This disclosure relates in general to automatic cutting machines for flexible materials and, more particularly, relates to automatic cutting machines with a vacuum hold-down system using an overlay sheet for retaining the flexible materials on a cutting surface.
Fabricating flexible products from web material includes a number of steps and utilizes complicated machinery. First, the web material is spread on a spreading table by a spreading machine. The material is typically spread one layer at a time to form a stack or a layup having a certain width and height. The stack is then moved to a cutter table and held in place with a vacuum hold-down system. A conventional cutter table extends in a lateral or Y-axis direction and a longitudinal or X-axis direction and has a permeable bristle surface. A cutter head is typically movably attached to a cutter beam with the cutter beam being movable along the cutter table in the X-axis direction and with the cutter head being movable with respect to the cutter beam in the Y-axis direction.
Once the layup is moved to the cutter table, parts are cut by the cutter head according to the desired the shapes of the cut parts. The cut parts can have either the same or different shapes. However, the individual parts in each layer will have the same shape as the part in the layer above or below. After the material has been cut, the layup of material must be evacuated from the cutting machine. The cut parts are then sewn together into a finished product at a later time.
In the past, various arrangements have been provided for paying out one or more air-impermeable overlay sheets as the cutter moves in cutting relation to a layup, for example to cover holes or kerfs formed in the layup by the cutting operation. One such apparatus designed to minimize leakage and loss of vacuum through cut sheet material is shown in U.S. Pat. No. 3,742,802 to Maerz, assigned to the assignee of the present disclosure.
A problem associated with the transfer of material from the discharge end of a conveyor bed onto a take-off table surface is that the overlay sheet material, in particular a single limp ply of such material, often bunches up as it reaches the take-off table. This may require manual intervention to maintain a continuous workflow.
Accordingly, it is an object of the present disclosure to provide an apparatus for handling overlay sheet material on a cutting apparatus including a conveyor for moving work material in a longitudinal direction and a support for positioning a tensioner frame adjacent the conveyor. A tensioner frame, attached to the support, has a nip wheel and a drive for rotating the nip wheel with a tangential speed in excess of the longitudinal conveyor speed. The nip wheel engages the overlay sheet material applying a tension thereto in the same longitudinal direction as the conveyor.
In keeping with the foregoing object, a more specific object of the disclosure is to provide a drive that includes an electric motor operatively connected to the nip wheel.
Yet a further object of the present disclosure is to provide a drive that includes a drive wheel operatively connected to the nip wheel.
Other objects and advantages of the present disclosure will become apparent from the following disclosure and the appended claims.
Referring to
The cutter table 24 includes a frame 32 and extends in a lateral, or Y-coordinate, direction from a console side 34 to a remote side 36 and in a longitudinal, or X-coordinate, direction from a take-on end 40 to a take-off end 42. The cutter table includes a conveyor 44 with a permeable bristle surface 46 that advances the layup 14 in the X-coordinate direction.
A cutter beam 52 supports the cutter head 26 and is movable in the X-coordinate direction along a pair of guide rails 54 secured to the cutter frame 32. The cutter beam also supports the camera 30 mounted on the other side of the beam 52 to avoid interference with the cutter head 26. The cutter head 26, which cuts the layup 14, and the camera 30, which scans the upper ply 12, move in the lateral or Y-coordinate direction across the cutter beam 52. A cutter tool 56 is supported within the cutter head 26.
The cutting apparatus 20 also includes an operator control panel 62 formed substantially integrally with the beam 52 and including a plurality of function buttons. The cutting apparatus 20 also includes a computer 66 with a monitor 68 and a keyboard 70 for controlling various cutting operations. The computer 66 includes data 72 such as cut data and matching data.
A roll of thin air-impermeable overlay material 96 is disposed substantially adjacent to the take-on end 40 of the cutter table 24 of the cutter apparatus 20. A layer of the thin overlay material 96 is spread over the air-permeable layup 14 for facilitating vacuum hold-down of the layup 14 during cutting operations.
A take-off table 23 is disposed at the take-off end 42 of the cutter table 24 for accommodating cut parts 16 subsequent to the cutting operation. The take-off table 23 includes a conveyor 50 that clears the material advanced from the cutter table 24.
In accordance with the disclosure, an overlay material tensioner is provided adjacent the take-off end 42 of cutter table 24 for maintaining tension on the overlay material as it comes off of cutter table 24 onto take-off table 23. The overlay tensioner may be rotatably mounted on a pivot support rod 108 fixedly attached to the side of cutter table 24 and/or take-off table 23. Preferably, two overlay material tensioners are provided per cutting table, one on each side of take-off table 23.
As shown in
In a first active position, shown in
It may be appreciated that by setting an appropriate electric motor speed, a tension is created in the overlay material 96 preventing gathering and bunching of the overlay material. The overlay material tensioner 102 applies tension to the overlay material 96 by trying to drive nip wheel 114 significantly faster than the take-off table conveyor 50. The slip clutch 122 allows the surface speed of the nip wheel 114 to match the surface speed of the take-off table conveyor 50, while generating an adjustable pull force (tension) on the overlay material 96. This tensioning action depends on there being a difference in the coefficients of friction between the nip wheel 114 to overlay material 96 and the overlay material 96 to take-off table conveyor 50.
The slip clutch torque should be set so that it creates as much tension on the overlay material 96 as possible without tearing the overlay material 96 or creating “excessive” stretching. Slip clutch torque may be adjusted manually by turning the adjustment knob 124 on the slip clutch 122. It will be appreciated that the amount of downward pressure/contact force exerted by nip wheel 114 is important. The higher the downward pressure/contact force, the greater the drive torque necessary and the greater the chance of damaging the overlay material 96 as the overlay material moves relative to the surface of the take-off table conveyor 50, and the less likely the overlay material 96 will actually be able to move across the surface of the take-off table conveyor 50 due to mechanical interlocking of the surfaces. It may be generally advantageous to maintain a relatively low contact force. However, if the contact force is too low, then the lateral tension force will be limited, since the tension force is a product of the contact force and the coefficient of friction between nip wheel 114 and the overlay material 96. Thus, these forces must be balanced in a manner known to those skilled in the art.
Preferably, the tangential speed of the nip wheel 114 should be approximately 20% faster than the surface speed of the take-off table conveyor 50. It may be appreciated that a benefit of a relatively large speed differential is minimization of the bunching/pleating of the overlay material. A higher speed differential, however, may negatively impact slip clutch life.
In a second inactive position, shown in
As shown in
The second tensioner frame 206 includes a knurled drive wheel 216 and nip wheel 218 rotatably mounted thereon. The axle of the knurled drive wheel 216 is connected to a belt drive pulley 219 to transfer power via a drive belt 221 to a belt drive pulley 220 connected to the nip wheel 218. The belt drive pulley 220 of the nip wheel 218 may include a slip clutch 222 to control the amount of power transferred from the knurled drive wheel 216 to the nip wheel 218. The knurled drive wheel 216 is sized relative to nip wheel 218 such that the tangential speed of the nip wheel is approximately 20% faster than that of the knurled drive wheel 216.
In a first active position, shown in
In a second inactive position, shown in
While the present disclosure has been illustrated and described with respect to a particular embodiment thereof, it should be appreciated by those of ordinary skill in the art, that various modifications to this disclosure may be made without departing from the spirit and scope of the present disclosure.
The present application claims the benefit and priority of U.S. Provisional Application Ser. No. 63/000,118, dated Mar. 26, 2020, the contents of which are incorporated herein by reference in their entirety for all purposes whatsoever.
Number | Name | Date | Kind |
---|---|---|---|
3495492 | Gerber | Feb 1970 | A |
3742802 | Maerz | Jul 1973 | A |
3777604 | Gerber | Dec 1973 | A |
4434691 | LeBlond | Mar 1984 | A |
7284305 | Allen | Oct 2007 | B1 |
20010037709 | Kuchta et al. | Nov 2001 | A1 |
Number | Date | Country |
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1045746 | Oct 2000 | EP |
1790443 | May 2007 | EP |
Entry |
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International Search Report and Written Opinion issued in corresponding international patent application No. PCT/US2021/024192, dated Jun. 14, 2021, 14 pages. |
Number | Date | Country | |
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20210300709 A1 | Sep 2021 | US |
Number | Date | Country | |
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63000118 | Mar 2020 | US |