Systems and methods providing an electrical interface between a male plug (1002) and a female receptacle (100, 500, 1000, 1600). The methods comprise: receiving a conductive pin (402, 800, 1006, 1602) of the male plug in a socket opening (112, 900, 1012, 1612) of the female receptacle; providing (a) first spring loaded floating contact points (460) between an elongate body (422) of the conductive pin and an electrical contact (106A-106B) of the female receptacle and (b) at least one second spring loaded floating contact point (462) between a tip (420) of the conductive pin and the electrical contact (110) of the female receptacle, when the conductive pin is fully inserted into the female receptacle; and maintaining at least two of the spring loaded floating contact points when the pin moves within the socket opening as a result of an external force applied to the male plug or female receptacle.

A system for implementing an electrical rotary joint in a large-diameter system using relatively small-diameter capsule slip rings is described herein. The system includes a system rotor that rotates about a system axis of rotation, and a system stator that is stationary with respect to the system rotor. The system also includes at least one conductive contact channel disposed on one of the system rotor and the system stator. The system further includes at least one capsule slip ring (CSR) coupled to the other of the system rotor and the system stator. The at least one CSR has a conductive annular element coupled thereto, the conductive annular element in mechanical contact with the at least one conductive contact channel such that the at least one CSR forms an electrical rotary joint between the system rotor and the system stator.

The invention relates to a device for guiding a cable for linking a submerged robot, in particular a robot for cleaning swimming pools, to the device for controlling and powering same, said guiding device comprising: a. a coupling including a rotary connector, connected by one side to a first floating portion of the linking cable extending from the control and power device to said coupling and, by the other side, to a second portion of the linking cable extending from said coupling to the submerged robot; b. a floating mounting including: bi. a float; bii. an interface for mechanically linking the rotary connector to said float; and biii. a hood extending above the surface when the floating mounting is submerged in a liquid and removably connected to the float; c. in which the mechanical link between the float and the rotary coupling is a ball-and-socket link.

A rotatable coupling for audio cables is shown having a stator and a rotor divining an electrical rotary interface (301) for providing continuous connection between audio cables. A protective stator housing (304) retains the stator and a protective rotor housing (305) retains the rotor. A rolling-element bearing (306) with an inner race and an outer race allows the protective housings to axially rotate.

Disclosed is a rotary steering drilling apparatus. The rotary steering drilling apparatus includes a plurality of cylinders that are fixedly connected in series, wherein at least a part of adjacent cylinders are in power connection via a power connection unit; the power connection unit includes a first electrical connecting assembly and a second electrical connecting assembly, the cylinder in power connection is provided with a first electrical connecting assembly at one end and a second electrical connecting assembly at the other end, the adjacent cylinders are in power connection via the first electrical connecting assembly and the second electrical connecting assembly, and the first electrical connecting assembly and the second electrical connecting assembly on the same cylinder are in power connection; the first electrical connecting assembly includes a first electrical connecting ring which is arranged annularly, and the first electrical connecting ring includes a plurality of first conducting regions and first insulating regions which are distributed circumferentially and are spaced apart; and the second electrical connecting assembly includes a second electrical connecting ring which is arranged annularly, and the second electrical connecting ring includes a plurality of second conducting regions and second insulating regions which are spaced apart. The rotary steering drilling apparatus according to the present application can achieve multi-path power connection between adjacent cylinders and has the advantages of being convenient to mount, high in conductivity reliability and the like.

A slipring device includes a first part and a second part rotatable against each other. Both parts include housings with slipring components. A first housing at the first part has a hollow shaft with a bayonet lock notch to engage with a locking ring having at least one bayonet lock protrusion. The locking ring can easily be attached by a bayonet lock to lock the first part and the second part together.

An electronic device is provided. The electronic device comprises a housing, a flexible display configured to be at least partially rolled around a rotation axis in a substantially circular shape in an internal space of the housing, a battery located in the internal space in which the flexible display is rolled, a first printed circuit board located on one surface of the battery that is oriented in a direction of the rotation axis, the first printed circuit board being electrically connected to the flexible display and including a first wireless communication circuitry, and a second printed circuit board located inside the housing to face the first printed circuit board and including a second wireless communication circuitry. The first printed circuit board may be configured to be rotatable about the rotation axis in a state of being electrically connected to the second printed circuit board.

The invention concerns a handle for a video endoscope for medical or industrial applications, comprising a housing and an interface portion, where the interface portion includes a first connector element at its distal end connected to an electric transmission element that is connectable to a connector element of an associated elongate shaft to form a detachable electrical and/or mechanical connection between the handle and the associated shaft. The includes an electrical connection assembly arranged at an exterior of the interface portion forming an electrical connection between the electric transmission element and a stationary electric and/or electronic component of the handle. The handle also includes at least a first bearing for rotatably supporting the interface portion in and/or at the housing, such that when the shaft and handle are connected the shaft is rotatable via the rotatably supported interface portion relative to the housing of the handle.

A rotating spindle capable of conductively contacting via bearings contains: a power supply module, a body, a first conductive assembly, and a second conductive assembly. The power supply module includes a first circular shell, an insulation element, a second circular shell, a first bearing, and a second bearing. The body is accommodated in the first circular shell and includes two elongated orifices, two guide orifices, and two electrode orifices. The first conductive assembly includes a first internal conductive wire, a first external conductive wire, and a first electrode. The first internal conductive wire is connected with the first electrode and extends out of the one guide orifice. The second conductive assembly includes a second internal conductive wire, a second external conductive wire, and a second electrode. The second internal conductive wire is connected with the first electrode and extends out of the other guide orifice.

An electrically conductive assembly is for a bearing disposed about a shaft and disposed within a housing. The conductive assembly includes an annular retainer coupleable with a bearing outer ring or with the bearing housing and having a centerline and an open inner end defining an annular groove. At least two and preferably several conductors each have a radially outer end disposed within the retainer groove and a radially inner end contactable with the shaft. Each conductor is formed of a plurality of conductive fibers arranged to extend radially inwardly from the retainer inner end. The at least two conductors are spaced apart circumferentially about the centerline so as to define at least two axial passages between the retainer and the shaft. Preferably, the conductors are separated by spacers formed of conductive fibers each having a length shorter than the length of the fibers of the conductors.