61 |
Method and apparatus for sandwiching corrugated core between skin layers |
US3461013D |
1963-12-11 |
US3461013A |
1969-08-12 |
GEWISS LUCIEN VICTOR |
|
62 |
Corrugated bodies and method of forming same |
US57396366 |
1966-08-22 |
US3410473A |
1968-11-12 |
PETRIE ROBERT M |
|
63 |
Method and apparatus for bundling corrugated cardboard blanks |
US43250854 |
1954-05-26 |
US2771935A |
1956-11-27 |
LUDWIG CLEMENS |
|
64 |
Machine for forming structural material |
US31283052 |
1952-10-02 |
US2769481A |
1956-11-06 |
MEANOR DOYLE W; HAVENS GLENN G |
|
65 |
Formed from a paper product structure |
JP2007535926 |
2005-10-21 |
JP4870083B2 |
2012-02-08 |
幸子 岩崎 |
|
66 |
Sheet material corrugation equipment |
JP2005511701 |
2003-12-11 |
JP4589870B2 |
2010-12-01 |
アキシェフ,ニアツ,イレコヴィッチ; ザキロフ,イルダス,ムハメトガレーヴィッチ; ニキティン,アレクサンダー,ブラディミロヴィッチ |
|
67 |
Thermoplastic honeycomb body of the half-closed, its manufacturing process and manufacturing equipment |
JP2007541587 |
2005-11-21 |
JP4368399B2 |
2009-11-18 |
フェアペスト,イグナス; プフルーク,ヨヘン |
|
68 |
Thermoplastic honeycomb body of the half-closed, its manufacturing process and manufacturing equipment |
JP2007541587 |
2005-11-21 |
JP2008520456A |
2008-06-19 |
フェアペスト,イグナス; プフルーク,ヨヘン |
半閉型の熱可塑性の折り畳まれたハニカム構造が説明される。 これは、材料の平面に対して垂直に塑性変形されることにより連続的なウェブ基材から製造され、その際半六角形のセル壁と小さい接続領域が形成される。 伝達方向に折り畳むことにより、ハニカム構造を形成するようにセル壁が合わせられる。 |
69 |
Method of manufacturing a curve bent structure |
JP2005510786 |
2003-11-20 |
JP2007521152A |
2007-08-02 |
アキシェフ,ニアツ,イレコヴィッチ; ザキロフ,イルダス,ムハメトガレーヴィッチ; ニキティン,アレクサンダー,ブラディミロヴィッチ |
本発明は最も一般的な態様において、薄板材コルゲーションの方法として定義されることが可能であり、かつ旅客機の曲線サンドイッチパネルの曲線折曲構造体光コルゲートコア製造に使用されることが可能である。 かかる技術的能力を広げることを目的として、コルゲートブランクはその側面から稜部の結合部に圧縮され、曲線折曲構造体デザインパラメータにより画定される曲径を側方部に提供する。 さらに、かかる状況で固定されて、ブロックは内部応力を緩和するために製品材料において熱的に処理され、所与の曲線折曲構造体に引き伸ばされる。
|
70 |
JPH0581831B2 - |
JP8696985 |
1985-04-22 |
JPH0581831B2 |
1993-11-16 |
KUMA TOSHIMI; OKANO HIROSHI |
|
71 |
Manufacture of corrugated fiberboard molding |
JP8666589 |
1989-04-05 |
JPH02265734A |
1990-10-30 |
SAKURABASHI RIYOUETSU; WATANABE MASAHIRO |
PURPOSE: To make it possible to prepare a corrugated fiberboard molding without occurrence of wrinkle and tear and where adhering of a skin material can be finished by means of one stroke method by forming slits and cutouts in advance on a linear of a fiberboard, fixing temporarily it by placing an adhesive on the remained part of the fiberboard, fixing temporarily a supplementary sheet to the linear by placing a thermofusible adhesive between them to form a fiberboard blank and heat-molding this blank.
CONSTITUTION: To manufacture a molding, a combination, so-called single-state fiberboard, wherein a core 1 and the first liner 2 are bound with a thermofusible adhesive 4 and the second liner 3 a surface of which is coated with a thermofusible adhesive 4 and which is separated with said combination are provided. Slits S and cutouts N are formed in advance on this second liner 3 and in addition a supplementary sheet 5 with an adhesive 4 is adjoined to the linear 3. These materials are combined together and temporarily fixed. This blank 8 is press-molded while it is heated between a fixed mold adjoining to the liner 2 and a movable mold adjoining to the supplementary sheet 5. In this molding, occurrence of wrinkle and tear is prevented by slits and cutouts.
COPYRIGHT: (C)1990,JPO&Japio |
72 |
Apparatus for making construction material |
JP6993378 |
1978-06-12 |
JPS5460375A |
1979-05-15 |
JIYON DERAITO; KURIFUOODO DAGURASU SHIERAA |
|
73 |
JPS5036444B1 - |
JP3053171 |
1971-05-10 |
JPS5036444B1 |
1975-11-25 |
|
|
74 |
THREE DIMENSIONAL AUXETIC STRUCTURE, MANUFACTURING METHOD AND TOOLING |
US15957289 |
2018-04-19 |
US20180312239A1 |
2018-11-01 |
Iker VÉLEZ DE MENDIZÁBAL ALONSO; Esteban MARTINO GONZÁLEZ; David APELLANIZ DE LA FUENTE; Alfonso PARRA RUBIO; Elena MOYA SANZ |
A three-dimensional auxetic structure, comprising a plurality of adjoining hollow cells, each hollow cell having cell walls and a transversal cross section of the plurality hollow cells following a two-dimensional auxetic pattern, each cell wall comprising folding lines parallel to a plane containing the auxetic pattern such that peaks and valleys are defined in the cell walls and the cell walls being foldable along the folding lines. |
75 |
Method and device for manufacturing ultralight cardboard structures having substantial mechanical stability |
US14354621 |
2012-10-29 |
US09322160B2 |
2016-04-26 |
Alfred Iseli |
A process of manufacturing a cardboard building construction material, said cardboard building construction material comprising a plurality of glued cardboard plies, wherein the cardboard plies are rolled on a drum (122) into a roll (114) and wherein glue (134) is circumferentially applied in spaced apart strips (238) thereby defining a non-glued region between the strips, in which region a cutter (246) cuts the cardboard plies from an outer diameter toward an inner diameter of the roll (114). |
76 |
FOLDED STRUCTURE, INTERCONNECTION OF ELEMENTS, SANDWICH PANEL, AS WELL AS FOLDING PROCESS AND FOLDING TOOL |
US14820576 |
2015-08-07 |
US20160039164A1 |
2016-02-11 |
Florian Tuczek |
A three dimensional folded structure, for use in lightweight design and lightweight construction, is folded at regular intervals and cannot be folded flat. The folded structure substantially extends in two directions and includes a small number of folded ply sheets. Each of the ply sheets is formed by an originally planar blank of an initially flat material lying in a zero plane and includes fold lines and polygonal holes disposed at regular distances. Each of the ply sheets is subdivided into a plurality of segments, each in the form of a polygonal planar entity that is, except at a border of the ply sheet, delimited by the fold lines and the border-edge-sections of a respective polygonal hole. Each ply sheet is folded up in two directions. During folding, the holes close into slits. Each slit of one ply-sheet is completely bridged by the other ply-sheet. |
77 |
Apparatus for fabrication of a structural member and related fabrication methods |
US14128580 |
2013-08-14 |
US09174768B2 |
2015-11-03 |
David Michael Love |
A fabrication machine is disclosed herein. In various aspects, the fabrication machine includes a brake adapted to mechanically cooperate with a wrapper to impart a longitudinal tension to the wrapper by controlling the force required to advance the wrapper, the wrapper comprised of a cellulose-based material. The brake is adjustable to allow selection of longitudinal tension in the wrapper, in various aspects. Various aspects may include a wrapper roll in mechanical cooperation with the brake, the wrapper being drawn from the wrapper roll as the wrapper is advanced. The fabrication machine secures the wrapper at the selected tension about the core to form a structural member, in various aspects. Methods of use of the fabrication machine are disclosed herein. This Abstract is presented to meet requirements of 37 C.F.R. §1.72(b) only. This Abstract is not intended to identify key elements of the apparatus and methods disclosed herein or to delineate the scope thereof. |
78 |
APPARATUS FOR FABRICATION OF A STRUCTURAL MEMBER AND RELATED FABRICATION METHODS |
US14128580 |
2013-08-14 |
US20150059182A1 |
2015-03-05 |
David Michael Love |
A fabrication machine is disclosed herein. In various aspects, the fabrication machine includes a brake adapted to mechanically cooperate with a wrapper to impart a longitudinal tension to the wrapper by controlling the force required to advance the wrapper, the wrapper comprised of a cellulose-based material. The brake is adjustable to allow selection of longitudinal tension in the wrapper, in various aspects. Various aspects may include a wrapper roll in mechanical cooperation with the brake, the wrapper being drawn from the wrapper roll as the wrapper is advanced. The fabrication machine secures the wrapper at the selected tension about the core to form a structural member, in various aspects. Methods of use of the fabrication machine are disclosed herein. This Abstract is presented to meet requirements of 37 C.F.R. §1.72(b) only. This Abstract is not intended to identify key elements of the apparatus and methods disclosed herein or to delineate the scope thereof. |
79 |
Pleated Paper and the Method of Manufacturing |
US12398335 |
2009-03-05 |
US20090233023A1 |
2009-09-17 |
David Goodrich |
A novel packaging wrap is used in cushioning a product for shipment and is formed from the combination of a layer of pleated sheet material, the pleated material being creased at the apices of each pleat, and a planar layer of sheet material which is adhered to, and preferably, adhesively bonded, to a pleated sheet of kraft paper. The pleated sheet material has a weight in the range from about 30 to 50 pounds and the planar sheet material is preferably tissue paper having a weight of less than about 20 pounds. The pleated sheet material preferably, has a pleat angle in the range from above 45 degrees to below 85 degrees, and most preferably the pleats have an angle of about 50 to 65 degrees. Preferably, the pleats have a height in the range from about 3 sixteenths of an inch to about one half inch, in terms of distance between top planar sheet and bottom planar sheet. |
80 |
METHOD FOR MAKING AN OBJECT FROM A PAPER PROJECT AND OBJECT FORMED |
US11577492 |
2005-10-21 |
US20090208711A1 |
2009-08-20 |
Sachiko Iwasaki |
A paper-constructed object usable to form a high strength structure is itself formed using a fiber-powder paper product. The fiber-powder paper product is formed from a biodegradable plastic base material and fiber-powder surface coating material. The fiber-powder surface coating material is applied to at least one surface of the biodegradable plastic base material. The paper-constructed object includes a top sheet, a middle sheet and a bottom sheet of the fiber-powder paper. The middle sheet has a plurality of projections formed in it. The projections can be pyramidal, with a square base and side surfaces that are equilateral triangles. The plurality of equilateral 4-sided pyramidal projections are contiguous and extend between the top and bottom sheets. The four base edges of the equilateral 4-sided pyramidal projections are bonded to the bottom sheet and the tips of the equilateral 4-sided pyramidal projections are bonded to the top sheet. |