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 |
|---|---|---|---|---|---|---|
| 161 | METALIZED ELASTOMERIC ELECTRICAL CONTACTS | EP05858193.5 | 2005-09-30 | EP1834379B1 | 2012-07-11 | HOUGHAM, Gareth, Geoffrey; AFZALI, Ali; CORDES, Steven, Allen; COTEUS, Paul, W.; FARINELLI, Matthew, J.; GOMA, Sherif, A.; LANZETTA, Alphonso, P.; MORRIS, Daniel, Peter; ROSNER, Joanna; YOHANNAN, Nisha |
| Techniques or forming enhanced electrical connections are provided. In one aspect, and electrical connecting device comprises an electrically insulating carrier having one or more contact structures traversing a plane thereof. Each contact structure comprises an elastomeric material having an electrically conductive layer running along at least one surface thereof continuously through the plane of the carrier. | ||||||
| 162 | METALIZED ELASTOMERIC ELECTRICAL CONTACTS | EP05858193.5 | 2005-09-30 | EP1834379A2 | 2007-09-19 | HOUGHAM, Gareth, Geoffrey; AFZALI, Ali; CORDES, Steven, Allen; COTEUS, Paul, W.; FARINELLI, Matthew, J.; GOMA, Sherif, A.; LANZETTA, Alphonso, P.; MORRIS, Daniel, Peter; ROSNER, Joanna; YOHANNAN, Nisha |
| Techniques or forming enhanced electrical connections are provided. In one aspect, and electrical connecting device comprises an electrically insulating carrier having one or more contact structures traversing a plane thereof. Each contact structure comprises an elastomeric material having an electrically conductive layer running along at least one surface thereof continuously through the plane of the carrier. | ||||||
| 163 | ELECTRICAL CONNECTOR FOR A FLEXIBLE FLAT CONDUCTOR AND A SWITCH DEVICE | EP04765758.0 | 2004-10-01 | EP1673837B1 | 2007-08-08 | GIMBEL, Markus; GLASER, Stephan-Ernst; SCHLINKHEIDER, Jörg |
| Electrical connector for electrically contacting a conductive line (120) embedded in a foil cable (102), wherein the electrical connector comprises an insulating housing, which at least partially encloses the foil cable (102), and at least one contact element (116) for electrically contacting the conductive line (120), wherein the insulating housing comprises a contact housing (114), in which the at least one contact element (116) is received, and a foil holder (126), which is separated therefrom, which may be mechanically fixed to the foil cable (102) and is joined to the contact housing (114) such that the contact element (116) abuts the conductive line (120) in a contact region (118). | ||||||
| 164 | Electrical highway cable connector | EP85200884.6 | 1982-11-03 | EP0164800B1 | 1989-03-01 | Gorman, Anthony Graham; Peacock, John Richard |
| A connector which can make electrical connection to the wires in a highway cable without cutting the cable is formed with two hinged members which can be closed together to make the connection. On closing, conducting needles penetrate the insulation of the cable to contact the wire core. For a co-axial cable, the needle for the central core is insulated except at the tip. | ||||||
| 165 | BI-VERTICAL MAIN DISTRIBUTING FRAME CONNECTOR | EP83902595.4 | 1983-07-14 | EP0116069B1 | 1988-10-05 | SCERBO, Louis, Joseph; SOLTIS, Robert, Alvin |
| A connector (100) has cross-connect terminals (122) which interconnect telephone central office wiring and outside plant wires. The connector (100) consists of two connector units (101, 102) arranged in mirror relationship. The connector (100) is totally front-facing and has designation dividers (125, 131) to facilitate identification of the cross-connect terminals (122) and associated protector modules (108). | ||||||
| 166 | BI-VERTICAL MAIN DISTRIBUTING FRAME CONNECTOR | EP83902595.0 | 1983-07-14 | EP0116069A1 | 1984-08-22 | SCERBO, Louis, Joseph; SOLTIS, Robert, Alvin |
| Un connecteur (100) possède des terminaux de connexion transversale (122) qui relient les câblages d'un central téléphonique au câble provenant de l'extérieur. Le connecteur (100) se compose de deux unités de connecteur (101, 102) disposées selon un agencement spéculaire. Le connecteur (100) n'occupe qu'une face antérieure et possède des diviseurs de désignation (125, 131) qui facilitent l'identification des terminaux de connexion transversale (122) et des modules de protection associés (108). | ||||||
| 167 | Highway cable connector | EP82305845.8 | 1982-11-03 | EP0079722A1 | 1983-05-25 | Gorman, Anthony Graham; Peacock, John Richard |
A connector which can make electrical connection to the wires in a highway cable without cutting the cable is formed with two hinged members which can be closed together to make the connection. On closing, conducting needles penetrate the insulation of the cable to contact the wire core. For a co-axial cable, the needle for the central core is insulated except at the tip. |
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| 168 | RELAY TERMINAL BLOCK | US15529110 | 2015-01-08 | US20170264030A1 | 2017-09-14 | Shinya KANEOYA |
| A relay terminal block fixed to a fixing part by a screw includes a main body having a first surface facing the fixing part, and a second surface on a rear surface side of the first surface. The main body is formed with a recessed portion depressed from the second surface toward the first surface, a through-hole formed from a bottom surface of the recessed portion through to the first surface, and a protrusion that is provided at an edge of the recessed portion to protrude in a direction away from the second surface. The through-hole is formed to have an inner diameter larger than an outer diameter of a shaft of the screw and smaller than an outer diameter of a head of the screw, and the recessed portion is formed to have an inner diameter larger than the outer diameter of the head of the screw. | ||||||
| 169 | ELECTRICAL CONNECTOR FOR CONNECTING A CABLE | US14920149 | 2015-10-22 | US20170047691A1 | 2017-02-16 | Wen Wei Lin |
| An electrical connector used for mating a mating connector includes an insulating body having multiple terminal slots in communication with an insertion space, multiple terminals, an insulating block. Each terminal slot has at least one side wall from which a depressed portion is depressed, the depressed portion is laterally in communication with the terminal slot. Each terminal has a connection portion connected to a contact portion and a soldering portion, a stopping portion protrudes from the connection portion and is located at the depressed portion. The insulating block is insert molded at a back end of the insulating body. A protruding portion protrudes from a front end of the insulating block and enters the depressed portion. The stopping portion is stopped in front of the protruding portion. | ||||||
| 170 | Method for fabricating MEMS device and MEMS device | US13037762 | 2011-03-01 | US08800141B2 | 2014-08-12 | Takashi Katsuki; Takeaki Shimanouchi; Masahiko Imai; Osamu Toyoda; Satoshi Ueda |
| There is provided a method for fabricating a device, preferably for a micro electro electro mechanical system. The method includes forming a first electrode on a substrate, where the first electrode has a first sloped end at least at one end thereof; forming a sacrificial layer on the first electrode, where the sacrificial layer has a first sloped edge, the first sloped edge and the first sloped end are overlapped each other so that a thickness of the first sloped edge decreases as a thickness of the first sloped end increases; forming a first spacer on the first electrode, where the first spacer has contact with the first sloped edge; forming a beam electrode on the sacrificial layer and the first spacer; and removing the sacrificial layer after the forming the beam electrode. | ||||||
| 171 | ELECTRIC CONNECTOR | US13937601 | 2013-07-09 | US20140017914A1 | 2014-01-16 | Takayoshi ENDO; Sakai YAGI; Takuya TAKEDA |
| An electric connector includes at least one terminal pin having, at opposite ends thereof, terminals to be inserted into through-holes formed through printed circuit boards spaced away from and facing each other, and an aligner for aligning the terminal pins in a row in such a condition that the terminal pins are movable relative to the aligner, the terminal pin including a movement-limiter which restricts movement of the terminal pin in a direction of an axis thereof. | ||||||
| 172 | SIGNAL DETECTION APPARATUS FOR SAS DEVICES | US13110985 | 2011-05-19 | US20120268104A1 | 2012-10-25 | FA-SHENG HUANG |
| A signal detection apparatus for a serial attached SCSI (SAS) device includes an SAS female connector to be connected to a SAS device, an SAS male connector to be connected to a system, and first to fourth pairs of subminiature version A (SMA) connectors. When the first pair of SMA connectors is connected to an oscillograph to detect a pair of output signals from the SAS device, the second and third pairs of SMA connectors connect the SAS device with the system. When the second pair of SMA connector is connected to the oscillograph to detect another pair of output signals from the SAS device, the first and fourth pairs of SMA connectors connect the SAS device with the system. | ||||||
| 173 | HIGH FREQUENCY DETECTION DEVICE AND COAXIAL CABLE INCLUDING THE SAME | US13185060 | 2011-07-18 | US20120019267A1 | 2012-01-26 | Isao TABUCHI |
| The present invention provides a high frequency detection device that detects a high frequency voltage signal according to a high frequency voltage generated in a power transmission body. The high frequency detection device includes a substrate and a capacitance conductor fixed to the substrate. The capacitance conductor includes a penetration portion and a capacitor electrode. In the penetration portion, the power transmission body is disposed so as to extend along the penetration portion in a state in which the axial direction of the power transmission body and the substrate are substantially orthogonal. The capacitor electrode is provided to be opposed to the power transmission body. | ||||||
| 174 | METHOD FOR FABRICATING MEMS DEVICE AND MEMS DEVICE | US13037762 | 2011-03-01 | US20110216469A1 | 2011-09-08 | Takashi Katsuki; Takeaki Shimanouchi; Masahiko Imai; Osamu Toyoda; Satoshi Ueda |
| There is provided a method for fabricating a device, preferably for a micro electro electro mechanical system. The method includes forming a first electrode on a substrate, where the first electrode has a first sloped end at least at one end thereof; forming a sacrificial layer on the first electrode, where the sacrificial layer has a first sloped edge, the first sloped edge and the first sloped end are overlapped each other so that a thickness of the first sloped edge decreases as a thickness of the first sloped end increases; forming a first spacer on the first electrode, where the first spacer has contact with the first sloped edge; forming a beam electrode on the sacrificial layer and the first spacer; and removing the sacrificial layer after the forming the beam electrode. | ||||||
| 175 | LAYOUT SCHEMES AND APPARATUS FOR MULTI-PHASE POWER SWITCH-MODE VOLTAGE REGULATOR | US12698819 | 2010-02-02 | US20110188218A1 | 2011-08-04 | Michael R. Hsing; Anthonius Bakken |
| A multi-phase voltage regulator is disclosed where each phase is comprised of an array of high and low side transistors that are integrated onto a single substrate. Further, a system of mounting the voltage regulator onto a flip chip and lead frame is disclosed wherein the source and drain lines form an interdigital pattern. | ||||||
| 176 | Metalized Elastomeric Probe Structure | US11718283 | 2005-09-30 | US20080094085A1 | 2008-04-24 | Gareth Hougham; Ali Afzali; Steven Cordes; Paul Coteus; Matthew Farinelli; Sherif Goma; Alphonso Lanzetta; Daniel Morris; Joanna Rosner; Nisha Yohannan |
| A probe structure for an electronic device is provided. In one aspect, the probe structure includes an electrically insulating carrier having one or more contact structures traversing a plane thereof. Each contact structure includes an elastomeric material having an electrically conductive layer running along at least one surface thereof continuously through the plane of the carrier. The probe structure includes one or more other contact structures adapted for connection to a test apparatus. | ||||||
| 177 | Method and apparatus for shaping spring elements | US09753188 | 2000-12-29 | US06836962B2 | 2005-01-04 | Igor Y. Khandros; Thomas H. Dozier; Gary W. Grube; Gaetan L. Mathieu |
| Interconnection elements for electronic components, exhibiting desirable mechanical characteristic (such as resiliency, for making pressure contacts) are formed by using a shaping tool (512) to shape an elongate core element (502) of a soft material (such as gold or soft copper wire) to have a springable shape (including cantilever beam, S-shape, U-shape), and overcoating the shaped core element with a hard material (such as nickel and its alloys), to impart to desired spring (resilient) characteristic to the resulting composite interconnection element. A final overcoat of a material having superior electrical qualities (e.g., electrical conductivity and/or solderability) may be applied to the composite interconnection element. The resulting interconnection elements may be mounted to a variety of electronic components, including directly to semiconductor dies and wafers (in which case the overcoat material anchors the composite interconnection element to a terminal (or the like) on the electronic component), may be mounted to support substrates for use as interposers and may be mounted to substrates for use as probe cards or probe card inserts. The shaping tool may be an anvil (622) and a die (624), and may nick or sever successive shaped portions of the elongate elements, and the elongate element may be of an inherently hard (springy) material. Methods of fabricating interconnection elements on sacrificial substrates are described. Methods of fabricating tip structures (258) and contact tips at the end of interconnection elements are also described. | ||||||
| 178 | Arrangement for establishing electrical contact in joints, and a method of producing the arrangement | US216828 | 1994-03-24 | US5435746A | 1995-07-25 | Karl-Erik Leeb |
| An arrangement for establishing electrical contact in joints, and a method of producing the arrangement. The arrangement comprises an electric contact making device which is enclosed in a joint between two metal surfaces between which electrical contact shall be established. The joint and the contact making device are held together and protected by plastic material. The arrangement is produced by applying pressure to the joint so that the surface penetrating devices of the contact making device will spring, and by converting the plastic material from a fluid state to a solid state while maintaining the pressure, so that the resilient biassing effect of the surface penetrating devices against the metal surfaces will be made permanent in the arrangement. | ||||||
| 179 | Contact for insulated wire | US649183 | 1976-01-15 | US4018499A | 1977-04-19 | David William Rickards |
| The contact is stamped from sheet metal and comprises a plate with a wire receiving slot opening into an edge of the plate between two arms and an integral core penetrating lance protruding between the arms into the slot and towards the slot opening, the arms having portions extending laterally towards each other adjacent the opening to define a wire-receiving mouth of restricted size which portions are formed with opposed insulation severing edges facing generally away from the lance. | ||||||
| 180 | Method for fabricating lead through for Dewar flask | US614803 | 1975-09-19 | US3992774A | 1976-11-23 | Gordon J. Burrer; Gene A. Robillard |
| An improved method for fabricating lead throughs in a Dewar flask is disclosed. Each lead through is provided with a contact portion which is essentially parallel to the side surface of the inner flask. The contact portion is bonded to a conductive path on the side surface of the inner flask. | ||||||
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