A tool for mounting a coaxial cable on a first connector is disclosed, wherein the coaxial cable extending along a first axial is adapted to pass through a first outer sleeve of the first connector, wherein the tool comprises a plunger; and a mold comprising an upper mold hinge and a lower mold hinge, wherein the upper mold hinge pivotally connected to the lower mold hinge so as to rotate the upper mold hinge relative to the lower mold hinge with respect to a rotation axis, and a second axial direction of the rotation axis is parallel to the first axial direction, wherein the plunger is adapted to push the first connector so as to force the upper mold hinge and the lower mold hinge to press the first outer sleeve so as to deform the first outer sleeve radially.

An insulation displacement contact (IDC) cluster includes a plurality of IDC cluster modular units each having a plurality of receptacles adjacent to one another in a row. Each of the receptacles receives an IDC terminal. A first IDC cluster modular unit of the IDC cluster modular units is coupled to a second IDC cluster modular unit of the IDC cluster modular units to form a modular structure by stacking and fastening together, arranging the receptacles of the IDC cluster modular units in parallel rows.

An electrical connector for grounding a multicore cable having a shield includes a spring terminal engaging the shield and an insulation displacement connection (IDC) terminal terminating a ground wire. The shield is grounded through the electrical connector.

Disclosed herein is an electrical outlet cutting jig that includes a ruler and a body having a lower perimeter, wherein the body includes a first channel defined along a first axis of the body. The body also includes a first level indicator and a second level indicator orthogonal to the first level indicator to enable a user to align the cutting jig correctly. The first channel is configured to receive the ruler such that a lower surface of the ruler is flush with the lower perimeter of the body and such that the ruler can slide within the first channel. The ruler enables the user to position the body of the cutting jig at a predetermined distance from a location, such as a door frame, floor, skirting board, or the like.

Disclosed herein is an electrical outlet cutting jig that includes a ruler and a body having a lower perimeter, wherein the body includes a first channel defined along a first axis of the body. The body also includes a first level indicator and a second level indicator orthogonal to the first level indicator to enable a user to align the cutting jig correctly. The first channel is configured to receive the ruler such that a lower surface of the ruler is flush with the lower perimeter of the body and such that the ruler can slide within the first channel. The ruler enables the user to position the body of the cutting jig at a predetermined distance from a location, such as a door frame, floor, skirting board, or the like.

A connector assembly has a connector part and a cable manager part. The cable manager part can be provided with a separable lacing fixture that functions to retain the severed portions of the wires that result from the termination process, rather than allowing the severed wire portions to fall to the floor in an uncollected state. In one aspect, the cable manager part has a main body to which the separable lacing fixture is attached via a plurality of breakaway portions.

An Insulation Displacement Contact Compliant connector system (IDCC) which includes a housing, header pins, and a Printed Circuit Board (PCB). Each header pin has at least a single barb to be retained into the housing. Each pin has a blade for contacting a wire. A compliant feature on the pin retains itself into holes in the PCB. The housing has a negative space similarly shaped to the pin. The housing includes a strain relief which provides a lead-in for a wire. When the system is fully assembled, the pins reside in the housing, and exit through the housing and into and through respective holes in the PCB. A wire can be inserted into the housing once the pins reside in the housing. There are several options for the assembly process including a) a pin-to-housing insertion process; b) a housing assembly-to-PCB process or a connector-to-PCB process; and c) a wired housing assembly-to-PCB assembly process or a wire harness-to-PCB assembly process.

An Insulation Displacement Contact Compliant connector system (IDCC) which includes a housing, header pins, and a Printed Circuit Board (PCB). Each header pin has at least a single barb to be retained into the housing. Each pin has a blade for contacting a wire. A compliant feature on the pin retains itself into holes in the PCB. The housing has a negative space similarly shaped to the pin. The housing includes a strain relief which provides a lead-in for a wire. When the system is fully assembled, the pins reside in the housing, and exit through the housing and into and through respective holes in the PCB. A wire can be inserted into the housing once the pins reside in the housing. There are several options for the assembly process including a) a pin-to-housing insertion process; b) a housing assembly-to-PCB process or a connector-to-PCB process; and c) a wired housing assembly-to-PCB assembly process or a wire harness-to-PCB assembly process.

A punchdown tool for fitting wires into connectors including a housing with a front side, a back side, a front end, a rear end opposite the front end, a leading surface on the front end, and an interior defined between the front and back sides. The punchdown tool also includes a drive mechanism with a hammer, an anvil, and a drive spring. The drive mechanism is positioned in the interior of the housing adjacent the front end. The punchdown tool further includes a circuit board positioned in the interior of the housing adjacent the rear end with a controller. The punchdown tool also includes a light positioned on the leading surface of the housing that is electrically coupled to the controller and at least one battery positioned in the interior of the housing for supplying power to the light and the circuit board.

A robotic wire termination system for efficiently and accurately connecting a plurality of wires to an electrical connector having a plurality of connector pins with corresponding wire receptacles. The system generally includes a housing, a removable alignment plate, a robotic positioner, a heating device, a touch responsive display, and a control unit. The alignment plate removably holds a selected electrical connector in a specific position and orientation with the connector pins exposed in the housing and the wire receptacles exposed outside. The display provides a visual representation of the connector pins and selections of the connector pins. The control unit receives inputs indicating the pin selections and controls the robotic positioner to sequentially move the heating device along three orthogonal longitudinal axes to a series of heating positions relative to the selected connector pins to provide heat for melting solder to connect wires to the wire receptacles.