An electrical connection component includes a conductor, and a housing into which the conductor is press-fitted. The housing includes a press-fitted portion having a hollow shape and into which the conductor is press-fitted in a press-fitting direction, and a restriction portion provided at a position different from a position of the press-fitted portion, the restriction portion restricting at least a part of the conductor from being displaced in a direction different from the press-fitting direction from a time point when press-fitting of the conductor into the press-fitted portion is started to a time point when the press-fitting is completed.

A terminal block includes a lower bus bar and an upper bus bar that overlap each other at overlap portions and an insulating middle cover disposed between the overlap portion of the lower bus bar and the overlap portion of the upper bus bar. The lower bus bar and the upper bus bar are provided with their respective ones of first to fourth terminals exposed from the middle cover, at positions different from the overlap portions and the first to fourth terminals are disposed at positions radially spaced apart from the overlap portions.

A conductor connection terminal having a first insulating material housing and a second insulating material housing. The first and the second insulating material housings each have a plurality of conductor insertion openings arranged side by side for inserting an electrical conductor in a conductor insertion direction into the insulating material housing. The first insulating material housing has a first busbar and the second insulating material housing has a second busbar, and at least two conductor insertion openings of the first insulating material housing and the second insulating material housing are each associated with a clamping spring having a clamping leg. The clamping leg and the respective busbar form a clamping point for an electrical conductor to be clamped.

An apparatus may include (1) a terminal connector configured to be electrically coupled to a power interface of a computing device, (2) an inline terminal block assembly that is independent of the terminal connector, (3) at least one terminal-side power cable configured to be electrically coupled between the terminal connector and the inline terminal block assembly, and (4) at least one distribution-side power cable configured to be electrically coupled between the inline terminal block assembly and a power distribution system.

A power feeder device can include a base having a mounting portion and a plurality of connector structures extending from the mounting portion and spaced apart relative to each other to form a respective gap therebetween. Each connector structure can be configured to receive a respective pair of terminals to electrically connect the respective pair of terminals within connector structures and to block a line of sight between adjacent pairs of terminals. The device can also include a cover configured to mate with the base to enclose each of the plurality of connector structures and to increase a length of a creepage path between each pair of terminals by at least partially inserting into each gap between the connector structures. The base and the cover can be configured to form a terminal opening on each lateral side when assembled to allow pass-through of a conductor and/or portion of each terminal. In certain embodiments, at least one of the terminals of the respective pair of terminals can be a bus bar extending from a bus bar chassis and the base and/or the cover can form a creepage barrier that extend into a chassis wall opening of the bus bar chassis to increase a length of a chassis creepage path from the respective pair of terminals to the bus bar chassis.

An insulation displacement contact system includes a first insulation displacement contact, a second insulation displacement contact, and a cover having a first portion over the first insulation displacement contact and a second portion over the second insulation displacement contact. The cover includes a retention gap between the first portion and the second portion to engage the cover with a first pair of prongs of the first insulation displacement contact. The first portion of the cover includes a first ledge and a second ledge configured to engage the cover with a second pair of prongs of the first insulation displacement contact.

Provided is a molding method of a sealing cover, realized by setting up a sealing cover mold, the mold includes a cavity and a core group arranged in the cavity, including setting up a first core and a second core, the mold opening direction of the first core and the second core are not parallel. The present application does not need a process hole to perform the injection molding of the sealing cover with a fastening structure, whose sealing is also better.

A plastic shell for mounting a connection terminal includes a main body configured as an integral single component. The main body includes a top surface and a bottom surface opposed to each other. The bottom surface is depressed toward the top surface to form an internal space for accommodating a conductive terminal. A connecting portion for mating with the clamping portion of the conductive terminal is disposed in the internal space. A front end surface of the main body has a wire insertion hole for inserting a wire into the conductive terminal, and the wire insertion hole is in communication with the internal space.

Provided is a relay connector including a relay terminal including a first connection portion configured to connect to a first device side terminal and a second connection portion configured to connect to a second device side terminal; a clamping member including a first clamping portion configured to clamp the first device side terminal together with the first connection portion and a second clamping portion configured to clamp the second device side terminal together with the second connection portion; a lower case configured to hold the relay terminal; and an upper case configured to hold the clamping member, wherein a connector case includes a first insertion opening and a second insertion opening; and guide portions are formed on the clamping member, the guide portions guiding the first device side terminal inserted from the first insertion opening and the second device side terminal inserted from the second insertion opening.

The present invention is directed to a resilient force clamping connection (2) for a terminal block (1), in particular a connection terminal or connecting terminal, so as to electrically connect at least one conductor, said resilient force clamping element comprising a busbar (3), and a clamping spring (4) having a support limb (40), a resilient bend (41) that adjoins the support limb (40), and a clamping limb (42) that adjoins the resilient bend (41), wherein the clamping limb (42) comprises at a free end (420) that is remote from the resilient bend (41) a clamping section (421) so as to form a conductor clamping site (K) between the clamping section (421) and the busbar (3) so as to electrically connect a conductor (L) to the resilient force clamping connection (2). At least one actuating limb (43) extends from the clamping limb (42) between the resilient bend (41) and the free end (420) in a direction away from the support limb (40), wherein the actuating limb (43) comprises an actuating section (430) in order to cooperate with a release element (5) so as to open the conductor clamping site (K). The present invention is further directed to a terminal block (1) so as to electrically connect at least one conductor, said terminal block comprising an insulated housing (6) and at least one resilient force clamping connection (2) according to the present invention and being received at least in part by the insulated housing (6).