Provided are a cable securing clamp and a data transmission device. The cable securing clamp includes a clamp body and a snap member. The clamp body is provided with a first through hole, a side wall of the clamp body is provided with a second through hole communicating with the first through hole, and the first through hole is configured to allow a cable to pass through. A first end of the snap member is pivotally connected to the clamp body, a second end of the snap member is in interference fit with the second through hole, a surface of the second end of the snap member is provided with a tooth structure, and the tooth structure is configured to snap the cable in the first through hole such that the cable is secured in an extending direction of the first through hole.

Provided is a cable holding member which includes: an insulated main body; a through-hole; a bend portion; and a cover portion, in which the through-hole is configured to allow a cable to be inserted therethrough from one end side toward the other side of the main body, the cover portion is configured in such a manner as to be bendable relative to the main body along the bend portion, and at least a part of the cover portion is configured to, upon the cover portion being bent relative to the main body, be capable of covering a plane intersecting with a direction where the cable is inserted, at an opening end face of an opening portion of the through-hole, the opening end face being located on the other end side, or a vicinity thereof.

The present invention provides a contact with low impedance even in a high frequency band. The contact (1) includes a base part (3), a contact part (5), and a spring part (7). The spring part (7) is elastically deformed to bias the contact part (5) in the x-axis positive direction and the z-axis positive direction. The contact part (5) includes a sliding part (23A) oriented in the x-axis positive direction. The base part (3) includes a part to be slided (14) oriented in the x-axis negative direction. The contact part (5) is biased in the x-axis positive direction by the spring part (7), so that the sliding part (23A) is in pressure contact with the part to be slided (14). The contact part (5) is configured to be slidable in the z-axis direction relative to the base part (3) while maintaining a state in which the sliding part (23A) is in pressure contact with the part to be slided (14).

A connecting terminal (A, B) comprising: a housing (1) comprising a conductor inlet opening (8) configured to receive a conductor (9) to be clamped, the housing (1) comprising a conductor clamping region extending from the conductor inlet opening (8) in an insertion direction of the conductor (9) to be clamped; a current rail (3) disposed in the housing (1) and forming at least a first boundary of the conductor clamping region; and a spring clamp (4) disposed in the housing (1) and configured to exert a clamping force towards the first boundary of the conductor clamping region shall provides a more reliable operation over an extended period of time, in particular with maximum size conductors. To that end, the current rail (3) comprises a first extension (27) forming a second boundary of the conductor clamping region.

A conductor connection terminal with at least one spring-loaded clamping connection for connecting an electrical conductor, wherein the conductor connection terminal has at least one housing with a conductor insertion opening for inserting the electrical conductor to be connected, a busbar, a clamping spring with a clamping arm for clamping the electrical conductor to the busbar in a contact area on the busbar, and a pivotable actuation element for actuating the clamping spring, wherein the actuation element has at least one actuation handle for a manual actuation and at least one bearing plate which is connected to the actuation handle and via which the actuation element is rotatably mounted on at least one component of the conductor connection terminal, wherein the actuation handle is accessible from the outside on an actuation side of the housing.

An electrical connector comprises an insulating body, a pair of first terminal members, a pair of second terminal members, and a fastening part. The insulating body comprises a mating groove. The pair of first terminal members is disposed in the mating groove. Each of the first terminal members comprises a plurality of first elastic contacting parts. The pair of second terminal members is disposed in the mating groove. The pair of first terminal members is disposed between the pair of second terminal members. Each of the second terminal members comprises a plurality of second elastic contacting parts. The second elastic contacting part abuts against the first elastic contacting portion correspondingly. The fastening part fastens the pair of first terminal members and the pair of second terminal members.

Systems and method are described for a terminal block that can include an insulating block that is composed of an electrically insulating material. The insulating structure can have a first via extending between a first and second opening in the insulating block. A second via can extend between a third and fourth opening in the insulating block. A distance between the first and second openings may be less than a distance between the third and fourth openings. A first electrical conducting element can extend between the first and second openings. A second electrical conducting element can extend between the third and fourth openings. The first and second electrical conducting elements can be separated from one another by a portion of the insulating block.

Systems and method are described for a terminal block that can include an insulating block that is composed of an electrically insulating material. The insulating structure can have a first via extending between a first and second opening in the insulating block. A second via can extend between a third and fourth opening in the insulating block. A distance between the first and second openings may be less than a distance between the third and fourth openings. A first electrical conducting element can extend between the first and second openings. A second electrical conducting element can extend between the third and fourth openings. The first and second electrical conducting elements can be separated from one another by a portion of the insulating block.

A modular communications plug is disclosed having a simplified design that allows for more efficient termination of a cable into the plug. The plug includes modular components that are applicable to different applications.

Provided is a technique of reliably easily making connection even in a case where the thickness of a cable is changed in an electric connector for a shield-equipped multicore cable. The electric connector includes a tubular conductive shell 30, covers 40 and 50 provided outside the shell 30 to cover at least part of the shell 30, and a movable cover 60 coupled to the cover 50 through a rotary shaft 63. The cover 40 has locking pieces 41 on a cable side. The movable cover 60 has locking pieces 61 to be engaged with the locking pieces 41. At least one of the locking piece 41 or the locking piece 61 includes multiple locking pieces arranged along a circumferential direction of a circle about the rotary shaft 63. The locking pieces 41 and the locking pieces 61 form a ratchet mechanism, and have such a structure that the locking pieces 41 and the locking pieces 61 are movable in an approaching direction and movement in a direction in which the locking pieces 41 and the locking pieces 61 are separated from each other is restricted.