Examples disclosed herein generally relate to methods and apparatus for the insertion of one or more wires into a cavity of a fixture of a structure or component. The wire insertion apparatus includes a grommet, a gripper adapted to interface with the grommet, and at least a first vibrating element. The first vibrating element is connected to and vibrates one or more of the apparatus, the grommet, the gripper, the wire, and/or a component of the apparatus. Vibration, induced in any direction, enables the cavities to shift position during insertion relative to the contact, thus increasing the tolerance of the cavity, reducing the failure rate of wire insertion, and reducing total production time. The vibration breaks the static friction of the contact in the grommet or dielectric opening, creates the positive locating required to insert the contact in the grommet and/or dielectric, and/or pivots the contact.

A terminal locator for holding a terminal in a crimping zone of a terminal crimping device includes a housing configured to be positioned forward of crimp tooling defining the crimping zone. The housing has a terminal cavity extending along a terminal axis configured to receive the terminal such that a crimp barrel of the terminal extends rearward of the housing along the terminal axis into the crimping zone for crimping to a wire. A spacer is held by the housing. The spacer has a spacer blocking surface configured to locate the terminal and block axial rearward movement of the terminal. A latch is held by the housing. The latch is deflectable to allow insertion and removal of the terminal from the terminal cavity, the latch having a latch blocking surface configured to locate the terminal and block axial forward movement of the terminal.

The present document describes an assembly for connecting a test unit to a wiring harness or equipment to be tested, and a method for testing using the assembly. The assembly may comprise a test box unit, a generic mate-in interface, an intermediate mate-in interface and at least one specific mate-in interface. The intermediate mate-in interface comprises an input/output connector connected between the generic-to-intermediate connector and the intermediate-to-specific connector, for enabling at least one of inputting a signal into the intermediate mate-in interface and outputting a signal from the intermediate mate-in interface. The assembly is used for performing tests on the equipment using at least one of a device adapted for generating a signal and a device adapted for measuring at least one attribute of a signal or circuit which is/are connected to the input/output connector of the intermediate mate-in interface.

A spin weld apparatus for spin welding a prepared end of a coaxial cable with a coaxial connector includes a cable clamp dimensioned to grip the coaxial cable and a drive collet dimensioned to enclose and rotationally interlock with a lateral surface of the coaxial connector. The drive collet is dimensioned to rotationally interlock with an interlocking portion of a spin welder. The spin welder is dimensioned to axially align the coaxial connector with the coaxial cable for spin welding when the drive collet is rotationally interlocked with the spin welder.

An operation method for busbars docking platform has putting a first busbar and a loading unit in a receiving groove, arranging the first busbar to touch the loading unit, removing the loading unit; loading a connecting rod to the loading unit; putting the loading unit in the receiving groove; triggering the first release member to impact the loading unit; triggering the second release member to retract the action unit; removing the loading unit; putting a second busbar in the receiving groove; putting the first busbar between the action unit and the second busbar; removing the first busbar; putting the first busbar in the receiving groove; triggering the first release member to impact the first busbar; triggering the second release member to retract the action unit; and taking the first busbar and the second busbar out from the receiving groove.

A platform for connecting busbars has a loading unit having a blind hole on a docking surface for receiving a connecting rod, an action unit used for impacting the loading unit or a busbar to push the connecting rod into a pre-hole on the busbar, a limit unit used for stopping the busbar from moving along its length direction, and a support unit used for supporting the action unit and the limit unit. The connecting rod is assembled to the first busbar by the action unit combined the loading unit and then the connecting rod already assembled to the first busbar is assembled to the second busbar by the action unit.

An apparatus (100) for installing at least one electrical contact (152) into a connector housing (150) comprises a base (110) configured to fixedly support the connector housing (150), an alignment guide (122), extending from the base (110) and having a central axis (164), and a carrier (124), translatably and pivotally coupled with the alignment guide (122). With the connector housing (150) fixedly supported by the base (110), the alignment guide (122) is configured to be parallel to an insertion axis (160) of a socket (154) of the connector housing (150), and the carrier (124) is movable parallel to the insertion axis (160). The apparatus (100) additionally comprises a tool holder (132), coupled to the carrier (124). The tool holder (132) has a working axis (162), only one degree of freedom relative to the carrier (124), and only three degrees of freedom relative to the base (110).

A compensating plug connector comprising a plug, a receptacle mating zone, a cable mating zone and an intermediate zone. Each of the zones is such that Near End Cross Talk (NEXT) resulting from transmission of the high frequency signal across each zone is below a specified amount chosen such that NEXT introduced by a high frequency signal transmission between via all the zones is below a level as specified for the cabling category.

Methods and systems for providing crosstalk compensation in a jack are disclosed. According to one method, the crosstalk compensation is adapted to compensate for undesired crosstalk generated at a capacitive coupling located at a plug inserted within the jack. The method includes positioning a first capacitive coupling a first time delay away from the capacitive coupling of the plug, the first capacitive coupling having a greater magnitude and an opposite polarity as compared to the capacitive coupling of the plug. The method also includes positioning a second capacitive coupling at a second time delay from the first capacitive coupling, the second time delay corresponding to an average time delay that optimizes near end crosstalk. The second capacitive coupling has generally the same overall magnitude but an opposite polarity as compared to the first capacitive coupling, and includes two capacitive elements spaced at different time delays from the first capacitive coupling.

A method for automatically mounting a connector housing with a contact part attached to an electrical line includes holding the contact part, determining an actual rotational position of the contact part, comparing the actual rotational position with a predetermined rotational position, and performing a rotational position correction thereby aligning the connector part to the connector housing. The connector housing is fixed to a holder and the contact part is inserted into a cavity of the connector housing by means of a movable gripper.