| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 201 | 固体表面层压板的制备方法及制得的层压板 | CN00104954.2 | 2000-04-05 | CN1270097A | 2000-10-18 | M·E·英格里姆; M·T·克瑞奇; R·M·马佛提; B·A·拉布罗克; Y·M·李 |
| 本发明披露了一种固体表面层压板的制备方法。通过将热塑性聚丙烯酸酯聚合物加入挤出生产线;将不透明层材料加入挤出生产线;并且将热塑性聚丙烯酸酯聚合物层和不透明层共挤出形成固体表面层压板而实现该方法。 | ||||||
| 202 | 聚碳酸酯模塑组合物及其作为共挤塑板材涂层的应用 | CN98807555.5 | 1998-07-14 | CN1265123A | 2000-08-30 | S·安德斯; H·勒维尔; W·尼星; W·黑瑟 |
| 本发明涉及包含紫外吸收剂和两种脱模剂的聚碳酸酯模塑组合物,涉及生产所述聚碳酸酯模塑组合物的方法,并涉及它们作为共挤塑板材层的应用。 | ||||||
| 203 | 热塑性组合物 | CN98103282.6 | 1998-07-25 | CN1215740A | 1999-05-05 | J·M·布鲁内奥; J·马格内; E·佩尔劳德; X·马卡里安 |
| 用于散射光定形制品的热塑性组合物含有一种透明热塑性聚合物,具体地是(甲基)丙烯酸(共)聚合物和平均尺寸为0.4—200微米的聚酰胺颗粒。在包括由该组合物得到的板的光显示装置中的应用。 | ||||||
| 204 | 改进的轻型装甲的车辆及其制造方法 | CN96191071.2 | 1996-08-14 | CN1172526A | 1998-02-04 | 理查德·C·梅德林; 詹姆斯·E·芒恩; 丹尼尔·T·梅德林; 梅尔文·W·弗洛伊德; 乔·I·沃尔夫 |
| 披露了一改进的轻型装甲的车辆和改装标准汽车使其成为轻型装甲的车辆的低成本方法,金属帽和槽装配在叠合车窗的周围以保护叠合车窗的边沿免受应力、水汽和大气的侵害,并且装配在标准汽车的原车窗框内,另一种叠合抗破入的车窗装配在标准汽车的原窗框内,预先制造的刚性加工成的轻型非透明装甲被模塑成可紧密地装配在标准汽车内,另外,采用一些防弹钢小块以给装甲车中的各处增加装甲和结构的整体性,总之,装甲被设计成有利于元件的低成本现场制造和低成本的安装过程以生产出支付得起的轻型装甲车。 | ||||||
| 205 | 耐热光学塑料层压薄板及其制造方法 | CN94194921.4 | 1994-09-30 | CN1142799A | 1997-02-12 | 藤井贞男; 松本贤次 |
| 由以光学透明的多芳基化合物或聚碳酸酯为代表的聚合物组成的第一层与由玻璃化温度比该层低的光学透明材料组成的第二层层压而成的、耐热性和透明性优异的光学塑料层压薄板。具备耐冲击性和刚性,而且有优异的光学特性,可用来作为光电子元件用基板。 | ||||||
| 206 | 夹层玻璃用中间膜和车辆侧窗用夹层玻璃 | CN96107782.4 | 1996-05-30 | CN1142437A | 1997-02-12 | 松扉初; 坂东明彦; 植田直树; 林聪史 |
| 本发明涉及夹层玻璃用中间膜,它是由乙烯—乙酸乙烯酯共聚物或乙烯—(甲基)丙烯酸酯共聚物100重量份、透明性改良剂0.01~4重量份、具有有机官能团和加水分解性基团的硅烷偶合剂0.01~4重量份和松香类树脂或烃类树脂1~40重量份构成的树脂组合物所形成的。本发明还涉及一种车辆侧窗用夹层玻璃,它是一种可以将车辆侧窗设计成能够升降的,由中间膜介在多块玻璃板之间进行层压加工而成的夹层玻璃,而上述的中间膜是由一种含有乙烯—乙酸乙烯酯共聚物或乙烯—(甲基)丙烯酸酯共聚物或这些共聚物的改性物作为主成分的树脂组合物所形成的。 | ||||||
| 207 | 层压板材及由其制成的织机综框 | CN96105857.9 | 1996-05-16 | CN1141236A | 1997-01-29 | 井口博一; 藤井干也; 松岛春男; 增田义典; 田中嘉治 |
| 一种层压板材和由该板材制做的一种重量轻的综框。层压板材包括(a)一复合材料层,该复合材料层包括树脂基质和由增强纤维形成的增强层和(b)一些金属层,每一金属层叠放在复合材料层的两个相对表面上。在一较好模式中,树脂片材和增强纤维的增强层交替地叠放,两个金属层的每一金属层放置在叠放层的垂直相对表面上,并且加热所获得的粘结层以及用压模机压制以促使组合层的热焊。 | ||||||
| 208 | 低模量夹层 | CN88103645 | 1988-06-16 | CN1032521A | 1989-04-26 | 查理斯·里查德·科莱曼; 索马斯·乔治·鲁卡维纳 |
| 揭示了一种用于层压热膨胀系数不同的刚硬板而不发生翘曲的低剪切模量的热塑性聚氨酯,以及含有所述低模量夹层的层压板。 | ||||||
| 209 | 交通工具装配玻璃 | CN201320639214.4 | 2013-10-16 | CN203805785U | 2014-09-03 | G·博托; B·哈尼施费格尔; O·克莱纳特; A·朗; W·舍茨勒; S·施穆克; J·米纳蒂; M·平斯克尔 |
| 本实用新型涉及一种交通工具装配玻璃,包括玻璃板(10)、光导层(12,22,32)、折射层(14)和光源(16)。所述光导层设置用于引导在其端面上耦合输入的光并且具有耦合输出装置(8,13),通过所述耦合输出装置使得所引导的光在所述光导层的至少一个主面上进行光输出。所述光导层(12,22,32)与所述玻璃板(10)材料锁合地连接。所述折射层(14)设置在所述玻璃板(10)与所述光导层(12,22,32)之间,所述折射层具有比所述光导层(12,22,32)低的折射率,并且所述折射层同时构造成片式层(14)。所述光源(16)被如此设置,使得在所述光导层(12,22,32)的至少一个端面上光耦合输入。 | ||||||
| 210 | 用于高速地面运输系统的玻璃窗 | CN201020133158.3 | 2010-02-26 | CN201857351U | 2011-06-08 | 克劳斯-迪特尔·施瓦贝; 鲁迪格尔·弗赖塔格; 乔斯·西默 |
| 本实用新型涉及用于高速地面运输系统的玻璃窗,其包括一层或多层基于锂铝硅玻璃或锂铝硅玻璃陶瓷的玻璃板。 | ||||||
| 211 | METAL-AND-RESIN COMPOSITE AND METHOD FOR MAKING THE SAME | US16293323 | 2019-03-05 | US20190193370A1 | 2019-06-27 | CHWAN-HWA CHIANG; BAO-SHEN ZHANG; CHIEH-HSIANG WANG |
| A method for making a metal-and-resin composite, including: providing a metal substrate made of stainless steel; forming a plurality of nano pores on a surface of the metal substrate by chemical etching the metal substrate; forming an intermediate layer on the metal substrate by dipping the metal substrate in a coupling agent solution, the intermediate layer filling at least portion of each nano pore; and forming a resin member by placing the metal substrate in a mold and molding molten resin on a surface of the intermediate layer, the resin member covering and bonding with the intermediate layer, treating the metal substrate with a coupling solution having a silane compound coupling agent to make the intermediate layer. | ||||||
| 212 | Methods, System and Apparatuses for in SITU Removal of Window Distortion | US16252998 | 2019-01-21 | US20190188343A1 | 2019-06-20 | Tyler R. Sterling; Garrett Murdock Myhre; John Robert Lesh, JR.; Thanh Dac Tran |
| Methods systems and apparatuses for reducing or substantially eliminating distortion in a transparent substrate in situ are disclosed. | ||||||
| 213 | LAMINATED SHEET AND LAMINATE | US15771501 | 2016-10-25 | US20180347117A1 | 2018-12-06 | Hayato FUSHIMI; Hirokazu SUNAGAWA; Go BANZASHI |
| An object of the present invention is to provide an ultrafine cellulose fiber-containing sheet, in which generation of warp (curl) is suppressed. The present invention relates to a laminated sheet having two or more layers of sheet comprising ultrafine cellulose fibers with a fiber width of 1000 nm or less, wherein among two or more layers of the sheet, when the thickness (μm) of the thickest sheet is defined as Tmax and the thickness (μm) of the thinnest sheet is defined as Tmin, the value of Tmax/Tmin is 3 or less, and the thickness of a single layer of the sheet is 15 μm or more. | ||||||
| 214 | INTEGRATED TRANSPARENT CONDUCTIVE FILMS FOR THERMAL FORMING APPLICATIONS | US15763547 | 2016-09-27 | US20180279471A1 | 2018-09-27 | Zhe Chen; Jing Chen; Yonglei Xu; Yuzhen Xu |
| A method of thermoforming an article from an integrated transparent conductive film includes heating the integrated transparent conductive film to a formable temperature in a mold, wherein the integrated transparent conductive film comprises a substrate comprising a transparent thermoplastic material, wherein the substrate includes a substrate first surface and a substrate second surface; a transparent conductive layer disposed adjacent to the substrate, wherein the transparent conductive layer includes a transparent conductive layer first surfaced disposed on the substrate first surface; and an electrical circuit etched onto a transparent conductive layer second surface; thermoforming the integrated transparent conductive film to the article comprising the mold shape; cooling the formed article; and removing the formed article form the mold; wherein the formed article has a functional electrical circuit after thermoforming. | ||||||
| 215 | Adhesive Fabrication Process for Garments and Other Fabric Products | US15869942 | 2018-01-12 | US20180263319A1 | 2018-09-20 | Joseph E. Gallagher |
| A process for fabricating a three-dimensional, multi-layered fabric product with a moisture barrier is provided. A partially seamed inner lining fabric assembly having at least a two-dimensional shape is laminated with a membrane barrier film having flaps left un-laminated to cover at least one seam. The inner lining fabric assembly is further seamed and flaps of the of the membrane barrier film overlapped into contact with each other and sealed to provide a continuous moisture barrier. A process for fabricating a stretchable section of a garment with a moisture barrier is also provided. At least a section of a garment is formed from fibers arranged in a pattern having a direction of stretch in one direction and a three-dimensional surface texture such that a portion of the fibers protrude above another portion of the fibers. The stretchable section is stretched in the direction of stretch. Segments of a membrane barrier film are adhered to an outer edge of the protruding portion of the fibers while the section is stretched in the direction of stretch, leaving intermediate segments of the barrier film free from adherence to the section. In this way, the intermediate segments of the membrane barrier film include slack that folds up to form ruches when the section is in a relaxed state. | ||||||
| 216 | Glass plate substitute film, and display device | US15007691 | 2016-01-27 | US10072175B2 | 2018-09-11 | Akira Arakawa |
| Provided is a glass plate substitute film having superior substitutability for glass plates due to having superior impact resistance and light weight compared with glass plates, as well as sufficient scratch-preventing property, blooming resistance and yellowing resistance. The glass plate substitute film of the present invention includes: a substrate layer; and one or a plurality of surface layers overlaid on one side or both two sides of the substrate layer, wherein the substrate layer contains as a principal component a polycarbonate having a constitutional unit derived from a dihydroxy compound represented by the following formula (1), and wherein the dihydroxy compound is an extract of a plant or a derivative thereof. At least one surface layer of the one or the plurality of surface layers preferably contains an active energy ray-curable resin as a principal component. The active energy ray-curable resin is preferably an ultraviolet ray-curable epoxy resin. | ||||||
| 217 | METHOD FOR MANUFACTURING EXTERIOR HOUSING AND ELECTRONIC DEVICE COMPRISING SAME | US15751212 | 2016-05-26 | US20180249586A1 | 2018-08-30 | Young-Gyun KIM; Minjung KIM; Jeeyoung OH; Gyoosug LEE |
| An electronic device of the present invention comprises: an exterior housing including a first surface facing a first direction, and a second surface facing a second direction opposite to the first direction; a display of which at least a part is exposed through the first surface; and a polymer plate which forms at least a part of the second surface of the housing. The polymer plate comprises: at least one opaque layer; at least one polymer layer that is translucent or transparent and is disposed on the at least one opaque layer; and a coating layer that is disposed on the at least one polymer layer and has a hardness greater than or equal to a selected hardness. Each of the at least one opaque layer, the at least one polymer layer, and the coating layer may comprise a first surface, and a second surface extending from the first surface so that at least a part thereof is bent. Other embodiments are also possible. | ||||||
| 218 | METAL RESIN COMPOSITE MOLDED BODY AND METHOD FOR PRODUCING THE SAME | US15580175 | 2016-04-28 | US20180229263A1 | 2018-08-16 | Yusuke Nishikori; Masanori Endo; Miyuki Yoshida |
| A metal resin composite molded body wherein various metal bases and a resin molded body are integrally and firmly bonded with each other; and a versatile method for producing this metal resin composite molded body are provided. Particularly provided are: a metal resin composite molded body wherein an aluminum base and a polyolefin resin molded body are integrally and firmly bonded with each other; and a simple method for producing this metal resin composite molded body. A metal resin composite molded body comprises a metal base, a polypropylene resin layer and a thermoplastic resin molded body. The polypropylene resin layer is bonded to the metal base with a hydrophilic surface being interposed therebetween. The hydrophilic surface is formed on the metal base. The thermoplastic resin molded body is bonded to the polypropylene resin layer by means of anchoring effect and compatibilizing effect with the polypropylene resin layer. | ||||||
| 219 | Light weight temperature resistant transparent laminate structure | US13452424 | 2012-04-20 | US10046540B2 | 2018-08-14 | Katherine T Leighton; Edgar L Aleshire; Wiktor Serafin; Christopher M Snively; Carsten Weinhold; Theodore A Wegert; Kurt Schaupert |
| A transparent laminate structure is provided that includes a front section, a rear section, and a middle section securing the front and rear sections to one another with a gap therebetween. The front section has a strike face formed of an impact resistant layer and a polymer backing layer bonded to the impact resistant layer by an interlayer. The rear section has a forward face comprising at least one polymer layer. The front and middle sections can form an integral subassembly. | ||||||
| 220 | HEATING GLAZING WITH THINNED OUTER SHEET OF GLASS AND HEATING LAYER WITH FLOW SEPARATION LINES | US15738757 | 2016-06-30 | US20180208293A1 | 2018-07-26 | Thomas TONDU; Pierre CHAUSSADE; Vincent LEGOIS |
| A laminated glazing includes a first structural ply assembled with a first glass sheet of 0.5 to 1.5 mm thickness by way of a first adhesive interlayer, the first glass sheet forming a first exterior face of the laminated glazing, the face of the first glass sheet oriented toward the first adhesive interlayer bearing a first conductive heating layer of 2 Ångströms to 500 nm thickness, and the first conductive heating layer including flow-separating lines of 0.05 to 0.2 mm thickness spaced apart by 8 to 20 mm. | ||||||
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