The present invention pertains to a coating composition for the coating of a substrate such as a mirror or a glass. The invention is characterized in that the coating composition comprises a polyalkylsiloxane with terminal hydroxyl groups or a mixture of different polyalkylsiloxanes with terminal hydroxyl groups, silicon tetrahalide or alkyl halogen silane or mixtures thereof, and an inert aprotic.

A conductive laminate includes a first organic film, a fine metal wire arranged on the first organic film, and a second organic film arranged to cover the fine metal wire, in which the fine metal wire includes a blackening layer, an intimate attachment layer, and a metal conductive layer in order from a side of the first organic film, and moisture contents of the first organic film and the second organic film are less than 3.00%.

A system for automatically dispensing a fluid from a deformable container onto a panel includes a primer head having a container receiver and a container deformer, the container receiver receiving and holding a container of primer thereat. An adapter is received into an opening of the container and is secured to a portion of the primer head, and the container is retained at the container receiver of the primer head. A primer tip is disposed at the adapter. With the container held at the container receiver and retained at the primer head, the primer head moves to position the primer tip at the panel. When the primer tip is positioned at the panel, the container deformer automatically operates to deform the container to cause a predetermined amount of primer to be dispensed from the container, through the adapter and to the primer tip and onto the panel.

Disclosed is a process for producing a film-coated substrate having a relatively flat distribution of film thickness such that the film thickness is suppressed from s gradually increasing toward a downstream side of flow of a coating liquid even when a coating film is formed on a plate-shaped substrate by a flow coating method in which the substrate is held in raised attitude. The film-coated substrate according to the present invention is employed in particular as an openable/closable window glass of an automotive door, and is suitable for one where the substrate includes an uncoated region where no coating film is formed, wherein the uncoated region is configured to be received in a receiving part of an upper frame of the door.

In the case of a structural glass element with a plastic-coated glass panel and at least one assembly element attached hereon, the glass panel is coated in particular with a silicone-based elastomer across its entire surface, and the coating at the same time creates an adhesive joint with one section of the assembly element supported on the glass panel.

A polymer brush includes a substrate material, a polymerization initiator layer containing a hydrolysis and condensation polymerization polymer comprising a first organosilane and a metal alkoxide on a surface of said substrate material, and polymer chains extending from a surface of the polymerization initiator layer. The first organosilane is a polymerization initiator group-containing organosilane having the following formula (I): XR.sup.1-Ph-(R.sup.2).sub.mSiR.sup.3.sub.nR.sup.4.sub.3-n . . . (I) where X stands for a halogen atom, R.sup.1 stands for an alkylene group having 1 to 3 carbon atoms, Ph stands for a phenylene group, R.sup.2 stands for a C1 to C10 alkylene group optionally via an oxygen atom, R.sup.3 stands for an alkoxy group having 1 to 3 carbon atoms or chloro group, R.sup.4 stands for an alkyl group having 1 to 6 carbon atoms, m is 0 or 1, n is 1, 2 or 3.

A light-transmitting structure is disclosed. The light-transmitting structure includes a glass-based substrate that has a first major surface and a second major surface opposite the first major surface. The glass-based substrate comprises a first composition that is transparent and has a first refractive index n.sub.1. The light-transmitting structure further includes a plurality of surface regions fused with the glass-based substrate to define a light-scattering surface interposed with the first major surface. Each surface region comprises a second composition that is transparent and has a second refractive index n.sub.2 that is different than the first refractive index n.sub.1. The first major surface and the light-scattering surface define an interface to an ambient environment.

A glass container and related methods of manufacturing a glass container. A solution having a composition including a silane, a solvent, a catalyst, and water, is applied to an exterior glass surface of the glass container, at an application temperature between 5 and 40 degrees Celsius, such that the solution at least partially fills the surface imperfections to provide a room-temperature-curable cold-end coating on the glass container. Then, the applied solution is allowed to cure on the exterior glass surface of the glass container, at a curing temperature between 5 and 40 degrees Celsius.

A process for producing a sintered lithium disilicate glass ceramic dental restoration by way of sintering under reduced atmospheric pressure conditions at a temperature above 600 C. is described. Further described is a kit of parts for producing a sintered lithium disilicate glass ceramic dental restoration.

In the case of a structural glass element with a plastic-coated glass panel and at least one assembly element attached hereon, the glass panel is coated in particular with a silicone-based elastomer across its entire surface, and the coating at the same time creates an adhesive joint with one section of the assembly element supported on the glass panel.