| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 181 | LASER CUT ARTICLES | US15842236 | 2017-12-14 | US20180104945A1 | 2018-04-19 | Pingfan Wu; Edward J. Woo; Ian R. Owen; Bruce E. Tait; Frederick P. LaPlant; Patrick R. Fleming |
| Laser conversion of multilayer optical film bodies comprising polyester and polycarbonate materials. | ||||||
| 182 | ELECTROMAGNETIC SHIELDING MATERIAL | US15562472 | 2015-06-18 | US20180079177A1 | 2018-03-22 | KOICHIRO TANAKA; KENJI SATO |
| Provided is an electromagnetic shielding material having improved electromagnetic shielding properties, light weight properties and formability. The present invention relates to an electromagnetic shielding material having a structure in which at least three metal foils are laminated via insulating layers, wherein all of combinations of the metal foils and the insulating layers making up the electromagnetic shielding material satisfy the equation: σM×dM×dR≧3×10−3, in which: the symbol σM represents conductivity of each metal foil at 20° C. (S/m); the symbol dM represents the thickness of each metal foil (m); and the symbol dR represents the thickness of each insulating layer (m). | ||||||
| 183 | Resin-soluble veils for composite article fabrication and methods of manufacturing the same | US14566072 | 2014-12-10 | US09902118B2 | 2018-02-27 | Dominique Ponsolle; Robert Blackburn; Billy Harmon; Richard Price; Marc Doyle |
| Embodiments of the invention are directed to resin-soluble thermoplastic veils for use in liquid resin infusion processes, methods of manufacturing resin-soluble thermoplastic veils for use in liquid resin infusion processes, and methods of manufacturing composite articles using resin-soluble thermoplastic veils for use in liquid resin infusion applications. The resin-soluble thermoplastic veils according to embodiments of the invention and of which function as a toughening agent in composites having the veil incorporated therein have improved characteristics including, but not limited to, increased uniformity and decreased thickness relative to prior art veils. These characteristics translate into improvements in the processing of a composite article including, but not limited to, a substantial or complete elimination in premature dissolution of the veil during cure. The resultant composite article also realizes improvements including, but not limited to, distribution evenness of the toughening agent throughout the composite. | ||||||
| 184 | LITHIUM-AIR BATTERY SEPARATORS AND RELATED COMPOSITIONS | US15220237 | 2016-07-26 | US20180034031A1 | 2018-02-01 | Paula T. Hammond-Cunningham; Sun Hwa Lee |
| Battery separators for lithium-air batteries are provided. In some embodiments, a lithium-air battery may comprise one or more electrochemical cells including an anode, a cathode, an electrolyte, and a battery separator positioned between the anode and the cathode. The battery separator may comprise a porous membrane having a lithium ion conductive film on at least a portion of the porous membrane. The lithium ion conductive film may comprise layers designed to impart beneficial properties to the porous membrane and/or battery, such as resistance to dendrite formation, while having relatively minimal or no adverse effects on one or more important properties of the porous membrane (e.g., ionic conductivity, electrolyte permeability, weight, mechanical stability) and/or the overall battery. The respective characteristics and number of the layers in the lithium ion conductive film may be selected to impart desirable properties to the battery separator and/or the battery while having relatively minimal or no adverse effects. | ||||||
| 185 | LAYER SEQUENCE REPEATER MODULE FOR A MODULAR DISK CO-EXTRUSION DIE AND PRODUCTS THEREOF | US15684751 | 2017-08-23 | US20180029338A1 | 2018-02-01 | Henry G. Schirmer |
| A layer sequence repeater module for a co-extrusion die includes a cell formed of a plurality of thin annular disks stacked on top of each other in an axial direction of the co-extrusion die. Each disk includes a plurality of openings aligned with openings in the adjacent disks, thus forming multiple inner and outer melt passages. At least one of the layer sequence repeater module includes at least one first cap disk, at least one second cap disk, at least one distribution disk, at least one repeater disk and at least one spreader disk. The layer sequence repeater module may be a separately assembled and individually removable module of the co-extrusion die. Alternatively or additionally, the layer sequence repeater module may be incorporated into a module of the co-extrusion die. | ||||||
| 186 | Laminated film | US14768361 | 2014-03-14 | US09878523B2 | 2018-01-30 | Takayuki Uto; Kazuyoshi Ota; Yoshihiro Masuda; Wataru Goda |
| [Problem] Provided is a laminated film which exhibits good general adhesiveness to PVAs, EVAs and PVBs having a wide range of saponification degrees as well as good moist heat-resistant adhesiveness.[Means for Solution] The laminated film comprises a resin layer (α) composed of an aliphatic urethane structure-containing resin composition (I) on at least one side of a thermoplastic resin film, the resin layer (α) satisfying the following properties (i) and (ii): (i) the resin layer (α) has a surface free energy (sum of the dispersion force and the polar force) of not less than 30 mN/m and not greater than 45 mN/m; and (ii) the resin layer (α) has a polar force of not less than 5.0 mN/m and not greater than 15.0 mN/m. | ||||||
| 187 | FILTER MEDIUM FOR AIR FILTER, FILTER PACK, AIR FILTER UNIT, AND METHOD FOR PRODUCING FILTER MEDIUM FOR AIR FILTER | US15538597 | 2015-12-24 | US20170348626A1 | 2017-12-07 | Tatsumi SAKANO; Kunihiko INUI; Yoshiyuki SHIBUYA |
| A filter medium includes first and second porous films mainly containing fluororesin, and a pre-collection member upstream of the first film. The second film is downstream of the first film. The pre-collection member has a pressure drop when air is passed through at a flow rate of 5.3 cm/s of between 15 Pa and 55 Pa, a collection efficiency of NaCl particles having a particle diameter of 0.3 μm when air containing the particles is passed hrough at a flow rate of 5.3 cm/s of between 25% and 80%, a thickness of 0.4 mm or less, and a PF value between 7 and 15. The PF value={−log((100−collection efficiency (%))/100)}/(pressure drop (Pa)/1000). A ratio of the PF value of the pre-collection member to the PF value when the first and second films are overlapped, is between 0.20 and 0.45. The filter medium can be used in a filter pack or filter unit, and may be produced by integrating the first and second films and the pre-collection member using heat lamination. | ||||||
| 188 | COMPOSITE MATERIAL, SHELL FOR MOBILE DEVICE, THEIR MANUFACTURING METHODS, AND MOBILE DEVICE | US15532882 | 2015-12-01 | US20170346175A1 | 2017-11-30 | Lihong ZHAO; Wenhai LUO; Dingwen MAO |
| Disclosed are a composite material, a shell for a mobile device, their manufacturing methods, and a mobile device. The composite material includes: a first metal substrate (100); a first resin fibre plate (200) disposed on an upper surface of the first metal substrate; an antenna layer (300) disposed on an upper surface of the first resin fibre plate; a second resin fibre plate (400) disposed on an upper surface of the antenna layer; and a second metal substrate (500) disposed on an upper surface of the second resin fibre plate. | ||||||
| 189 | ELECTRICALLY HEATABLE LAYER STACK | US15482178 | 2017-04-07 | US20170332443A1 | 2017-11-16 | Peter LINDE |
| An electrically heatable layer stack is disclosed. The electrically heatable layer stack includes at least two substrate layers, and at least one carbon nanotubes-, CNT-, layer, which is arranged between the substrate layers and which is configured to conduct an electric current. The substrate layers and the at least one CNT-layer are configured to produce heating of at least one of the substrate layers when an electric current is applied to the at least one CNT-layer. A vehicle assembly group, an aircraft, a method and a system for manufacturing an electrically heatable layer stack are also disclosed. | ||||||
| 190 | CARBON FIBER PREPREG | US15220344 | 2016-07-26 | US20170282508A1 | 2017-10-05 | CHIH-HSIAO CHIEN; CHING-CHUN LIN |
| A carbon fiber prepreg is disclosed. The carbon fiber prepreg, exclusive of any additive scrims, comprises a multiple carbon fiber layers and resin layers in an integral form, characterized in that: for the carbon fiber prepreg at each standard unit of the carbon fiber prepreg (g/m2, indicating a weight percentage of the carbon fiber and the resin in the carbon fiber prepreg), the resin layers and the carbon fiber layers are both of multi-layer in a manner that each resin layer is impregnated with two adjacent carbon fiber layers so that the carbon fiber layers are able to be consolidated firmly for strengthening overall structure of the carbon fiber prepreg. | ||||||
| 191 | COMPOSITE WOOD PANELS WITH CORRUGATED CORES AND METHOD OF MANUFACTURING SAME | US15414810 | 2017-01-25 | US20170266839A1 | 2017-09-21 | RONALD J. BATTY |
| A composite wood panel is manufactured from thin wood laminae cut from wood unsuitable for peeler logs or dimensional lumber. A cold set adhesive is applied to the wood laminae and they are formed into a randomly oriented mat that is cold rolled into a thin, pliable cold rolled stock that can be corrugated. A hot set adhesive may also be applied to the laminae to improve strength of the composite wood panel. The hot set adhesive is set in a hot press after the cold rolled stock is produced. | ||||||
| 192 | DURABLE SOLAR MIRROR FILM WITH ASYMMETRIC CONSTRUCTION | US15121512 | 2015-03-02 | US20170242164A1 | 2017-08-24 | MARK B. O'NEILL; DIANE NORTH |
| The present disclosure generally relates to multilayer optical films having an asymmetric construction and durable solar mirror films comprising such multilayer optical films, as well as constructions including durable solar mirror films. | ||||||
| 193 | METHOD FOR MAKING A BIOFABRICATED MATERIAL CONTAINING COLLAGEN FIBRILS | US15433650 | 2017-02-15 | US20170233834A1 | 2017-08-17 | Brendan Patrick PURCELL; David Thomas Williamson; Francoise Suzanne Marga; Susan J. Schofer; Darryl Miles Cassingham; Stephen M. Spinella; Amy Congdon |
| Described herein is a method for producing a biofabricated material from collagen or collagen-like proteins which are recombinantly produced and which contain substantially no 3-hydroxyproline. The collagen or collagen-like proteins are isolated from animal sources, or produced by recombinant DNA techniques or by chemical synthesis. The collagen or collagen-like proteins are fibrillated, crosslinked, dehydrated and lubricated thus forming the biofabricated material having a substantially uniform network of collagen fibrils. | ||||||
| 194 | Shockwave Controlled Ballistic Protection | US15497948 | 2017-04-26 | US20170227333A1 | 2017-08-10 | Guillermo R. Villalobos; Shyam S. Bayya; Woohong Kim; Bryan Sadowski; Michael Hunt; Robert E. Miklos; Colin C. Baker; Jasbinder S. Sanghera; Alex E. Moser |
| A transparent composite armor is made of tens to hundreds or even thousands of thin layers of material each with a thickness of 10-500 μm. An appropriate amount of impedance mismatch between the layers causes some reflection at each interface but limit the amplitude of the resulting tensile wave below the tensile strength of the constituent materials. The result is an improvement in ballistic performance and that will result is a significant impact in reducing size, weight, and volume of the armor. | ||||||
| 195 | Multilayer structure, inner liner for pneumatic tire, and pneumatic tire | US14118933 | 2012-05-29 | US09724968B2 | 2017-08-08 | Hideki Kitano; Tetsuo Amamoto; Takatsugu Tanaka; Yuwa Takahashi; Nahoto Hayashi; Masao Hikasa; Yusuke Tanaka |
| To provide a multilayer structure that may adhere to rubber material without the necessity of providing an adhesive layer, an inner liner and a pneumatic tire using the multilayer structure. According to the present invention, a multilayer structure 1 is formed by alternately laminating elastomer layers 3 containing thermoplastic elastomer and barrier layers 2 containing a gas barrier resin, wherein an outermost layer 4 laminated uppermost among layers constituting the multilayer structure 1 contains an elastomer component that may heat-adhere to diene rubber. | ||||||
| 196 | IMPROVED FLAME RESISTANT THERMAL LINERS AND GARMENTS MADE WITH SAME | US15404701 | 2017-01-12 | US20170203540A1 | 2017-07-20 | Matthew Lucius Colatruglio; Michael T. Stanhope |
| Embodiments of the present invention replace relatively bulky nonwoven thermal insulating materials used in thermal liners with thin, lightweight, flexible films that maintain or improve TPP performance while reducing the thickness, and enhancing the flexibility, of the thermal liner so as to increase wearer comfort. Moreover, the films incorporated into the thermal liners can be both air and vapor permeable such that the TPP performance is not realized at the expense of THL performance. Rather, the THL performance of garments incorporating embodiments of thermal liners contemplated herein is comparable to—if not improved over—garments formed with traditional thermal liners. | ||||||
| 197 | REINFORCED THERMOPLASTIC DUCTS AND THEIR MANUFACTURE | US14989763 | 2016-01-06 | US20170191585A1 | 2017-07-06 | Douglas Dean Maben |
| Duct segments that define a channel for conveying a fluid, where the duct wall includes a sheath of reinforcing fabric incorporating multiple reinforcing fibers, and a thermoplastic fused with the sheath of reinforcing fabric. The duct segments may be prepared by wrapping a mandrel configured to define the inner mold line of a desired duct segment with a thermoplastic film, enveloping the wrapped mandrel with a reinforcing sheath incorporating reinforcing fibers; wrapping the enveloped mandrel with another thermoplastic film to form a multilayer duct segment precursor; enclosing the mandrel and multilayer duct segment precursor within an outer mold defining the outer mold line for the desired duct segment; heating the duct segment precursor at a temperature and for a time sufficient to fuse the layers of the multilayer duct segment precursor; and then cooling the resulting duct segment. | ||||||
| 198 | EPOXY RESIN CURING AGENT AND PREPARATION METHODS AND USES THEREOF | US15130085 | 2016-04-15 | US20170166513A1 | 2017-06-15 | Qingchong Pan |
| The present invention relates to an epoxy resin curing agent having a structure of Formula I and preparation methods and uses thereof. The present invention makes a resin composition formed by the epoxy resin curing agent have good low dielectric properties by using an epoxy resin curing agent having a specific structure, and the cured products of the epoxy resin composition have low dielectric constant and dielectric loss and good heat resistance and are low dielectric materials having great economic properties and being environmental friendly. | ||||||
| 199 | Multilayer separator with superior permeability | US14580885 | 2014-12-23 | US09623640B2 | 2017-04-18 | Min Ho Jeon; Byoung Cheon Jo; Sang Bae Cheong; Sang Hyun Park; Tae Gyu Kan |
| Provided are a multilayer separator capable of improving interlayer peel strength and exhibiting excellent permeability due to a high degree of alignment, and a method of manufacturing the same. The method of manufacturing a multilayer separator includes: manufacturing a precursor film by co-extruding and molding a polypropylene based resin melt having a melt index (2.16 kg, 230° C.) of 0.3 to 5 g/10 min and a polyethylene based resin melt having a melt index (2.16 kg, 190° C.) of 0.1 to 1.5 g/10 min so as to be alternately laminated; and heat-treating and stretching the manufactured film, wherein a melt index ratio (A/B) of the polypropylene based resin melt (A) and polyethylene based resin melt (B) is 2 to 10. | ||||||
| 200 | FILM LAMINATION WITH FLEX-TAILS FOR A TOUCH SENSOR | US15269235 | 2016-09-19 | US20170068347A1 | 2017-03-09 | Jason D. Wilson; Mark Green; Bill Emery |
| Different lamination methods may be used to create a touch sensor with a darkened side of metalized film facing the user. One lamination method includes laminating a metalized film to an optically clear adhesive (OCA) layer such that an edge of the metalized film including the termination pads remain un-adhered to the OCA layer. Flex-tails may be bonded to the termination pads at a later time by bending up the un-adhered edge. Anisotropic Conductive Film (ACF) may be placed on the termination pads prior to laminating the metalized films. Flex-tails may be placed onto an OCA layer in a location where the termination pads on the metalized film will be located when laminated to the OCA layer. A strip of ACF may be placed on the flex-tail pads. The flex-tails may be bonded to the termination pads of the metalized film prior to the metalized film being laminated. | ||||||
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