A wall-mounted electrical-connector-engaging assembly for axial engagement with an electrical connector, the assembly including (a) a wall-surface adapter having front and back faces and attached to a wall over an opening in the wall and (b) a backcap. The adapter back face has a plurality of wire-connection points for installation of a corresponding plurality of wires, and the adapter front face has a plurality of slidably-engaging electrical connection points for engagement in at least an axial direction with the electrical connector. The backcap surrounds the plurality of wire-connection points and adjacent portions of the corresponding plurality of wires connected thereto, and includes a twist lock for installation on the wall-surface adapter.

A wall-mounted electrical-connector-engaging assembly for axial engagement with an electrical connector, the assembly including (a) a wall-surface adapter having front and back faces and attached to a wall over an opening in the wall and (b) a backcap. The adapter back face has a plurality of wire-connection points for installation of a corresponding plurality of wires, and the adapter front face has a plurality of slidably-engaging electrical connection points for engagement in at least an axial direction with the electrical connector. The backcap surrounds the plurality of wire-connection points and adjacent portions of the corresponding plurality of wires connected thereto, and includes a twist lock for installation on the wall-surface adapter.

An inter-device cabling movement system includes a base and a plurality of cable attachment devices that extend from the base in a port identification sequence. Each of the plurality of cable attachment devices includes a cable engagement element that is configured to engage a respective cable, and a cable securing element that is configured to secure the cable engagement element to the respective cable. The cable engagement elements and cable securing elements may be utilized to secure each cable attachment device to respective cables connected to first ports on a first device so that those respective cables may be disconnected from the first pots on the first device and reconnected to second ports on a second device based on the port identification sequence.

An inter-device cabling movement system includes a base and a plurality of cable attachment devices that extend from the base in a port identification sequence. Each of the plurality of cable attachment devices includes a cable engagement element that is configured to engage a respective cable, and a cable securing element that is configured to secure the cable engagement element to the respective cable. The cable engagement elements and cable securing elements may be utilized to secure each cable attachment device to respective cables connected to first ports on a first device so that those respective cables may be disconnected from the first pots on the first device and reconnected to second ports on a second device based on the port identification sequence.

Methods, apparatus, systems, and articles of manufacture to improve pin contact are disclosed. An apparatus disclosed herein includes a back plate, a circuit board disposed between the back plate and a socket, and a spring sheet disposed between the back plate and the circuit board.

Methods, apparatus, systems, and articles of manufacture to improve pin contact are disclosed. An apparatus disclosed herein includes a back plate, a circuit board disposed between the back plate and a socket, and a spring sheet disposed between the back plate and the circuit board.

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.

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.

Aspects of the present disclosure relate to an apparatus for aligning a connector during engagement or disengagement from a port. In some embodiments the apparatus includes a sleeve, a channel in the sleeve, and a handle extending away from the sleeve. In some embodiments, the sleeve is designed to receive a cable connector with a first opening at a first end of the sleeve and a second opening at the second end of the sleeve, the sleeve designed to receive a cable connector through the first end and allow the cable connector to exit through the second end after the cable connector has been engaged to a port. In some embodiments, the channel extends a length of the sleeve from the first end to the second end.

A method for assembling a catheter is disclosed. The method includes printing conductive traces on at least one flexible substrate and encapsulating the at least one flexible substrate to provide for environmental protection. The at least one encapsulated flexible substrate is inserted into a shaft of a catheter. Then, connectors are attached to each end of the at least one encapsulated flexible substrate. One set of the connectors are further attached to sensors located at a distal end of the catheter and another set of the connectors are further attached to electronics in a handle of the catheter.