子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 基于碳纤维纸的折叠芯以及由折叠芯制成的制品 | CN201080052771.5 | 2010-11-17 | CN102639787A | 2012-08-15 | M·R·莱维特; D·W·考卡 |
| 本发明涉及由包含20-85重量%的碳纤维絮状物的纸材制成的折叠芯结构。碳纤维具有至少1.5∶1的非圆形横截面长宽比。纸材具有至少35%的纤维体积分数。碳纤维的算术平均长度为至少0.5mm,并且长度加权平均长度为至少0.9mm。 | ||||||
| 2 | 可压缩结构天花板或墙壁板件 | CN200610051371.8 | 2001-04-23 | CN100379931C | 2008-04-09 | P·G·斯维斯茨; K·库佩鲁斯; W·B·科尔森; J·T·思龙 |
| 本发明涉及一种可压缩结构天花板或墙壁板件,包括:至少一个具有内表面和外表面的外材料层;多个可压缩的间隔物,被固定到所述内表面且从所述内表面突伸出;以及连接结构,用于将所述间隔物共同固定在远离所述外层的位置;其中每一个间隔物是纵向细长的并且包括纵向延伸的侧隔壁和纵向延伸的折叠线,从而,通过施加压力到外层或连接结构,使得所述间隔物沿所述折叠线折叠并被压缩以减小板件的厚度;以及每一个间隔物在常态时膨胀并且是有弹性的以便在被压缩后回复到这样的构造从而板件将在常态下呈现为其常规的膨胀形式;所述间隔物包括半刚性但可折叠材料的单独层;所述可折叠材料由玻璃纤维通过树脂粘合在一起制成从而每个所述折叠线是有弹性的并且包括一个不严重破坏所述纤维而形成的压痕。 | ||||||
| 3 | 用于制造多孔结构镶板的方法和装置 | CN200310122300.9 | 2003-12-03 | CN1513649A | 2004-07-21 | P·G·斯维斯茨克; K·库佩鲁斯; T·杰斯克; E·巴拉; S·库克 |
| 制造多孔层压结构镶板的装置,包括一个或多个柔性条状材料的供给台,包括用于将条状材料相继折叠成多孔结构并将该多孔结构供入一输送机的折叠辊,在这里多孔结构保持被压缩。该装置还包括一层压台,在该层压台上被折叠的多孔结构被层压至上部和/或下部片材上,多列粘合物质在其与多孔结构接合之前已经被应用于这些板材上。被折叠的多孔结构在与板材接合之前被加热以增强板材与多孔结构之间的粘结以及随后的粘结,层压板通过一冷却台以使该粘合介质固化。从层压台下游,层压板经过一侧边折叠台,在该折叠台上,板材边缘在层压板边缘上方被折叠以精加工层压板的侧边,随后层压板被送入一切削工具中,将连续的层压板裁切成预定的长度。裁切镶板端部,接收刚性边缘条完全精加工镶板。本发明的方法是通过所述装置的部件来实行的步骤。 | ||||||
| 4 | 可压缩结构板 | CN200610100181.0 | 2001-04-23 | CN1924245A | 2007-03-07 | P·G·斯维斯茨; K·库佩鲁斯; W·B·科尔森; J·T·思龙 |
| 一种用在建筑结构中、或用于对建筑结构进行建造、装修或装饰的结构板(50),其包括一外层(54)和一连接层(56),在这两层之间有多个可塌陷或可压缩的间隔物(52)。板件在常态下是膨胀的,并具有所需的最终使用厚度,但为便于运输,板件还可被压缩成较薄的厚度和形状。板件的重量非常轻,但结构很强,且如果需要的话,可沿一个横向方向对其有选择地进行弯曲。板件易于被切割成预定的尺寸或形状。 | ||||||
| 5 | 层压材料的弯曲加工方法和层压材料 | CN00802666.1 | 2000-02-07 | CN1163348C | 2004-08-25 | 冈田智仙; 善崎清志 |
| 一种层压材料,厚度较大,并具有小半径曲面,其中,作为原材料提供层压材料(170),在该层压材料(170)中,面板(181、182)固定到芯材(183)的两个表面,在圆弧内侧的面板(181)未固定到芯材(183),层压材料(170)的一个端侧固定到支架(30、40),面板(181)的另一端沿离开芯材(183)的方向移动,从而将其弯曲成圆弧状,另一端不固定到芯材(183)。 | ||||||
| 6 | 可压缩结构板 | CN01811699.X | 2001-04-23 | CN1439074A | 2003-08-27 | P·G·斯维斯茨; K·库佩鲁斯; W·B·科尔森; J·T·思龙 |
| 一种用在建筑结构中、或用于对建筑结构进行建造、装修或装饰的结构板(50),其包括一外层(54)和一连接层(56),在这两层之间有多个可塌陷或可压缩的间隔物(52)。板件在常态下是膨胀的,并具有所需的最终使用厚度,但为便于运榆,板件还可被压缩成较薄的厚度和形状。板件的重量非常轻,但结构很强,且如果需要的话,可沿一个横向方向对其有选择地进行弯曲。板件易于被切割成预定的尺寸或形状。 | ||||||
| 7 | 三明治式构件及其制造方法 | CN201480032931.8 | 2014-06-04 | CN105283611A | 2016-01-27 | 弗莱迪.伊塞利 |
| 本发明涉及一种三明治式构件,尤其壁件,其包括至少一个具有大量并排布置的通道的纤维蜂窝状核,所述纤维蜂窝状核容纳在第一和第二覆盖层之间。按照本发明规定,所述第一和/或第二覆盖层设计为混凝土覆盖层、尤其由高性能混凝土构成,或者设计为石膏覆盖层。 | ||||||
| 8 | 可压缩结构板 | CN200610051371.8 | 2001-04-23 | CN1800558A | 2006-07-12 | P·G·斯维斯茨; K·库佩鲁斯; W·B·科尔森; J·T·思龙 |
| 一种用在建筑结构中、或用于对建筑结构进行建造、装修或装饰的结构板(50),其包括一外层(54)和一连接层(56),在这两层之间有多个可塌陷或可压缩的间隔物(52)。板件在常态下是膨胀的,并具有所需的最终使用厚度,但为便于运输,板件还可被压缩成较薄的厚度和形状。板件的重量非常轻,但结构很强,且如果需要的话,可沿一个横向方向对其有选择地进行弯曲。板件易于被切割成预定的尺寸或形状。 | ||||||
| 9 | 可压缩结构板 | CN01811699.X | 2001-04-23 | CN1246553C | 2006-03-22 | P·G·斯维斯茨; K·库佩鲁斯; W·B·科尔森; J·T·思龙 |
| 一种用在建筑结构中、或用于对建筑结构进行建造、装修或装饰的结构板(50),其包括一外层(54)和一连接层(56),在这两层之间有多个可塌陷或可压缩的间隔物(52)。板件在常态下是膨胀的,并具有所需的最终使用厚度,但为便于运输,板件还可被压缩成较薄的厚度和形状。板件的重量非常轻,但结构很强,且如果需要的话,可沿一个横向方向对其有选择地进行弯曲。板件易于被切割成预定的尺寸或形状。 | ||||||
| 10 | 层压材料的弯曲加工方法和层压材料 | CN00802666.1 | 2000-02-07 | CN1336870A | 2002-02-20 | 冈田智仙; 善崎清志 |
| 一种层压材料,厚度较大,并具有小半径曲面,其中,作为原材料提供层压材料(170),在该层压材料(170)中,面板(181、182)固定到芯材(183)的两个表面,在圆弧内侧的面板(181)未固定到芯材(183),层压材料(170)的一个端侧固定到支架(30、40),面板(181)的另一端沿离开芯材(183)的方向移动,从而将其弯曲成圆弧状,另一端不固定到芯材(183)。 | ||||||
| 11 | Method and device for manufacturing panel of cellular structure | JP2003405125 | 2003-12-03 | JP2004181966A | 2004-07-02 | SWISZCZ PAUL G; KUPERUS KO; JESKE TIMOTHY; BALLARD EUGENE; COOK STEPHEN |
| <P>PROBLEM TO BE SOLVED: To provide a manufacturing device and a manufacturing method for a panel of cellular laminate structure. <P>SOLUTION: The device is composed of a feeding section to fold up a flexible strip material into a cellular structure sequentially and feed the cellular structure to a conveyor capable of holding it compressed; a laminating station to laminate the folded cellular structure to an upper and/or lower sheet materials on which a gluing vehicle is applied before abutting the cellular structure; a heating station to heat the gluing vehicle; a cooling station to cool after lamination; a side part forming station 80 to fold up the sheet material on the side of the panel; and a cutting station 82 to cut the cellular laminate thus formed. <P>COPYRIGHT: (C)2004,JPO&NCIPI | ||||||
| 12 | Method for bending processing of laminated material and laminated material | JP3376899 | 1999-02-12 | JP2000229352A | 2000-08-22 | OKADA TOMONORI; YOSHIZAKI KIYOSHI |
| PROBLEM TO BE SOLVED: To provide a laminated material relatively thick and having a curved surface with a small radius. SOLUTION: A laminated material 170 wherein surface plates 181, 182 are fixed to both surfaces of a core material 183 and the surface plate 181 becoming the inside of a circular arc is not fixed to the core material 183 is prepared as a material. In such a state that one end of this laminated material 170 is fixed on stands 30, 40, the other end of the surface plate 181 is moved in the direction separated from the core material 183 to be bent into a circular arc shape and, next, an adhesive is applied to either one of the contact surface of the surface plate 181 on the other end side thereof and the core material 183 and the core material 183 and the other end of the surface plate 182 are moved along the bent surface plate 181 to be bent. | ||||||
| 13 | Folding cores and articles made therefrom based on carbon fiber paper | JP2012540002 | 2010-11-17 | JP2013511629A | 2013-04-04 | ミハイル アール レヴィット; ダリウス ヴロジミェシュ カウカ |
| 本発明は、20〜85重量%の炭素繊維フロックを含む紙から製造される折りたたみコアに関する。 炭素繊維は、少なくとも1.5:1の非円形断面アスペクト比を有する。 紙は、少なくとも35%の繊維体積分率を有する。 炭素繊維の算術平均繊維長は少なくとも0.5mmであり、また長さ加重平均繊維長は少なくとも0.9mmである。 | ||||||
| 14 | Compressible structure panel | JP2001578746 | 2001-04-23 | JP2003531325A | 2003-10-21 | クペラス,コ; コルソン,ウェンデル・ビー; スウィスヅクツ,ポール・ジー; スロン,ジェイソン・ティー |
| A structural panel for use in building structures or in the formation, finish or decoration thereof includes an outer sheet and a connector sheet with a plurality of collapsible or compressible dividers therebetween. The panel in a rest condition is expanded and of a desired thickness for final use but can be compressed into a relatively thin thickness or profile for shipping purposes. The panel is very lightweight but structurally strong and can be selectively bent in one transverse direction if desired. The panel can be easily cut or formed into any predetermined size or shape. | ||||||
| 15 | METHOD AND APPARATUS FOR FABRICATING CELLULAR STRUCTURAL PANELS | US11557746 | 2006-11-08 | US20070144092A1 | 2007-06-28 | Paul Swiszcz; Ko Kuperus; Tim Jeske; Eugene Ballard; Stephen Cook |
| An apparatus for manufacturing cellular laminate structural panels includes one or more supply stations of a flexible strip material including folding rollers for sequentially folding the strip material into cellular structures and feeding the cellular structures into a conveyor where the cellular structures are held in compression. The apparatus further includes a laminating station where the folded cellular structures are laminated to an upper and/or lower sheet material to which lines of a bonding medium have been applied prior to engagement with the cellular structures. The folded cellular structures are heated before engaging the sheet material so as to enhance the bonding of the sheet material to the cellular structures and subsequent to bonding, the laminate is passed through a cooling station to set the bonding medium. Downstream from the laminating station, the laminate passes through a side edge folding station where edges of the sheet material are folded over side edges of the laminate to finish the side edges of the laminate and subsequently the laminate is passed into a cutter for cutting the continuous laminate into predetermined lengths. Ends of the cut panels then receive rigid edge strips to fully finish the panel. The method of the invention includes the steps performed by the components of the apparatus. | ||||||
| 16 | Pearlescent honeycomb material and method for fabricating same | US10393888 | 2003-03-21 | US06854388B2 | 2005-02-15 | Karen S. Herhold; Leo Warner |
| A pearlescent honeycomb material and an apparatus and method for making expandable pearlescent honeycomb structures suitable for use as window coverings. In one embodiment, a pearlescent material is prepared and then folded into tubular strips. These folded tubular strips with adhesive lines applied to them are fed continuously through a cutter which cuts them into predetermined lengths. The cut strips are then accelerated to a stacker for further processing before the next cut strip arrives. In another embodiment, webs of material are fed continuously in a downstream direction, adhesive lines are applied, a middle web is slitted into strips, and the strips bonded along opposite edges to the outer webs. By choosing for the outer webs transparent or porous material, and for the middle web opaque material, a light or air controlling honeycomb structure results. | ||||||
| 17 | Pearlescent honeycomb material and method for fabricating same | US10393888 | 2003-03-21 | US20040045469A1 | 2004-03-11 | Karen S. Herhold; Leo Warner |
| A pearlescent honeycomb material and an apparatus and method for making expandable pearlescent honeycomb structures suitable for use as window coverings. In one embodiment, a pearlescent material is prepared and then folded into tubular strips. These folded tubular strips with adhesive lines applied to them are fed continuously through a cutter which cuts them into predetermined lengths. The cut strips are then accelerated to a stacker for further processing before the next cut strip arrives. In another embodiment, webs of material are fed continuously in a downstream direction, adhesive lines are applied, a middle web is slitted into strips, and the strips bonded along opposite edges to the outer webs. By choosing for the outer webs transparent or porous material, and for the middle web opaque material, a light or air controlling honeycomb structure results. | ||||||
| 18 | EXPANDABLE AND COLLAPSIBLE WINDOW COVERING AND METHODS FOR MAKING SAME | US08622070 | 1996-03-26 | US20030234070A1 | 2003-12-25 | JOHN D. RUPEL; DARRELL J. KUTCHMAREK; THOMAS W. TOLBERT |
| A method for producing an expandable and collapsible product for use in a window covering includes the steps of pleating a continuous length of material, bonding together opposing faces that face one side of the product to form a series of enclosed cells, bonding together opposed faces facing the other side of the product to form another series of enclosed cells, and removing creases from one side of the product to open one of the series of enclosed cells so that the other series of enclosed cells remains intact and connected to one another. The creases may be removed by abrading the material along the creases. The opposed faces may be bonded by applying a bead of adhesive to one of the faces and compressing the faces together. Also provided is a window covering having a multi-cellular expandable and collapsible body. The body has a number of strips of material that are creased in the center parallel to the long edges. The long edges are joined together to form a tab. Each of the strips of material define an elongated cell bounded by the creased fold on one side and the tab on the other. Successive cells are joined together by a bond line intermediate the creased folds and the tabs. A headrail is connected to the top of the body, and a bottom rail is connected to the bottom of the body. The body is provided with a means for raising and lowering the bottom rail with respect to the headrail. | ||||||
| 19 | Method for fabricating honeycomb material | US09902511 | 2001-07-09 | US20010045256A1 | 2001-11-29 | William Velte Goodhue |
| A process and apparatus for making expandable honeycomb structures suitable for use as window coverings. In one embodiment, folded tubular strips with adhesive lines are fed continuously through a cutter which cuts them into predetermined lengths. The cut strips are then accelerated to a stacker for further processing before the next cut strip arrives. In another embodiment, webs of material are fed continuously in a downstream direction, adhesive lines are applied, a middle web is slitted into strips, and the strips bonded along opposite edges to the outer webs. By choosing for the outer webs transparent or porous material, and for the middle web opaque material, a light or air controlling honeycomb structure results. | ||||||
| 20 | Process for fabricating honeycomb material | US92947392 | 1992-08-14 | US5228936B1 | 1996-06-11 | GOODHUE WILLIAM V |
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