Patent Application
20070095782
The invention relates to the domain of metal closing caps with plastic inserts, typically designed for closing bottles with screw caps.
A number of closing caps with metal shells and plastic inserts are already known, the metal shell being used for capping by crimping the cap onto the threaded glass ring, and the threaded insert performing the cap open-close function by screwing - unscrewing the cap, and creating the leak tight closing seal.
Thus, the applicant's patents include:
There are several types of requirements and problems due to closing caps according to the state of the art:
The invention is intended to develop a closing cap that satisfies these three objectives.
According to the invention, the screw closing cap designed to cooperate with a neck of a receptacle, typically a bottle designed to contain an alcoholic drink such as wine, the said neck forming a mouth lip on the upper part and comprising an outer thread on its sidewall and a recessed part on which the said cap will be crimped, comprises a) a typically metal outer shell, typically including an outer head and an outer skirt, b) an insert typically made of plastic, the said insert contained in the said shell and fixed to the said shell, comprising a head and a skirt provided with an inner thread designed to cooperate with the outer thread of the said neck, and c) a seal typically forming an add-on part fixed to the said insert, the said seal comprising a central part and a peripheral part or border, and is characterised in that the said insert comprises a radial compression means of the said seal in contact with the said neck, such that when the said closing cap is screwed to the said neck, the said border is compressed radially between the said insert and the said neck, and thus the seal and the opening torque of the said cap are to a large extent independent of the axial position of the said cap with respect to the said neck.
The applicant had already observed that many problems encountered in capping using caps according to the state of the art were due particularly to slight variations in the height of the bottles to be capped, or possibly a small difference in the axial distance between the cap and the mouth lip, particularly due to the normal clearance of cap devices, which were the cause of a variation in the axial compression of the seal on the neck mouth lip, and consequently a variable seal and a variable screwing torque.
Thus, following his observations, the applicant developed a cap in which the add-on seal is compressed radially, and on an industrial capping line he observed that firstly a greater tolerance was possible on the axial position of the cap with respect to the mouth lip while still obtaining the required seal, and secondly the screwing-unscrewing torque was approximately constant and remained within the normal range of values, without the need to compress the seal in the axial direction.
Furthermore, the use of such a cap enabled higher capping rates, largely due to this greater tolerance.
According to the invention, radial compression is a compression comprising a preponderant radial component, which assumes a compression force applied along a compression direction at an angle of more than 45° from the vertical, the angle being 90° in the case of pure radial compression and 0° in the case of a pure axial compression.
All figures are related to the invention.
a is a view of an axial section of an insert (3) without its seal (4).
b is an enlarged view of part of the insert in
c is a lateral top perspective view of an insert (3), at a smaller scale than the insert in
d corresponding to
a is a left partial axial section of an insert (3) with its seal (4), the seal (4) being fixed to the insert by the inner thread (33).
b is a right partial axial section of the insert (3) in
c is an enlarged right partial axial sectional view of a cap (1) screwed onto a neck (5) illustrating radial compression (6) of the peripheral edge (41) of the seal (4) in contact with the upper vertical part (51) of the neck (5), by the circular tab (32) in the case in which the cap (1) is at an axial distance HO from the mouth lip (50) of the neck (5).
a and 3b are similar to
In
In
In
According to
a shows an axial section of the reversible fixing of the pouring spout (7) with the central part (40) of the seal (4) obtained using a support part (8), the pouring spout comprising a plurality of fixing arms (73) cooperating reversibly with the said support part (8) fixed to the central part (40) of the seal (4)
b shows an axial section of the pouring spout (7) fixed to the neck (5) after unscrewing of the cap (1).
c is a partial view in a horizontal plane showing the fixing arms (73) of the pouring spout (7) cooperating with the head (82) of the support part (8).
The cap (1) on the left part of the figure is shown screwed rather than crimped, and on the right part the cap (1) is shown crimped, a portion of the outer skirt (21) having been pushed under the recessed part (53) of the neck (5) during capping.
a is a diagrammatic axial sectional view of radial compression (6) of the seal (4) in contact with the neck (5).
b and 7c are diagrammatic partial axial views illustrating the case in which the insert fixes the cap (1) to the neck (5) due to a plurality of hooks (371) of a lower part (37) cooperating with the recessed part (53) of the neck (5), and includes a means of detecting a first opening due to a line of weakness (36) formed by a plurality of connecting strips connecting the lower part (37) to the rest of the insert (3).
b corresponds to the cap (1) screwed before being opened for the first time., while
According to the invention, so as to form the said radial compression means (6):
a) the said inner skirt (31) may comprise a circular tab (32) with an axial spacing equal to h1 from the said inner head (30) forming the bottom of the said insert, the said distance h1 typically varying from 0.5 mm to 5 mm, so as to form an annular groove (35) with an axial height equal to at least the thickness e of the said seal (4), the said annular groove (35) being limited at its top part by the said tab (32) and at its lower part typically by the said thread (33), the said tab (32) having a radial width 1 typically varying from 0.2 mm to 2 mm,
b) the diameter of the said seal (4) may be chosen such that the said edge (41) is capable of cooperating with the said annular groove (35), the said seal (4) having an annular overlap area with the said tab and typically with the said thread called the upper area and the lower area respectively, so that the said seal (4) remains fixed to the said insert (3) before the said cap (1) is screwed onto the said neck (5), or after the said cap (1) is unscrewed from the said neck (5),
c) when the said cap (1) is screwed onto the said neck (5), the said tab (32) or a flexible radial end (320) of the said tab (32) and the said edge (41) of the said seal (4) can cooperate, the said tab (32) or the said flexible radial end (320) applying the said radial compression (6) on the said edge (41), so as to apply the said edge in contact with the said neck (5) and typically an upper part (51) of the said neck, forming an overlap area (60) between the said edge (41) and the said tab or radial end (320) inclined at more than 45° from the vertical, thus sealing the said cap (1) screwed to the said neck (5).
a illustrates the case of an overlap area forming an angle of approximately 60° from the vertical.
In some cases, this angle may be as large as 80° and possibly even 90° in the case in which the tab (32) is at a sufficient axial distance from the inner head (30) of the insert so as to face the vertical part of the said upper part (51) of the neck (5).
As illustrated in
According to the invention, the said inner skirt (31) of the said insert (3) may have a thickness Ej at the bottom of the thread (33) varying from 0.1 mm to 1 mm, and typically from 0.15 mm to 0.5 mm.
a and 1d show inserts (3) with skirt thickness Ej equal to 0.3 mm (maximum value).
The said insert (3) may be a threaded and typically moulded insert made of a thermoplastic material, typically chosen from among PS, PET, PA, and polyolefins such as PE or PP. High-impact PS will be used in preference.
Inserts are typically injection moulded.
The said shell (2) may be an aluminium or tin metal shell, or may be made of a crimpable multilayer metalloplastic material.
As illustrated on the right part of
Typically, the said seal (4) may be made of a multilayer material, typically including a compressible central core C made of a thermoplastic material with a density varying from 200 to 500 kg/m3, a lower layer I typically made of polyolefin or possibly an oxygen barrier material designed to come into contact with the said alcoholic drink.
Its thickness e can vary from 0.5 to 3 mm.
According to one embodiment of the invention, the said insert (3) may have a height Hi less than the height Hc of the said shell (2). The height Hc of the said shell (2) may be at least twice as high as the height Hi of the said insert (3) so as to form a cap with a long skirt as illustrated for example in
In this case, the said shell (2) may include a means of detecting or facilitating a first opening, typically a line of weakness (22) or a first opening strip formed on the said outer skirt, the said means being located at a height between Hc and Hi, such that the said means is located above the said recessed part (53) of the said neck (5) when the said cap (1) is screwed onto the said neck (5), the said cap (1) being crimped to the said neck (5) by local deformation of the said outer skirt (21) of the said shell (2) in the said recessed part (53), such that the said cap (1) cannot be unscrewed without breaking the line of weakness of removing the said strip.
According to another embodiment of the invention, the height Hi of said insert (3) may be equal to at least the height Hc of the said shell (2) as illustrated in
In this case, in particular the said insert (3) may include a means of detecting or facilitating a first opening, the said inner skirt of the said insert including an attachment means in its lower part designed to cooperate with the said recessed part when the said cap is screwed and crimped to the said neck.
In
As soon as the cap (1) is unscrewed as illustrated in
According to the invention, the said shell (2) may have a radius of curvature RC of the said shell at the junction between the said outer head and the said outer skirt varying from 0.5 mm to 5 mm, and typically equal to 1.5 mm or 2.5 mm.
As shown in
It has been observed that the lack of free space between the said shell and the said insert has an influence on the seal if storage or transport conditions can involve relatively high temperature conditions typical of tropical countries.
The applicant considered that the lack of free space, and the fact that the shell forms a binding band for the insert, should limit creep and relaxation of stresses in the insert such that it would consequently be possible for it to keep its mechanical properties and assure the said radial compression even after temperatures are temporarily as high as 40° to 50° C.
Typically, the said insert (3) and the said shell (2) are fixed by force fitting and/or by an adhesive layer fixing the said outer skirt (21) and inner skirt (31) together.
Advantageously, the said adhesive layer is a hot-melt layer.
As shown in
a and 5b illustrate the case in which the pouring spout (7) is reversibly fixed to the central part (40) of the seal (4).
The pouring spout (7) may include a typically vertical partition (70) capable of penetrating into the said neck (5) and a flared upper part (71) that pours the contents of the bottle, the partition (70) being provided with a plurality of sealed ribs (72) fixing the pouring spout to the neck (5). This pouring spout (7) includes arms (73) that cooperate with a part (8) by reversible snapping-on. The said part (8) includes a stand (8) sealed to the central part of the seal (40) and a rod (81) carrying a head (82) that cooperates with the end of the ribs (72).
All figures correspond to example embodiments according to the invention.
All inserts (3) were made by injection moulding of high-impact PS.
All metal shells were fabricated by drawing a 0.21 mm thick aluminium strip so as to obtain shells with a height Hc typically equal to 60 mm.
The seals were obtained from a material available in the shops made by CORELEN ®, in a strip with thickness e of 1.2 mm.
This material comprises a 1 mm thick expanded PE or EPE core, its complete multilayer structure possibly being represented by EPE / Kraft paper / Sn / PVDC, the PVDC layer being in contact with the liquid, intermediate layers of adhesive fixing the adjacent layers if necessary.
EPE / PE / PVDC / PE or PE / PVDC / PE / EPE / PE / PVDC / PE type seals were also used for the tests.
Inserts were assembled in the shells by depositing a hot-melt strip on the inside of the said outer skirt (21), and the said insert (3), typically comprising the said seal, was force fitted until the said inner head (30) stopped in contact with the said outer head (20).
Capping tests were carried out on bottles with glass rings references BVP 30H60 and BVS30H60.
A) Inserts and caps according to figures 1a to 1d:
Inserts (3) according to
These inserts (3) comprise a circular tab (32) at an axial distance h1 of 2.8 mm, the said tab having a radial width 1 equal to 1.55 mm —see
The radius of curvature RCi of these inserts (3) was taken equal to 0.79 mm.
a shows a first variant of an insert —the seal (4) being missing —in which the said circular tab (32) and the upper end of the threads (33) define an annular groove (35) with an axial width of 1.4 mm.
On the variant shown in
B) Inserts and caps according to
An insert (3) with its seal (4) was also shown diagrammatically in
c shows an enlarged detailed illustration of the radial compression (6) of the border (41) of the seal (4) by the circular tab (32) of the insert (3) clamped in the typically metal shell (2).
In this case, the overlap area (60) between the border (41) and the tab (32) by its radial end (320) is approximately vertical, such that the compression direction (61) makes an angle of approximately 90° from the vertical.
C) Inserts and caps according to
An insert (3) was made with a radius of curvature Rci of 2.5 mm. This insert was also used to make two caps (1), differing from the metal shell (2) by the radius of curvature RC.
The shell (2) in
D) Caps with pouring spouts obtained according to
A pouring spout (7) and a part (8) acting as a temporary support for the pouring spout were formed by injection moulding of PE, enabling automatic catering of the pouring spout with respect to the neck. The part (8) was heat-sealed to the central part (40) of the seal (4) that included a lower layer also made of PE.
The said part (8) is fixed to the said pouring spout (7) provided that a minimum axial force is applied, but is typically sufficient so that the said pouring spout does not separate from the said part (8) under its own weight, such that the said seal (4) and the said part (8) remain fixed to the said insert (3) when the said cap is opened, the pouring spout (7) remaining fixed to the neck due to the friction forces generated by the said ribs (72).
E) Inserts and caps obtained according to
Inserts and cap were made such that the angle between the direction of the radial compression (61) after screwing in and capping and the vertical is between 45 and 90°.
F) Inserts and caps obtained according to
These inserts are moulded with a plurality of tabs forming hooks (371) capable of cooperating with the recessed part (53) located below the mating ring (54) of the neck (5) such that in this case there is no crimping of the outer skirt (21) in the said recessed part (53).
The caps (1) obtained were screwed onto necks as illustrated on the left part of
Firstly, as illustrated in
Thus, contrary to what was observed with screw caps according to the state of the art, the leak tightness and the opening torque to unscrew the cap remain approximately constant throughout a production campaign, regardless of the source of the glass bottles used.
The seal of caps was measured by filling 75 cm3 bottles with red wine with alcohol content of 12° at atmospheric pressure at 20° C, leaving a free volume of 13 cm3 above the wine level. After screwing and crimping the caps on the bottles, the bottles were heated gradually and the temperature at which the first leaks occurred were marked, as a function of the increased pressure in the bottle that was also measured.
All other things being equal, caps according to the invention had a very much better seal than caps according to the state of the art.
Furthermore, storage tests at ambient temperature and at 50° showed that the opening torque was within the range varying from 11 to 13 lbs/inch, namely 1.24 to 1.47 N.m, while the cap according to the state of the art required a much higher torque:
Furthermore, having increased the reliability of capping, the applicant observed that capping rates with caps according to the invention could be increased by about 10% without any risk of seal defects appearing.
The applicant also observed that it is possible to obtain a good seal without the need for a high opening torque, as is the case with caps according to the state of the art.
Thus, even elderly persons are capable of unscrewing caps according to the invention.
Finally, the applicant has observed that caps (1) according to the invention could have a better seal at “high temperature” using caps of the type shown in
As is clear from the above, screw caps according to the invention have major advantages over caps according to the state of the art, and they do not introduce any extra manufacturing costs and they use the same production techniques and materials as caps according to prior art.
These advantages may be summarised as follows:
use for capping wine, alcohol, spirit and aperitif bottles. T,0190
| Number | Date | Country | Kind |
|---|---|---|---|
| 03/07610 | Jun 2003 | FR | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/FR04/01568 | 6/23/2004 | WO | 12/21/2005 |
