The invention relates to a method and a machine for preparing and depositing a packaging sleeve or strip on a palletized load, and consisting in:
Overpackaging a palletized load by means of a plastic cover is performed in conventional manner from a film or a sleeve with or without pleats. Depending on the type of load to be packaged and the type of packaging required, either a heat-shrink film or a stretchable film is used.
In the case of a heat-shrink film, the heat source generally used for shrinking the film onto the load is provided by gas burners arranged on the four corners of a mobile frame designed to move vertically at a small distance along the lateral surface of the load to heat the film. Creation of a lunula is generally achieved by combination of a combined effect of shrinking and blowing or sucking air at the ends of the load. This system is difficult to master when the vertical overshoot of film with respect to the load is large, when the dimensions of the load to be packaged are large or when there is a significant difference between the length and width of the product to be packaged, when the shrinkage parameters are incorrectly adjusted or drift, or when shrinking is disturbed by external phenomena (draughts, wind, ambient temperature variations, etc.). This technique of shrinking the film by heating imposes precise adjustment of the temperature and operating time of the burners. Incorrect adjustment can therefore give rise to damage for the operator, for example fire risks on the products, damage to the packaging in case of overheating, etc.
In the case of a stretchable film, transverse stretching generally takes place after the sleeve has been pleated on stretching fingers. The packaging rates of existing machines remain limited. When a sleeve higher than the load is deposited to create a lunula, the film does not always position itself on the top and bottom faces of the load when the depositing means are withdrawn. The film can in fact be deposited on the vertical faces of the product. Formation of the lunula is not controlled, resulting in risks of random positioning on the load.
The two documents EP 1106507 and U.S. Pat. No. 3,961,459 describe overpackaging machines in which the closed bottom face of the cover or sleeve places itself on the top face of the product to be packaged, the film then being unwound throughout the whole descent of the grippers along the product.
The document U.S. Pat. No. 4,454,705A describes a machine which deposits a sleeve by means of bars which retract by translations, but without forming a lunula on the top and/or bottom face.
A first object of the invention consists in depositing a stretchable plastic film sleeve on a load with formation of at least one lunula on one of the two top or bottom faces to obtain optimum overlapping of the load, and perfect packaging aesthetics without resorting to heat sources for shrinking the film.
The packaging method according to the invention consists in using grippers in the form of bars equipped with a notch at least at one of the ends thereof to apply a reduced stretching ratio at the level of the notch so as to create a lunula on the top and/or bottom face after the set of grippers has been disengaged and the sleeve has been deposited on the load.
The method of applying the sleeve onto the load does not use a heat source of the gas burner type for shrinking the film, but only the elastic relaxation properties of the film used. The elasticity characteristics of the film can be modified, in particular during a pre-stretching phase before formation of the sleeve.
Differential stretching is performed without prior pleating of the sleeve, enabling production rates to be increased. The presence of the lunulas on the top and bottom faces enables the ends of the packaged load to be covered regularly. The presence of a lunula at the bottom part enhances securing of the sleeve on the load during disengagement of the gripper bars. The size of the top or bottom lunula may vary according to the height of the cutout sleeve compared with the height of the product to be packaged. The bottom lunula should therefore be dimensioned so as to guarantee securing of the sleeve on the product when the bars are withdrawn.
The use of two sets of grippers enables the latter to be either synchronized raising them two by two on one and the same gripper arm, or to be desynchronized raising them individually on two independent arms.
The throughput rates can in fact be increased by using a gripper device comprising two synchronized sets of grippers. The handling arm is rotated through a half-turn in the raised position to position the stretched sleeve above the load in the depositing station, and to simultaneously move the empty second set of grippers back to the preparation station, and the handling arm is then moved to the lowered position to perform placing of the stretched sleeve on the load in the depositing station, and to pick up the next sleeve simultaneously formed in the preparation station, respectively by means of the first set of grippers and the second set of grippers. When the handling arm is raised to the raised position, the two sets of grippers move up simultaneously causing the grippers to be disengaged from the packaged load, and from the preparation station before the rotational movement of said arm.
The invention takes account of different formation techniques of the sleeve in the preparation station from reels of film of various cross-sections:
The cover is cut according to the height of the load so as to present two open ends.
A second object of the invention consists in providing a machine for preparation and deposition of a stretchable plastic film sleeve on a load, enabling formation of at least one lunula and stable and aesthetic packaging of the load.
The machine comprises a preparation station of a sleeve from a flexible plastic film wound flat around a storage reel, and a gripper device to take hold of the sleeve and transfer it to the deposition station to envelop the load. According to the invention, each bar has a notch at least at one of the ends thereof to obtain a differential stretching ratio allowing formation of a lunula on the top and/or bottom surface of the load.
Preferably, each bar rotates by a predetermined angle at the end of deposition travel and then moves in translation to the middle part of a lateral face of the load to allow vertical disengagement thereof in the upwards direction. The sleeve is thus easily released without impairing the packaging quality.
According to an alternative embodiment, the bars can have rounded cross-sections to deposit the sleeve and to then disengage. Following a vertical disengagement of the round bars without rotation, a top lunula can be obtained. Formation of a bottom lunula is performed by letting the film overflow under the bars and by stretching the sleeve more when deposition is performed.
According to a preferred embodiment, the gripper device comprises two sets of grippers movable in the heightwise direction between a raised position and a lowered position, and control means to, in the raised position, position said stretched sleeve above the load by means of the first set of grippers, while at the same time moving the empty second set of grippers back to the preparation station, and at the same time, in the lowered position, to perform placing of the stretched sleeve on the load in the depositing station, respectively by means of the first and second set of grippers.
Such a machine with two working stations one of which operates in masked time enables high packaging rates to be achieved, given that preparation of the sleeves is performed during deposition on the loads. The control means control the whole system to ensure synchronization of the displacement movements of the handling arm and of the sets of grippers. The movements of the two sets of grippers can be simultaneous being mechanically linked to one another, or be independent.
Different sleeve preparation stations can equip the machine according to the type of packaging cover used.
The depositing station can be equipped with an additional securing system of the load to be packaged designed to oppose any friction effect of the bars on the film which would pull the load upwards when vertical removal of the bars takes place.
Other advantages and features will become more clearly apparent from the following description of particular embodiments of the invention given as non-restrictive examples only and represented in the accompanying drawings, in which:
a to 9d illustrate the different phases of disengagement of the gripping bars when a sleeve with lunulas is deposited on the load;
a and 12b are schematic plan views of
With reference to
Such a packaging machine with two workstations, one of which works in masked time, enables high throughput rates to be obtained, given that preparation of sleeves MA in station 11 takes place during the deposition operation of previous sleeve MA on a load CH located in the other station 15.
Packaging sleeve MA is formed from a stretchable plastic film, in particular described in the document EP-A-1060988. Sleeve MA, once it has been formed, undergoes a first stretching operation before deposition, followed by a second flexible relaxation operation on load CH at the end of deposition. Load CH presents a parallelepipedic shape.
Formation of sleeve MA with open opposite ends is performed in preparation station 11 in three different manners:
Sleeve MA, regardless of its production method, is then picked up in preparation station 11 by gripper device DP by means of a first separation movement of bars 18, and is pulled upwards by a vertical movement to disengage it from preparation station 11 to perform overstretching thereof.
Gripper device DP comprises two sets of grippers 13, 14 of identical structure, each set being equipped with four vertical bars 18 mounted movable in translation two by two on two horizontal and parallel beams 19. The two beams 19 are themselves mounted movable in translation on rods 20 parallel to a frame, which rods extend orthogonally with respect to beams 19. Bars 18 of each gripper set 13, 14 are thereby animated with two perpendicular translational movements enabling sleeve MA to be given a perimeter suitable for deposition on load CH.
Each bar 18 can in certain cases be animated with a limited rotational movement around its vertical axis to enable sleeve MA to be disengaged at the end of cycle.
Actuation of bars 18 for disengagement of sleeve MA can be performed by any other control mechanism.
The profile of bars 18 varies according to the type of packaging to be performed, with the presence of lunulas (
To constitute a sleeve MA with lunulas (
The length of bars 18 can be adjusted according to the required length of sleeve MA.
Handling arm 12 bears the two sets of grippers 13, 14 and is mounted on the main frame (not shown). According to one embodiment, arm 12 can be animated with a first rotational movement (arrow F1,
Implementation of Sleeve MA on Load CH is Performed in the Following Manner:
Once sleeve MA has been formed, the four bars 18 of gripper set 13 situated above preparation station 11 come and pick up sleeve MA and pull it up to the raised position following the upward vertical movement of handling arm 12 (arrow F2).
In the case of
After sleeve MA has been disengaged from preparation station 11, the four bars 18 of the first gripper set 13 stretch sleeve MA transversely at the four corners (
At no time is sleeve MA pleated when transfer thereof is performed from preparation station 1, and during differential stretching.
Then, during or at the end of the stretching phase, handling arm 12 performs a rotational movement through 180° (arrow F1,
At the end of rotation of handling arm 12, the four bars 18 of first gripper set 13 adjust their position above load CH to obtain an optimum sleeve perimeter p3 for deposition (see
In the lowered position of arm 12 corresponding to downward travel of first gripper set 13, bars 18 rotate through more or less 45° (arrows F3,
This results in flat cross-section bars 18 remaining parallel to two opposite lateral sides of load CH to minimize deformation of sleeve MA in the elongation direction of its perimeter.
In
According to an alternative embodiment, extraction of notched bars 18 can also take place by means of two translational movements, in particular a lateral movement to release the corners and a vertical extraction movement.
In
The film used is a tubular cover H1 with pleats 16 (
To trigger the preparation cycle of sleeve MA, station 11 comprises two sets of four grips 28, 29 that move to a position at the top of sleeve MA and underneath lower clamping jaw 25. Sleeve MA is opened by means of two separators 30, and clamping jaws 25, 26 open after cover H1 has been picked up by grips 28 of the first set. The latter pull cover H1 up to a predetermined height which depends on the length of sleeve MA. In this position, grips 29 of the second set position themselves just above the upper clamping jaw 26, and close to pick up cover H1 at its four corners.
After clamping jaws 25, 26 have closed, blade cutting device 27 cuts thus prepared sleeve MA to the required length. Upper clamping jaw 26 opens, and set of grips 28, 29 open sleeve MA at pick-up perimeter p1 (
The four bars 18 of one of the sets of grippers 13, 14 then enter inside sleeve MA positioning grips 28, 29 at the level of notches 21. Opening of the two sets of grips 28, 29 releases sleeve MA, which is held by the four gripping bars 18. Grips 28, 29 are moved apart laterally, and are then moved to the lowered position underneath bottom clamping jaw 25. Grips 28, 29 are inserted in pleats 17 of the next sleeve.
With reference to
In
The end of the film is secured at the beginning of the cycle by a securing grip 35 integral to plate 34. Plate 34 rotates around its vertical axis (arrow F5) so as to wind the pre-stretched film around the four sets of two rollers 33. At the end of the winding phase, securing grip 35 has reverted to its original position, and pivots through 90° to enable welding means 36 to weld the film. After welding, the film is cut by means of a cutting device 127, and grip 35 is then opened.
Gripper bars 18 then come and take hold of sleeve MA thus formed and pull it vertically upwards after having slightly stretched the sleeve to unstuck it from rollers 33. A motor roller 37 delivers a certain length of film so that the end reaches the level of securing grip 35.
An additional width 38 coming from a second reel B4 (
According to a development of the invention, a cap (not shown) can be added to the top of load CH being joined to sleeve MA by any means, in particular by heat sealing. The tightness is thereby improved according to the nature of the load.
Depending on the height of the loads to be packaged, two sleeves can be successively fitted at different levels of the load.
In the field of household appliances, the weight of the products to be packaged is around 40 kg. To prevent any risk of packaged load CH being pulled upwards during the extraction phase of bars 18, depositing station 15 can be equipped with an additional securing system SR designed to oppose a possible friction effect of the bars on the film.
In
Another embodiment illustrated in
In
Number | Date | Country | Kind |
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0511478 | Nov 2005 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR2006/002502 | 11/9/2006 | WO | 00 | 5/27/2008 |