The present invention relates to an arrangement for driving a flat substrate. Such an arrangement is mounted in a packaging production machine. The invention also relates to a packaging production machine incorporating a station for feeding a converting unit with a flat substrate and the subsequent unit for converting the substrate. Such a unit for converting the substrate is a diecutting platen press or else a printing platen.
A packaging production machine is designed for the manufacture of boxes, that will be suitable for forming packages, by folding and gluing. In a packaging production machine, production begins with an initial flat substrate, that is to say for example a continuous substrate, such as a virgin web of cardboard. This substrate is unwound continuously, printed by one or more printing units, optionally embossed, and then cut in a diecutting platen press.
The blanks or boxes obtained are then shingled before being stacked in rows in order to form stacks in a delivery and palletizing station for the purpose of being stored or being conveyed out of the production machine.
The packaging production machine comprises several driving arrangements. The substrate must be driven, either in a continuous manner, or in a discontinuous manner, if the converting unit requires a momentary stop in the progression of the substrate during the conversion.
Documents CH-602,462 and CH-618,660 disclose a feeding station for a platen press, comprising a feathering drive leading the substrate around the circumference of an off-center roller mounted between two rotary plates. A pulling member is mounted upstream of the feathering drive that is designed to continually feed this feathering drive. The pulling member comprises a pulling roller over which the web substrate passes and a pressure roller.
An infeed member is mounted downstream of the feathering drive which is designed to feed the platen press. The infeed member comprises a driven bottom roller and a set of pressure belts that can be raised on command so as to cancel out the pulling effect applied to the substrate. The pulling member and the infeed member are provided for driving the flat cardboard.
However, these two members are not suitable for driving substrates that have a fragile surface or a surface that must not be damaged. Such surfaces are particularly attractive for the consumer who buys the product with its final packaging. The packaging manufacturer therefore seeks to promote the product by virtue of the packaging. This means that such modifications to the exposed surface of the substrate must not sustain damage throughout the packaging production process.
A main object of the present invention consists in developing an arrangement for driving a flat substrate. A second object is to produce a driving arrangement specifically for a substrate of which the surface has one or more modifications forming one or more delicate zones. A third object is to associate a driving of a substrate at high speed with a conservation of the integrity of this same substrate. Yet another object is that of creating a packaging production machine comprising a converting unit and a feeding station for feeding the converting unit with a substrate having an arrangement for driving the substrate.
The invention concerns an arrangement for driving a flat substrate along a longitudinal direction. The arrangement is mounted in a packaging production machine. The flat substrate has a surface that has sustained at least one modification. The arrangement comprises:
means for driving the substrate along the longitudinal direction, and
means for bearing this substrate against the driving means, having at least one bearing zone facing toward these driving means, this substrate being able to be engaged between these driving means and the bearing means and driven by these driving means and bearing means.
According to one aspect of the present invention, the arrangement is characterized in that the bearing zone has a transverse position and a transverse dimension, chosen as a function of a transverse position and a transverse dimension of the modification, so as to prevent damaging this modification between these driving means and bearing means.
In the whole of the description, the substrate is defined, as a nonexhaustive example, as being in the form:
of paper, or cardboard, or plastic, such as polyethylene terephthalate (PET), bi-oriented polypropylene (BOPP), or other polymers, or aluminum, or of other materials, or in the form
of flat board, or corrugated cardboard, or else a flexible material, such as polyethylene (PE), or of yet other materials, or in the form
The flat substrate has sustained at least one first earlier process for modifying its surface. The modification on the surface is defined as a nonexhaustive example, as being:
The modification or modifications are localized or repetitive over the whole surface of the substrate. The modification is on only one side of the flat substrate or it is on both sides.
The longitudinal direction is defined by referring to the median axis of the machine of which the direction is determined by that of the driving of the substrate. The transverse direction is defined as being the direction perpendicular to the driving direction of the substrate.
In other words, in order to protect the substrate and its surface, the bearing means present only one or a series of interruptions in the transverse direction. This or these interruptions have one or more positions in the transverse direction corresponding to one or more positions in the transverse direction of the modification or modifications. Furthermore, this or these interruptions have one or more dimensions in the transverse direction corresponding to one or more dimensions of the modification or modifications in the transverse direction.
At the interruption or interruptions, there is no contact between the bearing zone and the substrate. In this manner, the bearing zone is placed beside the modification or modifications. By its positioning at the bearing means, the bearing zone will not crush or damage the modification or modifications. This positioning of the bearing zone is all the more important the higher the speed of the driving means, of the arrangement for driving the substrate and of the whole packaging production machine.
According to another aspect of the present invention, a packaging production machine, comprising a converting unit and a station for feeding the converting unit with a web substrate, is characterized in that it comprises at least one arrangement having one or more of the technical features described below and in the claims. The arrangement or arrangements are installed upstream or downstream of the converting unit and/or upstream or downstream of the feeding station.
The invention will be clearly understood and its various advantages and features will better emerge from the following description of the nonlimiting exemplary embodiment, with reference to the appended schematic drawings in which:
As illustrated in
The packaging production machine (1) has upstream from the feeding station (2), as an example, printing units, means for monitoring the quality and the register, as well as means for embossing or any other means (not shown) for modifying the surface of the web (4).
The feeding station (2) delivers this same web (4) downstream to the platen press (3) at an intermittent speed. The platen press (3) cuts the web (4) and delivers the substrate in the form of blanks (5). The blanks (5) leave the press (3) with the modification (not visible in the figures) on their surface. The direction of travel or of progression (arrow F in
In order to ensure an optimum operation of the press (3), the feeding station (2) may comprise, in order from upstream to downstream:
A third driving arrangement (13) for ejecting or exiting the blanks (5) from the press (3), according to the second embodiment of the invention, is positioned downstream from the platen press (3). The third arrangement (13) for driving the blanks (5), according to the second embodiment of the invention, is substantially similar to the second arrangement (12) for driving the web (4) according to the second embodiment of the invention.
The feathering drive is a main drive roller (9) rotating (arrow R in
The loop control (10) comprises a satellite roller (18) mounted by being placed side-by-side parallel to the main roller (9). The web (4) is engaged between the main roller (9) and this satellite roller (18), and it is maintained there, while being able to be driven. The web (4) forms a path which covers approximately three-quarters of a circumference of the main roller (9) and half a circumference of the satellite roller (18).
The satellite roller (18) is able to oscillate (arrow O in
The frequency of the oscillations (O) of the satellite roller (18) generates variations in the speed of the web (4). The web (4) changes cyclically from a constant speed to a zero speed, and vice versa, from a zero speed to a constant speed. These changes in speed and consequently the frequency of the oscillations (O) are chosen according to the cutting strike speed of the press (3) situated downstream.
The web (4) has a surface that has sustained at least one modification, for example an embossing. The embossing is obtained by an embossing unit positioned in the machine (1) upstream from the infeed station (2). Such an embossing creates bumps at the web surface (4).
According to the first embodiment (see
The first arrangement (11) may advantageously be placed upstream from the converting unit, in the form of the diecutting platen press (3), in a feeding station (2) for this press (3).
The first arrangement (11) first of all comprises means for driving the web (4), along the longitudinal direction (F), preferably able to be formed by the main drive roller (9).
The first arrangement (11) then comprises means (19) for bearing the web (4) against the driving means, i.e. against the main roller (9). In a very advantageous manner, these bearing means (19) may comprise a pressure roller (21). This pressure roller (21) forms a rotary element pivoting (arrow P in
The web (4) is able to be engaged (see
As shown in
A transverse position (arrow Y in
In this manner, the recesses (24) are matched up with the modification of the web (4) and the protrusions (23) pass beside the embossing, i.e. beside the modification of the web (4). By the choice of pressure roller (21), the operator prevents damaging this modification between the pressure roller (21) and the main roller (9). By the appropriate match between the pressure roller (21) and the work done and the modification made upstream, the web (4) will be protected in the course of its driving.
In order to obtain a constant bearing, the bearing means (19) may comprise at least one pressure member (26), in the form of two side cylinders. The pressure member (26) can push (arrow T in
The bearing means (19) may also preferably comprise a structure (27) to which the pressure member (26) can be attached. The bearing means (19) may also preferably comprise two side levers (28). The two levers (28) are located on each side of the pressure roller (21) and may be able to hold the pressure roller (21) by its axis (22) when this pressure roller (21) is in the active position and in operation. The two levers (28) may be able to pivot (arrow U in
The first arrangement (11) may advantageously comprise two side flanges (29). The two flanges (29) may be able to receive the pressure roller (21) when this pressure roller (21) is in the inactive position and is no longer in operation.
When there is a job change, the pressure in the pressure member (26) is released and the pressure roller (21) moves away from the main roller (9). The pressure roller (21) can therefore move from the active position (
The two flanges (29) may be mounted on a transverse ramp (31). The ramp (31) may be moved transversely, in order to be able to enter and exit the pressure roller (21) transversely (arrow M in
The operator will be able to remove the old pressure roller (21) and insert a new pressure roller (21) with different features (Y and D) for the bearing protrusions (23), outside the feeding station (2) and the machine (1). In this manner, the ergonomics of the operation for changing the pressure roller (21) will be greatly improved for the operator.
The second arrangement (12) may advantageously be placed upstream from the converting unit, in the form of the diecutting platen press (3), in a feeding station (2) for this press (3). The third arrangement (13) may advantageously be placed downstream from the converting unit, in the form of the diecutting platen press (3).
The second and third arrangements (12 and 13) comprise first of all means for driving the web (4) and respectively blanks (5) along the longitudinal direction (F), which may preferably comprise a driving roller (32). The roller (32) may be rotatably driven (arrow R in
The second and third arrangements (12 and 13) also comprise means (35) for bearing the web (4) and respectively blanks (5) against the driving means, i.e. against the roller (32). Very advantageously, these bearing means (35) may comprise only one or a series of pressure rollers (36), in this instance being six in number. These rollers (36) form a rotary element pivoting (arrow P in
The web (4) or the blanks (5) are able to be engaged (see
As shown in
A transverse position (arrow Y in
In this manner, the gaps (38) match up with the modification of the web (4) or blanks (5) and the rollers (36) run to the side of the embossing, or to the side of other modifications, i.e. to the side of the modification of the web (4) or blanks (5). By choosing the position and the width of each of the rollers (36), the operator prevents damaging this modification between the rollers (36) and the roller (32). By the appropriate match between the pinch rollers (36) and the job done and the modification made upstream, the web (4) or the blanks (5) will be protected as they are driven.
In order to obtain a constant pressure, the bearing means (35) may comprise at least one pressure member (39) in the form of a cylinder. The pressure member (39) can push (arrow T in
The bearing means (35) may also preferably comprise a structure (41) to which the pressure member (39) can be attached. The bearing means (35) may also preferably comprise two side levers (42). The two levers (42) are located on each side of the roller (36) and may be able to hold the roller (36) by its axis (37). The two levers (42) may be able to pivot downward (arrow U in
During a change of job, the pressure in the pressure member (39) is released and the roller (36) moves away from the roller (32). The roller (36) may thus move from the active position (
In a favorable manner, the roller (36), the structure (41), the two levers (42) and the pressure member (39) may form a bearing subassembly (43) that can be set transversely. To do this, the structure (41) may be able to slide on a transverse ramp (44) so as to adjust the transverse position of the bearing subassembly (43) and thus of the roller (36).
The ramp (44) may be moved transversely, in order to enter and exit transversely (arrow M in
The operator will be able to remove the old roller or rollers (36) and install one or more new rollers (36), with different features for the bearing widths (D), outside the feeding station (2) and outside the machine (1). The operator will be able to set the transverse position (Y) of each of the bearing subassemblies (43) and thus of each of the rollers (36). In this manner, the ergonomics of the operation for changing bearing subassembly (43) will be greatly improved for the operator.
The present invention is not limited to the embodiments described and illustrated. Many modifications can be made without however departing from the context defined by the scope of the set of claims.
Number | Date | Country | Kind |
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08021265 | Dec 2008 | EP | regional |
The present application is a divisional under 37 C.F.R. §1.53(b) of prior U.S. patent application Ser. No. 13/133,420, filed Jun. 8, 2011, which in turn is a U.S.C. §371 National Phase conversion of PCT/EP2009/008072, filed Nov. 12, 2009, which claims priority of European Application No. 08021265.7, filed Dec. 8, 2008. The contents of each of these applications are incorporated in full by reference herein.
Number | Name | Date | Kind |
---|---|---|---|
1648990 | Little | Nov 1927 | A |
4060187 | Grob | Nov 1977 | A |
4244504 | Grob et al. | Jan 1981 | A |
4863086 | Armelin | Sep 1989 | A |
5398604 | Burke et al. | Mar 1995 | A |
5595335 | Borel | Jan 1997 | A |
5727724 | Dowling | Mar 1998 | A |
6533154 | Kitai et al. | Mar 2003 | B2 |
6602176 | Ganneval | Aug 2003 | B1 |
20020113355 | Lange et al. | Aug 2002 | A1 |
20040050895 | Zweifel et al. | Mar 2004 | A1 |
20060175372 | Brost et al. | Aug 2006 | A1 |
20070057005 | Theilacker | Mar 2007 | A1 |
Number | Date | Country |
---|---|---|
605462 | Sep 1978 | CH |
618660 | Dec 1978 | CH |
4340915 | Aug 1994 | DE |
0835836 | Apr 1998 | EP |
1378475 | Jan 2004 | EP |
2816603 | May 2002 | FR |
265343 | Feb 1927 | GB |
1496103 | Dec 1977 | GB |
Entry |
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International Search Report dated May 18, 2010, issued in corresponding international application No. PCT/EP2009/008072. |
Number | Date | Country | |
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20150203315 A1 | Jul 2015 | US |
Number | Date | Country | |
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Parent | 13133420 | US | |
Child | 14672297 | US |