The present invention generally relates to the finishing of paper and other graphic substrates wound in rolls printed by way of digital restitution systems and in particular to an automatic cutting device.
It is known that graphic technique, including digital restitution, is more and more oriented towards printing by way of the ink-jet technology digital files on rolls of graphic substrates having the most varied characteristics and size.
There are known automatic cutting devices for the finishing and the cutting of printed substrates along a longitudinal direction corresponding to the feeding direction, as well as along a transverse direction perpendicular to the longitudinal direction. To this end, these cutting devices comprise a working plane configured to allow feeding of a printed substrate, at least one longitudinal cutting unit and at least one transverse cutting unit that are generally provided with pairs of counter-rotating blades. The counter-rotating blades of each pair are intended to contact opposite faces of the printed substrates and are arranged side by side so as to behave like scissors and allow to separate printed images from the respective longitudinal and transverse peripheral edges, which form processing scraps.
The longitudinal cutting units are oriented in the longitudinal direction of the printed substrates and are mounted on suitable cross-members which allow to position them at variable distances relative to each other in a transverse direction, perpendicular to the longitudinal direction, depending on the position of the longitudinal edges.
The transverse cutting units are movable along the transverse direction from one side to the opposite side of the working plane along a slit formed therein and generally comprise two pairs of blades that are spaced apart in the transverse direction.
The international publication WO 2006/126224 A1 in the applicant's name discloses an example of an automatic cutting device of the above-mentioned type.
It is known that in order to make a transverse cut on a printed substrate the latter is temporarily stopped and a transverse cutting unit is moved from one side to the opposite side of the working plane along the slit so as to make a first cut. The substrate is then made to advance in the longitudinal direction by a short predetermined distance and stopped again. The transverse cutting unit is operated a second time so as to make a second cut by running along the slit from one side to the opposite side of the working plane in the opposite direction with respect to the direction of the first cut. The scrap thus separated from printed substrate falls into the slit.
In order to cut scraps in the transverse direction it is therefore necessary to operate the transverse cutting unit twice, to stop the printed substrate two times and make it to advance in-between.
The digital printing industry is rapidly evolving and there is currently a strong need to reduce the time taken by cutting operations, in particular along the transverse direction. Therefore, cutting devices meeting this need are desirable, which is an object of the present invention.
Said object is achieved with a cutting device, whose main features are specified in the first claim, while other features are specified in the remaining claims.
An idea of solution underlying the invention is to provide a cutting device wherein the transverse cutting unit is provided with pairs of counter-rotating blades spaced apart in the longitudinal direction, which allows to carry out on a printed substrate two parallel cuts simultaneously in a single run of the cutting unit in the transverse direction. Thanks to this configuration it is possible to remarkably reduce the cutting time.
The supports of the counter-rotating blades of the transverse cutting unit arranged parallel to each other are movable relative to one another in the longitudinal direction, thus allowing to separate scraps having a different size in this direction.
Adjustment of the mutual distance of the supports, and therefore of the counter-rotating blades, may be done manually or automatically by means of linear actuators.
The transverse cutting unit may also advantageously comprise a supporting surface adapted to prevent scraps from falling on the shafts of the counter-rotating blades or, more generally, between their supports, thus affecting operation of the cutting unit.
The supporting surface may advantageously comprise a shaped portion configured so as to impart an arch shape to the scraps that facilitates its advancement and fall in the slit past the cutting unit. This feature of the invention is particularly effective in the case of printed substrates made of thin and light paper, that have a low rigidity and therefore tend to build up, thus making it difficult to discharge the scraps.
The transverse cutting unit may also comprise a pair of conveyor belts operatively connected to the pairs of counter-rotating blades mounted on any one of the supports. The conveyor belts have the function to contact and drag the scraps past the cutting unit, thus facilitating their discharge into the slit of the working plane. This feature of the invention is particularly effective in the case of printed substrates made of thin and light paper or paper made of materials that are prone to static electricity buildup, which tend to adhere to the rotating blades and make it very difficult and problematic to discharge scraps.
A printed substrate, generally coming from a roll, has a natural tendency to be rolled up again. There is therefore the risk that the leading edge of a printed substrate proceeding along the working plane is inserted in the slit for discharging the scraps. According to a further aspect of the invention, the cutting device advantageously comprises auxiliary supporting means configured to support a printed substrate when crossing the slit of the working plane in the longitudinal direction. The auxiliary supporting means may for example comprise a flap restrained along one of the edges of the portions of the working plane that face the slit along which the transverse cutting unit runs and the scraps are discharged. Alternatively, one or more blowers configured to dispense jets of air towards the slit may be employed, or a combination of both a flap and one or more blowers.
Further advantages and features of the cutting device according to the present invention will become clear to those skilled in the art from the following detailed and non-limiting description of embodiments thereof with reference to the accompanying drawings in which:
The cutting device 100 comprises a transverse cutting unit 300 arranged in correspondence with a slit 120 which stretches out in a transverse direction T, perpendicular to the longitudinal direction L.
The slit 120 divides the working plane 110 into two portions that are respectively indicated with reference numbers 110a and 110b, and allows movements of the transverse cutting unit 300 from side to side of the working plane and discharge of the scraps produced by the transverse cutting unit while cutting.
The transverse cutting unit 300, shown in
In
With reference to
To this aim, the cutting unit 300 is provided with adjustment means e.g. comprising a worm screw 330 restrained to the two uprights 310, 320. The worm may e.g. be operatively connected to a crank 331 restrained thereto allowing to drive it manually, or to a motor (not shown) for automatic actuation.
Alternatively, the adjustment means may comprise one or more linear actuators of electrical, hydraulic or pneumatic type restrained to the uprights 310, 320 and operatively connected to a control system of the automatic cutting device 100.
By way of example, the distances between the blades of the cutting unit 300 may vary between 1 and 5 centimeters.
The cutting unit 300 further comprises at least one supporting surface 340 adapted to prevent the scrap 210 from falling on the shafts of the blades or, more generally, between the uprights 310, 320, thus affecting the operation of the cutting unit 300.
The supporting surface 340 stretches out between the uprights 310, 320 of the counter-rotating blades in the longitudinal L and transverse T directions and is arranged above the shafts of the counter-rotating blades with respect to the vertical direction V.
In the embodiment of the invention shown in
In the illustrated embodiment, the plate 341 is e.g. arranged above the plate 342.
According to an alternative embodiment of the invention, the supporting surface 340 can be formed by inserting one or more resilient members coaxially to the shafts of the blades intended to contact the lower surface of the printed substrate 200. As shown in
The supporting surface 340 may advantageously comprise a shaped portion configured so as to impart an arch shape to the scraps, hence a greater flexural rigidity, so as to facilitate its movement past the cutting unit and fall into the slit. This feature of the invention is particularly effective in the case of printed substrates made of thin and light papers, that have a low flexural rigidity and tend to build up, thus making it more difficult to discharge the scraps.
As shown in
Now referring to
In
As schematically indicated in
Once made a cut in the transverse direction T, the printed substrate 200 is made to advance in the longitudinal direction L until it reaches the next cutting position, in correspondence of which it is stopped so as to operate the cutting unit 300 again. A leading edge 220 of the support 200 resulting after each cut in the transverse direction T must cross the slit 120. Since the printed substrate 200 typically comes from a roll, it has a natural tendency to be rolled up again. There is therefore the risk that while proceeding in the longitudinal direction L the leading edge 220 of the printed substrate 200 enters the slit 120 rather than it proceeds on the second portion 110b of the working plane 110.
According to a further aspect of the invention, in order to solve this problem the cutting device 100 comprises auxiliary supporting means configured to support the printed substrate 200 in the passage between the first and second portions 110a, 110b of the working plane 110 at the slit 120.
Now referring to
The flap member 400 is movable between a first operating position, wherein it is substantially aligned with the working plane 110 and a second non-operating position, wherein it is arranged inside the slit 120 and does not interfere with the passage of the cutting unit 300. In the illustrated embodiment the flap member 400 is e.g. pivoted at the edge of the portion 110b of the working plane 110, but it will be understood that it could alternatively be pivoted in a completely equivalent way at the edge of the portion 110a of the working plane 110.
It will also be understood that the flap member 400 could also be slidably restrained to the portion 110a or the portion 110b of the working plane 110 and movable e.g. underneath it or retractable into a slit formed therein.
According to an alternative embodiment of the invention, the supporting means may comprise a blowing member 500 arranged below the working plane 110 in the vertical direction V and configured to deliver a jet of air at the slit 120 during the passage of the printed substrate 200 after each transverse cut. The blowing member 500 may e.g. be in the form of a single duct stretching out in the transverse direction T, provided with a dispensing slit 510 stretching out in the same direction through which air jets may be blown. There may be alternatively used a number of blowing members arranged in parallel.
According to a further variant of the invention it is possible to combine the flap member 400 and the blowing member 500. As shown in
The invention has herein been described with reference to preferred embodiments thereof. It is to be understood that there may be further embodiments relating to the same inventive idea, as defined by the scope of protection of the claims set forth below.
Filing Document | Filing Date | Country | Kind |
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PCT/IT2015/000172 | 7/1/2015 | WO | 00 |