first lead terminal connected to an upper face of the battery, and a second lead terminal connected to a lower face of the battery; a first wiring layer disposed inside the casing and connected to the first lead terminal; and a second wiring layer disposed inside the casing to overlap with the second lead terminal in planar view. An upper face of the pin is higher in height than an upper face of the second wiring layer. The pin separates the second lead terminal and the second wiring layer from each other such that the second lead terminal and the second wiring layer are electrically insulated from each other.

An electronic device includes: a casing; a through hole which penetrates a bottom plate of the casing; a pin inserted into the through hole; a battery mounted on the pin inside the casing, wherein the battery includes a first lead terminal connected to an upper face of the battery, and a second lead terminal connected to a lower face of the battery; a first wiring layer disposed inside the casing and connected to the first lead terminal; and a second wiring layer disposed inside the casing to overlap with the second lead terminal in planar view. An upper face of the pin is higher in height than an upper face of the second wiring layer. The pin separates the second lead terminal and the second wiring layer from each other such that the second lead terminal and the second wiring layer are electrically insulated from each other.

Disclosed is a battery with an open bottom, comprising a battery assembly and an electrolyte storage box for accommodating an electrolyte. Said battery assembly comprises at least one battery pack, and said at least one battery pack can move between a first position and a second position relative to said electrolyte storage box; in the first position, said at least one battery pack contacts said electrolyte so as to enable said battery with an open bottom to generate electricity, and in the second position, said at least one battery pack is separated from said electrolyte such that said battery with an open bottom is turned off. The battery pack of the battery with an open bottom in the present invention can move between the first and the second positions relative to the electrolyte storage box so as to rapidly contact and react with the electrolyte.

Disclosed is a battery with an open bottom, comprising a battery assembly and an electrolyte storage box for accommodating an electrolyte. Said battery assembly comprises at least one battery pack, and said at least one battery pack can move between a first position and a second position relative to said electrolyte storage box; in the first position, said at least one battery pack contacts said electrolyte so as to enable said battery with an open bottom to generate electricity, and in the second position, said at least one battery pack is separated from said electrolyte such that said battery with an open bottom is turned off. The battery pack of the battery with an open bottom in the present invention can move between the first and the second positions relative to the electrolyte storage box so as to rapidly contact and react with the electrolyte.

The device 10 includes a liquid filled bellows activated battery composed of two non Miscible fluids 14, 15 flowing through a channel 13 containing two electrodes 16, 17 of different metals. One of the fluids 14 is an electrolyte while the second 15 one is electrically non conducting. At rest the two electrodes 16, 17 are in the non conductive fluid 15. When the electrical device is actuated, manually or by an external force, the fluids surrounding the electrodes 16, 17 are replaced by the electrolyte 14 thus generating an electrical voltage between the two electrodes. The electrical current can be used to temporarily generate light or supply energy to another device. When the actuation mechanism is released, the electrodes 16, 17 are surrounded by the non conductive fluids 15 again and the electrical current is stopped.