Abstract: An apparatus and a method for transferring data and energy over network units of a defined network. The apparatus has at least two units, a bus coupling the units with a receive line and a transmit line and a bus control device coupled with the bus, the bus control device having first means for controlling the transfer of data defined by the defined network as data voltage signals over the transmit line and over the receive line, second means for charging the data voltage signals on the transmit line with first supply voltage signals adapted for voltage supply of units of a first plane system, and third means for charging the data voltage signals on the receive line with second supply voltage signals adapted for voltage supply of units of a second plane system.

Abstract: An automotive vehicle capable of receiving power from a power distribution circuit including a power line and return line includes a controller disposed within the vehicle. The controller is configured to be electrically connected with the power distribution circuit, determine a difference between a resistance of the power line and a resistance of the return line, and control a current flow through the distribution circuit based on the determined difference.

Abstract: The integrated power system provides for the integration of multiple sources of power for powering a vehicle accessory. The integrated power system provides a power sharing connection which provides for a balance of the load current demanded by the vehicle accessory. As a result, excessive engine loading is avoided.

Abstract: A supply system for supplying in a contact-free manner electrical energy and data signals to a subscriber module, including a support member, a supply bar mounted on the support member, which supply bar supports primary energy and data interfaces, and at least one bus subscriber module mounted on the support member, which bus subscriber module includes secondary energy and data interfaces arranged adjacent and spaced from the primary energy and data interfaces, respectively, whereby electrical energy and data signals supplied to the primary interfaces are transmitted in a contact-free manner to the secondary interfaces, respectively. Preferably the support member is a mounting rail having an inverted top-hat configuration, with the supply bar being mounted longitudinally in the space defined by the horizontal bottom and vertical side walls of the mounting rail.

Abstract: The invention relates to a method for securing the operation of a voltage-holding device used for starting or restarting the internal combustion engine of a vehicle, the voltage-holding device being electrically connected by a multiplex network to an electric machine and to a monitoring computer. According to the method, the voltage-holding device can be activated only if it has previously received an activation authorization message, which can be a starting or restarting message, sent by the computer to the electric machine and to the voltage holding device, or a message transmitted by the electric machine indicating that it is about to restart the internal combustion engine.

Abstract: A voltage supply unit for providing an adaptive voltage supply to a consumer in a means of transport, wherein the voltage supply unit comprises a voltage output device and an output control device. The output control device and the voltage output device are designed to set an output voltage of the voltage supply unit adaptively in a consumer-dependent manner.

Abstract: A system for omni-orientational wireless energy transfer is described. A transmitter unit has a transmitter resonator with a coil that is configured to be coupled to a power supply to wirelessly transmit power to a receiver unit. A receiver unit has a receiver resonator with a coil coupled to a device load. At least one of the resonators is a non-planar resonator that spans a non-degenerate two-dimensional surface having at least one concave portion.

Abstract: A power generation system includes power generating modules, and a module fixing device configured to fix the power generating modules. Each power generating module includes a power generating module body including a power generator that generates DC energy, and a power transmitter attached to the power generating module body. The power transmitter includes an oscillator that converts the DC energy into RF energy with a frequency f0, and a power transmitting antenna that transmits the RF energy as a resonant magnetic field. The module fixing device includes a first fixing member configured to fix the power generating modules, power receiving antennas each of which receives at least a part of the RF energy transmitted by the corresponding power transmitting antenna, and a second fixing member configured to fix the power receiving antennas. The respective outputs of the power receiving antennas are combined in parallel by the combining section.

Abstract: The invention concerns a PV system in which a multitude of PV modules are interconnected to PV generators. Each of the PV modules comprises a network interface for transmitting module-specific data to a control device and analyzing the same. The data network is designed as a self-organizing network, in particular as a self-organizing meshed radio network.

Abstract: An induction type power supply system with synchronous rectification control for data transmission is disclosed to include a supplying-end module with a supplying-end coil and a receiving-end module with a receiving-end coil for receiving power supply from the supplying-end coil and providing a feedback data signal to the supplying-end coil during power supply transmission subject to the operation of a rectifier and signal feedback circuit of the receiving-end module that breaks off electric current transiently to change the load characteristics of the receiving-end coil, assuring a high level of data signal transmission stability and a high level of power transmission efficiency.

Abstract: In one embodiment, a solar array system is described. The example solar array system is prefabricated as a single unit. The solar array system includes a plurality of solar panels. The solar panels of the plurality of solar panels are configured to be electrically connected to one another. At least one solar panel of the plurality of solar panels is electrically connected to a mini-inverter. The mini-inverter is configured to perform maximum power point tracking (MPPT) and apply a load to at least one solar panel of the plurality of solar panels. The mini-inverter is also configured to convert direct current (DC) power generated by the plurality of solar panels to alternating current (AC) power. The solar array system further includes a plurality of locking hinges. The locking hinges are configured to allow the plurality of solar panels to be folded on top of one another.

Abstract: The present disclosure discloses an energy harvest system converting an AC source provided by an energy harvester to a desired voltage. The AC source is boosted to the desired voltage by a bi-directional booster converter comprising fourth controllable transistors configured in an H-bridge, and stored by a storage capacitor. The desired voltage is then used to power various loads.

Abstract: A wireless power feeder 116 feeds power from a feeding coil L2 to a receiving coil L3 by wireless based on a magnetic field resonance phenomenon between the feeding coil L2 and receiving coil L3. A power transmission control circuit 200 supplies AC current at a drive frequency fo to the feeding coil L2. The feeding coil L2 outputs AC power in substantially a non-resonant state with respect to circuit elements on the power feeding side. Then, power is supplied to a receiving coil circuit 130 by a magnetic field resonance between the feeding coil L2 and receiving coil L3.

Abstract: A wireless power feed system with high transfer efficiency of electric power is disclosed. The wireless power feed system includes a power feeding device and a power receiving device, wherein the power feeding device includes a first electromagnetic coupling coil that is connected to an AC power source via a directional coupler; a first resonant coil; a switch connected to the opposite ends of the first resonant coil; a control circuit which conducts switching on/off of the switch based on a parameter of an amplitude of a reflective wave detected by the directional coupler; and an analog-digital converter provided between the first electromagnetic coupling coil and the control circuit; and the power receiving device includes a second resonant coil; and a second electromagnetic coupling coil, and wherein the first electromagnetic coupling coil is provided between the first resonant coil and the second resonant.

Abstract: A direct feeding apparatus for impedance matching of a wireless power transmission device includes a helical type resonator, and a feeding unit configured to directly feed power to a region having a relatively small current value as compared to a center of a conductive line of the resonator.

Abstract: A power supply apparatus includes a converter to convert AC power into DC power, an SMPS to convert the DC power into DC powers desired by loads, a capacitor to interconnect the converter and the SMPS, a PTC element connected to the converter, a first switch connected in parallel with the PTC element, and a second switch connected in series with the first switch. The method includes turning on the second switch to start charging of the capacitor, turning on the first switch to charge the capacitor to a target voltage level, and turning off both the first switch and second switch if a voltage across the capacitor rises over the target voltage level, to discharge the voltage across the capacitor so as to lower the voltage across the capacitor to the target voltage level or lower.

Abstract: According to one embodiment, there is provided a power-fluctuation reducing apparatus in a power generation system to control a converter connected to the power generation system and connected to secondary batteries. The power-fluctuation reducing apparatus includes adjusting direct current voltages output from the secondary batteries, respectively, detecting the directing current voltages output from the secondary batteries, respectively, controlling to adjust the direct current voltages output from the secondary batteries to make the direct current voltages uniform, based on the detected direct current voltages, and controlling the converter to reduce power fluctuations in the power generation system.

Abstract: In an embodiment, a voltage amplifier is provided. In this voltage amplifier, a DC/DC boost converter converts an input DC voltage to an output DC voltage, which is higher than the input DC voltage. A DC/AC converter connected to the DC/DC boost converter converts the output DC voltage to an AC pulse-train. A voltage multiplier connected to the DC/AC converter converts the AC pulse-train to an amplified output DC voltage that is higher than the AC pulse-train. A discharger connected to the voltage multiplier can discharge the amplified output DC voltage.

Abstract: The present invention addresses the problem of avoiding that wind turbine voltage levels within a wind power plant do not exceed predetermined overvoltage and/or undervoltage protection levels. In particular, the present invention relates to shifting of an output voltage level of a wind power plant in order to protect an internal power plant grid against overvoltages.

Abstract: A power feeding apparatus, power receiving apparatus, wireless power feeding system, and method for wireless transfer of power are provided. The power feeding apparatus includes an impedance detector, a controller, a power transmitter, a variable matching circuit, and a signal transmitter. The controller is configured to provide first control information and second control information based on an impedance detected by the impedance detector. The power feeding apparatus' variable matching circuit is configured to change a variable diameter of a power feeding coil according to the first control information. The power receiving apparatus includes a power receiver, a signal receiver, and a variable matching circuit. The power receiving apparatus'variable matching circuit is configured to change a variable diameter of a power feeding coil according to the second control information provided by the power feeding apparatus.