The present invention relates to systems for processing paperboard sheets, such as container blanks, and more particularly to a vacuum assisted sheet transfer device such as is used, for example, to transfer sheets between the printing stations in a sheet-fed printing system.
As is well known in the art, sheet-fed flexographic printing machines are used for multicolor printing on one side of solid or corrugated paperboard blanks which are subsequently converted into containers or cartons. The blanks are fed through multiple rotary print stations and, typically, into a rotary die cutter at the downstream end. The finished blanks are folded and glued, all in a manner well known in the industry. In order to avoid contact with the freshly printed face of the blanks, the blanks are typically transferred between print stations and between the last print station and the rotary die cutter with vacuum-assisted belt conveyor devices that engage the unprinted face of the blank, usually from above, but may be from below. Since accurate registration of the blanks must be maintained from one print station to the next and into the die cutter, vacuum assisted belt transfer devices must be capable of capturing and transferring the blanks reliably and without loss of register. As a result, large volumes of air are required to induce adequate levels of negative pressure in the areas where sheets are present and, of course, correspondingly large blowers must be used. In addition, the large volume airflow is provided continuously and without regard to sheet length or the spacing between sheets. Vacuum-assisted sheet transfer devices are known in which vacuum generated airflow through the sheet transfer system is controlled laterally to accommodate sheets of varying width, but such devices are typically mechanically complex.
Therefore, it would be desirable to have a vacuum distribution system for a belt conveyor sheet transfer device that applies vacuum only when and where a sheet is present, to thereby minimize air volume loss and to permit the use of smaller blowers.
In accordance with the present invention, a self-valving vacuum distribution system for a belt operated sheet transfer conveyor applies sheet holding vacuum precisely and only where the sheet is located, both in the machine direction and in the cross machine direction. The vacuum that follows the moving sheets actuates the vacuum control valves such that they open to provide vacuum only beneath the advancing sheet and not beyond the lateral edges of the sheet.
The self-valving vacuum distribution system of the present invention comprises a vacuum plenum that has a flat surface over which a pair of spaced conveyor belts operate to define with the surface an open vacuum channel section; and, vacuum control valves that are spaced along the channel in the plenum surface and which are held closed by a high pressure differential between the vacuum plenum and the open vacuum channel and are biased to open under a reduced pressure differential between the vacuum plenum and the vacuum channel when the channel is covered by a sheet carried over the channel on the conveyor belts. The apparatus preferably includes a vacuum starter opening in the plenum surface upstream of the control valves to provide initial vacuum communication between the plenum and the upstream end of the vacuum channel. The apparatus preferably operates with an infeed device adapted to move a line of spaced sheets in series into contact with the conveyor belts to cause the leading edge of each sheet to override the vacuum starter opening and each control valve in succession, thereby progressively closing the vacuum channel and reducing the pressure differential to said reduced level allowing the valves to be biased open.
When operating to process a line of spaced sheets, passage of the trailing edge of each sheet over the control valves causes the valves to progressively close. The conveyor belts preferably have flat coplanar conveying surfaces, and the plenum surface between the belts is recessed from the conveying surfaces to form the vacuum channel.
In a presently preferred embodiment, each of the control valves comprises a flat resilient metal plate operatively connected by an edge to the plenum surface and having a closure face bent to curve away at an acute angle from the plane of the surface to provide the bias to open at said reduced pressure differential, and a vacuum opening in the plenum surface that provides vacuum communication between the plenum and the vacuum channel, said vacuum opening aligned with the valve plate and closed thereby at the high pressure differential.
In the preferred embodiment of the invention, the apparatus includes a plurality of laterally adjacent vacuum channels, each channel providing support for an incremental width of the sheet, and the vacuum plenum is operatively connected to the adjacent vacuum channels. In the presently preferred embodiment, each of the control valves includes a vacuum opening in the plenum surface that provides vacuum communication between the plenum and the vacuum channel, and a valve plate that is attached to the plenum surface and is operative to seal the vacuum opening against the valve bias at the high pressure differential. This supply of plenum vacuum to the starter openings may be provided by a starter vacuum conduit that is controlled by the control valve to provide the plenum vacuum pressure to the starter opening of the next laterally adjacent vacuum channel when the sheet is wide enough to cover that next adjacent channel. The starter vacuum conduit preferably includes a vacuum inlet end in the plenum surface and a vacuum outlet end having an open connection to the vacuum starter opening in the next adjacent vacuum channel, and wherein the valve plate is operative to close the vacuum inlet end at the high pressure differential and to open the inlet end at the reduced pressure differential. A starter vacuum conduit is provided to connect the plenum surfaces of each pair of laterally adjacent vacuum channels.
In a variation of the present invention, a sheet-actuated vacuum assisted sheet conveyor comprises a pair of laterally spaced, coplanar, parallel driven flat conveyor belts positioned to operate over a surface of a vacuum plenum, the plenum surface between the belts being recessed from the coplanar flat belts to define a shallow vacuum channel, a plurality of vacuum control valves are located in the vacuum surface spaced in the direction of conveyor belt movement and provide vacuum communication between the plenum and the vacuum channel. The control valves are operative to be held closed by a negative pressure in the plenum sufficient to create a first pressure differential across the valve when no sheet is present. The valves are biased to open for vacuum communication when a sheet is present at a second pressure differential across the valve less than the first pressure differential. Means are provided for moving sheets into planar contact with the conveyor belts in a manner that progressively covers the vacuum channel. Means are also provided for applying the plenum vacuum to an upstream end of the vacuum channel, upstream of the upstreammost valve, such that, as a sheet moves to progressively cover the vacuum channel, vacuum pressure in the channel moves in the downstream direction with the sheet to cause the pressure differential across each valve in succession to decrease to the second pressure differential, causing the valves to serially open, thereby applying the plenum vacuum directly to the sheet to hold the same against and to move with the conveyor belts. The foregoing variant of the invention also utilizes vacuum control valves which comprise a vacuum opening in the plenum surface of the vacuum channel, and a valve plate that is attached to the plenum surface and is operative to seal the vacuum opening against the valve bias at the first pressure differential. The valve plate preferably comprises a thin spring steel plate attached at one edge to the plenum surface and permanently bent along a hinge line to define a flat body portion extending away from the surface at an acute angle when the valve is open.
The means for applying the plenum vacuum pressure to the upstream end of the vacuum channel preferably comprises a vacuum starter opening in the plenum surface. The preferred apparatus also includes a plurality of laterally adjacent vacuum channels that are operatively connected to the vacuum plenum, each channel providing support for an incremental width of the sheet. The vacuum starter opening of each of the laterally adjacent vacuum channels is connected by a starter vacuum conduit to a directly adjacent vacuum channel such that the plenum vacuum pressure in said directly adjacent channel, when the control valve for that directly adjacent channel is open, is communicated to the starter opening of the laterally adjacent channel. Each starter vacuum conduit includes a vacuum inlet end in the plenum surface of the directly adjacent vacuum channel under the reed valve.
In accordance with the method of the present invention, the vacuum assisted transfer of the sheets delivered in serial spaced relation is performed in accordance with the steps of (1) driving a pair of laterally spaced coplanar parallel flat conveyor belts over a surface of a vacuum plenum with the plenum surface between the belts recessed to define a shallow vacuum channel, (2) positioning a plurality of vacuum control valves in the vacuum surface with the valves spaced in the direction of conveyor belt movement and providing fluid communication between the plenum and the vacuum channel, (3) holding the valves closed by generating a negative pressure in the plenum sufficient to create a first pressure differential across the valves, (4) biasing the valves to open for fluid communication at a second pressure differential across the valves less than the first pressure differential, (5) moving the sheets into planar contact with the conveyor belts to cause each sheet to progressively cover the vacuum channel, (6) applying a starter vacuum pressure to an upstream end of the vacuum channel upstream of the upstreammost valve, and (7) utilizing the moving sheet to progressively cover the vacuum channel, causing the (a) the vacuum pressure in the channel to move downstream with the sheet, (b) the pressure differential across each valve to decrease in succession to said second pressure differential, and (c) said valves to serially open, thereby applying the plenum vacuum pressure to the sheet to hold the sheet against and to move with the conveyor belts.
The method also preferably includes the steps of (1) providing a plurality of laterally adjacent vacuum channels, (2) utilizing the adjacent channels to provide support for incremental widths of the sheet, and (3) transferring the negative plenum pressure from the vacuum channel to which the starter vacuum is applied to the upstream ends of the laterally adjacent vacuum channels serially in response to the opening of each respective control valve.
Referring first to
The plenum 10 has a lower plenum surface 11 which is of a layered sandwich construction as will be detailed hereinafter. A series of laterally spaced conveyor belts 12 are each mounted to operate over the plenum surface 11 between a head pulley 13 and a tail pulley 14, with the return runs of the belts operating around an upper drive roll 15. The belts have flat outer conveying surfaces 16 and toothed inner surfaces in the manner of timing belts. The drive roll 15 is hobbed or otherwise machined with a tooth profile to provide positive driving engagement with the toothed belts 12. A drive motor 29, operatively connected to the drive roll 15, is mounted inside the plenum 10. The plenum 10 is mounted between a pair of laterally opposed end plates 17, one of which is provided with a large opening 18 which is connected with appropriate ducting (not shown) to a blower (also not shown) having a capacity sufficient to at least generate a negative vacuum pressure in the plenum of about three inches of water (about 0.75 kPa) with a maximum width sheet fully engaged. The plenum includes a long central supply chamber 20 connected along each of its lower edges to shallow distribution chambers 21 extending in upstream and downstream directions and defining with the lower plenum surface 11 a plenum chamber 19.
The flat conveying surfaces 16 of the conveyor belts 12 are coplanar and define the plane of the lowermost surface of the sheet transfer apparatus. Each adjacent pair of conveyor belts 12 and the plenum surface 11 therebetween define a shallow vacuum channel 22 that runs the full length of the apparatus between the head and tail pulleys 13 and 14. Each of the vacuum channels 22 (there being sixteen in the apparatus shown) is divided by common laterally extending divider strips 23 into a series of vacuum channel sections 24 (there being eleven vacuum channel sections 24 in each vacuum channel 22 in the disclosed embodiment). The row of upstreammost channel sections are starter vacuum channel sections 25, the construction and function of which will be described.
Referring also to
Overlying each steel strip 31 is a spacer grid 35 which may have a thickness of about 0.25 in (about 6.4 mm). Each spacer grid 35 includes continuous lateral edges 36 which run the full length of the sheet transfer apparatus and are spaced laterally from the edges of the next adjacent spacer grid to define guide slots for the toothed faces of the conveyor belts 12. The spacer grids 35 also include laterally extending connector strips 37 which comprise the divider strips 23 that define the cross machine direction rows of vacuum channel sections 24 and the upstream row of starter vacuum channel sections 25. A slider plate 41 is placed over each of the spacer grids 35 to provide a low coefficient of friction surface for the conveyor belt edges and for the surface of the paperboard sheet 51 that is being carried on the surface 16 of the belts 12. The slider plate may have a thickness of about 0.0625 in (about 1.6 mm). In the final assembly, the exposed surface of the slider plate 41 is recessed from the conveying surfaces 16 of the belts 12 by about 0.050 in (about 1.3 mm). The conveyor belts 12 may be spaced laterally from one another by about 5 in (about 125 mm), thereby defining the long shallow vacuum channels 22 running the full length of the sheet transfer apparatus. Each slider plate 41 includes a pair of L-shape vacuum communication slots 40 for each of the vacuum channel sections 24. When the vacuum control valve 34 is open, the vacuum communication slots 40 allow plenum vacuum to be supplied to the vacuum channel sections and thus to a sheet being carried over it, as will be described in greater detail below.
A pair of adjacent vacuum channels 22 at the center of the apparatus comprise the main vacuum channels 42. The vacuum starter opening 30 at the upstream end of each of these channels is always in direct open communication with the plenum chamber 19. At the center of the arrangement of vacuum opening slots 28 in the first row of vacuum channel sections 24, the plenum wall 26 is also provided with a vacuum inlet opening 43. The vacuum inlet opening 43 in each of the main vacuum channels 42 is connected by a vacuum conduit 44 to the vacuum starter opening 30 of the next laterally adjacent vacuum channel 22, as best seen in
As best seen in
In operation, a negative vacuum pressure is generated in the vacuum plenum in stages. Because all of the vacuum control valves 34 are biased open, the large open flow area would make it difficult to initially evacuate the plenum with a blower having a capacity sized for normal operation. Therefore, the air flow openings 46 in the bottom plate 45 of the vacuum supply chamber 20 are all closed by operating the pneumatic cylinders 47 to close the air flow valves 48. When the vacuum in the supply chamber 20 has reached a desirable level, the air flow valves 48 may be opened in sequence to permit the evacuation of the plenum chamber 19 in a controlled manner. The valve plates 32 of the vacuum control valves are constructed such that, when the pressure differential across the valve (i.e., between the plenum chamber 19 and the vacuum channels 22) reaches a desired level, for example 3 in of water (0.75 kPa), the valve plates 32 will be sucked against the plenum lower wall 26, closing the vacuum control valves 34. In this state, the apparatus is ready to receive and transfer sheets which may, for example, be exiting and under the control of the print rolls 53 of an upstream printer. As is best seen in
The apparatus and method of the present invention also provide automatic cross machine direction vacuum adjustment to accommodate sheets of varying widths. As indicated previously, a sheet 51 entering the apparatus from upstream will pass over and cover the vacuum starter openings 30 and vacuum will build up in the starter vacuum channel sections 24 and be carried with the sheet to the vacuum channel sections 25 and the first control valves 34 which will open as indicated above. When the valve plate 32 lifts to open the valve, vacuum pressure in the vacuum channel 22 will enter the vacuum inlet opening 43 and communicate via the starter vacuum conduit 44 to the vacuum starter opening 30 of the next adjacent vacuum channel 22. If an incremental width of the sheet is sufficient to cover that next adjacent starter vacuum channel section 24 and vacuum starting opening, the vacuum will build up in the channel and travel downstream with the lead edge 50 of the sheet 51 to cause the vacuum control valves 34 in that machine direction line of valves to sequentially open. If there is no incremental width of the sheet sufficient to cover an adjacent vacuum channel 22, there will be no vacuum build up in the channel and the control valves 34 will simply not open. In other words, the incremental increase in sheet width must be sufficient to extend in the cross machine direction onto the next belt surface. Thus, the system is automatically self-adjusting in the cross machine direction, as well as in the machine direction.
The apparatus and method of the present invention provide a substantial advantage over prior art devices insofar as a much lower volume of vacuum airflow is necessary, thus substantially decreasing the required blower horsepower and the noise generated by blower operation. The vacuum air flow is held to an absolute minimum and, as a further beneficial result, the reduced air flow will not tend to dry the ink on the print plates or on the anilox rolls as compared to prior art vacuum transfer apparatus. The wider the sheets being conveyed, the more valves there will be in the cross machine direction with inherent vacuum leaks at the lead and tail edges of the sheet. The vacuum supply must be sufficient to maintain the minimum vacuum pressure (e.g. 3 inches of water or 0.75 kPa) when handling maximum size sheets.
In lieu of a control valve 34 utilizing a thin spring steel valve plate 32, a control valve may be utilized that comprises a spring biased poppet type valve mounted inside the plenum chamber 19. This type of valve would, for example, include a coiled compression spring surrounding the valve stem and providing a bias that would cause the valve to open when there is about one-half of the full pressure differential across the valve, i.e. between vacuum channel section 25 and the plenum 19. As with the preferred embodiment control valve, plenum vacuum would overcome the spring bias and hold the poppet type valve closed until a moving sheet travels over the vacuum channel section a sufficient distance to provide a vacuum pressure in the channel section sufficient to reduce the pressure differential across the valve, thereby permitting the biasing spring to begin to open the same. Thereafter, plenum vacuum would communicate with the vacuum channel section, further reducing the pressure differential across the valve and supplying full plenum vacuum to hold the sheet on the conveyor belts.
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Number | Date | Country | |
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20050156376 A1 | Jul 2005 | US |