Embodiments of the present disclosure include an apparatus for enclosing energy storage devices. An apparatus according to the present disclosure can include: an elongated sleeve having a contoured interior configured to enclose each of a plurality of energy storage devices, wherein the elongated sleeve is composed at least partially of a thermally conductive material; and at least one slot disposed on an exterior surface of the elongated sleeve, wherein the at least one slot is configured to receive for mechanically coupling a mounting rail to the elongated sleeve.

Embodiments of the present disclosure include an apparatus for enclosing energy storage devices. An apparatus according to the present disclosure can include: an elongated sleeve having a contoured interior configured to enclose each of a plurality of energy storage devices, wherein the elongated sleeve is composed at least partially of a thermally conductive material; and at least one slot disposed on an exterior surface of the elongated sleeve, wherein the at least one slot is configured to receive for mechanically coupling a mounting rail to the elongated sleeve.

Thermally regenerative ammonia-based battery systems and methods of their use to produce electricity are provided according to aspects described herein in which ammonia is added into an anolyte to charge the battery, producing potential between the electrodes. At the anode, metal corrosion occurs in the ammonia solution to form an ammine complex of the corresponding metal, while reduction of the same metal occurs at the cathode. After the discharge of electrical power produced, ammonia is separated from the anolyte which changes the former anolyte to catholyte, and previous anode to cathode by deposition of the metal. When ammonia is added to the former catholyte to make it as anolyte, the previous cathode becomes the anode. This alternating corrosion/deposition cycle allows the metal of the electrodes to be maintained in closed-loop cycles, and waste heat energy is converted to electricity by regeneration of ammonia, such as by distillation.

Thermally regenerative ammonia-based battery systems and methods of their use to produce electricity are provided according to aspects described herein in which ammonia is added into an anolyte to charge the battery, producing potential between the electrodes. At the anode, metal corrosion occurs in the ammonia solution to form an ammine complex of the corresponding metal, while reduction of the same metal occurs at the cathode. After the discharge of electrical power produced, ammonia is separated from the anolyte which changes the former anolyte to catholyte, and previous anode to cathode by deposition of the metal. When ammonia is added to the former catholyte to make it as anolyte, the previous cathode becomes the anode. This alternating corrosion/deposition cycle allows the metal of the electrodes to be maintained in closed-loop cycles, and waste heat energy is converted to electricity by regeneration of ammonia, such as by distillation.

Disclosed is an insulating bonding part for bonding to a solid electrolyte including beta-alumina, the insulating bonding part comprising a plurality of layers which have different mixing ratios of the alpha-alumina and CaO, wherein the layer closer to the solid electrolyte including the beta-alumina has a higher ratio of the CaO, and wherein the layer farther from the solid electrolyte including the beta-alumina has a higher ratio of the alpha-alumina.

Disclosed is an insulating bonding part for bonding to a solid electrolyte including beta-alumina, the insulating bonding part comprising a plurality of layers which have different mixing ratios of the alpha-alumina and CaO, wherein the layer closer to the solid electrolyte including the beta-alumina has a higher ratio of the CaO, and wherein the layer farther from the solid electrolyte including the beta-alumina has a higher ratio of the alpha-alumina.

Method and system for generating electrical energy from a volume of water.

Method and system for generating electrical energy from a volume of water.

Various embodiments of systems and methods for a thermogalvanic brick are disclosed.

Various embodiments of systems and methods for a thermogalvanic brick are disclosed.