Mail sorting installation with a tray conveyor and a tray-manipulating shuttle robot

Abstract

The sorting installation (1) of the invention includes sorting outlets (2) aligned along a sorting conveyor (3), each outlet having a recess (4) for receiving a tray (5) in which sorted mailpieces (6) are stored, and also a tray conveyor (8) that extends under the sorting outlets for moving full trays. The installation further includes a shuttle robot (9) provided with a chute (14) having a bottom end (14a) that is slidingly attached to a guide rail (10) extending along the tray conveyor, the shuttle robot being designed to extract a tray full of mail automatically from a recess in a sorting outlet and to drop it onto the top portion of the chute in such a manner that, on reaching the bottom of the chute, the tray is injected onto the tray conveyor under the effect of gravity.

Claims

1. A sorting installation comprising: sorting outlets aligned along a sorting conveyor, each outlet being provided with a recess for receiving a tray in which sorted mailpieces are stored, a tray conveyor that extends under said sorting outlets for transporting trays full of sorted mailpieces from the sorting outlets to a feed inlet of the sorting conveyor, and a shuttle robot suitable for traveling on the floor in autonomous manner along the sorting outlets, wherein the robot is provided with handling means comprising motor driven pickup head comprising two horizontal parallel bars that are telescopic and movable vertically, said handing means being suitable for extracting a tray from a recess of a sorting outlet and for placing it on the tray conveyor, said robot including a chute having a bottom end that is slidingly attached to a guide rail extending along said tray conveyor, the handling means being arranged so as to place the tray extracted from the sorting outlet onto the top portion of the chute in such a manner that, on reaching the bottom of the chute, the tray is injected onto the tray conveyor under the effect of gravity.

2. The sorting installation according to claim 1, wherein said shuttle robot includes a structure carrying a vertical guide rail in which the top end of said chute is slidably mounted and in that the bottom end of the chute is connected mechanically to the structure by a set of rods forming a parallelogram suitable for deforming in order to compensate for a variation in height between the floor on which the shuttle robot travels and said guide rail.

3. The sorting installation according to claim 2, wherein said shuttle robot includes a return spring that pulls the top end of the chute sliding in said guide rail upwards.

4. The sorting installation according to claim 3, wherein said shuttle robot includes a return spring that pulls the bottom end of the chute downwards.

5. The sorting installation according to claim 4, wherein said chute has a slide surface made by rollers.

6. The sorting installation according to claim 1, wherein said shuttle robot includes a return spring that pulls the bottom end of the chute downwards.

7. The sorting installation according to claim 1, wherein said chute has a slide surface made by rollers.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The present invention can be better understood and other advantages appear on reading the following detailed description of the embodiment given by way of non-limiting example and with reference to the accompanying drawings, in which:

(2) FIG. 1 is a diagrammatic view from above of a sorting installation of the invention;

(3) FIGS. 2a to 2c are diagrams showing the shuttle robot in front of various sorting outlets of the sorting installation of the invention.

DESCRIPTION OF THE EMBODIMENT

(4) FIGS. 1, 2a, 2b and 2c, show a sorting installation 1 of the invention that includes sorting outlets 2 aligned along a sorting conveyor 3, each outlet being provided with a recess 4 for receiving a tray 5 in which sorted mailpieces 6 are stored.

(5) FIG. 1 also shows a feed inlet 7 designed for putting mailpieces 6 in series on the sorting conveyor 3 in the conveying direction F1 for subsequent sorting into the corresponding sorting outlets 2.

(6) A tray conveyor 8 is also provided under the sorting outlets 2 in order to convey the trays 5 filled with mailpieces 6 from the sorting outlets 2 to the feed inlet 7 in a conveying direction F2.

(7) In this example, a tray 5 is extracted from a recess 4 of a sorting outlet 2 and is injected onto the tray conveyor 8 under said sorting outlet 2 by means of a shuttle robot 9 suitable for traveling on the floor S1 in autonomous manner along the sorting outlets 2 in the travel direction F3.

(8) The shuttle robot 9 couples to a guide rail 10 that extends in front of the tray conveyor 8 over its entire length, as can be seen in FIGS. 1 and 2a to 2c.

(9) As shown in FIG. 2a, the shuttle robot 9 comprises a structure 11, in this embodiment an L-shaped structure with a wheeled platform 11a and a back plate lib, on which there are mounted handling means 12 suitable for extracting a tray from a recess of a sorting outlet and for placing it on the tray conveyor.

(10) The handling means 12 include a motor-driven pickup head 13 comprising two horizontal parallel bars that are telescopic and movable vertically in order to extract a tray 5 from the recess 4 of a sorting outlet 2.

(11) The handling means also include a tray chute 14 that extends under the telescopic head 13 from a top end 14b towards a bottom end 14a that is used to provide sliding coupling with the guide rail 10.

(12) The bottom end 14a of the chute is coupled to the guide rail 9 by means of three guide wheels 15 that come to bear against an abutment 16 of the guide rail 9.

(13) As can be seen in FIG. 2b, the bottom end 14a of the chute comes flush with the tray conveyor 8 so that each tray 5 can slide directly from the chute onto the conveyor without manual intervention or motor-driven means.

(14) The slope of the chute 14 is therefore selected so that the trays 5 slide by gravity onto the tray conveyor 8.

(15) The chute 14 could also comprise rollers 17 mounted to be free to turn so as to facilitate sliding of the trays 5 and accept smaller gradients for the slope of the chute.

(16) The telescopic pickup head 13 moves down and unloads the tray 5 extracted from the recess 4 of the sorting outlet 2 onto the top portion of the chute 14 so that it can be injected onto the tray conveyor 8.

(17) The shuttle robot 9 also comprises two connecting rods 18 that are parallel one above the other and that connect the bottom end 14a of the chute mechanically to the structure 12 of the shuttle robot 9 so as to form a parallelogram suitable for being deformed when there is a variation in height between the floor S1 and the guide rail 10 and/or the bottom end 14a of the chute.

(18) The rods 18 preferably have ties of identical length so that the distance between the structure 12 and the bottom end 14a of the chute is always the same.

(19) In non-restrictive manner, two sets of rods 18 could be used and placed on either side of the structure 12 in the manner of two vertical side walls.

(20) In this embodiment, the rods 18 perform multiple functions consisting in holding the chute 14 parallel with the structure 12 relative to the guide rail 10, in holding the chute 14 tensioned on the structure 9, and in avoiding tipping of the chute 14 at its bottom end 14a.

(21) In this embodiment, the shuttle robot 9 shown in FIGS. 2a to 2c is attached to the tray conveyor 8 in front of various sorting outlets 2.

(22) In FIG. 2a, the height H1 between the floor S1 and the bottom end 14a of the chute is less than the height H2 of FIG. 2b, which is itself less than the height H3 shown in FIG. 2c.

(23) Thus, the greater the height between the floor S1 and the bottom end 14a of the chute, the more the parallelogram formed by the rods 18 is deformed.

(24) The slope of the chute is thus constant and uncoupling of the shuttle robot 9 at the three guide wheels 15 with the tray conveyor 8 is avoided, in particular uncoupling of the guide wheel 15 that is situated under the tray conveyor 8, which prevents uncoupling of the shuttle robot 9 by frontal traction relative to the tray conveyor 8, which generally becomes uncoupled when the chute 14 tips forwards.

(25) In addition, in order to accommodate the variation in height between the bottom end 14a of the chute and the floor S1, the shuttle robot 9 includes a guide rail 19 that extends vertically from the base of the structure 12 and in which the top end 14b of the chute 14 is slidably mounted.

(26) Sliding of the top end 14b of the chute in the guide rail 19 could also be damped by means of a return spring 20, or of an elastic, that tends to pull upwards the top end 14b of the chute sliding in said guide rail 19.

(27) Finally, with the aim of holding the bottom portion 14a of the chute pressed against the guide rail 10 of the tray conveyor 8, a return spring 21 is arranged between the bottom end 14a of the chute and the structure, that tends to pull the bottom end 14a of the chute down towards the floor S1.

(28) Without restricting the ambit of the invention, a plurality of shuttle robots 9 could be used on the same guide rail 10 so as to accelerate the rate at which trays 5 are extracted from and injected onto the tray conveyor 8.