| 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 | 具有尺寸及阻抗可变的间隔装置的多触点触摸传感器 | CN200980134748.8 | 2009-08-05 | CN102144272A | 2011-08-03 | 帕斯卡尔·若盖; 朱利安·奥利维耶 |
| 本发明涉及一种多触点触摸传感器,包括支撑层(11)和可弹性形变的交互层(10),所述交互层(10)在其下表面上具有导电轨道(12)网络,所述支撑层(11)在其上表面上具有与所述交互层(10)的导电轨道(12)网络不平行的导电轨道(13)网络。所述交互层(10)和所述支撑层(11)被第一组刚性绝缘隔离物(14)分隔开。第二组导电隔离物(15)被设置为与所述两个导电轨道(12、13)网络中的至少一个导电轨道网络相接触。所述第二组隔离物(14)的阻抗和尺寸被确定为使得:在休眠时阻止发生接触,以及;在所述交互层(10)形变时允许在所述第二组隔离物(15)和与所述第二组隔离物(15)相对的层的导电轨道网络之间实现局部接触。本发明还涉及一种所述传感器的控制器、一种包括所述传感器的多触点触摸屏以及一种包括由所述传感器构成的一套离散触点的键盘。 | ||||||
| 2 | Touch sensor panel with in-plane backup bypass connections | US14621788 | 2015-02-13 | US09223454B2 | 2015-12-29 | John J Gorsica; Dale F Bengtson; Michael F Olley |
| Touch sensor panels (104) have 2-D periodic arrangements of electrodes (304) connected together forming a plurality of horizontal and vertical logical lines (506, 514) for measuring X-Y coordinates of a user's touch. Electrodes forming the horizontal logical lines are interleaved with electrodes forming the vertical logical lines. Each of the vertical and horizontal logical lines includes multiple tracks (502, 504, 510, 512). The tracks of each logical line are cross connected by in-plane cross connects (314, 318) formed in the same layer by the same process that is used to form the electrodes. Diamond and square electrode embodiments are described. | ||||||
| 3 | Transparent conductor and panel switch | US11475915 | 2006-06-28 | US07645954B2 | 2010-01-12 | Noriyuki Yasuda |
| The present invention provides a transparent conductor comprising a successive lamination of a support, a conductive particle layer containing a conductive particle and a first binder, and a conductive film layer containing a bead and a second binder; wherein a surface of the conductive film layer opposite from the conductive particle layer is rough. | ||||||
| 4 | TOUCH SENSOR PANEL WITH IN-PLANE BACKUP BYPASS CONNECTIONS | US14621788 | 2015-02-13 | US20150177886A1 | 2015-06-25 | John J Gorsica; Dale F Bengtson; Michael F Olley |
| Touch sensor panels (104) have 2-D periodic arrangements of electrodes (304) connected together forming a plurality of horizontal and vertical logical lines (506, 514) for measuring X-Y coordinates of a user's touch. Electrodes forming the horizontal logical lines are interleaved with electrodes forming the vertical logical lines. Each of the vertical and horizontal logical lines includes multiple tracks (502, 504, 510, 512). The tracks of each logical line are cross connected by in-plane cross connects (314, 318) formed in the same layer by the same process that is used to form the electrodes. Diamond and square electrode embodiments are described. | ||||||
| 5 | Touch sensor panel with in-plane backup bypass connections | US13564859 | 2012-08-02 | US08988387B2 | 2015-03-24 | John J Gorsica; Dale F Bengtson; Michael F Olley |
| Touch sensor panels (104) have 2-D periodic arrangements of electrodes (304) connected together forming a plurality of horizontal and vertical logical lines (506, 514) for measuring X-Y coordinates of a user's touch. Electrodes forming the horizontal logical lines are interleaved with electrodes forming the vertical logical lines. Each of the vertical and horizontal logical lines includes multiple tracks (502, 504, 510, 512). The tracks of each logical line are cross connected by in-plane cross connects (314, 318) formed in the same layer by the same process that is used to form the electrodes. Diamond and square electrode embodiments are described. | ||||||
| 6 | Transparent touch switch | JP19632687 | 1987-08-07 | JPS6452353A | 1989-02-28 | OKAMOTO TOSHINORI |
| PURPOSE:To make a switching section highly dense and obtain the uniform transparency over the whole panel by deforming insulating fine grains when depressing a glass plate and making both electrodes conductive with conductive fine grains having a smaller size. CONSTITUTION:Three kinds of spacer grains 7-9 with different grain sizes are dispersed between an upper glass plate 2 forming an upper electrode 1 and a lower glass plate 4 forming a lower electrode 3. The first spacer grains 7 with the largest grain size are made of an insulating material such as synthetic resin with some elasticity, the second spacer grains 8 with the grain size smaller than that of the first spacer grains 7 are made of a conductive material at least on the surface of the grains 8, the third spacer grains 9 with the smallest grain size are made of a hard material, and they are mixed in the transparent resin paste 10 at the preset distribution density. When the upper glass plate 2 is pressed, the insulating fine grains 7 are pressed and deformed, and a pair of the transparent electrodes 1, 3 are made conductive by the conductive fine grains 8 with the small grain size. The transparency of the panel face is thereby unified, and the positional resolution of a switch can be improved. | ||||||
| 7 | CAPTEUR TACTILE MULTICONTACTS A MOYENS D'ESPACEMENT DE TAILLE ET IMPEDANCE VARIABLES | EP09804599.0 | 2009-08-05 | EP2321833A1 | 2011-05-18 | JOGUET, Pascal; OLIVIER, Julien |
| The invention relates to a multi-contact tactile sensor including an elastically deformable interaction layer (10) and a supporting layer (11), the lower surface of the interaction layer (10) having an array of strip conductors (12) and the upper surface of the supporting layer (11) having an array of strip conductors (13) that are not parallel to the array of strip conductors (12) on the interaction layer (10). The interaction layer (10) and the supporting layer (11) are separated by a first series of rigid insulating spacers (14). A second series of conducting spacers (15) is placed in contact with at least one of the two arrays of strip conductors (12, 13). The impedance and the dimensions of the spacers (14) of the second series are determined so as to prevent contact at rest and to enable local contact during the deformation of the interaction layer (10) between the spacers (15) of the second series and the array of strip conductors of the layer opposite said spacers (15). The invention also relates to a controller for controlling one such sensor, a mult-contact tactile screen including one such sensor and a keyboard comprising a set of discrete keys, formed by one such sensor. | ||||||
| 8 | Multipoint contact touch sensor having a gap retaining means of various sizes and various impedances | JP2011521612 | 2009-08-05 | JP5524963B2 | 2014-06-18 | ジョグ,パスカル; オリビエ,ジュリアン |
| 9 | Multipoint contact touch sensor having a gap retaining means of various sizes and various impedances | JP2011521612 | 2009-08-05 | JP2011530130A | 2011-12-15 | オリビエ,ジュリアン; ジョグ,パスカル |
| A multi-contact tactile sensor including an elastically deformable interaction layer and a supporting layer, a lower surface of the interaction layer including an array of strip conductors and an upper surface of the supporting layer including an array of strip conductors that are not parallel to the array of strip conductors on the interaction layer. The interaction layer and the supporting layer are separated by a first series of rigid insulating spacers. A second series of conducting spacers is in contact with at least one of the two arrays of strip conductors. The impedance and dimensions of the spacers of the second series are determined to prevent contact at rest and enable local contact during deformation of the interaction layer between the spacers of the second series and the array of strip conductors of the layer opposite the spacers. A controller can control one such sensor, a multi-contact tactile screen can include one such sensor, and a keyboard including a set of discrete keys can be formed by one such sensor. | ||||||
| 10 | CONTACT MEMBER, SLIDING CONTACT, ELECTRICAL DEVICE AND METHOD FOR PRODUCING CONTACT MEMBER | US15900145 | 2018-02-20 | US20180174774A1 | 2018-06-21 | Ichizo SAKAMOTO; Makito MORII; Kazushi MAETA; Yuki YAMAMOTO |
| A surface layer including a base material made of a conductor and dispersed particles dispersed in the base material is formed on a surface of a fixed contact, and the dispersed particles each include a base particle that is metal oxide and a coating layer formed on an outer surface of the base particle. | ||||||
| 11 | Touch Sensor Panel with In-Plane Backup Bypass Connections | US13564859 | 2012-08-02 | US20140035833A1 | 2014-02-06 | John J. Gorsica; Dale F. Bengtson; Michael F. Olley |
| Touch sensor panels (104) have 2-D periodic arrangements of electrodes (304) connected together forming a plurality of horizontal and vertical logical lines (506, 514) for measuring X-Y coordinates of a user's touch. Electrodes forming the horizontal logical lines are interleaved with electrodes forming the vertical logical lines. Each of the vertical and horizontal logical lines includes multiple tracks (502, 504, 510, 512). The tracks of each logical line are cross connected by in-plane cross connects (314, 318) formed in the same layer by the same process that is used to form the electrodes. Diamond and square electrode embodiments are described. | ||||||
| 12 | MULTICONTACT TOUCH-SENSITIVE SENSOR INCLUDING VARIABLE-SIZE AND VARIABLE-IMPEDANCE SPACING MEANS | US13057582 | 2009-08-05 | US20110141026A1 | 2011-06-16 | Pascal Joquet; Julien Olivier |
| A multi-contact tactile sensor including an elastically deformable interaction layer and a supporting layer, a lower surface of the interaction layer including an array of strip conductors and an upper surface of the supporting layer including an array of strip conductors that are not parallel to the array of strip conductors on the interaction layer. The interaction layer and the supporting layer are separated by a first series of rigid insulating spacers. A second series of conducting spacers is in contact with at least one of the two arrays of strip conductors. The impedance and dimensions of the spacers of the second series are determined to prevent contact at rest and enable local contact during deformation of the interaction layer between the spacers of the second series and the array of strip conductors of the layer opposite the spacers. A controller can control one such sensor, a multi-contact tactile screen can include one such sensor, and a keyboard including a set of discrete keys can be formed by one such sensor. | ||||||
| 13 | Transparent conductor and panel switch | US12591598 | 2009-11-24 | US20100072052A1 | 2010-03-25 | Noriyuki Yasuda |
| The present invention provides a transparent conductor comprising a successive lamination of a support, a conductive particle layer containing a conductive particle and a first binder, and a conductive film layer containing a bead and a second binder; wherein a surface of the conductive film layer opposite from the conductive particle layer is rough. | ||||||
| 14 | Transparent conductor and panel switch | US11475915 | 2006-06-28 | US20070182457A1 | 2007-08-09 | Noriyuki Yasuda |
| The present invention provides a transparent conductor comprising a successive lamination of a support, a conductive particle layer containing a conductive particle and a first binder, and a conductive film layer containing a bead and a second binder; wherein a surface of the conductive film layer opposite from the conductive particle layer is rough. | ||||||
| 15 | Transparent conductor and panel switch | JP2005193032 | 2005-06-30 | JP4479608B2 | 2010-06-09 | 徳行 安田 |
| 16 | Transparent conductor and panel switch | JP2005193032 | 2005-06-30 | JP2007012484A | 2007-01-18 | YASUDA NORIYUKI |
| PROBLEM TO BE SOLVED: To provide a transparent conductor capable of suppressing generation of Newton rings and suppressing variation in electric resistance. SOLUTION: The transparent conductor has a substrate, a conductive particle layer containing conductive particles and a first binder, and a conductive film layer containing beads and a second binder laminated in this order, and the surface of the conductive film layer on the opposite side of the conductive particle layer has concavo-convex shape. COPYRIGHT: (C)2007,JPO&INPIT | ||||||
| 17 | Transparent touch switch | JP19632787 | 1987-08-07 | JPS6452354A | 1989-02-28 | OKAMOTO TOSHINORI |
| PURPOSE:To stabilize the switching operation by deforming insulating fine grains at the time of pressing a glass plate, making both electrodes conductive with conductive fine grains having a small grain size, and preventing the excessive compression between the insulating fine grains and the conductive fine grains with bard fine grains having the smallest grain size. CONSTITUTION:Three kinds of spacer grains 7-9 with different grain sizes are dispersed between both glass plates 2, 4. The first spacer grains 7 with the largest grain size are made of an insulating material such as synthetic resin with some elasticity, the second spacer grains 8 with the grain size smaller than that of the first spacer grains 7 are made of a conductive material at least on the surface of the grains 8, the third spacer grains 9 with the smallest grain size are made of a hard material such as glass fiber or glass, and they are mixed in the transparent resin paste 10 at the preset distribution density. The insulating fine grains 7 and the conductive fine grains 8 further continue the compression deformation by the pressing force to the glass plate 2, both electrodes l, 3 are brought into contact with the hard fine grains 9 with the smallest grain size, and the excessive depression is prevented. The malfunction of a switch caused by the crushing is thereby prevented. | ||||||
| 18 | 가변 크기 및 가변 임피던스 스페이싱 수단을 포함하는 멀티컨택트 촉각 센서 | KR1020117005193 | 2009-08-05 | KR1020110047219A | 2011-05-06 | 조개,빠스깔; 올리비에,쥴리앙 |
| 본 발명은 탄성적으로 변형가능한 인터랙션층(10) 및 지지층(11)을 포함하며, 인터랙션층(10)의 하부 표면은 스트립 도전체들(12)의 어레이를 갖고, 지지층(11)의 상부 표면은 인터랙션층(10) 상의 스트립 도전체들(12)의 어레이에 평행하지 않은 스트립 도전체들(13)의 어레이를 갖는 멀티컨택트 촉각 센서에 관한 것이다. 인터랙션층(10) 및 지지층(11)은 제1 시리즈의 단단한 절연성 스페이서들(14)에 의해 분리된다. 제2 시리즈의 도전성 스페이서들(15)이 스트립 도전체들(12, 13)의 2개의 어레이 중 적어도 하나에 접촉하여 배치된다. 제2 시리즈의 스페이서들(14)의 임피던스 및 치수는 휴지 시에 접촉을 방지하고, 인터랙션층(10)의 변형 동안 제2 시리즈의 스페이서들(15)과 상기 스페이서들(15)에 반대되는 층의 스트립 도전체들의 어레이 간의 국부적 접촉을 가능하게 하도록 결정된다. 본 발명은 또한 그러한 센서를 제어하기 위한 컨트롤러, 그러한 센서를 포함하는 멀티컨택트 촉각 스크린, 및 그러한 센서에 의해 형성된 개별 키들의 집합을 포함하는 키보드에 관한 것이다.
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| 19 | 면내 백업 바이패스 접속들을 갖는 터치 센서 패널 | KR1020130090312 | 2013-07-30 | KR101540851B1 | 2015-07-30 | 고시카,존제이.; 벵트슨,데일에프.; 올레이,마이클에프. |
| 터치센서패널들(104)은사용자의터치의 X-Y 좌표들을측정하기위한복수의수평및 수직논리적라인들(506, 514)을형성하는함께접속된전극들의 2-D 주기적배열들(304)을갖는다. 수평논리적라인들을형성하는전극들은수직논리적라인들을형성하는전극들과인터리브된다. 수직및 수평논리적라인들각각은복수의트랙들(502, 504, 510, 512)을포함한다. 각각의논리적라인의트랙들은전극들을형성하는데 이용되는동일한프로세스에의해동일한층에형성된면내교차접속들(314, 318)에의해교차접속된다. 다이아몬드및 정사각형전극실시예들이설명된다. | ||||||
| 20 | 면내 백업 바이패스 접속들을 갖는 터치 센서 패널 | KR1020130090312 | 2013-07-30 | KR1020140018120A | 2014-02-12 | 고시카,존제이.; 벵트슨,데일에프.; 올레이,마이클에프. |
| 터치센서패널들(104)은사용자의터치의 X-Y 좌표들을측정하기위한복수의수평및 수직논리적라인들(506, 514)을형성하는함께접속된전극들의 2-D 주기적배열들(304)을갖는다. 수평논리적라인들을형성하는전극들은수직논리적라인들을형성하는전극들과인터리브된다. 수직및 수평논리적라인들각각은복수의트랙들(502, 504, 510, 512)을포함한다. 각각의논리적라인의트랙들은전극들을형성하는데 이용되는동일한프로세스에의해동일한층에형성된면내교차접속들(314, 318)에의해교차접속된다. 다이아몬드및 정사각형전극실시예들이설명된다. | ||||||
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