A connector for device that is downsized is provided. The connector for device is configured to be attached to a device housing including a hole and configured to hold an electric wire inserted into the hole, and the connector for device includes a tube-shaped housing into which the electric wire is inserted and which is configured to be inserted into one end of the hole of the device housing, and a front holder configured to be engaged with one end of the tube-shaped housing, wherein the front holder includes an electric wire holding portion to which the electric wire is held, and a locking portion that is continuous with the electric wire holding portion and configured to be engaged with the tube-shaped housing, and wherein the electric wire holding portion is positioned inside the tube-shaped housing in a state where the locking portion is engaged with the tube-shaped housing.

A connector for device that is downsized is provided. The connector for device is configured to be attached to a device housing including a hole and configured to hold an electric wire inserted into the hole, and the connector for device includes a tube-shaped housing into which the electric wire is inserted and which is configured to be inserted into one end of the hole of the device housing, and a front holder configured to be engaged with one end of the tube-shaped housing, wherein the front holder includes an electric wire holding portion to which the electric wire is held, and a locking portion that is continuous with the electric wire holding portion and configured to be engaged with the tube-shaped housing, and wherein the electric wire holding portion is positioned inside the tube-shaped housing in a state where the locking portion is engaged with the tube-shaped housing.

A cable-gland system provides a sealing function to openings in an electronic chassis that receive cables. The cable-gland system comprises a plurality of individual cable glands. Each of the plurality of individual cable glands includes an exterior end to be positioned adjacent an exterior of the chassis, and an interior end for positioning within the chassis. Each of the plurality of individual cable glands includes a through-hole extending between the exterior and interior ends for receiving one of the cables, and an outer surface between the exterior and interior ends. Each of the plurality of individual cable glands has a male projection on one side of the outer surface and a female recess on an opposing side of the outer surface. The cable glands are connectable to form the cable-gland system by mating the male projection on one cable gland with the female recess of an adjacent cable gland.

A cable-gland system provides a sealing function to openings in an electronic chassis that receive cables. The cable-gland system comprises a plurality of individual cable glands. Each of the plurality of individual cable glands includes an exterior end to be positioned adjacent an exterior of the chassis, and an interior end for positioning within the chassis. Each of the plurality of individual cable glands includes a through-hole extending between the exterior and interior ends for receiving one of the cables, and an outer surface between the exterior and interior ends. Each of the plurality of individual cable glands has a male projection on one side of the outer surface and a female recess on an opposing side of the outer surface. The cable glands are connectable to form the cable-gland system by mating the male projection on one cable gland with the female recess of an adjacent cable gland.

An apparatus for use with a cable, wherein the apparatus comprises a conduit and a stopper, wherein the stopper is formed in one or more parts from a plastic; the stopper comprises an internal hole which is configured to accommodate a cable and the stopper has an outer surface of which at least a part conforms to the geometry of one end of the conduit; the geometry of the one end of the conduit is flared and accommodates the shape of the stopper; and the conduit is configured to accommodate the cable.

An apparatus for use with a cable, wherein the apparatus comprises a conduit and a stopper, wherein the stopper is formed in one or more parts from a plastic; the stopper comprises an internal hole which is configured to accommodate a cable and the stopper has an outer surface of which at least a part conforms to the geometry of one end of the conduit; the geometry of the one end of the conduit is flared and accommodates the shape of the stopper; and the conduit is configured to accommodate the cable.

The method of manufacturing the insulation member includes manufacturing a 3D printing material using a mixed material in which one or more materials selected from among polycarbonate (PC), polybutylene terephthalate (PBT), acrylonitrile-butadiene-styrene (ABS), polyamide (PA), polyoxymethylene (POM), and polyethylene terephthalate (PET), one or more fillers selected from among TiO2, SiO2, and AlO3, and a curing agent are mixed, and which contains different amounts of the fillers at predetermined intervals in a longitudinal direction, and sequentially stacking the manufactured 3D printing material using a 3D printer to thus manufacture a target insulation member so that the mixed material containing different amounts of the fillers at predetermined intervals in a longitudinal direction of the insulation member is sequentially stacked.

The method of manufacturing the insulation member includes manufacturing a 3D printing material using a mixed material in which one or more materials selected from among polycarbonate (PC), polybutylene terephthalate (PBT), acrylonitrile-butadiene-styrene (ABS), polyamide (PA), polyoxymethylene (POM), and polyethylene terephthalate (PET), one or more fillers selected from among TiO2, SiO2, and AlO3, and a curing agent are mixed, and which contains different amounts of the fillers at predetermined intervals in a longitudinal direction, and sequentially stacking the manufactured 3D printing material using a 3D printer to thus manufacture a target insulation member so that the mixed material containing different amounts of the fillers at predetermined intervals in a longitudinal direction of the insulation member is sequentially stacked.

This anisotropic conductive sheet has an insulation layer, a plurality of conduction paths, and a plurality of adhesion layers disposed therebetween. The adhesion layers each contain a silane coupling agent composition containing a silane coupling agent having a vinyl group and a hydrolyzable group, or a polycondensate of said composition. In the anisotropic conductive sheet: a) the insulation layer contains an addition crosslinked product of a silicone rubber composition containing an organopolysiloxane having a SiH group, and the vinyl groups of the adhesion layers is bound to the SiH group of the insulation layer through an addition reaction; or b) the insulation layer contains an organic peroxide crosslinked product of a silicone rubber composition containing an organopolysiloxane having a SiCH.sub.3 group, the vinyl groups of the adhesion layers is bound to the SiCH.sub.3 group of the insulation layer through a radical addition reaction.

This anisotropic conductive sheet has an insulation layer, a plurality of conduction paths, and a plurality of adhesion layers disposed therebetween. The adhesion layers each contain a silane coupling agent composition containing a silane coupling agent having a vinyl group and a hydrolyzable group, or a polycondensate of said composition. In the anisotropic conductive sheet: a) the insulation layer contains an addition crosslinked product of a silicone rubber composition containing an organopolysiloxane having a SiH group, and the vinyl groups of the adhesion layers is bound to the SiH group of the insulation layer through an addition reaction; or b) the insulation layer contains an organic peroxide crosslinked product of a silicone rubber composition containing an organopolysiloxane having a SiCH.sub.3 group, the vinyl groups of the adhesion layers is bound to the SiCH.sub.3 group of the insulation layer through a radical addition reaction.