| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 21 | Exhaust connection member with braided cover | US14328330 | 2014-07-10 | US09157559B2 | 2015-10-13 | Robert F. Stalcup, II; Scott R. Swank |
| An exhaust connection coupler and a method for manufacturing a braid cover incorporated therein are provided. | ||||||
| 22 | REINFORCED GABION AND PROCESS FOR ITS MANUFACTURE | US14385914 | 2013-03-07 | US20150071708A1 | 2015-03-12 | Francesco Ferraiolo |
| A reinforced gabion comprising two adjacent walls with a common edge manufactured using a single sheet of double twisted metal mesh fabric formed from metal wires which have two different diameters respectively corresponding to the two walls. Preferably the metal mesh fabric has a mesh with at least one twisted side formed from at least two metal wires woven together in which each twisted side is aligned in the direction of the common edge between the two walls. | ||||||
| 23 | 3-dimensional lattice truss structure composed of helical wires and method for manufacturing the same | US13391719 | 2010-08-25 | US08745958B2 | 2014-06-10 | Ki Ju Kang; Seung Chul Han; Jai Hwang Joo |
| Disclosed are three-dimensional porous light-weight structures composed of helical wires and the manufacturing method of the same. Continuous helical wire groups in three or six directions having a designated angle (for example, 60 degrees or 90 degrees) with respect to one another in a space cross and are then assembled, and thus new truss-shaped three-dimensional lattice truss structures having high strength and stiffness to weight ratio and a large surface area and method of mass-producing the structures at low costs are provided. The three-dimensional porous light-weight structures are manufactured by a method in which helical wires are three-dimensionally assembled through a continuous process rather than a method in which net-shaped wires are simply woven and stacked, and thus have a configuration similar to the ideal hexahedron truss, Octet truss, or truss in which regular octahedrons and cuboctahedrons are combined, thereby having excellent mechanical properties or thermal or aerodynamic properties. | ||||||
| 24 | Exhaust connection member with preformed braided cover | US12942684 | 2010-11-09 | US08382165B2 | 2013-02-26 | Robert Franklin Stalcup, II; Scott Robert Swank |
| An exhaust connection coupler and a method for manufacturing a braid cover incorporated therein are provided. The coupler may include an inner flexible bellows member and an outer braid cover surrounding the bellows member. The braid cover may be formed into a predetermined shape prior to assembly with the coupler. The braid member can include a generally cylindrical body section and two end sections each forming necks having diameters that are smaller than the diameter of the body section. The body section of the braid cover is self-supporting and is positioned an appreciable distance from the bellows member in order to avoid any friction and to create a thermally insulating air gap therebetween. The braid cover may be constructed of braided wire filaments that are formed into shape with forming dies. The braid cover may be pressed between two forming dies in order to create its desired shape. | ||||||
| 25 | EXHAUST CONNECTION MEMBER WITH PREFORMED BRAIDED COVER | US12942684 | 2010-11-09 | US20120112453A1 | 2012-05-10 | Robert Franklin STALCUP, II; Scott Robert Swank |
| An exhaust connection coupler and a method for manufacturing a braid cover incorporated therein are provided. The coupler may include an inner flexible bellows member and an outer braid cover surrounding the bellows member. The braid cover may be formed into a predetermined shape prior to assembly with the coupler. The braid member can include a generally cylindrical body section and two end sections each forming necks having diameters that are smaller than the diameter of the body section. The body section of the braid cover is self-supporting and is positioned an appreciable distance from the bellows member in order to avoid any friction and to create a thermally insulating air gap therebetween. The braid cover may be constructed of braided wire filaments that are formed into shape with forming dies. The braid cover may be pressed between two forming dies in order to create its desired shape. | ||||||
| 26 | TRUSS TYPE PERIODIC CELLULAR MATERIALS HAVING INTERNAL CELLS, SOME OF WHICH ARE FILLED WITH SOLID MATERIALS | US13003947 | 2008-09-24 | US20110117315A1 | 2011-05-19 | Ki Ju Kang; Jun Hyung Byun |
| Provided are three-dimensional truss type periodic cellular materials, wherein a plurality of internal cells are formed periodically and part of the internal cells are filled with solid material like as metal, ceramic, synthetic resin, or composite materials for the purpose of preventing buckling of the truss elements when external compressive or shear loads is applied to the truss structure. By filling only parts of internal cells provided in the truss with appropriate solid materials, the buckling of truss elements can be suppressed maximally and effectively, and even if the buckling accidentally occurs, the sharp decline of strength can be prevented so as to ensure sufficient structural stability of the truss type periodic cellular materials. | ||||||
| 27 | Information technology process for prefabricated building panel assembly | US11707765 | 2007-02-16 | US07894920B2 | 2011-02-22 | Vincent D. Mifsud; Giuseppe Corrado Aprile; Michael J. Churchill; Michele Tancredi |
| The disclosed technology enables manufacturers to efficiently design and manufacture structural wall panels, floor panels and roof panels from cold-formed steel for use in residential and commercial construction. The panels are individual components that can be installed at a building site to form a structure that includes walls, floor and a roof. Structures may be manufactured in a manufacturing facility and delivered to a construction site for installation. | ||||||
| 28 | METHOD FOR MANUFACTURING A THREE DIMENSIONAL FRAME STRUCTURE FOR USE AS A CORE STRUCTURE IN A SANDWICH CONSTRUCTION | US12197037 | 2008-08-22 | US20090049693A1 | 2009-02-26 | Hans-Jurgen Weber; Gregor Christian Endres |
| A method is provided for manufacturing a three dimensional frame structure that can be used as a core structure in a sandwich construction. Furthermore, a frame structure is provided for a sandwich construction, which frame structure has been manufactured in accordance with the method. In the method, a two dimensional lattice structure is made from bar-shaped linear semi finished products, in which structure the semi finished products intersect at defined points of intersection; the bar-shaped linear semi finished products are connected at the points of intersection and are softened by locally applying heat to the lattice structure in each case along three non-intersecting (imaginary) straight lines. In order to impart a three dimensional shape to the lattice structure a force (F) is introduced into the lattice structure along the middle one of the (imaginary) straight lines to which heat has been applied, wherein, as a result of deformation of the lattice structure, the introduced force F is deflected into pairs of tensile forces acting in the semi finished products, as a result of which the lattice structure is pulled into a third dimension, along the middle (imaginary) straight line to which heat has been applied. | ||||||
| 29 | Manufacturing method for a prefabricated building panel | US11707561 | 2007-02-16 | US20070271870A1 | 2007-11-29 | Vincent Mifsud; Giuseppe Aprile; Michael Churchill; Michele Tancredi |
| The disclosed technology enables manufacturers to efficiently design and manufacture structural wall panels, floor panels and roof panels from cold-formed steel for use in residential and commercial construction. The panels are individual components that can be installed at a building site to form a structure that includes walls, floor and a roof. Structures may be manufactured in a manufacturing facility and delivered to a construction site for installation. | ||||||
| 30 | Component manufacturing system for a prefabricated building panel | US11707646 | 2007-02-16 | US20070260345A1 | 2007-11-08 | Vincent Mifsud; Giuseppe Aprile; Michael Churchill; Michele Tancredi |
| The disclosed technology enables manufacturers to efficiently design and manufacture structural wall panels, floor panels and roof panels from cold-formed steel for use in residential and commercial construction. The panels are individual components that can be installed at a building site to form a structure that includes walls, floor and a roof. Structures may be manufactured in a manufacturing facility and delivered to a construction site for installation. | ||||||
| 31 | Method and plant for continuously producing construction | US09807106 | 1999-10-05 | US06915572B1 | 2005-07-12 | Gerhard Ritter |
| Method and apparatus for the continuous manufacture of structural members, in which two parallel, flat wire mesh mats comprising longitudinal and transverse wires intersecting with each other and welded together at the points of intersection are advanced on a production line and between the wire mesh mats is introduced an insulating body, whereupon the straight link wires are passed through the insulating body and with their ends welded to the wire mesh mats, so that the latter are held a predetermined distance apart, wherein first an endless, coherent web of insulating material is produced from individual insulating panels and advanced and then the insulating body is cut off this web of insulating material in a selectable length. | ||||||
| 32 | Lattice block material | US664687 | 1996-06-17 | US5679467A | 1997-10-21 | Jonathan Priluck |
| Disclosed is a structural material having a lattice configuration. In one embodiment of the invention, the structural material is manufactured by weaving a continuous wire filament on a loom assembly. In an alternative embodiment of the invention, the structural material is formed using substrate sheets that are machined or molded into a desired configuration. The structural material of the invention can be used alone or layered to form a multi-laminate material. | ||||||
| 33 | Wire insertion apparatus | US436241 | 1995-05-17 | US5598617A | 1997-02-04 | Klaus Ritter; Gerhard Ritter |
| An apparatus for inserting wire into an intermittently fed insulating body (I) of a structural element (B), with a wire supply device (6, 7) disposed on a pivotable base plate (1) and with a device (15, 16, 21) for forming and shaping a wire receiving duct, wherein, in the feed direction of the structural element, the forming and shaping device is disposed in front of the wire supply device as well as at the same angle as it and on the same side of the insulating body and is fixedly connected with the wire supply device, can be moved together with it in the direction toward the insulating body of the structural element and away from it and is pivotable together with it. | ||||||
| 34 | Lattice block material | US312224 | 1994-09-26 | US5527590A | 1996-06-18 | Jonathan Priluck |
| Disclosed is a structural material having a wire lattice configuration. The structural material can manufactured by first weaving a continuous wire filament on a loom assembly. Once woven into arrays of parallel wires, the filament is fixed in position and cut into segments. The segments are then placed in a rig. The rig positions the segments at relative angles so as to form a matrix or mesh. In the final step of the manufacturing process, the wires are welded together using, for example, a forge press. Alternatively, the material can be formed by first holding wire segments in a pair of rigs and then sequentially welding the wire segments together. The structural material of the invention can be used alone or layered to form a multilaminate material. | ||||||
| 35 | Machine for manufacturing construction panels | US682576 | 1991-04-08 | US5102027A | 1992-04-07 | An Se Hong |
| A machine manufactures construction panels which include a plate-shaped heat insulating core, upper and lower wires located closely at opposite sides of the heat insulating core, first and second supporting members inserted in the heat insulating core and the upper and lower wire meshes in an inclined manner opposite to one another and welded to the upper and lower wire meshes. The machine has an intermittently driven conveyor unit, a plurality of spacer angles for stacking the plate-shaped heat insulating core and the upper and lower wire meshes with certain gaps therebetween to form a panel pre-assembly to be mounted on the conveyor unit, a plurality of quick-moving and inserting sections for the first and second supporting members disposed in an inclined manner and opposite to one another. The quick-moving and inserting sections include a plurality of quick-moving units provided with a unit for accommodating and discharging one by one the first and second supporting members which are cut in advance, and a plurality of inserting units with tubes provided with a hole having a diameter slightly larger than a diameter of the first and second supporting members. | ||||||
| 36 | Apparatus for manufacturing building panels | US241725 | 1988-09-08 | US4917284A | 1990-04-17 | Angelo Candiracci |
| The apparatus, for manufacturing building panels for construction walls with antiseismic and thermoacoustic insulation characteristics, includes a horizontal table for assembling a panel formed by at least one layer of insulating material and by a pair of metal grids associated with the opposite faces of said insulating layer, means for advancing said panel step by step to a station for inserting, cutting and welding connecting elements of said metal grids. The inserting and welding station includes means adapted to insert the connecting elements transversely to the insulating layer, lower welding means adapted to weld the connecting elements, which pass through the insulating layer, to the lower metal grid of the panel, means for cutting the connecting elements at the upper metal grid of the panel, and upper welding means adapted to weld the cut connecting elements to the upper metal grid of the panel. | ||||||
| 37 | Method for assembling three-dimensional metal structures, machine for the manufacturing thereof, and structures obtained with such a method | US22865 | 1987-03-06 | US4838322A | 1989-06-13 | Andre DeSchutter; Casalatina Silvano |
| A method and apparatus for assembling three-dimensional wire structures. The method includes the steps of preparing a series of plane nettings comprising lengthwise wires and brace wires, and aligning the nettings on holders. The method further includes the steps of placing a pair of cross wires across and against the lengthwise wires of the netting and welding the cross wires to the nettings. These last two steps are repeated, each time with the netting in a different position. | ||||||
| 38 | Method for assembling three-dimensional metal structures, machine for the manufacturing thereof, and structures obtained with such a method | US725655 | 1985-04-22 | US4667707A | 1987-05-26 | Andr/e/ De Schutter; Silvano Casalatina |
| A method and apparatus for assembling three-dimensional wire structures. The method includes the steps of preparing a series of plane nettings comprising lengthwise wires and brace wires, and aligning the nettings on holders. The method further includes the steps of placing a pair of cross wires across and against the lengthwise wires of the nettings and welding the cross wires to the nettings. These last two steps are repeated, each time with the nettings in a different position, until the three-dimensional structure is completed. | ||||||
| 39 | Method and apparatus for the production of welded grid bodies | US372478 | 1982-04-28 | US4500763A | 1985-02-19 | Gerhard Schmidt; Klaus Ritter; Gerhard Ritter |
| Grid bodies which consist of two parallel plane grid mats of longitudinal and transverse wires crossing one another and welded together at the points of cross, and of spacer wires, which hold the mats spaced apart and which are welded at each end to one wire of one of the two grid mats, are produced in a continuous method and in such a way that if necessary an insulating core may be introduced into the grid body during its production. For this purpose two widths (3,4) of grid matting are drawn off in steps from stock coils (1,2), straightened and arranged at a distance apart. Simultaneously a number of wires (22,23) are drawn off in steps from stock coils (20,21), straightened and introduced through one (3) of the widths (3,4) of grid matting from the side into the gap between the widths of grid matting, welded to one wire in each width of grid and separated from the wire stock. | ||||||
| 40 | Modular building panel | US36553873 | 1973-05-31 | US3879908A | 1975-04-29 | WEISMANN VICTOR P |
| An improved prefabricated modular building panel includes a three-dimensional lattice fabricated of a plurality of rod-like slender elongated metal elements. The lattice elements are arranged to define a pair of substantially parallel spaced major lattice surfaces, and side and end lattice edge surfaces. A plurality of strut members traverse the interior of the lattice and interconnect the major surfaces to define a plurality of passages within the lattice. The passages are open at at least one end thereof to one of the lattice edge surfaces. Thermal insulating filler material is disposed within the lattice and extends from side to side and from end to end of the lattice. The filler material includes a plurality of insulative elements positioned in the passages through the passage open ends to be disposed wholly within the lattice. A bonding agent is used to secure the insulative elements in position within the lattice, and the bonding preferably is a layer of foam material applied over the insulative elements within the lattice to foam at least partially in situ and to bond to the insulative elements and to the metal elements of the lattice, particularly the lattice strut members.
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