子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 21 | METHOD FOR MANUFACTURING CONTACTLESS POWER-SUPPLY DEVICE, AND RESONATOR | EP14834612.5 | 2014-08-07 | EP3057114A1 | 2016-08-17 | MAEKAWA Yuji; HARA Masakazu |
Provided is a method for manufacturing a wireless power-transmitting device including a power-transmitter (114) having a transmission coil (115), and a power-receiver (125) having a reception coil (126). The method includes a step of forming, in the electrically-conductive member, an eddy current interruption unit (140) configured to change a state of an eddy current, formed in the electrically-conductive member by the transmission coil (115) (reception coil (126)), by interrupting and redirecting a portion of the eddy current to obtain processed electrically-conductive members (116, 127), and preparing a plurality of types of the processed electrically-conductive members (116, 127) whose eddy current interruption units (140) are different in form from each other; and a step of selecting one type of the processed electrically-conductive member from the plurality of types of the processed electrically-conductive members and arranging the selected one type of the processed electrically-conductive member near the transmission coil (115) (reception coil (126)), thereby finely adjusting the inductance of the transmission coil (115) (reception coil (126)) to reach a preset inductance. |
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| 22 | RESONATOR | EP14834612.5 | 2014-08-07 | EP3057114B1 | 2018-09-19 | MAEKAWA, Yuji; HARA, Masakazu |
| Provided is a method for manufacturing a wireless power-transmitting device including a power-transmitter (114) having a transmission coil (115), and a power-receiver (125) having a reception coil (126). The method includes a step of forming, in the electrically-conductive member, an eddy current interruption unit (140) configured to change a state of an eddy current, formed in the electrically-conductive member by the transmission coil (115) (reception coil (126)), by interrupting and redirecting a portion of the eddy current to obtain processed electrically-conductive members (116, 127), and preparing a plurality of types of the processed electrically-conductive members (116, 127) whose eddy current interruption units (140) are different in form from each other; and a step of selecting one type of the processed electrically-conductive member from the plurality of types of the processed electrically-conductive members and arranging the selected one type of the processed electrically-conductive member near the transmission coil (115) (reception coil (126)), thereby finely adjusting the inductance of the transmission coil (115) (reception coil (126)) to reach a preset inductance. | ||||||
| 23 | METHOD FOR MANUFACTURING CONTACTLESS POWER-SUPPLY DEVICE, AND RESONATOR | EP14834612 | 2014-08-07 | EP3057114A4 | 2017-08-09 | MAEKAWA YUJI; HARA MASAKAZU |
| Provided is a method for manufacturing a wireless power-transmitting device including a power-transmitter (114) having a transmission coil (115), and a power-receiver (125) having a reception coil (126). The method includes a step of forming, in the electrically-conductive member, an eddy current interruption unit (140) configured to change a state of an eddy current, formed in the electrically-conductive member by the transmission coil (115) (reception coil (126)), by interrupting and redirecting a portion of the eddy current to obtain processed electrically-conductive members (116, 127), and preparing a plurality of types of the processed electrically-conductive members (116, 127) whose eddy current interruption units (140) are different in form from each other; and a step of selecting one type of the processed electrically-conductive member from the plurality of types of the processed electrically-conductive members and arranging the selected one type of the processed electrically-conductive member near the transmission coil (115) (reception coil (126)), thereby finely adjusting the inductance of the transmission coil (115) (reception coil (126)) to reach a preset inductance. | ||||||
| 24 | Chip component | US14373900 | 2012-12-26 | US09646747B2 | 2017-05-09 | Hiroshi Tamagawa; Hiroki Yamamoto; Katsuya Matsuura; Yasuhiro Kondo |
| A chip component includes a substrate, an element circuit network including a plurality of element parts formed on the substrate, an external connection electrode provided on a surface of the substrate to provide external connection for the element circuit network, a plurality of fuses formed on the substrate and disconnectably connecting each of the plurality of element parts to the external connection electrode, a solder layer formed on an external connection terminal of the external connection electrode and a resin film which covers the surface of the substrate and other surface which intersects the surface of the substrate. | ||||||
| 25 | METHOD FOR MANUFACTURING WIRELESS POWER-TRANSMITTING DEVICE, AND RESONATOR | US15008536 | 2016-01-28 | US20160141099A1 | 2016-05-19 | Yuji MAEKAWA; Masakazu HARA |
| Provided is a method for manufacturing a wireless power-transmitting device including a power-transmitter having a transmission coil, and a power-receiver having a reception coil. The method includes forming, in the electrically-conductive member, an eddy current interruption unit configured to change a state of an eddy current, formed in the electrically-conductive member by the transmission coil (reception coil), by interrupting and redirecting a portion of the eddy current to obtain processed electrically-conductive members, and preparing a plurality of types of the processed electrically-conductive members whose eddy current interruption units are different in form from each other; and selecting one type of the processed electrically-conductive member from the plurality of types of the processed electrically-conductive members and arranging the selected one type of the processed electrically-conductive member near the transmission coil (reception coil), thereby finely adjusting the inductance of the transmission coil (reception coil) to reach a preset inductance. | ||||||
| 26 | TUNABLE INDUCTIVE DEVICE FOR PARAMETRIC AUDIO SYSTEMS AND RELATED METHODS | US14035789 | 2013-09-24 | US20150086040A1 | 2015-03-26 | ELWOOD GRANT NORRIS |
| An apparatus and method for optimizing a parametric emitter system having a pot core inductive device coupled between an amplifier and emitter. The pot core inductive device allows for adjustments of the air gap formed between the two halves of the pot core structure to adjust its inductive value. This post-manufacture adjustability allows for corrections of differences caused by operations of other components in the audio system and to account for slight differences in the electrical circuit of different amplifier/emitter combinations. As efficiency of the system is dependent on the functional relationship between the amplifier, inductive device, and emitter, this allows for fine tuning of the signal to obtain high quality. | ||||||
| 27 | TRANSFORMER WITH ADJUSTABLE LEAKAGE INDUCTANCE AND DRIVING DEVICE USING THE SAME | US12686519 | 2010-01-13 | US20100109569A1 | 2010-05-06 | CHIH-CHAN GER; YU-HSIANG LIAO |
| A transformer with adjustable leakage inductance includes a first bobbin, a first winding, and a second winding. The first bobbin includes a first region and a second region. The second winding includes a first coil portion and a second coil portion. One of the first winding and the first coil portion of the second winding is wound around the first region of the first bobbin, and the other of the first winding and the first coil portion of the second winding is wound outside of the one wound around the first region of the first bobbin. The second coil portion of the second winding is wound around the second region of the first bobbin. | ||||||
| 28 | TRANSFORMER WITH ADJUSTABLE LEAKAGE INDUCTANCE AND DRIVING DEVICE USING THE SAME | US11616865 | 2006-12-28 | US20070216508A1 | 2007-09-20 | CHIH-CHAN GER; YU-HSIANG LIAO |
| A transformer (50) with adjustable leakage inductance includes a first bobbin (525), a first winding (521), and a second winding (522). The first bobbin includes a first region (B1) and a second region (B2). The second winding includes a first coil portion (522a) and a second coil portion (522b). One of the first winding and the first coil portion of the second winding is wound around the first region of the first bobbin, and the other of the first winding and the first coil portion of the second winding is wound outside of the one wound around the first region of the first bobbin. The second coil portion of the second winding is wound around the second region of the first bobbin. In the invention, the leakage inductance of the transformer is adjustable via adjusting the number of the coils of the first coil portion and the second coil portion. | ||||||
| 29 | Segmented stator | US3644767D | 1970-03-23 | US3644767A | 1972-02-22 | KASARGOD SADANAND VITHAL; ABHYANKAR SHREENLWAS SHANKAR |
| In the segmented stator assembly disclosed, four teeth extend inwardly, and rectangularly relative to each other, from surrounding segments. The teeth form a bore at the center of the assembled segments. Each tooth has two parallel edges one of which extends along a line passing through the center of the bore. The centerline of each tooth is offset from the bore center. Coil-carrying bobbins are mounted on respective teeth so their axes coincide with the centerlines of the teeth on which they are mounted. The offset of each bobbin leaves space for intrusion of an edge of the transversely directed adjacent bobbin.
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| 30 | Rotary variable differential transformer used as a sine-cosine generator | US3491321D | 1968-11-26 | US3491321A | 1970-01-20 | CHASS JACOB |
| 31 | Inductive transducer with servo system | US3454854D | 1967-10-02 | US3454854A | 1969-07-08 | BOOTH GEORGE M |
| 32 | Electromagnetic transducer | US2535960 | 1960-04-28 | US3195039A | 1965-07-13 | KONING MENNO G |
| 33 | Variable linkage transformers | US47508854 | 1954-12-14 | US2882483A | 1959-04-14 | HUSON STEPHENSON GEOFFREY |
| 34 | 가변 리액터 | KR20160096678 | 2016-07-29 | KR20180013248A | 2018-02-07 | 신찬수; 박준영; 노병규; 남홍우 |
| 본발명은가변리액터에관한것으로서, 더욱상세하게는철심과코어가중첩되는구간을가변시켜리액턴스값을선형적으로가변시키는가변리액터를제공한다. | ||||||
| 35 | 집전모듈 | KR1020130106404 | 2013-09-05 | KR101474766B1 | 2014-12-22 | 조동호; 정구호; 이충희; 송보윤; 신승용; 김양수; 신재규; 정상훈 |
| 본 발명의 일 실시예는, 집전코일의 위치에 따라 각 집전코일에 불균형하게 나타나는 상호 인덕턴스 차이를 상쇄시킴으로써 각 집전코일 간 유도전압의 차이에 의한 영향을 줄여 무선전력전송차량에 공급되는 전압을 고르게 할 수 있는 효과가 있는 집전모듈에 관한 것이다. | ||||||
| 36 | 무선 충전 시스템 | KR1020140158266 | 2014-11-13 | KR1020160057577A | 2016-05-24 | 이우영; 하태종; 여인용; 송병섭; 최규영 |
| 무선충전시스템이개시된다. 본발명의일 실시예에따른차량의무선충전시스템은복수의송신코일들을갖는전력송신부; 및복수의송신코일들각각의전류및 전압을측정하고, 상기측정된각 송신코일의전류및 전압의크기에기반하여상기복수의송신코일들중 일부의송신코일에만충전전원을인가하는제어부를포함할수 있다. | ||||||
| 37 | 전압조정 기능을 갖는 위상조정 변압기 권선회로 | KR1020110102002 | 2011-10-06 | KR1020130037544A | 2013-04-16 | 우재희; 박균수 |
| PURPOSE: A phase control transformer winding circuit is provided to supply fixed power to a load side by controlling a power phase angle between a power side and a load side. CONSTITUTION: A main transformer(10) comprises a high-tension winding line(3) and a tap winding line(4) for controlling a phase. A serial transformer(20) comprises an excitation winding line(2) and a serial winding line(1). The neighboring transformer includes the tap winding line for controlling power connecting to the excitation winding line. [Reference numerals] (10) Main transformer; (20) Serial transformer; | ||||||
| 38 | A STEP-FREE INDUCTION CONTROLLED VOLTAGE REGULATOR | PCT/SE9801745 | 1998-09-29 | WO9917314A3 | 1999-06-17 | FROMM UDO; SASSE CHRISTIAN; SCHUETTE THORSTEN; LEIJON MATS |
| A step-free induction controlled voltage regulator, primarily for high-voltage regulation, includes a magnetic circuit based upon a magnetizable core (1) having one or more flux paths or legs (2) with at least one winding (3) supplying the output voltage (U). The output winding leg (2) includes a regulation arrangement (4-8) comprising a rotatable rotor means (4) carrying a regulator winding (6) electrically connected in series with the output winding (3). A compensator winding (7) can be arranged around the leg (2) and electrically connected in series with a capacitor means (8). At least one of the regulator winding (6) and the supply winding (3), or a part thereof, is wound by a high-voltage cable comprising at least one conductor surrounded by a first layer having semiconducting properties, a solid insulating layer, and a second layer having semiconducting properties. | ||||||
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