Abstract: A multilayer polymer capacitor (MLPC), including a casing, a multilayer core, an electroplated positive terminal, a first electroplated negative terminal, and a second electroplated negative terminal. The casing includes a casing body and a cover plate. The casing body is provided with an accommodating cavity, whose bottom is provided with a through hole. The multilayer core is provided in the accommodating cavity. An anode lead-out part and a cathode lead-out part are provided at two ends of the accommodating cavity, respectively. The electroplated positive terminal and the first electroplated negative terminal are provided on outer side surfaces of two ends of the casing, respectively. The second electroplated negative terminal is provided on an outer bottom surface of the casing, and is electrically connected to the multilayer core.

Abstract: An adhesive composition is provided. The adhesive composition includes an organic silicon polymer, a silicon coupling agent, carboxylic polyester, and a solvent. Based on the total weight of the adhesive composition, the content of the organic silicon polymer is 10 wt % to 60 wt %, the content of the silicon coupling agent is 10 wt % to 60 wt %, and the content of the carboxylic polyester is 10 wt % to 60 wt %.

Abstract: A cover film with high dimensional stability includes an insulation film, a first adhesive layer, and a carrier. A first side of the first adhesive layer is connected to a first surface of the insulation film, and a second side of the first adhesive layer is configured to adhere to at least one metal conductor of a flexible printed circuit board. The carrier includes a supporting film and a second adhesive layer. A first side of the second adhesive layer is connected to the supporting film, and a second side of the second adhesive layer is adhered to a second surface of the insulation film, wherein bonding strength of the second adhesive film is smaller than bonding strength of the first adhesive film.

Abstract: A novel method to increase volumetric hydrogen storage capacity for Pt/AC materials, which comprises a material providing step, an acid washing step, a glucose mixing step, a pellet pressing step combining liquefaction and carbonization, a impurity removing step, a mixed solution introducing step, and a washing and filtering step to provide a method for high quality hydrogen storage material production by supporting platinum on active carbon.

Abstract: This invention provides a dynamic hydrogen-storage apparatus and the method thereof, which includes the following steps: (a) filling a container with a porous hydrogen-storage material which is loaded or doped with a catalyst; (b) setting an operational pressure and a pressure drop for the operation of storing hydrogen; (c) providing the hydrogen-storage material with a hydrogen so as to increase the pressure of the hydrogen to the operational pressure; (d) decreasing the pressure of the hydrogen by the pressure drop; and (e) repeating steps (c) and (d) for a predetermined amount of times.

Abstract: A novel method to increase volumetric hydrogen storage capacity for Pt/AC materials, which comprising a providing material step, an acid washing step, a glucose mixing step, a pellet pressing step combining liquefaction and carbonization, a removing impurity step, a introducing mixed solution step, and a washing and filtering step to provide a method for high quality hydrogen storage material production by supporting platinum on active carbon.

Abstract: This invention provides a dynamic hydrogen-storage apparatus and the method thereof, which includes the following steps: (a) filling a container with a porous hydrogen-storage material which is loaded or doped with a catalyst; (b) setting an operational pressure and a pressure drop for the operation of storing hydrogen; (c) providing the hydrogen-storage material with a hydrogen so as to increase the pressure of the hydrogen to the operational pressure; (d) decreasing the pressure of the hydrogen by the pressure drop; and (e) repeating steps (c) and (d) for a predetermined amount of times.

Abstract: A method of forming a hydrogen storage structure is disclosed, which comprises: providing a porous material formed by micropores and nanochannels, wherein said micropores have a size less than 2 nm and a volumetric ratio larger than 0.2 cm3/g, said nanochannels have a width less than 2.5 nm, and fractal networks formed by said nanochannels have a fractal dimension closed to 3; to form an oxidized porous material by oxidation of said porous material and to properly increase and tailor sizes of said micropores and nanochannels; and forming metal particles of diameters less than 2 nm in said micropores and said nanochannels of said oxidized porous material. By the method according to the present invention, it is capable of constructing a hydrogen storage structure with room-temperature hydrogen storage capability of almost 6 wt %, which satisfies the on-board target criteria of DOE in America by 2010.

Abstract: The present invention provides a method for constructing a fractal network structure in hydrogen storage material to improve the hydrogen uptake at room temperature, the method including the following steps: providing a hydrogen storage material comprising a source and a receptor of hydrogen atoms, wherein the source is disposed above the receptor, and a chemical bridge is disposed between the source and the receptor, wherein the chemical bridge is composed of precursor material; and treating the hydrogen storage material to construct a fractal network structure of mesopores and micropores in the receptor, so as to enhance the hydrogen storage capacity of the hydrogen storage material at room temperature.

Abstract: The present invention provides a high capacity hydrogen storage material in which a plural mesopore channels and fractal networks of nanopore channels communicating therewith and connecting to the micropores are formed in a microporous material, wherein a plural metal particles are formed on the surface of the mesopore and nanopore channels and of the micropores. In another embodiment, the present invention also provides a method for making the hydrogen storage material through oxidizing the microporous material so as to form a plural mesopore channels and fractal networks of nanopore channels, both of which are connected to the micropores to form a base for the deposition of metal particles capable of decomposing hydrogen molecules into hydrogen atoms. The high capacity hydrogen storage material is capable of increasing the capacity of hydrogen storage, and besides, the oxidizing process for making the hydrogen storage material is simple and has merits of saving cost.

Abstract: An apparatus is disclosed for containing metal-organic frameworks for storing hydrogen for use in a fuel cell. The apparatus includes a cartridge for containing the metal-organic frameworks, a filter connected to the cartridge for filtering out powder of the metal-organic frameworks during the release of the hydrogen, a ball valve connected to the filter for controlling the travel of the hydrogen, a pressure regulator connected to the ball valve for regulating the pressure of the hydrogen, a flow controller connected to the pressure regulator for controlling the flow rate of the hydrogen and a pipe connected to the flow controller on one hand and connected to the fuel cell on the other hand for providing the hydrogen to the fuel cell. The flow controller includes a flow meter for showing the flow rate of the hydrogen and a needle valve operable for changing the flow rate of the hydrogen.

Abstract: The present invention provides a high capacity hydrogen storage material in which a plural mesopore channels and fractal networks of nanopore channels communicating therewith and connecting to the micropores are formed in a microporous material, wherein a plural metal particles are formed on the surface of the mesopore and nanopore channels and of the micropores. In another embodiment, the present invention also provides a method for making the hydrogen storage material through oxidizing the microporous material so as to form a plural mesopore channels and fractal networks of nanopore channels, both of which are connected to the micropores to form a base for the deposition of metal particles capable of decomposing hydrogen molecules into hydrogen atoms. The high capacity hydrogen storage material is capable of increasing the capacity of hydrogen storage, and besides, the oxidizing process for making the hydrogen storage material is simple and has merits of saving cost.

Abstract: A collaboration commerce method, which, with customers not knowing the whole collaboration commerce operation procedure, lowers the operation and executive costs among different supplier to achieve the optimal gains of collaboration commerce. The method comprises the steps of: a customer ordering a commodity through a web page; transmitting the commodity ordering information to a collaboration server; transmitting the commodity ordering information further to a plurality of enterprise resource planning servers; executing the integrated operation step of the plurality of enterprise resource planning server to generate a customized table list; sending the customized table list back to the customer for confirmation.

Abstract: A collaboration commerce method, which, with customers not knowing the whole collaboration commerce operation procedure, lowers the operation and executive costs among different supplier to achieve the optimal gains of collaboration commerce. The method comprises the steps of: a customer ordering a commodity through a web page; transmitting the commodity ordering information to a collaboration server; transmitting the commodity ordering information further to a plurality of enterprise resource planning servers; executing the integrated operation step of the plurality of enterprise resource planning server to generate a customized table list; sending the customized table list back to the customer for confirmation.