阅读说明：本技术 用于加工诸如纸、纸板或薄膜的片材材料的加工机的片材进料器 (Sheet feeder for a processing machine for processing sheet material such as paper, cardboard or film ) 是由 S·威克 于 2018-10-09 设计创作，主要内容包括：本发明涉及一种加工机(1)的片材进料器(4),所述加工机用于加工诸如纸或薄膜的片材材料,所述片材进料器(4)包括驱动轴(10),所述驱动轴(10)在大致垂直于片材进给方向延伸,且设有至少一个抽吸夹持器(12),所述抽吸夹持器(12)在当所述驱动轴(10)受驱动时在所述片材材料上方旋转。所述抽吸夹持器(12)可在非活动位置与活动位置之间改变位置,在所述非活动位置,所述抽吸夹持器不与所述片材材料配合,在所述活动位置,所述抽吸夹持器可作用于所述片材材料的顶部并将其夹带。(The invention relates to a sheet feeder (4) of a processing machine (1) for processing sheet material, such as paper or film, the sheet feeder (4) comprising a drive shaft (10), the drive shaft (10) extending substantially perpendicular to a sheet feeding direction and being provided with at least one suction gripper (12), the suction gripper (12) rotating above the sheet material when the drive shaft (10) is driven. The suction gripper (12) is displaceable between an inactive position, in which it does not engage the sheet material, and an active position, in which it can act on the top of the sheet material and entrain it.)

1. A sheet feeder (4) of a converting machine (1) for converting sheet material, such as paper or film, the sheet feeder (4) having a drive shaft (10), the drive shaft (10) extending substantially perpendicular to a direction of sheet feeding and being provided with at least one suction gripper (12), the suction gripper (12) rotating over the sheet material when the drive shaft (10) is driven, wherein the suction gripper (12) is displaceable between an inactive position, in which the suction gripper (12) does not cooperate with the sheet material, and an active position, in which the suction gripper (12) can continuously grip a top of the sheet material.

2. Sheet feeder according to claim 1, characterized in that the plurality of suction grippers (12) are divided into groups spaced from each other in the axial direction of the drive shaft (10).

3. A sheet material feeder according to claim 2, wherein four to ten sets are provided.

4. Sheet feeder according to claim 2 or 3, characterized in that each group has a plurality of suction grippers (12), which suction grippers (12) are spaced apart from each other in circumferential direction around the drive shaft (10).

5. Sheet feeder according to claim 4, characterized in that each group has three suction grippers (12).

6. Sheet feeder according to any one of the preceding claims, characterized in that each suction gripper (12) has a body (40) and a suction cup (44), the suction cup (44) being repositionable relative to the body (40), the body (40) being attached at a position remote from the central axis of the drive shaft (10).

7. Sheet feeder according to claim 6, characterized in that the body (40) is rotatably attached to the drive shaft (10).

8. Sheet feeder according to claim 6 or 7, characterized in that the radius of movement of the body (40) around the drive shaft (10) is variable.

9. Sheet feeder according to claim 8, characterized in that the sheet feeder is provided with a repositioning mechanism (20, 22, 30, 32), the position and alignment of the suction grippers (12) being controlled by the repositioning mechanism (20, 22, 30, 32) with respect to the plane in which the sheet (50) lies.

10. Sheet feeder according to any one of claims 6 to 9, characterized in that the drive shaft (10) has a plurality of retaining bars (14), the retaining bars (14) extending parallel to the axis of rotation of the drive shaft (10), and the body (40) of the suction gripper (12) is connected with the retaining bars (14).

11. Sheet feeder according to claim 10, characterized in that the retaining rod (14) is rotatable and displaceable relative to the drive shaft (10).

12. Sheet feeder according to claims 9 and 11, characterized in that the repositioning mechanism (20, 22) repositions the retaining bar (14).

13. Sheet feeder according to claim 12, wherein the repositioning mechanism has a cam track (30) and a cam follower (32).

14. Sheet feeder according to any one of the preceding claims, characterized in that at least one pneumatic channel is integrated into the drive shaft (10), with which pneumatic channel the suction grippers (12) are connected.

15. Sheet feeder according to claim 14, characterized in that each holding rod (14) is provided with one of said pneumatic channels.

16. Sheet feeder according to any one of the preceding claims, characterized in that the sheet feeder is provided with a compacting device (60).

Technical Field

The present invention relates to a sheet feeder for a processing machine for processing sheet material such as paper, paperboard or film.

Background

The processing machine may be a laminator that applies a coating material, such as a plastic film, to the substrate and bonds the two together tightly. The converting machine may also be a machine for making corrugated cardboard. However, other conceivable embodiments of the application are also possible.

The sheet material feeder is for gripping a respective uppermost sheet material from the stepped stack of sheet materials and removing it from the stack in a sheet material feed direction for further processing of the uppermost sheet material.

Disclosure of Invention

The invention aims to produce a device with a simpler structure.

In order to achieve this object, the invention provides a sheet feeder having a drive shaft which extends in a direction substantially perpendicular to the sheet feeding and is provided with at least one suction gripper which rotates over the sheet material when the drive shaft is driven, wherein the suction gripper is displaceable between an inactive position in which the suction gripper does not cooperate with the sheet material and an active position in which the suction gripper can continuously grip the top of the sheet material. The invention is based upon a basic idea of combining two moving parts, i.e. a vertical movement and a horizontal movement, as known from the prior art, into a single flow moving part. To this end, the suction gripper rotates above the stack of sheet materials, so that, in a suitable segment of its movement path, it grips, lifts and continues to grip the uppermost sheet of the stack. Thus, there is no need to transfer a sheet from the first device lifting the sheet to the second device removing the sheet from the stack and pushing it forward.

Preferably, a plurality of suction grippers are provided, which are divided into a plurality of groups spaced apart from each other in the axial direction of the drive shaft. The reasonable number of sets and the distance of the sets from each other depends on the characteristics of the sheets to be taken from the stack. In this regard, particularly preferred numbers of sets are four to ten sets of suction grippers.

According to one embodiment of the invention, it is provided that each group has a plurality of suction grippers which are spaced apart from one another in the circumferential direction around the drive shaft. This may increase the number of cycles.

It is particularly preferred to have three suction grippers per group. In this case, when the suction gripper grasps, lifts and pushes the uppermost sheet slightly forward, the next suction gripper has been moved forward.

Preferably each suction gripper has a body and a suction cup, the suction cup being repositionable relative to the body, the body being attached at a location remote from the central axis of the drive shaft. The size of the radius at which the body of the suction gripper is attached has a decisive influence on the distance by which the uppermost sheet gripped by the respective suction gripper can be pushed forward.

The body is preferably rotatably attached to the drive shaft such that the leading end of the suction gripper gripping a sheet can be maintained parallel to the plane of the sheet for some portion of the movement process of the suction gripper.

The radius of movement of the body about the drive shaft is preferably variable such that the vertical and horizontal portions of the course of movement of the suction gripper are controlled in a predetermined manner.

The present invention may provide a repositioning mechanism, the position and alignment of the suction gripper being controlled by the repositioning mechanism relative to the plane in which the sheet lies. The movement path of the suction gripper is controlled by the repositioning mechanism such that the suction gripper moves in a distance (at least almost) parallel to the plane of the sheet even when the drive shaft performs a rotational movement.

According to one embodiment of the invention, the drive shaft has a plurality of retaining rods which extend parallel to the axis of rotation of the drive shaft and to which the body of the suction gripper is connected. The retaining rod allows all suction holders to be changed position, all suction holders being simply connected at the same time in the same position, viewed in the circumferential direction.

Preferably, the retaining rod is rotatable and displaceable relative to the drive shaft such that the alignment of the retaining rod and the radius at which the suction gripper is located at each point of its path of movement can be controlled simultaneously in a predetermined manner.

The position and rotation of the holding rod are preferably changed by the change-position mechanism. According to a simple embodiment, the repositioning mechanism has a cam track and a cam follower. In this way, the required change of position of the holding rod can be achieved purely mechanically without the use of servomotors or similar complex components.

According to one embodiment of the invention, at least one pneumatic channel is integrated into the drive shaft, the suction gripper being connected with the pneumatic channel. The compressed air or vacuum required for actuating the suction gripper can thus be provided rather easily.

Depending on the embodiment of the control system controlling the pneumatics and the suction grippers, a dedicated pneumatic channel may be provided in the drive shaft for each holding rod.

According to one embodiment of the invention, a pressing device is provided which cooperates in a suitable manner with the sheets located on the stack when the suction gripper lifts the uppermost sheet.

Drawings

The invention is described below by means of an embodiment, which is shown in the attached drawings, in which:

fig. 1 schematically shows an embodiment of a processing machine for processing sheet material;

figure 2 shows the main parts of the sheet feeder in a schematic perspective view;

figure 3 shows a portion of the sheet feeder of figure 2 in an enlarged view;

figure 4 shows the part of the sheet feeder shown in figure 3 with a part of the frame removed so that the part of the sheet feeder behind the frame can be seen;

figure 5 shows the connection guide of figure 4 in a schematic top view;

figure 6 shows, in a schematic top view, a group of suction grippers and their repositioning mechanism;

figures 7 to 12 show schematically the different steps of removing the uppermost sheet from the stack.

Detailed Description

In fig. 1 it can be seen that a machine 1 is used for processing sheet material. In the embodiment shown in the figures, the machine bonds two sheets together, for example, by pressing one sheet onto the other.

The first stack of sheets is indicated with reference number 2 and the second stack of sheets is indicated with reference number 3. In operation, one sheet in the stack 2 is correspondingly connected to one sheet in the stack 3, e.g. both are glued together.

The individual sheets may be sheets of paper, plastic film, cardboard or similar material.

To remove individual sheets from the stack, a sheet feeder is provided. A sheet material feeder is exemplarily located on the stack 3 and is indicated with reference number 4.

The sheet feeder 4 is explained in more detail below with the aid of fig. 2 to 7.

The main component of the sheet feeder 4 is a drive shaft 10, which drive shaft 10 is arranged above the plane in which the uppermost sheet of the stack 3 lies. In this regard, the drive shaft 10 extends parallel to this plane and perpendicular to the direction in which each sheet is further fed after it has been removed from the stack 3 (see arrow P of FIG. 1; this direction is also referred to as the sheet feeding direction).

A frame 11 is provided for mounting the drive shaft 10 and other related parts of the sheet feeder, the frame 11 being arranged above the position of the stack 3.

A plurality of suction grippers 12 are arranged on the drive shaft 10. The suction grippers are intended to grip the uppermost sheet in each stack and to move it forward relative to the stack 3 in the direction of arrow P.

The suction gripper 12 is attached away from the axis of rotation of the drive shaft 10, so that it moves along a closed path of movement about said axis of rotation when the drive shaft 10 is driven.

The plurality of suction grippers 12 are divided into a plurality of groups that are spaced apart from each other in the axial direction. As can be seen in fig. 2, a total of six groups of suction grippers 12 are provided along the axis of rotation of the drive shaft 10. As can be seen in fig. 3, each group has three suction grippers 12.

The suction grippers 12 are distributed over a total of three holding rods 14, all three holding rods 14 extending parallel to the axis of rotation of the drive shaft 10. Viewed in the circumferential direction, the retaining rods 14 are arranged at an angular distance of 120 ° from one another.

More specifically, it can be seen in fig. 3 and 4 that the outer set of suction grippers 12 can be repositioned in the axial direction (see rack 15). This makes it possible to set the working width of the sheet feeder in response to different formats.

The three retaining rods 14 are mounted in two retaining elements 16, the retaining elements 16 being arranged on two opposite axial ends of the drive shaft 10. Each retaining element 16 has three retaining arms 18 extending in a radial direction, each retaining arm 18 having a guide slot 20 provided therein, the guide slots 20 extending radially, one end of the retaining rod 14 being received in the guide slot 20.

The guide groove 20 allows the retaining rod 14 to change its position in the radial direction with respect to the axis of rotation of the drive shaft 10.

The radius at which each retaining bar 14 is located is defined by a guide rail 22, which is shown in detail in fig. 3. The guide rail 22 has, in the broadest definition, an annular configuration, the side of which facing the stack 3 is flat.

In this regard, the guide rail 22 is provided in one of the two end plates of the frame 11, and the drive shaft 10 is also mounted in the frame 11.

When the drive shaft 10 is rotated, the retaining rod 14 not only changes position after each rotation with respect to the radial distance of the axis of rotation, but also rotates within a certain range each time with respect to the respective retaining arm 18. To control this rotation, a cam track 30 (see fig. 4 in greater detail) is provided in which a plurality of cam followers 32 move within the cam track 30. Each cam follower 32 is connected to the retaining bar 14 by a connecting bar 34.

The guide groove 20 forms with the guide rail 22 and the cam track 30 with the cam follower 32 a repositioning mechanism by which the position and alignment of the suction gripper 12 is controlled after each rotation of the drive shaft 10. In general, each suction gripper 12 is moved in such a way that its "front face" (i.e. the suction cup to be placed on the respective sheet) is positioned parallel to the plane of the respective sheet as long as it is engaged with the respective sheet. Thus, the respective suction grippers 12 are again "flying" into a position in which they can grip the sheet again.

Due to this sequence of movements, the cam track is usually located outside the guide rail 22, seen in the axial direction.

Each suction gripper 12 has a body 40 (see fig. 3), the body 40 being non-rotatably fixed on one of the holding rods 14. A telescopically extendable ram 42 is displaceably mounted in the body 40, with an actual suction cup 44 connected to the front face of the ram 42.

A return spring 48 (see fig. 6) is disposed within the body 40, the return spring 48 urging the ram 42 into a retracted position in which the suction cup 44 is repositioned toward the body 40.

The suction holder 12 is actuated by compressed air and has a Venturi nozzle (Venturi nozzle) so that the required vacuum can be generated in the suction cup 44. The supply of compressed air to actuate the suction cup 44 causes the ram 42 to telescopically reposition outwardly out of the body 40 against the force of the return spring.

Said compressed air is supplied in a pneumatic channel into the drive shaft 10 and is conveyed from the drive shaft 10 to the body 40 via a connecting nozzle 46 visible in fig. 2; the hose connected to the connection nozzle 46 is not shown in fig. 2 for clarity.

Depending on the characteristics of the control system and the suction grippers, a single pneumatic channel may be provided, to which all suction grippers are connected, or an individual pneumatic channel may be provided for each suction gripper of a holding rod.

The operating principle of the sheet feeder 4 is explained below with the aid of fig. 7 to 12. In this connection, one suction gripper 12 of a group of suction grippers is taken as an example, wherein the respective suction device is indicated with a black dot in order to be more easily found.

The drive shaft 10 rotates clockwise in fig. 7 to 12 to remove its respective uppermost sheet from the stack 3 in the direction of arrow P, which allows further processing of the sheet.

The suction gripper 12 is seen moving close to the stack 3 from above, wherein the suction gripper 12 is rotated using the change of position mechanism, more specifically the cam track 30 and the corresponding cam follower 32, so that the ram 42 is located substantially perpendicular to the plane of the uppermost sheet of the stack 3 (see fig. 7 and 8). In this connection, the holding rod 14 is located on a relatively large radius.

The ram 42 also extends outwardly with the suction cup 44 (again see fig. 7 and 8) as the suction gripper 12 is being pushed toward the stack 3. When the drive shaft 10 has rotated a sufficient distance, the suction cup 44 rests on the uppermost sheet 50 of the stack 3 (see fig. 9).

After the suction cup 44 rests against the sheet material 50 and is thus sealed there, the supply of compressed air to the suction gripper 12 is started, so that the return spring retracts the ram 42 into the body 40, while the vacuum on the suction cup 44 continues to act. In this way, the sheet 50 is lifted from the stack 3 (see fig. 10). At the same time, the pressing device 60 is actuated, fixing the sheets on the stack 3 in its lower position.

It is also possible to assist the separation of the uppermost sheet from the stack by blowing air in a manner known per se.

As the drive shaft 10 continues to rotate, the suction gripper 12 continues to move clockwise (see fig. 11), completing a movement that is substantially translational, parallel to the plane of the sheets of the stack 3, and in the direction of the arrow P due to the guide 22.

Fig. 12 shows a case where the sheet 50 is repositioned to the left to be grasped by the conveying device 70 schematically shown in fig. 1. At about the same time, the suction cup 44 is deactivated to release the sheet. In fig. 8 it can be seen that in this case the next suction cup has been moved closer to the uppermost sheet of the then stack 3, so that the next sheet can be grasped and supplied to the transport device 70.

The drive shaft 10 does not necessarily have to operate as a single component extending along the axis of rotation about which the suction gripper 12 is repositioned. Rather, other designs are also conceivable. It is only important that the suction gripper 12 is movable along a circular path about the axis of rotation.