1. Field of the Invention
The invention concerns, in general, the technology of automatic maintenance operations in printing and package manufacturing machinery. Especially the invention concerns the task of maintaining smooth and reliable operation of a coater that on a manufacturing line comes after a sheet-fed printer.
2. Description of Related Art
Many manufacturing processes involve handling workpieces initially in planar, sheet-like form. As an example, the manufacturing process of packages is considered. The manufacturing process is typically arranged so that it takes advantage of the relatively easy handling of workpieces at the stage when they are still in planar form. A typical process for manufacturing cardboard packages comprises at least a printer, a stacker, and a die cutter in this order. Coaters, dryers, and/or other arrangements may follow the printer for implementing steps that, from the viewpoint of printing, represent post-processing. As an example, a coater may be disposed directly after the printer to apply a layer of water- or solvent-based varnish over at least parts of the printed surface.
At the time of writing this description, the printer is more and more often a sheet-fed digital printer, capable of flexibly enabling short series production and making fast changes to at least parts of the printed pattern(s) even after each workpiece. Compared to the relatively long and regular runs made with traditional web-fed printing presses, print works executed with a sheet-fed digital printer are frequently characterized by irregular output, meaning that pauses of variable duration may occur between consecutive workpieces and series of workpieces that come out of the printer. A consequence of the flexibility of the printer is a requirement for also the subsequent machinery to adapt their operation to the irregularities in operation.
As an example, we may consider a flexographic coating unit like the one schematically illustrated in
If the coating substance is to be applied in specific patterns, the mirror images of corresponding patterns have been formed in positive (as elevated areas) on the surface of the plate cylinder. The coating substance then only becomes spread on the elevated areas, and consequently forms the desired patterns on the printed surface when the surface of the plate cylinder presses against the appropriate workpiece. The “printing plate”, as the outmost surface layer of the plate cylinder is called, is made of flexible material such as a selectively hardened light-sensitive polymer, which explains the descriptor “flexographic”.
For obvious reasons, the varnish or other coating substance must dry relatively quickly, although a dryer may follow the coater to expedite drying. An exposed layer of a typical water-based varnish used in cardboard packages becomes leathery in just tens of seconds, and completely solid only shortly thereafter. On the surfaces of the workpieces, quick drying of the coating substance is an advantage. However, on the surface of the plate cylinder it may cause problems, especially if the output rate of workpieces from the printer is irregular.
From German Utility Model DE202010007499U1, and German Patent Applications DE102004062114A1 and DE102008020393A1 various general cleaning arrangements for cylinders are known.
An objective of the present invention is to present a cleaning arrangement, a coater, and a method for cleaning a coater that would facilitate flexible handling of sheet-fed workpieces. Another objective of the present invention is to make the coater adapt to the possibly irregular output rate of workpieces from a digital printer. Yet another objective of the invention is to ensure high-quality coating of irregularly fed workpieces. Yet another objective of the invention is to minimize the need for user intervention in the machine parts that follow a digital printer on a manufacturing line.
These and further advantages can be achieved by using a cleaning arrangement that comprises a cleaning web as well as moving mechanisms for moving the cleaning web both tangentially and radially with respect to a plate cylinder of the coater. A wetting arrangement can be used to selectively wet portions of the cleaning web. Remnants of the wetting liquid can be removed from the surface of the plate cylinder with pressurized air. For the last-mentioned purpose, there can be used a blower nozzle, the other task of which is to ensure the detaching of a front end of a passing workpiece from the outer surface of the plate cylinder.
The exemplary embodiments of the invention presented in this patent application are not to be interpreted to pose limitations to the applicability of the invention. The verb “to comprise” is used in this patent application as an open limitation that does not exclude the existence of also unrecited features.
The invention, both as to its construction and its method of operation, together with additional objects and advantages thereof, will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.
The cleaning arrangement comprises a cleaning web, which in the embodiment of
The cleaning arrangement also comprises a tangential moving mechanism, the task of which is to controllably move the cleaning web in at least one direction in a plane defined by the cleaning web. In the embodiment of
Additionally, the cleaning arrangement comprises a radial moving mechanism that is configured to controllably move the cleaning web in at least one direction that is not within said plane, i.e., out of the plane defined by the portion 202 of the cleaning web that is drawn between the two rollers. An example of a radial moving mechanism comprises an inflatable cushion 205 on the back surface side of the cleaning web, and a controllable valve 206 for inflating and deflating said inflatable cushion 205. The surface of the cleaning web that comes against the plate cylinder is called the cleaning surface, so the back surface is the opposite surface. These surfaces may well be the surfaces of a single, unitary layer of cleaning web material, although it is also possible to use a multilayer material for the cleaning web.
As an alternative to an inflatable cushion, the radial moving mechanism could comprise, for example, a movable blade, a movable roller, and/or a movable pad on the back surface side of the cleaning web. Any of these could be used to controllably press the cleaning web against an outer surface of a plate cylinder and to temporarily detach the cleaning web from the outer surface of the plate cylinder as needed. The movement considered here takes place essentially in the radial direction of the plate cylinder; hence the designation “radial moving mechanism”.
The upper part of
When an unused portion of the cleaning web has been drawn under the inflatable cushion, the cleaning arrangement is ready for another cleaning sweep of the kind shown in the leftmost illustration. Whether the plate cylinder rotates or not during the winding of the cleaning web, is not important. Directions of rotation are represented by arrows.
The rightmost illustration at the upper part of
In the embodiment shown in the rightmost illustration at the upper part of
Since the aim of the cleaning is to absorb, from the outer surface of the plate cylinder, remnants of coating substance that are not usable any more for coating any incoming workpiece, the porosity of the cleaning web comes into question. It is advantageous to make the cleaning web of a material that is porous enough to allow remnants of the coating substance to be absorbed.
It has been found that for more efficient cleaning, it may be advantageous to wet a portion of the cleaning web with a liquid that acts as a solvent for the coating substance. For example, if water-based varnish is used as a coating substance, the wetting liquid may be water. Similarly if the coating substance is soluble for example, in some organic solvent, that solvent may be used as a wetting liquid. If wetting is used, it sets another requirement for porosity: the material of the cleaning web must be porous enough to allow the wetting liquid to spread within it. If wetting liquid is dosed on the back surface of the cleaning web, the material must be porous enough to allow sufficient quantities of the wetting liquid to diffuse through the cleaning web to its cleaning surface so that the wetting liquid is able to perform its task in dissolving coating substance from the surface of the plate cylinder.
Examples of materials that can be used for the cleaning web comprise, but are not limited to, tissue materials that at the time of writing this description are available from Baldwin Technology Company, Inc., 8040 Forsyth Blvd, St. Louis, Mo. 63105, USA. A person skilled in the art, having knowledge of such tissue materials and having been advised of their applicability to the cleaning arrangement described here, could also consider other cleaning web materials.
Also, similar to the embodiment of
For implementing the wetting, the cleaning arrangement of
In order to control the amount, rate, and timing of the application of wetting liquid to the cleaning web, the cleaning arrangement of
If a wetting arrangement is used, it is advantageous to place it so that wetting of a portion of the cleaning web takes place either simultaneously or before that portion comes in contact with the outer surface of the plate cylinder. In the embodiment of
Supply functions, i.e., the supply of driving (and braking) power 305, the supply of water or other wetting liquid 306, and the supply of air (or other inflating substance) 307 are shown schematically at the upper part of
The outer surface of the plate cylinder may comprise recesses, especially if there are areas of the workpieces that should not receive coating. Remnants of wetting liquid may remain in such recesses, even if a dry portion of the cleaning web would be used to sweep the surface of the plate cylinder after sweeping it with a wetted portion. For removing remnants of the wetting liquid (and also for removing dry dust, if any is encountered) from the outer surface of the plate cylinder, the cleaning arrangement may comprise one or more blower nozzles with an operating direction directed to a space faced to by the cleaning surface of the cleaning web. This definition of the operating direction is easier to understand, when it is reminded that the plate cylinder occupies that space; in other words, the operating direction of the blower nozzle(s) is towards the outer surface of the plate cylinder. Concerning the dimension and/or distribution of the blower nozzle(s) across the transverse width of the cleaning web, the same considerations apply as for the wetting nozzle(s).
Before describing the double use of the blower nozzle(s), the spatial relations and purposes of some parts of the cleaning arrangement may be briefly recapitulated with reference to other parts of the coater in
The cleaning arrangement comprises one or more wetting nozzles 303 with an operating direction towards said back surface. The one or more wetting nozzles are located between the feed roller 203 and the spool 204, with the operating direction towards the planar portion 202 of the cleaning web drawn between the feed roller 203 and the spool 204.
The cleaning arrangement of the coater seen in
A momentary puff of pressurized air from the blower nozzle 402 implements a so-called air knife that ensures the detaching of a front end of a passing workpiece from the outer surface of the plate cylinder 101. For this purpose, it is important to time the puff of air correctly so that it hits exactly the front end of a passing workpiece. However, the cleaning of the outer surface of the plate cylinder is typically performed during a break in printing, when there are no workpieces coming through the coater. Thus, the use of pressurized air blown through the blower nozzle 402 may be timed more freely. If the whole “active” surface of the plate cylinder (meaning that portion of its outer surface that is actually used to transfer coating substance onto a workpiece) is cleaned with a cleaning arrangement that comprises wetting, it is advantageous to keep pressurized air coming through the blower nozzle 402 during the whole time interval when the active surface of a rotating plate cylinder turns past the blower nozzle 402.
For the sake of completeness,
A method for cleaning a coating unit according to an embodiment of the invention is preferably implemented by making a programmable control arrangement execute a program comprising computer-readable instructions that, when executed by a computer, cause the implementation of the method.
Controlling the coater involves controlling the rotation of all rollers and cylinders for the rotation of which there are control means, such as motors, gears, and/or brakes. Controlling the rotation of rollers and cylinders is schematically shown as 511. Also, since in this description we assume that the coater is utilized especially to spread varnish on sheet-like workpieces that are to become packages, controlling the dosing of the varnish is illustrated as 512. The dosing of varnish or other coating substance can be accomplished with means that are known as such from the technology of coaters as well as flexographic and other printers. For the purpose of the present invention, it is noted that it is advantageous to have the dosing of the coating substance interrupted (for example, by disconnecting a coating-substance-spreading roller from the plate cylinder) for those periods when the outer surface of the plate cylinder is cleaned. Thus, the part of controlling the coater that is schematically illustrated as 512 should allow temporarily interrupting the dosing of coating substance onto the plate cylinder as a response to a corresponding command from the control program.
Controlling the cleaning arrangement is schematically shown as 513. It comprises controlling the movements of the cleaning web, as illustrated in 521. Moving the cleaning web involves using a radial moving mechanism to press a cleaning web against an outer surface of the plate cylinder, and using a tangential moving mechanism in a direction tangential to said outer surface of the plate cylinder to bring an unused portion of said cleaning web to a location where it can be pressed against the outer surface of the plate cylinder. This part of the cleaning control should interact with the control of the rotating movements of the rollers and cylinders in 511, for rotating the plate cylinder to rub its outer surface against the cleaning web.
Air dosing control, illustrated as 522, can be used to controllably inflate and deflate an inflatable cushion, the inflating of which causes it to bulge outwards and consequently push the cleaning web against the plate cylinder. Also, the task of temporarily detaching the cleaning web from the outer surface of the plate cylinder goes under air dosing control, if an inflatable cushion is used, because said detaching is accomplished by deflating the inflatable cushion. If the cleaning arrangement comprises one or more blower nozzles, air dosing control 522 can additionally be used for removing remnant wetting liquid from the outer surface of the plate cylinder by blowing air towards the outer surface of the plate cylinder from said blower nozzle(s). In an advantageous case said nozzle(s) is (are) also used to ensure the detaching of a front end of a passing workpiece from the outer surface of the plate cylinder.
Wetting liquid dosing control, illustrated as 523, can be used to wet a portion of the cleaning web before—or simultaneously with—pressing it against the outer surface of the plate cylinder. Since also interrupting the wetting can be considered to go under wetting liquid dosing control 523, it has also a role in the method step where, after pressing a wetted portion of the cleaning web against the outer surface of the plate cylinder, a dry portion of the cleaning web (which is dry because the delivery of wetting liquid was interrupted) is pressed against the outer surface of the plate cylinder.
To which further state a transition occurs from the wait state 602, depends on how long it takes for the next workpiece to arrive. If the waiting period is only short, a transition to the coating state 601 can be made directly, because the coater is in complete readiness to begin the coating of the next workpiece. However, during the waiting period, the coating substance that was left on the surface of the plate cylinder is drying all the time. After the waiting period has lasted longer than a first threshold, the layer of coating substance on the surface of the plate cylinder has become so dry that trying to transfer it onto the next workpiece could result in suboptimal quality of the coating. Therefore, if the waiting period had some medium length, information about the arrival of a next workpiece causes a transition to a refresh state 603, in which some fresh coating agent is dosed on the surface of the plate cylinder before the coating of the next workpiece can begin.
If the waiting period becomes still longer and no information is still received about the arrival of a next workpiece, there occurs, after a second threshold that is longer than said first threshold, a transition from the wait state 602 to a cleaning state 604. During the cleaning state 604, the coater executes a method for cleaning a coating unit according to an embodiment of the invention, in order to prevent the remaining coating substance from solidifying on the surface of the plate cylinder and in order to ensure optimal condition of the surface of the plate cylinder before coating the next workpiece. An example of the method steps to be taken is shown in the upper right part of
spray and spool: a portion of the cleaning web is wetted before—or simultaneously with—pressing it against the outer surface of the plate cylinder, and the spool is rotated to ensure that the wetted portion reaches a location where it can be pressed against the outer surface of the plate cylinder
inflate and turn the plate cylinder: a radial moving mechanism (here: an inflatable cushion) is used to press the wetted portion of the cleaning web against the outer surface of the plate cylinder
deflate and spool: the radial moving mechanism is used to temporarily detach the cleaning web from the outer surface of the plate cylinder, and the spool is rotated to bring an unused portion of the cleaning web to a location where it can be pressed against the outer surface of the plate cylinder
inflate and turn plate cylinder: the radial moving mechanism is used to press the unused (dry) portion of the cleaning web against the outer surface of the plate cylinder
blow air: remnant wetting liquid is removed from the outer surface of the plate cylinder by blowing air towards it from a blower nozzle, preferably one that is also used during coating to ensure the detaching of a front end of a passing workpiece from the outer surface of the plate cylinder
deflate and stop: the cleaning is ended by detaching the cleaning web from the plate cylinder and stopping the remaining movement (if any) of the feed roller and spool.
After the cleaning state 604, a transition occurs to a park state 605, in which the plate cylinder is prepared for beginning the next coating. The name “park state” comes from the fact that since the time that still needs to be waited before the next workpiece comes in is not known, it may be preferable to stop the plate cylinder, possibly after driving it into a point of its rotational movement that is optimal in view of starting its rotating motion for the next time.
The detailed embodiments that have been described above are not to be construed as limiting the scope of protection since variations with the scope of the invention will be apparent to those of ordinary skill in the art. As an example, even if a roll-to-roll embodiment has been shown for implementing the tangential movement of the cleaning web, it is possible to use, for example, a plate-like cleaning web or cleaning pad that can be moved within the plane that is defined by its planar form. Also, even if the blower nozzles have been specifically described as applicable to double use, this is not a requirement of the invention. Especially if the detaching of the front end of each coated workpiece from the plate cylinder can be ensured without an air knife, one or more blower nozzles can be designed solely for the purposes of removing remnants of the wetting liquid, in which case the nozzle(s) can be placed and formed in a way that most optimally serves that function.
Number | Date | Country | Kind |
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20125448 | Apr 2012 | FI | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/058368 | 4/23/2013 | WO | 00 |