| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 221 | 통기성 탄성 라미네이트 및 그의 제조 방법 | KR1020067011995 | 2004-12-17 | KR1020060127412A | 2006-12-12 | 오시키,매튜,존; 클락,티모시,엘.; 피콕,앤드류,제이.; 크리,제임스,더블류. |
| A method for forming a laminate including introducing a nonelastic material (50) into contact with an elastic material (60) which is extruded thereon, introducing materials (50) and (60) to a pressure differential source (30) with material (50) interposed between source (30) and material (60), and applying a pressure differential via source (30) to form an apetured laminate. | ||||||
| 222 | 인테리어 라이닝용 헤드라이너의 제조 방법 | KR1020050034856 | 2005-04-27 | KR1020060066584A | 2006-06-16 | 미로네스고메즈,라몬; 아리즈나바레타에스테반프란시스코야비에르 |
| 본 발명은 자동차 인테리어용 헤드라이너의 제조 방법에 관한 것으로, 특히 층상재료로부터 얻어진 헤드라이너로서 중심층은 최소한 두 개의 저밀도 섬유재료층(2)으로 이루어지고, 각각의 섬유재료는 열경화성수지(3)에 완전히 매립되어 있는 헤드라이너를 개시한다. 층의 형성 및 층간 결합은 열프레스를 사용하여 자동으로 이루어진다. 자동차, 헤드라이너, 열프레스, 인테리어 라이닝. | ||||||
| 223 | 방출이 제어되는 물질을 포함하는 탄력성 재료 | KR1020057008942 | 2003-11-10 | KR1020050086726A | 2005-08-30 | 마마로포롤로스,조지 |
| A flexible material allows for the controlled release of a microencapsulated substance. One element of the material is interwoven fibers. A second element is means for passing a current and generating localized heating interspersed among the fibers. A third element is at least one microcapsule, situated on or within the interwoven fibers and means for passing a current, containing a substance and releasing said substance upon rupture due to localized heating generated by selectively heating the means for passing a current. A fourth element is a means for controlling the current passed through the means for passing a current to enable controlled localized heating. | ||||||
| 224 | Holographic Laminate and the Tube Made Thereof | US15542112 | 2015-01-08 | US20180275606A1 | 2018-09-27 | Jun WANG; BoXian LI; Guoxing ZHANG |
| A laminate that may be used to store a product such as a toothpaste, various food items, lotions, etc. The laminate includes a reflective metal layer, a hologram layer, and an outer film interposed between the reflective metal layer and the hologram layer, wherein the outer film is transparent or translucent. The formation of the hologram layer can be performed at a lower temperature that the formation of other laminate structures so as not to damage the hologram. The laminate may be used as a tube wall, and can provide a self-sealing side seam. | ||||||
| 225 | Multi-axial grid or mesh structures with high aspect ratio ribs | US15418135 | 2017-01-27 | US10024002B2 | 2018-07-17 | Anthony T. Walsh |
| A multi-axial geogrid possesses a series of interconnected strands or ribs that are arranged along at least two different axes within the plane of the structure. The strands or ribs have an aspect ratio, defined as the ratio of the thickness to width, of greater than 1.0, thickness being the direction normal to the plane of the structure. The geogrid can be manufactured by modifying the process parameters in order to create high aspect ratio ribs, using any of the various known methods for producing geogrids. A reinforced civil engineering structure, and method therefor, is formed by embedding in soil one or more horizontal layers of geogrid having high aspect ratio ribs. The reinforced structure shows improved rutting performance when subjected to vehicular traffic. | ||||||
| 226 | Lightweight, durable apparel and laminates for making the same | US13826046 | 2013-03-14 | US09215897B2 | 2015-12-22 | Matthew A. Johnson; Edward C. Gunzel |
| Laminates are described having a durable outer film surface for use in making lightweight liquidproof articles of apparel, such as outerwear garments. A method of making the laminate and a lightweight outerwear garment having an abrasion resistant exterior film surface is described. | ||||||
| 227 | WATERPROOF APERTURED SURFACES OR MATERIALS USING NANOPARTICLE HYDROPHOBIC TREATMENTS | US14661506 | 2015-03-18 | US20150189960A1 | 2015-07-09 | Mark D. Shaw; Mathew P. Clancy |
| A method of manufacturing waterproof apertured materials or surfaces using nanoparticle hydrophobic compositions and treatments, and preferably superhydrophobic compositions and treatments, wherein apertures of a size that would normally render the surface or material water-permeable may be provided in the surface or material. The method comprises determining the extent of the hydrophobic field that extends beyond the physical edge of a particular treated intersecting member interwoven to form the material to determine the allowable size of an aperture, such that the extended hydrophobic field present on the intersecting members surrounding an aperture will be sufficient to prevent surface wetting and water permeability by fully overlapping the aperture or by presenting a reduced area effective aperture that precludes passage of water. In certain embodiments, the apertured material is provided with a liquid impermeable backing layer. | ||||||
| 228 | MULTI-SEASONAL CAMOUFLAGE PATTERN FABRICS AND COATINGS FOR HUNTING | US14562272 | 2014-12-05 | US20150083318A1 | 2015-03-26 | Benjamin Robert Harvey; William Allan Chesher |
| A method of making fabrics and coatings in a camouflage pattern with a printed camouflage pattern ink layer covered by a temperature activated color changing ink layer or layers printed in a camouflage pattern, which matches the pattern in the underlying printed camouflage fabric ink layer. The temperature activated color changing ink layer changes color state with a change of temperature to another color state or a clear state, which reveals the color state of the underlying printed camouflage fabric layer. The temperatures at which the temperature activated color changing ink changes color state occurs at a pre-determined temperature so that the camouflage pattern reveal the color states and the characteristics of the foliage of the season to which the temperature corresponds. | ||||||
| 229 | Product with embossments having a decreasing line weight | US11957055 | 2007-12-14 | US08470431B2 | 2013-06-25 | Lee D. Wilhelm |
| Embossed sheet materials are disclosed. In accordance with the present disclosure, the embossing pattern includes at least one line element that has a gradually decreasing depth. The gradually decreasing depth has been found to alter the shadow characteristics of the embossing pattern thus creating a line in the embossing pattern that appears to decrease in line weight. The decrease in line weight is accomplished without having to change the width of the embossment, although the width can also be changed in conjunction with the depth. Being able to incorporate line weight variations into embossing patterns can dramatically improve the aesthetic appeal of the patterns. | ||||||
| 230 | Air-permeable composite fabric | US12113595 | 2008-05-01 | US08454784B2 | 2013-06-04 | Thomas C. Colasanto; Mark Shanley |
| An air-permeable composite fabric is provided. The composite fabric has an inner fabric layer, an outer fabric layer, and an intermediate vapor barrier. The vapor barrier is selected from adhesive material and an adhesive/membrane combination designed so the composite fabric has a level of air permeability to allow air flow between the first fabric layer and the second fabric layer and a variable level of water vapor diffusion resistance that decreases as air speed impinging on the composite fabric increases. | ||||||
| 231 | Polymeric shell adherently supported by a liner and a method of manufacture | US13099589 | 2011-05-03 | US08367168B2 | 2013-02-05 | Michael Flather; Paul Saunders; Dave Narasimhan |
| An article comprising at least one cured, liquid-impervious polymeric shell substantially free from defects, at least one liner, and a non-tacky, thermoplastic adhesive layer between the shell and the liner, wherein the adhesive layer is melted and solidified to create a non-tacky bond between the shell and the liner, which can be moisture-absorbing or cut-resistant, whereby the liner supports and limits stretch ability of the shell, thereby preventing adhesive delamination between the adhesive layer and either of the shell and/or the liner; a method for the manufacture of an article comprising a supported, polymeric shell, such as a glove, a gauntlet, an apron, or a boot, comprising providing a cured, liquid-impervious, polymeric shell, providing a knitted/woven liner, incorporating a non-tacky, thermoplastic adhesive layer between the shell and the liner, such as by hot-melt spraying, dry-powder spraying or fiber-coating, creating intimate contact between the shell, the adhesive layer, and the liner, subjecting the shell, the adhesive layer, and the liner to infrared radiation to melt the adhesive layer and create a bond between the shell and the liner, and cooling the shell; as well as other methods. | ||||||
| 232 | Composite filter media | US12102434 | 2008-04-14 | US08343251B2 | 2013-01-01 | Thaddeus J. Ptak; Russell Baldinger |
| A composite filter media having excellent dust-releasing properties provided with a layer of netting formed of a low surface free energy material that is hot calendered to the upstream surface of a supporting layer formed of non-woven synthetic fibers. A filtering layer formed of non-woven synthetic fibers is laminated to the downstream surface of the supporting layer. The filtering layer may include an electrostatic charge to increase filter efficiency at a reduced pressure drop across the composite media. | ||||||
| 233 | Multi-layer flame retardant fabric | US11757031 | 2007-06-01 | US08298645B2 | 2012-10-30 | Moshe Rock; Jane Hunter; David Costello; Gadalia Vainer |
| A composite velour fabric garment includes a laminate consisting of an outer woven shell layer, an inner thermal layer of knit construction, and an intermediate layer disposed between and laminated to each of the shell layer and the thermal layer. The outer woven shell layer contains spandex in at least a weft direction for stretch and recovery in a width direction. The knit construction of the inner thermal layer provides stretch in at least a width direction, in harmony with the shell layer, and the inner thermal layer has a raised surface facing inwardly, away from the shell layer. The raised surface includes a plurality of discrete pillar regions of sinker loop yarn arranged in a grid or box pattern and configured to form a plurality of intersecting channels between a wearer's body and the inner thermal layer. The intermediate layer has controlled air permeability, including zero air permeability. One or more of the outer, inner, and intermediate layers include flame retardant material. | ||||||
| 234 | Shoulder strap and method for manufacturing the same | US11839273 | 2007-08-15 | US08226453B2 | 2012-07-24 | Wai Ching Andy Lau |
| A shoulder strap includes a first stretch fabric and a second stretch fabric, and a first rigid fabric sandwiched between the first stretch fabric and a second stretch fabric and adhered to the first stretch fabric. The rigid fabric is located at an intermediate position between opposite ends of the first stretch fabric and the second stretch fabric. | ||||||
| 235 | Laminated panel and process | US12974161 | 2010-12-21 | US08206534B2 | 2012-06-26 | Rodrigue McDuff; Stephen Murphy; Luc Vachon; Philippe Koyess |
| A laminated panel (23) comprises a fusible layer (23A) having an upper surface. A mesh layer (23A, A1) has an encapsulated portion enclosed in the fusible layer so as to be below the upper surface of the fusible layer (23A). An embossed portion (A1) protrudes from the upper surface of the fusible layer (23A). A method (10) of forming a laminated panel with the fusible layer and the mesh layer comprises the steps of: i) heating the fusible layer (23A) to fuse a portion of the fusible layer; and ii) pressing only selected portion of the mesh layer against the fusible layer to provide for the formation of an embossed pattern (A1) on the resulting laminated panel (10). | ||||||
| 236 | MULTI-FUNCTIONAL BODY ARMOR | US13322292 | 2011-03-23 | US20120060681A1 | 2012-03-15 | Eric C. Hoenes |
| A flexible, multi-functional, multi-ply material mix and device, capable of providing ballistic protection are herein presented. The device and material herein presented provide multiple electronic and ballistic functionality integrated into a soft body armor that is lighter in weight and more comfortable to wear than previously available alternatives. | ||||||
| 237 | VAPOR PERMEABLE FABRIC CONSTRUCTS | US12875870 | 2010-09-03 | US20120058294A1 | 2012-03-08 | Gregory L. Todt; Seckin Ozol; Rajesh Hemendra Shah |
| This invention relates to protective, multi-layered, breathable fabric constructs. The constructs which are flexible employ a fabric layer and a breathable coating layer applied to the fabric. Under certain preferred embodiments, the fabric constructs also employ an energy dissipating fiber material disposed opposite the coating layer. Also, the present invention teaches a method of protecting a valuable or sensitive object from damage caused by corrosion, weather, bio mass, or other environmental related conditions using the fabric material. The fabric constructs may be post-formed using heat or other methods to create shaped-to-form covers. | ||||||
| 238 | Method for manufacturing a particularly soft and three-dimensional nonwoven and nonwoven thus obtained | US11658655 | 2004-07-29 | US07968025B2 | 2011-06-28 | Roberto Pedoja |
| The present invention relates to a method for manufacturing nonwoven and nonwoven obtainable by said method. Particularly, the invention relates to a nonwoven provided with improved tactile and absorbent characteristics, which make it suitable for use in the field of surface cleaning, personal hygiene, or formation of garments. | ||||||
| 239 | STRETCHED ELASTIC NONWOVENS | US11659298 | 2005-08-03 | US20110143623A1 | 2011-06-16 | Jean Claude Abed; Henning Roettger; Steven P. Webb; Jared A. Austin |
| A method for producing an elastic nonwoven fabric, comprising: stretching a nonwoven web in the cross machine direction, machine direction, or both directions to reduce the basis weight and/or denier of the nonwoven web to form the elastic nonwoven fabric, wherein the nonwoven web comprises a plurality of multicomponent strands having first and second polymer components longitudinally coextensive along the length of the strands, said first component comprising an elastomeric polymer, and said second polymer component comprising a polymer less elastic than the first polymer component. | ||||||
| 240 | Method of Manufacturing a Polypropylene Pinch Bag | US12809953 | 2008-12-19 | US20110082019A1 | 2011-04-07 | Roger Bannister |
| A method of manufacturing a gusseted pinch bag from polypropylene. A sheet or seamless tube of polypropylene is provided. The sheet is preferably comprised of one or more layers of axially and/or biaxially oriented polypropylene. Perforation lines in a pinch pattern are formed in the sheet or tube. Preferably a laser forms a series of small, closely spaced holes in the sheet along the perforation line. The laser heats the plastic surrounding the holes, causing the polypropylene molecules between the holes to lose their orientation. Thus, the polypropylene in the perforation line between the holes is substantially weakened. If a sheet is used, it is folded into a gusseted tube and the edges are sealed together to make a tube. If a seamless tube is used, the tube is gusseted. In either case, a lateral force is then applied to the terminal tube, breaking the perforation line and separating the terminal tube from the sheet. The bottom end of the tube is then sealed, thereby forming a bag. | ||||||
QQ群二维码
意见反馈
意见反馈