Storage module with stacking and unstacking functions

Abstract

A storage module (1) comprises a storage zone (3) for storing flat articles (2) by accumulation in a stack and on edge, a main conveyor (9) that extends transversely to the storage zone, a stacking function for transferring an article from the main conveyor to the storage zone and for stacking it at the back of the stack of articles in the storage zone, and an unstacking function for extracting an article from the stack of articles and for transferring it to the main conveyor. The unstacking function comprises an unstacking plate (7) having a perforated belt and controlled suction and disposed between the main conveyor and the storage zone, said unstacking plate having a first segment parallel to the stack of articles and a second segment that is adjacent to the first segment and that extends slantwise relative to the first segment, said controlled suction being disposed in the slantwise second segment of the unstacking plate.

Claims

1. A storage module comprising a storage zone for storing flat articles by accumulation in a stack and on edge, a main conveyor that extends transversely to the storage zone, a secondary conveyor for transferring an article from the main conveyor to the storage zone and for stacking the article at the back of the stack of articles in the storage zone, and an unstacking plate for extracting an article from the back of the stack of articles and for transferring the article to the main conveyor, wherein the unstacking plate comprises a perforated belt and controlled suction, said unstacking plate being disposed between the main conveyor and the storage zone, said unstacking plate having a first segment parallel to the stack of articles and a second segment that is adjacent to the first segment and that extends slantwise relative to the first segment, said controlled suction being disposed in the slantwise second segment of the unstacking plate.

2. A storage module according to claim 1, wherein the second slantwise segment of the unstacking plate forms an angle lying in the range 3 to 15 relative to the top of the stack of articles.

3. A storage module according to claim 1, wherein said first and second unstacking plate segments join each other in the vicinity of a middle longitudinal axis of the stack of articles.

4. A storage module according to claim 1, wherein the unstacking plate comprises a moving barrier suitable for being moved into a first position for preventing any article from being extracted from the stack of articles, and into a second position for allowing an article to be extracted from the stack of articles, and wherein said moving barrier is pivotally mounted to push back into the storage zone any article that has been partially extracted from the stack of articles when the barrier is pivoted to go from the second position to the first position.

5. A postal sorting machine comprising a storage module according to claim 1.

6. A postal sorting machine according to claim 5, wherein the storage module is adapted to store mail stack separators in a stack and on edge.

7. A postal sorting machine according to claim 6, comprising a sorting conveyor extending along sorting outlets of the machine, said sorting conveyor constituting the main conveyor of the storage module.

8. A postal sorting machine according to claim 6, wherein the separators are made of flexible cardboard.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The present invention can be better understood and other advantages appear on reading the following description and on examining the accompanying drawings, in which:

(2) FIG. 1 is a highly diagrammatic view of a storage module of the invention in stacking mode, with mail stack separators stored in a stack on edge in the storage zone;

(3) FIG. 2 is a highly diagrammatic view of the storage module in stacking mode with a separator arriving at the inlet of the storage zone;

(4) FIG. 3 is a highly diagrammatic view of a storage module of the invention in unstacking mode, with mail stack separators stored in a stack on edge in the storage zone;

(5) FIG. 4 is a highly diagrammatic view of the storage module in unstacking mode, with a separator being extracted from the stack of separators;

(6) FIG. 5 shows the unstacking function in more detail with an unstacking plate of the invention having a slantwise segment and when the controlled suction is not activated;

(7) FIG. 6 shows the unstacking function with the controlled suction activated in the slantwise segment of the unstacking plate; and

(8) FIG. 7 is a highly diagrammatic view of an example of a postal sorting machine for sorting mail, which machine includes a storage module for mail stack separators.

DESCRIPTION OF EMBODIMENTS

(9) FIGS. 1 to 4 are highly diagrammatic views of a storage module 1 of the invention for storing flat articles, and, in this example, for storing mail stack separators 2.

(10) Naturally, the invention is applicable to any type of flat article, such as mail or sheets of paper, or the like.

(11) In FIGS. 1 to 4, the storage module 1 is shown diagrammatically as seen from above, the separators 2 being seen from above in a stack and on edge in the storage zone 3.

(12) The storage zone 3 has a stacking deck or bottom that extends in a longitudinal direction A and on which the separators 2 rest on edge and extend transversely relatively to the direction A.

(13) The storage zone has a longitudinal edge defined by a jogging edge 5 that extends along the direction A.

(14) A paddle 6 is provided in the storage zone so as to slide along the jogging edge and retain the front of the stack of separators 2.

(15) A return system (not shown in the figures), such as a spring, is provided for urging the paddle 6 towards a position at the back of the storage zone where an unstacking plate 7 is disposed.

(16) The paddle 6 and its return system may be replaced with a motor-driven paddle assembly. That motor-driven assembly is servo-controlled to a sensor placed on the unstacking plate 7, making it possible to manage the pressure exerted by the stack of separators 2 on the unstacking plate 7.

(17) That return system thus acts to oppose the movement of the paddle 6 towards the front of the storage zone as the separators accumulate into a stack, and tends to push the stack of separators 2 back towards the unstacking plate 7.

(18) The bottom 8 may thus be mounted to move in the direction A. For example, it may comprise a notched belt mounted on idler pulleys that are disposed at the front and at the back of the storage zone.

(19) The low end of the paddle may be engaged in a notch of the belt so that the movement of the paddle is synchronized with the movement of the belt.

(20) The bottom 8 may also advantageously be a stacking deck having idler rollers in contact with the underside of the stack of separators, thereby limiting the friction forces exerted by the separators on the bottom 8 of the storage zone.

(21) FIGS. 1 to 4 show a main conveyor 9 that extends in a main direction D transversely (perpendicularly in this example) to the storage zone (in direction A in this example).

(22) In this example, the conveyor 9 is a two-belt conveyor that is suitable for moving the separators on edge and in series in the direction D by nipping them between the belts. As described below, the conveyor 9 may be constituted by the sorting conveyor in a postal sorting machine.

(23) As shown in FIGS. 1 to 4, the unstacking plate 7 is disposed between the main conveyor 9 and the storage zone 3.

(24) A secondary conveyor 10 is provided upstream from the storage zone relative to the direction D so as to perform a stacking function of the storage module, and another secondary conveyor 11 is provided downstream from the storage zone relative to the direction D for performing an unstacking function of the storage module.

(25) A switching flap 9A is provided in the path of the main conveyor at the intersection with the conveyor 10 upstream from the storage zone relative to the direction D in order to divert the separators 2 moving in series and on edge from the main conveyor to the secondary conveyor 10 and in order to feed the storage zone 3 when the storage zone is in the stacking function.

(26) The unstacking plate 7 is provided with a system 12 having a perforated belt and having controlled suction that makes it possible to extract a separator from the back of the stack of separators and to transfer it towards the main conveyor through the secondary conveyor 11.

(27) In accordance with the invention, the unstacking plate 7 has a first segment 7A that is shown in more detail in FIGS. 5 and 6 and that is parallel to the stack of separators 2 in the storage zone and thus to the direction D in FIGS. 1 to 4, and a second segment 7B adjacent to the segment 7A and that extends slantwise relative to the segment 7A and away from the stack of separators.

(28) As can also be seen in FIGS. 5 and 6, the controlled suction represented by 12A (a suction nozzle connected to a vacuum chamber) is disposed in the second segment 7B of the unstacking plate, which segment is the further downstream relative to the direction D.

(29) The perforated belt 12B is also shown, which belt forms a closed loop and is engaged over two drive pulleys, and co-operates with the controlled suction to cause the last separator stored at the back of the stack of separators to be extracted by suction and to be transferred towards the secondary conveyor 11.

(30) In particular, in FIG. 5, the controlled suction 12A is off, and the current separator 2 to be extracted from the back of the stack of separators extends undeformed and parallel to the other separators in the stack.

(31) The space between said current separator 2 and the segment 7B of the unstacking plate forms a sort of separation dihedral 13 that opens out towards the secondary conveyor 11 that is closed off in part by the jogging edge 5 of the storage zone.

(32) In practice, the gap between the slantwise segment 7B and the jogging edge 5 must be greater than the thickness of a separator, e.g. in the range 3 to 4 times greater.

(33) In FIG. 6, the controlled suction 12A is actuated, thereby causing the leading portion of the current separator 2 to be sucked against the segment 7B of the unstacking plate while the trailing portion of the current separator is pressed against the segment 7A of the unstacking plate.

(34) The current separator 2 is thus folded substantially in its middle (middle in the transverse direction of the stack) and the leading portion of the current separator 2 is thus offset from the remainder of the stack of separators.

(35) At the same time, the perforated belt 12B imparts movement to the current separator 2 so as to separate it from the stack and so as to transfer it towards the secondary conveyor 11 through the separation dihedral 13.

(36) It should be noted that the separator adjacent to the current separator 2 in the stack remains in abutment against the jogging edge 5 while the current separator 2 is being extracted, thereby making it possible to avoid the risks of two or more bunched separators being taken together from the storage module in unstacking mode.

(37) The angle of inclination of the second segment 7B of the unstacking plate relative to its segment 7A that is parallel to the stack of separators may lie in the range 3 to 15. This angle must be compatible with the flexibility of the separators.

(38) Preferably, the two segments 7A and 7B join each other in the vicinity of a longitudinal middle axis of the stack of articles so that each separator is deformed substantially in its middle by the unstacking plate without being damaged.

(39) FIGS. 1 to 4 show a barrier 14 in the in the separation dihedral 13.

(40) This barrier 14 is mounted to move so as to take up a first position that is shown in FIGS. 1 and 2, in which position it prevents a separator from being extracted from the stack of separators when the storage module is in stacking mode.

(41) In FIGS. 3 and 4, the barrier 14 has been moved to take up a second position in which it allows a separator to be extracted from the stack of separators when the storage module is in unstacking mode.

(42) Advantageously, in accordance with the invention, the barrier 14 is a pivotally mounted barrier (as indicated by a circularly arcuate arrow in FIGS. 3 and 4) that is mounted to pivot about an axis adjacent to the end of the jogging edge 5 in the separation dihedral. With this arrangement, the pivotally mounted barrier is suitable for acting on any separator 2 that has been partially extracted from the stack due to bunching to push it back into the storage zone. Any such separator is pushed back in when the barrier 14 goes from the second position to the first position, i.e. when the storage module goes from unstacking mode to stacking mode.

(43) This arrangement makes it possible to further reduce the risks of bunching or of jamming, and therefore increases the reliability of the storage module of the invention.

(44) It should be noted that said pivotally mounted barrier 14 makes it possible, on its own, to reduce the risks of bunching or of jamming in a storage module having an unstacking plate 7 without a slantwise segment 7B.

(45) Operation of the storage module with the stacking and unstacking functions is described briefly below with reference to FIGS. 1 to 4.

(46) In FIG. 1, separators 2 are already stored in a stack and on edge in the unstacking zone 3.

(47) The switching flap 9A is directed to divert a flow of articles from the main conveyor 9 to the secondary conveyor 10.

(48) In stacking mode, the controlled suction 12 is off and the barrier 14 is in the first position in which it closes off the separation dihedral 13.

(49) In FIG. 2, a separator has reached the secondary conveyor 10 and is going to be stacked at the back of the stack of separators in the storage zone 3.

(50) As the separators 2 are moved in series and on edge along the main conveyor 9, they are thus diverted one-by-one by the flap 9A towards the secondary conveyor 10 so as to stack up one behind the other in the storage zone 3.

(51) In FIG. 3, the storage module 1 is in unstacking mode.

(52) The flap 9A has been actuated into a position indicated by an arrow such that the main conveyor 9 bypasses the storage module 1. The flap 9A thus closes off the passageway from the conveyor 9 to the conveyor 10.

(53) In addition, the barrier 14 is in the second position in which it opens up the separation dihedral 13.

(54) In FIG. 4, when the controlled suction 12 is activated, the leading portion of the current separator 2 at the back of the stack in the storage zone is sucked against the slantwise segment 7B of the unstacking plate, and said current separator is then extracted and transferred towards the main conveyor 9 via the separation dihedral 13 and via the secondary conveyor 11.

(55) FIG. 7 shows a postal sorting machine 20 by way of example, with a mailpiece unstacker 21 that puts the mailpieces into series in the sorting machine.

(56) In the feed magazine of the unstacker 21, two stacks of mailpieces are shown that are separated by a separator 2, e.g. of the flexible cardboard type.

(57) In this example, the sorting machine has sorting outlets 22 and a storage module of the invention for separators 1, which storage module is disposed between the sorting outlets 22 and the unstacker 21, along the sorting conveyor of the machine that, in this example, constitutes the main conveyor 9 of the storage module 1.

(58) FIG. 7 shows a monitoring and control unit that controls the actuators of the sorting machine, and, in particular, the actuators of the flap 9A, of the controlled suction 12, and of the barrier 14 in the storage module.

(59) In a postal sorting machine with a sorting conveyor having a return loop that loops back towards an inlet for feeding mailpieces into the machine, the storage module 1 for mail stack separators may be disposed upstream from said return loop, e.g. after the sorting outlets.