81 |
Quartz/solid surface laminate |
US11410546 |
2006-04-25 |
US20070248836A1 |
2007-10-25 |
John Linde |
The present invention relates to a method of fabricating a laminate sheet product by using heat and pressure to form thermoformable particulates, such as acrylics and/or non-thermoformable particulates, such as polyester granules, quartz, or silica, into a sheet product. The invention also includes a particulate laminate sheet product comprising a melamine or phenolic backer sheets and a layer of one or more particulates. In preferred embodiments, melamine overlay sheets are also included in the laminate sheet. The invention also includes a particulate laminate sheet product made by the method of fabricating a laminate sheet product using heat and pressure to form thermoformable particulates, such as acrylics and/or non-thermoformable particulates, such as polyester granules, quartz, or silica, into a sheet product. |
82 |
Products containing an anti-fungal amount of a salt of formic acid |
US10965051 |
2004-10-14 |
US07267888B1 |
2007-09-11 |
James Richard Von Krosigk; Thomas E. Peterson |
A building material adapted for controlling growth of vegetative fungi from spores having a compressed calcium sulfate layer, a paper layer over the sulfate layer, an adhesive for securing the paper layer to the sulfate layer; an amount of between about 30 wt % to 50 wt % of a salt of formic acid disposed on the paper layer thereby forming sheet rock with an ionic lattice on the surface to prevent vegetative growth from fungi spores, and a paint, an adhesive, a sealant, and an insulation each containing an antifungal amount of a salt of formic acid, such as potassium formate. |
83 |
Paper envelope having an integrated magnetic recording medium |
US11341980 |
2006-01-27 |
US20070178261A1 |
2007-08-02 |
Avery Levy; Zory Ginzburg |
A paper envelope which includes as an integral part thereof, a magnetic recording medium which is disposed in a plurality of interconnected cells. The cells containing the magnetizable material to form the magnetic recording medium are covered by an additional layer of paper to protect and/or retain the magnetizable particles in place. |
84 |
Optically embossed sheet for a laminate and method of making |
US11119953 |
2005-05-02 |
US07141295B2 |
2006-11-28 |
John Carmelo Genzabella; William Michael Hines, Jr.; George Anthony Baldasarre |
An optically embossed sheet (10) for a laminate (107) for decorative boards includes a base layer (12) having a print surface (14) and an opposed resin application surface (16), wherein the print surface (14) defines a decorative area (18). A small particle ink (20) overlies the decorative area (18), and a large particle ink (22) overlies the small particle ink (20) within a low-gloss region (24) defined within the decorative area (18). A thermosetting resin is applied only to the resin application surface so that more than fifty percent of the particles of the small particle ink (20) at the print surface (14) are coalesced by the thermosetting resin (26) into agglomerations (27), and less than about thirty percent of the particles of the large particle ink (22) are coalesced into agglomerations (27) giving rise to a substantial gloss differential at the print surface (14). |
85 |
Paper-laminated articles of manufacture and method |
US10856533 |
2004-05-28 |
US20040247917A1 |
2004-12-09 |
Antonio
M.
Mendes |
Molded wood-based decorative articles can be prepared by first laminating a paper sheet to a shaped, wood-based substrate, e.g., natural wood or a man-made board, preferably fiberboard, prior to applying a moldable cellulosic composition over at least one outer surface of the paper overlay. Surprisingly, the moldable cellulosic composition has excellent adherence to the paper overlay, so long as the paper does not have an anti-stick coating, such as a silicone or other lubricious surface treatment. The preferred paper is kraft paper that has no surface coating. After adhering the paper to the shaped, wood-based article, the moldable cellulose-based composition is applied to one or more outer surfaces of the paper overlay in a thickness of preferably in the range of {fraction (1/32)} inch to 1.0 inch and the cellulosic composition then is molded to form a decorative pattern on one or more outer surfaces of the paper overlay. The article then is coated with a decorative coating material, such as a water-or oil-based paint or powder coating, single or multiple coats, over both the molded cellulosic composition and paper overlay to provide exceptional aesthetics. |
86 |
Laminate flooring planks incorporating antimicrobial agents |
US10773859 |
2004-02-06 |
US20040175545A1 |
2004-09-09 |
Robert
R.
Krebs; Victoria
Lynn
Stolarski; Curt
R.
Haffner |
A flooring plank includes a decorative upper surface, a core layer providing support and stability to the flooring plank and a backing layer secured to the underside of the core layer. The core layer includes a plurality of edges adapted for engagement with adjacent flooring planks during the installation of flooring planks in accordance with the present invention. In addition, the backing layer includes at least one sheet of resin impregnated paper and an antimicrobial agent acting upon unwanted biological organisms so as to inhibit the growth of mold, mildew, bacteria or other unwanted biological agents adjacent the underside of the flooring plank. |
87 |
Magnet sheet for display and method of manufacturing the same |
US10190542 |
2002-07-09 |
US20040009370A1 |
2004-01-15 |
Seiji
Abe |
It is sought to provide a magnet sheet for display, which, while being as large as A3 to A4 sizes or more, is free from being broken or formed with holes, has a desired uniform thickness, permits ready printing on it with a plotter, a copier or like printing machine, is excellent in the magnetic attachment property and permits a heretofore unseen, magnetically attachable large size advertisement poster. A magnet sheet 1 for display is formed by laminating a print sheet 3 of paper or synthetic resin film having a thickness of 0.1 to 0.2 mm on either one or each surface of a magnet sheet 2 having a width of 600 mm or more, a length capable of being set as desired and a thickness of 0.1 to 0.2 mm and magnetically attachable to a magnetic surface. A desired display such as a painting, letters, drawings and photographs is printed on the surface of the print sheet by using a plotter, a copier, a printer or like printing machine. |
88 |
Abrasion resistant laminate and process for producing same |
US09977425 |
2001-10-15 |
US20020025426A1 |
2002-02-28 |
Fouad
Torkum
Karam |
A laminated panel having an abrasion resistant surface is provided. The laminated panel includes a web being impregnated with a thermo-set resin, a bottom coat and an abrasion resistant top coat; a substrate; and thermo-fusing a bottom sheet to a second surface of the substrate opposite the first surface. The web is thermo-fused to one surface of the substrate, and the bottom sheet is simultaneously thermo-fused to the opposite surface of the substrate. A process for making an abrasion resistant laminated panel is also provided. The process includes the steps of partially impregnating a paper sheet or web with a thermosetting resin, drying it, coating the top side of the partially impregnated paper sheet or web with an abrasion resistant coat, simultaneously coating the bottom side of the paper sheet or web with a thermosetting resin composition, thermo-fusing the coated paper sheet or web to a first surface of a substrate and a bottom sheet to produce the laminated panel. |
89 |
Adhesive for bonding decorative melamine treated paper to particle board |
US739399 |
1996-10-31 |
US5804618A |
1998-09-08 |
Robson Mafoti; Tien-Chieh Chao |
Polyvinyl acetate emulsion based adhesives can be made effective for bonding melamine formaldehyde resin treated decorative solid color and print paper to particle board. This polyvinyl acetate emulsion based adhesive is formulated with tackified polyvinyl alcohol, starch, a tackifier and a coupling agent. Stress cracking is substantially eliminated. Additionally, wrinkling and edge and corner peel resulting during the movement of sheets of melamine resin treated paper on the top and bottom surfaces of sheets of particle board through a heating and pressing zone is substantially eliminated. |
90 |
Moisture resistant frozen food packaging using an over-print varnish |
US660671 |
1996-06-05 |
US5766732A |
1998-06-16 |
Robinson Camden Perkins Claytor |
This invention relates to moisture resistant frozen food packaging using highly-sized paperboard and press applied moisture resistant over-print varnishes. Such structures of this type, generally, employ a moisture-resistant coating which is placed between the food product and the paperboard in order to provide a barrier for the food from the board and also to prevent the paperboard from absorbing moisture. Also, edge-wick moisture absorption is minimized by the use of the highly-sized sheet. |
91 |
Film composite |
US436454 |
1995-06-29 |
US5714269A |
1998-02-03 |
Francisco Munoz Madrid |
A film suitable for continuous application to particle boards in the making of laminated particle board is disclosed, which film is stem penetrable and impregnated with semi-cured impregnating resins and provided with a partially cured layer of glue on one side and a fully cured lacquer layer on the other side, which film is permeable to gases generated during production of laminated particle board. A process for producing such a film is also disclosed and also a method for producing a laminated particle board by means of a continuous direct lamination process. |
92 |
Process for making colored resin impregnated paper sheets with a
three-dimensional surface structure and laminates using the sheets |
US601558 |
1984-04-18 |
US4652482A |
1987-03-24 |
Hans-Dieter Diesel; Hans J. Schmidt; Burkhard Sauer |
A process for the production of colored films of paper impregnated with synthetic resin which contain melamine resin and have a three-dimensional surface structure, by printing the paper films with a colored pattern using an aqueous protein-based printing ink and lacquering thereover. The color which is printed in the regions in which the lacquer layer is to be thinner than in the other regions contains a lacquer repellent, and the printed and dried paper film is impregnated with an aqueous impregnation of a melamine resin from the unprinted side, with the formation of a one-sided excess of resin, and is dried. The printed and impregnated film is coated on the printed side with an aqueous lacquer based on melamine resins, and the lacquered film is hardened at elevated temperature without applying pressure. A laminate is produced by joining the unprinted side of the hardened film to a substrate such as chipboard. |
93 |
Process for protecting the surface of an image |
US21130171 |
1971-12-23 |
US3799827A |
1974-03-26 |
TAKIMOTO M; MATSUMOTO S |
IMAGES ARE PROTECTED BY LAMINATING A FILM OVER THE SURFACE OF THE IMAGE. A PRESSURE ROLLER PROVIDED WITH PROJECTIONS IS USED TO IMPROVE THE BONDING OF THE FILM TO THE IMAGE SUPPORT.
|
94 |
Thin decorative sheet and a decorative laminate produced therefrom |
US3736220D |
1971-03-30 |
US3736220A |
1973-05-29 |
MANUBAHI SHAH B |
A DECORATIVE PAPER SHEET FOR USE IN A DECORATIVE LAMINATED IMPREGNATED WITH AN ACRYLIC POLYMER COMPOSITION AND PREFERABLY WITH A MELAMINE RESIN-ACRYLIC POLYMER COMPOSITION AND SURFACED WITH FINELY DIVIDEED PARTICLES OF A POLYMER OF ACRYLONITRILE AND TO THE LAMINATES PRODUCED THEREFROM.
|
95 |
Thermosensitive recording material |
US14772274 |
2014-03-06 |
US10099499B2 |
2018-10-16 |
Daiki Iwata; Takeshi Kajikawa; Hideo Aihara |
To provide a thermosensitive recording material, containing: a support; an under layer; a thermosensitive recording layer; and a protective layer, where the under layer, the thermosensitive recording layer, and the protective layer are provided in this order on at least one surface of the support, wherein the support is synthetic paper, or a synthetic resin film, wherein the under layer contains a binder resin, and hollow particles, wherein an adhesive force of the thermosensitive recording material at −20° C., as measured by the described measuring method of the adhesive force, is 10.0 N/25 mm or greater. |
96 |
FLEXIBLE MICROSPHERE ARTICLES HAVING HIGH TEMPERATURE STABILITY |
US15550140 |
2015-06-15 |
US20180044465A1 |
2018-02-15 |
Christopher B. Walker, Jr.; John C. Clark; Alexander J. Kugel; Vivek Krishnan; Abdullahi A. Mohamud |
There is provided an article a binder resin layer comprising an aliphatic polyurethane polymer comprising a plurality of soft segments, and a plurality of hard segments, where the soft segments comprise polycarbonate polyol; and a plurality of microspheres partially embedded and adhered to a first major surface of the binder resin layer, wherein the specific chemical identities and relative amounts of the segments and moieties of the aliphatic polyurethane polymer are sufficient to impart a glass transition temperature of 10° C. or less in the article and a storage modulus in the article that changes less than 15 MPa from 25° C. to 175° C. |
97 |
Composite Film |
US15555387 |
2015-08-24 |
US20180037010A1 |
2018-02-08 |
Lambert Nekula; Martin Kornfeld; Adolf Schedl; Harald Gruber |
A composite film including at least one backing film made of a backing material, at least one barrier layer made of a barrier film and at least one laminating adhesive layer therebetween. On the side of the barrier layer away from the backing layer, the composite film has a raised pattern, and in the area of the raised pattern, the barrier layer has stretched stretching regions relative to the non-stretched barrier film. In the area of the raised pattern, the barrier layer has on the side facing the backing layer surfaces that are not joined to the backing layer. |
98 |
ARTICLES WITH CONFOUNDED EMISSION CHARACTERISTICS AND METHODS AND APPARATUS FOR THEIR AUTHENTICATION |
US15430194 |
2017-02-10 |
US20170154488A1 |
2017-06-01 |
William Ross Rapoport; Carsten Lau; James Kane |
Embodiments include articles, authentication methods and apparatus, and article manufacturing methods. An article includes a substrate with a first luminescent taggant, and an extrinsic feature with a second luminescent taggant, which is positioned proximate a portion of the article surface. The first and second taggants produce emissions in overlapping emission bands as a result of exposure to excitation energy. Above the extrinsic feature, the substrate and extrinsic feature emissions combine in the overlapping emission band to produce “confounded” emissions that are distinguishable from the substrate emissions taken alone. An authentication system determines whether, in a region corresponding to a “substrate-only” region of an authentic article, emissions having first emission characteristics are detected in the overlapping emission band. The system also determines whether, in a region corresponding to an “extrinsic feature” region of an authentic article, the confounded emissions are detected in the overlapping emission band. |
99 |
Packaging materials with enhanced thermal-insulating performance |
US13958086 |
2013-08-02 |
US08647717B2 |
2014-02-11 |
Vladislav Babinsky; Sven S. Arenander; Bruce W. Babcock; David H. Hawes; Dobridge C. Newman |
A method for preparing a thermo-insulating packaging material including steps of providing a first paper-based substrate, applying a fluid thermal-insulating composition onto the first paper-based substrate, the thermal-insulating composition including a filler, an organic binder, a plasticizer, and water, applying a second paper-based substrate over the thermal-insulating composition such that the thermal-insulating composition is positioned between the first paper-based substrate and the second paper-based substrate to form a structure, and drying the structure. |
100 |
Packaging Materials with Enhanced Thermal-Insulating Performance |
US13958086 |
2013-08-02 |
US20130312894A1 |
2013-11-28 |
Vladislav Babinsky; Sven S. Arenander; Dobridge C. Newman; Bruce W. Babcock; David H. Hawes |
A method for preparing a thermo-insulating packaging material including steps of providing a first paper-based substrate, applying a fluid thermal-insulating composition onto the first paper-based substrate, the thermal-insulating composition including a filler, an organic binder, a plasticizer, and water, applying a second paper-based substrate over the thermal-insulating composition such that the thermal-insulating composition is positioned between the first paper-based substrate and the second paper-based substrate to form a structure, and drying the structure. |