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 |
|---|---|---|---|---|---|---|
| 1 | 光固化性组合物和使用所述组合物的膜的制造方法 | CN201380048923.8 | 2013-09-20 | CN104640884A | 2015-05-20 | 伊藤俊树; 饭田贤一; 松藤奈央子 |
| 要用于制造具有高生产性的膜的本发明的光固化性组合物是一种光固化性组合物,其要用于在所述光固化性组合物与在其表面上具有凹凸图案的模具接触的状态下,通过将所述光固化性组合物使用光来固化而制造具有预定图案形状的膜,所述光固化性组合物包括:聚合性化合物;光聚合引发剂;用于通过光刺激来产生气体的感光性气体产生剂;和用于增加在所述模具和所述光固化性组合物之间的界面处的产生自所述感光性气体产生剂的所述气体的聚集速率的气体产生促进剂,其中所述气体产生促进剂包括没有聚合性取代基的含氟原子的表面活性剂。 | ||||||
| 2 | 快速加热和冷却的模具 | CN201380032277.6 | 2013-06-19 | CN104412705A | 2015-03-11 | A·基沙尔德; J·费让布然 |
| 本发明涉及一种模具,包括第一部分(101),其中所述第一部分包括:骨架(111),所述骨架上设有成型区(112),用于在所述成型区和骨架之间形成机械接触面(115);在所述接触面和所述成型区(112)之间的腔室(131)内沿纵向方向延伸的第一电感器(132);以及在所述成型区和骨架之间的接触面延伸的冷却装置(140)。 | ||||||
| 3 | 具有高的表面质量的成型体 | CN201280058169.1 | 2012-11-28 | CN103946309A | 2014-07-23 | T.图尔克; U.格罗泽; M.德布勒; B.泽米施; A.迈尔; C.克林肯贝格; R.奥泽 |
| 本发明涉及热塑性组合物,含有:A)30.0-100.0重量份的至少一种芳族聚碳酸酯,B)0.0重量份-50.0重量份的橡胶改性的接枝聚合物和/或乙烯基共聚物,C)0.00-50.00重量份的聚酯,D)5.0-50.0重量份的至少一种具有选自如下的颗粒形状的无机填料:球形/立方体、管状/圆盘形和片状几何结构,E)0.00–5.00重量份的其它常规添加剂。本发明进一步涉及具有高的表面质量、高的尺寸稳定性和高的耐热变形性的热塑性成型体,以及热塑性模塑组合物和用于制备所述成型体的方法。本发明另外涉及由所述热塑性成型部件制备的涂敷的成品部件。 | ||||||
| 4 | 光固化性组合物和使用所述组合物的膜的制造方法 | CN201380048923.8 | 2013-09-20 | CN104640884B | 2016-10-12 | 伊藤俊树; 饭田贤一; 松藤奈央子 |
| 要用于制造具有高生产性的膜的本发明的光固化性组合物是一种光固化性组合物,其要用于在所述光固化性组合物与在其表面上具有凹凸图案的模具接触的状态下,通过将所述光固化性组合物使用光来固化而制造具有预定图案形状的膜,所述光固化性组合物包括:聚合性化合物;光聚合引发剂;用于通过光刺激来产生气体的感光性气体产生剂;和用于增加在所述模具和所述光固化性组合物之间的界面处的产生自所述感光性气体产生剂的所述气体的聚集速率的气体产生促进剂,其中所述气体产生促进剂包括没有聚合性取代基的含氟原子的表面活性剂。 | ||||||
| 5 | 注塑成型品的制造方法及注塑成型品 | CN201280011911.3 | 2012-02-29 | CN103415380B | 2016-01-20 | 宫下贵之; 广田晋一; 高嶋正人 |
| 本发明提供生产率优异的注塑成型品的制造方法,其可以抑制毛刺的产生量并获得高结晶度的成型品。所述制造方法使用在模具内表面形成有由多孔氧化锆构成的隔热层的模具,在100℃以下的模具温度下对聚亚芳基硫醚类树脂组合物进行注塑成型。隔热层优选使用喷镀法形成的物质。另外,隔热层优选的导热系数为2W/m·K以下。另外,隔热层优选的厚度为200μm以上。 | ||||||
| 6 | 聚酯粉末组合物、方法及制品 | CN200980157286.1 | 2009-12-22 | CN102325645B | 2015-07-15 | 拉斐尔·马蒂诺尼 |
| 本发明提供了一种粉末组合物、制品以及由这种粉末组合物形成制品的方法。在一个实施方式中,所述粉末组合物包含至少一种聚酯聚合物粉末和一定量的增强颗粒,所述增强颗粒具有优选至少5∶1的长径比。在另一实施方式中,所述粉末组合物包含至少一种聚酯聚合物粉末,该聚酯聚合物粉末具有中-高熔融温度、是芳族的并且是半结晶的。在一个优选的实施方式中,所述粉末组合物能够经由激光烧结工艺形成在高温环境下具有一个或多个所需机械性质的三维制品。 | ||||||
| 7 | 注塑成型品的制造方法及注塑成型品 | CN201280011911.3 | 2012-02-29 | CN103415380A | 2013-11-27 | 宫下贵之; 广田晋一; 高嶋正人 |
| 本发明提供生产率优异的注塑成型品的制造方法,其可以抑制毛刺的产生量并获得高结晶度的成型品。所述制造方法使用在模具内表面形成有由多孔氧化锆构成的隔热层的模具,在100℃以下的模具温度下对聚亚芳基硫醚类树脂组合物进行注塑成型。隔热层优选使用喷镀法形成的物质。另外,隔热层优选的导热系数为2W/m·K以下。另外,隔热层优选的厚度为200μm以上。 | ||||||
| 8 | 快速加热和冷却的模具 | CN201380032277.6 | 2013-06-19 | CN104412705B | 2016-09-14 | A·基沙尔德; J·费让布然 |
| 本发明涉及一种模具,包括第一部分(101),其中所述第一部分包括:骨架(111),所述骨架上设有成型区(112),用于在所述成型区和骨架之间形成机械接触面(115);在所述接触面和所述成型区(112)之间的腔室(131)内沿纵向方向延伸的第一电感器(132);以及在所述成型区和骨架之间的接触面延伸的冷却装置(140)。 | ||||||
| 9 | 具有高的表面质量的成型体 | CN201280058169.1 | 2012-11-28 | CN103946309B | 2016-01-20 | T.图尔克; U.格罗泽; M.德布勒; B.泽米施; A.迈尔; C.克林肯贝格; R.奥泽 |
| 本发明涉及热塑性组合物,含有:A)30.0-100.0重量份的至少一种芳族聚碳酸酯,B)0.0重量份-50.0重量份的橡胶改性的接枝聚合物和/或乙烯基共聚物,C)0.00-50.00重量份的聚酯,D)5.0-50.0重量份的至少一种具有选自如下的颗粒形状的无机填料:球形/立方体、管状/圆盘形和片状几何结构,E)0.00–5.00重量份的其它常规添加剂。本发明进一步涉及具有高的表面质量、高的尺寸稳定性和高的耐热变形性的热塑性成型体,以及热塑性模塑组合物和用于制备所述成型体的方法。本发明另外涉及由所述热塑性成型部件制备的涂敷的成品部件。 | ||||||
| 10 | 聚酯粉末组合物、方法及制品 | CN200980157286.1 | 2009-12-22 | CN102325645A | 2012-01-18 | 拉斐尔·马蒂诺尼 |
| 本发明提供了一种粉末组合物、制品以及由这种粉末组合物形成制品的方法。在一个实施方式中,所述粉末组合物包含至少一种聚酯聚合物粉末和一定量的增强颗粒,所述增强颗粒具有优选至少5∶1的长径比。在另一实施方式中,所述粉末组合物包含至少一种聚酯聚合物粉末,该聚酯聚合物粉末具有中-高熔融温度、是芳族的并且是半结晶的。在一个优选的实施方式中,所述粉末组合物能够经由激光烧结工艺形成在高温环境下具有一个或多个所需机械性质的三维制品。 | ||||||
| 11 | 光硬化性組成物及びこれを用いた膜の製造方法 | JP2013188418 | 2013-09-11 | JP6278645B2 | 2018-02-14 | 伊藤 俊樹; 飯田 賢一; 松藤 奈央子; 北川 健司 |
| 12 | Airgel-based types for Mems production | JP2009008849 | 2009-01-19 | JP5575404B2 | 2014-08-20 | ロバート・ジェイ・カールソン |
| The invention is directed to a patterned aerogel-based layer that serves as a mold for at least part of a microelectromechanical feature. The density of an aerogel is less than that of typical materials used in MEMS fabrication, such as poly-silicon, silicon oxide, single-crystal silicon, metals, metal alloys, and the like. Therefore, one may form structural features in an aerogel-based layer at rates significantly higher than the rates at which structural features can be formed in denser materials. The invention further includes a method of patterning an aerogel-based layer to produce such an aerogel-based mold. The invention further includes a method of fabricating a microelectromechanical feature using an aerogel-based mold. This method includes depositing a dense material layer directly onto the outline of at least part of a microelectromechanical feature that has been formed in the aerogel-based layer. | ||||||
| 13 | Method for producing injection molding and injection molding | JP2011050878 | 2011-03-08 | JP2012187728A | 2012-10-04 | MIYASHITA TAKAYUKI; HIROTA SHINICHI; TAKASHIMA MASATO |
| PROBLEM TO BE SOLVED: To provide a method for producing an injection molding, by which the molding of high crystallinity can be obtained while suppressing production amount of burrs and productivity is excellent.SOLUTION: A polyarylene sulfide based resin composition is injection-molded at metal mold temperature of ≤100°C by using a metal mold, at an inner surface of which a heat insulation layer consisting of porous zirconia is formed. Preferably, the heat insulation layer is formed by a thermal spraying method. Moreover, the heat insulation layer preferably has thermal conductivity of ≤2 W/m×K. Further, the heat insulation layer preferably has thickness of ≥200 μm. | ||||||
| 14 | Forming device of optical information recording medium | JP24809688 | 1988-09-30 | JPH0295813A | 1990-04-06 | NISHIZAWA AKIRA; KONDO TETSUYA |
| PURPOSE:To obtain a comparatively simple and not expensive device by a structure wherein a matrix made of ultraviolet transmitting material, a pressing means, with which the surface of ultraviolet non-transmitting plastic board material is brought into close contact with the face having transferring pit train of the matrix, and an ultraviolet irradiating means, which is arranged at the back of the matrix, are equipped. CONSTITUTION:An ultraviolet lamp 2 is lit under the condition that a board material 8a is placed on the top surface of a matrix 1 made quartz glass. Since the quartz glass matrix 1 hardly absorbs ultraviolet rays, the light energy of the ultraviolet lamp 2 reaches the surface of the board material with almost no damping of the energy. Since the polycarbonate board material 8a is hard to transmit ultraviolet rays, almost all the light energy is absorbed at the surface of the board material 8a, resulting in bringing said surface up to high temperature and in the gelatinized state. The resultant board material 8a, the surface of which has been gelatinized, is pressed against the surface of the matrix 1 with a device, resulting in transferring the reversed shapes of the transferring pits 1a of the matrix 1 to the surface of the board material. Next, since environment has large heat capacity, when the irradiation with the ultraviolet lamp 2 is stopped, the surface of the board material 8a is cooled rapidly, resulting in easily separating a formed item from the matrix. | ||||||
| 15 | JPH028887B2 - | JP12376381 | 1981-08-07 | JPH028887B2 | 1990-02-27 | SHIDA CHOKICHIRO |
| 16 | High-conductivity two-dimensional polyaniline nanosheets and method for fabricating the same | US15130911 | 2016-04-15 | US10056167B2 | 2018-08-21 | Moon Jeong Park; Il Young Choi; Joung Phil Lee |
| The present invention relates to a new method of synthesizing two-dimensional polyaniline (PANI) nanosheets using ice as a removable hard template. The method comprises polymerizing aniline on an ice surface. The synthesized PANI nanosheets show distinctly high current flows of 5.5 mA at 1 V and a high electrical conductivity of 35 S/cm, which mark a significant improvement over previous values on other PANIs reported over the past decades. These improved electrical properties of the PANI nanosheets are attributed to the long-range ordered edge-on π-stacking of the quinoid ring, ascribed to the ice surface-assisted vertical growth of PANI. The PANI nanosheet can be easily transferred onto various types of substrates via float-off from the ice surfaces. In addition, PANI can be patterned into any shape using predetermined masks, and this is expected to facilitate the eventual convenient and inexpensive application of conducting polymers in versatile electronic device forms. | ||||||
| 17 | Photocurable composition and method of manufacturing film using the composition | US14405929 | 2013-09-11 | US09982102B2 | 2018-05-29 | Toshiki Ito; Chieko Mihara; Youji Kawasaki |
| Provided are a photocurable composition having high filling property and capable of reducing a mold release force upon production of a film through the utilization of a photo-imprint method, and a method of manufacturing a film using the photocurable composition. The photocurable composition is a photocurable composition, including at least the following component (A) to component (C): (A) a polymerizable compound; (B) a photopolymerization initiator; and (C) a surfactant represented by the following general formula (1): Rf1-Rc-X. (1) | ||||||
| 18 | Method for making an article from a curable material | US14381574 | 2012-02-27 | US09757876B2 | 2017-09-12 | Sergei Douglas Broeska; Leon Fainstein |
| The present disclosure is directed at a method for making an article from a curable material, such as pliable fibre-reinforced polymer. The method includes printing a dissolvable, three dimensional substructure using a substructure material; applying the curable material to the substructure; curing the curable material while it is on the substructure; and dissolving the substructure using a dissolving agent. Using a 3D printer to print the substructure allows for faster and more economical manufacture of composite articles, such as prototype parts, relative to conventional methods that utilize CNC machines. | ||||||
| 19 | Photocurable composition and method of manufacturing film using the composition | US14419382 | 2013-09-20 | US09541826B2 | 2017-01-10 | Toshiki Ito; Kenichi Iida; Naoko Matsufuji |
| A photocurable composition of the present invention to be used for manufacturing a film with high productivity is a photocurable composition to be used for manufacturing a film having a predetermined pattern shape by curing the photocurable composition with light under a state where the photocurable composition is brought into contact with a mold having concavo-convex on a surface thereof, the photocurable composition including: a polymerizable compound; a photopolymerization initiator; a photosensitive gas generating agent for generating a gas through light stimulation; and a gas generation promotor for increasing an aggregation rate of the gas generated from the photosensitive gas generating agent at an interface between the mold and the photocurable composition, in which the gas generation promotor includes a fluorine atom-containing surfactant that is free of a polymerizable substituent. | ||||||
| 20 | APPARATUSES AND METHODS UTILIZING ETCH STOP LAYERS | US15163214 | 2016-05-24 | US20160265119A1 | 2016-09-15 | Michael R. Feldbaum; Koichi Wago; Gennady Gauzner; Kim Y. Lee; David S. Kuo |
| Provided herein is an apparatus, including a substrate; an etch stop layer overlying the substrate, wherein the etch stop layer is substantially resistant to etching conditions; and a patterned layer overlying the etch stop layer, wherein the patterned layer is substantially labile to the etching conditions, and wherein the patterned layer comprises a number of features including substantially consistent feature profiles among regions of high feature density and regions of low feature density. | ||||||
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