There is provided a contact structure, comprising a substrate contact including a first contact portion that is located on a leading end side of the substrate contact and that comes into contact with a substrate and a second contact portion that is located nearer to a base end side of the substrate contact than the first contact portion; a seal member configured to cover a periphery of the substrate contact and to have a sealing surface that comes into contact with the substrate to seal the substrate contact; a first pressing portion configured to elastically apply a contact pressure on the substrate to the substrate contact; and a second pressing portion configured to come into contact with the seal member and to apply a contact pressure on the substrate to the seal member independently of the first pressing portion, wherein the first contact portion adheres to the seal member, and the second contact portion is fit in the seal member to be displaceable relative to the seal member.

It is aimed to enable a short circuit in a retainer insertion hole to be avoided. Short-circuit preventing walls (18) configured to partition between cavities (11) adjacent in an arrangement direction are provided in a retainer insertion hole (15). A retainer (13) is provided with a plurality of frame-like portions (20) along the arrangement direction of the respective cavities (11). Each frame-like portion (20) is formed to be able to communicate with the corresponding cavity (11). Escaping grooves (32) are formed along a mounting direction of the retainer (13) between the frame-like portions (20) adjacent in the arrangement direction. Escaping grooves (32) are open on front end parts in the mounting direction of the retainer (13) such that the retainer (13) is mountable into the retainer insertion hole (15) while avoiding interference with the short circuit preventing walls (18).

A terminal connector or two-part connector comprising male and female parts having respective contact pins and contact receivers (10,15) of a construction generally known in the art. In the body (1) of the or at least one part, closely juxtaposed a terminal block (9), there is provided a conductor management device (8) adapted to receive conductors (12) as they are unbundled from the connected cable or reel and support the unbundled or individual conductors through the transitional region of the connector part to where they are secured at the terminal block (9). The conductor management device (8) has through body apertures defining each conductor path (14) to align each conductor with its respective receiver (13). In a different configuration, the conductor management device provides strain relief to the conductors, provides support and conductor rigidity, provides a locking means and is a bore modifier.

A method for sealing a plug pin in a housing. The housing has at least one cutout for sealing a region between plug pin and the housing. The method includes: providing the housing having the plug pin, the plug pin contacting the housing in two edge regions of the plug pin situated opposite one another and running along a direction of insertion, and forming in the edge regions a positive-fit connection with the housing; introducing casting compound into the at least one cutout in such a way that the casting compound reaches two oppositely situated sides of the plug pin, and the casting compound seals the region between the plug pin and the housing in fluid-tight fashion, and the casting compound does not come into contact with the two ends of the plug pin situated opposite one another along the direction of insertion; and curing of the casting compound.

A grommet for use in a cable fitting includes a body having a bore substantially therethrough and a resilient membrane located within the bore. The resilient membrane is elastically deformable from a receiving position before the cable is inserted into the bore, to an inserted position, after the cable is fully inserted into the bore. In the receiving position, the resilient membrane is substantially conically shaped having an apex substantially coincident with an insertion opening of the body, and, the resilient membrane is axially displaced during the insertion of the cable to an inverted position with respect to the receiving position where the apex is oriented away from the insertion opening. The resilient membrane has a thinner membrane portion extending from the apex towards the bore to provide a controlled tear during cable insertion. The body has an exit opening which comprises resilient gripping teeth projecting axially from the body with an axially extending resilient foldable membrane located between at least two adjacent resilient teeth and foldable therebetween when they are radially compressed. Once force is applied by the axial movement of the fitting assembly onto a tapered surface of the grommet, the flexible gripping members radially collapse towards an inserted cable. The combination of the resilient membrane and the axially extending teeth separated by a foldable membrane allow for an increased friction fit and sealing interface on the cable. The grommet may be assembled in a strain relief connector having a nut, a connector body and optionally an insert. The insert has a removed section longitudinally coincident with a gripping surface facilitating movement of the gripping surface towards the cable.

Included are terminal metal parts, a housing provided with a fitting part housing the terminal metal parts thereinside and to be inserted and fit into a counterpart fitting part having an inner circumferential wall face, a front holder causing the fitting part to be inserted along an insertion direction of the fitting part to the counterpart fitting part, and a ring-shaped water stop member having an inner circumferential face side mounted on a protruding portion of an outer circumferential wall face of the fitting part from the front holder to fill a ring-shaped gap between the protruding portion of the outer circumferential wall face and the inner circumferential wall face of the counterpart fitting part.

A connector production method includes the steps of holding a flat plate conductor with a first insulator, joining central portions of one or more contacts to the first insulator such that front end portions of the one or more contacts are exposed at a front part of the first insulator and rear end portions of the one or more contacts project from a rear part of the first insulator, placing a shell made of metal over the first insulator such that the shell covers outer peripheral portions of the one or more contacts, fixing and electrically connecting the shell to the flat plate conductor, and forming a second insulator such that the second insulator covers the rear part of the first insulator and a rear part of the shell while the rear end portions of the one or more contacts project from the second insulator.

A connector includes: a terminal fitting; a housing containing the terminal fitting inside and provided with a fitting portion inserted and fitted into inside of a hole-shaped counterpart fitting portion of a counterpart wall member; a shield shell including a cylindrical portion covering, from outside, a projecting portion of the housing, a flange portion projecting outer than an outer circumferential surface of the cylindrical portion, and a fixed portion bent from an end portion of the flange portion and fixed on an end surface of the counterpart wall member; and an annular water stop member attached to the flange portion and pressed between the flange portion and the wall surface of the counterpart wall member. The shield shell is provided with a through hole provided in a bent portion between the flange portion and the fixed portion and causing inside and outside thereof to communicate with each other.

A feedthrough for a connector system includes an insulator comprising a passage therethrough, a conductor pin located in the passage, and a pressure sleeve located between the insulator and the conductor pin. The pressure sleeve is coupled to the insulator and to the conductor pin, and the conductor pin is movable relative to the insulator under thermal or pressure expansion or contraction.

A high-voltage connector assembly and a motor-operated compressor including the same are disclosed. The high-voltage connector assembly according to embodiments disclosed herein may include a cover defining an outer appearance and a shielding plate designed to shield an electrical noise signal. The cover and the shielding plate may be integrally formed by a double shot molding or insert injection molding. Accordingly, manufacturing time and costs of the cover and the shielding plate may be reduced. In addition, the cover and the shielding plate may be coupled to each other in a more stable manner. Further an outer circumferential portion of the shielding plate may have a higher roughness than the cover. Alternatively, the outer circumferential portion of the shielding plate may be provided with a plate protrusion or an uneven portion. Accordingly, a contact area between the shielding plate and the cover may be increased.