A coaxial cable connector for attachment to an end of a coaxial cable is disclosed. The coaxial cable connector includes a rotatable body segment having a body wall with an outer surface and an inner surface defining a width of the body wall. The body wall has a radial dimension which varies along a perimeter of the rotatable body segment. The inner surface defines a longitudinal opening extending between a forward end of the rotatable body segment and a rearward end of the rotatable body segment. A post positions proximal the forward end of the rotatable body segment. The post has a first end and a second end with a bore extending therebetween. The post is rotationally stationary with respect to the rotatable body segment. A coupling member positions proximal to the first end of the post. The rotatable body segment is rotated to close the coaxial cable connector.

A cable gland having a first cable gland portion and a second cable gland portion in engagement with each other is disclosed. The cable gland comprises earthing members (60) in electrical engagement with the first and second gland portions, each earthing member including a spike (68) for penetrating through a sheath layer of an electrical cable, following radially inward movement of the spike, thereby forming an electrical earth connection with a conducting portion of a cable. The first gland portion comprises a first cam surface and the second gland portion comprises a second cam surface, wherein the first and second cam surfaces are adapted to engage respective earthing member cam surfaces (72, 74) of the earthing member, the first and second cam surfaces thereby causing the earthing member and the corresponding spike to move radially inwards as the first and second gland portions are brought into threaded engagement with each other.

A cable gland having a first cable gland portion and a second cable gland portion in engagement with each other is disclosed. The cable gland comprises earthing members (60) in electrical engagement with the first and second gland portions, each earthing member including a spike (68) for penetrating through a sheath layer of an electrical cable, following radially inward movement of the spike, thereby forming an electrical earth connection with a conducting portion of a cable. The first gland portion comprises a first cam surface and the second gland portion comprises a second cam surface, wherein the first and second cam surfaces are adapted to engage respective earthing member cam surfaces (72, 74) of the earthing member, the first and second cam surfaces thereby causing the earthing member and the corresponding spike to move radially inwards as the first and second gland portions are brought into threaded engagement with each other.

An electrical cable connector includes a contact subassembly having a center contact, a dielectric holder, and an outer contact. The dielectric holder defines a channel that is open at a top side of the dielectric holder. The center contact has a termination region that is held in the channel. The termination region includes a first cable insulation displacement (CID) feature. The outer contact includes a second CID feature extending from a base wall of the outer contact outside of the dielectric holder. The second CID feature extends into the channel through an aperture in the dielectric holder. The first CID feature engages a core conductor of a cable and the second CID feature engages a shield layer of the cable as the cable is loaded into the channel from above the top side of the dielectric holder.

An electrical cable connector includes a contact subassembly having a center contact, a dielectric holder, and an outer contact. The dielectric holder defines a channel that is open at a top side of the dielectric holder. The center contact has a termination region that is held in the channel. The termination region includes a first cable insulation displacement (CID) feature. The outer contact includes a second CID feature extending from a base wall of the outer contact outside of the dielectric holder. The second CID feature extends into the channel through an aperture in the dielectric holder. The first CID feature engages a core conductor of a cable and the second CID feature engages a shield layer of the cable as the cable is loaded into the channel from above the top side of the dielectric holder.

A cable connector with two sets of clamping plates for applying a clamping force and reducing the impact of impedance discontinuity includes an insulating base, a housing, a signal terminal, and two ground terminals. The insulating base has a top portion concavely provided with a receiving space. The housing is mounted on the insulating base and has a through hole corresponding to the receiving space. The signal terminal and the ground terminals are set separately in a bottom portion of the insulating base, have top portions respectively configured for clamping a coaxial cable extending into the receiving space, and have bottom portions soldered respectively to a signal contact and a ground contact on a circuit board. One of the ground terminals is adjacent to the signal terminal to reduce the impact of impedance discontinuity. The other ground terminal applies an additional clamping force to the coaxial cable.

An electrical shield connector configured to be attached to an end of a shielded cable having a conductive wire and a shield conductor longitudinally surrounding the conductive wire. The shield connector includes a connection portion that is configured for connection with a corresponding mating electrical shield connector and a cable attachment portion that is configured to longitudinally receive an end of the shield conductor. The connection portion defines a shroud surrounding an electrical terminal attached to the conductive wire. The cable attachment portion and/or crimp wings projecting therefrom define a projection that is configured to contact and indent the shield conductor, thereby mechanically and electrically connecting the shield connector to the shield conductor. The cable attachment portion may also define a knurled pattern in an interior surface of the cable attachment portion, such as a knurled pattern having a number of rhomboid-shaped indentations.

An electrical shield connector configured to be attached to an end of a shielded cable having a conductive wire and a shield conductor longitudinally surrounding the conductive wire. The shield connector includes a connection portion that is configured for connection with a corresponding mating electrical shield connector and a cable attachment portion that is configured to longitudinally receive an end of the shield conductor. The connection portion defines a shroud surrounding an electrical terminal attached to the conductive wire. The cable attachment portion and/or crimp wings projecting therefrom define a projection that is configured to contact and indent the shield conductor, thereby mechanically and electrically connecting the shield connector to the shield conductor. The cable attachment portion may also define a knurled pattern in an interior surface of the cable attachment portion, such as a knurled pattern having a number of rhomboid-shaped indentations.

A coaxial connector includes a housing, and a bushing which is attached to the housing and on which the leading end of the coaxial cable is placed. In the coaxial connector, the housing includes a first circular cylinder and a crimping portion holding the bushing, the bushing is press-contacted to an insulation film by a force from the crimping portion, a socket includes a contact portion enclosed by the first circular cylinder and an attachment portion that is press-contacted to the insulation film by a force from the bushing and is connected to a second central conductor through cutting and removing part of the insulation film, and a minimum length from the center of the first circular cylinder to the crimping portion is longer than a maximum length from the center of the outer conductor to an outer edge of the receptacle.

A twinax cable assembly comprises a cable lacing section between the assembly end sections. The cable assembly includes twinax cable sets of twinax cables. Each cable includes a pair of conductors spaced apart in a lateral direction. Each of the cable sets has connector ends where each of the cables in the cable sets connects to a terminal component. A tie bar is mounted on one end and another tie bar is mounted on the other end between the lacing section and the ends of the cables. The cables in each cable set lace through the other cable sets with the pair of conductors in each of the twinax cables substantially aligned in the lateral direction such that when the cable assembly bends substantially around a bend axis in the lateral direction the pairs of conductors in each of the twinax cables remain substantially aligned in the lateral direction.