A True Wireless System (TWS) headphone is provided, which comprises a charging case and one or two earbuds. The earbuds may be attached into the charging case by a two pogo pin connector. The earbuds can detect the different status of the battery in the charging case via the two pogo pin connector and can auto power on or off accordingly when taken out or put into the charging case.

A wireless charging module includes a housing configured to support at least one coil module therein. The housing includes an upper housing portion and a lower housing portion. The upper housing portion includes at least one vent. The lower housing portion includes at least one vent. One or more ducts are provided within the housing. The one or more ducts are in communication with the at least one vent of the upper housing portion and the at least one vent of the lower housing portion. An airflow path is defined from the at least one vent of the upper housing portion through the one or more ducts to the at least one vent of the lower housing portion for allowing an air flow internally within the housing generally around and/or adjacent at least a portion of the at least one coil module supported within the housing.

A device management system, method and apparatus are disclosed. The device management method comprises: sending, in response to a borrow and return request, an unlocking instruction to an electromagnetic lock configured for a device management cabinet, wherein the electromagnetic lock unlocks the device management cabinet in response to the unlocking instruction; receiving charging state information of a target device storage unit that is returned by the device management cabinet, wherein said device is stored in the target device storage unit; receiving lock state data of the device management cabinet that is sent by the electromagnetic lock, and acquiring electric quantity state information of said device; and generating, according to the charging state information, the electric quantity state information and the lock state data, borrow and return information of said device.

A portable power station is disclosed. The portable power station includes an illumination device including a device body, and a light source configured to emit a light through an optically transmissive portion of the device body. The portable power station further includes a housing including a middle portion between a bottom portion and a top portion. The portable power station further includes a device holder configured to be positioned on the top portion and support the device body in an operative position. The portable power station further includes a diffuser configured to be removably mounted to the device body in the operative position. The portable power station further includes a first receptacle disposed on the middle portion and configured to removably receive and secure the device body, such that the optically transmissive portion remains at least partially uncovered, and a second receptacle configured to removably receive and secure the diffuser.

An adapter for a charging cradle includes: a perimeter wall defining a channel between first and second ends; a first device interface on an inner surface of the perimeter wall in communication with the first end, the first device interface configured to receive and align a first mobile device configuration with the charging cradle; a second device interface on the inner surface of the perimeter wall in communication with the second end, the second device interface configured to receive and align a second mobile device configuration with the charging cradle; a cradle interface on an outer surface of the perimeter wall, and configured to couple the adapter to the charging cradle in one of (i) a first orientation to expose a connector of the charging cradle via the first end of the channel, and (ii) a second orientation to expose the connector via the second end of the channel.

In various aspects, an electronic docking system includes a docking device and an electronic device. The electronic device can be configured to be removably attached to the docking device. The docking device can include a first magnetic member and the electronic device can include a second magnetic member. The first magnetic member of the docking device can be configured to move from a first position to a second position.

A charge system for wireless temperature probe includes a probe body and a charging relay box detachably connected with the probe body, the probe body is provided with a first wireless charging component and a sealing structure. The charging relay box is internally provided with a power supply module, a control module and a second wireless charging component configured to establish a near field communication path with the first wireless charging component, and the control module is used to control the power supply module to adaptively supply power to the probe body through the near field communication path, the probe body comprises a handle, a sealing ring, a probe tube and an internal assembly, a head of the internal assembly is inserted in the probe tube, and a tail of the internal assembly is inserted in the handle.

A charge system for wireless temperature probe includes a probe body and a charging relay box detachably connected with the probe body, the probe body is provided with a first wireless charging component and a sealing structure. The charging relay box is internally provided with a power supply module, a control module and a second wireless charging component configured to establish a near field communication path with the first wireless charging component, and the control module is used to control the power supply module to adaptively supply power to the probe body through the near field communication path.

A cleaner charging system is provided. The cleaner charging system includes a charging station and a robot cleaner. The robot cleaner receives power from the charging station and includes a motor, an impeller that is rotated by the motor and generates a suction force, a suction opening that is an inlet through which dust is suctioned by the suction force, a dust container in which the suctioned dust is collected, a third docking terminal, a fourth docking terminal, a battery, and a second switching device that connects the third docking terminal and the battery.

Systems and method for an electric toothbrush and charging dock. The electric toothbrush may include at least one magnetic member and at least one charging coil in a central portion. The charging dock may include at least one magnetic member and at least one transmitting coil. The charging dock may include a proximal portion which may be attached to a distal portion of the charging dock to be rotatable relative to the distal portion. The charging dock may include at least one unit capable of receiving power from a power source. The energy received by the unit from the power source may be transmitted to the transmitting coil. The energy may be transmitted from the transmitting coil to the receiving coil in the electric toothbrush via inductive or resonance charging. The energy may be transferred from the receiving coil to a battery in the electric toothbrush.