This invention provides methods for processing of platinum metallized high temperature co-fired ceramic (HTCC) components with minimum deleterious reaction between platinum and the glass constituents of the ceramic-glass body. The process comprises co-firing a multilayer laminate green ceramic-glass body with via structures filled with a platinum powder-based material in a reducing atmosphere with a specified level of oxygen partial pressure. The oxygen partial pressure should be maintained above a minimum threshold value for a given temperature level.

An embodiment of the present invention relates to a bonded object or a method for manufacturing a bonded object, the bonded object having bases bonded therein while placing an adhesive layer in between, the adhesive layer being obtained from a fluororubber composition that contains at least one fluororubber selected from fluoroelastomer (FKM) and perfluoroelastomer (FFKM), and has a Mooney viscosity (ML 1+10) at 121? C., measured in accordance with ASTM D1646, of 80 to 115.

A process for producing a laminate in a coating line including the subsequent steps of: providing a metal strip; pre-heating the metal strip to a temperature of at least 100 C.; producing a laminate by adhering a first thermoplastic polymer coating layer on one major surface of the strip and a second thermoplastic polymer coating layer on the other major surface of the strip wherein the first thermoplastic polymer coating layer includes a polymer with a melting point below 200 C.; heating the laminate in a non-oxidising gas atmosphere in a post-heating step to at least the melting point of the polymer or polymers in the second polymer coating layer, and at least 220 C.; rapidly cooling or quenching the laminate to a temperature of below 50 C. Also, a polymer coated metal strip produced thereby, or a can produced therefrom.

The present invention concerns a method of producing an insulation product comprising a board of porous insulation material wrapped in a gas-impermeable foil, said method comprising the steps of providing a succession of porous insulation material boards on a first conveyor apparatus and feeding the boards on a second conveyor apparatus; providing wrapping foil and wrapping said foil to form a tube around the boards on said second conveyor apparatus, flushing the boards with an insulating gas, and sealing the wrapping foil at the ends of each board transverse to the direction of travel of the second conveyor apparatus.

Automatic separation of substrates from spacers within a substrate/spacer stack or laminate for use during a hard disk recording media fabrication process. In one example, a delamination apparatus includes a roller or brush configured to rotate while pressing against a flat surface of a substrate at one end of the laminate to peel the substrate from the laminate to expose an adjacent spacer and to then rotate against a flat surface of the spacer to peel the spacer from the laminate to expose another substrate of the laminate. The apparatus also includes a pusher bar configured to push against the opposite end of the laminate to push the laminate against the roller. The pusher bar may be offset from a central longitudinal axis of the laminate. A bath may be provided for submerging the laminate, the pusher, and the roller in a lubricating liquid. Method embodiments are also described.

The automobile decorative-part (1) comprises a resin-compact (3) having a decorative-layer (2) on its surface-layer and comprises a clear-coat layer (4) for protecting said surface-layer, and that a high-gloss region (R1) of a relatively high-gloss level is mixed with a low-gloss region (R2) of a relatively low-gloss level on the surface of said decorative-part, and that a clear-coat paint is sprayed by an atomization-coating machine onto the surface of the decorative-layer (2), and that the atomization-coating machine contains an ester-based solvent of a low-boiling point as the main-solvent that has a boiling-point of 100 degrees Celsius or less and has a solid-content of 35 to 40 percent by mass, thus forming the clear-coat layer (4) that makes it partially possible to mat the gloss of the surface of the clear-coat layer, thus manufacturing a decorative-part with an excellent quality design.

Automatic separation of substrates from spacers within a substrate/spacer stack or laminate for use during a hard disk recording media fabrication process. In one example, a delamination apparatus includes a roller or brush configured to rotate while pressing against a flat surface of a substrate at one end of the laminate to peel the substrate from the laminate to expose an adjacent spacer and to then rotate against a flat surface of the spacer to peel the spacer from the laminate to expose another substrate of the laminate. The apparatus also includes a pusher bar configured to push against the opposite end of the laminate to push the laminate against the roller. The pusher bar may be offset from a central longitudinal axis of the laminate. A bath may be provided for submerging the laminate, the pusher, and the roller in a lubricating liquid. Method embodiments are also described.

A separation method includes a separation step in which a treatment target electrode including a current collector and an electrode mixture is treated with an ultrasonic wave in water (a treatment liquid) while the frequency of the ultrasonic wave is swept in order to separate the current collector and the electrode mixture from each other. A separation device includes a separation unit that treats the treatment target electrode with an ultrasonic wave in water to separate the current collector and the electrode mixture from each other and a controller that controls the separation unit such that the ultrasonic treatment is performed while the frequency of the ultrasonic wave is swept.

An embodiment of the present invention relates to a bonded object or a method for manufacturing a bonded object, the bonded object having bases bonded therein while placing an adhesive layer in between, the adhesive layer being obtained from a fluororubber composition that contains at least one fluororubber selected from fluoroelastomer (FKM) and perfluoroelastomer (FFKM), and has a Mooney viscosity (ML 1+10) at 121 C., measured in accordance with ASTM D1646, of 80 to 115.