| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 161 | MULTILAYER NONWOVEN FABRIC FOR FOAM MOLDING | US14950672 | 2015-11-24 | US20160075103A1 | 2016-03-17 | Taro ICHIKAWA; Yoshinori KOBAYASHI; Hidenori YOSHIZAWA |
| Multilayer nonwoven fabrics for foam molding that have excellent resistance to the separation of layers, have reinforcing effects and urethane leakage prevention performance, and are producible without the occurrence of fiber dust on the surface. In the multilayer nonwoven fabric for foam molding, a reinforcing layer is stacked on at least one side of a dense layer, the dense layer includes a meltblown nonwoven fabric layer (A) and spunbonded nonwoven fabric layers (B) that are stacked on both sides of the layer (A), and the meltblown nonwoven fabric layer (A) and the spunbonded nonwoven fabric layers (B) are partially thermocompression bonded with each other. | ||||||
| 162 | Lacrosse head pocket and related method of manufacture | US14815201 | 2015-07-31 | US09259883B1 | 2016-02-16 | David K. Morrow; Bruce Huffa; Thomas H. Burns; Richard J. Janisse; Sean J. Slater; Dale W. Kohler; Craig M. Herman |
| A lacrosse head pocket and a related method of manufacture are provided to facilitate consistent, repeatable and/or custom manufacture of lacrosse equipment. The pocket can be constructed from multiple different sections joined with one another, or can be knitted, weaved or otherwise assembled on an automated assembly machine from strands, and/or can be formed as a unitary textile material having regions/sections with different physical and/or mechanical properties. The pocket can be integrally molded within portions of a lacrosse head to eliminate manually constructed connections between the pocket and lacrosse head. The lacrosse head can be integrally molded with a lacrosse handle to provide a one-piece unitary lacrosse stick. Related methods of manufacturing also are provided. | ||||||
| 163 | LACROSSE HEAD POCKET AND RELATED METHOD OF MANUFACTURE | US14815201 | 2015-07-31 | US20160039134A1 | 2016-02-11 | David K. Morrow; Bruce Huffa; Thomas H. Burns; Richard J. Janisse; Sean J. Slater; Dale W. Kohler; Craig M. Herman |
| A lacrosse head pocket and a related method of manufacture are provided to facilitate consistent, repeatable and/or custom manufacture of lacrosse equipment. The pocket can be constructed from multiple different sections joined with one another, or can be knitted, weaved or otherwise assembled on an automated assembly machine from strands, and/or can be formed as a unitary textile material having regions/sections with different physical and/or mechanical properties. The pocket can be integrally molded within portions of a lacrosse head to eliminate manually constructed connections between the pocket and lacrosse head. The lacrosse head can be integrally molded with a lacrosse handle to provide a one-piece unitary lacrosse stick. Related methods of manufacturing also are provided. | ||||||
| 164 | LACROSSE HEAD POCKET AND RELATED METHOD OF MANUFACTURE | US14815172 | 2015-07-31 | US20160038804A1 | 2016-02-11 | Thomas H. Burns; Adam D. Paquette; Sean J. Slater |
| A lacrosse head pocket and a related method of manufacture are provided to facilitate consistent, repeatable and/or custom manufacture of lacrosse equipment. The pocket can be constructed from multiple different sections joined with one another, or can be knitted, weaved or otherwise assembled on an automated assembly machine from strands, and/or can be formed as a unitary textile material having regions/sections with different physical and/or mechanical properties. The pocket can be integrally molded within portions of a lacrosse head to eliminate manually constructed connections between the pocket and lacrosse head. The lacrosse head can be integrally molded with a lacrosse handle to provide a one-piece unitary lacrosse stick. Related methods of manufacturing also are provided. | ||||||
| 165 | LACROSSE HEAD POCKET AND RELATED METHOD OF MANUFACTURE | US14815145 | 2015-07-31 | US20160038803A1 | 2016-02-11 | Thomas H. Burns; Adam D. Paquette; Dale W. Kohler; Sean J. Slater |
| A lacrosse head pocket and a related method of manufacture are provided to facilitate consistent, repeatable and/or custom manufacture of lacrosse equipment. The pocket can be constructed from multiple different sections joined with one another, or can be knitted, weaved or otherwise assembled on an automated assembly machine from strands, and/or can be formed as a unitary textile material having regions/sections with different physical and/or mechanical properties. The pocket can be integrally molded within portions of a lacrosse head to eliminate manually constructed connections between the pocket and lacrosse head. The lacrosse head can be integrally molded with a lacrosse handle to provide a one-piece unitary lacrosse stick. Related methods of manufacturing also are provided. | ||||||
| 166 | COMPOSITE FLANGE WITH THREE-DIMENSIONAL WEAVE ARCHITECTURE | US14884538 | 2015-10-15 | US20160031182A1 | 2016-02-04 | CHRISTOPHER M. QUINN; SREENIVASA R. VOLETI |
| According to various embodiments, a carbon fiber structure is presented. The carbon fiber structure may address loads presented to an engine component in various directions. For instance, non-planar surfaces of a composite comprising a structure disclosed herein may achieve enhanced stiffness and/or strength. Thus, delamination of elements comprising a structure disclosed herein may be reduced. A three dimensional weave of carbon fiber elements through-thickness may provide enhanced strength to the composite material. | ||||||
| 167 | LACROSSE HEAD POCKET AND RELATED METHOD OF MANUFACTURE | US14873436 | 2015-10-02 | US20160023071A1 | 2016-01-28 | Thomas H. Burns; Richard J. Janisse; Sean J. Slater; Dale W. Kohler; Craig M. Herman |
| A lacrosse head pocket and a related method of manufacture are provided. The pocket can be a molded pocket including individual molded strings, combined strings, shooting strings and support rails extending around a perimeter of the pocket. Certain pocket elements can include transition parts to smoothly transition components having different cross sections. The pocket can include a pre-formed ball channel and hole units having broadsides for connection to a head or other component. The pocket can be attached to a pocket frame, and optionally constructed from a mesh or other synthetic material that is tensioned with the pocket frame. A mold and related molding method are also provided. | ||||||
| 168 | Lacrosse head pocket and related method of manufacture | US14043492 | 2013-10-01 | US09162382B2 | 2015-10-20 | Thomas H. Burns; Richard J. Janisse; Sean J. Slater; Dale W. Kohler; Craig M. Herman |
| A lacrosse head pocket and a related method of manufacture are provided. The pocket can be a molded pocket including individual molded strings, combined strings, shooting strings and support rails extending around a perimeter of the pocket. Certain pocket elements can include transition parts to smoothly transition components having different cross sections. The pocket can include a pre-formed ball channel and hole units having broadsides for connection to a head or other component. The pocket can be attached to a pocket frame, and optionally constructed from a mesh or other synthetic material that is tensioned with the pocket frame. A mold and related molding method are also provided. | ||||||
| 169 | Method for detecting insert objects in an injection-moulded part | US13697495 | 2011-05-18 | US09149965B2 | 2015-10-06 | Erik Nielsen |
| A method for detecting an insert object in an injection-molded part pertains to an insert object that is fixedly connected to the injection-molded part during the injection molding by the insert object being placed in a cavity, which is surrounded by a mold wall of a mold, before the beginning of the injection-molding cycle. The mold wall includes at least one temperature or pressure sensor, which records and analyzes at least one measured value at at least one point in time during an injection-molding cycle. On the basis of the analysis, it is established whether an insert object was present at a specific location in the cavity during the injection-molding cycle. Finally, after it is ejected, the injection-molded part is sorted as an accepted part or a rejected part on the basis of the analysis of the measured value. | ||||||
| 170 | COMPOSITE PROSTHESIS WITH EXTERNAL POLYMERIC SUPPORT STRUCTURE AND METHODS OF MANUFACTURING THE SAME | US14252710 | 2014-04-14 | US20150202061A1 | 2015-07-23 | Matthew Noesner; Jerry Dong |
| A prosthesis including a support structure for enhancing kink and/or crush resistance. The support structure is connected to an outer surface of the prosthesis and includes at least two components, one of which has a lower melting point than the other. The component with the lower melting point is used to connect the support structure to the outer surface of the prosthesis. | ||||||
| 171 | Footwear assembly method with 3D printing | US13553368 | 2012-07-19 | US09005710B2 | 2015-04-14 | David P. Jones; Ryan R. Larson |
| Methods and systems are disclosed for apparel assembly using three-dimensional printing directly onto fabric apparel materials. Disclosed is a method and system for direct three-dimensional printing and assembly of an article of apparel, including designing a three-dimensional pattern for printing, positioning at least a portion of the article on a tray in a three-dimensional printing system, the portion being positioned substantially flat on the tray, printing a three-dimensional material directly onto the article using the designed pattern, curing the printed material, and removing the article from the three-dimensional printing system. | ||||||
| 172 | MANUFACTURING METHOD OF INTEGRATED FOAM-MOLDED PRODUCT AND INTEGRATED FOAM-MOLDED PRODUCT | US14479626 | 2014-09-08 | US20150072107A1 | 2015-03-12 | Etsunori FUJITA; Yumi OGURA; Seiji KAWASAKI; Shigeki WAGATA; Yoshimi ENOKI |
| To obtain an integrated foam-molded product whose manufacturing cost is reduced and which makes an effective use of a property of an integration target. Foaming heat generated at the time of the foaming of a polyurethane foam raw material, whose influence has been conventionally prevented by contriving a special measure, is positively used. The integration target is influenced by foaming heat generated at the time of the foaming of the polyurethane foam raw material in a mold, to thermally deform into a desired shape along a mold shape. Consequently, it is possible to mold the integration target into an arbitrary shape in a step of integrating the integration target with a polyurethane foam layer in the mold by integrated foaming, and therefore, there is no need to work the integration target to a state closer to a final shape in a step before it is disposed in the mold, which can simplify manufacturing steps and reduce manufacturing cost. | ||||||
| 173 | Method and apparatus for producing plastic products with integrated reinforcing structure | US13062839 | 2009-09-07 | US08974713B2 | 2015-03-10 | Lothar Kroll; Wolfgang Nendel; Frank Helbig; Karl-Heinz Hoyer; Tino Zucker; Martin Würtele |
| The present invention relates to a method and to an apparatus for producing plastic products with an integrated reinforcing structure. To do so, a flexible fabric is first placed onto a surface of a cavity of a mold and is successively coated with plastic on the various sides. | ||||||
| 174 | METHOD OF MANUFACTURING A PIECE OF AUTOMOTIVE VEHICLE EQUIPMENT AND ASSOCIATED PIECE OF EQUIPMENT | US14384125 | 2013-03-05 | US20150056430A1 | 2015-02-26 | Stève Jeunesse; Valérie Marcel |
| This method includes the arrangement of a first sheet (22A) of porous material on a first face (18) of a base layer and of a second sheet (22B) of porous material of a second face (20) of the base layer before a heating step. Each sheet (22A, 22B) of porous material has a thickness of less than that of the formed layer (16).The sheets (22A, 22B) of porous material confine between them the molten polymeric material derived from the heat fusible polymer fibers during the heating step. The sheets (22A, 22B) of porous material are bound to the formed layer (16) after the step for building up the formed layer (16), in order to make up a first composite body (12A). | ||||||
| 175 | METHOD OF MANUFACTURING ELECTRONIC PERCUSSION PAD | US14459704 | 2014-08-14 | US20150053068A1 | 2015-02-26 | TOMOYA MIYATA |
| An electronic percussion pad includes: a pad main body that is formed of a foaming elastomer; and a composite layer that includes an expandable fiber sheet laminated on a front surface of the pad main body. In the composite layer, fiber of the fiber sheet and a foaming elastomer of the pad main body are present, and the composite layer contains bubbles. | ||||||
| 176 | Process for the rapid fabrication of composite gas cylinders and related shapes | US12046716 | 2008-03-12 | US08858857B2 | 2014-10-14 | Geoffrey Michael Wood; Pamela M. Schneider; Steven C. Stenard |
| A method of fabricating a composite vessel encompassing rapid manufacturing that is applicable to composite hydrogen and other gas storage tanks, both for high-pressure cylinders, as well as low-pressure conformal tanks. The process of fabrication includes using a liner, of metal or plastic materials, over which a braided or developed preform is wrapped. The dry fiber wrapped liner is placed in a mold and resin injected into the cavity formed between the liner and the mold outer walls. The liner is flooded with heated and/or cooled pressurized fluid thus enabling complete and independent process control from within the liner for both the resin injection and the cure phases. Fiber placement control is determined through combined biaxial and triaxial braid/preform design, and by wrapping at controlled tension onto the supporting liner. Fiber tension control is further enhanced by the methodology of mold loading whereby tensioning forces are enacted during actual load and close. The process may use thermoset or thermoplastic resins and any of a variety of fibrous reinforcements such as carbon, boron, glass, natural, aramid or other fibers. | ||||||
| 177 | Footwear Assembly Method With 3D Printing | US13553368 | 2012-07-19 | US20140020192A1 | 2014-01-23 | David P. Jones; Ryan Larson |
| Methods and systems are disclosed for apparel assembly using three-dimensional printing directly onto fabric apparel materials. Disclosed is a method and system for direct three-dimensional printing and assembly of an article of apparel, including designing a three-dimensional pattern for printing, positioning at least a portion of the article on a tray in a three-dimensional printing system, the portion being positioned substantially flat on the tray, printing a three-dimensional material directly onto the article using the designed pattern, curing the printed material, and removing the article from the three-dimensional printing system. | ||||||
| 178 | Method for manufacturing thermoplastic resin pre-impregnated fiber structure | US13133658 | 2009-01-09 | US08623252B2 | 2014-01-07 | Ma Shui-Yuan; Ling-Ling Cheng |
| A process of manufacturing a fibrous article includes submerging a fiber substrate in a bath of first thermoplastic resin to impregnate the fiber substrate with the first thermoplastic resin; heating the fiber substrate until the fiber substrate becomes a thick continuous fiber substrate; cutting the thick continuous fiber substrate into units; stacking the fiber substrate units; pressing and heating the stacked fibrous structure units until a stacked fibrous structure is formed; heating a mold; conveying the stacked fibrous structure to the mold to melt; cooling the mold to shape the molten fibrous structure into a half-finished article; removing the half-finished article out of the mold; eliminating burrs and sharp edges of the half-finished article; conveying the half-finished article to the mold; and uniformly applying a molten second thermoplastic resin on an inner surface of the half-finished article by injection molding to produce the finished fibrous article. | ||||||
| 179 | Thermoplastic/Fiber Composite-Based Electrically Conductive Structures | US13954079 | 2013-07-30 | US20130309396A1 | 2013-11-21 | David J. Legare |
| A low-cost method for thermoplastic injection molding of thermoplastic/fiber composite structures which are imparted with the desired properties of electrical conductivity, radio frequency (RF) energy reflectivity, and electromagnetic interference (EMI) shielding, while also possessing the basic physical and structural properties of the same part produced by traditional resin/fiber composite means such as expoxy/carbon fiber lay-up or infusion. | ||||||
| 180 | PROCESSES FOR PRECUTTING LAMINATED FLOCKED ARTICLES | US13646381 | 2012-10-05 | US20130115408A1 | 2013-05-09 | Louis Brown Abrams |
| A process for forming a flocked article is provided that includes the steps of: (a) cutting a pre-formed or solid adhesive film into a desired shape; (b) removing a first portion of the cut pre-formed adhesive film from a second portion of the cut pre-formed adhesive film; and (c) heating and applying pressure to the cut pre-formed adhesive film to adhere the film to flock to form a flocked article. | ||||||
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