| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 具有多层隔膜的微机电系统结构 | CN201510971269.9 | 2015-12-22 | CN105712285A | 2016-06-29 | 雷诺·罗宾; 尼古拉斯·洛尔弗兰; 卡里姆·赛格尼 |
| 本发明涉及制造尤其是MEMS开关的MEMS设备的方法,其包括在基板上方形成柱与传导(传输)线以及在柱与传导线上方形成隔膜的步骤,形成隔膜步骤包括形成第一隔膜层和在柱中的一个上方的区域和/或传导线上方的区域中在第一隔膜层上方形成第二隔膜层使得第一隔膜层具有第二隔膜层未形成在其中的区域,该区域邻近第二隔膜层形成于其中的区域。此外,提供了尤其是MEMS开关的MEMS设备,其包括形成在基板上方的柱与传导(传输)线以及在柱与传导线上方的隔膜。隔膜包括第一隔膜层与在柱中的一个上方的区域和/或传导线上方的区域中形成在第一隔膜层上方的第二隔膜层,使得第一隔膜层具有第二隔膜层未形成在其中的区域,该区域邻近第二隔膜层形成于其中的区域。 | ||||||
| 2 | 多级开关 | CN201610004117.6 | 2016-01-04 | CN105760029A | 2016-07-13 | 艾伦·罗杰·莫里; 迪安·弗朗索瓦·罗伊; 肯尼思·亚瑟·斯尼尔 |
| 本发明公开了一种用于触控设备的多级开关,所述开关包括:触控检测层、开关电路基板和电触点组,所述电触点组包括连接于所述触控检测层的第一电触点和连接于所述开关电路基板的第二电触点,所述开关基于所述触控检测层测到触摸和所述电触点组发生啮合后进行触发。本发明还公开一种使用多级开关防止意外触发的方法和安装了这种开关的汽车。 | ||||||
| 3 | 机电开关装置及其操作方法 | CN201180025382.8 | 2011-06-08 | CN102906846B | 2015-08-12 | M·德蓬; C·哈格雷特纳; C·波兹蒂斯; A·塞巴斯蒂安 |
| 本发明涉及一种机电开关装置(100、200),其包括第一开关部分(111、112、211、212)、第二开关部分(121、122、220)和致动器装置(130、230)。所述致动器装置(130、230)被配置为提供致动力,由此使所述第一和第二开关部分(111、112、121、122、211、212、220)相对于彼此被致动,以从断开状态改变为连接状态。所述致动器装置(130、230)还被配置为至少当所述第一和第二开关部分(111、112、121、122、211、212、220)处于连接状态时,提供具有调制的致动力。本发明还涉及一种操作机电开关装置(100、200)的方法。 | ||||||
| 4 | 一种微电子开关及有源矩阵有机发光显示装置 | CN201410715663.1 | 2014-11-28 | CN104409286A | 2015-03-11 | 崔子巍; 吴昊; 朱红; 于洪俊; 薛海林; 王陆旸 |
| 该发明涉及显示技术领域,公开了一种微电子开关及有源矩阵有机发光显示器件,其中,微电子开关包括:栅电极;源漏电极;第一静电电极;具有开位和关位两种工作位置的悬臂;设置于悬臂的连接部;设置于悬臂的第二静电电极,第二静电电极与栅电极电连接、且与第一静电电极相对设置,第一静电电极与第二静电电极之间设有绝缘介质层;当栅电极向第二静电电极加载的电压小于设定阈值时,悬臂位于一种工作位置,当栅电极向第二静电电极加载的电压大于设定阈值时,悬臂切换至另一工作位置。上述微电子开关中,控制源漏电极通断的部件为微机械结构,其连通源电极和漏电极时的阈值电压均一性好,有利于简化有源矩阵有机发光显示装置中的像素驱动电路。 | ||||||
| 5 | 集成式机电致动器 | CN201180016557.9 | 2011-03-29 | CN102822931A | 2012-12-12 | M·德蓬 |
| 本发明提供了一种集成式机电致动器和一种用于制造此类集成式机电致动器的方法。所述集成式机电致动器包括致动器电极之间的静电致动器间隙和接触电极之间的电接触间隙。在所述致动器电极与所述接触电极之间提供具有倾斜角的倾斜。此电接触间隙的厚度等于在制造过程中通过蚀刻被除去的牺牲层的厚度。 | ||||||
| 6 | 一种T型同轴机电开关 | CN201510397913.6 | 2015-07-03 | CN105097367A | 2015-11-25 | 尹沃良; 华海月; 凌闯; 王方杰; 文春华; 熊为华 |
| 本发明提出了一种T型同轴机电开关,包括:控制电路组件、电磁驱动组件、微波信号传输通路组件以及外壳,通过控制电路组件控制电磁驱动组件中线圈内的电流,通过电磁驱动组件上的推杆驱动传输通路组件上的导杆运动,进而带动传输簧片动作,使得微波信号输入端与输出端连接或者断开,实现两两端口相导通。本发明的T型同轴机电开关能够实现最高频率到33GHz的切换能力,而且具有高抗振性,解决了现有技术工作频率低、环境适应性差的问题。 | ||||||
| 7 | 可配置的多栅开关电路系统 | CN201080046300.3 | 2010-10-15 | CN102576629B | 2015-06-10 | D·刘易斯 |
| 提供带有可配置的多栅开关电路系统的集成电路。开关电路系统可包括开关控制电路系统和多栅开关阵列。每个多栅开关可具有第一和第二端子、第一和第二栅极以及金属桥。金属桥连接到第一端子。金属桥可在栅极之上延伸且在断开状态时可悬浮在第二端子上。金属桥可具有尖端,在导通状态时,其向下弯曲以和第二端子物理接触。开关控制电路系统可提供行和列控制信号以加载所需要的开关状态到开关阵列中。开关阵列可被分割成形成多路复用器的开关组。多路复用器可用于如可编程逻辑器件电路的可编程电路中。 | ||||||
| 8 | 集成式机电致动器 | CN201180016557.9 | 2011-03-29 | CN102822931B | 2015-02-25 | M·德蓬 |
| 本发明提供了一种集成式机电致动器和一种用于制造此类集成式机电致动器的方法。所述集成式机电致动器包括致动器电极之间的静电致动器间隙和接触电极之间的电接触间隙。在所述致动器电极与所述接触电极之间提供具有倾斜角的倾斜。此电接触间隙的厚度等于在制造过程中通过蚀刻被除去的牺牲层的厚度。 | ||||||
| 9 | 机电开关装置及其操作方法 | CN201180025382.8 | 2011-06-08 | CN102906846A | 2013-01-30 | M·德蓬; C·哈格雷特纳; C·波兹蒂斯; A·塞巴斯蒂安 |
| 本发明涉及一种机电开关装置(100、200),其包括第一开关部分(111、112、211、212)、第二开关部分(121、122、220)和致动器装置(130、230)。所述致动器装置(130、230)被配置为提供致动力,由此使所述第一和第二开关部分(111、112、121、122、211、212、220)相对于彼此被致动,以从断开状态改变为连接状态。所述致动器装置(130、230)还被配置为至少当所述第一和第二开关部分(111、112、121、122、211、212、220)处于连接状态时,提供具有调制的致动力。本发明还涉及一种操作机电开关装置(100、200)的方法。 | ||||||
| 10 | 可配置的多栅开关电路系统 | CN201080046300.3 | 2010-10-15 | CN102576629A | 2012-07-11 | D·刘易斯 |
| 提供带有可配置的多栅开关电路系统的集成电路。开关电路系统可包括开关控制电路系统和多栅开关阵列。每个多栅开关可具有第一和第二端子、第一和第二栅极以及金属桥。金属桥连接到第一端子。金属桥可在栅极之上延伸且在断开状态时可悬浮在第二端子上。金属桥可具有尖端,在导通状态时,其向下弯曲以和第二端子物理接触。开关控制电路系统可提供行和列控制信号以加载所需要的开关状态到开关阵列中。开关阵列可被分割成形成多路复用器的开关组。多路复用器可用于如可编程逻辑器件电路的可编程电路中。 | ||||||
| 11 | 입력 장치 | KR1020130002570 | 2013-01-09 | KR101407850B1 | 2014-06-16 | 히사츠구신스케 |
| 입력 장치(100)는 터치판(111), 박막 센서(113), 전극부(114) 및 배선부(115)를 포함한다. 상기 터치판은 사용자 조작 시에 상기 손가락에 의해 터치된 전면을 갖고 있다. 상기 박막 센서는 상기 터치판의 배면에 접합된다. 상기 전극부와 배선부는 상기 박막 센서 상에 형성되고 서로 연결된다. 상기 터치판은 적어도 제1 부재(111a)와 제2 부재(111b)를 포함하는 복수의 상이한 부재로 구성된다. 상기 복수의 상이한 부재는 각자의 유전 상수를 갖고, 상기 터치판의 판두께 방향에서 각각 적층 및 라미네이트된다. 상기 복수의 상이한 부재는 상기 전극부와 상기 배선부에 따라서 상이한 유전 상수를 제공하고 상기 터치판 전체에 걸쳐 균일한 판두께를 제공하도록 상기 판두께 방향에서 상이한 치수비를 갖는다.
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| 12 | MICROMACHINE SWITCH AND METHOD OF MANUFACTURE THEREOF | EP00922875.0 | 2000-04-26 | EP1176620B1 | 2004-01-14 | MARUMOTO, Tsunehisa |
| 13 | MICROMACHINE SWITCH AND METHOD OF MANUFACTURE THEREOF | EP00922875 | 2000-04-26 | EP1176620A4 | 2002-06-19 | MARUMOTO TSUNEHISA |
| 14 | MICROMACHINE SWITCH AND METHOD OF MANUFACTURE THEREOF | EP00922875.0 | 2000-04-26 | EP1176620A1 | 2002-01-30 | MARUMOTO, Tsunehisa |
A micromachine switch for use in a millimeter wave circuit and a microwave circuit is simpler in structure than conventional micromachine switches. The micromachine switch has first and second high-frequency signal lines (1b, la), cantilever (11) fixed to an end of the first high-frequency signal line (1b) and extending to a position above second high-frequency signal line (1a), first insulating means (15) disposed on second high-frequency signal line (1a), second insulating means (14) disposed in an area where cantilever (11) and second high-frequency signal line (1a) confront each other, and first control signal line (2) connected between an end of second high-frequency signal line (1a) and first insulating means (15), for applying a control signal. When the control signal is applied to second high-frequency signal line (1a), cantilever (11) is attracted to second high-frequency signal line (1a), and connected to second high-frequency signal line (1a) via second insulating means (14) in a high-frequency fashion. |
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| 15 | Switch assembly | EP82100243 | 1982-01-14 | EP0056624A3 | 1983-04-06 | Sato, Ryuichi; Taniguchi, Tsutomu; Koga, Hirofumi |
A switch assembly includes first and second contact members which are operatively provided to take one of two positions, a break-position in which the first and second contact members are separated from each other, and a make-position in which the first and second contact members are electrically connected with each other. Magnetic members are provided operatively in association with the first and second contact members to define a closed magnetic loop with a current path extending through the loop, when the first and second contact members are turned to the make-position. The magnetic members attract each other by the magnetic flux through the closed loop to maintain the first and second contacts in the make-position when the current flowing through the current path is not zero. Thus, the first and second contact members are permitted to return to the break-position at a zero crossing point of a.c. current flowing through the contacts. |
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| 16 | Perfectionnements aux dispositifs pour détecter la rupture d'un élément de circuit électrique | EP79400522.3 | 1979-07-20 | EP0007867A1 | 1980-02-06 | Lewiner, Jacques; Dreyfus, Gérard; Perino, Didier |
II s'agit de détecter la rupture d'un fusible 1. On applique une tension continue U fonction de la tension prélevée aux bornes du fusible entre une électrode fixe 3 et une électrode mobile 4 formant ensemble un condensateur. L'électrode 4 est sollicitée vers l'électrode 3 par un électret 5 solidaire de cette dernière et dans le sens contraire par un aimant 6 et par la tension U : dès que cette tension dépasse un seuil correspondant à la rupture du fusible, l'électrode bascule et ferme un interrupteur 9 à des fins d'alarme. Applications courantes. |
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| 17 | GENERATEUR D'ELECTRICITE | EP13777270.3 | 2013-10-15 | EP2909869B1 | 2018-03-21 | VIALA, Bernard; LEBEDEV, Gor; DELAMARE, Jérome; GARBUIO, Lauric; LAFONT, Thomas; CUGAT, Orphée |
| 18 | CONFIGURABLE MULTI-GATE SWITCH CIRCUITRY | EP10773196.0 | 2010-10-15 | EP2489055A1 | 2012-08-22 | LEWIS, David |
| Integrated circuits with configurable multi-gate switch circuitry are provided. The switch circuitry may include switch control circuitry and an array of multi-gate switches. Each multi-gate switch may have first and second terminals, first and second gates, and a metal bridge. The metal bridge is attached to the first terminal. The metal bridge may extend over the gates and may hover above the second terminal in the off state. The metal bridge may have a tip that bends down to physically contact the second terminal in the on state. Switch control circuitry may provide row and column control signals to load desired switch states into the switch array. The switch array may be partitioned into groups of switches that form multiplexers. The multiplexers may be used in programmable circuits such as programmable logic device circuits. | ||||||
| 19 | MINIATURE ACTUATING DEVICE | EP92912318.0 | 1992-06-17 | EP0592469B1 | 1997-05-21 | GRAVESEN, Peter; BRANEBJERG, Jens, Anders |
| A miniature actuating device (1), is disclosed, with a carrier (13), a diaphragm (11), a hollow space (15) being formed between the carrier (13) and the diaphragm (11) and an insulating layer (12) being arranged between them, and with two electrode terminals (16, 17) for producing an electrostatic field between the diaphragm and the carrier for an activated state. With an actuating device of this kind, it is desired that the throw that can be achieved under the influence of the electrostatic field be rendered as large as possible. To that end, the hollow space is present only in the state of rest and in the activated state virtually disappears. | ||||||
| 20 | Switch assembly | EP82100243.3 | 1982-01-14 | EP0056624A2 | 1982-07-28 | Sato, Ryuichi; Taniguchi, Tsutomu; Koga, Hirofumi |
A switch assembly includes first and second contact members which are operatively provided to take one of two positions, a break-position in which the first and second contact members are separated from each other, and a make-position in which the first and second contact members are electrically connected with each other. Magnetic members are provided operatively in association with the first and second contact members to define a closed magnetic loop with a current path extending through the loop, when the first and second contact members are turned to the make-position. The magnetic members attract each other by the magnetic flux through the closed loop to maintain the first and second contacts in the make-position when the current flowing through the current path is not zero. Thus, the first and second contact members are permitted to return to the break-position at a zero crossing point of a.c. current flowing through the contacts. |
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