The present invention is concerned with a drum printer, in particular an inkjet printer, which has increased throughput.
Drum printers are known in the printing industry. These are usually high throughput machines, such as HP Scitex TJ8000 and TJ8300 that print on flexible and semi-rigid substrates wrapped around the drum. Auxiliary devices, such as ink curing or drying devices, loading devices, etc. are arranged close to the drum surface. Substrate loading and unloading processes, when performed manually or automatically from a roll of substrate material, require the printing drum to be static at the time of substrate loading. Drying/curing of printed image requires a relatively long substrate pass that increases significantly the footprint of the printer. Drum printers also have a fixed throughput defined by the number of print heads or arrays operative for printing, although in some cases change of throughput is desired.
According to a first aspect of the invention there is provided a printing method comprising the steps of;
loading a substrate onto a substrate carrier from a loading cassette;
printing an image onto said substrate;
unloading said substrate from said substrate carrier onto an unloading cassette;
and wherein said loading and/or unloading steps comprise relative displacement between said loading and/or unloading cassette and said substrate carrier.
Preferably, the relative displacement is achieved by displacement of the loading cassette and/or the unloading cassette.
Preferably, said relative displacement comprises generally linear reciprocating movement.
Preferably, said relative displacement comprises displacement of said loading and/or unloading cassette relative to said substrate carrier along a path generally tangential to said substrate carrier.
Preferably, said relative displacement comprises displacement of said loading and/or unloading cassette relative to said substrate carrier along a path generally radially of said substrate carrier.
Preferably, said relative displacement comprises rotational displacement of said substrate carrier.
Preferably, the method comprises the step of adhering said substrate to said substrate carrier by the application of a vacuum between said substrate and said substrate carrier.
Preferably, said loading and unloading steps occur concurrently.
Preferably, the method comprises the step of directing curing radiation onto said substrate during the entire printing process.
According to a second aspect of the invention there is provided a printing method comprising the steps of;
loading a substrate onto a substrate carrier;
printing an image onto said substrate;
unloading said substrate from said substrate carrier;
and wherein said loading and unloading steps occur concurrently.
Preferably, said loading and/or unloading steps comprise relative displacement between said loading and/or unloading cassette and said substrate carrier.
Preferably, the relative displacement is achieved by displacement of the loading cassette and/or the unloading cassette.
Preferably, said relative displacement comprises generally linear reciprocating movement.
Preferably, said relative displacement comprises displacement of said loading and/or unloading cassette relative to said substrate carrier along a path generally tangential to said substrate carrier.
Preferably, said relative displacement comprises displacement of said loading and/or unloading cassette relative to said substrate carrier along a path generally radially of said substrate carrier.
Preferably, said relative displacement comprises rotational displacement of said substrate carrier.
Preferably, said relative displacement comprises linear displacement of said substrate carrier.
Preferably, the method comprises the step of adhering said substrate to said substrate carrier by the application of a vacuum between said substrate and said substrate carrier.
According to a third aspect of the invention there is provided a printer comprising;
a print head;
a substrate carrier;
a substrate loading cassette;
a substrate unloading cassette;
and means for effecting relative displacement between said substrate carrier and said substrate loading and/or unloading cassette.
Preferably, said substrate carrier comprises a drum having an array of vacuum orifices therein.
Preferably, said displacement means is adapted to effect displacement of the loading cassette and/or the unloading cassette.
Preferably, the printer comprises a source of curing radiation.
Preferably, said displacement means is adapted to effect displacement of the drum.
In use the drum 108 rotates around its rotational axis 126 and in addition it may undergo displacement relative to the loading cassette 112 and/or the unloading cassette 116. In one mode of operation the drum 108 is adapted to perform a reciprocal linear movement toward and away from loading cassette 112 as illustrated by arrow 128. In another mode of operation, the drum 108 is capable of performing a reciprocal linear movement up and down from its nominal position as illustrated by arrow 132.
In a further mode of operation, the loading cassette 112 with blank substrates 114 is capable of performing a reciprocal linear movement up and down from its nominal position, as illustrated by arrow 136. This reciprocating movement or displacement is thus in a direction generally radially of the drum 108. Alternatively or additionally, and as shown by arrow 140, the loading cassette 112 may be capable of performing a reciprocal linear movement towards and away from the drum 108. This reciprocating movement is in a direction generally tangential to the drum 108.
The unloading cassette 116 is also capable of performing a reciprocal linear movement up and down, arrow 144, from its nominal position, and a reciprocal linear movement towards and away from drum 108 as indicated by arrow 148.
The print head 104 is usually an array, or a number of arrays, of monochrome or color printing inkjet print heads. For example, for printing with four conventional printing colors cyan, magenta, yellow, and black, it could be an assembly of four different arrays. In another embodiment, the print head 104 is an assembly of eight individual arrays where in addition to four conventional printing colors a light cyan, light magenta, light yellow, and light black colors are added.
In one mode of printing, printer 100 prints with eight colors. In another mode of printing the light cyan, magenta, yellow and black color print head arrays are purged and switched for operation with conventional cyan, magenta, yellow and black inks. This ink system switch instantly doubles the throughput of printer 100.
Drum 108 has no grippers or other mechanical substrate holding means. For substrate loading, drum 108 advances towards loading cassette 112 and locates over cassette 112 and the edge of upper sheet of substrate 114 placed into cassette 112. Drum rotation is initiated and it is synchronized with cassette 112 up or down movement, such that row 156 of smart orifices becomes aligned with the edge of substrate 114, or a section of substrate 114 immediate to the edge. Vacuum is activated and drum 108 contacts edge of substrate 114 with the row of smart orifices 156. Vacuum attaches substrate 114 to drum 108 and as the drum continues to rotate the substrate wraps around the drum 108. The level of vacuum is selected such as to firmly hold substrates of different weights. A roller 160 mounted proximate to the drum 108 and loading cassette 112 or an air stream from an air knife may assist in attaching the substrate to the drum surface. Concurrently with pulling substrate 114 from loading cassette 112 drum 108 returns to the nominal position at which printing is performed.
In another embodiment the drum 108 performs only a rotational movement around its axis 126. The loading cassette 112 moves up and down, and towards and away from the drum 108, with the final linear velocity equal to the linear velocity of the surface of the drum 108 and thereby loading/unloading the substrate 114 without discontinuing drum rotation. The displacement of the loading cassette 112 aligns the edge of the substrate 114 with the row of smart orifices 156, and the vacuum applied at the orifices 156 attaches substrate 114 to the drum 108. As the drum 108 continues to rotate, the substrate wraps around the drum 108. A roller 160 may be mounted proximate to the drum 108 and loading cassette 112 or an air stream from an air knife (not shown) may assist in attaching the substrate 114 to the surface of drum 108. Upon completion of substrate loading, the loading cassette 112 returns to the nominal position and the printing process is initiated. Substrate 114 loading and unloading processes are concurrent processes.
Depending on the printer architecture, unloading is performed in a similar manner. Either the drum 108 or unloading cassette 116 performs the movements required to detach the substrate 114 from drum 108 surface and receive it into the unloading cassette 116. The edge of the substrate 114 is detached by reversing vacuum direction and blowing an air stream through the vacuum orifices 152 and 156. The drum 108 continues to rotate and unloads the substrate 114 into the unloading cassette 116.
Alternatively, an array of pick-up fingers (not shown) may detach the edge of the substrate 114 from the drum 108 and continuous drum rotation then fully unloads the substrate 114 into the unloading cassette 116.
In one embodiment, eight print head arrays are operative to print, as explained above, an image with eight printing colors, which may for example be four conventional process colors with the addition of light cyan, light magenta, light yellow, and light black colors. In another embodiment, when higher throughput is required the inking system of the four light colors (LC, LM, LY, and LB) is purged by any known purging method and switched to four conventional print colors. This simple operation doubles the throughput of the printer 100.
Printed ink should be dried or cured to a condition that eliminates ink tackiness or smear and practically makes the printed substrate 114 ready for use. The present printer 100 prints with UV curable inks and the ink is cured by radiation energy emitted by the curing radiation source 124. In order to speed up the curing and improve the UV energy utilization source 124 utilizes an extended reflector 164. Such reflector construction distributes more evenly the curing radiation around the drum/substrate surface and allows conducting the ink curing process for a longer time with different curing energy level resulting in completely cured image.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/US2007/022947 | 10/30/2007 | WO | 00 | 5/20/2010 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2009/058116 | 5/7/2009 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4783669 | Piatt et al. | Nov 1988 | A |
6084602 | Rombult et al. | Jul 2000 | A |
6120143 | Narushima et al. | Sep 2000 | A |
6471334 | Kline et al. | Oct 2002 | B2 |
6821039 | Lewis | Nov 2004 | B2 |
20090033732 | Naivelt | Feb 2009 | A1 |
Number | Date | Country | |
---|---|---|---|
20100258016 A1 | Oct 2010 | US |