Abstract: One embodiment provides a non-contact power transmitter device including a sealed housing provided at least partially within a surface, and a transmitter coil within the sealed housing configured to inductively transfer power to a power receiver device. The power transmitter device also includes a transmitter control unit coupled to the transmitter coil, a transceiver configured to communicate with the power receiver device, and an electronic processor coupled to the transmitter control unit and the transceiver. The electronic processor is configured to establish, using the transceiver, communication with the power receiver device, and negotiate power transfer requirements between the power transmitter device and the power receiver device. The electronic processor is also configured to control the transmitter coil unit to transfer power to the power receiver device.

Abstract: One embodiment provides a non-contact power transmitter device including a sealed housing provided at least partially within a surface, and a transmitter coil within the sealed housing configured to inductively transfer power to a power receiver device. The power transmitter device also includes a transmitter control unit coupled to the transmitter coil, a transceiver configured to communicate with the power receiver device, and an electronic processor coupled to the transmitter control unit and the transceiver. The electronic processor is configured to establish, using the transceiver, communication with the power receiver device, and negotiate power transfer requirements between the power transmitter device and the power receiver device. The electronic processor is also configured to control the transmitter control unit to transfer power to the power receiver device.

Abstract: A battery management platform including a battery configured to supply a type of power to at least one load device, and a central charging station configured to provide power to charge the battery while the battery is coupled to the central charging station. The central charging station including a locking mechanism configured to: secure the battery to the central charging station when a status of the battery is determined to be checked-in, and disengage to allow the battery to be removed when the status is verified to be check-out. Wherein the locking mechanism includes an override function configured to allow a user to disengage the locking mechanism without an electronic command.

Abstract: A battery management system including a battery center and a controller. The battery center includes one or more battery receptacle. The battery center is configured to: receive one or more batteries, identify one or more batteries, and charge one or more batteries. The controller includes a memory and an electronic processor. The controller is configured to: receive, from the battery center, a status of one or more batteries, receive, from a user, an unlock request, and output, to the battery center, an unlock command. Wherein, the battery center unlocks one or more batteries from the one or more battery receptacle upon receiving the unlock command.

Abstract: A device charging system including a battery configured to supply a type of power to at least one load device and a central charging station configured to receive the battery The central charging station including a locking mechanism configured to secure the battery to the central charging station, an output port configured to supply power to the battery, and an electronic processor. The electronic processor configured to: receive an unlock command from at least one selected from a group consisting of a remote device and a user-interface of the central charging station, and disengage the locking mechanism upon receiving the unlock command.

Abstract: A device charging system application to track one or more batteries configured to supply power to at least one load device and a central charging station in communication with the battery and including a transceiver and an electronic processor configured to define a virtual boundary within an area proximate to the central charging station, determine a proximate location of the battery, determine, based the location of the battery, whether the battery is within the virtual boundary, and transmit a command to the battery causing the battery to stop supplying power to the load device when the battery is not within the virtual boundary.

Abstract: One embodiment provides a non-contact power transmitter device including a sealed housing provided at least partially within a surface, and a transmitter coil within the sealed housing configured to inductively transfer power to a power receiver device. The power transmitter device also includes a transmitter control unit coupled to the transmitter coil, a transceiver configured to communicate with the power receiver device, and an electronic processor coupled to the transmitter control unit and the transceiver. The electronic processor is configured to establish, using the transceiver, communication with the power receiver device, and negotiate power transfer requirements between the power transmitter device and the power receiver device. The electronic processor is also configured to control the transmitter coil unit to transfer power to the power receiver device.

Abstract: One embodiment provides a non-contact power transmitter device including a sealed housing provided at least partially within a surface, and a transmitter coil within the sealed housing configured to inductively transfer power to a power receiver device. The power transmitter device also includes a transmitter control unit coupled to the transmitter coil, a transceiver configured to communicate with the power receiver device, and an electronic processor coupled to the transmitter control unit and the transceiver. The electronic processor is configured to establish, using the transceiver, communication with the power receiver device, and negotiate power transfer requirements between the power transmitter device and the power receiver device. The electronic processor is also configured to control the transmitter coil unit to transfer power to the power receiver device.

Abstract: A power system including a load terminal, a sensor, and an electronic processor. The load terminal is configured to electrically connect to a load device. The sensor is configured to sense an electrical characteristic of the load device. The electronic processor is configured to receive, via the sensor, the electrical characteristic of the load device, supply power, via the load terminal, to the load device, discontinue supply of power to the load device when the electrical characteristic of the load device crosses a predetermined threshold, and enter a standby mode upon discontinuing supply of power to the load device. Wherein when in standby mode the electronic processor, at predetermined time intervals, determines if the load device crosses the predetermined threshold a second time.

Abstract: A power receptacle including an outlet configured to electrically connect to a load device and an electronic processor. The electronic processor is configured to determine a state of charge of a battery of the load device. The electronic processor is further configured to supply power to the load device when the state of charge of the battery is below a predetermined threshold and to discontinue supply of power to the load device when the state of charge of the battery is at or above the predetermined threshold.

Abstract: One embodiment provides a non-contact power transmitter device including a sealed housing provided at least partially within a surface, and a transmitter coil within the sealed housing configured to inductively transfer power to a power receiver device. The power transmitter device also includes a transmitter control unit coupled to the transmitter coil, a transceiver configured to communicate with the power receiver device, and an electronic processor coupled to the transmitter control unit and the transceiver. The electronic processor is configured to establish, using the transceiver, communication with the power receiver device, and negotiate power transfer requirements between the power transmitter device and the power receiver device. The electronic processor is also configured to control the transmitter coil unit to transfer power to the power receiver device.

Abstract: A battery management system including a battery center and a controller. The battery center includes one or more battery receptacle. The battery center is configured to: receive one or more batteries, identify one or more batteries, and charge one or more batteries. The controller includes a memory and an electronic processor. The controller is configured to: receive, from the battery center, a status of one or more batteries, receive, from a user, an unlock request, and output, to the battery center, an unlock command. Wherein, the battery center unlocks one or more batteries from the one or more battery receptacle upon receiving the unlock command.

Abstract: A device charging system application to track one or more batteries configured to supply power to at least one load device and a central charging station in communication with the battery and including a transceiver and an electronic processor configured to define a virtual boundary within an area proximate to the central charging station, determine a proximate location of the battery, determine, based the location of the battery, whether the battery is within the virtual boundary, and transmit a command to the battery causing the battery to stop supplying power to the load device when the battery is not within the virtual boundary.

Abstract: A power receptacle including an outlet configured to electrically connect to a load device and an electronic processor. The electronic processor is configured to determine a state of charge of a battery of the load device. The electronic processor is further configured to supply power to the load device when the state of charge of the battery is below a predetermined threshold and to discontinue supply of power to the load device when the state of charge of the battery is at or above the predetermined threshold.

Abstract: A system for monitoring parameters of load equipment is provided. A power connector is provided with intelligence, at least one sensor, and a wireless communication component. The power connector is capable of monitoring physical parameters measured by the at least one sensor, such as voltage, current, temperature, and moisture. The system can further provide an alarm if the sensed parameter falls out of a predetermined range.

Abstract: A system for monitoring parameters of load equipment is provided. A power connector is provided with intelligence, at least one sensor, and a wireless communication component. The power connector is capable of monitoring physical parameters measured by the at least one sensor, such as voltage, current, temperature, and moisture. The system can further provide an alarm if the sensed parameter falls out of a predetermined range.

Abstract: A system for monitoring parameters of load equipment is provided. A power connector is provided with intelligence, at least one sensor, and a wireless communication component. The power connector is capable of monitoring physical parameters measured by the at least one sensor, such as voltage, current, temperature, and moisture. The system can further provide an alarm if the sensed parameter falls out of a predetermined range.

Abstract: A system for monitoring parameters of load equipment is provided. A power connector is provided with intelligence, at least one sensor, and a wireless communication component. The power connector is capable of monitoring physical parameters measured by the at least one sensor, such as voltage, current, temperature, and moisture. The system can further provide an alarm if the sensed parameter falls out of a predetermined range.

Abstract: An electrical connector adapted to receive a mating plug utilizes low-profile jack terminal contacts that can flex in their PCB-anchored base portions, which are substantially parallel to the PCB. Any bend in the distal connecting portion or in the intermediate transition portion of each terminal contact is gradual and forms an obtuse angle, thus minimizing stress concentrations. The contacts preferably are arranged in two oppositely facing and interdigitating rows of four contacts each. In one embodiment, the terminal contacts are anchored to the PCB by a contact cradle that constrains the base portion of each terminal contact at two spaced anchoring locations, allowing the base portion to flex therebetween. In another embodiment, the base portions of the terminal contacts are embedded in at least one elastomeric member, which is fitted to the PCB.

Abstract: A multi-port telecommunications connector panel has an electrically conductive housing that defines a plurality of ports, each with a plug receiving cavity aligned with a respective set of jack contacts. The housing surrounds the sets of jack contacts individually and collectively to separate and isolate adjacent ports. Electrically conductive isolation barriers, which are electrically connected to and may be integral with the housing, separate adjacent sets of insulation displacement contacts, which are arranged in an offset pattern.