A rechargeable cleaner includes a body, a rechargeable battery, a charger, and a body controller. The body is configured to generate suction power capable of sucking dust together with air using a motor. The rechargeable battery is configured to supply electric power to the motor. The charger is configured to charge the battery. The body controller is disposed in the body. The body controller controls at least one of a charging current and a charging voltage based on cell voltage information indicating a cell voltage, cell temperature information indicating a cell temperature, and battery identification information for identifying the battery that are acquired from the battery, and based on charger identification information for identifying the charger acquired from the charger.

A vehicle-roadway interface for power and data exchange with roadway sensors system used along a road surface for use with at least one vehicle, with the system comprising at least one active vehicle-based adapter removably mounted to the at least one vehicle and a plurality of passive roadway-based beacons affixed to or within the road surface. The system utilizes an innovative transmitted power system that allows the vehicle-based adapter to provide power to each of the roadway beacons whenever the equipped vehicle passes within proximity of the roadway beacon, while the vehicle is normally traveling along the roadway. Each of the roadway-based beacons communicates in real time with the vehicle-based adapter to detect, collect, transmit, and receive information concerning at least temperature conditions, moisture conditions, lane management, traffic management, record-keeping of passing vehicles, and high-fidelity geographic location coordinates.

An energy harvesting device may include a hub structure configured to rotate about an axis. The energy harvesting device may further include a first arm. The first arm may include a hinge connecting a first proximal end of the first arm to the hub structure. The first arm may further include a first weight coupled to a first distal end of the first arm. The energy harvesting device may include a second arm. The second arm may include a second hinge connecting a second proximal end of the second arm to the hub structure. The energy harvesting device may further include a second weight coupled to a second distal end of the second arm.

A power supplying device comprising a battery, a charging circuit and a DC-AC conversion circuit is provided. The charging circuit is electrically coupled to an AC power source and configured to charge the battery. The DC-AC conversion circuit is electrically coupled to the battery and configured to supply an AC output. When the power supplying device is powered on, both of the charging circuit and the DC-AC conversion circuit are enabled.

Power allocation in printing devices is disclosed. Independent load requests are received from printing device heater systems. A first load request is received from a first heater system and a second load request is received from a second heater system. Power grants are allocated based on a general power arbitration of a power source in response to the independent load requests. The power grants include a first power grant based on the first load request and a second power grant based on the second load request. The power grants are adjusted based on a contextual printing condition. The power grants are adjusted to apportion a measure of the second power grant to the first power grant rather than provide the measure of the second power grant to the second heater system if a print substance density is outside a selected print substance density threshold.

A system for providing power to more than one ultrasonic welding probe from M power supplies includes N multipoint units and a base. Each of the N multipoint units includes: a housing, a plurality of analog or digital inputs configured to carry distance information regarding probe distance of a plurality of ultrasonic welding probes, a dedicated high voltage input connector connectable via a high voltage cable to a dedicated high voltage output connector of one of the M power supplies, and a microcontroller. The microcontroller is configured to: direct power from the dedicated high voltage input connector to a corresponding one of the plurality of ultrasonic welding probes, and sample the distance information of the plurality of ultrasonic welding probes at a rate of at least once per millisecond. The base houses the M power supplies, wherein M and N are both integers greater than or equal to 1.

Techniques for implementing a fault-tolerant power supply are described. In an example, a system converts an alternating-current (AC) voltage to an initial direct current (DC) voltage. The system further converts the initial DC voltage to a first DC voltage and a second DC voltage. The system applies the first DC voltage to a high-priority device such as a metrology device. The system applies the second DC voltage to a low-priority or peripheral device. When the initial DC voltage is outside a voltage range, the system deactivates the second DC voltage to the lower-priority device and maintains the first DC voltage to the metrology device.

A device charger is provided. The device charger includes: a faceplate having an electrical outlet-sized aperture therethrough, the faceplate comprising an electrical circuit; a first body extending from a rear side of the faceplate, the first body comprising an AC-to-DC power supply; a second body extending from the rear side of the faceplate, the first body and the second body including respective electrical contacts located to electrically contact one or more respective electrical outlet terminals, the respective electrical contacts configured to provide alternating current from the terminals to an AC input of the power supply at least partially via the electrical circuit of the faceplate; and at least one electrical connector, located at a front side of the faceplate, connected to a DC output of the power supply, the at least one electrical connector for providing DC power to an external device connected thereto.

A system and method for providing power to a down hole electrical submersible pump, the system including but not limited to a first 260 kVA drive module and a on a second 260 kVA drive module; a substantially optimized sine wave filter on the load side of the drive; and two harmonic filters, a first one on a first harmonic filter integrated into a first 260 kVA drive module and a second harmonic filter on a second 260 kVA.

Protection system for limiting the impact of disruptions of an external urban or industrial electrical network on a local electrical network of a site which is connected to the external network and which includes at least one local electric power source, referred to as local source connected to the local network and capable of injecting the surplus electric power into the external network, with the protection system including a synchronous machine connected to the local network which is itself connected to the external network by way of a choke, referred to as network choke. The protection system includes at least a local choke which is associated with the local source and which is connected to the local network between this local source and the synchronous machine.