摘要:
The present invention provides a manufacturing method of a flat-panel display unit and a carrier therefor which make it unnecessary to implement alignment in each step, except for alignment which require higher precision, by performing the alignment in advance in the pre-stage of a series of steps. The present invention also provides a manufacturing method of a flat-panel display unit which allows alignment with accuracy of about 50 to 100 .mu.m to be performed simply, reliably and quickly. According to the inventive manufacturing method, a display panel is mounted non-shiftably on the carrier and while being mounted thereon, is then carried between processing machines and is processed by the processing machines. In mounting the display panel on the carrier, it is aligned with the carrier in advance by visually aligning alignment marks thereof. In processing it by the processing machine, the carrier and the processing machine are put into a predetermined state in which they are aligned and thereby, the display panel is put into a state in which it is aligned with the processing machine.
摘要:
A tape carrier package is stacked on an array substrate while interposing a thermosetting type anisotropic conductive adhesive between a plurality of first conductors formed on the end portion of the array substrate and a plurality of second conductors formed on the tape carrier package. Subsequently, a heater tool of a thermocompression bonding apparatus applies pressure and heat to the anisotropic conductive adhesive via the tape carrier package. In this case, the anisotropic conductive adhesive is slowly heated up to its hardening end temperature to harden after it softens, thereby thermocompression bonding the first and second conductors to each other by the anisotropic conductive adhesive.
摘要:
A tape carrier package is stacked on an array substrate while interposing a thermosetting type anisotropic conductive adhesive between a plurality of first conductors formed on the end portion of the array substrate and a plurality of second conductors formed on the tape carrier package. Subsequently, a heater tool of a thermocompression bonding apparatus applies pressure and heat to the anisotropic conductive adhesive via the tape carrier package. In this case, the anisotropic conductive adhesive is slowly heated up to its hardening end temperature to harden after it softens, thereby thermocompression bonding the first and second conductors to each other by the anisotropic conductive adhesive.
摘要:
A two stage jointed stationary blade of a high pressure or intermediate pressure steam turbine is formed with a bolt joint in place of a welded joint so as to make detachment and disassembly possible, and thereby facilitating maintenance and inspection work and reducing assembling man-hours. A stationary blade (front stage)(2), outer ring front portion (1) and inner ring front portion (3) are welded into an integral structure. A stationary blade (rear stage) 22, outer ring rear portion (21) and inner ring rear portion (23) are also welded into an integral structure. The outer ring front portion 1, outer ring center portion 10 and the outer ring rear portion 21 are mutually engaged via engaging portions (4, 11 and 12, 24) with precise positioning and then jointed together integrally by bolt (30). The two stage jointed stationary blade can be engaged with moving blades (33, 35), labyrinth seals (32, 34) can be fitted to seal fitting portions (6, 26), and seal fins (31, 34) can be fitted in seal fin grooves (13, 27).
摘要:
A material for use in flexible printed wiring board having high reliability and allowing for processing fine wiring includes a compound represented by the following general formula (I): wherein one of X and Y represents O and the other represents NAr2R2, and R1, R2, Ar1, and Ar2 are as defined in the specification, and a resin composition comprising the compound as a reactive monomer.
摘要翻译:用于具有高可靠性并且允许精细布线的柔性印刷线路板的材料包括由以下通式(I)表示的化合物:其中X和Y中的一个表示O,另一个表示NAr 2 R 2,并且R 1,R 2, Ar1和Ar2如说明书中所定义,以及包含该化合物作为反应性单体的树脂组合物。
摘要:
A tandem support structure for an exhaust gas purifying catalyst comprises a sleeve, a first honeycomb disposed on an upstream side of exhaust gases, and a second honeycomb disposed on a downstream side of exhaust gases at a position axially separated from the first honeycomb. The second honeycomb is fixed to the sleeve, and the first honeycomb is held by a holding member which axially extends in an upstream direction from said second honeycomb, without contacting the sleeve. Since an air layer exists between the first honeycomb and the sleeve, heat radiation from the first honeycomb is prevented and temperature rising characteristics of the first honeycomb are improved.