Patent application number | Description | Published |
20120146431 | Power Transfer System and Noncontact Charging Device - A power transfer system includes a power transmission device and a power reception device. A central conductor and a peripheral conductor are formed near the upper surface of a casing of the power transmission device. The peripheral conductor surrounds the central conductor in an insulated state from the central conductor. An alternating voltage generating circuit is provided for the power transmission device and applies an alternating voltage between the central conductor and the peripheral conductor. A central conductor and a peripheral conductor are formed near the lower surface of a casing of the power reception device. The peripheral conductor surrounds the central conductor in an insulated state from the central conductor. A load circuit is provided for the power reception device, and a voltage induced between the central conductor and the peripheral conductor is applied to the load circuit. | 06-14-2012 |
20120146574 | Power Transfer System and Noncontact Charging Device - A power transfer system includes a power transmission device, a power reception device and a capacitive coupling conductor. A high-voltage side conductor is formed near the upper surface of a casing of the power transmission device, and a low-voltage side conductor is formed near the lower or surrounding surface of the casing. The power transmission device includes an alternating voltage generating circuit. A high-voltage side conductor is formed near the lower surface of a casing of the power reception device, and a low-voltage side conductor is formed near the upper surface of the casing of the power reception device. The power reception device includes a load circuit. The high-voltage side conductors are capacitively coupled to each other when facing each other, and the low-voltage side conductors are capacitively coupled to each other via a capacitive coupling conductor. | 06-14-2012 |
20120181980 | Power Transfer System and Noncontact Charging Device - A high-voltage side conductor is formed near the upper surface of a power transmission device, and a low-voltage side conductor is formed near the lower surface of the power transmission device. The power transmission device includes an alternating voltage generating circuit. A high-voltage side conductor is formed near the lower surface of a power reception device, and a low-voltage side conductor is formed near the upper surface of the power reception device. The power reception device includes a load circuit. When the high-voltage side conductors face a capacitive coupling conductor of an auxiliary sheet, capacitances are generated respectively between the high-voltage side conductors and the capacitive coupling conductor. Thus, the high-voltage side conductors are capacitively coupled to each other via the capacitive coupling conductor. | 07-19-2012 |
20120286583 | Power Transmitting Device, Power Receiving Device, and Power Transmission System - A power transmission system that includes a power transmitting device and a power receiving device. The power transmitting device includes a high-frequency voltage generator, a piezoelectric resonator, a power transmitting device side passive electrode, and a power transmitting device side active electrode. The power receiving device includes a piezoelectric resonator, a load, a power receiving device side passive electrode, and a power receiving device side active electrode. The active electrode of the power transmitting device and the active electrode of the power receiving device are in proximity with each other, whereby the power transmitting device and the power receiving device are capacitively coupled through the active electrodes and the surrounding dielectric medium. | 11-15-2012 |
20120286742 | Power Reception Device and Power Transmission Device - A power reception device and a power transmission device which are capable of suppressing an adverse effect of an electric field. A power reception device includes a capacitive coupling electrode comprising a high voltage side conductor and a low voltage side conductor extending around the high voltage side conductor. The high voltage side conductor is disposed on a surface of a housing. The low voltage side conductor is disposed inside a circuit board. A plurality of module parts are mounted on a surface of the circuit board which is located on an opposite side away from the high voltage side conductor with respect to the low voltage side conductor. | 11-15-2012 |
20120299392 | Power Transfer System - The frequency generated by a high-frequency high-voltage generator is set to a higher one of the frequencies of two coupled modes which take place when a resonance circuit of a power transmission device and that of a power reception device are coupled to each other. For this reason, charge generated on an active electrode of the power transmission device and that generated on an active electrode of the power reception device have the same polarity, while an electric potential of a passive electrode of the power transmission device and that of a passive electrode of the power reception device have the same polarity. When the passive electrode of the power transmission device is connected to the ground, the electric potential of the passive electrode is zero V. Therefore, the electric potential of the passive electrode of the power reception device is substantially zero V. | 11-29-2012 |
20120299397 | POWER TRANSMISSION DEVICE AND POWER TRANSFER SYSTEM - A power transmission device that includes a high-frequency high-voltage generating circuit which applies a high voltage of high frequency between a power transmission device side active electrode and a power transmission device side passive electrode, the power transmission device side passive electrode being disposed in a manner to surround the power transmission device side active electrode and the high-frequency high-voltage generating circuit. An auxiliary high-frequency high-voltage generating circuit is provided between a ground of the power transmission device having a potential substantially equal to the ground potential and the power transmission device side passive electrode. The auxiliary high-frequency high-voltage generating circuit suppresses a potential change of the power reception device side passive electrode relative to the ground potential. | 11-29-2012 |
20130002048 | HIGH-FREQUENCY POWER DEVICE, POWER TRANSMISSION DEVICE, AND POWER TRANSFER SYSTEM - A power transfer system includes a power transmission device and a power reception device which are capacitively coupled to allow electrical conduction therethrough in the manner of alternating current. The power transmission device includes an active electrode, a passive electrode, a step-up transformer, and a high-frequency voltage generating circuit. The power reception device includes an active electrode, a passive electrode, and a load circuit. A divider for voltage division based on load capacitances (C | 01-03-2013 |
20130187479 | ELECTRIC POWER TRANSMISSION SYSTEM AND POWER TRANSMISSION DEVICE USED IN THE ELECTRIC POWER TRANSMISSION SYSTEM - An electric power transmission system that includes a power receiving device having a first coupling electrode and a power transmission device having a second coupling electrode, both the devices being coupled via an electrostatic field, and the power transmission device configured to transmit electric power to the power receiving device in a noncontact state. The power transmission device includes a third coupling electrode that is disposed at a distance from the second coupling electrode. The third coupling electrode has a potential higher than that of the second passive electrode and lower than that of the second active electrode. | 07-25-2013 |
20130270922 | POWER TRANSMITTING DEVICE AND POWER TRANSMISSION SYSTEM - A casing of a power transmitting device is provided with a power transmitting device side passive electrode, a power transmitting device side active electrode, and a power transmitting module. A jacket mounted on a terminal is provided with a power receiving device side passive electrode, a power receiving device side active electrode, a power receiving module, and a DC-DC converter. A heat sink portion with fins is formed on a portion of the power transmitting device side passive electrode. When the terminal is mounted on the power transmitting device, the power receiving device side passive electrode is electrically connected to the power transmitting device side passive electrode, and the power receiving device side active electrode faces the power transmitting device side active electrode. In this state, the heat of the power receiving module and the DC-DC converter is dissipated from the power transmitting device side passive electrode. | 10-17-2013 |
20140009002 | POWER TRANSMISSION SYSTEM AND POWER RECEIVING APPARATUS - A piezoelectric transformer includes capacitance elements, an inductance element, a resistance, and an ideal transformer. A first resonance circuit includes the piezoelectric transformer, the capacitance of a capacitance element of a coupling electrode of a power receiving apparatus, and the capacitance of a capacitance element of a coupling electrode of a power transmitting apparatus. On the other hand, a second resonance circuit includes an equivalent output capacitance of the piezoelectric transformer and an inductance element. The frequency of a high-frequency high voltage that is generated by a high-frequency high-voltage generating circuit is set to a value between two resonance frequencies generated by a complex resonance of the first resonance circuit and the second resonance circuit. | 01-09-2014 |
20140028114 | POWER TRANSFER SYSTEM AND NONCONTACT CHARGING DEVICE - A power transfer system includes a power transmission device and a power reception device. A central conductor and a peripheral conductor are formed near the upper surface of a casing of the power transmission device. The peripheral conductor surrounds the central conductor in an insulated state from the central conductor. An alternating voltage generating circuit is provided for the power transmission device and applies an alternating voltage between the central conductor and the peripheral conductor. A central conductor and a peripheral conductor are formed near the lower surface of a casing of the power reception device. The peripheral conductor surrounds the central conductor in an insulated state from the central conductor. A load circuit is provided for the power reception device, and a voltage induced between the central conductor and the peripheral conductor is applied to the load circuit. | 01-30-2014 |
20140152122 | WIRELESS POWER TRANSMISSION SYSTEM, POWER TRANSMITTING DEVICE, AND POWER RECEIVING DEVICE - In a power transmitting device constituting a wireless power transmission system, a voltage generating circuit applies a voltage between an active electrode and a passive electrode. In a power receiving device, a voltage generated between an active electrode that is opposed to the active electrode, and a passive electrode that is opposed to or brought into contact with the passive electrode when the power receiving device is placed on the power transmitting device is inputted to a load circuit as a power supply voltage. Passive electrodes of the power transmitting device are provided to electrostatically shield the opposed active electrodes with respect to the earth. Consequently, a wireless power transmission system, a power transmitting device, and a power receiving device are configured so the potential of the power transmitting device and the power receiving device during power transmission is stabilized to thereby prevent malfunction of the power receiving device. | 06-05-2014 |
20140159852 | TRANSFORMER - To greatly improve the productivity, the general versatility, the downsizing, the performance and the like, as compared to those of the conventional transformer, provided is a transformer including: a core; a primary winding; a secondary winding; a bobbin provided with a low voltage side coil winding portion and a high voltage side coil winding portion, wherein the secondary winding is wound onto each of the coil winding portions; and a casing disposed so as to cover an outer periphery of the bobbin, wherein the primary winding is wound onto a portion of an outer periphery of the casing corresponding to a position of the low voltage side coil winding portion. | 06-12-2014 |
20140175907 | WIRELESS POWER TRANSMISSION SYSTEM - A power transmitting apparatus includes an active electrode, a passive electrode, a voltage generating circuit that applies a voltage between the active electrode and the passive electrode, and a reference potential electrode connected to a reference potential. A power receiving apparatus includes an active electrode, a passive electrode, a secondary battery connected between the active electrode and the passive electrode, and a reference potential electrode connected to a reference potential. Power is transmitted from the power transmitting apparatus to the power receiving apparatus as a result of the respective electrodes facing each other and being capacitively coupled to each other when the power receiving apparatus is mounted to the power transmitting apparatus. | 06-26-2014 |
20140210276 | POWER RECEPTION DEVICE, POWER TRANSMISSION DEVICE AND WIRELESS POWER TRANSMISSION SYSTEM - A mobile terminal device performs short range communication with an R/W device and receives power from a power transmission device. The mobile terminal device includes a coil antenna, an RFID IC circuit that performs short range communication with the outside via the coil antenna, a charging circuit that receives power received by the coil antenna which is capacitively coupled with a passive electrode and switches that switch to a short range communication state in which short range communication is performed via the coil antenna or a power reception state in which power is received via the coil antenna. Accordingly, a power reception device, a power transmission device and a wireless power transmission system are provided with which wireless power transmission can be realized without obstructing size reduction by giving a single member two functions. | 07-31-2014 |
20140253052 | POWER TRANSMISSION DEVICE AND POWER TRANSMISSION CONTROL METHOD - Power transmission device that causes a power supply circuit to supply a first voltage to a first active electrode when power transmission is performed, causes the power supply circuit to supply a second voltage that is lower than the first voltage to the first active electrode and causes power reception device detection means to perform frequency sweeping at a first time interval until the power reception device is mounted, or causes the power supply circuit to supply a third voltage that is lower than the first voltage to the first active electrode and causes the power reception device detection means to perform frequency sweeping at a second time interval that is longer than the first time interval until the power reception device is removed. | 09-11-2014 |
20140265623 | STEP-DOWN CIRCUIT AND POWER RECEIVING DEVICE USING STEP-DOWN CIRCUIT - A step-down circuit using a piezoelectric transformer that includes a rectangular parallelepiped piezoelectric plate having opposite end portions in a lengthwise direction thereof, which are constituted as two lower voltage portions provided with output electrodes, and a region sandwiched between the two lower voltage portions. The region being partly constituted as a higher voltage portion provided with an input electrode. The two lower voltage portions and the higher voltage portion are each polarized and driven in a 3/2λ or a 5/2λ mode. The higher voltage portion or vicinities thereof are polarized in directions symmetric to each other on both the sides of a center of the higher voltage portion or on both the sides of the higher voltage portion. The output electrodes on the positive and negative charge sides of respective polarized lower voltage portions are connected to each other. | 09-18-2014 |
20140265624 | PIEZOELECTRIC TRANSFORMER, PIEZOELECTRIC TRANSFORMER MODULE, AND WIRELESS POWER TRANSMISSION SYSTEM - A piezoelectric transformer includes a rectangular plate-shaped piezoelectric board having a length L in a longitudinal direction. In the piezoelectric board, five regions having a length L/5 are formed. In the two of regions, inner electrodes are formed in a thickness direction and conducted to outer electrodes provided in these regions. In a third region, outer electrodes are provided. The two regions of the piezoelectric board are polarized in the thickness direction, and two adjacent regions thereof are polarized in the longitudinal direction, and the third region is non-polarized. When a voltage is applied to the outer electrodes, the piezoelectric board expands and contracts in the longitudinal direction due to a piezoelectric effect. Thus, a piezoelectric transformer which enables high-efficient energy conversion even when a driving frequency is increased and a wireless power transmission system using the piezoelectric transformer are provided. | 09-18-2014 |
20140300201 | Power Transfer System - A capacitance (Cp) is a capacitance formed between a transmitting-device-side passive electrode and a receiving-device-side passive electrode. A capacitance (Ca) is a capacitance formed between a transmitting-device-side active electrode and a receiving-device-side active electrode. A bridge circuit formed by Z | 10-09-2014 |
20140361639 | ELECTRIC FIELD COUPLING TYPE WIRELESS ELECTRIC POWER TRANSMITTING SYSTEM AND ELECTRIC POWER RECEIVING APPARATUS INCLUDED THE SAME - An electric power receiving apparatus of an electric power transmitting system includes an overvoltage suppressing unit connected in parallel to a resonant circuit. The overvoltage suppressing unit is formed by an impedance element. Impedance of the impedance element is set to such a value that a rise in a voltage across at least one pair of electric power receiving electrodes is suppressed as compared to a case in which the impedance element is not connected, in the process in which coupling capacitance Cm between electric power transmitting electrodes and the electric power receiving electrodes changes from a value held while the electric power transmitting electrodes and the electric power receiving electrodes are in a predetermined positional relationship during normal electric power transmission to substantially zero. | 12-11-2014 |