Sheet orientation device, machine for processing a sheet, and method for orienting a sheet

Abstract

The invention relates to a sheet alignment device (5) for a machine for the processing of sheets (B) consisting of a thin, flat material such as paper, cardboard or film, with a feed section, at least one sensor (30, 32) for determining the position and/or alignment of the sheet (B) and also at least two alignment modules (10), each having an alignment roller (12), to which a drive device (14) is assigned in each case, whereby there is assigned to each alignment module (10) a swivel device (16), with which the alignment roller (10) can be swivelled around a swivel axis (A) perpendicular to the feed section. The invention relates also to a machine for the processing of sheets (B) consisting of a thin, flat material such as paper, cardboard or film, whereby a sheet alignment device (5) of the aforementioned type is provided. The invention relates finally to a method for the aligning of a sheet (B) consisting of thin, flat material such as paper, cardboard or film by means of the following steps: the alignment of the sheet (B) is determined, the sheet (B) is speeded up, turned and/or displaced laterally by means of at least two alignment rollers (12), controllable with regard to circumferential speed and alignment, on a feed section.

Claims

1. A sheet alignment device for processing of sheets, the sheet alignment device comprising: a feed section, at least one sensor for determining a position and/or an alignment of a sheet, at least two alignment modules, a first alignment module of the at least two alignment modules having a first alignment roller, a first drive device, and a first swivel device, the first alignment roller being driven by the first drive device, a second alignment module of the at least two alignment modules having a second alignment roller, a second drive device, and a second swivel device, the second alignment roller being driven by the second drive device, each of the first swivel device and the second swivel device swiveling the first alignment roller and the second alignment roller, respectively, around respective swivel axes perpendicular to a plane of the sheet alignment device, and a control system configured to: calculate a skew amount and a misalignment amount based on the position and the alignment of the sheet; and based on the control system calculating that the skew amount indicates the sheet is not skewed and the misalignment amount indicates the sheet is misaligned laterally, control the first drive device to drive the first alignment roller to a same speed as the second drive device drives the second alignment roller, and control the first swivel device and the second swivel device to swivel the first alignment roller and the second alignment roller to a same adjustment about the respective swivel axes, wherein: the first alignment roller and the second alignment roller cooperate respectively with a first counter-roller and a second counter-roller, each of the first counter-roller and the second counter-roller corresponds to a first pressure module and a second pressure module, respectively, to control a pressure force that the first counter-roller and the second counter-roller press against the first alignment roller and the second alignment roller, respectively, and the control system is further configured to, when a front edge of the sheet approaches a gap between the first alignment roller and the second alignment roller and the first counter-roller and the second counter-roller, control the first pressure module and the second pressure module to move the first counter-roller and the second counter-roller away from the first alignment roller and the second alignment roller, so that the sheet can be introduced into the gap without the front edge of the sheet being slowed down.

2. The sheet alignment device according to claim 1, wherein the at least one sensor includes two position sensors upstream of the at least two alignment modules, the two position sensors detecting a front edge of the sheet moved along the feed section.

3. The sheet alignment device according to claim 1, wherein the at least one sensor comprises an alignment sensor, with which a side edge and/or the alignment of the sheet can be detected.

4. The sheet alignment device according to claim 1, wherein each of the first pressure module and the second pressure module has a pneumatic cylinder, an eccentric, an electric motor or a solenoid.

5. A machine for the processing of the sheets, the machine comprising: a sheet alignment device as claimed in claim 1.

6. The machine according to claim 5, wherein the sheet is aligned to a substrate, the sheet and the substrate are brought together, and the sheet and the substrate are affixed together.

7. The machine according to claim 5, wherein the sheets have a thickness of 0.1 to 1.2 mm.

8. The machine according to claim 5, wherein the sheets have a grammage of 90 to 500 g/m2.

9. The machine according to claim 5, wherein the sheets have a size with a width of 400 to 1,650 mm and a length of 400 to 2,050 mm.

10. A method for aligning a sheet using a sheet alignment device as claimed in claim 1, the method comprising: determining the alignment of the sheet, and speeding up, turning, and/or displacing laterally the sheet by the first alignment roller and the second alignment roller, controllable with regard to circumferential speed and alignment, on the feed section.

11. The method according to claim 10, wherein the sheet is synchronized with a substrate.

12. The sheet alignment device of claim 1, wherein the control system is further configured to, when the skew amount indicates the sheet is not skewed and when the misalignment amount indicates the sheet is misaligned laterally: when the front edge of the sheet enters the gap between the first alignment roller and the second alignment roller and the first and second counter-rollers, control the first swivel device and the second swivel device to align the first alignment roller and the second alignment roller in a transport direction of the sheet and, only thereupon, control the first swivel device and the second swivel device to swivel the first alignment roller and the second alignment roller to the same adjustment about the respective swivel axes for a time; and before a back edge of the sheet leaves the first alignment roller and the second alignment roller, control the first swivel device and the second swivel device to align the first alignment roller and the second alignment roller in the transport direction of the sheet.

13. The sheet alignment device of claim 1, wherein the control system is further configured to: when the skew amount indicates the sheet is skewed and when the misalignment amount indicates the sheet is properly aligned laterally, control the first drive device to drive the first alignment roller at a higher speed than the second drive device drives the second alignment roller; and when the skew amount indicates the sheet is skewed and when the misalignment amount indicates the sheet is misaligned laterally, control the first drive device to drive the first alignment roller at the higher speed than the second drive device drives the second alignment roller, and control the first swivel device and the second swivel device to swivel the first alignment roller and the second alignment roller to the same adjustment about the respective swivel axes.

14. The sheet alignment device of claim 13, wherein the control system is further configured to, when the skew amount indicates the sheet is skewed and when the misalignment amount indicates the sheet is properly aligned laterally: when the front edge of the sheet enters the gap between the first alignment roller and the second alignment roller and the first and second counter-rollers, control the first drive device and the second drive device to drive the first alignment roller and the second alignment roller at the same speed; when the sheet has been grasped by the at least two alignment modules, control the first drive device to drive the first alignment roller to the higher speed; and when the sheet leaves the first alignment roller and the second alignment roller, control the first drive device and the second drive device to drive the first alignment roller and the first alignment roller at the same speed.

15. The sheet alignment device of claim 1, wherein the control system is further configured to control speeds and alignments of the first and second alignment rollers based on whether: a front edge of the sheet has entered the gap between the first alignment roller and the second alignment roller and the first and second counter-rollers; the sheet has been grasped by the at least two alignment modules; and a back edge of the sheet has left the first alignment roller and the second alignment roller.

16. The sheet alignment device of claim 15, wherein the control system is configured to control the first swivel device and the second swivel device to swivel the first alignment roller and the second alignment roller to the same adjustment for a time when the front edge of the sheet has entered the gap.

17. The sheet alignment device of claim 15, wherein, when the skew amount indicates the sheet is skewed and when the misalignment amount indicates the sheet is properly aligned laterally, the control system is configured to: control the first drive device to drive the first alignment roller to a same speed as the second drive device drives the second alignment roller when the front edge of the sheet enters the gap; and control the first drive device to drive the first alignment roller at a higher speed when the sheet has been grasped.

18. A sheet alignment device for processing of sheets, the sheet alignment device comprising: a feed section, at least one sensor for determining a position and/or an alignment of a sheet, at least two alignment modules, a first alignment module of the at least two alignment modules having a first alignment roller, a first drive device, and a first swivel device, the first alignment roller being driven by the first drive device, a second alignment module of the at least two alignment modules having a second alignment roller, a second drive device, and a second swivel device, the second alignment roller being driven by the second drive device, each of the first swivel device and the second swivel device swiveling the first alignment roller and the second alignment roller, respectively, around respective swivel axes perpendicular to a plane of the sheet alignment device, and a control system configured to: calculate a skew amount and a misalignment amount based on the position and the alignment of the sheet; based on the control system calculating that the skew amount indicates the sheet is not skewed and the misalignment amount indicates the sheet is misaligned laterally, control the first drive device to drive the first alignment roller to a same speed as the second drive device drives the second alignment roller, and control the first swivel device and the second swivel device to swivel the first alignment roller and the second alignment roller to a same adjustment about the respective swivel axes; and when the skew amount indicates the sheet is not skewed and when the misalignment amount indicates the sheet is misaligned laterally: when a front edge of the sheet enters a gap between the first alignment roller and the second alignment roller and corresponding counter-rollers, control the first swivel device and the second swivel device to align the first alignment roller and the second alignment roller in a transport direction of the sheet and, only thereupon, control the first swivel device and the second swivel device to swivel the first alignment roller and the second alignment roller to the same adjustment about the respective swivel axes for a time; and before a back edge of the sheet leaves the first alignment roller and the second alignment roller, control the first swivel device and the second swivel device to align the first alignment roller and the second alignment roller in the transport direction of the sheet.

19. A sheet alignment device for processing of sheets, the sheet alignment device comprising: a feed section, at least one sensor for determining a position and/or an alignment of a sheet, at least two alignment modules, a first alignment module of the at least two alignment modules having a first alignment roller, a first drive device, and a first swivel device, the first alignment roller being driven by the first drive device, a second alignment module of the at least two alignment modules having a second alignment roller, a second drive device, and a second swivel device, the second alignment roller being driven by the second drive device, each of the first swivel device and the second swivel device swiveling the first alignment roller and the second alignment roller, respectively, around respective swivel axes perpendicular to a plane of the sheet alignment device, and a control system configured to: calculate a skew amount and a misalignment amount based on the position and the alignment of the sheet; based on the control system calculating that the skew amount indicates the sheet is not skewed and the misalignment amount indicates the sheet is misaligned laterally, control the first drive device to drive the first alignment roller to a same speed as the second drive device drives the second alignment roller, and control the first swivel device and the second swivel device to swivel the first alignment roller and the second alignment roller to a same adjustment about the respective swivel axes; and control speeds and alignments of the first and second alignment rollers based on whether: a front edge of the sheet has entered a gap between the first alignment roller and the second alignment roller and corresponding counter-rollers; the sheet has been grasped by the at least two alignment modules; and a back edge of the sheet has left the first alignment roller and the second alignment roller, wherein, when the skew amount indicates the sheet is skewed and when the misalignment amount indicates the sheet is properly aligned laterally, the control system is configured to: control the first drive device to drive the first alignment roller to a same speed as the second drive device drives the second alignment roller when the front edge of the sheet enters the gap; and control the first drive device to drive the first alignment roller at a higher speed when the sheet has been grasped.

20. The sheet alignment device of claim 19, wherein the control system is configured to control corresponding pressure modules to move the corresponding counter-rollers away from the first alignment roller and the second alignment roller so that the sheet can be introduced into the gap without the front edge of the sheet being slowed down.

Description

(1) The invention is described below with the help of one embodiment, which is represented in the appended drawings, where the following are shown:

(2) FIG. 1 a machine according to the invention in a perspective view;

(3) FIG. 2 in a schematic top view an alignment module, which is used in a sheet alignment device integrated into the machine of FIG. 1;

(4) FIG. 3 a schematic section through the alignment module of FIG. 2, which cooperates with a counter-roller;

(5) FIG. 4 a schematic top view of the feed section provided with two alignment modules;

(6) FIG. 5 schematically a first example of a correction of the alignment of a sheet, which is achieved with the sheet alignment device according to the invention;

(7) FIG. 6 a second example of a correction; and

(8) FIG. 7 a third example of a correction.

(9) FIG. 1 shows a machine 1 for the processing of sheets consisting of a thin, flat material such as paper, cardboard or film. The sheets are staged in the form of a stack 2, from where they are supplied to a feed section 4 by means of a sheet feeder 3. A sheet B can be seen here on the feed section 4.

(10) Integrated into the feed section 4 is a sheet alignment device 5, by means of which the alignment of the sheets B supplied via the feed section 4 can be corrected. The sheets B are then brought together with a substrate S, in order for example to be stuck or laminated together. The substrate sheets S are removed from a stack 6.

(11) The sheet alignment device has two alignment modules 10 (see more particularly FIGS. 2 to 4), which each have an alignment roller 12 as essential part. Each of the alignment rollers 12 is provided to cooperate with the surface of a sheet that is to be aligned. For this purpose the alignment roller has at least on its circumferential surface a material that is characterised by a friction coefficient. The alignment roller 12 can consist for example of rubber.

(12) Each alignment module 10 has a drive device 14, with which the rotational speed of the corresponding alignment roller 12 can be controlled. The drive device 14 can more particularly contain an electric motor.

(13) Each alignment module 10 has furthermore a swivel device 16, with which the alignment roller 12 can be swivelled around a swivel axis A (see also the arrow P in FIG. 2). In this connection the swivel axis A stands perpendicular on the plane, along which the sheets B are transported through the sheet alignment device 5.

(14) Each alignment roller 12 cooperates with a counter-roller 20, such that the sheets B can be moved through between the alignment roller 12 and the counter-roller 20.

(15) Assigned to each counter-roller 20 is a pressure module 22, with which it is possible to control the pressure force, with which the counter-roller 20 is forced against the alignment roller 12. Moreover the counter-roller 20 can be moved away from the alignment roller 12 briefly by means of the pressure module, such that a sheet can be “threaded” into the gap between alignment roller 12 and counter-roller 20, without the front edge of the sheet being slowed down in the process.

(16) In contrast to the alignment rollers 12 the alignment of the rotational axis of the counter-rollers 20 is not adjustable; the swivel axis always remains perpendicular to the direction along which the sheets are transported.

(17) The counter-rollers 20 have at least on their circumferential surface a material that has a low friction coefficient. Accordingly the movement of a sheet in the region of the cooperation between an alignment roller 12 and the counter-roller 20 corresponds to the circumferential speed and alignment of the corresponding alignment roller 12.

(18) The sheet alignment device 5 has furthermore sensors for determining the position and the alignment of the sheets B.

(19) FIG. 4 shows two position sensors 30, which are arranged upstream of the two alignment modules 10. The two position sensors 30 are located “on the same level”, such that they determine the front edge of a sheet B simultaneously, when this is aligned correctly.

(20) The two position sensors 30 are arranged at such a spacing on the two sides of a central plane of the sheet alignment device 5, that they can determine the front edge of a sheet even if there is maximum lateral misalignment.

(21) Basically, for the accuracy of determination, it is desirable to choose the largest possible spacing of the position sensors. In order however also to be able to determine smaller sheets, the spacing of the position sensors from one another can be adjusted.

(22) The sheet alignment device 5 has furthermore an alignment sensor 32, which is arranged laterally. This serves to determine a side edge of a transported sheet B, more particularly in the region of the transition to the front edge. If the alignment of the front edge is known together with the position of the side edge for example on the transition to the front edge, it is possible to calculate not only, whether and optionally how much a sheet B is skewed relative to the correct alignment, but also, how far it is misaligned laterally.

(23) Starting out from the signals of the sensors 30, 32, a control system not shown here calculates, how the alignment and/or position of each individual sheet must be corrected, in order for it to be brought together with the substrate S in the desired manner.

(24) FIG. 5 shows schematically a sheet B, which is transported in the transport direction T along the sheet alignment device 5 and is aligned correctly there. In the example of FIG. 5 the sheet B in the initial state is skewed clockwise in comparison with its correct alignment. The two alignment modules 10 are therefore controlled, such that the sheet B, when the alignment rollers 12 cooperate with it, transport it somewhat faster on the left side than on the right side, such that the sheet B finally, when it is located downstream of the alignment modules 10, has its correct alignment (see the sheet B represented again in continuous lines downstream of the alignment rollers 12).

(25) For simplification the higher speed of the left alignment roller 12 in FIG. 5 is represented by a longer speed arrow. In fact however, when the front edge of the sheet B that is to be aligned enters the gap between the alignment rollers 12 and the counter-rollers 20, the alignment rollers 12 will rotate at such a speed, that the circumferential speed of the alignment rollers corresponds to the speed of transport of the sheet. Only when the sheet has been grasped completely by the two alignment modules 10, is the left (in relation to FIG. 5) alignment roller 12 brought briefly up to a higher circumferential speed, such that the necessary correction of the alignment of the sheet B takes place. When the sheet B leaves the alignment rollers 12, these rotate again at a speed corresponding to the speed of transport of the sheet B.

(26) With the alignment modules 10 it is also possible to synchronise the sheet with the substrate S, to which it is to be supplied. The sheet B can therefore be speeded up or delayed overall, such that the front edge of the sheet B meets the front edge of the substrate S exactly.

(27) FIG. 6 shows a sheet B, which is misaligned laterally upstream of the alignment modules. Because the sheet B does not need to be turned, the alignment modules are therefore both operated at the same speed (this is represented by means of the two speed arrows, which are of equal length). However the alignment rollers 12 are adjusted by means of the swivel device, such that the sheet B overall is transported askew, until it adopts its correct position downstream of the alignment modules 12.

(28) Here also it can be provided that, when the front edge of the sheet B enters the gap between the alignment rollers and the counter-rollers, the alignment rollers 12 are aligned in the transport direction of the sheet B and only thereupon are swivelled suitably for a short time. Before the back edge of the sheet leaves the alignment modules 10, the alignment rollers 12 have been swivelled round again by means of the swivel device 14, such that the rotational axis of the alignment rollers 14 is perpendicular to the longitudinal direction of the sheet alignment device and to the transport direction T.

(29) FIG. 7 shows an example, in which the sheet B is both skewed and also misaligned laterally. Accordingly the alignment rollers 12 are both swivelled round, in order to compensate for the lateral misalignment, and also driven suitably at different speeds, in order to compensate for the skewing.

(30) It is basically conceivable, that suitable sensors, which are able to determine the alignment and/or position of the sheets, B are provided also downstream of the alignment modules 10. In this case it is then possible to implement a closed-loop control system, which leads to an even greater precision in the correction of the alignment of the sheets B.