Abstract: A method is provided for balancing power amongst parallel connected power converters in an uninterruptible power supply (UPS). The method includes: applying a control signal to each of the parallel connected power converters, where the control signals applied to the parallel connected power converters are derived from a common control signal output by a centralized controller; receiving measurements of current being supplied by each power converter to the load; and adjusting phase of voltage applied to at least one of the power converters based on the received current measurements, such that the phase adjustment causes same magnitude of current to flow though each filter. Advancing phase angle of the voltage increases current supplied by the at least one power converter while retarding phase angle of the voltage decreases current supplied by the at least one power converter.

Abstract: A system for generating electrical power includes engine generators positioned on a pad and housed within an enclosure. The pad may have a first side having an associated long axis and a shorter second side having an associated short axis. The short axis is transverse to the long axis. The engine generators are electrically coupled to one another in a parallel fashion. Each engine generator includes a prime mover and an alternator that are serially aligned with the short axis of the pad. The enclosure encloses the engine generators and has a plurality of side walls, a roof, and a floor. The enclosure includes at least one intake opening formed in the floor to provide airflow into an interior of the enclosure.

Abstract: A wireless power transmission apparatus includes a communicator configured to receive information associated with a reference power of a wireless power reception apparatus and information associated with a power measured at an input terminal of a direct current-to-direct current (DC/DC) converter of the wireless power reception apparatus, a controller configured to control an output power based on the information associated with the reference power and the information associated with the power measured, and a source resonator configured to transmit the output power to the wireless power reception apparatus by resonating with a target resonator.

Abstract: A power receiver includes a secondary-side resonant coil configured to receive electric power from a primary-side resonant coil; a rectifier circuit; a smoothing circuit; a DC-DC converter connected having first and second output terminals; third and fourth output terminals disposed on an output side of the DC-DC converter and connected to a secondary battery; a sub-secondary battery having fifth and sixth output terminals; a switch configured to switch connection between the first and second output terminals, the third and fourth output terminals, and the fifth and sixth output terminals; and a controller configured, when the secondary-side resonant coil starts to receive the electric power, to control the switch to respectively connect the first and second output terminals and a load or first and second input terminals of the sub-secondary battery and to respectively connect the third and fourth output terminals and the fifth and sixth output terminals.

Abstract: The present disclosure describes a methodology for wireless power transmission based on pocket-forming. The method includes a transmitter device capable of forming pockets of energy used by a receiver device to charge an electronic device such as a computers, cell phones, tablet and/or devices of the like. The method may include using an array of antennas at the transmitter to locate the position of a receiver device. The transmitter may identify the position of the device by capturing a signal from a receiving device using two subsets from the array of antennas. The subset of antennas may then be adjusted to form pockets of energy at the appropriate location of the receiving device. Previously stored data pertaining to each antenna in the array may serve to determine the proper adjustments for the entire array of antennas based on the results from the subsets used to capture the receivers signal.

Abstract: Disclosed, in one example, is an energy consumption node. The node includes a guided surface wave receive structure configured to obtain electrical energy from a guided surface wave traveling along a terrestrial medium. The node also includes a distribution system coupled to the guided surface wave receive structure and configured to distribute the obtained electrical energy to an electrical load coupleable to the distribution system.

Abstract: A load control apparatus includes: a relay control unit that outputs an open or close command; a power supply adjustment unit; a contact resistance measurement unit that measures a resistance value of the relay; and an adjustment command generation unit that outputs to the power supply adjustment unit an increase command that causes a current flowing between the contacts of the relay or a voltage applied therebetween to be a value greater than a steady-state value when the resistance value becomes greater than or equal to a predetermined threshold value, and outputs to the power supply adjustment unit a release command that returns the current flowing between the contacts of the relay or the voltage applied therebetween to the steady-state value when, after the increase command is outputted, the resistance value becomes smaller than the predetermined threshold value and the close command is received from the relay control unit.

Abstract: Disclosed is a direct current uninterruptible power supply system. The direct current uninterruptible power supply system according to an embodiment of the present invention is electrically connected to a direct current power converter for converting commercial alternating current power to direct current power, in order to: supply the direct current power to a load and charge an auxiliary power supply device therein with the direct current power. In the case of a short circuit of the direct current power converter due to a current leakage or breakage of the direct current power converter, or if the direct current power converter is disconnected, the direct current uninterruptible power supply system enables the auxiliary power supply device to constantly supply power to the load while completely blocking the electrical connection to the direct current power converter.

Abstract: The embodiments described herein include a transmitter that transmits a power waves (e.g., radio frequency (RF) signal waves) to create a three-dimensional pocket of energy. At least one receiver can be connected to or integrated into electronic devices and receive power from the pocket of energy. A wireless power network may include a plurality of wireless power transmitters each with an embedded wireless power transmitter manager, including a wireless power manager application. The wireless power network may include a plurality of client devices with wireless power receivers. The wireless power transmitter managers may receive a plurality of power transfer attributes from one or more of the wireless power receivers, client devices, a management control system, and sensors. A master transmitter manager may select at least one of the power transmitter managers to control the transmission of power waves in accordance with the plurality of power transfer attributes.

Abstract: An ECU performs a controlling process including: switching a main converter to a boost converter CNV2 when a boost converter CNV1 is set as a main converter and when a first stress value Va is greater than a second stress value Vb; switching a sub converter to the boost converter CNV1; switching the main converter to the boost converter CNV1 when the boost converter CNV1 is not set as a main converter, and when the second stress value Vb is greater than the first stress value Va; and switching the sub converter to the boost converter CNV2.

Abstract: An appliance for treating at least one item according to a cycle of operation and configured to receive power from a power source having an AC voltage line and a neutral line includes a treating chamber for receiving the item and a central control unit to control independent electrical loads associated with the cycle of operation. The central control unit includes a plurality of parallel controlled master switches in the AC voltage line and a plurality of parallel controlled slave switches in the neutral line. The master and slave switches define a number of independent loads equal to the number of the master switches multiplied by the number of the slave switches.

Abstract: In at least one embodiment, an apparatus comprising a vehicle inverter is provided. The vehicle inverter is programmed to invert a direct current (DC) input into a maximum alternating current (AC) output to power at least one external load and to receive first information indicative of whether a vehicle is in one of a drive mode and a park mode. The vehicle inverter is further programmed to provide the maximum AC output to the power the at least one external load in response to the information indicating that the vehicle is in the park mode and to invert the DC input into a first AC output that is less than the maximum AC output to power the at least one external load in response to the information indicating that the vehicle is in the drive mode.

Abstract: The present invention relates to a coil type unit for wireless power transmission, a wireless power transmission device, an electronic device, and a manufacturing method of a coil type unit for wireless power transmission. A coil type unit for wireless power transmission according to the present invention includes a coil pattern having a wiring pattern shape; a magnetic portion having the coil pattern attached to one surface thereof and a conductive pattern formed thereon; an insulating adhesive portion interposed between the magnetic portion having the conductive pattern formed thereon and the coil pattern to bond the magnetic portion and the coil pattern to each other while insulating the coil pattern and the conductive pattern from each other; and a conductive via for electrically connecting both ends of the coil pattern and the conductive pattern.

Abstract: An example method is performed at a first transmitter in communication with other power transmitters, the method including: receiving, from a respective transmitter of the other transmitters, information indicating at least (1) a network address, and (2) status information regarding whether the respective transmitter is in master or non-master mode. The method also includes, if none of the other power transmitters is in the master mode, determining whether a first network address of the first transmitter is lower than respective network addresses of the other transmitters. The method further includes: if the first network address is lower than the respective network addresses: operating the first transmitter in the master mode; and sending an indication that the first transmitter is in the master mode. While the first transmitter is in the master mode, the first transmitter assigns each of the other transmitters to transmit power waves to one or more receivers.

Abstract: A power transmission system according to an embodiment includes a transmitting device and a receiving device. The transmitting (receiving) device includes a transmitting (receiving) housing and a transmitting (receiving) coil. The transmitting (receiving) housing includes a first transmitting (receiving) surface and a second transmitting (receiving) surface. The transmitting (receiving) coil includes a first transmitting (receiving) part and a second transmitting (receiving) part. A first facing area and a second facing area at the reference position are set such that change of strength of magnetic coupling between the transmitting coil and the receiving coil of when the receiving device is moved in a direction perpendicular to the first transmitting surface becomes smaller than change of strength of magnetic coupling between the transmitting coil and the receiving coil of when the receiving device is moved in a direction perpendicular to the second transmitting surface.

Abstract: A power supply device may be capable of wirelessly transmitting power at a plurality of resonance frequencies. The power supply device may include: a power conversion unit converting input power into first power; and a wireless power supply unit varying a switching frequency for switching the first power and wirelessly transmitting the switched first power at at least one of a plurality of resonance frequencies.

Abstract: A wireless power transmitter device that includes a transmitter circuit, a transmitter coil, a transmitter communication unit and a transmitter control unit is provided. The transmitter circuit generates a transmitting current. The transmitter coil receives the transmitting current to generate an electromagnetic field to induce a receiving current in a wireless power receiver device. The transmitter communication unit is configured to receive a report of a received power of the wireless power receiver device therefrom. The transmitter control unit receives the report of the received power and determines whether a frequency splitting phenomena occurs according to the received power. When the frequency splitting phenomena occurs, the transmitter control unit adjusts at least one of a configuration of the transmitter coil and a configuration of the transmitter circuit or adjusts a transmitting frequency of the transmitting current.

Abstract: The invention relates to apparatus (40) comprising: an inductor; a rectifier coupled to the inductor; a voltage converter coupled to the rectifier; a battery coupled to the voltage converter; a load coupled to the voltage converter; and a control unit coupled to the voltage converter and arranged to cause either the battery to be charged by the rectifier, or the load to be powered by the rectifier, or the load to be powered by the battery, as a function of the state of a switch for controlling powering of the load and as a function of the output voltage of the rectifier.

Abstract: A wireless power transmission system according to the present disclosure includes: a pair of antennas, between which power is transmissible wirelessly by resonant magnetic coupling at a frequency f0, one of which is a series resonant circuit, and the other of which is a parallel resonant circuit; and a control section, which controls a transmission frequency according to the magnitude of the power being transmitted between the antennas. If the power transmitted between the antennas is greater than a reference value P1, the control section sets the transmission frequency to be a value that falls within a first level range that is higher than the frequency f0. But if the power is smaller than the reference value P1, then the control section sets the transmission frequency to be a value that falls within a second level range that is lower than the first level range.

Abstract: A boat is disclosed. The boat includes an electrical storage having a storage element electrically connected to a positive and a negative pole. The boat also includes a water sensor configured to determine whether one of the poles is in contact with water, and a disconnection device operatively connected to the water sensor and configured to interrupt the electrical connection between at least one of the poles and the storage element when the water sensor determines that one of the poles is in contact with water.