Method for Feeding Laminar Elements Into an Insertion Device and Feeding Station

Abstract

A method for feeding laminar elements into an introducer associated with a graphic printing station provided for printing at least one of the faces of the laminar element, wherein a plurality of laminar elements are grouped in an orderly manner in a stacked group of laminar elements that extends upwards, such that the longitudinal axis of each of the laminar elements is located perpendicular with respect to an advance direction of the group, the advance direction of the group being perpendicular to the advance direction of the introducer. This group of laminar elements is turned 180 degrees with respect to a rotation axis that is parallel to the advance direction of the introducer, such that the upper face of each one of the laminar elements is oriented downwards, the turned laminar element advancing in a direction perpendicular to the advance direction of the introducer.

Claims

1. (canceled)

2. (canceled)

3. A feeder station of laminar elements, for supplying laminar elements to an introducer, comprising: a reception area for receiving laminar elements arranged in a group stacked one on top of the other; turning means for rotating 180 the laminar elements coming from the reception area; and a transfer device provided with stop means and movement means for moving in two directions perpendicular to each other, the laminar elements coming from the turning means towards an outlet area oriented in the advance direction of the introducer, wherein the turning means comprises a structure provided with a plurality of fork-shaped sections that are arranged in the shape of a cross, each one provided with a plurality of spikes that define a housing for the arrangement of the plurality of laminar elements, and rotation means coupled to the structure, said rotation means being associated with motor means linked to a control unit, wherein the plurality of spikes pass between the free spaces between a plurality of transport belts that form part of the movement means located in the inlet and outlet area of the turner.

4. The feeder station according to claim 3, wherein the reception area includes lifting means provided for handling a plurality of laminar elements coming from the group of laminar elements towards a horizontal support platform arranged before the turning means.

5. The feeder station according to claim 4, wherein the horizontal platform includes movement means on which the plurality of laminar elements moves.

6. The feeder station according to claim 5, wherein the movement means comprise at least one transport belt movable by means of rotating pulleys ending in the area where the turning means are arranged.

7. (canceled)

8. (canceled)

9. (canceled)

10. The feeder station according to claim 3, wherein the transfer device comprises first transport means based on rotating rollers and second transport means based on a plurality of conveyor belts linked to rotating pulleys, the rotation axis of the rotating rollers being perpendicular to the rotation axis of the pulleys.

11. The feeder station according to claim 7, wherein the rotating rollers are joined to vertically movable structures, such that in a first operating position, the contact surface of the rotating rollers with a laminar element is located on a plane above the contact surface of a laminar element with the conveyor belt and in a second operating position, the contact surface of the rollers is located below the contact surface of the conveyor belt.

12. The feeder station according to claim 3, wherein the stop means comprise a plate supported on a support structure that may move axially in the transfer device.

13. The feeder device according to claim 3, wherein the stop means include guide means to raise and lower the plate.

14. An introducer assembly of laminar elements comprising an introducer linked to a feeder station according to claim 3, wherein the advance direction of the introducer is perpendicular to the advance direction of the reception area of the feeder station.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0030] FIG. 1 is a perspective view of a feeder station for handling laminar elements according to the present invention;

[0031] FIG. 2 is a detailed view of a region of the transfer that forms part of the station of the invention;

[0032] FIGS. 3a-3k are sequential perspective views of the stages that make up a method by means of the feeder station shown in FIG. 1;

[0033] FIG. 4 is a perspective view of the turning means present in the feeder station; and

[0034] FIG. 5 is a schematic elevation view of the operation of the turning means shown in FIG. 4 wherein the advance direction of the group of laminar element is shown by arrows, the top figure showing turning means formed by two forks that extend in opposite directions to each other and in the bottom figure they are comprised by four forks arranged in a cross (when seen in elevated side view).

DESCRIPTION OF A PREFERRED EMBODIMENT

[0035] In view of the aforementioned figures and, in accordance with the numbering adopted, an example of a preferred embodiment of the invention can be observed therein, which comprises the parts and elements indicated and described in detail below.

[0036] As may be seen in FIG. 1, an embodiment by way of example is shown and described of the feeder station of laminar elements, generally indicated with reference (1), which is provided for supplying cardboard laminar elements that, for example, are used to make up cardboard boxes. This feeder station is linked to an introducer, of a known type, for which reason it shall not be described in greater detail. An example of an introducer may be that which is described in Spanish patent No. ES 2547473 by the same applicant.

[0037] The feeder station (1) comprises the following main parts: [0038] a reception area (2) where a stack of the laminar elements (3), each one of them arranged horizontally or parallel to the floor plane, arrives by means of conveyor belts in order to be subsequently divided into groups that are smaller in height in order to be subsequently turned; [0039] turning means that enable a rotation action of 180 of the laminar elements (3) coming from the reception area (2) that are described below; and [0040] a transfer device, generally indicated with reference (4), provided with stop means (which shall be explained in detail below) and movement means for moving in two directions perpendicular to each other, the group formed by a plurality of laminar sheets coming from the turning means towards an outlet area oriented in the advance direction of the introducer (5) (represented schematically in the figures), indicated with the arrow (fi).

[0041] Returning again to the reception area (2), it also includes lifting means (not shown) located in a structure (6) provided for handling and holding a group of laminar elements (3) coming from the stack of laminar elements, towards a horizontal support platform arranged before the turning means.

[0042] Furthermore, the horizontal support platform includes movement means on which the group of laminar elements (3) move, comprising a plurality of transport belts (8) arranged parallel to each other, each moving by means of rotating pulleys (not shown) ending in the area where the turning means are arranged.

[0043] With respect to the aforementioned turning means, they comprise a structure provided with two forks joined together, as shown in FIG. 4, although the number of forks may be greater, for example, four. Each fork (7) defines a housing for the arrangement of the group of laminar elements to be turned. The forks (7) are formed by a plurality of spikes (70) that pass between the free spaces between a plurality of transport belts that form part of the movement means located in the inlet and outlet area of the turner. Said forks are linked to rotation means (not shown) coupled to the aforementioned structure, said rotation means being associated to motor means linked to a control unit. In a preferred embodiment, the rotation means comprise a central rotation shaft (20) from which the fork-shaped sections extend, which is coupled to an electric motor (not shown).

[0044] As may be seen, the transfer device (4) comprises first transport means based on rotating rollers (11) and second transport means based on a plurality of conveyor belts (9) located parallel to each other, each one of them linked to rotating pulleys (10), the rotation axis of the rotating rollers (11) being perpendicular to the rotation axis of the pulleys (10).

[0045] The rotating rollers (11) are joined integrally or in groups to one or more vertically movable structures (not shown), such that in a first operating position, the contact surface of the rotating rollers (11) with a laminar element is located on a plane above the contact surface of a laminar element with the conveyor belt and in a second operating position, the contact surface of the rollers is located below the contact surface of the conveyor belt.

[0046] Now referring to the stop means in the transfer device (4), they comprise a plate (12), which acts as a wall, which is supported on a support structure (13) that may move axially on a gantry structure (14) arranged in the upper portion of the transfer device (4) as well as guide means to raise and lower the plate (12). In this embodiment, the guide means comprise a vertical column (15) on which the plate (12) moves in a guided manner. The different movements carried out by the plate (12) are managed by the control unit.

[0047] A transport structure, generally indicated with reference (16), is provided between the transfer device (4) and the introducer (5), which enables the group of laminar elements to be moved, by movement means, from the transfer device (4) to the introducer (5), said transport structure (16) including an encasing stop (17) arranged in an intermediate portion. Thus, as may be seen in FIGS. 1 and 3a-3j, the reception area (2), transfer device (4) and transport structure (16) adopt an L-shaped configuration.

[0048] This encasing stop (17) is provided to individually distribute the laminar elements (3) inside the introducer (5). In this way, a gradual loading takes place in the feeder area of the introducer (5).

[0049] The aforementioned movement means may comprise a plurality of conveyor belts (18) arranged parallel to each other in a frame (19). Advantageously, in this case the conveyor belts (18) are telescopic in order to adapt to the size of the laminar body.

[0050] It should be noted that if the laminar body has a width smaller than half the maximum width of the introducer (5), it is possible to work with two lines of introduction of laminar material, i.e., the groups of laminar elements can be manipulated before entering the introducer (5) such that they form two rows, as shown in FIG. 3e-3j. In this case, the transport means formed by the conveyor belts (18) may operate such that they are distributed in two transport groups, each transport group acting for each row.

[0051] The operating method of the feeder station (1) for a group of laminar elements described above is detailed below.

[0052] Firstly, and as shown in FIG. 3a, a plurality of laminar elements (3) are grouped in an orderly manner located on a horizontal plane in a vertical grouping (A) based on an initial column (C) of laminar elements coming from, for example, a corrugating or shaping machine of laminar elements, such that the longitudinal axis (E) of the laminar elements is located perpendicular with respect to an advance direction of the group (A), the advance direction of the group being perpendicular to the advance direction (fi) of the introducer (5).

[0053] Then, the group of laminar elements (3) is turned 180 degrees with respect to a rotation axis (not shown) that is parallel to the advance direction of the introducer (5), such that the upper face of each one of the laminar elements is oriented downwards, as shown in FIGS. 3b-3d.

[0054] Then, as shown in FIG. 3e, the group A of now turned laminar elements continues to move in an advance direction perpendicular to the advance direction of the introducer (5) through the first transport means up to the stop means located in the transfer device. At the same time, the second group (A) enters the turner.

[0055] Then, as shown in FIGS. 3f and 3g, the group of laminar elements moves in the same direction as the advance direction (fi) of the introducer (5) through transport means, the advance direction being parallel to the longitudinal axis (E) of the laminar elements (3).

[0056] Subsequently, and as shown in FIG. 3h, the group (A) passes through the encasing stop (17), such that the laminar elements (3) of the group (A) are separated and are individually arranged horizontally before arriving at the loading area of the introducer (5). The same FIG. 3h shows how the stop of the transfer device (4) moves forward in order to slow the second group (A) in a position such that it enables creating a new row of laminar elements that is parallel to the previous row.

[0057] FIGS. 3i and 3j show how the second group (A) follows the same stages as the previous group.

[0058] Lastly, FIG. 3k shows the introducer (5) introducing two parallel rows of laminar elements, such that two work lines are created.

[0059] The details, shapes, dimensions and other accessory elements used to manufacture the feeder station of the invention may be suitably substituted for others which do not diverge from the scope defined by the claims included below.