A system for mounting an electronic device includes a socket and a stand, the stand having a ball portion. The socket and the ball portion include first magnetic material to hold the socket and the ball portion together in a position selected by a user, the socket further including a magnetic array, the magnetic array having magnetism to hold an electronic device to the socket. In one alternative, the first magnetic material is separate from the magnetic array.

A charging dock, an electronic product, a charging system and a charging method are provided. The charging dock includes a housing, a first charging terminal, a first magnetic device, a first detection device and a first control circuit. The first charging terminal, the first magnetic device, the first detection device and the first control circuit are in the housing. The first magnetic device is to attract the charging plug near the first magnetic device to enable the charging plug to move in a direction towards the first charging terminal. The first control circuit is to control the first charging terminal to be energized when the first detection device detects that the first charging terminal is electrically coupled to the charging plug.

Electrode array assembly (10) including a carrier assembly (12) and a connector assembly (14). The carrier assembly (12) includes an array of first electrical contacts (20) coupled to a plurality of electrodes (18), and a first housing (22) canying the array of first contacts (20) and configured to allow access to the first contacts (20). The connector assembly (14) includes an array of second electrical contacts (26), and a second housing (28) canying the second contacts (26) and configured to allow access to the second contacts (26). Each of the carrier assembly (12) and the connector assembly (14) include complementary retention elements (30) and complementary locating formations (32), whereby engaging the complementary locating formations (32) allows the complementary retention elements (30) to secure the first housing (22) to the second housing (28), and allows the first contacts (20) to couple with the second contacts (26).

The present disclosure discloses a connector module with improved convenience in use and durability. To achieve the above-described object, the connector module according to the present disclosure has at least one receptacle and a receiving groove having an inner space of a predetermined depth, is configured to be connected to an external connector module provided in an external device, and is provided in an internal device, and the connector module includes at least one plug configured to be coupled to the receptacle for electrical connection with the receptacle, a coupling part including a coupling guide rib wherein the coupling guide rib extends toward the external connector module, is inserted into the receiving groove when the external connector module is connected to the connector module, and is configured to guide a coupling position of the connector module, and a fastening part coupled to the coupling part such that the coupling part moves in a predetermined distance range and configured such that a portion of the fastening part is fixed to the internal device.

A magnetic connector has a plug core disposed around a plug contact set and a receptacle core disposed around a receptacle contact set. The plug core defines a generally elongated circular plug core edge. The receptacle core defines a generally elongated concentric-circular receptacle core edge. The receptacle core edge defines an air gap and the plug core defines an anchor configured to insert into the air gap. A coil is disposed around the receptacle core, and the coil, the plug core and the air gap define a magnetic circuit. The coil is electrically energized so as to form a magnetic field within an air gap, lock the anchor within the air gap and lock the plug contact set to the receptacle contact set accordingly.

A connection unit includes: a body having peripheral edges; magnets, at least one of which being disposed on each side of the peripheral edges of the body; and electrode terminals, at least three of which being disposed on the each side of the peripheral edges of the body. An outer surface of the body has a curved surface. The electrode terminals are disposed along the curved surface or the surface having the polygonal cross section of the outer surface. The electrode terminals disposed on the peripheral edges of the body have either: one positive electrode terminal and two negative electrode terminals, or one negative electrode terminal and two positive electrode terminals.

A load handling device for lifting and moving containers stacked in a storage system a grid framework structure, the load handling device including: a vehicle body housing a driving mechanism operatively arranged for moving the load handling device on the grid framework structure; a lifting device having a lifting drive assembly and a grabber device configured to releasably grip a container and lift the container from the stack into a container-receiving space; are chargeable power source electrically coupled to an electrical charge point for electrically coupling to a charge head of a charge station wherein; the electrical charge point includes a charge collector connectable to the charge head of the charge station under action of a magnet.

A method is disclosed for performing extension mobility via a headset connection. The method includes receiving a headset identifier from a headset. Also, the method includes, in response to receiving the headset identifier, sending the headset identifier to a device management server. Further, the method includes receiving a call control user identifier from the device management server, and sending, to a call control server, the call control user identifier. Still yet, the method includes receiving, from the call control server, a configuration profile associated with the call control user identifier. One or more settings of a desk phone are configured using the configuration profile.

An electrical connector for mounting on an external circuit board includes: an insulating body; a terminal module assembled on the insulating body and including a plurality of mating terminals, an insulating carrier with an accommodating cavity, plural intermediate terminals fixed on one side of the insulating carrier and electrically connected to the mating terminals, plural pin terminals fixed on the other side of the insulating carrier, and a magnetic module accommodated in the accommodating cavity and electrically connected to the intermediate terminals and the pin terminals, wherein the insulating carrier is a two-piece housing, the intermediate terminals are held in one housing piece, and the pin terminals are held in the other housing piece.

An electric interface comprising a motherboard (100) containing at least two interface receptacles (101) located on the motherboard (100) and at least one module (200) with the interface plugs (203). Each of the interface receptacles (101) includes at least one ground line contact (GND) at least one power line contact (VCC), at least two signal line contacts (SIG1, SIG2). All ground line contacts (GND) are connected to each other. All power line contacts (VCC) are connected to each other. All contacts of the first signal line (SIG1) are connected to each other. All contacts of the second signal line (SIG2) are connected to each other. Each module (200) contains a microcontroller (201) and an unit (202). The microcontroller (201) is connected to at least four module lines (PROBE1, PROBE2, PROBE3, PROBE4).