| 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 | Function driving device, function driving method, and function driving program | JP2012205727 | 2012-09-19 | JP2014059824A | 2014-04-03 | AMETANI KAZUSHI |
| PROBLEM TO BE SOLVED: To provide a function driving device, a function driving method, and a function driving program, capable of detecting an inclination of electronic equipment satisfactorily even when a user is in motion or in exercise.SOLUTION: In electronic equipment 100 including an acceleration sensor 111, a display section 112 and a light emission section 113, a control section 115 determines whether or not a user US is taking an action of viewing a display surface of the display section 112 of the electronic equipment 100 by: determining whether or not angles φ,θ indicative of an inclination direction of the electronic equipment 100 which are acquired on the basis of acceleration data fall within a set range previously determined; determining, when they fall within the set range, whether or not a state deviating from the set range occurs; and further determining whether or not the state falling within the set range continues for a prescribed time or longer in a stable manner. | ||||||
| 22 | Ball switch of multi-ball switch within the device | JP2009540621 | 2007-11-17 | JP5185950B2 | 2013-04-17 | ブランク トーマス |
| 23 | Ball switch of multi-ball switch within the device | JP2009540621 | 2007-11-17 | JP2010524148A | 2010-07-15 | ブランク トーマス |
| 層構造/プレート構造のマルチボールスイッチ装置内のボールスイッチは、ボールスイッチコンタクトから平坦なコンタクト路が導出されている。 ボールスイッチの室(3)の金属製の内壁(11)は、室プレート(9)の両側で円環状ストリップ(4,5)として終端している。 底部プレート(6)上の円形ディスク(1)を、誘電性の材料から成る同心的なシールリング(7)が取り囲んでおり、該シールリング上には、室プレートで向かい合って位置する金属製の円環状ストリップが同心的に完全に載置されている。 底部プレート(6)と室プレート(9)とは、円形ディスクを取り囲む接着剤層(10)を介して互いに結合されている/押し合わされている。 これによって、室壁は、円形ディスク(1)と、導出された導体路(2)とから電気的に絶縁されている。 室の円環状ストリップ(4)と、底部プレート(6)との間には、該円環状ストリップと底部プレートとの間に位置するシールリング(7)を介して、雰囲気シールが生じる。 ボールスイッチは、随意に、種々の形式で覆うことができる。 | ||||||
| 24 | Motion switch | JP2007176231 | 2007-07-04 | JP2009016166A | 2009-01-22 | YAMAGUCHI NORISHIGE |
| PROBLEM TO BE SOLVED: To provide a mechanical motion switch which is of micro size and can be used for a long time under a severe environment such as high temperature condition with high reliability. SOLUTION: The motion switch 10 has a metal case 11 of cylindrical shape with a lid and a lower lid 12 press-fitted and fixed to the metal case 11. In the lower lid 12, two leads 13 which are supported and fixed to the lower lid 12 by a hermetic seal 14 and are electrically insulated between the lower lid 12 are provided penetrated. Each lead 13 is extended from the lower lid 12 to the deep wall 11A side up to a prescribed position separated from the deep wall 11A, and a metal ball 16 is arranged movably between these between each detection end 13A at the tip of each lead 13 and the deep wall 11A. A coil spring 15 of which base end is fixed to the lower lid 12 is arranged inside the metal case 11 so as to wind around the two leads 13. Then, the tip part of the coil spring 15 elastically presses the metal ball 16 to the deep wall 11A side by its elastic force. COPYRIGHT: (C)2009,JPO&INPIT | ||||||
| 25 | Acceleration detection device | JP2003349887 | 2003-10-08 | JP2005116371A | 2005-04-28 | MATSUMOTO TORU |
| <P>PROBLEM TO BE SOLVED: To improve responsiveness and achieve small sizing, the stability of an acceleration detection property, and an improvement in productivity and cost reduction. <P>SOLUTION: This acceleration detection device comprises a mass unit 1 housed in a case 10 movably, an elastic member 16 for energizing the mass unit 1 rearward, and an opening and closing switch which opens and closes by moving forward against an energizing force as the mass unit 1 receives acceleration. The mass unit 1 is constructed of a synthetic resin material of high specific gravity made by an injection molding process, and metallic powder having corrosion resistance and a material of a sliding property are added to the synthetic resin material. <P>COPYRIGHT: (C)2005,JPO&NCIPI | ||||||
| 26 | 반도체 소자 및 그 제조 방법 | KR1020120104396 | 2012-09-20 | KR101366553B1 | 2014-02-26 | 주성욱; 정충경 |
| The embodiment includes a step of forming a lower electrode pattern on a substrate, a step of forming a first interlayer dielectric on the lower electrode pattern, a step of forming a second interlayer dielectric including a middle electrode pattern on the first interlayer dielectric, a step of forming an upper electrode pattern on the second insulating layer, a step of forming a third interlayer dialectic on the upper electrode pattern, a step of forming a cavity exposing a part of the middle electrode pattern by etching the first to the third interlayer dielectric, and a step of forming a contact ball in the cavity. | ||||||
| 27 | 다중 볼 스위치 장치의 볼 스위치 | KR1020097009298 | 2007-11-17 | KR1020090094072A | 2009-09-03 | 블랑크,토마스 |
| The ball switch in a multiball switch arrangement in layered /laminated construction has a flat contact guide away from the ball switch contacts. The metallic inner wall (11) of the chamber (3) of the ball switch ends on both sides of the chamber plate (9) in annular strips (4, 5). The circular disk (1) on the base plate (6) is surrounded by a concentric sealing ring (7) made of dielectric material on which the opposite annular strip (4) on the chamber plate completely and concentrically rests in the assembled condition. The base plate (6) and the chamber plate (9) are joined/pressed together via an adhesive layer (10) surrounding the circular disk in such a way that the chamber wall is electrically insulated from the circular disk (1) and the outgoing conductor track (2), and between the annular strip (4) of the chamber and the base plate (6) an atmospheric seal exists across the intermediate sealing ring (7). Optionally, the ball switch can be covered in various ways. | ||||||
| 28 | Electric current inertial switch | EP13175150.5 | 2013-07-04 | EP2682975A3 | 2015-04-01 | Tyminski, Dariusz; Tlustowski, Adam; Komorniczak, Wojciech; Górski, Tomasz; Wojciechowski, Piotr; Bartosiewicz, Adam |
An electric current inertial switch comprising a movable contact (1) fastened on an insulating base plate (2) and having two arms of different length situated at an angle each in relation to the other, as well as a fixed contact (4), whereas said movable contact (1) and said fixed contact (4) have contact elements (7) located opposite one to another, as well as conducting elements (5) connecting the inertial switch with the electrical circuit. The movable contact (1) is shaped as an L letter having its shorter arm (6) fastened in the base plate, and contact elements (7) of the movable contact (1) and of the fixed contact (4) are made of material having attraction-oriented magnetic properties. The switch is automatically switching on electric current in case of acceleration, even greater than 3000 g.
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| 29 | KUGELSCHALTER IN EINER MULTI-KUGELSCHALTER-ANORDNUNG | EP07819853.8 | 2007-11-17 | EP2102881A1 | 2009-09-23 | BLANK, Thomas |
| The ball switch in a multiball switch arrangement in layered /laminated construction has a flat contact guide away from the ball switch contacts. The metallic inner wall (11) of the chamber (3) of the ball switch ends on both sides of the chamber plate (9) in annular strips (4, 5). The circular disk (1) on the base plate (6) is surrounded by a concentric sealing ring (7) made of dielectric material on which the opposite annular strip (4) on the chamber plate completely and concentrically rests in the assembled condition. The base plate (6) and the chamber plate (9) are joined/pressed together via an adhesive layer (10) surrounding the circular disk in such a way that the chamber wall is electrically insulated from the circular disk (1) and the outgoing conductor track (2), and between the annular strip (4) of the chamber and the base plate (6) an atmospheric seal exists across the intermediate sealing ring (7). Optionally, the ball switch can be covered in various ways. | ||||||
| 30 | Beschleunigungsschalter mit Schnappfeder | EP91111084.9 | 1991-07-04 | EP0466021A3 | 1992-09-02 | d'Elsa, Uwe |
Bei einem Beschleunigungsschalter zum Schließen mindestens eines elektrischen Kontaktpaares (6', 6'') durch eine auf eine Feder einwirkende Trägheitsmasse (1), wobei die Feder und die Trägheitsmasse (1) so gewählt sind, daß der Beschleunigungsschalter erst anspricht, wenn eine auf die Trägheitsmasse (1) einwirkende Beschleunigungskraft einen vorgegebenen Wert überschreitet, ist die Feder ein monostabiles Schnappelement (4). An der dem Schnappelement (4) zugewandten Seite der Trägheitsmasse (1) kann ein elastisches Pufferelement (10), das ein elastomeres Material und/oder eine Verzögerungsfeder (12) enthalten kann, vorgesehen sein. Der Beschleunigungsschalter kann bei entsprechender Anordnung der Schnappelemente (4) und ihrer zugehörigen Kontaktpaare (6', 6'') auf Beschleunigungen in jeder beliebigen Raumrichtung ansprechen. |
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| 31 | Beschleunigungsschalter mit Schnappfeder | EP91111084.9 | 1991-07-04 | EP0466021A2 | 1992-01-15 | d'Elsa, Uwe |
Bei einem Beschleunigungsschalter zum Schließen mindestens eines elektrischen Kontaktpaares (6', 6'') durch eine auf eine Feder einwirkende Trägheitsmasse (1), wobei die Feder und die Trägheitsmasse (1) so gewählt sind, daß der Beschleunigungsschalter erst anspricht, wenn eine auf die Trägheitsmasse (1) einwirkende Beschleunigungskraft einen vorgegebenen Wert überschreitet, ist die Feder ein monostabiles Schnappelement (4). An der dem Schnappelement (4) zugewandten Seite der Trägheitsmasse (1) kann ein elastisches Pufferelement (10), das ein elastomeres Material und/oder eine Verzögerungsfeder (12) enthalten kann, vorgesehen sein. Der Beschleunigungsschalter kann bei entsprechender Anordnung der Schnappelemente (4) und ihrer zugehörigen Kontaktpaare (6', 6'') auf Beschleunigungen in jeder beliebigen Raumrichtung ansprechen. |
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| 32 | Electric current inertial switch | EP13175150.5 | 2013-07-04 | EP2682975A2 | 2014-01-08 | Tyminski, Dariusz; Tlustowski, Adam; Komorniczak, Wojciech; Górski, Tomasz; Wojciechowski, Piotr; Bartosiewicz, Adam |
An electric current inertial switch comprising a movable contact (1) fastened on an insulating base plate (2) and having two arms of different length situated at an angle each in relation to the other, as well as a fixed contact (4), whereas said movable contact (1) and said fixed contact (4) have contact elements (7) located opposite one to another, as well as conducting elements (5) connecting the inertial switch with the electrical circuit. The movable contact (1) is shaped as an L letter having its shorter arm (6) fastened in the base plate, and contact elements (7) of the movable contact (1) and of the fixed contact (4) are made of material having attraction-oriented magnetic properties. The switch is automatically switching on electric current in case of acceleration, even greater than 3000 g.
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| 33 | ACCELERATION SENSOR | EP09717268 | 2009-03-05 | EP2307891A4 | 2013-11-27 | KELLEY WHITMORE B JR |
| An acceleration sensor is provided. The acceleration sensor contains a first electrically conductive element and a second electrically conductive element. An electrically insulative element is connected to the first electrically conductive element and the second electrically conductive element, where at least a portion of the first electrically conductive element and at least a portion of the second electrically conductive element make contact with the electrically insulative element. At least one electrically conductive spring is located within a cavity of the sensor, wherein the cavity is defined by at least one surface of the first electrically conductive element, at least one surface of the electrically insulative element, and at least one surface of the second electrically conductive element. | ||||||
| 34 | Collision detecting device for motor vehicle | EP89117146.4 | 1989-09-15 | EP0359288A3 | 1990-12-12 | Kumita, Norio; Yamamoto, Takaaki; Narita, Seiichi; Ori, Takaaki |
A collision detecting device for a motor vehicle includes a base plate (1) coupled within an open end of a bottomed cylindrical case (2) and secured in place to provide a sealed chamber, a support shaft rotatably mounted within the sealed chamber, a rotary member (3) provided on the support shaft for rotation therewith and having the center of gravity positioned eccentrically from its rotation axis, a pair of contact elements (5a, 5a) provided on the rotary member for rotation therewith and being symmetrically arranged with respect to the rotational axis of the rotary member, a pair of electric terminals (9, 10) fixed to the base plate, the terminals each having an internal contact portion (9a, 10a) slidably engageable with each of the contact elements (5a) and an external terminal pin (9b, 10b) for connection to an electric control circuit, and a spring (8) disposed within the sealed chamber to apply a counteracting rotational force to the rotary member depending on an angle of rotation through which the rotary member has rotated. |
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| 35 | Collision detecting device for motor vehicle | EP89117146.4 | 1989-09-15 | EP0359288A2 | 1990-03-21 | Kumita, Norio; Yamamoto, Takaaki; Narita, Seiichi; Ori, Takaaki |
A collision detecting device for a motor vehicle includes a base plate (1) coupled within an open end of a bottomed cylindrical case (2) and secured in place to provide a sealed chamber, a support shaft rotatably mounted within the sealed chamber, a rotary member (3) provided on the support shaft for rotation therewith and having the center of gravity positioned eccentrically from its rotation axis, a pair of contact elements (5a, 5a) provided on the rotary member for rotation therewith and being symmetrically arranged with respect to the rotational axis of the rotary member, a pair of electric terminals (9, 10) fixed to the base plate, the terminals each having an internal contact portion (9a, 10a) slidably engageable with each of the contact elements (5a) and an external terminal pin (9b, 10b) for connection to an electric control circuit, and a spring (8) disposed within the sealed chamber to apply a counteracting rotational force to the rotary member depending on an angle of rotation through which the rotary member has rotated. |
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| 36 | LINEAR IMPACT SWITCH FOR DETECTING GENERALLY HORIZONTAL IMPACTS | US14670369 | 2015-03-26 | US20150279595A1 | 2015-10-01 | MARK E RALSTIN; JOHN EDWARD HUMPHREYS, Jr. |
| A linear impact switch provides a contact closure, when pressure-activated at any of multiple locations over substantial distances and surface areas. Preferred switch units are positioned with their impact faces in a generally vertical orientation to receive generally horizontal forces. The switch units may be used to trigger an alarm in a falling rock or slide area, wherein the switch units are placed beside a road, path, or other perimeter, for example, on a barrier, fence, retaining wall, or other structure. The switch units may be simple and durable, using a conductive outer (or forward) member and a conductive inner (or rearward) member, whereby the impact/pressure forces the outer/forward member to make contact with the inner/rearward member, thereby closing the switch to send or relay a signal notifying drivers or authorities of the event that caused the signal, even though the event may be in an isolated or seldom-inspected region. | ||||||
| 37 | SWITCHING DEVICE | US14235367 | 2012-07-26 | US20140251770A1 | 2014-09-11 | Lior Kogut; Boris Neoponyashchy; Avihay Ohana; Nir Pernat |
| An acceleration responsive switching device formed as a micro-electromechanical systems (MEMS) device in which components are deposited and etched on and or above a substrate. The device has a proof mass module. The proof mass module includes: at least one proof mass made of metal; at least three resilient suspending members made of metal, for suspending the proof mass; a lingule made of metal, connected to the proof mass; at least two contact pads to which at least one of the three resilient suspending members is permanently attached thereby allowing current to flow from the at least two pads to the proof mass module; and at least one additional contact pad, which is set against the lingule. | ||||||
| 38 | Setback and set-forward activated electrical switches | US13850264 | 2013-03-25 | US08748762B2 | 2014-06-10 | Jahangir S. Rastegar; Richard T. Murray |
| An electrical switch including: a body; a mass element; a spring element attached at one end to the body and at another end, at least indirectly, to the mass element; and an inclined surface upon which the mass element moves from a resting position to an all-fire position. The inclined surface being inclined with respect to a firing setback acceleration. When the body experiences the firing setback acceleration, the mass element travels at least across the inclined surface against a force of the spring element to contact an electrical contact and close a circuit. | ||||||
| 39 | FUNCTION DRIVING APPARATUS, FUNCTION DRIVING METHOD, AND COMPUTER-READABLE STORAGE MEDIUM HAVING FUNCTION DRIVING PROGRAM THEREON | US14019947 | 2013-09-06 | US20140077625A1 | 2014-03-20 | Hitoshi AMAGAI |
| A function driving apparatus of the present invention includes an acceleration sensor which detects acceleration components of a device in directions of x axis, y axis, and z axis which are orthogonal to each other, at every predetermined time interval; and a control section which transforms, at every predetermined time interval, the acceleration components detected by the acceleration sensor to polar coordinate components formed of an r component representing a distance from an origin of an xyz space, a θ component representing an angle formed with the x axis, and a φ component representing an angle formed with an xy plane including the x axis and the y axis, and drives a specific function of the device when a state in which the θ component and the φ component are within a predetermined set range continues for a predetermined time or longer. | ||||||
| 40 | Setback and Set-Forward Activated Electrical Switches | US13850264 | 2013-03-25 | US20130228425A1 | 2013-09-05 | Jahangir S. Rastegar; Richard T. Murray |
| An electrical switch including: a body; a mass element; a spring element attached at one end to the body and at another end, at least indirectly, to the mass element; and an inclined surface upon which the mass element moves from a resting position to an all-fire position. The inclined surface being inclined with respect to a firing setback acceleration. When the body experiences the firing setback acceleration, the mass element travels at least across the inclined surface against a force of the spring element to contact an electrical contact and close a circuit. | ||||||
