Abstract: A cable-retention device assembly includes a first assembly portion and a second assembly portion. The first and second assembly portions include a platform and a plurality of assembly joints. Each assembly joint includes a nose forming a terminal end, first and second interfacing sides extending from the platform to the nose, and a tunnel running through the assembly joint from the first interfacing side to the second interfacing side. Assembly joints of the first assembly portion are sized and shaped to cooperatively interface with assembly joints of the second assembly portion, such that tunnels of each plurality of assembly joints collectively define a cable-routing channel when the first and second assembly portions are mated. A cable is routable through the cable-routing channel to prevent separation between the first and second assembly portions.

Abstract: A connection arrangement for a floor power distribution system is provided herein. The connection arrangement includes a hub arrangement having a hub housing and an electrical connector. The hub housing is configured to abut a floor. The connection arrangement also includes a door module having a lower portion configured to abut the floor, a raised portion configured to engage the hub housing of the hub arrangement, and a door that is movable between a closed position to prevent access to the electrical connector and an open position to allow access to the electrical connector.

Abstract: Claimed by the inventions is a cable tray (23, 140) comprising a first part (51) constituting one piece having a uniform thickness, the first part (51) forming at least a first support surface (52) of a first accommodation (53) for the plurality of cables (54), the first part (51) having a plurality of first through holes (15) formed by a first plurality of edges (19) in the first part (51), wherein at least a part of each said edge (19) protrudes and is directed with an angle away from the support surface (52) of the first accommodation (53), where 45°<?<180°. Also a method of manufacturing such a cable tray is claimed by the invention.

Abstract: A cable routing structure includes a plurality of cables that are superposed on one another and that are movable relatively to one another in length directions thereof, and a line length difference housing case that contains parts of the plurality of cables and is movable in a reciprocating direction. The line length difference housing case absorbs differences in line length among the plurality of cables generated in accordance with a moving position of the line length difference housing case.

Abstract: A cable connector is provided for coupling to and mounted within the internal cavity of an electrical box for securing an electrical cable passing through an opening in the electrical box. The cable connector includes a housing having a first end positioned next to or adjacent the cable opening in the electrical box and a second end spaced from the first end and the cable opening. At least one and typically two cable retaining members are positioned in the cable opening of the housing between the front wall and the rear wall. The cable retainer has a body with a plurality of retaining arms extending into an axial passage of the body for gripping the outer surface of a cable.

Abstract: A clip is used to manage cords. The clip features a containment sleeve with a portion thereof being open, thereby forming a gap for passage into the sleeve, and extending outward as two opposing flanges. A cord is passed through the gap so as to reside in the sleeve and the flanges are used to interface with a rigid wire found in the environment of the cord. The clip has particular use in wire-constructed merchandizers and other such structures and for managing cords to provide power for lighting and other display enhancement devices.

Abstract: A remote display system including a portable display that wirelessly receives data and power from a primary station. The primary station, which is remote from and without a tangible connection with the portable display, includes a data transmitting element and a power transmitting element. The portable display includes a power receiving element that receives power wirelessly from the power transmitting element and a data receiving element operable to receive data from the data transmitting element.

Abstract: A device (1) covers the connection point (10) between two elongate, electrically conductive components (11, 12) in a moisture-tight manner. The device has a tubular sleeve (2) that surrounds the connection point (10). In the mounted position, a sealing element (3, 4) is attached to each of the two axial ends of the sleeve (2), which sealing element closes the sleeve (2) and lies tightly against the wall of the sleeve and has a feed-through (13, 14) for one of the electrically conductive components (11, 12), which feed-through is matched to the shape of the electrically conductive component (11, 12) in such a way that said electrically conductive component is tightly surrounded. In the mounted position, a cover (5, 6) that encompasses the sleeve and the sealing element (3, 4) located in the sleeve is attached to each of the ends of the sleeve (2), which cover has a feed-through (15, 16) for one of each of the electrically conductive components (11, 12).

Abstract: The present invention provides a protection device which includes a laminar element 16 which is formed of an insulation resin and has at least one throughhole; electrically conductive metal thin layers 22 and 28 which are positioned on each of main surfaces of the laminar element, and a fuse layer 40 which is positioned on a side surface defining said at least one throughhole and electrically connects the electrically conductive metal thin layers. The fuse layer includes a first metal layer 41 consisting of a metal having a higher melting point and a second metal layer 42 consisting of a metal having a lower melting point. The protection device of the present invention allows a larger amount of a current to flow therethrough and can provide a protection from an excessive current.

Abstract: An apparatus with load dump protection incorporates first and second half-bridge circuits, first and second comparators, and first and second clamping circuits. The first comparator compares a supply voltage with a first set voltage and generates a first comparison signal while the supply voltage exceeds the first set voltage. The second comparator compares the supply voltage with a second set voltage and generates a second comparison signal while the supply voltage exceeds the second set voltage. The first clamping circuit divides the supply voltage and provides a divided voltage to the first half-bridge circuit in response to the second comparison signal. The second clamping circuit divides the supply voltage and provides a divided voltage to the second half-bridge circuit in response to the second comparison signal.

Abstract: A power generation system includes a generator operatively coupled to an engine for generating electrical power and supplying the electrical power to a grid. Further, the power generation system includes a resistive braking system operatively coupled between the generator and the grid. The resistive braking system includes a mechanical switch connected in parallel with a resistor, and a controller for, in response to a grid event, controlling power from the engine and operating the mechanical switch to redirect current between the mechanical switch and the parallel connected resistor.

Abstract: An inrush current control device for an IC chip having multiple functional units and M power switches comprises a programmable counter unit, a selector unit and an enable signal driving unit. The programmable counter unit counts a clock signal and sets a predetermined counting value. The selector unit is connected to the programmable counter unit and has N output ports for outputting N enable signals. The enable signal driving unit has N enable driving circuits correspondingly connected to the N output ports of the selector unit, and controlling on/off states of N groups of the M power switches. The programmable counter unit controls the selector unit to output the N enable signals to the N enable signal driving circuits at a predetermined time interval determined by the predetermined counting value to switch on the N power switches groups successively to reduce the transient inrush current.

Abstract: A driver circuit comprises a mains input and a switch mode power converter for delivering an output derived from the mains input by switching using a pulse width modulation signal. The switch mode power converter comprises a pulse width controller for controlling the pulse width of the pulse width modulation signal. A monitor is used for monitoring the pulse width of the pulse width modulation signal and for detecting a surge event from the pulse width, wherein the monitor is for detecting the surge event from changes in the pulse width and/or duty cycle over time, and comprises a monitor circuit for detecting a surge event based on the pulse width and/or duty cycle reducing to correspond to a first pulse from a second pulse, remaining at the first pulse for a time period falling within a first threshold range and then returning to the second pulse, wherein the width of the first pulse is narrower than the second pulse.

Abstract: A protection device for connection to a power bus of an electrical power system includes a bidirectional clamping apparatus configured to conduct current when a voltage across the bidirectional clamping apparatus is more positive than a positive voltage standoff and when the voltage across the bidirectional clamping apparatus is more negative than a negative voltage standoff; and a control element in series with the bidirectional clamping apparatus, the control element and the bidirectional clamping apparatus providing a current path across the power bus when a magnitude of a voltage on the power bus exceeds a positive voltage threshold or a negative voltage threshold, the positive voltage threshold being greater than the positive voltage standoff of the bidirectional clamping apparatus and the negative voltage threshold being more negative than the negative voltage standoff of the bidirectional clamping device.

Abstract: A power supply apparatus is provided that has a plurality of secondary batteries connected in series, outputs a composite voltage of all of the secondary batteries, and outputs an output of a part of the secondary batteries as a partial voltage. The power supply apparatus includes a detecting unit that detects states of the secondary batteries, a changing unit that changes an order of series connection of the plurality of secondary batteries based on a detection result of the detecting unit in such a manner that the partial voltage is outputted from a secondary battery that is in a relatively good state.

Abstract: An antenna-based modular power system includes a prime power supply configured to generate a first alternating current (AC) power signal having a first AC voltage level. At least one transformer is configured to convert the first AC signal into a second AC signal having a second AC voltage level less than the first AC voltage level. At least one Transmit or Receive Integrated Microwave Module (T/RIMM) dual power converter antenna array is in signal communication with the at least one transformer. The at least one T/RIMM dual power converter antenna array includes at least one load, and an AC/DC converter is embedded therein to convert the second AC signal into a DC power drive signal to energize the at least one load.

Abstract: A device (10) for the electric power supply of a load (11), includes at least two energy storage elements (13, 14), elements for determining the power needs of the load (11), elements (16, 17) for monitoring each energy storage element (13, 14), which are able to provide information about a maximum instantaneous power of each energy storage element (13, 14), a calculation body (19) for determining a maximum secured power according to the electromotive force (Ebat(t)) and the resistance (Rbat(t)) of the Thévenin model, a maximum specified current and a maximum specified voltage, and elements (Cbat(t), Csc(t)) for controlling each energy storage element (13, 14), the elements being adjusted over time according to the power needs of the load (11) and the maximum secured power of each energy storage element (13, 14).

Abstract: An electric apparatus according to an embodiment includes a plurality of connection devices connectable to a plurality of external power supplies; a battery; a charge circuit to charge the battery using electric power supplied from the external power supplies; a plurality of switch sections each connected between the connection devices and the charge circuit; a storage section to store therein a priority degree for supplying power to the battery for each power supply type of the external power supplies; and a controller to control power supply from the external power supplies to the charge circuit. The controller detects power supply types of the external power supplies connected to the connection devices, and compares priority degrees corresponding to the power supply types detected and switches off the switch sections of the connection devices that are connected to the external power supplies except an external power supply having a highest priority degree.

Abstract: A control system (300) allows recognized standard premise electrical outlets, for example NEMA, CEE and BS, among others to be remotely monitored and/or controlled, for example, to intelligently execute blackouts or brownouts or to otherwise remotely control electrical devices. The system (300) includes a number of smart receptacles (302) that communicate with a local controller (304), e.g., via power lines using the TCP/IP protocol. The local controller (304), in turn, communicates with a remote controller (308) via the internet.

Abstract: Electrical power is dynamically managed among one or more power sources and one or more loads. A plurality of monitor nodes is connected to an input terminal connected to each source, and to an output terminal connected to each load. A plurality of electrical power storage cells is connected among the input and output terminals, each cell being capable of storing power from at least one of the sources and being capable of discharging stored power to at least one of the loads. A plurality of controllable switches is connected to the cells. A programmed controller dynamically monitors operating conditions at the monitor nodes during operation of each source and each load, and selectively dynamically controls the switches to interconnect the cells in different circuit topologies in response to the monitored operating conditions.

Abstract: A total harmonic distortion (THDi) reduction circuit for a power factor correction (PFC) controller to control a PFC stage. The THDi reduction circuit determines whether an input signal, such as an alternating current (AC) line voltage is a high voltage or low voltage signal. For a high voltage input signal, the THDi reduction circuit may limit the duty cycle of a control signal to a PFC stage to minimize a voltage spike at the zero-crossing point of the input signal and thereby minimize THDi. For a low voltage input signal, the THDi reduction circuit may extend the duty cycle of the control signal to the PFC stage, while ensuring that the control signal has at least a predetermined off-time, i.e. the duty cycle is less than 100 percent. Extending the control signal duty cycle, especially for low voltage input signals under high load, may minimize THDi.

Abstract: An apparatus may control the power delivered from an AC power source to an electrical load, and may comprise a controllably conductive device. The apparatus may also comprise a controller that may be operatively coupled to a control input of the controllably conductive device. The apparatus may also include a first wireless communication circuit operable to communicate via a first protocol and to join a first wireless communication network operable to communicate via the first protocol. The first wireless communication circuit may be in communication with the controller. The controller may be operative to determine a first condition for communicating via the first protocol. The controller may also be operable to control the first wireless communication circuit to join the first wireless communication network upon the first condition being satisfied.

Abstract: Systems, methods, and devices relating to inverters. A control system for use with photovoltaic panel coupled inverters controls the function and operation of the inverter based on the voltage at the point of common coupling. The inverter is operated in either current control mode or in voltage control mode based on whether or not the inverter is coupled to a grid or whether other energy sources are available to control the voltage at the point of common coupling.

Abstract: A device, system, and method for global maximum power point tracking comprises monitoring an output power of a DC power source while executing a maximum power point tracking algorithm and adjusting a maximum power point tracking command signal in response to the output power being less than a reference output power. The command signal is adjusted until the output power exceeds a previous output power by a reference amount. The command signal may be a voltage command signal, a current command signal, an impedance command signal, a duty ratio command signal, or the like.

Abstract: A multi-farm wind power dispatch management system is provided which includes wind turbine dispatch controllers for controlling wind power dispatch of respective wind farm components and wind farm dispatch management systems for receiving respective wind farm component operating parameters and generating respective farm-level operating parameters. The system also includes group dispatch management systems for receiving the farm-level operating parameters and generating respective group level operating parameters.

Abstract: Power rail control systems that include power multiplexing circuits that include cross-current conduction protection are disclosed. Power multiplexing circuit includes supply selection circuits each coupled between a respective supply power rail and an output power rail coupled to a powered circuit. To maintain power to the powered circuit during switching coupling of the output power rail, but while also avoiding current cross-conduction path between supply power rails, diode drop control circuits are provided in supply selection circuits. In diode drop operation mode, the diode drop control circuit associated with a higher voltage supply power rail is configured to regulate voltage supplied by such supply power rail to the output power rail to power the powered circuit. A current cross-conduction path is not created, because diode drop control circuits associated with lower voltage supply power rails are reverse biased to prevent current from flowing through their associated supply selection circuits.

Abstract: A wireless rail system for providing power and control to auxiliary devices on the rail is disclosed. Such a system includes a one or more channels mounted to a structural building component forming a rail. Auxiliary devices on the rail communicate with each other and user devices. Each of the auxiliary devices are addressable either wirelessly or by a parallel bus within the rail. The auxiliary devices are connected and disconnected from the rail by rotating approximately 90 degrees.

Abstract: An electrical storage system includes an electrical storage device, a voltage sensor, a current sensor and a controller. The controller calculates a full charge capacity of the electrical storage device on the basis of a state of charge of the electrical storage device at the time when external charging is started, a state of charge of the electrical storage device at the time when the external charging is completed, and an accumulated value of a current value during the period when the external charging is being carried out, and sets a polarization elimination time. When a stopped time during the period when charging or discharging of the electrical storage device is stopped is longer than the polarization elimination time, the controller regards a voltage value of the electrical storage device at the time of at least one of the start of the external charging or the completion of the external charging as an open circuit voltage of the electrical storage device.

Abstract: A power adapter and a terminal are provided. The power adapter includes a power conversion component and a charging interface, the power conversion component being configured to form a charging loop with a terminal via the charging interface for charging a battery of the terminal. The power adapter further includes a communication component and an adjustment component, the communication component is configured to receive a battery parameter sent by the terminal, the battery parameter being used for indicating at least one of a current electric quantity and a current voltage value of the battery of the terminal; and the adjustment component is configured to determine a target current value corresponding to the at least one of current voltage value and the current electric quantity of the battery, and to adjust an output current value of the power adapter to the target current value.

Abstract: A power adapter has an adapter housing, AC to DC power conversion circuitry disposed within the adapter housing, a positive power contact and a negative power contact disposed on the adapter housing and operatively connected with the power conversion circuitry, AC wall outlet prongs mounted in one of the faces and operatively connected with the power conversion circuitry, a DC power connection interface connected by a cable to the adapter housing, wherein the cable operatively connects the DC power connection interface with the power conversion circuitry; and a magnet disposed in the first face of the adapter housing. The magnet and the power contacts of the power adapter mate with corresponding magnet and power contacts of a battery unit, which also includes a battery housing and an electrolyte disposed within the battery housing.

Abstract: A charger cradle for recharging a rechargeable lighting device is described. The cradle may include two prongs that flex outwards to allow a lighting device to be inserted into the cradle. After the lighting device is fully inserted, the prongs resume a normal position to exert an inward force on the lighting device to secure it in place. The cradle may also include two moveable cradle arms, in lieu of two prongs, to allow a spring mechanism within the device to motivate the moveable cradle arms to grasp a lighting device when the lighting device is inserted into the rechargeable lighting device.

Abstract: A structure with detachable battery for an electronic device includes an electronic device casing, a guiding structure, and a sliding tongue. The electronic device casing has a chamber for receiving a battery. The guiding structure is disposed on an outer sidewall of a battery. The guiding structure includes a guiding groove. The guiding groove and the chamber are open toward each other. An engaging groove is laterally disposed in the guiding groove. The engaging groove is open in a transverse direction of the chamber. A releasing-guiding slope opposite the engaging groove is disposed in the guiding groove to extend from the opening of the guiding groove and tilt toward the engaging groove. The sliding tongue is disposed slidably on an inner sidewall of the chamber such that battery becomes fixed inside the chamber or slidably abuts against the releasing-guiding slope, thereby ejecting the battery out of the chamber.

Abstract: Methods and devices for connecting a mobile device with different data storage devices located either locally or remotely are provided. The device may apply one or more rules to create a hierarchical virtualization of the several data storage devices. The virtualization may then be provided to the user as a single, hierarchical file system. Further, a monitoring system may monitor the file system to determine if any new applications have been installed or if applications are currently being executed. If a connection is made to a secure network, the system may provide the information derived from the monitoring to the secure network. The secure network can then analyze the information to determine if any of the applications should be uninstalled from the device or should be stopped while the device is connected to the network.

Abstract: A charger device may include a coupling component configured to deliver power for charging user devices and a wireless interface configured to broadcast wireless signals. The coupling component may include a connector that may be plugged into a user device or an inductive coil to be inductively coupled to a user device. The charger device may determine whether the coupling component is coupled to a user device and transmit via the wireless interface an “available” signal indicating the charger device is available in response to determining the coupling component is not coupled. The user device may provide a notification to the user based, at least in part, on receiving the “available” signal. The user device may provide the notification further based on other information, such as activity of a user detected by the user device, a geolocation determined by the user device, or information received from a service provider.

Abstract: A system and method is described for rapid charging and power management of a battery for a meter. A charger component is operably associated with the meter and is capable of executing a rapid charge algorithm for a rechargeable battery. The algorithm includes monitoring for a connection to an external power source and implementing a charging routine of a battery at a first charge rate and then at a second charge rate. The second charge rate is lower than the first charge rate. A temperature rise in the rechargeable battery due to the first charge rate has a negligible heat transfer effect on the fluid sample. The meter can also include a power switch for controlling current flow to a battery fuel gauge. The power switch is open when the meter enters into a sleep mode. The state of battery charge is determined after the meter exits the sleep mode.

Abstract: A device and method are provided for saving power and electricity in a charging device including external power supplies and battery chargers having a primary circuit and a secondary circuit where a switch is located in the primary circuit and a current sensing device in the secondary circuit to sense when there is a drop in current in the secondary circuit or no current in the secondary circuit because the load such as a cell phone or tablet is charged and when this occurs the switch in the primary circuit is opened and the primary circuit no longer draws power from the source of power until the switch in the primary circuit is closed by either a user activating a switch to reenergize the charging device, where the switch may be powered by an on-board battery to close the primary circuit, or where a control circuit is activated by a program in the load or device to be charged, such that the charging device will cycle on and off according to an external app program residing on the device to be charged or some

Abstract: This disclosure provides a mobile terminal, a DC-charging power source adaptor, and a charging method, where firstly the DC-charging power source adaptor is configured to communicate with the mobile terminal in a UART communication mode, and then a strategy to identity the type of charging is designed in the mobile terminal dependent upon configuration of communication pins of a different charging device, so that the mobile terminal identifies automatically the type of the external device. Also a specialized rapid charging mode is designed for the DC-charging power source adaptor, the battery of the mobile terminal being charged is DC-charged at large current by charging voltage output by the DC-charging power source adaptor, and the volt value of the charging voltage is adjusted dynamically according to the varying voltage of the battery.

Abstract: A charge control circuit includes an analog to digital converter (ADC) and a control unit, wherein the ADC is arranged for monitoring a temperature of a battery and converting the monitored temperature to a digital value; and the control unit is coupled to the analog to digital converter, and is arranged for determining whether to generate a control signal to adjust a charge current or a charging voltage of a battery or not according to the digital value, and the ADC and the control unit are fully hardware architectures.

Abstract: The present disclosure provides a method for wirelessly sharing power among multiple mobile devices connected to a power sharing community network using a mobile device application. This method may provide an easy and effective way to wirelessly share power from a group of mobile devices to one or more mobile devices in need of charge, located within the same area, such as a train station, bus station, food courts, airport terminals, etc. The method may include wireless power transmission through suitable techniques such as pocket-forming.

Abstract: A wireless charging device comprises a transmitter coupled to at least one transmitting antenna and operable to cause the at least one transmitting antenna to emit electromagnetic radiation; a conductive structure adapted to confine the electromagnetic radiation to a charging zone; and a detector for detecting a degree of impedance mismatch between the transmitter and the at least one transmitting antenna. A receiver for use with the wireless charging device and a wireless charging system are also disclosed.

Abstract: The configurations of LLC charger and controlling methods thereof are provided. The proposed charger includes a transmitter-receiver (TX-RX) transformer including a TX-matrix core set (TX-MCS) and an RX-MCS, an LLC power stage electrically connected to the TX-MCS, and a rectifier electrically connected to the RX-MCS so as to charge a battery pack with a non-contact power transmission.

Abstract: A screen rack for two screens, comprising a case for electric components, whereby power supply adapters for a PC and two screens that can be installed on the screen rack are arranged in the case.

Abstract: This disclosure relates to a DC-charging power source adaptor including a charging interface, an AC to DC converting unit, and a controlling unit; and the DC-charging power source adaptor is timed to communicate with a mobile terminal which is a charging object, to acquire a change in voltage of a battery in the mobile terminal and further adjust dynamically a volt value of charging voltage output by the DC-charging power source adaptor according to the change in voltage of the battery, and DC-charges the battery in the mobile terminal using the charging voltage.

Abstract: This disclosure generally relates to a system, apparatus, and method for diagnosing a vehicle battery for further charging purposes. A battery diagnostic tool is provided to receive temperature information on the vehicle battery during a vehicle battery charging operation. The temperature information is referenced to generate a temperature gradient that will be further referenced to identify temperature changes to the vehicle battery over a period of time.

Abstract: A charging compartment adapted for use on a body of a photovoltaic panel cleaning equipment for recharging of battery power of the photovoltaic panel cleaning equipment is provided, in which the charging compartment includes a charging and stopping rack and a telescopic supporting rack. The charging and stopping rack is used for stopping a body and charging the body, and the telescopic supporting rack is used for supporting the charging and stopping rack. The charging and stopping rack and a photovoltaic panel to be cleaned are enabled and configured to be on a same plane by adjusting the angle of the charging and stopping rack. By adopting the charging compartment, the photovoltaic panel cleaning equipment is facilitated to allow the body to remain stationary while being together with the photovoltaic panels which are undergoing cleaning, as well as same time recharging battery power of the photovoltaic panel cleaning equipment.

Abstract: An uninterruptible power supply device (U1) includes a converter (40), an inverter (41), a bidirectional chopper (24), and a controller (53). The bidirectional chopper (24) includes first to fourth transistors (Q11-Q14), first to fourth diodes (D11-D14), and first and second, coils (51, 52). In a charging mode, the controller (53) causes the first and fourth transistors (Q11, Q14) to be complementarily turned on and controls the ON period of each of the first and fourth transistors (Q11, Q14) so as to cause respective detected values of first current and second current (11, 12) flowing through the first coil and the second coil (51, 52) to be equal to each other.

Abstract: Embodiments disclosed herein may generate and transmit power waves that, as result of their physical waveform characteristics (e.g., frequency, amplitude, phase, gain, direction), converge at a predetermined location in a transmission field to generate a pocket of energy. Receivers associated with an electronic device being powered by the wireless charging system, may extract energy from these pockets of energy and then convert that energy into usable electric power for the electronic device associated with a receiver. The pockets of energy may manifest as a three-dimensional field (e.g., transmission field) where energy may be harvested by a receiver positioned within or nearby the pocket of energy.

Abstract: An inductive power transfer circuit or inductive rotary joint has an inductive rotating coupler with a primary side and a primary winding rotatably arranged against a secondary side and a secondary winding. The secondary side is connected via a rectifier to a load. The stray inductance of the coupler together with a resonance capacitor a series resonance circuit having a series resonance frequency. An inverter in a full bridge circuit is provided for converting a DC input voltage into an AC voltage. The inverter is operable in a full bridge mode to deliver a high power level and in a half bridge mode to deliver a low power level. This results in a broad dynamic range, soft power on and improved safety, as switching between the modes may be controlled by a simple hardware.

Abstract: A controlling method and device for a wireless power transfer system, wherein the wireless power transfer system includes a transmitting component and a receiving component, and further includes a contactless transformer & compensation (CT&C) circuit, and the controlling method includes: obtaining positional relationship information of the transmitting component and the receiving component; adjusting the number of coil turns of the transmitting component based on the positional relationship information, and making conditions of a CT&C voltage gain characteristic and an input impedance characteristic after a charging inverter bridge of the wireless power transfer system meet a charging condition. The abovementioned technical solution can provide a protection for a stable operation of the wireless power transfer system with a non-mechanical adjusting device, and the wireless charging can be achieved without using a mechanical adjusting device to align and range.

Abstract: An electrical article with cord-free charging zone provides users in a work area with access to low-voltage charging for portable electronic devices, in which electrical current is conveyed upon placement of an electronic device within the charging zone. The electrical article is configured for use in a work area, and includes a housing, a low voltage charging zone with power unit, and an electrical power input. The charging zone is defined along at least a portion of an upper surface of the housing. The low voltage power unit is operable to cordlessly convey electrical power to a portable electrical or electronic device that is positioned at the low voltage charging zone.