101 |
Fireproof sandwich board |
JP52507998 |
1996-12-03 |
JP2001505828A |
2001-05-08 |
カールステン クリスチャンセン |
(57)【要約】 ポリアミド球が埋入されたポリエステルの層で一方の側面がコーティングされた鋼板(11)の連続ウェブを用意し、昇華可能な染料で模様が印刷された転写材料(12)の連続ウェブを用意し、両ウェブを面対面接触させて加熱ローラ(13)の周囲の一部の回りを走行させ、昇華法により鋼板のウェブの印刷を行なうことにより製造される耐火サンドイッチボード用ライナのコイル。 ライナは感じの良い外観を有し、本発明により製造されるボードは、引火試験において優れた性能を証明している。 |
102 |
JPH07504471A - |
JP51578193 |
1993-02-26 |
JPH07504471A |
1995-05-18 |
|
|
103 |
Anti-fouling coating for marine structure |
JP26299388 |
1988-10-20 |
JPH01230683A |
1989-09-14 |
JIEIMUZU ERU MANISOO |
PURPOSE: To prevent a toxicant from leaching into seawater, to easily remove the toxicant by making it operate effectively on sticking contaminant organisms, and to give superior durability with small consumption by forming the subject coating by sticking a 2nd layer of a porous organic high molecular film on a 1st layer of a marine antifoulant and anticorrosive coating material containing a biological toxicant.
CONSTITUTION: On the surface of a marine structure e.g. a ship 1, a coating layer 2 of a marine antifoulant and anticorrosive coating material containing a biological toxicant such as red lead oxide, basic blue lead sulfate, lead, zinc, and strontium chromate and optionally a coating layer 3 of a marine antifoulant and anticorrosive coating material containing a biological toxicant such as HgO, Cu
2O, HgCl
2, lead linoleate, and tributyl tin compound are formed thereupon to obtain the 1st layer. While the coating material of the coating layer 3 of is wet, the 2nd layer consisting of a porous high molecular film 4 of a porous polytetrafluoroethylene, etc., is partially incorporated in the 1st layer to fill gaps of the 2nd layer partially with the 1st layer, and this surface is brought into contact with seawater wherein marine organisms 5 are living.
COPYRIGHT: (C)1989,JPO |
104 |
Insulating material |
JP17789386 |
1986-07-30 |
JPS62121292A |
1987-06-02 |
ABI TSUZUURU |
|
105 |
Reinforcing material and reinforcing panel |
JP3657581 |
1981-03-16 |
JPS57151361A |
1982-09-18 |
OSADA MASAO; MIURA TOSHIKATSU; OKADA YUKIO; ASOSHINA HIDESHI; TOMINAGA TAKASHI; ROKUSHIYA TADAHIRO; SHIMIZU MASAHITO |
|
106 |
REMOVABLE FLOORING SYSTEM |
US16006776 |
2018-06-12 |
US20180354230A1 |
2018-12-13 |
Ming Zhao; Kyle Sanford Smith; Murty Venkata Bhamidipati; Michael Joseph Schatz; David Royston Hughes |
A removable multi-layered flooring system comprising a 1) a foundation or primer layer applied to an underlying flooring surface, 2) a peelable support comprising a supporting material and a cross-linkable or curable polymer composition that penetrates the supporting layer to form a unified, cohesive support that can be peeled from the foundation/primer layer in its entirety, and 3) one or more upper polymer layers applied to the top of the peelable support. The multilayered system can be applied to the surface of a sub-flooring, e.g., concrete, and remains secured until such time as a new flooring is desired, at which time the peelable support and upper polymer layers are removed, e.g., by peeling them from the foundation layer. |
107 |
COMPOSITE STRUCTURE ASSEMBLY HAVING A CONFORMABLE CORE |
US15588791 |
2017-05-08 |
US20180319121A1 |
2018-11-08 |
John C. Waldrop, III; Zachary Benjamin Renwick; Matthew Scott Thompson; Michael William Hayes |
A composite structure assembly includes a composite core including a flexible base and a plurality of cells extending from the flexible base. The composite core is conformable to different shapes. The plurality of cells are configured to move in response to movement of the flexible base. At least one of the plurality of cells may include a central column connected to a first flared end and a second flared end that is opposite from the first flared end. |
108 |
Systems for thermal management and methods for the use thereof |
US15811185 |
2017-11-13 |
US10121725B2 |
2018-11-06 |
Yuan Zhao; Mulugeta Berhe; Daniel Maslyk; Scott Timon Allen |
In accordance with the present invention, there are provided heat dispersing articles, assemblies containing same, methods for the preparation thereof, and various uses therefor. In one aspect of the present invention, there are provided heat dispersing articles. In another aspect of the present invention, there are provided methods for producing the above-referenced articles. In yet another aspect of the present invention, there are provided assemblies containing the above-referenced articles. In still another aspect of the present invention, there are provided methods for making the above-referenced assemblies. In yet another aspect, there are provided methods to dissipate the heat generated by portable electronic devices. |
109 |
CYANATE RESIN BLENDS AND RADOMES INCLUDING THEM |
US15913759 |
2018-03-06 |
US20180258223A1 |
2018-09-13 |
Kapsoo Cheon; Marie J. Demers; Ajay Padwal |
Certain embodiments are directed to cyanate resin blends comprising, for example, a mixture of a cyanate monomer and a cyanate oligomer. The resin blends are effective to provide a dielectric constant of less than 2.7, a glass transition temperature of at least 150° C. and a moisture absorption of less than 1.5%. Radomes using the resin are also described. |
110 |
Prepreg and fiber-reinforced composite material |
US14234996 |
2012-07-25 |
US10072377B2 |
2018-09-11 |
Yuko Shimizu; Nobuyuki Tomioka; Shirou Honda; Maki Nagano; Yuji Echigo; Hiroshi Takezaki; Junko Kawasaki; Hiroshi Taiko |
A fiber reinforced composite material having high interlaminar toughness and compressive strength under wet heat conditions, as well as an epoxy resin composition for production thereof and a prepreg producible from the epoxy resin composition is described. The prepreg includes at least constituents [A], [B], and [C] as specified below and reinforcement fiber, wherein 90% or more of constituent [C] exists in the depth range accounting for 20% of the prepreg thickness from the prepreg surface: [A] epoxy resin; [B] epoxy resin curing agent; and [C] polymer particles insoluble in epoxy resin. |
111 |
FUSED SHEET FOR ELECTROMAGNETIC WAVE ABSORPTION-EXTINCTION AND SHIELDING, AND FOR ELECTRONIC EQUIPMENT HIGH HEAT DISSIPATION, AND METHOD OF MANUFACTURING THE SAME |
US15317154 |
2016-09-06 |
US20180162098A1 |
2018-06-14 |
Hak Sik JOO |
The present invention discloses a fused sheet for electromagnetic wave absorption/extinction and shielding, and for electronic equipment high heat dissipation. The fused sheet for electromagnetic wave absorption/extinction and shielding, and for electronic equipment high heat dissipation of the present invention includes a premolded graphite sheet prepared by molding a graphite substrate into a sheet form having a density in a range of 0.1-1.5 g/cm3 and an incomplete state of crystal structure; and a porous metal sheet having a plurality of pores connected to upper and lower surfaces of the porous metal sheet, wherein the premolded graphite sheet is stacked on one surface of the porous metal sheet, and press molded to be integrally attached and combined, so as to have a density of 1.6 g/cm3-6.0 g/cm3 |
112 |
Fluid-Filled Chamber for an Article of Footwear |
US15894076 |
2018-02-12 |
US20180160772A1 |
2018-06-14 |
Bryan K. Youngs |
A fluid-filled chamber is provided and includes a first barrier layer, a second barrier layer, a foam structure, and a tensile member. The second barrier layer is secured to the first barrier layer to define an interior void between the first barrier layer and the second barrier layer. The interior void contains a predetermined volume of fluid. The foam structure and the tensile member are disposed within the interior void, whereby the tensile member includes a plurality of fibers extending in a first direction between the first barrier layer and the second barrier layer. |
113 |
PANEL FOR COVERING AND/OR SOUNDPROOFING A WALL OF A VEHICLE AND ASSOCIATED METHOD OF MANUFACTURE |
US15571403 |
2016-05-02 |
US20180126924A1 |
2018-05-10 |
Clément Humbert; Vincent Bonin; Laurent Mougnard |
A panel for covering and/or soundproofing a wall of a vehicle includes a central layer produced by impregnating a flexible and porous material with a thermoformable resin, then rigidifying the thermoformable resin. The panel also includes two reinforcement layers arranged on either side of the central layer. The impregnation of the flexible and porous material with the thermoformable resin is carried out deep within the flexible and porous material by subjecting a powder of the thermoformable resin to an alternating electric field, the two reinforcement layers being made of a flexible or semi-rigid material. |
114 |
OUTER COATING FOR SHIP HULL |
US15572088 |
2016-05-25 |
US20180094144A1 |
2018-04-05 |
Christian BUMM |
The invention relates to an outer coating of a ship's hull in the underwater area, wherein the coating comprises a bottom layer on the hull exterior, said layer being made of an adhesive or an ethylene-propylene-diene rubber and being particularly designed as a film, and a superimposed top layer made of an ultra high-molecular weight polyethylene. |
115 |
WET COATING COMPOSITIONS FOR PAPER SUBSTRATES, PAPER SUBSTRATES COATED WITH THE SAME AND PROCESS FOR COATING A PAPER SUBSTRATE WITH THE SAME |
US15809600 |
2017-11-10 |
US20180072915A1 |
2018-03-15 |
Yvon MONGRAIN; Guillaume TURGEON |
A wet coating composition useful for coating a cellulosic fiber-based substrate is provided. The composition includes two aqueous emulsions. The first emulsion includes an oxidized paraffin/polyethylene wax and the second emulsion includes an ethylene/acrylic acid copolymer wax, ethylene/acrylic amide copolymer wax, ethylene/acrylic acid/acrylic amide copolymer wax or a mixture thereof. The oxidized paraffin/polyethylene wax has a surface energy less than or equal to 25 mN/m being substantially dispersive energy. The wet coating composition when dried forms a coating having a surface energy ranging from 20 to 60 mN/m being the sum of dispersive and polar energies. A process for treating a cellulosic fiber-based substrate with the wet coating composition, a substrate coated and articles including the coated substrate are also described. The process involves a heating step to allow migration of the coating towards a core of the cellulosic fiber-based substrate. |
116 |
Cyanate resin blends and radomes including them |
US14314059 |
2014-06-25 |
US09914803B2 |
2018-03-13 |
Kapsoo Cheon; Marie J. Demers; Ajay Padwal |
Certain embodiments are directed to cyanate resin blends comprising, for example, a mixture of a cyanate monomer and a cyanate oligomer. The resin blends are effective to provide a dielectric constant of less than 2.7, a glass transition temperature of at least 150° C. and a moisture absorption of less than 1.5%. Radomes using the resin are also described. |
117 |
ALUMINUM-SILICON CARBIDE COMPOSITE AND PRODUCTION METHOD THEREFOR |
US15500210 |
2015-07-29 |
US20170236767A1 |
2017-08-17 |
Takeshi MIYAKAWA; Motonori KINO; Hideki HIROTSURU |
An aluminum-silicon carbide composite including flat-plate-shaped composited portion containing silicon carbide and an aluminum alloy, and aluminum layers containing an aluminum alloy provided on both plate surfaces of composited portion, wherein circuit board is mounted on one plate surface and the other plate surface is used as heat-dissipating surface, wherein: the heat-dissipating-surface-side plate surface of the composited portion has a convex curved shape; the heat-dissipating-surface-side aluminum layer has a convex curved shape; ratio (Ax/B) between the average (Ax) of the thicknesses at the centers on opposing short sides of outer peripheral surfaces and thickness (B) at central portions of the plate surfaces satisfies the relationship: 0.91≦Ax/B≦1.00; and a ratio (Ay/B) between the average (Ay) of the thicknesses at the centers on opposing long sides of outer peripheral surfaces and thickness (B) at central portions of the plate surfaces satisfies the relationship: 0.94≦Ay/B≦1.00 and production method therefor. |
118 |
Free-Standing Modular Fence System |
US15152042 |
2016-05-11 |
US20170167162A1 |
2017-06-15 |
Michael E. Martin |
A free-standing fence system includes two or more posts and one or more substantially planar prefabricated panels. Each prefabricated panel is configured to be coupled to two of the posts. Each prefabricated panel comprises a foam core and a first veneer layer. The foam core has a first side and a second side. The first veneer layer is coupled to and substantially covers the entire first side of the foam core. The veneer layer comprises one or more veneer members. Each veneer member includes a decorative layer of a continuous natural stone material and a binding layer coupled to a rear surface of the decorative layer. |
119 |
Double-Sided Adhesive Sheet, Joining Method Using Double-Sided Adhesive Sheet, And Method For Producing Double-Sided Adhesive Sheet |
US15370830 |
2016-12-06 |
US20170081559A1 |
2017-03-23 |
Hiroki Nakahara; Yoshikazu Soeda |
A double-sided adhesive tape has an adhesive member which is formed in the shape of a film and whose both surfaces in a thickness direction have an adhesive force and a pair of separation films which are arranged so as to sandwich the adhesive member in the thickness direction. The double-sided adhesive tape is formed so as to have a non-planar shape and to reduce the occurrence of wrinkles in the adhesive member when the adhesive member is adhered to a non-planar adherend. |
120 |
Composite Materials with Tapered Reinforcements |
US14739831 |
2015-06-15 |
US20160361890A1 |
2016-12-15 |
Daniel H. Hecht |
A composite material includes a plurality of reinforcements arranged in a plurality of layers. Each reinforcement comprises a tapered shape that allows the reinforcements of a particular layer to nest with reinforcements of an adjacent layer. The composite material further includes an adhesive that is at least partially between the layers of reinforcements. |