摘要:
An electrostatic discharge (ESD) protector includes a first high heat-conductive substrate, a second high heat-conductive substrate, a varistor layer, and a plurality of via-hole electrodes. The first high heat-conductive substrate is provided with a plurality of first through-holes. The second high heat-conductive substrate is provided with a plurality of second through-holes. The varistor layer that is mainly composed of zinc oxide is disposed between the first high heat-conductive substrate and the second high heat-conductive substrate. The varistor layer includes internal electrodes. Each of via-hole electrodes penetrates the varistor layer and fills both one of the first through-holes and one of the second through-holes to couple both the ones to each other.
摘要:
A method of making a multi-layered ceramic substrate which includes the steps of laminating a desired number of green sheets each being made of glass ceramics containing at least an organic binder and a solvent and each having a pattern of electrodes formed thereon by the use of an electroconductive paste, to thereby provide a green sheet laminate, The electrodes on opposite surfaces or an entire surface layer of the green sheet laminate are subsequently printed with a paste comprising an inorganic component added with at least an organic binder containing a Zn composition. On each surface of the laminate printed with the paste of the Zn composition, a green sheet made of an inorganic composition incapable of being sintered at a temperature of crystallization of the glass ceramics is then laminated thereby providing a laminate plate which is subsequently fired. After the firing, both of the inorganic composition incapable of firing sintered and the Zn composition are removed from the opposite surfaces of the laminate. The paste of the Zn composition may contains a main component selected from the group consisting of Zn, ZnO, Zn(OH).sub.2, ZnAl.sub.2 O.sub.4, and ZnCO.sub.3.
摘要翻译:一种制造多层陶瓷基板的方法,其包括以下步骤:将所需数量的生坯片材层叠,所述生坯片材由至少含有有机粘合剂和溶剂的玻璃陶瓷制成,并且各自具有通过使用 导电糊,从而提供生片层压体。随后用包含添加至少含有Zn组合物的有机粘合剂的无机组分的糊料印刷相对表面上的电极或生片层压体的整个表面层。 在印有Zn组合物的糊料的层压板的每个表面上,将由玻璃陶瓷的结晶温度下不能烧结的无机组合物制成的生片层叠,从而提供随后烧制的层压板。 烧成后,从层叠体的相对面除去无法烧成的无机组合物和Zn组合物。 Zn组合物的糊剂可以含有选自Zn,ZnO,Zn(OH)2,ZnAl 2 O 4和ZnCO 3的主要成分。
摘要:
A touch panel and a method of producing the touch panel are provided in which a touch panel having a gap between two transparent substrates that is uniform in a plane can stably be obtained by setting a gap between the two transparent substrates in an area where a wiring substrate is disposed to a desired gap. A touch panel includes a pair of transparent substrates opposed to and away from each other and connection terminals provided on at least one of opposed surfaces of the pair of transparent substrates. A wiring substrate that is disposed between the pair of transparent substrates and has one surface electrically connected to the connection terminals and the other surface disposed away from one of the transparent substrates opposed to the other transparent substrate on which the connection terminals are provided. An insulating layer provided in a gap between the pair of transparent substrates in an area where the wiring substrate is disposed in a state where the wiring substrate and the connection terminals are connected.
摘要:
An electric power generation cell 1 is constituted by arranging a fuel electrode layer 4 on one side of a solid electrolyte layer 3 and an air electrode layer 2 on the other side of the solid electrolyte layer 3. The solid electrolyte layer 3 is constituted of an oxide ion conductor mainly composed of a lanthanum gallate based oxide. The fuel electrode layer 4 is constituted of a porous sintered compact having a highly dispersed network structure in which a skeletal structure formed of a consecutive array of metal grains is surrounded by mixed conductive oxide grains. For the air electrode layer 2, a porous sintered compact mainly composed of cobaltite is used. This configuration reduces the overpotentials of the respective electrodes and the IR loss of the solid electrolyte layer 3, and accordingly can actualize a solid oxide type fuel cell excellent in electric power generation efficiency.
摘要:
An object is to provide a process for producing a carbon nanotube (CNT) reinforced composite material, wherein CNT is homogeneously dispersed in a resin to obtain the composite material having an excellent mechanical strength. Hydrophilic CNTs 12 are dispersed in a first solvent 11 to prepare a first dispersion liquid 13. The dispersion liquid 13 and a synthetic resin raw material 15 are added to a second solvent 14 and the resulting mixture is stirred to prepare a third dispersion liquid 17 where a second dispersion liquid 16 in which the synthetic resin raw material 15 is dissolved in the dispersion liquid 13 is dispersed in the solvent 14. The solvents 11 and 14 are removed from the dispersion liquid 17 to obtain a mixture of the hydrophilic CNTs 12 and the synthetic resin raw material 15. The mixture is molded to obtain the composite material in which the synthetic resin is reinforced with the hydrophilic CNTs 12. The second solvent 14 has smaller solubility of the synthetic resin raw material 15 than that of the solvent 11, is substantially not compatible to the solvent 11, and has volume larger than that of the solvent 11. The dispersion liquid 17 is sprayed on a substrate and the solvents 11 and 14 are removed to obtain the mixture and simultaneously to conduct molding of the mixture.
摘要:
The conductive particles can be sintered without being influenced by softening and removing of the adhesive layer. As a result, a wiring pattern of high precision can be formed without causing deformation of conductive pattern. It includes a step of filling grooves having a wiring pattern on a film with a conductive paste containing conductive component and resins, a step of adhering the conductive paste side surface of the film having the conductive paste to the adhesive layer side surface of the ceramic substrate having the adhesive layer, a step of forming a conductive pattern on the adhesive layer surface by peeling off the film substrate from a first laminated body having the film, conductive paste, adhesive layer, ceramic substrate, and film, and transferring the conductive paste filling up the grooves onto the surface of the adhesive layer, and a step of firing a second laminated body having the ceramic substrate, adhesive layer and conductive pattern, removing the adhesive layer, and sintering the conductive particles, in which the conductive component in the conductive paste is sintered at least (i) after the adhesive layer is softened, or (ii) after the adhesive layer is burnt.
摘要:
A ceramic substrate 1 made of magnetic substance on which an inductor 2 is formed is prepared. A ceramic substrate 3 made of dielectric substance on which a capacitor 4 is formed is also prepared. An intermediate layer 5 made of lass paste is printed on the inductor 2 and the capacitor 4. After debinding the substrates 1 and 3 independently, both the substrates are filed with the intermediate layer 5 therebetween so that both the substrates may be glued and integrated. As such, because the debinding process is provided before filing, less gas is generated in firing, and as a result, voids are restrained from occurring.
摘要:
A conductive paste includes inorganic material powders containing conductive powders and glass powders, an organic vehicle containing an organic binder and an organic solvent, and a metal organic compound.
摘要:
Conductive paste for via connection of a multilayer ceramic substrate, comprising: an inorganic component which consists of 30.0 to 70.0% by weight of powder of conductive material and the remainder being one of glass powder having a softening point higher than a starting point of sintering of insulating material and crystalline glass ceramic powder having a glass transition point higher than the starting point of sintering of the insulating material; and an organics vehicle component which consists of at least organic binder and solvent.
摘要:
Conductive ink has an inorganic compound comprising 70.0-95.0 wt. % of CuO which is conductive and 5.0-30.0 wt. % of inorganic binder mixed with each other, and solvent and organic binder in which the inorganic compound is dispersed. The inorganic binder consists of lead borosilicate crystalline glass or aluminum borosilicate crystalline glass soften and crystallizes at 850.degree.-950.degree. C. The diameter of CuO powder of the inorganic compound is 100-7.0 .mu.m. The diameter of the lead borosilicate crystalline glass powder or the aluminum borosilicate crystalline glass powder of the inorganic compound is 1.0-5.0 .mu.m. The organic binder consists of ethyl cellulose or copolymer of polyisobytylmethacrylate and poly.alpha.-methylstyrene. The conductive ink contains the organic binder at 0.5-2.0 wt. %.