81 |
Machine for making grille work. |
US1914812549 |
1914-01-16 |
US1139775A |
1915-05-18 |
KORLASKY FRANK A |
|
82 |
Means for giving a finished surface to wire-gauze. |
US1914867020 |
1914-10-16 |
US1138257A |
1915-05-04 |
STONIER FRANCIS |
|
83 |
Method of making a metallic structure. |
US1912698621 |
1912-05-20 |
US1063224A |
1913-06-03 |
SOMMER WILLIAM H |
|
84 |
Wire-bending machine. |
US1905292151 |
1905-12-18 |
US905917A |
1908-12-08 |
PERKINS WILLIAM A |
|
85 |
Spacing apparatus for wire-fence machines. |
US1906336620 |
1906-09-28 |
US859126A |
1907-07-02 |
SHOWALTER REUBEN S |
|
86 |
Tool for attaching stays to wire fences. |
US1899706954 |
1899-02-27 |
US640307A |
1900-01-02 |
JOHNSON WILLIAM H; FRY STEPHEN D |
|
87 |
Wire-fence spacer |
US614163D |
|
US614163A |
1898-11-15 |
|
|
88 |
Wire-fence machine |
US609456D |
|
US609456A |
1898-08-23 |
|
|
89 |
Mads mogenson |
US601041D |
|
US601041A |
1898-03-22 |
|
|
90 |
Spacing device for wire fences |
US561642D |
|
US561642A |
1896-06-09 |
|
|
91 |
Device foe |
US510933D |
|
US510933A |
1893-12-19 |
|
|
92 |
Setts |
US386761D |
|
US386761A |
1888-07-24 |
|
|
93 |
emerson |
US362577D |
|
US362577A |
1887-05-10 |
|
|
94 |
WIRE MESH RIVET |
US15582860 |
2017-05-01 |
US20170232500A1 |
2017-08-17 |
George Greenwood |
A wire mesh rivet (13) is provided which is used to produce a wire mesh isolator (11) in a bore (9) of a substrate such as a heat shield (7) for a vehicle exhaust system. The rivet (13) comprises a unitary wire mesh structure (19) which has a collar (15) and a shank (17). The collar (15) has a higher density than the shank (17), e.g., the collar (15) has the density of the finished isolator (11). The rivet (13) is formed into the finished isolator (11) by compressing the shank (17) to form a second collar, while restraining the original collar (15) from substantially changing its shape. The rivet (13) can include a metal insert (23) which prevents the wire mesh of the finished isolator (11) from experiencing high levels of compression when the substrate is fastened to its supporting structure. The rivets (13) can be carried by a dispensing strip (31) and can be formed into the finished isolator (11) using forming equipment (39) whose dimensions are compatible with the limited space available with some substrates. |
95 |
MACHINE FOR DEFORMING THE WIRES OF GRIDS FOR MAKING ELECTRIC ACCUMULATORS |
US13960817 |
2013-08-07 |
US20150040361A1 |
2015-02-12 |
Pietro Farina |
A machine for deforming the wires of grids for making electric accumulators, which comprises two lower moulds, and two upper moulds which are positioned above the lower moulds and which are operable to shift between a raised position, in which they are separated from the underlying lower moulds, and a lowered position in which they are pressed against the lower moulds to deform the wires of the grids on a grid strip. The upper moulds comprise respective projecting moulding areas and respective seats which are positioned between the moulding areas of the relative upper mould, and each housing a corresponding piece-detacher element which, when the upper moulds are in the raised position, is suitable to interfere with the grid remaining attached to the corresponding upper mould to separate the grid from such upper mould. |
96 |
Method and apparatus for creating stacks of nested sinuous springs |
US11969486 |
2008-01-04 |
US07954349B2 |
2011-06-07 |
Kelly M. Knewtson |
A method and apparatus is disclosed for simultaneously creating a pair of stacks of nested sinuous spring strips. This apparatus includes first and second generally circular forming drums onto which a feeder mechanism is operable to sequentially and alternately pass each of the spring strips from over a forming mandrel onto the top surface of the first and second generally circular forming drums. A first stripper mechanism is then operable to strip a first one of the strips onto a first stacking drum and for stripping a second following one of the strips onto a second stacking drum. A second stripper mechanism is then operable to strip those stacks from the stacking drums onto a pair of discharge chutes. |
97 |
Device for the automatic formation of packs of panels of electro-welded mesh and relative method |
US10520135 |
2003-07-14 |
US20050232746A1 |
2005-10-20 |
Ermanno Taboga |
Device and method for the automatic formation of packs of panels of electro-welded mesh. The device is arranged downstream of a production machine provided with a work plane. The device is provided with an expulsion element which arranges the panels emerging from the machine onto an accumulation plane located as an extension to the work plane of the machine, a turnover device which turns over every other panel with respect to the position in which it exits the machine, and a discharge device to discharge the panels. The device also comprises a switching device arranged downstream of the expulsion device in order to direct alternately, and substantially continuously, at least one panel either directly towards the accumulation plane or towards the turnover device. |
98 |
Nonwoven metal fabric and method of making same |
US10435451 |
2003-05-09 |
US20030203692A1 |
2003-10-30 |
Alexander
Krupnik; Terrence
P.
Kane; Kurt
H.
Schild |
A nonwoven, metal fabric is formed by providing a mass of loose fibers with sufficient lubricating oil for them to be carded without disintegration of the fiber web. The fiber web is then lapped and needled to form a metal fabric of superior strength, density, and thermal insulation properties. |
99 |
Method for producing microporous objects with fiber, wire or foil core and microporous cellular objects |
US09577176 |
2000-05-23 |
US06585151B1 |
2003-07-01 |
Amit K. Ghosh |
A method for producing microporous objects with fiber, wire or foil core with periodic welding of nodes by movement of the substrate and the making of a porous mat. Microporous objects are created by deposition of small dimension of solid from liquid streams undergoing solidification with the simultaneous welding of the streams at various nodal locations concurrently during the deposition process. Bulk porous material objects are created containing open spaces within the microstructure. Inserts can be added to create internal geometries. Variations in pore density from near-zero to about 95% with gradient densities can be created. Screens can be used for forming column-like supports within the microporous object. Holes can be punched in the fiber core to create desired properties of denser regions and to limit the thermal expansion of the mat in a single direction. The initial heat contact of the liquid metal is used to create the shape of the deposited segments as well as to remelt immediately deposited solid for in-situ welding. No additional heat source is employed to weld and create the network structure. |
100 |
Nonwoven metal fabric |
US09888871 |
2001-06-25 |
US06583074B1 |
2003-06-24 |
Alexander Krupnik; Terrence P. Kane; Kurt H. Schild |
A nonwoven, metal fabric is formed by providing a mass of loose fibers with sufficient lubricating oil for them to be carded without disintegration of the fiber web. The fiber web is then lapped and needled to form a metal fabric of superior strength, density, and thermal insulation properties. |