| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 121 | 光学薄膜及其制造方法以及高分子液晶微粒 | CN200580010270.X | 2005-03-17 | CN1973217A | 2007-05-30 | 村田亮; 东健策; 川月喜弘 |
| 本发明提供图象模糊和对比度下降问题得到抑制的,适宜用于进行防眩处理的光学薄膜及其制造方法。本发明的光学薄膜具有透明基体、及设置于其至少一面上的在透明树脂相中分散平均粒径0.5~10μm的透明微粒而成的涂层,其中,透明树脂相和透明微粒中的任一方含有分子取向高分子液晶化合物,另一方由光学各向同性树脂构成。 | ||||||
| 122 | 超亮低反射率液晶显示器 | CN02806985.4 | 2002-01-29 | CN1302321C | 2007-02-28 | J·J·萨内利; D·R·布赖林; D·R·多伊尔 |
| 一种呈现提高的光学显示性能的液晶显示器(LCD)。在较佳的实施例中,LCD包括液晶显示屏,它包括一对透明基片、夹在透明基片之间的液晶材料和位于液晶显示材料和透明基片之间的透明电极。该LCD还包括后偏振组件,它包括补偿膜、装在补偿膜的后表面上的偏振器和装在补偿膜前表面上的折射率匹配的压敏粘合剂(PSA),该PSA粘合到LCD屏的后表面。该LCD还包括前偏振器组件,它包括前偏振器、装在前偏振器的后表面上的补偿膜和装在偏振器的前表面上的折射率匹配的PSA。前偏振器与后偏振器相互交叉。前偏振器可以用第二折射率匹配的光学粘结材料粘合到LCD屏的前部或可以用空气间隙隔开。透明盖装在第二折射率匹配的PSA上。透明盖较佳地是塑料板。可以使该塑料板具有纹理结构来降低眩光,或者该塑料板可以具有应用到其前表面的防反射涂层或防反射膜。代替塑料板,该透明板可以是玻璃板或触摸屏。 | ||||||
| 123 | 涂布用涂料、使用该涂料的光学薄膜的制造方法、光学薄膜、偏振片及图像显示装置 | CN200580004116.1 | 2005-02-02 | CN1918252A | 2007-02-21 | 高田胜则; 山冈尚志; 山田敦 |
| 本发明提供了一种用于形成与透明薄膜的附着性优良的涂层的涂布用涂料。所述的涂料包含热固化型树脂、无机填料和含有环己酮的混合溶剂,上述热固化型树脂的含量相对于上述热固化型树脂和无机填料的总量为5~20重量%,上述环己酮的含量相对于上述混合物溶剂的总量为25~35重量%。通过将该涂料涂布在透明薄膜上,对所形成的涂装膜进行加热处理,可以形成在透明薄膜上附着性优良的涂层。由这种方法得到的透明薄膜和涂层的层叠体可以作为防反射薄膜使用。 | ||||||
| 124 | 显示面板以及电子装置 | CN200510064619.X | 2005-04-15 | CN1776486A | 2006-05-24 | 孙嘉鸿; 蔡耀铭; 张世昌; 李光振 |
| 一显示面板包含有一基板,其上定义有一数组区域以及一显示区域、一缓冲层设于基板上以及一图案化层设于缓冲层上,其中图案化层包含有一第一区以及一第二区,分别位于数组区域与显示区域内,此外,显示面板另包含有至少一栅极绝缘层设于图案化层与缓冲层上、一栅极电极设于栅极绝缘层上的第一区内,以及一平坦化层设于栅极电极与栅极绝缘层上。 | ||||||
| 125 | 广视角偏振器和液晶显示装置 | CN02152898.5 | 2002-10-10 | CN1216303C | 2005-08-24 | 佐佐木伸一; 山冈尚志; 村上奈穗; 吉见裕之 |
| 广视角偏振器具有:偏振膜;以及通过粘结层粘结叠层在偏振膜的至少一个表面上的相位延迟器,延迟器由叠层构成的复合相位延迟器构成,其中,由具有正双折射的热塑性树脂的延迟层A支撑着胆甾型液晶取向固化层的延迟层B,该延迟层在不大于350nm的选择反射波长范围之内,形成了复合相位延迟器以便在Re和Rth分别定义为Re=(nx-ny)×d和Rth=(nx-nz)×d时,使叠层具有不小于10nm的Re和不小于50nm的Rth-Re,其中,nx和ny是面内主折射率,nz是厚度方向折射率,而d是层厚度。液晶显示装置,具有:液晶单元;以上定义并安置在液晶单元的至少一个相对面上的广视角偏振器。 | ||||||
| 126 | 广视角偏振器和液晶显示装置 | CN02152898.5 | 2002-10-10 | CN1412582A | 2003-04-23 | 佐佐木伸一; 山冈尚志; 村上奈穗; 吉见裕之 |
| 广视角偏振器具有:偏振膜;以及通过粘结层粘结叠层在偏振膜的至少一个表面上的相位延迟器,延迟器由叠层构成的复合相位延迟器构成,其中,由具有正双折射的热塑性树脂的延迟层A支撑着胆甾型液晶取向固化层的延迟层B,该延迟层在不大于350nm的选择反射波长范围之内,形成了复合相位延迟器以便在Re和Rth分别定义为Re=(nx-ny)×d和Rth=(nx-nz)×d时,使叠层具有不小于10nm的Re和不小于50nm的Rth-Re,其中,nx和ny是面内主折射率,nz是厚度方向折射率,而d是层厚度。液晶显示装置,具有:液晶单元;以上定义并安置在液晶单元的至少一个相对面上的广视角偏振器。 | ||||||
| 127 | 光扩散部件和显示装置 | CN201220209103.5 | 2012-05-10 | CN202614963U | 2012-12-19 | 山本惠美; 前田强; 菅野透 |
| 本实用新型提供一种光扩散部件和显示装置。光扩散部件具备:具有透光性的基材;在基材的一个面形成的多个光扩散部;在基材的一个面,在与光扩散部的形成区域不同的区域形成的遮光层;和光散射体。光扩散部在基材侧具有光射出端面,并且在与基材侧的相反的一侧具有面积比光射出端面的面积大的光入射端面。光扩散部的从光入射端面到上述光射出端面的高度比上述遮光层的层厚大。光散射体比所述光扩散部更靠光射出侧地配置。 | ||||||
| 128 | PHASE RETARDATION DEVICE | PCT/KR2011006642 | 2011-09-08 | WO2012033355A3 | 2012-07-19 | CHO KI HO; LEE MIN SOO; JO MIN JE; PARK HYEON WOOK |
| The present invention relates to a phase retardation device comprising a base substrate, a liquid crystal polymer layer formed on the base substrate and oriented in one direction and hardened, an optical adhesive layer interposed between the base substrate and the liquid crystal polymer layer, and antireflection layers formed on the outer surfaces of the base substrate and of the liquid crystal polymer layer, respectively. According to the present invention, the reliability of a phase retardation device, in which a liquid crystal polymer is layered on a base film, is ensured in harsh, high-temperature and high-humidity conditions. | ||||||
| 129 | INDIUM TIN OXIDE (ITO) LAYER FORMING | PCT/US2009051876 | 2009-07-27 | WO2010017054A3 | 2010-04-01 | HUANG LILI; ZHONG JOHN Z |
| A layer of material, such as crystalline indium tin oxide (ITO), is formed on top of a substrate by heating the material to a high temperature, while a temperature increase of the substrate is limited such that the temperature of the substrate does not exceed a predetermined temperature. For example, a layer including amorphous ITO can be deposited on top of the substrate, and the amorphous layer can be heated in a surface anneal process using radiation while limiting substrate temperature. Another process can pass electrical current through the amorphous ITO. In another process, the substrate is passed through a high-temperature deposition chamber quickly, such that a portion of a layer of crystalline ITO is deposited, while the temperature increase of the substrate is limited. | ||||||
| 130 | LIGHT ABSORBERS AND METHODS | PCT/US2006061013 | 2006-11-17 | WO2007094875A3 | 2008-01-31 | PIEHL ARTHUR; MONROE MICHAEL G; CONOR KELLY; STERNER JOHN R; MCKINNELL JAMES C; PRZYBYLA JAMES R; WILLIAMS JOHN L |
| For one embodiment, a reflection is reduced to substantially zero regardless of a wavelength of incident light that produced the reflection. | ||||||
| 131 | DUAL MODULATION PROJECTOR | EP18178932.2 | 2018-06-21 | EP3418798A1 | 2018-12-26 | PERTIERRA, Juan P.; RICHARDS, Martin J.; LIPPEY, Barret |
An image projector (200) comprises a controller (210) operative to receive image data (226) and to provide control signals based at least in part on said image data; a light source (209) configured to provide an illumination beam (222, 224); a reflective phase modulating spatial light modulator, SLM, (220) configured to selectively steer portions of said illumination beam (224) to create a modulated illumination beam (214) responsive to signals from said controller, said modulated illumination beam (214) including light modulated by said phase modulating SLM and unmodulated light reflected from said phase modulating SLM; an optical component (204) disposed in the path of said modulated illumination beam; a filter disposed at or near a Fourier plane of said optical component (214) and operative to at least partially block said unmodulated light reflected from said phase modulating SLM to create a filtered, modulated illumination beam (216); and an amplitude modulating spatial light modulator (206) disposed in said filtered, modulated illumination beam (216) and configured to selectively modulate the amplitude of portions of said filtered, modulated illumination beam to create an imaging beam (218).
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| 132 | METHOD AND SYSTEM USING REFRACTIVE BEAM MAPPER TO REDUCE MOIRÉ INTERFERENCE IN A DISPLAY SYSTEM INCLUDING MULTIPLE DISPLAYS | EP16850506.3 | 2016-10-03 | EP3356865A1 | 2018-08-08 | BELL, Gareth; SINGH, Darryl |
| A multi-display system (e.g., a display including multiple display panels) includes at least first and second displays (e.g., display panels or display layers) arranged substantially parallel to each other in order to display three-dimensional (3D) features to a viewer(s). An optical element(s) such as at least a refractive beam mapper (RBM) is utilized in order to reduce moire interference. | ||||||
| 133 | DYNAMIC SECURITY DEVICE | EP15823815.4 | 2015-12-23 | EP3237224A2 | 2017-11-01 | MACPHERSON, Charles D.; BRASSARD, Daniel; MALIC, Lidija; MORTON, Keith J.; VERES, Teodor; GARANZOTIS, Theodoros |
| Gravitational Janus microparticle having, a center-of-mass, a center-of-volume, and a non-uniform density, wherein: the center-of-mass and the center-of-volume are distinct. When suspended in a fluid, the microparticle substantially aligns with either: i) the gravitational field; or ii) the direction of an acceleration, such that the Janus microparticle is in substantial rotation equilibrium. After perturbation from substantial rotational equilibrium, the Janus microparticle reversibly rotates to return to substantial rotational equilibrium. The gravitational Janus microparticle may comprise at least two portions, each having distinct physical and/or chemical characteristics, wherein at least one portion provides a detectable effect following rotation and alignment of the microparticle. | ||||||
| 134 | POLARISATION INSENSITIVE OPTICAL ROUTING DEVICE | EP13702503.7 | 2013-01-23 | EP2807519B1 | 2017-10-18 | CHU, Daping; COLLINGS, Neil; MOORE, John; PIVNENKO, Mykhaylo; ROBERTSON, Brian |
| We describe methods and devices for manipulating optical signals. A method of manipulating an optical signal comprises providing a device (100) comprising a layer (106) of blue phase liquid crystal in the path of the optical signal; and applying a dynamically varying spatial pattern of voltages across the layer (106) of blue phase liquid crystal, thereby causing the refractive index of the layer (106) of blue phase liquid crystal to vary according the dynamically varying spatial pattern. | ||||||
| 135 | Antireflection film and method of producing same | EP14198889.9 | 2012-03-26 | EP2902818B1 | 2016-09-21 | Shibayama, Naoyuki; Yoshihara, Toshiaki |
| 136 | WEICHMACHER UND OPTISCHE FILME | EP12713876.6 | 2012-03-19 | EP2697237B1 | 2016-03-02 | FIEBRANZ, Bernd; RIEGER, Bernhard; PAULUTH, Detlef; LIETZAU, Lars |
| 137 | REFLECTION-TYPE LIGHT CONTROL ELEMENT | EP13806403 | 2013-06-13 | EP2866085A4 | 2015-06-24 | YAMADA YASUSEI; YOSHIMURA KAZUKI; TAJIMA KAZUKI |
| 138 | Display device and support member thereof | EP14181094.5 | 2014-08-14 | EP2840436A3 | 2015-06-10 | Sasaoka, Hiromasa; Horiuchi, Hirofumi |
A display device (100; 1 00a; 100b) comprises a display panel (20) configured to display an image on a screen on a front surface of the display panel (20), a backlight unit (40) that covers a back surface side of the display panel (20) and irradiates light toward the back surface side of the display panel (20), a back surface member (50) disposed on a back surface side of the backlight unit (40), a frame-shaped member (10) that presses a peripheral edge portion of the display panel (20) from a front surface side of the display panel (20) and is fixed to the back surface member (50), and a support member (30) provided between the display panel (20) and the backlight unit (40). The support member (30) presses at least a portion of a peripheral edge portion of the backlight unit (40) from the front surface side.
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| 139 | PHOTOSENSITIVE RESIN COMPOSITION AND ANTIREFLECTION FILM | EP13822669.1 | 2013-07-19 | EP2878607A1 | 2015-06-03 | TAIRA Yoshihiko; NAKASHIMA Ryota |
Problem To provide: A photosensitive resin compostion which is cured by radiation and exhibits excellent wear resistance, antifouling properties, marker pen ink wiping-off properties, fingerprint wiping-off properties and low refractive index, and which provides low reflectance in cases where the photosensivive resin composition is used for an antireflection film; and an antireflection film which has a cured coating film of this photosensitive resin composition. Solution A photosensitive resin composition for an antireflection film that is characterized in that a low refractive index layer contains an acrylate, a colloidal silica, and an organic modified dimethyl polysiloxane having an acryloyl group and an acrylate-modified perfluoropolyether that serve as surface modification agents; and an antireflection film which is obtained by curing the photosensitive resincomposition. |
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| 140 | ANTI-GLARE AND ANTI-SPARKLE TRANSPARENT STRUCTURES | EP13817033.7 | 2013-05-31 | EP2870505A1 | 2015-05-13 | BOOKBINDER, Dana, Craig; HART, Shandon, Dee; KOCH, Karl, William, III; WEST, James, Andrew |
| A distortion-reducing anti-glare (DRAG) structure is disclosed, wherein the DRAG structure includes first and second transparent mediums. The first transparent medium has a first refractive index and a first light-scattering anti-glare (AG) surface. The first AG surface by itself reduces glare but introduces an amount of distortion to the transmitted light. A second transparent medium having a second refractive index greater than the first refractive index is selectively added to the first transparent medium to reduce the amount of distortion in the transmitted light. | ||||||
