Abstract: To provide a metal-carbon fiber reinforced plastic material (CFRP) composite that has excellent adhesion and adhesion durability at a member interface and a method of producing a metal-CFRP composite. The metal-CFRP composite according to the present invention includes: a metal member; a CFRP layer; and one or two layers of coating layers provided between the metal member and the CFRP layer. In the case where the coating layer consists of one layer, the coating layer is a coating layer containing an isocyanate group, and the matrix resin contains a phenoxy resin as a main component thereof, contains an epoxy group, and has bonds represented in (a structural formula 1) in the vicinity of an interface between the CFRP layer and the coating layer.

Abstract: A method manufactures a composite member that can exert a sufficient effect of reinforcing a metal part with a fiber-reinforced resin material when the metal part is obtained by bending a tubular member. The method firstly bends a tubular metal member having a plate-like outer wall extending in the longitudinal direction so that compressive stress acts on the outer wall to manufacture the metal part. Next the method prepares a plate-like metal plate. Next the method attaches a fiber-reinforced resin material to a surface of the prepared metal plate, the fiber-reinforced resin material including a fiber substrate containing reinforcement fibers having one orientation direction and impregnated with uncured thermosetting resin, followed by thermally curing of the thermosetting resin to prepare a reinforcement member. Next the method joins the metal plate of the reinforcement member to the surface of the outer wall of the metal part.

Abstract: A cytokine adsorption sheet comprises a nanofiber web formed by electrospinning a spinning solution prepared by mixing an adsorbent material capable of adsorbing cytokine and an electrospinnable polymer material. Thus, the dissolution of the adsorbent material by blood can be prevented.

Abstract: A thermally conductive article including a polymeric layer comprising a nonwoven polymeric material. In particular, flexible thermally conductive polymeric layer comprising an epoxy resin and a long-strand polymeric nonwoven material embedded in the epoxy resin. The polymeric nonwoven material may be heat stable at about 280 C.

Abstract: Disclosed is to a composite material, a structural element comprised of the composite material, an airplane wing spar and their methods of production. Some embodiments of the present invention include composite materials comprised of multiple layers of arrays of metallic bodies separated by layers of non-metallic material, wherein the orientation of metallic bodies in some metallic layers is structurally complementing to the orientation of metallic layers in adjacent metallic layers. Other embodiments of the present invention include structural elements, such as an airplane wing spar, comprised of the composite material.

Abstract: A method of constructing a three dimensional decorative object from a foil sheet and a fabric overlay is the subject of the invention. The method includes shaping the foil sheet into a three dimensional configuration, providing the foil sheet with an adhesive coating and adhering a fabric overlay to the foil. In another aspect of the invention the foil sheet has a fabric overlay adhered to one side and is utilized to form a three dimensional decorative object by shaping the sheet into the desired three dimensional object and then providing a decorative finish to the fabric side of the sheet. The method may include applying a layer of plaster on top of the fabric overlay. An article useful in constructing a three dimensional object is also encompassed by the invention. The article comprises a foil sheet having a fabric overlay adhered to one side.

Abstract: A flexible, wrappable multilayered heat shield is provided. The heat shield includes a reflective metal outermost layer, an innermost layer of high temperature yarn capable of withstanding temperatures up to about 650 degrees° C. continuously, and about 750° C. intermittently, and an intermediate layer of nonwoven material capable of withstanding temperatures up to about 550° C. continuously sandwiched between the outermost and innermost layers.

Abstract: The present invention provides a resin composition which can simply provide, with good reproducibility, a laminate, a printed wiring board, and the like that not only have excellent heat dissipation properties but have good moldability, good mechanical drillability and excellent appearance, and a prepreg, a metal foil-clad laminate, and the like using the same. A resin composition having a cyanate ester compound (A), an epoxy resin (B), a first inorganic filler (C), a second inorganic filler (D), and a molybdenum compound (E), wherein an average particle diameter ratio of the first inorganic filler (C) to the second inorganic filler (D) is in a range of 1:0.02 to 1:0.2.

Abstract: An improved process for forming a PTFE mat is described. The process includes providing a dispersion with PTFE, a fiberizing polymer and a solvent wherein said dispersion has a viscosity of at least 50,000 cP. An apparatus is provided which comprises a charge source and a target a distance from the charge source. A voltage source is provided which creates a first charge at the charge source and an opposing charge at the target. The dispersion is electrostatically charged by contact with the charge source. The electrostatically charged dispersion is collected on the target to form a mat precursor which is heated to remove the solvent and the fiberizing polymer thereby forming the PTFE mat.

Abstract: The invention relates to a polyimide containing polymaleic anhydride having the formula: wherein X represents functional groups having carbon chain with carbon numbers more than 10, benzene ring and a combination of carbon chain with carbon numbers more than 10 and benzene ring; and m, n and l are integers, and larger than or equal to 1.

Abstract: A surface heat shield device may include at least one mat made from a fireproof material. The at least one mat may be hardened. The at least one mat may be placed on a rack. The rack may have a plurality of drain holes and may have a plurality of heat resistant feet attached to a bottom side of the rack. The surface heat shield device may be placed between a surface and a heat source to prevent damage to the surface from the heat source such as a fire pit.

Abstract: A laminated lithographic printing plate comprising an aluminum layer having a first side and a second side, an aluminum oxide layer coating the first side aluminum layer, optionally a second aluminum oxide layer coating the second side of the aluminum layer, an image forming layer coating the first aluminum oxide layer, an adhesive layer adhering to the second side of the aluminum layer or to said second aluminum oxide layer when second aluminum oxide layer is present, and a base layer coating the adhesive layer is provided.

Abstract: A thermal shield material comprises a laminate of a homogeneously blended fiber mat of fiberglass, polyester and bi-component polyester, a plurality of tufts disposed on only one side of the laminate mat, the tufts formed by needling the laminate mat from a single side, first and second pressure sensitive adhesive layers disposed on first and second sides of the blended fiber mat, a foil layer on at least one of the first and second pressure sensitive adhesive layers.

Abstract: A halogen-free low-dielectric resin composition, and a prepreg and a copper foil laminate made by using same. The halogen-free low-dielectric resin composition, based on parts by weight of the organic solid content, comprises: 5 to 90 parts by weight of epoxidized polybutadiene resin; 10 to 90 parts by weight of benzoxazine resin; 10 to 90 parts by weight of epoxy resin; 1 to 50 parts by weight of curing agent; 10 to 50 parts by weight of organic fire retardant; 0.01 to 1 part by weight of curing catalyst; 0.1 to 10 parts by weight of initiator; and 10 to 100 parts by weight of packing. The halogen-free low-dielectric resin composition of the present invention uses the epoxidized polybutadiene resin, so as to not only solve the defect of the polybutadiene but also maintain the advantages on the dielectric property and flexibility, thereby improving the adhesive force thereof with the copper foil.

Abstract: A method of forming a needled fiberglass glass insulation product is provided. The formation of the needled insulation product may be conducted in a process in which the fibers are formed, a binder is sprayed onto the fibers, the fibers are collected and formed into a fiberglass pack, the fiberglass pack is passed through the oven, and at least partially cured insulation blanket is passed through a needling apparatus. The reduction in thickness and increased density caused by the needling process permits the production of lower thickness and high density insulation products.

Abstract: 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.

Abstract: An improved process for forming a PTFE mat is described. The process includes providing a dispersion with PTFE, a fiberizing polymer and a solvent wherein said dispersion has a viscosity of at least 50,000 cP. An apparatus is provided which comprises a charge source and a target a distance from the charge source. A voltage source is provided which creates a first charge at the charge source and an opposing charge at the target. The dispersion is electrostatically charged by contact with the charge source. The electrostatically charged dispersion is collected on the target to form a mat precursor which is heated to remove the solvent and the fiberizing polymer thereby forming the PTFE mat.

Abstract: This invention provides a new class of medical devices and implants comprising amorphous metal alloys. The medical devices and implants may be temporary or permanent and may comprise other materials as well, such as polymers, ceramics, and conventional crystalline or polycrystalline metal alloys. Specifically, this invention provides implantable surgical fabrics comprising amorphous metal alloys. The presence of amorphous metal alloys in these fabrics can serve a variety of purposes, including structurally reinforcing the surgical fabric and/or imparting to the fabric the ability to shield against harmful radiation. The fabric may be used inside or outside the body during medical procedures. Further, the implantable surgical fabrics may be woven or non-woven fabrics.

Abstract: A laminate material for lighter-than-air vehicles includes at least one monofilament yarn layer, a polymeric film layer adjacent to the at least one monofilament layer, and a metallized coating adjacent to said polymeric film layer. A clear film cover layer may be adhered to the metallized coating, and one or more fluorescent dyes may be incorporated into the clear film layer.

Abstract: A laminate with superior thermal conductivity, heat resistance, drill workability, and fire retardancy is provided. In a prepreg obtained by impregnating a woven or nonwoven fabric base with a thermosetting resin composition, the thermosetting resin composition contains 80 to 200 parts by volume of an inorganic filler per 100 parts by volume of a thermosetting resin, the inorganic filler contains (A) gibbsite type aluminum hydroxide particles having an average particle diameter (D50) of 2 to 15 ?m and (B) magnesium oxide having an average particle diameter (D50) of 0.5 to 15 ?m, and a compounding ratio (volume ratio) of the gibbsite type aluminum hydroxide particles (A) to the magnesium oxide (B) is 1:0.3 to 3.

Abstract: This invention is directed to a structural core comprising a fibrous web and a matrix resin, the matrix resin comprising from 15 to 75 weight percent of the weight of web plus resin, the matrix resin contains a first resin comprising tannin in an amount of 10 to 100 weight percent and a second resin in the event tannin is not present in an amount of 100 weight percent, A preferred second resin is phenolic, benzoxazine, polyester, cyanate ester, bismaleimide, epoxy, polyimide or combination thereof.

Abstract: A reflective insulation system. The reflective insulation system includes a reflective layer such as aluminum, a layer of fiberglass, and a layer of vapor retarding material. A first side of the layer of fiberglass is bonded to the reflective layer by a deposit of hot melt glue. The second side of the layer of fiberglass is bonded to the layer of vapor retarding material by a second deposit of hot melt glue. The vapor retarding layer may be a plastic material, such as polypropylene or a reflective material, such as aluminum. In an alternate construction, the reflective layer has a transverse dimension that is narrower than the vapor retarding material such that edge portions of the reflective layer are spaced inwardly with respect to edges of said vapor retarder material. A strip of adhesive tape, preferably foil tape, overlies and secures edge portions of the reflective and vapor retarder layers.

Abstract: A process for producing a polyvinyl alcohol film or fabric having a modified non-porous surface which can be used to form disposable protective clothing, wraps, and articles similar to TYVEK® by impinging steam on at least one surface.

Abstract: The invention concerns an under-roof screen (100) comprising: a first layer (102) produced from a first metallic or metallized material forming a thermal reflection barrier; a second layer (108) produced from a second woven material bonded to the first layer (102); a third layer (106) produced from a third insulating material and bonded to the second layer (108); and a fourth layer (104) produced from a fourth metallic or metallized material forming a thermal reflection barrier and bonded to the third layer (106); the first layer (102) and the second layer (108) being provided with micro-perforations (110) providing permeability to water vapor and impermeability to water and the fourth layer (104) being provided with perforations (112) providing permeability to water vapor.

Abstract: In a laminate, comprising at least one series of metal layers and fiber-reinforced plastic layers which are attached to one another, at least two different series are provided, these series including a transition, and at the location of the transition at least one of the internal layers is discontinuous and all the other layers are continuous.

Abstract: A primer-less coating composition for facestock comprises: a binder being a water-dispersible polymer; an ethylenically unsaturated compound which is aqueous-dispersible and miscible with or bonded to said water-dispersible polymer, wherein said ethylenically unsaturated compound is able to form a covalent bond with an ink; and a crosslinker, wherein said crosslinker is suitable for binding the coating to the facestock. The coating composition may be applied to a substrate to form a printable film. A printed film in accordance with the invention may be used in a label, for example for use on a container such as a bottle.

Abstract: 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.

Abstract: The present invention relates to a versatile multi-layer elastomer or thermoplastic elastomer based thermal and/or sound insulation material with improved fire retardant properties together with low smoke generation, the process for manufacturing of such material and the use of such material and resulting composites.

Abstract: A roof covering for a building having a roof with structured roof tiles and a structure projecting out from the roof surface, such as a chimney, a window, a wall, or ventilating pipe. The abstract of the disclosure is submitted herewith as required by 37 C.F.R. §1.72(b). As stated in 37 C.F.R. §1.72(b): A brief abstract of the technical disclosure in the specification must commence on a separate sheet, preferably following the claims, under the heading “Abstract of the Disclosure.” The purpose of the abstract is to enable the Patent and Trademark Office and the public generally to determine quickly from a cursory inspection the nature and gist of the technical disclosure. The abstract shall not be used for interpreting the scope of the claims. Therefore, any statements made relating to the abstract are not intended to limit the claims in any manner and should not be interpreted as limiting the claims in any manner.

Abstract: A vehicle panel (10) includes a core layer (12) and a layer of metalized film (14) bonded to the core layer (12). In one embodiment, the core layer (12) is made of a material with heat absorption or insulation properties. The layer of metalized film (14) is made of a material having heat reflective properties that can be bonded to the core layer (12). Alternatively, a compatible bonding agent can be applied to the core layer, the metalized film, or both. To form the vehicle panel (10), the layer metalized film (14) is positioned on one half of a mold tool and the core layer (12) is positioned on the other half of the mold tool. Heat is applied to the core layer (12) and the mold tool is closed such that the heat from the core layer (12) causes the metalized film (14) to be in a formable state and bonds to the core layer (12).

Abstract: A reflective panel and method of construction thereof from post consumer mixed Asian cardboard for forming structural and/or acoustic and/or thermal panels is provided. The method includes providing post consumer mixed Asian cardboard and comminuting the cardboard into predetermined reduced sized pieces. Then, combining the reduced sized pieces with a heat bondable textile material to form a substantially homogenous mixture. Further, forming a web of the mixture of a predetermined thickness in a dry nonwoven webbing process. Then, heating the web to bond the heat bondable material with the reduced sized pieces to form a nonwoven sheet having opposite sides. Further, bonding at least one reflective layer to at least one of the opposite sides of the nonwoven sheet.

Abstract: The invention relates to a vapor-insulating wall cladding (100), comprising aluminum foil (4) that acts as a vapor barrier, the foil being joined to a plaster base layer (3), characterized in that the plaster base layer (3) comprises a fiber layer (1), namely a non-woven fabric, woven fabric, knitted fabric or applied scrim coat, which is bound by a flexibly cured mortar (2), which joins the fiber layer to the aluminum foil and has the characteristics of plaster mortar.

Abstract: An energy-harvesting article includes two textile units each having a thin metal sheet and a leather sheet, a first adhesive layer interconnecting the thin metal sheets of the textile units, and two second adhesive layers each interconnecting the thin metal sheet and the leather sheet of a respective textile unit. The leather sheet covers the thin metal sheet, and includes a non-woven fabric substrate and a leather coating layer. Each of the non-woven fabric substrate and the leather coating layer includes a catalytic composition. By wrapping the energy-harvesting article to pipes, the material of the energy-harvesting article is considered as self-assembled monolayers, and the energy-harvesting article is harvesting energy from the environment and resonant tunneling through inner portions of the pipes to activate flowing medium inside the pipes, thereby improving energy efficiency and achieving energy conservation and reduction of greenhouse gas emission.

Abstract: A composite material comprising at least a first layer which comprises a surfactant component, surfactant-generated microcells, a filler component and a binder component; and a second layer which comprises a metallic component. The composite material may further comprise a substrate to which the first layer is adhered. The composite materials have heat insulating, and fire resistant characteristics and are particularly suited for use in building materials and mattresses.

Abstract: Insulating element from mineral fibers for shipbuilding with an insulating element in form of a plate or roll felt for shipbuilding the composition of the mineral fibers of the insulating element points an alkali/alkaline-earth mass ratio of the fiber structure of the insulating element is determined by an average geometrical fiber diameter of ?4 ?m and a surface weight of 0.8 through 4.3 kg/m2 and a binding agent portion above 0.5 until 4 weight %.

Abstract: A composite material comprising a substrate having an ionic charge which is coated with a coating having essentially the same ionic charge and a metallic component adhered on one or both sides of the coated substrate. The coating consists essentially of a filler material comprising clay and a binder material. The substrate is preferably fiberglass, the filler material may further comprise at least one additional filler selected from the group consisting of decabromodiphenyloxide, antimony trioxide, fly ash, charged calcium carbonate, mica, glass microspheres and ceramic microspheres and mixtures thereof and the binder material is preferably acrylic latex. The metallic component is preferably aluminum foil. The composite material has heat insulating and fire resistant characteristics.

Abstract: Exemplary embodiments provide materials and methods for ink jet printhead nozzle plate and related printing apparatus, wherein the ink jet printhead nozzle plate can include a coaxially electrospun layer to provide a low adhesion oleophobic textile surface exhibiting a low sliding angle and a high contact angle with ultra-violet gel ink and/or solid ink.

Abstract: A process for making a fibrous product using a binder based on a formaldehyde-containing resin and especially for making fiberglass insulation products, and to the fibrous products themselves, wherein the fibrous product has a backing sheet affixed thereto and the backing sheet is coated or impregnated with a formaldehyde scavenger composition, with the result that the fibrous products exhibit a reduced level of formaldehyde emission.

Abstract: A thermal barrier fabric includes an inner impermeable material layer, an outer impermeable material layer, a spacer material disposed between the inner and outer impermeable material layers, and a reflective layer of material disposed between the spacer and a selected one of the inner impermeable material layer and the outer impermeable material layer. The inner and outer impermeable material layers are bound to each other along portions thereof outboard of the spacer material and the reflective layer of material to define a closed compartment. The compartment is under a vacuum, such that the reflective layer of the fabric reflects thermal energy back toward the source thereof and the vacuum substantially prevents thermal energy transfer through the compartment.

Abstract: A fire-resistant fabric is provided that comprises a non-woven batt comprising an intertwined first plurality of flame-resistant fibers. The fire-resistant fabric further comprises one or more stitching yarns engaging the non-woven batt in the form of stitches configured for binding the intertwined flame-resistant fibers into a stitch-bonded fabric. The one or more stitching yarns include a yarn comprising a second plurality of flame-resistant fibers. At least one of the first and second pluralities of flame-resistant fibers comprises partially oxidized PAN fibers.

Abstract: A nonwoven sheet material and method of construction thereof is provided. The nonwoven sheet material includes a heat bondable textile material and a used post consumer material. The used post consumer material includes at least one of a non-thermoplastic material, thermoplastic material, a plastic composition including different types of plastic constituents, and other materials containing contaminants such as dirt, oil, grease and the like in a non-washed state, which are ordinarily considered non-reusable waste. The used post consumer material is bonded with the heat bondable textile material to form the nonwoven sheet material and panels formed therefrom.

Abstract: The invention relates to a lining element, in particular an interior lining and/or covering element, for motor vehicles, having a decorative layer and a support layer structure with at least one support layer, in which the air permeability and/or density and/or the mass per unit area of the support layer structure are preset for controlling the acoustic properties, and to a method for producing a lining element, in particular an interior lining element or covering element for motor vehicles, having a decorative layer and a support layer structure of at least one support layer with controlled acoustic properties. In particular, the acoustic properties of the lining element are controlled by matching the thickness, and/or the mass per unit area, and/or the air permeability of the lining element in zones, or over the entire surface, to sound emissions which are to be absorbed.

Abstract: A method and a device produce a fleece of metallic fibers in a layer in which the metallic fibers are welded to one another to form the fleece. A welding process is repeatedly carried out with regard to a portion or section of the fleece. Such metallic fiber fleeces are used, in particular, for exhaust gas treatment units in the automobile industry.

Abstract: Insulating element from mineral fibers for shipbuilding with an insulating element in form of a plate or roll felt for shipbuilding the composition of the mineral fibers of the insulating element points an alkali/alkaline-earth mass ratio of the fiber structure of the insulating element is determined by an average geometrical fiber diameter of ?4 ?m and a surface weight of 0.8 through 4.3 kg/m2 and a binding agent portion above 0.5 until 4 weight %.

Abstract: An animal house curtain comprising a metallized composite sheet can be made from a sheet layer having two outer surfaces, the sheet layer comprising at least one of a nonwoven fabric, woven fabric, nonwoven fabric-film laminate, woven fabric-film laminate, film and composites thereof, and at least one coating on at least one outer surface of the sheet layer, said coating comprising a metal coating layer having a thickness between about 15 nanometers and about 200 nanometers adjacent the outer surface of the sheet layer and wherein the emissivity of the composite sheet is less than about 0.50. Optionally, an organic coating layer of a composition containing a material selected from the group consisting of compounds, polymers, oligomers and combinations thereof, having a thickness between about 0.2 micrometer and about 2.5 micrometers can be deposited on the metal layer.

Abstract: A foamed composite armor laminate comprising interleaved combinations of ballistic resistant fabrics, and ceramic and/or metallic plates or sheets in a polymeric foam matrix. The foamed composite armor can be fabricated by inserting polymer powder or sheets between layers of fabric and/or ceramic or metallic sheets to form a laminated structure, heating this laminated structure under pressure to form a consolidated panel, and then foaming the polymeric portion of the consolidated panel in an autoclave or pressure vessel by saturating the polymeric portion with inert gas at elevated temperature, rapidly releasing the pressure and controllably cooling the laminated structure to ambient. Alternatively, pre-foamed panels can be laminated to fabric, ceramic and/or metallic sheets using adhesives or the like. Through proper selection of the various elements of the laminate, i.e.

Abstract: Invention relates to a roll cover and a covered roll for paper, board, finishing and tissue machines. More specifically it relates to a roll particularly used in calendar which roll comprises a metal roll body and a cover of a composite material on it. The cover has at least three layers which comprise polymer matrix and fiber reinforcement the material of the being different at least in successive layers.

Abstract: This invention is directed to a folded tessellated core structure having a high compression modulus. The core structure comprises a nonwoven sheet and a cured resin in an amount such that the weight of cured resin as a percentage of combined weight of cured resin and nonwoven sheet is at least 50 percent, The nonwoven sheet further comprises fibers having a modulus of at least 200 grams per denier (180 grams per dtex) and a tenacity of at least 10 grams per denier (9 grams per dtex) wherein, prior to impregnating with the resin, the nonwoven sheet has an apparent density calculated from the equation Dp=K×((dr×(100?% r)% r)/(1+dr/ds×(100?% r)% r), where Dp is the apparent density of the sheet before impregnation, dr is the density of cured resin, ds is the density of solid material in the sheet before impregnation, % r is the cured resin content in the final core structure in weight %, K is a number with a value from 1.0 to 1.

Abstract: One subject of the invention is a process for obtaining mineral wool comprising mineral fibres and an organic binder, in which process said mineral fibres are formed and said organic binder is added on at least part of the surface of said mineral fibres, characterized in that a compound is furthermore added to at least one part of the surface of said mineral fibres, said compound comprising at least one resin acid or resin acid derivative and also a water-repellent agent. The subject of the invention is also a mineral wool that can be obtained by this process.

Abstract: Armour plate comprising a mass of cured resinous material having a face surface and a back surface, a tile layer comprising a single ceramic or metal tile, or a plurality of coplanar ceramic or metal tiles arranged in edge to edge relationship, entirely embedded in the resinous mass to a depth of at least 1 mm from the face surface, and a backing layer of impact resistant flexible material embedded or partially embedded in the resinous mass on the side of the tile(s) towards the back surface.