Provided is a sensor which makes it easy to mount a cable to a circuit board. This sensor 1 is provided with: a circuit board 2; a connector 10 which is composed of a metal material and which is fixed to the circuit board 2; and a cable 3 which is connected to the circuit board 2 via the connector 10. The connector 10 has: a bottom part 11 that is connected to the circuit board 2; and a pair of pinching elements 12L, 12R that are raised upright from said bottom part 11. The cable 3 is held in a space S between the pair of pinching elements 12L, 12R.

Various implementations of insulation piercing connectors are disclosed. The insulation piercing connectors include a simple and efficient design for providing electrical tap connections to a power cable for voltage detection purposes. The insulation piercing connector includes at least a top housing and a bottom housing that come together to receive the power cable. Terminal contacts are housed internally within the insulation piercing connector, and the terminal contacts are positioned to pierce the power cable when the insulation piercing connector is assembled into an operational state.

A plug contact stamped from a strip of sheet metal, the plug contact including cut edges and rolled sides; a clamping section configured to fix the plug contact in a contact carrier; a contact fork formed by two spring elastic contact arms forming a receiving cavity between each other and including cut edges that are oriented towards each other, wherein a first end of the two spring elastic contact arms respectively originates from the clamping section and a second end of the two spring elastic contact arms respectively forms a contact bud, wherein the two spring elastic contact arms include rolled sides that are oriented towards each other and produced by forming the second end of the spring elastic contact arms respectively.

A plug contact stamped from a strip of sheet metal, the plug contact including cut edges and rolled sides; a clamping section configured to fix the plug contact in a contact carrier; a contact fork formed by two spring elastic contact arms forming a receiving cavity between each other and including cut edges that are oriented towards each other, wherein a first end of the two spring elastic contact arms respectively originates from the clamping section and a second end of the two spring elastic contact arms respectively forms a contact bud, wherein the two spring elastic contact arms include rolled sides that are oriented towards each other and produced by forming the second end of the spring elastic contact arms respectively.

A compliant mechanism tool for connector termination can be used to seat a rear body portion of a connector against or within a forward housing portion of the connector. Seating the rear body portion causes conductors, which are coupled to the rear body portion, to electrically couple with respective ones of contacts positioned with the forwarding housing. The compliant mechanism tool includes first and second handles that can be subjected to a squeezing motion causing connected first and second arms to propel a ram toward a head portion of the tool. The ram interfaces with the forward housing portion of the connector causing the forward housing to be pushed against the rear body portion causing seating of the rear body portion; motion of the forward housing is limited by a stop within the head portion of the tool.

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 compression tool for fastening a cable to a connector comprising an elongated tool frame, an anvil secured to one end of the tool frame, a compression plunger slidable along a portion of the tool frame, a handle set adapted to move the compression plunger toward and away from the anvil and a spacer block for securing the connector a distance from the anvil. The handle set may include a first handle movable from a first position wherein the plunger is a first distance from the anvil to a second position wherein the plunger is a second distance from the anvil. The spacer block may include a first end and a second end having a different depth from the first end and be rotatable so that the first end when rotated to the active position secures the connector a first distance from the anvil and the second end, when rotated to the active position secures the connector a second distance from the anvil.

Aspects of the present disclosure relate to an electrical connection device having features for cutting an electrical power conductor while maintaining downstream continuity and limiting access to the electrical power conductor.

An inline cable connector assembly connects one or more twisted pairs of wire leads of a first cable to one or more twisted pairs of wire leads to a second cable. The assembly includes first and second terminal housing parts, first and second wiring caps, and double ended insulation displacement contacts within the connector assembly.