Provided is a current limiting circuit (30) configured to: before release of a touch between a second contact (20b) provided at a position where a terminal (11a) on a power receiving side in which a current flows at supply of DC power in an electrode that supplies the DC power touches before touching a first contact (20a) provided for the electrode at supply of the DC power and the terminal (11a), decrease the current flowing into the terminal (11a) through the second contact (20b); and avoid flowing a current in a case where the terminal (11a) is touching the first contact (20a), and decrease the current flowing into the terminal (11a) through the second contact (20b) only in a case where the terminal (11a) is touching the second contact (20b).

A plug mounted on an optical cable with one or more optical contacts each one having a tab which is deformable elastically or mounted so as to pivot relative to the rest of the contact, including: a body including a front part and a rear part; a bushing fitted around the front part with axial sliding forward, the bushing bearing a tab with an appendage extending inside the rear part, the tab of the bushing and the tab of each contact being disposed relative to each other so that when a traction force is applied to make the bushing slide around the front part, the appendage is able to bear against the tab of each contact so as to deform it elastically or make it pivot until the disconnection is produced between the contact and the converter.

A plug mounted on an optical cable with one or more optical contacts each one having a tab which is deformable elastically or mounted so as to pivot relative to the rest of the contact, including: a body including a front part and a rear part; a bushing fitted around the front part with axial sliding forward, the bushing bearing a tab with an appendage extending inside the rear part, the tab of the bushing and the tab of each contact being disposed relative to each other so that when a traction force is applied to make the bushing slide around the front part, the appendage is able to bear against the tab of each contact so as to deform it elastically or make it pivot until the disconnection is produced between the contact and the converter.

The present invention concerns a plug intended to be mounted on at least one cable whose one end supports one or more contacts comprising: a body, comprising: a front portion extending along a longitudinal axis, the front portion being designed to be lodged in a socket, the front portion being adapted to lodge and hold the contact(s) or at least an optoelectronic converter connected to the contact(s); a rear portion forming a sheath, designed to lodge the end of the cable, itself supporting the contact(s); the rear portion being mounted floating about the front portion; a plurality of flexible tabs made of electrically conductive material, distributed on the outer periphery of the front portion, the flexible tabs being adapted to remain in mechanical contact with the interior of the socket when the front portion is lodged in the latter.

The present invention concerns a plug intended to be mounted on at least one cable whose one end supports one or more contacts comprising: a body, comprising: a front portion extending along a longitudinal axis, the front portion being designed to be lodged in a socket, the front portion being adapted to lodge and hold the contact(s) or at least an optoelectronic converter connected to the contact(s); a rear portion forming a sheath, designed to lodge the end of the cable, itself supporting the contact(s); the rear portion being mounted floating about the front portion; a plurality of flexible tabs made of electrically conductive material, distributed on the outer periphery of the front portion, the flexible tabs being adapted to remain in mechanical contact with the interior of the socket when the front portion is lodged in the latter.

Disclosed herein is a connector for electrically connecting a feedthrough of a vacuum tool to a high voltage power source, the connector comprising: a connector wire assembly configured to be in electrical connection with a high voltage power source; and a connector insulator comprising a channel configured to extend into the connector insulator and to receive a feedthrough pin so as to electrically connect the connector wire assembly with the feedthrough pin; wherein the connector insulator is configured to engage with the feedthrough so that a boundary surface of the connector insulator extends substantially bi-directionally in the direction of the longitudinal axis of the channel.

A hybrid dimming controller for a lighting control system providing isolated class 1 and class 2 dimming outputs. The controller has two NEC class 1 outputs for providing independent low-voltage dimming-control signals for two lighting loads and two NEC class 2 outputs for providing the same two independent dimming control-signals for the lighting loads. Thus, the controller has both a class 1 and a class 2 outputs for delivering the same dimming-control signal for each of the two lighting loads while maintaining within the controller the isolation that is required between class 1 and class 2 circuits.

A hybrid dimming controller for a lighting control system providing isolated class 1 and class 2 dimming outputs. The controller has two NEC class 1 outputs for providing independent low-voltage dimming-control signals for two lighting loads and two NEC class 2 outputs for providing the same two independent dimming control-signals for the lighting loads. Thus, the controller has both a class 1 and a class 2 outputs for delivering the same dimming-control signal for each of the two lighting loads while maintaining within the controller the isolation that is required between class 1 and class 2 circuits.

A heavy-duty plug-in connector has a ground terminal that can be conveniently assembled and can comprise the greatest possible number of electrical crimp plug-in contacts (4,5). For this purpose, ground plug-in contacts (4′, 5′), likewise of a crimping configuration, are fitted in formations (13, 13′, 23, 23′) of the contact carriers (1, 2) for electrical contacting with metallic protective earthing elements (3, 3′, 3″, 3″). For said contacting, the formations (13, 13′, 23, 23′) have a respective opening (130, 130′) or passage (230, 230′). In the formations (13, 13′, 23, 23′), not only ground plug-in contacts (4′, 5′) but also further plug-in contacts (4, 5) are arranged, so that the number of plug-in contacts (4, 5) of the plug-in connector is increased considerably.

A female electrical connector for use in a separable connector assembly is provided. The female electrical connector includes an elongate insulative body and a female contact disposed within the body. The female electrical connector also includes a tubular support sleeve extending between a first end and a second end. The first end of the tubular support sleeve is connected to the female contact. The tubular support sleeve defines a cavity at the second end. The female electrical connector further includes an insulating coupling connected to the second end of the tubular support sleeve. The insulating coupling includes an insulating sleeve that is moveable between a retracted position, where the insulating sleeve is retracted within the cavity of the tubular support sleeve, and an extended position, where the insulating sleeve extends outward from the cavity and away from the second end of the tubular support sleeve.