A cable inlet assembly for an inlet housing includes a cable inlet cover covering an inlet for at least one cable, and a locking element slidable between an unlocked position and a locked position. The locking element includes at least one opening adapted to receive a terminal of the at least one cable, and a first coupling element adapted to be coupled with a second coupling element of the cable inlet cover. The displacement of the cable inlet cover along a vertical direction induces a sliding of the locking element along an orthogonal direction between the unlocked position and the locked position for locking a position of the terminal.

The present disclosure relates to a process connection for connecting a sensor to a process inlet via a process seal and a fixing element. The process connection includes a sensor housing and a clamping element. The sensor housing has a housing body configured to receive the sensor and a housing collar that extends around the housing body and has a first sealing section, which encircles the housing body, and a contact area. The housing collar is formed integrally with the housing body. The first sealing section is suitable for receiving the process seal to connect the process inlet to the housing collar in a fluid-tight manner. The clamping element has a contact area which is suitable for coming into contact with the contact area of the housing collar to press the housing collar onto the process seal.

An impact-resistant cable connector includes a connector body, and a resilient block having a first surface facing the connector body and separated from the connector body by a first distance, a second surface opposite the first surface, and one or more bores, each of the one or more bores running through both the first surface and the second surface. One or more wires are coupled to the connector body, each respective one of the wires passing through a respective one of the bores. The resilient block is configured to limit bending of the one or more wires about a first axis parallel to the first surface. Such configuration may include spacing the resilient block away from the first surface by a first distance that is less than half the height of the resilient block.

Provides is an assembly for sealing a juncture of a cable in a wall. The wall includes at least one aperture. The aperture is used for coupling a connector comprised in the cable. A cable end is provided with at least one flange. The flange surrounds at least in part the cable end. The assembly includes at least one strain relief element. The strain relief element is configured, once in a position to cooperate with the wall and the flange, to press, directly or indirectly, the flange against the wall when the connector is coupled while the strain relief element remains attached to the wall, so that the flange surrounds, directly or indirectly, the aperture and prevents, directly or indirectly, any foreign matter from passing the juncture of the cable at the aperture.

A sealing process of LED modules, comprising: (1) a waterproof wire goes through a wire-through hole of a heat sink to be connected with a positive-negative solder joints on a PCB board, wherein the positive-negative solder joint and the position that the waterproof wire going through are subjected to glue sealing treatment, and a waterproof sealing process is operated between the waterproof wire and the wire-through hole; (2) fix the PCB board on the heat sink; (3) place one sealing ring into one of the grooves; (4) apply evenly a ring of liquid silica gel along the other groove of the lens set and the amount of the liquid silica gel is limited to completely sticking the solid silica gel sealing ring; (5) the heat sink installed with the PCB board and the waterproof wire as processed in step (2) is inversely buckled on the lens set which is set with the solid silica gel ring and the liquid silica gel as processed in step (4), so as to fix the heat sink entirety and the lens set. At least two waterproof sealing rings are used for completely isolating an LED chip from the outside so as to prevent all water vapor or other harmful gases from corroding the chip and the PCB, and the sealing rings are firmer when being compared with thin film sealing; the service life is longer and the guarantees to the sealing performance between the lens set and the heat radiation frame are realized.

A retainer resists decoupling of a first connector of a first cord from a second connector of a second cord. The retainer includes a first receiver having an adjuster to adjust the receiver about a portion of the first cord. The retainer includes a second receiver having an adjuster to adjust the receiver about a portion of the second cord. A connector housing couples the first and second receiver. The first receiver, second receiver, and connector housing form a continuous chamber in which lies portion of the first and second cords connected together when the retainer resides in an installed orientation. The retainer, in the installed orientation, resists incursion of water, dust particulate matter and other debris into the continuous chamber.

A power supplying module that can be reduced in size is provided. The power supplying module includes a module body, and a lead-in unit provided on one surface of the module body. The lead-in unit includes a plate unit that fixes at least one sealing tube to the one surface of the module body, and at least one circumference holding unit that holds a circumference of the corresponding sealing tube. The plate unit is provided with, in a longitudinal direction of the one surface of the module body, a plurality of cable insertion holes, and a plurality of positioning portions that position the plurality of circumference holding units to the corresponding cable insertion holes.

Provided are a cable securing clamp and a data transmission device. The cable securing clamp includes a clamp body and a snap member. The clamp body is provided with a first through hole, a side wall of the clamp body is provided with a second through hole communicating with the first through hole, and the first through hole is configured to allow a cable to pass through. A first end of the snap member is pivotally connected to the clamp body, a second end of the snap member is in interference fit with the second through hole, a surface of the second end of the snap member is provided with a tooth structure, and the tooth structure is configured to snap the cable in the first through hole such that the cable is secured in an extending direction of the first through hole.

A connector retention clip is disclosed. The connector retention clip can include a connector housing having a plurality of connector walls defining a connector opening operable to receive a coupled receptacle and plug connector therein. The plurality of connector walls can include a receptacle end wall and a plug end wall operable to extend about ends of the receptacle and plug, respectively, to provide a mechanical barrier preventing uncoupling of the coupled receptacle and plug connector. In addition, the connector retention clip can include a cable housing extending from the connector housing. The cable housing can have at least one cable wall defining a cable opening operable to receive a cable therein that extends from the coupled receptacle and plug connector.

Herein are provided a series of embodiments of a cable management device for use with cables with end connector covers. The device provides a tapered surface between the cable and locking screws so as to eliminate right angles which catch during movement of the cord. The device facilitates easy retraction of cables with bulky terminals through constricted spaces, eliminates snagging on other cables, and simplifies cable routing and use. The device further provides a means of rotating the screws while the device is in place. The device can be affixed to existing or newly manufactured cables.