According to a first aspect, the present invention relates to an element for producing a package for packaging a food product, the element being of the type comprising:
The invention is used in particular for packaging soft cheese.
In the remainder of the text, packages having substantially triangular bases are intended to refer to packages whose bases are effectively triangular with rectilinear sides, but also those whose bases have a curved side and are therefore in the shape of a disc sector.
FR-2 597 441 describes an element of the above-mentioned type for packaging a portion of soft cheese. In this element, the traction tongue extends in the intermediate zone along the centre axis of the zone which is intended to form the base of the package.
Although the opening of the package described in this document is on the whole satisfactory, the initiation and propagation of the tears require traction in two different directions.
The traction of the tongue is carried out a first time towards the tip and the second lateral wall of the package in order to unfold the flap in which the traction tongue is located. After this flap has been unfolded, the traction is produced a second time towards the base of the package and the projection in order to initiate and propagate the tears.
An action of this type is considered to be complex and difficult to implement by some consumers.
An object of the first aspect of the invention is therefore to overcome this problem by providing an element of the above-mentioned type which facilitates the opening of a package for packaging a food product.
The first aspect of the invention also relates to a package for packaging a food product.
The first aspect of the invention further relates to an assembly.
According to a variant, the food product is soft cheese.
According to a second aspect, the present invention relates to a device for cutting strips from at least one film, the device comprising at least two blades which have cutting edges which are intended to face each other, the blades being able to be moved relative to each other in a direction which is orthogonal relative to the film in order to propagate a cut in the film along the cutting edges.
The invention is used in particular for producing tear guiding strips for packages for packaging soft cheese.
Document FR-2 362 765 describes a cutting device of the above-mentioned type. This type of cutting device is found to be satisfactory for cutting strips from films having thicknesses greater than 36 μm.
It would be desirable to be able to provide finer strips for guiding tears in order to be able to reduce the costs of these strips. However, cutting devices of the above-mentioned type are found to be incapable of cutting strips from such fine films, without crumpling the strips obtained.
An object of the second aspect of the invention is therefore to overcome this problem by providing a cutting device which allows strips to be cut from finer films.
To this end, the second aspect of the invention relates to a cutting installation.
The second aspect of the invention also relates to a cutting method.
The second aspect of the invention further relates to a package.
According to a variant, the guiding strip has a thickness which is strictly less than 36 μm.
The invention will be better understood from a reading of the following description, given purely by way of example and with reference to the appended drawings, in which:
The sheet 1 illustrated in
In order to form a package, and as illustrated in
The sheet 1 comprises zones which are intended to form the different portions of the receptacle 2. These different portions will be described below. The same references will generally be used to refer to the portions of the receptacle 2 and the corresponding zones of the sheet 1.
The receptacle 2 comprises a base 3 in the form of a disc sector delimited by two lateral edges 5 and 7 and an edge 8 in the form of a circular arc. Perpendicularly relative to the plane of the base 3, the receptacle 2 comprises:
The lateral walls 9 and 11 meet each other at a tip 15 opposite the projection 13.
The lateral walls 9 and 11 and the projection 13 are extended with flaps 17, 19 and 21, respectively, which are intended to be folded down along folding lines 23, 25 and 27, when the package is closed.
Before folding, the sheet i further comprises intermediate zones 29, 31 and 33 which are arranged between the walls 9 and 11 and the flaps 17 and 19 thereof, between the wall 9 and the projection 13 and the flaps 17 and 21 thereof, and between the projection 13 and the wall 11 and the flaps 21 and 19 thereof, respectively. The lateral edges 35 and 37 of the projection 13 and the flap 21 extend the lateral edges 5 and 7 of the base 3.
The sheet 1 is also provided, at the side which is intended to form the inner face of the receptacle 2, with two strips 51a and 51b for guiding tears. The sheet 1 and the strips 51a and 51b thus form a packaging element.
The two strips 51a and 51b are, for example, produced from polyethylene (PET) and have a thickness which is strictly less than 36 μm, for example, 23 μm or 18 μm. The strips 51a and 51b have been thermowelded both to each other and to the sheet 1.
As illustrated in
The main portion 52a is extended, in the projection 13, with a first end 53a which is inclined, from the point of origin of the projection, relative to the edge 35 towards the centre axis A of the base 3. This inclination is, for example, 10°.
At the other side, the portion 52a is extended with a second end 55a which, in the example illustrated, is inclined by an angle α relative to the axis A. The angle α is, for example, between 15° and 25°.
This second end 55b extends slightly through the second lateral wall 11, then extends through the intermediate zone 29 and finally protrudes therefrom over a length 1 measured along the centre axis A of the base 3.
The second strip 51b has, in the region of the projection 13, a form which is symmetrical with respect to that of the first strip 51a relative to the centre axis A.
However, the main portion 52b of the strip 51b has a break 54b beyond which the main portion 52b is no longer substantially parallel with the edge 7 but instead intersects with it, so that the second end 55b of the strip 51b is located at the same side of the centre axis A as the end 55a of the strip 51a.
The main portions 52a and 52b meet each other at an intersection point 57 which is located, for example, in the intermediate zone 29. This intersection point 57 is laterally spaced-apart from the centre axis A.
Beyond the intersection point 57, the ends 55a and 55b of the strips 51a and 51b are superimposed, the end 55b being arranged below the end 55a and having the same shape as the end 55a.
The ends 55a and 55b are heat-sealed to each other and heat-sealed to the sheet 1. These two ends 55a and 55b therefore form a single traction tongue 58 which is laterally spaced-apart from the centre axis A and which protrudes from the intermediate zone 29 by the length 1.
In the example illustrated, this tongue 58 is rectilinear and inclined by the angle α relative to the centre axis A.
In order to obtain the receptacle 2 of
The traction tongue 58 protrudes upwards beyond the folding line 23 and therefore beyond the first lateral wall 9.
In the receptacle 2 which is thus obtained a pre-determined quantity of molten cheese is poured in the hot state to a depth which is equal to the height of the lateral walls 9 and 11 and the projection 13 in order to constitute a portion 70 which is visible in
A second sheet 71 which has dimensions which correspond to those of the base 3, is deposited on the portion 70. This second sheet 71 is, for example, also produced from aluminium covered with heat-sealing lacquer. Then, as illustrated in
As illustrated in
The tongue 58 is not sealed to the cover 72 and can therefore be more readily gripped by a consumer, even if he has short nails.
If the tongue 58 is folded down during sealing, the heating of the tongue 58 and in particular the fold thereof, allows it to keep this shape after production.
An assembly 73 is thus obtained which comprises a package 75, formed from the sheets 1 and 71, and the portion of soft cheese 70 packaged in the package 75.
In a variant, the tongue 58 can be folded down on the cover 72 not when the cover is sealed, but instead when the assembly 73 is placed in a casing.
The package 75 is opened as illustrated in
The consumer grips the tongue 58 which is not sealed to the flap 17, then applies a traction movement thereto which is directed towards the base 3 and the projection 13, as indicated by the arrow 77 in
Then, the traction continues in the same direction indicated by the arrow 77. The tears which are brought about substantially along the length of the tip 15 are propagated and guided along the edges 5 and 7 of the base 3. The remainder of the opening of the package 75 is carried out in conventional manner and is therefore not illustrated in the Figures.
Owing to the fact that the traction tongue 58 is spaced-apart from the centre axis A in the sheet 1, the initiation and the propagation of the tears does not involve any significant change in the traction direction as in FR-2 597 441. The opening is therefore logical and can be implemented by almost all consumers.
Owing to the existence of a single traction tongue 58 in the sheet 1 and not two tongues 58 which are arranged at one side and the other of the common axis and which are intended to be superimposed during the folding of the sheet 1, the risks of incorrectly gripping the traction tongue are reduced.
Furthermore, since the tongue 58 is folded down on the cover 72 in the packaging 75, the tongue is located and can be readily gripped by consumers. The tongue 58 was able to be folded down on the cover 72 since it protrudes beyond the first lateral wall 9 into the packaging 75.
In a variant, the tongue 58 may not be folded down or may not even protrude beyond the lateral wall 9. The tongue 58 is arranged along the first wall 9 as in the prior art.
In a variant, the tongue 58 may be formed by only one of the strips 51a and 51b.
In this manner, the second strip 51b may not have, beyond the intersection point 57, an end 55b which is superimposed on the end 55a. In yet another variant, the end 55b may not extend over the same length as the end 55a.
In yet other variants, the traction tongue 58 may have shapes other than those illustrated in
In the same manner, in a variant, the intersection point 57 may be located in the second wall 11 or in the base 3 close to the intersection between the edges 5 and 7.
It is also possible, for example, for the strip 51b to have no break 54b in the main portion thereof, as illustrated in
Furthermore, the strips 51a and 51b may be replaced with other forms of guiding means.
In this manner, these may be local weakenings of the first sheet 1 obtained, for example, by means a wheel or a laser beam.
Advantageously, the guiding strips 51a and 51b described above were obtained using an installation for cutting at least one film, as described below.
The installation 80 comprises:
The feeding means 83a and 83b are, for example, of the conventional type and may thus comprise traction rollers, as illustrated in document FR-2 362 765.
They move the films 84a and 84b towards the blade 92 in a substantially horizontal manner.
In the same manner, the feeding means 82 may have a conventional structure.
The cutting device 88 comprises two lower blades 90a and 90b and an upper blade 92.
As illustrated in
The installation 80 comprises means 98 for moving the upper blade 92 relative to the frame 81 between an upper position which the blade 92 occupies before cutting and which is illustrated in
In the upper position of the blade 92, the cutting edges 96a and 96b are located above the films 84a and 84b, respectively.
The cutting edges 96a and 96b are substantially horizontal and the movement of the blade 92 between the upper and the lower positions thereof is carried out in a substantially vertical manner, that is to say, substantially orthogonally relative to the plane of the films 84a and 84b when they are in the region of the upper blade 92.
As can be seen in
The lower blades 90a and 90b are arranged below the films 84a and 84b, respectively, at one side and the other of the upper blade 92. Their sides 102a and 102b, which face each other, have upper edges 104a and 104b which form cutting edges having shapes which complement those of the edges 96a and 96b.
The cutting edges 104a and 104b are arranged in the same plane which is slightly inclined relative to the horizontal, for example, by 5°.
The lower blades 90a and 90b can be moved on the frame 81 substantially parallel with the plane of the films 84a and 84b when they are in the region of the upper blade 92.
In the example illustrated, the lower blades 90a and 90b are articulated to the frame 81 by means of pivots 106a and 106b.
The blades 90a and 90b can thus be moved between a mutually close position and a mutually remote position, the path of this movement being small, for example, in the order of 0.5 mm.
The cutting device 88 comprises means 108a and 108b for resiliently returning the blades 90a and 90b to their mutually close position.
In the example illustrated, these means are springs which are arranged laterally at the outer side of the blades 90a and 90b, between the blades and the portions of the frame 81.
In other variants, these springs 108a and 108b may be replaced, for example, with a single spring 108 which connects the blades 90a and 90b to each other.
Preferably, these resilient return means can be adjusted.
Both in the upper position thereof, and in the lower position thereof, the upper blade 92 is interposed laterally between the lower blades 90a and 90b.
The return means 108a and 108b laterally press the blades 90a and 90b against the blade 92. In this manner, the cutting edges 104a and 104b are pressed against the cutting edges 96a and 96b substantially parallel with the plane of the films 84a and 84b in the region of the blade 92 at points of contact 110a and 110b (
Furthermore, the installation 88 comprises an electronic control unit 112 for automatically controlling, in particular via the means 82, 83a, 83b and 98, the execution of the cutting cycle described below.
The upper blade 92 is initially in an upper position, the contact points 110a and 110b are remote from the tail 93 of the upper blade 92. The lower blades 90a and 90b are in a mutually close position.
Before the cutting operation itself begins, the feeding means 82 have placed a sheet 1 below the cutting device 88 and the feeding means 83a and 83b have caused the films 84a and 84b to move forward slightly so that a width which corresponds to that of the strips 51a and 51b extends from the cutting edges 104a and 104b laterally towards the upper blade 92.
The upper blade 92 is lowered and the contact points 110a and 110b move progressively towards the tail 93 of the upper blade 92.
The movement of the contact points 110a and 110b brings about the progressive cutting of the strips 51a and 51b which are retained by means of suction, as they are cut, below the upper blade 92 owing to the suction apertures 100a and 100b.
During this movement of the contact points 110a and 110b, the insertion of the blade 92 between the lower blades 90a and 90b brings about their movement towards the mutually remote position thereof.
Owing to the return means 108a and 108b, the blades 90a, 90b and 92 are retained in a state pressed one against the other in the region of the contact points 110a and 110b substantially perpendicularly relative to the general directions in which the cuts are propagated in the films 84a and 84b, thus producing a scissor type effect. The corresponding retention forces have been indicated by the arrows 114a and 114b in
Following the cutting operation, the upper blade 92 continues its path as far as the lower position in which it presses the cut strips 51a and 51b against the sheet 1.
Heating means which are arranged in the frame 81 below the sheet 1 allow the strips 51a and 51b to be heat-sealed to each other and to the sheet 1.
Then, the upper blade 92 returns to its upper position, a new sheet 1 is placed below the device 88 and the films 84a and 84b are each moved forward by a distance which corresponds to the width of the strips 51a and 51b.
The cutting and sealing cycle is automatically repeated under the action of the unit 112.
Owing to the scissor type effect described above, it was possible to find that the guiding strips 51a and 51b are not crumpled during the cutting operation. This remains true even if the films 84a and 84b have extremely small thicknesses, for example, in the order of 23 μm or 18 μm.
In this manner, the installation 80 of
More generally, and regardless of the type of package in which the cut strips are used, the installation 80 allows films 84a and 84b having smaller thicknesses to be used, which significantly reduces the costs associated with the production of the tear guiding strips.
It is therefore possible to use an installation which implements the scissor type effect described above in order to produce guiding strips having various forms.
In the same manner, the cutting installation 80 may cut only a single guiding strip and riot two simultaneously as in the example described above.
In the example described above, the cutting device 88 is a module which may be disassembled from the frame 81 in order to be able to adjust the various elements and in particular the return means 108a and 108b thereof.
If there are a plurality of cutting devices 88 provided for the same installation 80, it is possible to adjust a device 88 whilst the other device 88 is installed and used in the installation 80.
More generally, the scissor type effect can be provided by displacing not the whole of one or more blades, but instead by deforming portions thereof.
This is illustrated in
The lower blade 90 is a blade which can be resiliently deformed in a horizontal manner.
In the example illustrated, resilient return means 1081 to 1083 are used to return the blade 90 against the upper blade 92. However, in yet another variant, the resilience of the lower blade 90 may be sufficient to dispense with means of this type and press the lower blade 90 against the upper blade 92. The blade 90 itself forms the resilient return means.
Number | Date | Country | Kind |
---|---|---|---|
05 07545 | Jul 2005 | FR | national |
05 07546 | Jul 2005 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/FR2006/001691 | 7/11/2006 | WO | 00 | 5/27/2008 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2007/006973 | 1/18/2007 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3412927 | Baur | Nov 1968 | A |
4801075 | Weber et al. | Jan 1989 | A |
5024331 | Litzler | Jun 1991 | A |
7318941 | Poupard et al. | Jan 2008 | B2 |
20060275531 | Dal | Dec 2006 | A1 |
20080276569 | Dal et al. | Nov 2008 | A1 |
Number | Date | Country |
---|---|---|
441 110 | Jul 1967 | CH |
299 03 463 | Jun 2000 | DE |
0 222 705 | May 1987 | EP |
1 019 809 | Jan 1953 | FR |
2 362 765 | Mar 1978 | FR |
2 597 436 | Oct 1987 | FR |
2 597 441 | Oct 1987 | FR |
2 854 388 | Nov 2004 | FR |
2 854 391 | Nov 2004 | FR |
Number | Date | Country | |
---|---|---|---|
20090065563 A1 | Mar 2009 | US |