| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 442228000 | Including a free metal or alloy constituent | 24 |
| 20090011674 | Method for Producing Planar Metallised Textile Structures, Planar Metallised Textile Structure and Use of the Thus Produced Planar Metallised Textile Structure - The present invention relates to a process for producing a metalized textile fabric, which comprises a textile fabric being
| 01-08-2009 |
| 20090047853 | Laminate structure with an interlayer - A laminate structure ( | 02-19-2009 |
| 20110159764 | METHODS OF IMPARTING CONDUCTIVITY TO MATERIALS USED IN COMPOSITE ARTICLE FABRICATION & MATERIALS THEREOF - Embodiments of the invention are directed to metal- or metal alloy-coated sheet materials (hereinafter, “metal-coated sheet material”) including, but not limited to, fabrics and veils which have a metal content of between one (1) and fifty (50) grams per square meter (gsm). The metal-coated sheet materials may be used as-is or in conjunction with prepregs, adhesives or surfacing films to provide lightning strike protection (LSP) and/or bulk conductivity, among other benefits, to the resultant composite article. In one embodiment, the metal-coated sheet material is impregnated with a resin. According to embodiments of the invention, a metal is applied to one or two sides of the fabric or veil by a physical vapor deposition coating process. The resultant metal-coated fabric or veil may be used as a carrier in surfacing films to impart surface conductivity; may be used as a carrier in adhesives to form conductive adhesive-bonded joints; may be interleaved (one or more metal-coated veils) between layers of prepreg to impart surface and/or bulk conductivity as well as toughness; or may be used to fabricate composite articles. | 06-30-2011 |
| 20150367604 | COVER ASSEMBLY FOR TEMPERATURE-SENSITIVE CARTONS OR ARTICLES - Temperature protection assemblies ( | 12-24-2015 |
| 442229000 | Metal or metal-coated strand | 5 |
| 20080287022 | FABRIC AND YARN STRUCTURES FOR IMPROVING SIGNAL INTEGRITY IN FABRIC-BASED ELECTRICAL CIRCUITS - Coaxial and twisted pair conductive yarn structures reduce signal crosstalk between adjacent lines in woven electrical networks. A coaxial conductive yarn structure includes an inner conductive yarn having a plurality of conductive strands twisted together. An outer conductive yarn is wrapped around the inner conductive yarn. An insulating layer separates the inner and outer yarns. A twisted pair conductive yarn structure includes first and second conductive yarns, each including a plurality of conductive strands being twisted together. The first and second conductive yarns are twisted together to form a helical structure. In a woven electrical network, at least one conductor of adjacent conductive yarn structures is connected to ground to reduce signal crosstalk. Coaxial and twisted pair yarn structures may also be formed simultaneously with weaving or knitting the threads that make up the structures into a fabric. | 11-20-2008 |
| 20100075558 | MULTILAYER LAMINATED MATERIAL WITH INHERENTLY LATENT PROTECTION AGAINST DEFORMATION UNDER THERMAL ACTION FOR COMPENSATING THE BIMETALLIC EFFECT - A solvent-free multilayer laminated material comprises a lower substrate layer comprising a thermoplastic polymer or a mixture of thermoplastic polymers, an intermediate layer arranged thereon and comprising a flexible material, a further fibrous intermediate layer comprising plastic, which is provided with an adhesive material and an upper layer comprising metal, comprising plastic or comprising wood or wood-like materials. It does surprisingly not show any deformation even under exposure to temperatures of about 80° C. over a period of up to 40 days and can be used for the production of articles of furniture, floor coverings, wall panels or shaped articles for the electrical, construction or automotive industry. | 03-25-2010 |
| 20100197184 | CONFORMABLE LAYER UTILIZING ACTIVE MATERIAL ACTUATION - A conformable protective layer, such as a fabric or covering, adapted for overlaying an object or space, and presenting a condition, such as a geometric configuration or stiffness, includes at least one shape memory alloy, electroactive polymer, or similar active material based actuator operable to undergo a reversible change when exposed to and/or removed from an external signal, and is configured such that the change is operable to autonomously modify the condition, or facilitate placement and removal of the layer. | 08-05-2010 |
| 20130137327 | ANTI-INTERFERENCE COVER MADE OF A COMPOUND MATERIAL FOR AN ELECTRONIC PRODUCT - An anti-interference cover made of a compound material for an electronic product has a fiber fabric. The fiber fabric is made of a compound material to take the form of a case, and has at least one unblocking area, each one of the at least one unblocking area having multiple non-conductive fibers interwoven and aligned longitudinally and transversely, and multiple conductive fibers interwoven and aligned longitudinally and transversely and not covered by the at least one unblocking area. When the cover is assembled with an electronic product, the at least one unblocking area of the cover allows electromagnetic wave transmitted and received by communication components to pass therethrough, thereby preventing blocking signals and providing a cover with high strength, thin profile and light weight. | 05-30-2013 |
| 20140030948 | FIBER-CONTAINING COMPOSITES - Provided in one embodiment is a method for producing a composition, comprising: heating a first material comprising an amorphous alloy to a first temperature; and contacting the first material with a second material comprising at least one fiber to form a composition comprising the first material and the second material; wherein the first temperature is higher than or equal to a glass transition temperature (T | 01-30-2014 |
| 442230000 | Vapor or sputter deposited metal layer | 2 |
| 20090197494 | Anti-microbial fabric and method for producing the same - A method for producing an anti-microbial fabric includes: (a) depositing anti-microbial metal-based clusters on an outer surface of a fabric substrate by sputtering a metal-based target material which possesses anti-microbial activity and which is prone to oxidation upon air exposure; and (b) depositing oxidation-resistant metal-based clusters on the outer surface of the fabric substrate by sputtering an oxidation-resistant metal-based target material in such an amount as to enable the oxidation-resistant metal-based clusters to partially cover the anti-microbial metal-based clusters so as to permit exposure of at least a part of one of the anti-microbial metal-based clusters. An anti-microbial fabric produced thereby is also disclosed. | 08-06-2009 |
| 20150345074 | METHOD FOR PRODUCING A METALLISED FABRIC, AND RESULTING FABRIC - The invention relates to a method for producing a metallised fabric, including a step of washing a woven substrate, the method including, after the washing step, the following steps: calendering the substrate by applying a compression force to the substrate, and vacuum-metallising the substrate in a rarefied atmosphere by depositing metal particles so as to form a layer of metal on the substrate. | 12-03-2015 |
| 442231000 | Chemically deposited metal layer (e.g., chemical precipitation or electrochemical deposition or plating, etc.) | 1 |
| 20140141674 | APPARATUS AND METHODS FOR PLASMA ENHANCED CHEMICAL VAPOR DEPOSITION OF DIELECTRIC/POLYMER COATINGS - Apparatuses and methods are described that involve the deposition of coatings on substrates. The polymer coatings generally comprise a wear resistant layer and/or a hydrophobic layer. The wear resistant layer can comprise a metal oxide or metal nitride. The hydrophobic layer can comprise fused polymer particles having an average primary particle diameter on the nanometer to micrometer scale. The coatings are deposited on substrates using specifically adapted plasma enhanced atomic layer deposition and plasma enhanced chemical vapor deposition approaches. The substrates can include computing devices and fabrics. | 05-22-2014 |
| 442232000 | Preformed metallic film or foil or sheet (film or foil or sheet had structural integrity prior to association with the woven fabric) | 12 |
| 20110183564 | METAL-CLAD PHENOLIC RESIN LAMINATE - The object of the present invention is to provide a metal-clad phenolic resin laminate having a combination of machine properties, electrical properties and tracking resistance. A metal-clad phenolic resin laminate obtained by heating and pressing a lamination which comprises: (i) a central layered portion comprising one paper base prepreg which is made of a paper base impregnated with a first phenolic resin composition containing a resol-based resin, or a predetermined number of the paper base prepregs laid on each other; (ii) outer layered portions laid on an upper and a lower sides of the central layered portion, in which each of the outer layered portions comprises one glass fiber substrate prepreg which is made of a glass fiber substrate impregnated with a second phenolic resin composition containing a resol-based resin, or a predetermined number of the glass fiber substrate prepregs laid on each other; and (iii) a metal foil laid at least on one of the outer layered portions laid on the upper and lower sides of the central layered portion. | 07-28-2011 |
| 20120149270 | MULTIPLE-BONDING MATERIAL - A multiple-bonding material applicable to a transportation vehicle is provided. The multiple-bonding material includes a metal plate and a composite. The composite is bonded to one surface of the metal plate, and includes a reinforcement material and a resin composition to bond the reinforcement material to the metal plate, wherein the reinforcement material is formed as a woven or non-woven fabric and disposed on the surface of the metal plate. Accordingly, the multiple-bonding material has improved rigidity and advantage in lighting of the vehicle, and can enhance impact and sound absorption and damping performance. | 06-14-2012 |
| 20120202399 | FOIL LAME' FABRICS AND METHODS OF MAKING FOIL LAME' FABRICS - A new method for manufacturing a new foil lame′ fabric (1) accepts lame′ fabric that had been treated to accept binder, (2) applies binder to one side of the lame′ fabric, (3) arranges hot stamping foil on the side of the lame′ fabric to which binder had been applied, to define an arrangement (wherein the hot stamping foil includes a carrier), (4) hot presses the arrangement of hot stamping foil and lame′ fabric to create a foil-lame′ combination, (5) cures the foil-lame′ combination, and (6) removes the carrier from the foil-lame′ combination. The lame′ fabric accepted may be prepared by (1) treating a tinted polyester metalized film to accept a binder adapted to accept a clear hot melt adhesive to define a treated film, (2) slitting the treated film, (3) winding the slit, treated film onto bobbins, and (4) weaving the slit, treated film with nylon yarn to produce the lame′ fabric. The hot stamping foil may be prepared by (1) treating a clear polyester base film with a release coat, (2) tinting the treated clear polyester base film to a desired color, and (3) metalizing the treated and tinted clear polyester based film. | 08-09-2012 |
| 20140087617 | ALUMINUM POLY(ARYL ETHER KETONE) LAMINATE, METHODS OF MANUFACTURE THEREOF, AND ARTICLES COMPRISING THE SAME - A laminate having excellent bond strength, and comprising a tempered aluminum layer comprising aluminum in an amount of 95 to less than 99 wt %, and at least one of cobalt, copper, lithium, magnesium, manganese, nickel, platinum, and silicon in a total amount of at least 0.5 wt %; and a poly(aryl ether ketone) layer, wherein at least a portion layer and the poly(aryl ether ketone) layer are in direct contact. | 03-27-2014 |
| 20160167342 | COMPOSITE MATERIAL MANUFACTURING METHOD AND COPPER CLAD LAMINATE MANUFACTURED BY THE SAME | 06-16-2016 |
| 442233000 | Plural metallic films or foils or sheets | 2 |
| 20090203279 | Resin composition, prepreg and their uses - A vinyl-compound-based resin composition containing a terminal vinyl compound (a) of a bifunctional phenylene ether oligomer having a polyphenylene ether skeleton, a specific maleimide compound (b), a naphthol aralkyl type cyanate ester resin (c) and a naphthalene-skeleton-modified novolak type epoxy resin (d) for a high-multilayer and high-frequency printed wiring board, which resin composition is excellent in varnish shelf life at low temperature and does not show a decrease in multilayer moldability, heat resistance after moisture absorption, electrical characteristics and peel strength even in a winter period and for a long period of time, and a prepreg, a metal-foil-clad laminate and a resin sheet each of which uses the above resin composition. | 08-13-2009 |
| 20140199909 | SILICONE-ORGANIC RESIN COMPOSITE LAMINATE AND MANUFACTURING METHOD THEREOF, AND LIGHT-EMITTING SEMICONDUCTOR APPARATUS USING THE SAME - The invention provides a silicone-organic resin composite laminate comprises a laminate in which an organic resin layer containing an inorganic fiber cloth into which a thermosetting organic resin has been impregnated, and a silicone resin layer containing an inorganic fiber cloth into which a curable silicone resin has been impregnated, being laminated with each one or more layers, and metal foils laminated at an uppermost surface and a lowermost surface of the laminate. There can be provided a silicone-organic resin composite laminate which has low linear expansion, good thermal dimensional stability, excellent mechanical characteristics, and excellent heat resistance and light resistance, and is suitable as a mounting substrate for an LED which corresponds to increase in luminance of the LED mounted substrate. | 07-17-2014 |
| 442234000 | Plural fabric layers | 4 |
| 20090209155 | LAYERED THERMALLY-INSULATING FABRIC WITH THIN HEAT REFLECTIVE AND HEAT DISTRIBUTING CORE - A composite fire-resistant, heat-diffusing, and heat-reflective article. The article includes at least two layers of a fire-retardant and heat-resistant fabric with a heat diffusing and/or heat-reflective core disposed between the fabric layers. The core may include at least one layer of a thin metal foil (e.g., thin aluminum foil). The composite fire-resistant, heat-diffusing, and heat-reflective article provides durability, fire resistance, and the ability to withstand high heat exposure on one face for an extended period of time without transferring significant heat to the opposite face. Combining fire-retardant fabrics with a heat diffusing and/or heat-reflective core achieves a true synergy by offering greater fire and heat protection to persons and structures than either component can offer alone. | 08-20-2009 |
| 20120071055 | Insulated Above Ground Pool - An above-ground pool which consists of a plurality of layers of which there is an inner woven reinforced vinyl layer, a second, foil-laminated, metalized layer which is entrapped between a third woven reinforced vinyl layer. The three layers are then sealed together to form a watertight structure. The inner and outer layer is designed to be able to withstand forces which a typical container would experience. The core of the material is polyester woven which is then encased in durable vinyl. The layers are all combined together to form a water-tight seal by using radio frequency energy to weld the inner and outer layer together to form a permanent seal while the foil laminated, metalized layer is entrapped between the inner and outer layer. | 03-22-2012 |
| 20160024785 | FIRE AND SMOKE PROTECTION SYSTEM - The present disclosure describes a fire and smoke protection system for limiting the spread of fire and smoke through an opening, including those in building structures. The system includes a flexible protection member configurable in a storage configuration for subsequent deployment into a protection configuration when fire occurs. The flexible protection member is configurable in single and/or multi-layer arrangements with one or more materials, alone or in combination, and using a variety of construction methods. Generally, the flexible protection member is manufacturable using fire resistant woven and knitted fabric elements, metal foil elements, intumescent elements, and/or wire mesh elements arranged to increase the resistance to forces encountered during a fire. The various elements may be seamed using different stitching patterns and gathered using non-fire resistant thread in order to increase flexibility and resistance to forces. The flexible protection member may also be formed in segments coupled together by clamping members. | 01-28-2016 |
| 442235000 | Including a nonwoven fabric layer | 1 |
| 20180023287 | RADIANT REFLECTIVE AND WATER BARRIER ROOFING UNDERLAYMENT | 01-25-2018 |
| 442236000 | Including a preformed synthetic polymeric film or sheet (i.e., film or sheet having structural integrity prior to association with the woven fabric) | 1 |
| 20080287023 | Heat Resistant Laminate and Method for Manufacturing Such Laminate - According to the invention, there is provided a more heat-resistant laminate comprising a metal foil, a fabric, and bonding means between the metal foil and the fabric, wherein the bonding means are a flouropolymer foil functioning as an adhesive film for bonding the fabric and the metal foil together. Hereby, an impermeable laminate is provided which is flexible and can withstand higher temperatures without delaminating. A laminate according to the invention can be mounted directly against hot components with temperatures up to 550° C. when the fabric is a woven glass fabric and as high as 1100° C. if the fabric is ceramic. The bonding means are stabile in temperatures up to 290° C. and provides a stabile and durable bonding also during temperature exposure of the laminate of 310° C. for an extended period of time. | 11-20-2008 |
