101 |
Polymeric films |
US09581630 |
2000-06-15 |
US06309756B1 |
2001-10-30 |
Paul Thomas Alder |
Polypropylene films having a base layer of a propylene polymer with at least one matte outer layer of a blend of a polyether block polyamide, polypropylene, and polybutene-1, the polybutene-1 representing from 40 to 60 wt. % of the blend. Such films have shown good antistatic properties combined with particularly low heat seal thresholds compared with similar films without the polybutene-1 in the outer layer or layers. |
102 |
Method for attaching a fluoride-based polymer layer to a polyphenylene ether or polystyrene layer, and related articles |
US09089760 |
1998-06-03 |
US06303224B1 |
2001-10-16 |
John R. Krahn; Herbert Shin-I Chao |
This invention is directed to a tie layer for improving the adhesion of a layer of a fluoride-based polymeric material to a layer of a polyphenylene ether- or polystyrene-based material. The tie layer comprises a copolymer of a styrenic material like high impact polystyrene, and an acrylic material such as poly(methyl methacrylate) (PMMA). The tie layer composition may further include at least one flexibilizing agent which is compatible with one of the materials in the other layers. Exemplary flexibilizing agents are blends or copolymers which comprise rubber and polystyrene, or core-shell impact modifiers, or combinations of these types of materials. The layers can be coextruded or laminated, using conventional techniques. |
103 |
Nonwoven-film laminates |
US09169704 |
1998-10-09 |
US06190758B1 |
2001-02-20 |
Steven Ray Stopper |
There is provided herein a multilayer laminate comprised of a layer of a film and a layer of a nonwoven fabric. The film is made from polymers and has as one surface a semi-crystalline/amorphous or “heterophasic” polymer, an optional inner, less expensive, filler type polymer, and as the other surface, a polymer with a lower coefficient of friction. The nonwoven fabric may be a spunbond or meltblown fabric, preferably spunbond and preferably also including a heterophasic polymer. The film and nonwoven components are bonded together using thermal point bonding preferably while the film is stretched at least 5 percent. Such a laminate may be made into a personal care product like a diaper, training pant, absorbent underpants, adult incontinence product, and feminine hygiene product. |
104 |
Method of reducing chipping and contamination of reservoirs and channels
in thermal ink printheads during dicing by vacuum impregnation with
protective filler material |
US970499 |
1992-11-02 |
US5306370A |
1994-04-26 |
Lawrence H. Herko; Robert P. Altavela; Joseph R. Weber; Robert M. White; Kathryn A. Wallace |
A method of fabricating thermal ink jet printheads comprises aligning and bonding a pair of silicon wafers together, which have, on opposing confronting surface thereof, a plurality of sets of linear arrays of heating elements and associated driver circuitry on one wafer surface and a plurality of sets of parallel grooves and a communicating reservoir for each set of grooves. The grooves and reservoirs are filled with a filler material which is solid or gels at room temperature and liquid at higher temperatures. The bonded pair of wafers are severed into a plurality of individual printhead sby dicing processes conducted at room temperature. One of the dicing processes cuts the grooves in a direction perpendicular thereto in order to form concurrently the nozzle face and nozzles. The solid filler material supports fragile edges of the wafers and prevents entry of dicing debris and other contaminants. The printheads are subjected to heat, spinning, and high pressure water spray to remove the filler material. |
105 |
Method and apparatus for producing continuous plastic-fabric bicomponent
lamina |
US787923 |
1991-11-06 |
US5282915A |
1994-02-01 |
Edward F. Westlake, Jr. |
Method and apparatus for producing a continuous bicomponent lamina having thermoplastic on one side and fabric on the other side by pressing fabric into extruded thermoplastic with sufficient force to embed the fabric in the extruded thermoplastic to form the continuous bicomponent lamina. |
106 |
Vacuumized plastic cap for heat insulating containers |
US38974873 |
1973-08-20 |
US3856172A |
1974-12-24 |
WALLES W |
Heat insulative properties of vacuum containers such as vacuum bottles are significantly improved by stoppering the container with a vacuumized plastic cap having a boundary wall of structural plastic material wherein the inner surface of the boundary wall is coated with a thin metallic layer and a layer of barrier plastic such as a vinylidene chloride copolymer and which encloses an evacuated space filled with a gas absorbing material such as activated charcoal.
|
107 |
Filled composition and article containing perfluorinated surfactant |
US29821472 |
1972-10-17 |
US3841957A |
1974-10-15 |
SPRENGLING G |
1. AN ARTICLE COMPRISING (A) A FLAT BOARD WHICH COMPRISES (1) ABOUT 15 TO ABOUT 70% OF A HARDENED, SYNTHETIC, ORGANIC RESIN; (2) ABOUT 30 TO ABOUT 85% NON-CONDUCTIVE FILLER; AND (3) ABOUT 0.001 TO ABOUT 1.0% OF A SURFACTANT HAVING A PERFLUORINATED CHAIN AT LEAST THREE CARBON ATOMS ALONG AT ONE END AND A POLAR GROUP AT THE OTHER END, SAID SURFACTANT POSSESSING THE PROPERTY OF LOWERING THE SURFACE ENERGY OF SAID RESIN BY FREELY MIGRATING TO THE SURFACE OF SAID RESIN AND TO ITS INTERFACES WITH SAID FILLER AFTER SAID RESIN IS HARDENED; AND (B) A CONDUCTING CIRCUIT BONDED TO AT LEAST ONE SIDE OF SAID FLAT BOARD.
|
108 |
Heat insulating container having plastic walls retaining vacuum |
US30545172 |
1972-11-10 |
US3828960A |
1974-08-13 |
WALLES W |
A container having a double wall construction of a structural plastic material is provided with improved thermal insulative properties by (1) metallizing at least one surface of each wall of the container with metal such as silver to provide a light reflective surface and to produce a partial barrier to atmospheric gases, (2) coating the metallized surface with a barrier plastic such as saran, (3) evacuating the space enclosed by the walls of the container, and (4) adding to the evacuated space a gas-absorbing material.
|
109 |
Multilayer riblet applique and methods of producing the same |
US15205460 |
2016-07-08 |
US10105877B2 |
2018-10-23 |
Diane C. Rawlings; Bruce K. Keough; Larry K. Olli; Alan G. Burg; James M. Kestner; George Michael Granger; James Charles McGarvey |
Multilayer riblet applique and methods of producing the same are described herein. One disclosed example method includes applying a first high elongation polymer material to a web tool, where the web tool is to be provided from a first roll, and heating, via a first heating process, the first high elongation polymer material. The disclosed example method also includes applying a second high elongation polymer material to the first high elongation polymer material, and heating, via a second heating process, the second high elongation polymer material. The disclosed example method also includes applying, via a laminating roller, a support layer to the second high elongation polymer material. |
110 |
Production of micro- and nano-fibers by continuous microlayer coextrusion |
US14394234 |
2013-04-15 |
US10077509B2 |
2018-09-18 |
Eric Baer; Deepak Langhe; Jia Wang |
A multilayered polymer composite film includes a first polymer material forming a polymer matrix and a second polymer material coextruded with the first polymer material. The second polymer material forms a plurality of fibers embedded within the polymer matrix. The fibers have a rectangular cross-section. |
111 |
Storage vessel for compressed fluids |
US14469831 |
2014-08-27 |
US09981461B1 |
2018-05-29 |
Hugh L. Horstman |
A vessel for storing pressurized gas. The storage vessel may be manufactured in a variety of predetermined shapes. Plural frame members are interconnected with each other, collectively forming a lattice frame. A network of internal supports is disposed within the interior of the lattice frame, the internal supports being made of a carbon-reinforced composite material. The storage vessel has an outer shell made up of layers of carbon-reinforced composite material sheets enveloping the exterior of the lattice frame. |
112 |
Honey impregnated composition dressing having super absorbency and intelligent management of wound exudate and method of making same |
US14820915 |
2015-08-07 |
US09962458B2 |
2018-05-08 |
Howard Kenneth Payne; Gregory Frank Devenish |
A super absorbent, honey-dosed foam/fiber composite, gap patterned wound dressing, comprising: a patterned foam/fiber composite structure having a gap patterned side and a non-gap patterned side, wherein the patterned side includes a pattern of foam/fiber gaps disposed between foam/fiber areas dosed with honey, where the pattern of foam/fiber gaps is formed by the honey-dosed areas, such that the patterned foam/fiber composite structure includes a layer of super absorbent material located substantially adjacent to the honey-dosed areas; and wherein a wound in contact with the gap patterned side discharges an exudate which substantially collects in the individual ones of the foam/fiber gaps causing honey in the individual ones of the honey-dosed areas to be substantially dispersed throughout a wound treatment zone and a portion of the exudate that is collected in the individual ones of the foam/fiber gaps is transferred to and collected in the super absorbent material. |
113 |
MULTILAYER RIBLET APPLIQUE AND METHODS OF PRODUCING THE SAME |
US15205460 |
2016-07-08 |
US20180009136A1 |
2018-01-11 |
Diane C. Rawlings; Bruce K. Keough; Larry K. Olli; Alan G. Burg; James M. Kestner; George Michael Granger; James Charles McGarvey |
Multilayer riblet applique and methods of producing the same are described herein. One disclosed example method includes applying a first high elongation polymer material to a web tool, where the web tool is to be provided from a first roll, and heating, via a first heating process, the first high elongation polymer material. The disclosed example method also includes applying a second high elongation polymer material to the first high elongation polymer material, and heating, via a second heating process, the second high elongation polymer material. The disclosed example method also includes applying, via a laminating roller, a support layer to the second high elongation polymer material. |
114 |
Circuit materials and articles formed therefrom |
US15177882 |
2016-06-09 |
US09809690B2 |
2017-11-07 |
Thomas A. Koes |
Disclosed is a circuit material, including dielectric substrate or a circuit subassembly further comprising a conductive layer, that is formed from a precursor composition, wherein the precursor composition comprises, based on the total weight of the precursor composition, thermosetting resin or thermoplastic polymer, optionally monomeric triallyl isocyanurate or triallyl cyanurate, dispersed particles of poly(triallyl isocyanurate) or poly(triallyl cyanurate), and optionally inorganic filler, wherein the circuit material has a Df of less than 0.0060 at 10 GHz. Also disclosed is a method of manufacturing such a circuit material in which emulsion polymerized particles of poly(triallyl isocyanurate) or poly(triallyl cyanurate) are dispersed in a thermosetting or thermoplastic resin. |
115 |
Composite molded article having two-layer structure |
US12736940 |
2009-05-26 |
US09770856B2 |
2017-09-26 |
Akira Ito; Satoshi Nagai; Hiroyuki Hamada; YewWei Leong |
The present invention has an object of providing a molded article of a composite structure obtained by bonding a polar thermoplastic resin, especially polyacetal, with another resin in a simple manner. According to the present invention, a molded article of a composite structure obtained by bonding a polar thermoplastic resin and a resin containing an aliphatic ester structure as a main component to each other in the state where at least a face at which both of the materials contact each other is in a melted state can be provided. |
116 |
COMPOSITE LAMINATE FLAME BARRIER FOR A THERMAL AND ACOUSTIC INSULATION BLANKET |
US15492295 |
2017-04-20 |
US20170217120A1 |
2017-08-03 |
LLEWELLYN BENTLEY RICHARDSON, III; DARIUSZ WLODZIMIERZ KAWKA |
A multilayer laminate comprising in order, a polymeric film layer capable of withstanding a temperature of at least 200 C for at least 10 min, an adhesive layer having an areal weight of from 2 to 40 gsm capable of activation at a temperature of from 75 to 200 degrees C. and an inorganic refractory layer wherein the refractory layer comprises platelets in an amount at least 85% by weight with a dry areal weight of 15 to 50 gsm and has a residual moisture content of no greater than 10 percent by weight. |
117 |
Composite flame barrier laminate for a thermal and acoustic insulation blanket |
US14705017 |
2015-05-06 |
US09643711B2 |
2017-05-09 |
Llewellyn Bentley Richardson, III; Dariusz Wlodzimierz Kawka |
A multilayer laminate for use as a flame barrier in an aircraft comprising (i) a polymeric film layer capable of withstanding a temperature of at least 200 C for at least 10 min, (ii) an adhesive layer having an areal weight of from 2 to 40 gsm capable of activation at a temperature of from 75 to 200 degrees C., (iii) an inorganic refractory layer, and (iv) aramid paper comprising from 50 to 90 weight percent of aramid fibers and from 10 to 50 weight percent of meta-aramid binder wherein the inorganic refractory layer of (iii) comprises platelets in an amount of at least 85% by weight with a dry areal weight of 15 to 50 gsm and a residual moisture content of no greater than 10 percent by weight. |
118 |
RADIOGRAPHIC FLAT PANEL DETECTOR HAVING A FERROMAGNETIC LAYER AND THE METHOD OF PRODUCTION THEREOF |
US15303757 |
2015-04-17 |
US20170040078A1 |
2017-02-09 |
Paul LEBLANS; Luc STRUYE; Ilse MANS; Sabina ELEN |
A radiographic flat panel detector includes a layer configuration in the order given: a) a radiation transparent substrate; and b) a scintillator layer applied by means of vapour deposition on the radiation transparent substrate; and c) an imaging array between the scintillator layer and a second substrate, characterised in that the radiation transparent substrate has on a side a layer including magnetizable particles and a method for producing the radiographic flat panel detector. |
119 |
THERMAL ACOUSTIC INSULATION BLANKETS |
US15106904 |
2014-12-23 |
US20170001709A1 |
2017-01-05 |
Paula COJOCARU; Stefano MORTARA; Francesco Maria TRIULZI; Marco APOSTOLO |
The present invention pertains to an insulation system comprising one or more insulation blankets, wherein each of said multilayer insulation blankets comprises: —a core consisting of an insulation material [material (I)], and —a shell encapsulating said core, said shell comprising at least one multilayer assembly comprising: (1) an outer layer [layer (L1)] consisting of a composition [composition (C1)] comprising, preferably consisting of at least one thermoplastic polymer [polymer (1)] having a limiting oxygen index (LOI) of at least 20% by volume, wherein at least one surface, preferably the inner surface, of said layer (L1) comprises one or more grafted functional groups [surface (L1-f)], (2) directly adhered to said at least one surface (L1-f), a layer consisting of at least one metal compound (M1) [layer (L2)], and (3) optionally, directly adhered to the opposite side of the layer (L2), a layer consisting of at least one metal compound (M2) [layer (L3)], said metal compound (M2) being equal to or different from said metal compound (M1). The present invention also pertains to a process for the manufacture of said insulation system and to uses of said insulation system in various applications including aircraft applications. |
120 |
PEBA FOR DIRECT ADHESION TO TPE |
US15192276 |
2016-06-24 |
US20160376483A1 |
2016-12-29 |
René-Paul EUSTACHE; Mathieu SABARD; Yves DEYRAIL; Quentin PINEAU; Inci TURAN-ALTUNTAS; Martin POUZET; Atsushi YOSHITAKE |
The invention relates to a copolymer having polyamide PA blocks and polyether PE blocks, in which PA is of diamine.diacid X.Y type; X, the number of carbons of the diamine, is within the range from 6 to 14, and Y, the number of carbons of the diacid, is within the range from 6 to 18. The invention also relates to the use of the said copolymer in a process of direct adhesion between two TPE materials for increasing the peel strength between these materials. |