The present invention relates generally to cutting of substrates printed by way of printing machines, such as advertising panels printed by digital printing machines, and in particular to a cutter for cutting printed substrates of a rigid type such as e.g. cardboard panels , PVC foam plates or multilayer flat products.
Known cutters for printed substrates generally comprise a supporting plane adapted to receive a printed substrate, as well as a plurality of cutting units comprising a blade having a substantially circular shape rotatably mourned about an axis parallel to the supporting plane. The cutting units are generally mounted on a cutter so as to make cats along mutual orthogonal directions, in particular along a longitudinal direction parallel to a feeding direction of a substrate, and along a transverse direction perpendicular thereto.
The cutters also generally comprise cylinders suitable to drag the printed substrate along the supporting plane, so that the cuts needed to separate individual images printed on the substrate are obtained by way of relative movements between the substrate and the blades of the cutting units. In order to make outs along the longitudinal direction, one or more longitudinal cutting units are used the blades of which are aligned along the feeding direction of the substrate. These cutting units are generally slidably restrained to a crosspiece of the cutter along suitable rails that allow adjustment of their relative positions as well as their locking on the crosspiece. In order to make cuts along the transverse direction at least one transverse cutting unit is generally provided, the blade of which is aligned along the transverse direction. This cutting unit is transversely movable between the ends of the cutter by way of a suitable motorized slider.
In digital printing processes of substrates made of a rigid material, printed images are separated irons each other by edges suitable to allow the cutting units described above to cut them. The edges are generally identified by special cutting marks, such as e.g. bar codes, that are automatically detectable via sensors, its particular optical sensors, which allow automatic cutting of printed substrates.
Since the width of the edges has a non-negligible size, the cutting operations necessary to cut the images printed from a substrate require to carry out for each edge a first and a second cut spaced according to the size of the edge to eliminate. In order to make a cut e.g. along the transverse direction, when the sensors detect a cutting mark the cutter cylinders are stopped, thus blocking the printed substrate for the execution of a first transverse cut. Subsequently, the cylinders cause the printed substrate to advance along a path the length of which corresponds to the width of the edge, then are stopped again to allow the execution of a second transverse cut.
This sequence of movements and stops of printed substrates results in cutting operations that are considered quite long by the those skilled in the art.
Another problem related to the execution of cuts in printed substrates is that after a cutting operation the edges separated from the images constitute scraps which move together with them and must be removed manually by an operator at the exit from the cutter, which is a time consuming operation.
There is therefore the need to reduce the time required for the cutting of printed substrates its order to increase the productivity of cutters which is an object of the present invention.
It is also an object of the present invention to eliminate cut edges or substrate scraps during cutting operations without manual intervention of an operator.
An idea of solution underlying the present invention is to make a cutter wherein the individual cutting units include a pair of parallel blades mutually spaced at a distance corresponding to the size of the edges present between images printed on a substrate.
It is also an idea of solution underlying the invention to provide a cutter comprising a system for the removal of substrate scraps during cutting operations without the need for manual intervention by an operator. To this aim, the double blade cutting units comprise an backing plane of the blades, which is arranged underneath the supporting plane of the cutter, and a connecting arm which extends diagonally from a frame on which the blades are mounted to the backing plane in a direction opposite to the cutting direction. The connecting arm is arranged between the blades and symmetrically relative thereto and a through opening is formed in the portion of the backing plane comprised between the area intended to contact the blades and the attachment point of the connecting arm. Therefore, the substrate is cut between the blades and the backing plane of the cutting unit and during a cutting operation the relative movement between the printed substrate and the cutting units causes substrate scraps to come into contact with the connecting arm, thereby being deflected diagonally towards the backing plane and then under the supporting surface of the cutter via the through opening formed in the backing plane.
Thanks to this configuration, the edges present between the images printed on the substrate can be cut in a single step by the cutting units and substrate scraps can be separated directly daring cutting operations without the need for manual intervention of an operator, as well as collected in one or more suitable containers arranged under the cutter.
The main advantage offered by the invention is therefore a remarkable reduction of the time needed to perform cutting operations, which considerably increases the productivity of a cutter.
The cutting units intended to perform cuts along the longitudinal direction are preferably arranged at an outlet end of the supporting plane of the cutter, thus allowing removal of substrate scraps without requiring modifications of the supporting plane. The cutting units intended to perform cuts along the transverse direction are preferably arranged at an intermediate position of the supporting plane relative to the feeding direction of the substrate, whereby the supporting plane comprises in such a position respective transverse apertures suitable to allow falling of substrate scraps thereunder.
In order to increase cutting efficiency, the cutting units may advantageously comprise a pair of grooves formed in the backing plane of the blades. In this way, printed substrates to be out are completely crossed by the blades in the direction of their thickness. The grooves serve as guides for the blades, which guides are tailored to ensure the execution of straight cuts.
Further advantages and features of the cutter according to the present invention will become clear to those skilled in the art from the following detailed and non-limiting description of an embodiment thereof with reference to the attached drawings in which:
Referring to
The cutter 10 is provided with a plurality of cutting units, generally indicated with the reference number 50, arranged so as to cut the printed substrate 30 along the edges 32, 33 in two directions that are mutually perpendicular, in particular a longitudinal direction L, parallel to the feeding direction F, and a transverse T, perpendicular to the feeding direction F.
The cutter 10 comprises at least one longitudinal cutting unit 501 adapted to perform cuts of the substrate 30 along the longitudinal direction L and at least one transverse cutting unit 502 adapted to perform cuts of the substrate 30 along the transverse direction T. The longitudinal and transverse cutting units 501, 502 have the same structure, the only difference being their orientation with respect to the cutter 10 in order to allow cuts of the substrate 30 along perpendicular directions.
In the illustrated embodiment, the cutter 10 comprises four longitudinal cutting units 501 and a single transverse cutting unit 502.
The longitudinal cutting units 501 are slidably restrained to a crosspiece 11 of the cutter 10 along suitable rails (not shown) which allow adjustment of their relative position and their locking thereto e.g. by way of clamps.
The transverse cutting unit 502 is instead restrained to a motorized slider 12 of the cutter 10 movable in the transverse direction T between its ends along a crosspiece 13.
According to the present invention, the cutting units 50 are provided with a pair of blades 51 parallel and mutually spaced at a distance corresponding to the width of the edges 32, 33 separating the images 31 printed on the substrate 30s for example through a spacer 52, thus allowing to separate these edges 32, 33 from the images 31 in a single step and to achieve a high cutting speed. In particular, the time a cutting operation takes is more than halved with respect to the cutting time of a traditional cutter, because, unlike known cutters a first and a second cut for the removal of the edges 32, 33 are no longer required and it is no longer necessary to move and stop the substrate between subsequent cuts for this purpose.
The cutter 10 further comprises a system suitable to allow removal of substrate scraps, i.e. the edges 32, 33 cut by the blades 51, during cutting operation without the need for manual intervention by an operator.
With particular reference to
The connecting arm 54 is parallel to the blades 51 and is arranged on a plane P parallel to the planes A, B on which the blades 51 lie.
The plane P is preferably arranged in a symmetrical position with respect to the planes A and B, i.e. symmetrically between the blades 51.
A through opening 56 is formed in the portion of the backing plane 53 comprised between die area arranged underneath the blades 51 and the area wherein the connecting arm 54 is fixed, whereby due to the relative movement between the printed substrate 30 and the cutting units 50 in the cutting direction, an edge or substrate scrap cut by the blades 51, e.g. a longitudinal edge 33, comes in contact with the connecting arm 54 and is thereby deflected diagonally towards the backing plane 53 crossing the through opening 56 and falling under the supporting plane 20 of the cutter 10, where it can e.g. be collected into a container (not shown).
The longitudinal cutting units 501 are preferably arranged at an outlet end of the supporting plane 20, whereby substrate scraps fall below it at the outlet 31 end of the supporting plane 30 of the cutter 10.
The transverse cutting unit 502 is instead preferably arranged at an intermediate position of the supporting plane 20 with respect to the feeding direction F. For this purpose the supporting plane 20 includes in this position a transverse aperture 21 adapted to allow removal of substrate scraps generated by transverse cuts.
It will be understood that this configuration of the cutter 10 is not essential in the invention, being it also possible to arrange the transverse cutting unit 502 at the outlet end of the supporting plane 20 and the longitudinal cutting unit 501 arranged at an intermediate position in correspondence to the transverse aperture 21. However, this configuration is preferred, because it allows a better access to the longitudinal cutting unit or units 501, facilitating their assembling and position adjustment along the rails of the crosspiece 11.
It will be also understood that the provision of the transverse aperture 21 in the supporting plane 20 is not essential in the invention. The supporting plane 20 in fact may as well be divided into two parts whose facing ends are arranged in correspondence with the cutting path of the transverse cutting unit 502 and suitably spaced apart to define an opening allowing passage of substrate scrap under the supporting plane of the cutter 10.
According to a former aspect of the invention, in order to facilitate falling of substrate scraps under the supporting plane 20, the connecting arm 54 may advantageously comprise a tail portion 57 which extends below the backing plane 53 from the fixing point of the connecting arm 54, thus forming an extension thereof.
As shown in
As shown in
Still in the aim to increase the cutting effectiveness, the blades 51 are preferably keyed on a same shaft (not shown) driven into rotation by a motor (not shows) of the cutter 10. Cutting is therefore performed not simply by way of a relative movement between the printed substrate 30 and the cutting units 50, but also by means of the rotation imparted by the motor to the blades 51, which allows to cut a wide range of materials from the softer ones, such as paperboard, to the harder ones, such as multi-layer products.
The alignment between the cutting units 50 and the edges 32, 33 present between the images 31 printed on the supports 30 may be performed manually, but is preferably carried out automatically by using cutting marks such as e.g. bar codes that are typically printed along the edges 32, 33.
For this purpose, the cutter 10 may include a plurality of optical sensors suitable for detecting the cutting marks indicative of the position of the edges 32, 33 and configured to allow automatic alignment between the cutting units 50 and the edges 32, 33 through an appropriate control program. In the embodiment shown in
The embodiment of the invention herein described and illustrated is just an example susceptible of numerous variants. For example, the cutter may comprise more than one transverse cutting unit 502 and correspondingly more than one transverse openings to allow discharge of substrate scraps generated by transverse cuts. Moreover, in order to adapt the cutting units 50 to various types of printed substrates, the distance between their blades 51 and the respective backing planes 53 may be adjustable, for example by way of screw registers or slots e.g. arranged where the connecting arm 54 is fixed to the backing plane 53.
Number | Date | Country | Kind |
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MI2012A000704 | Apr 2012 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2013/053239 | 4/24/2013 | WO | 00 |