Provided is a process for producing an automotive glass with a member in a highly efficient and space-saving manner. The process for producing an automotive glass with a member comprises bonding together an adhesion surface of an adherend and an adhesion surface of an automotive glass using an adhesive, and then curing the adhesive using a superheated steam generator, thereby attaching the adherend to the automotive glass; wherein the superheated steam generator comprises (1) a boiler part for generating steam, (2) a superheating unit for superheating the steam generated in the boiler part, and (3) a superheated steam vessel equipped internally with one or more heaters and one or more superheated steam outlets for discharging the superheated steam supplied from the superheating unit; and wherein the step of curing the adhesive is performed by covering the adherend placed on the automotive glass with the superheated steam vessel, spraying the superheated steam from the one or more superheated steam outlets to the adherend, and then spraying dry gas.

To provide a treated polymer production method which can be performed in a simplified manner and at low cost. In order to achieve the object, the treated polymer production method according to the present invention includes: reacting a surface of a polymer with a halogen oxide radical to surface-treat the polymer. The treated polymer is a metal-plated polymer, and the method further includes plating, with a metal, the surface of the polymer after the surface-treating, or the treated polymer is an adhesion laminate of the polymer and an adherend, and the method further includes adhering the adherend to the surface of the polymer after the surface-treating.

A composite fiber web having superior heat resistance and sound absorption and including a center layer containing a carbon fiber and a heat-resistant layer, and to a method of manufacturing the same. The method of the present invention can exhibit a fast manufacturing speed through a melt-blowing process that will generate economic benefits. The composite fiber web includes a composite layer and individual layers with various fiber diameters resulting in a superior sound absorption rate. The PET fiber included in the heat-resistant layer of the composite layer is an environmentally friendly material with superior heat resistance due to the inclusion of ultrafine fiber. Also, the composite fiber web has superior strength, conductivity, and electromagnetic shielding and deodorization effects, which allows it to be widely utilized for sound absorption materials and in all application fields thereof.

To provide a surface-treated polymer production method which can be performed in a simplified manner and at low cost. In order to achieve the aforementioned object, the surface-treated polymer production method according to the present invention include: reacting a surface of a polymer with a halogen oxide radical to surface-treat the polymer, and in the surface-treating, a reaction system is not irradiated with light.

A composite fiber web having superior heat resistance and sound absorption and including a center layer containing a carbon fiber and a heat-resistant layer, and to a method of manufacturing the same. The method of the present invention can exhibit a fast manufacturing speed through a melt-blowing process that will generate economic benefits. The composite fiber web includes a composite layer and individual layers with various fiber diameters resulting in a superior sound absorption rate. The PET fiber included in the heat-resistant layer of the composite layer is an environmentally friendly material with superior heat resistance due to the inclusion of ultrafine fiber. Also, the composite fiber web has superior strength, conductivity, and electromagnetic shielding and deodorization effects, which allows it to be widely utilized for sound absorption materials and in all application fields thereof.

Provided is a process for producing an automotive glass with a member in a highly efficient and space-saving manner. The process for producing an automotive glass with a member comprises bonding together an adhesion surface of an adherend and an adhesion surface of an automotive glass using an adhesive, and then curing the adhesive using a superheated steam generator, thereby attaching the adherend to the automotive glass; wherein the superheated steam generator comprises (1) a boiler part for generating steam, (2) a superheating unit for superheating the steam generated in the boiler part, and (3) a superheated steam vessel equipped internally with one or more heaters and one or more superheated steam outlets for discharging the superheated steam supplied from the superheating unit; and wherein the step of curing the adhesive is performed by covering the adherend placed on the automotive glass with the superheated steam vessel, spraying the superheated steam from the one or more superheated steam outlets to the adherend, and then spraying dry gas.

Embodiments using immersion de-taping are described. A substrate having a substrate tape attached thereto is provided. The substrate includes electrically conductive connectors attached to the substrate tape. A fluid is provided between the substrate and the substrate tape. While the fluid is between the substrate and the substrate tape, the substrate tape is removed from the substrate. Another embodiment is an apparatus comprising an immersion tank, a substrate chuck, first and second fixed rollers, and a moveable roller. The substrate chuck is configured to secure a substrate and to place the substrate into the immersion tank. The first fixed roller is operable to dispense a clamp tape. The second fixed roller is operable to roll the clamp tape. The moveable roller is operable to extend into the immersion tank and to adhere the clamp tape to a substrate tape on the substrate.

A system and method for creating three-dimensional nanostructures is disclosed. The system includes a substrate bonded to a carrier using a bonding agent. The bonding agent may be vaporizable or sublimable. The carrier may be a glass or glass-like substance. In some embodiments, the carrier may be permeable having one or a plurality of pores through which the bonding agent may escape when converted to a gaseous state with heat, pressure, light or other methods. A substrate is bonded to the carrier using the bonding agent. The substrate is then processed to form a membrane. This processing may include grinding, polishing, etching, patterning, or other steps. The processed membrane is then aligned and affixed to a receiving substrate, or a previously deposited membrane. Once properly attached, the bonding agent is then heated, depressurized or otherwise caused to sublimate or vaporize, thereby releasing the processed membrane from the carrier.

A method for producing a semi-finished honeycomb-core product for producing a sandwich component, a method for producing a sandwich component, a semi-finished honeycomb-core product, a sandwich component, and the use thereof as a component of a motor vehicle.

Embodiments using immersion de-taping are described. A substrate having a substrate tape attached thereto is provided. The substrate includes electrically conductive connectors attached to the substrate tape. A fluid is provided between the substrate and the substrate tape. While the fluid is between the substrate and the substrate tape, the substrate tape is removed from the substrate. Another embodiment is an apparatus comprising an immersion tank, a substrate chuck, first and second fixed rollers, and a moveable roller. The substrate chuck is configured to secure a substrate and to place the substrate into the immersion tank. The first fixed roller is operable to dispense a clamp tape. The second fixed roller is operable to roll the clamp tape. The moveable roller is operable to extend into the immersion tank and to adhere the clamp tape to a substrate tape on the substrate.