A photoelectric sensor including at least any one of a light projecting unit for emitting light and a light receiving unit for detecting light includes a substrate on which at least any one of the light projecting unit and the light receiving unit is mounted, a cover which has a protecting portion facing the substrate and for protecting the substrate and a side wall extending from a periphery of the protecting portion, and a sealing member which seals at least any one of the light projecting unit and the light receiving unit that is mounted on the substrate, in which the cover has a protruding portion on a surface which is positioned outside a side surface of the substrate and intersects an extending direction of the side wall, and the protruding portion is in contact with the sealing member.

A device for machining a cover for a motor vehicle may have a lower mold having a sealing element and a first recess and a second recess a distance from the first recess. The sealing element is arranged in part in the first recess of the lower mold so that the element extends with respect to a surface of the lower mold. The sealing element and the second recess of the lower mold are formed so as to define a cavity in a predefined manner in cooperation with a lower face of the cover. The device further may have a counter bearing which is designed, when forming the cavity on the lower face of the cover, to exert a counter force on an upper face of the cover towards the lower mold.

A passive horn integrally formed by using liquid silicone rubber, includes a first outer casing, a second outer casing, an inner casing and an iron piece. The first outer casing includes a sealing ring, a folding ring and a vibrating membrane, and the sealing ring, the folding ring and the vibrating membrane are integrally injection molded into the first outer casing. A groove is disposed in the second outer casing, and the first outer casing is disposed in the groove. The back surface of the vibrating membrane is provided with a casing groove, which is sequentially embedded with the inner casing and the iron piece. A preparation method of a passive horn integrally formed by using liquid silicone rubber, under the condition of integrated injection molding, may improve the yield rate, ensure product quality, save assembly time and labor cost, and improve production efficiency.

The purpose of this invention is to make it easy to handle all-rubber gaskets. To achieve this purpose, a gasket is characterized in that a gasket body of only rubber is combined with a carrier film that is made from a resin film to hold the gasket body in a non-adhesive state. A three-dimensional portion having a shape that is deformed along the external shape of the gasket body is provided at a position where the gasket body and a plane of the carrier film overlap, and a portion of the gasket body is contained in the three-dimensional section. The gasket body is used as a gasket for fuel cells incorporated into a fuel cell stack.

Pipe joints and more particularly circular push-on type pipe joints including a flexible gasket having both hard and soft portions and where the soft portion overlaps a flange and an inner curved section of the hard portion.

Various example embodiments relate to seaming a casing using injection moulding. The casing may be used for encapsulation of electronics. The injection moulded seam enables hermetically sealed encapsulation and use of elastomers for the casing. A casing for encapsulation and a manufacturing method for a casing is provided.

A packaging structure includes a main body adapted to be installed in an encapsulation mold and provided with an attachment surface to attach to at least part of a surface of a glass to be encapsulated, and a lip extending from the attachment surface of the main body to be suitable for sealing the surface of the glass, wherein at least a part of the packaging structure is made of flexible material.

Aspects of the present invention relate to a glazing assembly (1) for a vehicle (2). The glazing assembly (1) includes a glazing element (10), a finisher component (11) and a connector (14). The glazing element (10) has an inner surface (10A) and an outer surface (10B); the finisher component (11) has an inner surface (12A) and an outer surface (12B). A portion of the glazing element inner surface (10A) forms a first encapsulation area (A1); and a portion of the finisher component inner surface (12A) forms a second encapsulation area (A2). The finisher component (11) is connected to the glazing element (10) by the connector (14) which is composed of an encapsulation material which encapsulates the first encapsulation area (A1) and the second encapsulation area (A2). The resulting glazing assembly (1) has a substantially continuous outer surface. The present invention also relates to an encapsulated assembly (1) for an exterior of a vehicle (2). Furthermore, the present invention relates to methods of forming a glazing assembly (1); and an encapsulated assembly (1).

The camera arrangement comprises an electronics carrier, an imager connected to the electronics carrier, a lens assembly in optical communication with the image sensor along an optical axis, an outer shell, wherein the outer shell is injection-molded over and around the electronics carrier such that the electronics carrier is substantially encapsulated within the outer shell.

The object of the present invention is to effectively prevent the rust generation on a flange portion and to prevent the deformation of the flange portion due to the filling pressure of a molding material in the manufacture of a sealing device whereby a seal main body comprising a rubber-like elastic material and having a portion that covers both surfaces of the flange portion of a metal reinforcing ring is integrally formed on the reinforcing ring by means of a metal mold. To this end, the flange portion of the reinforcing ring is formed in advance with a shape which is distributed unevenly in the direction opposite the direction in which the flange portion is deformed from its original shape by the filling pressure of the molding material.