IT201900009663A1 - MACHINE FOR THE PROCESSING OF METALLIC SLICES IN THE FIELD OF THE PRODUCTION OF JARS AND RELATED METHOD. - Google Patents

Description

DESCRIPTION

Attached to a patent application for INDUSTRIAL INVENTION having the title

“MACHINE FOR THE PROCESSING OF METAL SHEETS

IN THE FIELD OF PRODUCTION OF JARS AND RELATED

METHOD"

The present invention relates to an automatic machine configured to automatically carry out a process for processing metal segments suitable for making the respective side walls of cans, with which machine an improvement in the production flexibility of the cans is obtained by means of a digital printing station of the cans. pieces integrated in the machine upstream of a calendering station of the same pieces once they have come out of the digital printing station. The present invention also relates to this manufacturing process. In the field of the production of cans with metal side walls, the side wall of the can is currently obtained by cutting a respective sector of metal sheet so as to obtain a segment which is subsequently deformed.

In the event that it is necessary to impress a desired graphic on the side wall of the can, for example a certain coloring of the side wall, currently this graphic is printed before cutting the respective sector of sheet metal.

Currently, can manufacturers receive the sheet already printed in a condition such that, before the cutting phase of the sheet metal sectors, the desired graphics are already printed on each sector.

This obliges can manufacturers to have a sufficient quantity of sheet metal available for each graphic, to meet possible market demands. This leads to considerable warehouse costs related to the graphic differences between the types of cans that may be required by the market.

A method or process for processing segments suitable for making the respective side walls of cans in accordance with the present description and / or in accordance with any of the attached method claims allows to reduce the warehouse costs related to the graphic differences between the types of jars that may be required by the market.

A machine in accordance with the present description and / or in accordance with any of the attached machine claims is configured to automatically carry out a method in accordance with the present description and / or in accordance with any of the attached method claims.

The characteristics of a machine and of a method according to the present description will be clarified by the following detailed description relating to respective exemplary embodiments of said machine and method.

The detailed description below refers to the attached drawing tables, in which:

Figure 1 is a view of a possible exemplary embodiment of a machine according to the present description;

Figure 2 is a schematic detail view of a part of the embodiment of Figure 1;

- Figures 3A to 3D show the part of Figure 2 in respective successive instants of a possible embodiment of a processing method in accordance with the present description;

- figure 4 illustrates a characteristic of a phase of the method subsequent to the instants of figures 3A-3D.

The attached drawing tables refer to an exemplary embodiment of a method according to the present description. In the following, by method is meant this exemplary embodiment of the method.

The method could alternatively be defined as a procedure. The attached drawing tables refer to an exemplary embodiment of a machine according to the present description. In the following, the term machine refers to this exemplary embodiment of the machine. The machine is indicated with 1 in figure 1.

The machine is configured to perform the method automatically.

The method is for the processing of pieces suitable for making the respective side walls of cans. This means that each piece will be destined to make the side wall of a respective can. The segments can be, for example, metallic. This means that it could be that each piece is at least partially or totally metallic.

Each piece could be a band or a band or a band.

The machine 1 comprises a magazine 11. The magazine 11 is configured to carry out, for each piece, a respective step of storing the piece. The magazine 11 is configured to stack the stored segments, so as to define a stack of stored segments. The pile is indicated in the figures with P. In figures 2, 3A, 3B and 3C a first section S1 is indicated. In figure 3D a second section S2 is indicated. Figure 4 indicates this first section S1, this second section S2, and a third section S3.

The magazine 11 comprises vertical support guides 111 to define the stack P.

The method comprises, for each piece, the respective step of storing the piece.

The machine 1 comprises a digital printing station 12. The printing station 12 is configured to perform, for each stored segment, a respective digital printing step of a desired graphic on the segment. The printing station 12 in figures 2, 3A, 3B, 3C, 3D and 4 is schematized by means of dashed blocks.

The method comprises, for each stored segment, the respective digital printing step of the desired graphics on the segment. By stored piece we mean a piece that has already been subjected to the storage step.

In Figure 4 each of the first section S1, second section S2 and third section S3 can be considered as shown during the respective printing step. Although they are shown during the printing phase, each of the first section S1, second section S2, and third section S3 can be considered as a stored section, as it was previously stored in the warehouse 11.

The printing station 12 comprises a digital printing system 121. The digital printing system 121 is configured to carry out, on each stored segment, a respective step for impressing said desired graphic.

For each stored segment, the respective printing step comprises the respective step for impressing said desired graphic on the segment.

The printing station 12 comprises a transport conveyor 122. The printing station 12 is configured so that the conveyor can carry out, for each stored piece, a respective step of transporting the piece through the printing system 121, so that the printing system printing 121 can carry out the respective printing step. For each stored segment, the respective printing step comprises the respective transport step of the blank. For each piece stored, the respective transport step is carried out during the respective step of impression of the desired graphic on the same piece.

The printing station 12 could also comprise a drying system 123, to carry out a drying step of the printed or imprinted graphics.

The transport conveyor 122 is configured so that, for each stored segment, the respective transport step is carried out by generating a transport movement of the segment. This transport movement comprises at least one predominantly translational component along a transport direction. This transport direction is represented by the direction of the arrow X4 in figure 4.

For each piece stored, the respective transport step is carried out by generating the respective transport movement of the piece. In Figure 4 each of the first section S1, second section S2 and third section S3 can be considered as shown simultaneously during the respective impression phase and the respective transport phase.

The machine comprises a calendering station 13. The calendering station 13 is configured to carry out, for each molded piece, a respective calendering step. With printed piece we mean a piece that has already been subjected to the printing phase.

The method comprises, for each molded piece, the respective step of calendering the piece.

The machine comprises a dispensing system 14. The dispensing system 14 is configured to carry out, for each stored piece, a respective step of dispensing the piece from the magazine 11 to the printing station 12. The dispensing system 14 is schematically shown in detail in figures 2 to 3D.

The method comprises, for each stored piece, the respective step of dispensing the piece from the magazine 11 to the printing station 12.

The dispensing system 14 comprises a pick-up element 141. The dispensing system 14 is configured so that the pick-up element 141 can carry out, for each stored segment and by means of a movement of said pick-up element 141, a respective phase of picking up the product. piece. The movement of this pick-up element 141 comprises at least one translational component prevalent along a pick-up direction. The pick-up direction is represented by the direction of the arrow X1 of Figure 3A. This pick-up direction could be transversal and / or orthogonal to the transport direction.

The withdrawal element 141 could include, for example, one or more suction cups.

For each stored segment, the respective dispensing step comprises the respective withdrawal step of the segment.

Figures 2 and 3A refer to an instant of the withdrawal step of the first piece S1. The direction of the arrow X1 indicates the direction in which the pick-up element 141 moves after contacting the piece.

Figure 3B refers to a final instant of the withdrawal phase. In this final instant of the step of picking up the first piece S1, the first piece S1 is above a horizontal support guide 112. This horizontal guide is located for example under the vertical support guides 111. The magazine 11 comprises the horizontal guide 112.

The delivery system 14 comprises a thrust element 142. The delivery system 14 is configured so that the thrust element 142 can carry out, for each piece taken up and by means of a movement of the thrust element 142, a respective thrust phase of the piece taken. During this respective pushing phase, the taken length is pushed out of the magazine 11. The movement of this pushing element 142 comprises at least one translational component prevalent along a pushing direction. This thrust direction is represented by the direction of the arrow X2 of Figure 3B. This pushing direction could coincide with the transport direction. This thrust direction is transverse and / or orthogonal to the drawing direction.

Withdrawn segment is meant a segment that has already been subjected to the respective withdrawal phase.

The thrust element 142 could include, for example, a pusher.

For each stored segment, the method comprises the respective pushing step of the removed segment.

For each piece stored, the respective thrust phase is carried out by means of the aforementioned movement of the thrust element.

Figure 3B shows an initial instant of the thrusting phase of the first length S1. Figure 3C shows a final instant of the thrusting phase of the first length S1.

In figure 3C the arrow X2 'indicates a direction of the return movement of the thrust element 142.

The machine 1 comprises a transfer conveyor 15. The machine 1 is configured so that the transfer conveyor 15 can carry out, for each piece pushed out of the magazine 11, a respective phase of receiving the piece.

The method comprises, for each piece pushed out of the magazine 11, the respective step of receiving the piece by the transfer conveyor 15.

The instant to which Figure 3C refers is both the final instant of the thrust phase and an instant during the phase of receipt of the first section S1 by the transfer conveyor 15.

The machine 1 is configured so that the transfer conveyor 15 can carry out, for each piece received, a respective step of transferring the blank from the magazine 11 to the printing station 12. During this respective transfer step, the blank is transferred from the magazine 11 to the printing station. transport conveyor 122.

The method comprises, for each piece received by the transfer conveyor 15, the respective step of transferring the piece from the magazine 11 to the printing station 12.

The instant to which the 3D figure refers is an instant during the transfer phase of the first piece S1 from the warehouse 11 to the transport conveyor 122.

The transfer conveyor 15 is configured so that, for each stored segment, the respective transfer step is carried out by generating a transfer movement of the segment. This transfer movement comprises at least one predominant translational component along a transfer direction. This transfer direction is represented by the direction of the arrow X3 of Figures 3C and 3D. This transfer direction may coincide with the transport direction. This transfer direction could coincide with the thrust direction.

For each piece stored, the respective transfer step is carried out by generating the respective transfer movement of the piece.

The machine 1 is configured so that, for each stored piece, the trajectory traveled by the picking element 141 during the movement of the picking element 141 intersects the path traveled by the thrust element 142 during the movement of the thrust element 142.

In the method, for each piece stored, the trajectory traveled by the withdrawal element 141 during the movement of the withdrawal element 141 intersects the trajectory traveled by the thrust element 142 during the movement of the thrust element 142.

In this way, the dispensing system 14 is able to operate quickly, to increase productivity.

The machine 1 comprises a control system. The control system is configured to automatically control at least said transfer conveyor 15 and transport conveyor 122, so that, for each stored piece, the average speed of the transport movement along the transport direction is lower than the average speed of the transport movement. transfer along the transfer direction.

The method comprises, for each stored segment, a respective step of automatic control of the respective transfer step and of the respective transport step. This respective control step is carried out in such a way that the average speed of the transport movement along the transport direction is lower than the average speed of the transfer movement along the transfer direction.

It should be considered that the average speed of the transport movement along the transport direction is limited by the characteristics of the printing station 12, and that, considering that the trajectories of the thrust element 142 and of the pick-up element 141 intersect, the pick-up element 141 can start picking up the next segment only once sufficient space has been freed, along the thrust direction, for the passage of the pick-up element 141.

Therefore, having considered the removal of a generic segment, such as the first segment S1 of Figures 3A-3D, for example, before the withdrawal element 141 can carry out the withdrawal phase of the subsequent segment, such as the second segment S2 could be shown in Figure 3D, the first section S1 must have cleared a sufficient area along the thrust direction X2 to allow the withdrawal element 141 to pass through again.

The difference between the average speed of the transfer movement and the average speed of the transport movement means that the transfer conveyor can act as an accelerator for the exit of the first piece S1 from the magazine, so as to reduce the stopping time of the element of pick-up 141 before starting the new movement to pick up the next piece S2.

This makes it possible to have a smaller pitch between the successive segments, during the printing phase, in order to increase the productivity of the method and / or of the machine. The step between the successive segments is indicated with d in figure 4.

The pushing direction may coincide with the transport direction and / or the transfer direction.

The control system is configured to automatically control at least said thrust member 142 and transfer conveyor 15 so that, for each stored length, the average speed of movement of thrust member 142 along the thrust direction is less than the average speed of the transfer movement of the blank along the transfer direction.

The method comprises, for each stored length, a respective step of automatic control of the respective transfer step and of the respective pushing step. This respective control step is carried out so that, for each stored piece, the average speed of the movement of the thrust element 142 along the thrust direction is lower than the average speed of the transfer movement of the piece along the transfer direction.

In this way the transfer conveyor 122 produces an acceleration effect of the exit of each piece from the warehouse, to first free up enough space for the beginning of the withdrawal of the next piece.

Each of the transport conveyor 122 and transfer conveyor 15 could be a conveyor belt. Each of the transport conveyor 122 and transfer conveyor 15 could be a magnetic conveyor belt.

A can manufacturing process according to the present description comprises such a method.

The machine 1, being configured to carry out the method, is a machine for the processing of the pieces as part of the can production process.

The machine 1, by means of the method it is configured to carry out, allows to carry out both the printing step of the pieces and the calendering step with the same machine, after the sheet sectors corresponding to the pieces have already been cut. This allows you to decide from time to time, based on the needs of the market, the graphics to be printed during the printing phase, reducing warehouse costs. The machine 1, by means of the method it is configured to carry out, is characterized by an excellent productivity thanks to the transfer conveyor which functions as an accelerator belt to accelerate the exit of the blanks from the magazine, so as to reduce the pitch between the blanks in the station. of printing.

Claims (12)

CLAIMS 1. Machine (1) for processing metal pieces (S1, S2) suitable for making respective side walls of cans, comprising: - a magazine (11) for carrying out, for each piece (S1; S2), a respective storage step of the piece (S1; S2); - a digital printing station (12), for carrying out, for each stored piece (S1; S2), a respective digital printing step of a desired graphic on the piece; - a calendering station (13), to carry out, for each molded piece (S1; S2), a respective calendering step. 2. Machine (1) according to claim 1, comprising a delivery system (14) for carrying out, for each stored piece, a respective phase of delivery of the piece (S1; S2) from the magazine (11) to the printing station ( 12); wherein the printing station (12) comprises: - a digital printing system (121) for carrying out, on each stored segment (S1; S2), a respective step of printing said desired graphic; - a transport conveyor (122) to carry out, for each stored piece (S1; S2), a respective transport phase of the piece (S1; S2) through the printing system (121), so that the printing system ( 121) can carry out the respective impression phase; wherein the delivery system (14) comprises: - a pick-up element (141) to carry out, for each stored piece (S1; S2) and by means of a movement of the pick-up element (141), a respective pick-up step of the piece (S1; S2), said movement of the pick-up element (141) comprising at least one translational component prevalent along a pick-up direction; - a thrust element (142) for carrying out, for each piece taken up (S1; S2) and by means of a movement of the thrust element (142), a respective pushing phase of the piece taken up (S1; S2), during which the removed segment (S1; S2) is pushed out of the magazine (11), said movement of the thrust element (142) comprising at least one translational component prevalent along a thrust direction which is transverse to the withdrawal direction; in which the machine (1) is configured so that, for each stored segment (S1; S2), the trajectory traveled by the pick-up element (141) during the movement of the pick-up element (141) intersects the path traveled by the element thrust (142) during movement of the thrust member (142); in which the machine comprises a transfer conveyor (15) to carry out, for each piece (S1; S2) pushed out of the magazine (11), a respective phase of receiving the piece (S1; S2) and, for each piece received ( S1; S2), a respective transfer step of the piece (S1; S2) from the warehouse (11) to the transport conveyor (122). 3. Machine according to claim 2, wherein: - said transfer conveyor (15) is configured so that, for each stored piece (S1; S2), the respective transfer phase is carried out by generating a transfer movement of the piece, said transfer movement comprising at least one predominant component translating along a direction transfer, said transfer direction being transverse to said pick-up direction; - said transport conveyor (122) is configured so that, for each stored segment (S1; S2), the respective transport phase is carried out by generating a transport movement of the segment (S1; S2), said transport movement comprising at least one component mainly translating along a transport direction coinciding with said transfer direction; - the machine (1) comprises a control system configured to automatically control at least said transfer conveyor (15) and transport conveyor (122), so that, for each stored piece (S1; S2), the average speed of the movement transport along the transport direction is less than the average speed of the transfer movement along the transfer direction. 4. Machine (1) according to claim 3, wherein: - the thrust direction coincides with said transfer direction; - the control system is configured to automatically control at least said thrust element (142) and transfer conveyor (15) so that, for each stored length (S1; S2), the average speed of the movement of the thrust element ( 142) along the pushing direction is less than the average speed of the transfer movement of the piece along the transfer direction. 5. Machine according to claim 3 or 4, in which said transfer conveyor (15) and transport conveyor (122) are mechanically distinct from each other. Machine according to claim 3 or 4 or 5, wherein said transfer conveyor (122) comprises a magnetic tape. 7. Method (1) for processing metal pieces (S1, S2) suitable for making respective side walls of cans, comprising: - for each piece, a respective step of storing the piece (S1; S2) in a warehouse (11); - for each stored segment (S1; S2), a respective digital printing step of a desired graphic on the segment, said printing step being carried out in a printing station (12); - for each printed piece, a respective step of calendering of the piece. Method according to claim 7, comprising, for each stored segment (S1; S2), a respective delivery step of the blank (S1; S2) from the magazine (11) to the printing station (12); in which, for each stored piece (S1; S2), the respective printing phase includes: - a step for impressing said desired graphics on the segment (S1; S2); - a respective transport step of the segment (S1; S2), said transport step being carried out during the respective impression step of the same segment; in which, for each stored segment (S1; S2), the respective dispensing phase includes: - a respective step for withdrawing the piece (S1; S2), said respective withdrawal step being carried out by means of a movement of a withdrawal element (141), said movement of the withdrawal element (141) comprising at least one translational component prevalent along a pick-up direction; - a respective pushing phase of the picked up piece (S1; S2), during which the picked up piece is pushed out of the magazine (11), said respective pushing step being carried out by means of a movement of a pushing element (142), called movement of the thrust element (142) comprising at least one translational component prevalent along a thrust direction which is transverse to the pick-up direction; in which, for each stored length (S1; S2), the trajectory traveled by the pick-up element (141) during the movement of the pick-up element (141) intersects the path traveled by the thrust element (142) during the movement the thrust element (142); wherein the method comprises, for each piece (S1; S2) pushed out of the magazine (11), a respective phase of receiving the piece (S1; S2) by a transfer conveyor (15); in which the method comprises, for each piece received (S1; S2) by the transfer conveyor (15), a respective step of transferring the piece (S1; S2) from the magazine (11) to the printing station (12), said transfer step being carried out by the transfer conveyor (15). Method according to claim 8, wherein, for each stored length (S1; S2): - the respective transfer step is carried out by generating a transfer movement of the piece, said transfer movement comprising at least one predominant component translating along a transfer direction, said transfer direction being transverse to said pick-up direction; - the respective transport phase is carried out by generating a transport movement of the segment (S1; S2), said transport movement comprising at least one predominant translational component along a transport direction coinciding with said transfer direction; in which the method comprises for each stored segment (S1; S2), a respective automatic control step of the respective transfer step and of the respective transport step, said respective control step being carried out in such a way that, for each stored segment (S1 ; S2), the average speed of the conveying motion along the conveying direction is less than the average velocity of the conveying motion along the conveying direction. Method (1) according to claim 9, wherein: - the thrust direction coincides with said transfer direction; - the method includes, for each stored segment (S1; S2), a respective automatic control step of the respective transfer step and of the respective pushing step, so that, for each stored segment (S1; S2), the average speed movement of the pushing element (142) along the pushing direction is less than the average speed of the transfer movement of the stub along the transferring direction. 11. Method according to claim 9 or 10, in which said transfer conveyor (15) and transport conveyor (122) are mechanically distinct from each other. A can manufacturing process comprising a method according to one or more of claims 7 to 11.