Abstract: A method includes attaching a package component to a package substrate, the package component includes: an interposer disposed over the package substrate; a first die disposed along the interposer; and a second die disposed along the interposer, the second die being laterally adjacent the first die; attaching a first thermal interface material to the first die, the first thermal interface material being composed of a first material; attaching a second thermal interface material to the second die, the second thermal interface material being composed of a second material different from the first material; and attaching a lid assembly to the package substrate, the lid assembly being further attached to the first thermal interface material and the second thermal interface material.

Abstract: A three-stage thermal management design of battery module, battery device, and battery system is provided, which not only prevents the battery cells from being impacted by the environment temperature, but also efficiently controls the temperature of the battery cells, such that the battery cells can reach the requirements of temperature equalization and appropriate opening temperature. The thermal management design of the battery module is mainly a design of a battery cell charging and discharging circuit having heat exchange.

Abstract: The present invention utilizes a three-stage thermal management design of battery module, battery device, and battery system that not only prevents the battery cells from being impacted by the environment temperature, but also efficiently controls the temperature of the battery cells, such that the battery cells can reach the requirements of temperature equalization and appropriate opening temperature. The thermal management design of the battery module is mainly a design of a battery cell charging and discharging circuit having heat exchange.

Abstract: The present invention provides a battery module, a battery device, and a battery system having a thermal management design. It utilizes a three-stage thermal management design of the battery module, the battery device, and the battery system to not only prevent the battery cells from being impacted by the environmental temperature, but also efficiently control the temperature of the battery cells, such that the battery cells can reach the requirements of temperature equalization and appropriate operating temperature. The thermal management design of the battery module is mainly a design of a battery cell charging and discharging circuit having heat exchange. The thermal management design of the battery device is mainly a battery device enclosure having a thermal insulation ability, so as to avoid or reduce the impact of the environmental temperature to the temperature of the battery module.

Abstract: An energy storage device is provided. The energy storage device includes at least an energy-type electrode pair, including a first positive electrode; a first negative electrode disposed opposite to the first positive electrode; and a first electrolyte disposed between the first positive electrode and the first negative electrode; at least a power-type electrode pair, including a second positive electrode; a second negative electrode disposed opposite to the second positive electrode; and a second electrolyte disposed between the second positive electrode and the second negative electrode; and a housing receiving the energy-type electrode pair and the power-type electrode pair.

Abstract: A battery cell balancing control system and a battery management method thereof are disclosed. The battery cell balancing control system is used for managing a battery apparatus, wherein the battery apparatus has a plurality of battery cells. The battery cell balancing control system comprises a detection module, a battery management module, and an adjusting module. The detection module is used for executing a battery checking procedure on the plurality of battery cells to generate a detection result. The battery management module is used for determining whether the plurality of battery cells has a controlled cell according to the detection result. If the controlled cell has not been found among the plurality of battery cells, the battery management module controls the adjusting module to execute a battery cell balancing procedure until the controlled cell is found.

Abstract: The present invention provides a multi-dimensional carbon active compound composite comprising a first carbon material, a second carbon material, an active compound, and further a seed material. This composite is capable of storing faradic or non-faradic charges. The produced multi-dimensional carbon can significantly inhibit the aggregation and disintegration of active compounds. Stacked carbon structure also formed a 3-D framework with high electron conductivity, which increases the rate capability of electrode. The green and simple synthesis process has a great potential for mass production. This green energy storage material can be widely applied to lithium secondary ion battery, supercapacitor, and lithium-air battery electrodes.

Abstract: A system and a method for electricity management are disclosed. The system includes a data management unit, a cabinet, a control unit, an uninterruptible power supply apparatus and a power switch. The cabinet is powered by an external power supply. When the data management unit sends a testing instruction to the cabinet, the control unit controls the power switch to shut down the external power supply such that the cabinet is powered by the uninterruptible power supply apparatus instead. The control unit measures a set of battery parameters of the uninterruptible power supply apparatus, computes a power supply capacity of the uninterruptible power supply apparatus according to the set of battery parameters, and returns the power supply capacity to the data management unit.

Abstract: An energy storage device is provided. The energy storage device includes at least an energy-type electrode pair, including a first positive electrode; a first negative electrode disposed opposite to the first positive electrode; and a first electrolyte disposed between the first positive electrode and the first negative electrode; at least a power-type electrode pair, including a second positive electrode; a second negative electrode disposed opposite to the second positive electrode; and a second electrolyte disposed between the second positive electrode and the second negative electrode; and a housing receiving the energy-type electrode pair and the power-type electrode pair.

Abstract: An energy storage device is provided. The energy storage device includes an energy type electrode pair having a first unit energy density and a first unit discharge power; a power type electrode pair having a second unit energy density and a second unit discharge power, and electrically connected to the energy type electrode pair; a housing receiving the energy type electrode pair and the power type electrode pair; a first electrolyte disposed in the energy type electrode pair; and a second electrolyte disposed in the power type electrode pair, wherein the energy type electrode pair forms a first electrically conductive circuit via the first electrolyte, and the power type electrode pair forms a second electrically conductive circuit via the second electrolyte.

Abstract: A battery cell balancing control system and a battery management method thereof are disclosed. The battery cell balancing control system is used for managing a battery apparatus, wherein the battery apparatus has a plurality of battery cells. The battery cell balancing control system comprises a detection module, a battery management module, and an adjusting module. The detection module is used for executing a battery checking procedure on the plurality of battery cells to generate a detection result. The battery management module is used for determining whether the plurality of battery cells has a controlled cell according to the detection result. If the controlled cell has not been found among the plurality of battery cells, the battery management module controls the adjusting module to execute a battery cell balancing procedure until the controlled cell is found.

Abstract: A system and a method for electricity management are disclosed. The system includes a data management unit, a cabinet, a control unit, an uninterruptible power supply apparatus and a power switch. The cabinet is powered by an external power supply. When the data management unit sends a testing instruction to the cabinet, the control unit controls the power switch to shut down the external power supply such that the cabinet is powered by the uninterruptible power supply apparatus instead. The control unit measures a set of battery parameters of the uninterruptible power supply apparatus, computes a power supply capacity of the uninterruptible power supply apparatus according to the set of battery parameters, and returns the power supply capacity to the data management unit.

Abstract: A battery apparatus is disclosed. The battery apparatus has a frame body, a plurality of battery units, a first electric conductive sheet, a first electric-insulated thermally conductive pad, and a thermally conductive panel. The frame body has an upper surface and a first lateral plane; the plurality of battery units are situated inside the frame body and a first electrode of each battery unit is exposed to the upper surface; the first electric conductive sheet touches the upper surface and contacts the first electrode for conducting the electric currents of the plurality of battery units; the first electric-insulated thermally conductive pad is situated above the first electric conductive sheet; the first thermally conductive panel is situated above the first electric-insulated thermally conductive pad and contacts the first lateral plane.

Abstract: A ceramic injection molding composition consisting of a three component binder system with a ceramic powder in which the binder system has good wettability towards the ceramic powder was disclosed. The binder system includes a first component soluble in water, a second component which is a water emulsified acrylic resin and a third component as a lubricant. A homogeneous powder binder blend can be achieved during low temperature mixing of the powder. As the binder system has strong affinity towards the ceramic powder and easily mixed with ceramic powder it eliminates the use of a high temperature mixing which involves difficult instruments. The binder system was successfully applied to a wide range of ceramic powders. The composition of the binder system depends on the powder and its density. Addition of water to powder binder mixture enhances the dispersion of powder into binder.