| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 81 | Sensor rotating apparatus | JP83893 | 1993-01-06 | JPH0682567A | 1994-03-22 | SHIN TOICHI |
| PURPOSE: To obtain a sensor rotating apparatus capable of sensing moving matter within a 360 deg. range by only one sensor reduced in wiring work and having an extremely simple structure from an aspect of appearance. CONSTITUTION: A sensor rotating apparatus is constituted of a decelerating gear member 5 decelerating drive force, a sensor rotating plate 2 wherein a sensor member 10 is stiffened, a hub supported in a rotatable manner, the rotary shaft allowed to cooperate by the rotation of the sensor rotating plate 2, the bearing member electrically connected to input terminals 12a, 12b at a time of the rotation of the rotary shaft and the support member 1b preventing the detachment of the connection of the bearing member. A peripheral state is sensed by the rotation of the sensor rotating plate 2 to send a sensing signal to a controller through the pin-shaped input terminals 12a, 12b provided in the rotary shaft. | ||||||
| 82 | JPH0463459U - | JP10780790 | 1990-10-15 | JPH0463459U | 1992-05-29 | |
| 83 | Plug-in type electrical connection structure of pickup in bearing | JP30098689 | 1989-11-21 | JPH02173418A | 1990-07-04 | SUBEN BENKUTANDAA; HAINTSU KIEENAA; YURUGEN KOOBERU |
| PURPOSE: To extinguish a damage during assembling and driving and to ensure a function of an anti-block braking device by disposing an inserted ring for connecting a pickup to an electronic circuit coaxial to a bearing and providing a contact shoe on the inserted ring. CONSTITUTION: A roller bearing having an inner ring 1 is engaged with a nonrotating shaft 2, and a synthetic resin ring 3 in which a pick up 4 for an anti-block braking device is buried is engaged with the inner ring 1. A pulse ring 5 is disposed on an inner diameter-installing surface of an outer ring. A plug-in ring 9 made of a synthetic resin is engaged with a circumferential surface of a stepped portion 8 of the shaft 2 so as to adhere it to a side surface 10 of the inner ring 1, and a slip ring 12 is provided to contact with a contact point 7 of the pickup 4. The slip ring 12 is connected to a connection cable 15 through a connection wiring. According to the constitution, a disorder of assembling is little and since the plug-in ring 9 does not rotate, a damage and a rupture are not caused. COPYRIGHT: (C)1990,JPO | ||||||
| 84 | JPS5933943B2 - | JP14748275 | 1975-12-12 | JPS5933943B2 | 1984-08-18 | JEFUERII BENETSUTO |
| 85 | Contact assembly | JP184178 | 1978-01-11 | JPS5388478A | 1978-08-03 | HARORUDO RII SUWAATSU; PIITAA AARU JIEIKOBUSUN; ROBAATO REOPORUDO PIAMAN; TERII ESU AREN |
| 86 | Denkikonekuta | JP14748275 | 1975-12-12 | JPS5184086A | 1976-07-23 | JEFUERII BENETSUTO |
| 87 | Tsudensochi | JP12474974 | 1974-10-28 | JPS5150488A | 1976-05-04 | IGAWA KAZUO; OGAWA NAOKI |
| 88 | SYSTEMS AND METHODS FOR IMPLEMENTING AN ELECTRICAL ROTARY JOINT IN A LARGE-DIAMETER SYSTEM USING SMALL-DIAMETER CAPSULE SLIP RINGS | US15891517 | 2018-02-08 | US20180183197A1 | 2018-06-28 | Jared William Moore; Steven Leslie Hills |
| A system for implementing an electrical rotary joint in a large-diameter system using relatively small-diameter capsule slip rings is described herein. The system includes a system rotor that rotates about a system axis of rotation, and a system stator that is stationary with respect to the system rotor. The system also includes at least one conductive contact channel disposed on one of the system rotor and the system stator. The system further includes at least one capsule slip ring (CSR) coupled to the other of the system rotor and the system stator. The at least one CSR has a conductive annular element coupled thereto, the conductive annular element in mechanical contact with the at least one conductive contact channel such that the at least one CSR forms an electrical rotary joint between the system rotor and the system stator. | ||||||
| 89 | Pivot linkage device with bearings comprising means for protection against high voltage transients | US14367166 | 2012-12-17 | US09933011B2 | 2018-04-03 | Frank Leferink; Edwin Leonardus Josephus Hogeman |
| The current invention relates to a pivot linkage device comprising at least one rolling bearing comprising at least one inner cage, one outer cage and a plurality of rolling elements denoted as the bearing components, the device further comprising means for protection against high voltage transients, wherein said protection means are exclusively formed by said bearing components, said bearing components being loaded by loading means arranged in such a manner that a direct electrical connection exists between these components. The current invention also relates to a method for protecting a bearing against high voltage transients by applying a preloading to the bearing's components. | ||||||
| 90 | Discharge Device And Method For Discharging Electrostatic Charges | US15467606 | 2017-03-23 | US20170280540A1 | 2017-09-28 | Lothar Theis; Daniel Pfeffer; Frank Burkard |
| A discharge device for a rolling bearing as well as a method for discharging electrostatic loads to a rolling bearing including a flexurally elastic conductor. The conductor includes a first conductor section and a second conductor section for forming a contact arrangement at a rolling bearing. The first conductor section electrically engages a first bearing ring and the second conductor section electrically engages a second bearing ring of the rolling bearing to form an electrically conductive connection between the first bearing ring and the second bearing ring. | ||||||
| 91 | SYSTEMS AND METHODS FOR IMPLEMENTING AN ELECTRICAL ROTARY JOINT IN A LARGE-DIAMETER SYSTEM USING SMALL-DIAMETER CAPSULE SLIP RINGS | US15046151 | 2016-02-17 | US20170237217A1 | 2017-08-17 | Jared William Moore; Steven Leslie Hills |
| A system for implementing an electrical rotary joint in a large-diameter system using relatively small-diameter capsule slip rings is described herein. The system includes a system rotor that rotates about a system axis of rotation, and a system stator that is stationary with respect to the system rotor. The system also includes at least one conductive contact channel disposed on one of the system rotor and the system stator. The system further includes at least one capsule slip ring (CSR) coupled to the other of the system rotor and the system stator. The at least one CSR has a conductive annular element coupled thereto, the conductive annular element in mechanical contact with the at least one conductive contact channel such that the at least one CSR forms an electrical rotary joint between the system rotor and the system stator. | ||||||
| 92 | DEPLOYABLE SELF-SUSTAINING SHELTER | US15404528 | 2017-01-12 | US20170198485A1 | 2017-07-13 | Nathan Tanner |
| An expandable, mobile structure is capable of sustaining a retracted state and an expanded state, and may be capable of alternately using public utilities as a power supply, or a self-contained “off-grid” power supply. This allows for use of the mobile structure in a multitude of locations, which are not governed by the presence or absence of an available external power supply. The structure may operate in an “on-grid” power mode when in an expanded condition, and in an “off-grid” mode in a retracted condition. The structure includes a different number of zones within the structure in the retracted state as compared to the expanded state. A modular HVAC system provides a different flow path of air in the retracted state and the expanded state. | ||||||
| 93 | SENSOR SYSTEM WITH A ROTATABLE ELECTRICAL OUTLET | US15172706 | 2016-06-03 | US20160359286A1 | 2016-12-08 | Alexander GERBER |
| A sensor system for measuring pressure, temperature, force, or fill level, whereby an electrical plug connection is made especially robust and reliable for frequent, cyclic pivoting movements. | ||||||
| 94 | Spring ring circuit assembly | US14710195 | 2015-05-12 | US09472915B1 | 2016-10-18 | Talbot Jaeger |
| A spring ring circuit assembly is provided for transmitting electricity between a first structure and a second structure which rotates relative to the first structure. The spring ring circuit assembly includes a spring ring which is affixed to and concentrically positioned around a spindle. The spring ring circuit assembly further includes a circular band concentrically positioned around the spring ring so as to create an annular space between the spring ring and circular band. The spring ring circuit assembly further includes an inner set of rollers positioned around and engaging the spring ring, and an outer set of rollers positioned within and engaging the circular band. The spring ring, rollers and circular band are made of electrically conductive materials so as to allow electricity to transmit between the spring ring and the circular band which is capable of rotating around the spring ring. | ||||||
| 95 | Weight supporting slip ring | US14611196 | 2015-01-31 | US09385495B1 | 2016-07-05 | Andrea Angelo Hilbert |
| A slip ring assembly is disclosed allowing significant external weight on either the stationary or rotating sides of the slip ring. Additionally, a slip ring assembly is disclosed allowing multiple small, linear, rolling contacts on each conductive ring of each electrical receiver disk of the slip ring (both the stationary and the rotating electrical receiver disks). Disclosed is an embodiment of a separator plate having a spiraling-out-from-the-center series of holes and in those holes of the separator plate are the small linear rolling, contacts. In one embodiment each spiraling series of holes with small the rolling contacts provides one rolling contact on each electrical conductive ring on each receiver disk. These spiral rings enable a slip ring designer to provide multiple rolling contacts on each circular electrical conduction ring by simply increasing the number or spiraled series of holes. | ||||||
| 96 | AUTOMATED CABLE BREAKOUT ASSEMBLY | US14942640 | 2015-11-16 | US20160137270A1 | 2016-05-19 | James R. Sturges; Haywood Hartwell; David A. Sharp; Christopher Blake; Joseph Ricci, JR. |
| A method of engaging an automated breakout assembly includes receiving, by a tow socket having a rotatable sleeve multiple mating connectors, a cable into the tow socket through a slot. The cable comprises a tow ball. Each mating connector is electrically coupled to an electrical conductor. The method includes receiving, by the rotatable sleeve, the randomly-aligned tow ball through an entrance. The method includes rotating a cam configured to rotate the rotatable sleeve to substantially align the mating connectors of the tow socket with connectors of the tow ball such that each electrical conductor electrically coupled to a mating connector couples to a corresponding connector of the tow ball. The method includes transferring a tow loading force between the cable and the tow socket by moving the cable. | ||||||
| 97 | Rotating vacuum chamber coupling assembly | US14403289 | 2014-03-11 | US09203200B2 | 2015-12-01 | Richard J. Fowler; Michael D. Drory |
| A coupling (30) for the introduction of a bias voltage into a vacuum chamber. The coupling consists of a metallic ball bearing assembly (36), a bearing sleeve or cup (34), and an EMI shielding gasket (42) seated within the bearing sleeve or cup. The ball bearing assembly is fitted within the EMI shielding gasket, about a metallic shaft (32) which, in turn, is coupled to a source of the bias voltage. The bearing sleeve or cup is, in turn, coupled to a rotating component such as a platen, for receiving the bias voltage within the vacuum chamber. | ||||||
| 98 | Method for downhole electrical transmission by forming an electrical connection | US14064176 | 2013-10-27 | US09045968B2 | 2015-06-02 | Joachim Sihler |
| A method facilitates transmission of electric signals across well components which move relative to each other in a wellbore environment. The method utilizes well components which are movably, e.g. rotatably, coupled to each other via one or more conductive bearings. Each conductive bearing has a conductive rolling element which enables relative movement, e.g. rotation, between the well components while simultaneously facilitating transmission of electric signals through the bearing. The method also involves coupling portions of the bearing to each of the well components, and those bearing portions may be connected with electric leads to enable flow of electric signals through the bearing during operation of the system downhole. | ||||||
| 99 | Rotary connector | US13951044 | 2013-07-25 | US08974233B2 | 2015-03-10 | Toshiaki Asakura; Keisuke Aikawa |
| In a rotary connector where a moving body turning with the rotation and revolution of planetary gears and flat cables including inverted portions at middle portions thereof are received in a receiving space between outer and inner cylindrical bodies, a bottom plate of a stationary-side housing is provided with an annular protrusion that comes into contact with lower surfaces of the planetary gears and a hollow portion that is positioned outside the annular protrusion in a radial direction, and the hollow portion is positioned directly below in a vertical direction when the stationary-side housing is mounted on an installation portion of a vehicle. Accordingly, a foreign matter entering the receiving space falls down onto the bottom plate and is accumulated in the hollow portion. Therefore, the hindrance to the rotation of the planetary gears, when the planetary gears catch a foreign matter, can be prevented. | ||||||
| 100 | Conductive roller | US12542430 | 2009-08-17 | US08211000B2 | 2012-07-03 | Takashi Marui; Takeshi Ishimaru; Noriaki Hitomi |
| A conductive roller has a core and a conductive foam formed on a peripheral surface thereof. The conductive foam constitutes a three-phase rubber composition containing 35 to 50 parts by mass of epichlorohydrin rubber, 25 to 35 parts by mass of ethylene-propylene-diene copolymer rubber, and 25 to 30 parts by mass of acrylonitrile-butadiene rubber as a rubber component thereof. The conductive foam does not have a coating layer formed on a surface thereof. The conductive roller has an Asker C hardness, an electric resistance value, an average surface-cell diameter, and a number of surface cells set to 30 to 36°, 106 to 107Ω, 100 to 200 μm, and 50 to 120/1.5 mm square respectively. | ||||||
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