The invention relates to the domain of screw stopper capsules that typically comprise an internal threaded plastic insert and a metallic external shell.
These capsules are typically intended for closing bottles containing alcoholic drinks and particularly wine.
Composite capsules comprising a threaded insert and a metallic shell are already known, particularly like those in the following patents issued in the name of the applicant.
Thus, French patent No. 2 763 046 describes a method of fastening an insert to a metallic shell.
Similarly, French patents No. 2 792 617, and No. 2 793 216 describe a composite stopper capsule in which the said insert performs the technical functions of the capsule.
French patent No. 2 802 181 describes a stopper capsule in which the said shell is crimped to the said insert, the capsule comprising a means of providing weight and/or volume to the said capsule above its sealed closing means.
French patent No. 2 803 827 describes a stopper capsule in which the said insert has a thin wall.
Screw stopper capsules are also known in which the thread is created by deformation of the metallic skirt of the capsule, for example as described in French patent 2 387 165.
Problems that Arise
Firstly, screw stopper capsules according to the state of the art do no always have sufficient manual grippability, to the extent that unscrewing of the capsule may require a torque, particularly for first opening, such that the fingers can tend to slide on the metallic shell, which is usually cylindrical.
One purpose of the invention is stopper capsules with a particular shape that is easier to handle and easier to screw/unscrew than stoppers according to the state of the art.
Secondly, there is also a continuously increasing demand for diversification of the shapes of the capsules, such that there is a need for non-cylindrical capsules in the strict sense of the term.
Satisfying this need is another important purpose of the invention.
Another purpose of the invention consists of capsules in which the shape of the shell enables immediate differentiation from marketed capsules that are typically cylindrical.
Furthermore, these capsules must satisfy mechanical strength requirements, particularly in terms of shock resistance.
Another purpose of the invention consists of a method for making these capsules according to the first purpose of the invention, industrially and at high speed.
Composite capsules are manufactured by procuring plastic inserts, metallic shells and assembling them together.
The plastic insert is formed by moulding of the thermoplastic material, typically by injection.
The metallic shells are manufactured typically by drawing a metal strip or sheet, usually aluminium or tin. Thus, in practice, it is known only how to produce cylindrically shaped metallic shells industrially at high speed.
According to the invention, the stopper capsule designed as a screw stopper for a container typically designed to contain alcoholic drinks, and typically a bottle in which the neck is provided with an outer thread and a tamper-evident ring, comprises two parts fixed together in rotation and axially by an assembly means, a) an inner part or insert with height h, made of plastic material, comprising a so-called inner head and a so-called inner skirt, the said inner skirt comprising an inner thread on its inside surface designed to cooperate with the thread of the said neck so as to be able to screw the said capsule to the said neck along a rotation axis or an axial direction, and b) an outer part or a shell with height H, typically metallic or metal based, comprising an outer head and an outer skirt masking all or part of the said inner skirt facing it, the said capsule typically being provided with a sealing means, a tamper-evident means and a first opening means, and characterised in that:
1) the said outer skirt of the said shell comprises at least a typically cylindrical part with height H1, diameter D1 adapted to the said neck, and at least a radially expanded part with height H2, inscribed in a circle with diameter D2>D1 and forming an annular radial cavity, the said typically cylindrical part of the said shell radially clamping the said inner skirt of the said insert like a hoop at least facing the said inner thread, the said expanded part being designed particularly to facilitate manual gripping of the said capsule and rotation of the capsule with respect to the said neck to open/close the said container by unscrewing/screwing the said capsule on the said neck,
2) the said radially expanded part (43) and the said typically cylindrical part (42) of the said outer skirt (41) typically having the same thickness Ep.
Following his work, the applicant observed that the means according to the invention could effectively solve the problems that arise concerning the capsules themselves.
The presence of a radially expanded part on the skirt of the said shell makes it possible to get a better manual grip of the capsule particularly in order to unscrew it, and to differentiate it from capsules already on the market.
Furthermore, the invention can be differentiated without increasing the height of containers closed with such capsules. The total height of a bottle with its capsule may in many cases be controlled by a standard or a requirement imposed by one of the many players involved in the line between the producer or the packager and the consumer. Thus, for example, it could not be envisaged that a drink distributor would agree to an increase in the space between bottle storage shelves because bottles are too tall.
Furthermore, these capsules have a high shock resistance, particularly because the radially expanded part of the outer skirt has a thickness Ep approximately the same as the thickness of the remainder of the outer skirt that is not expanded radially, while the expanded areas according to the state of the art have a thinner wall.
It is advantageous that this is the case since this expanded part (43) is exposed to shocks and therefore it should not be mechanically weaker than the remaining part of the metallic shell (4). This is achieved particularly through use of the method according to the invention described in the following.
a, 2a, 3a, 4a, 5a, 7a, 8a, 9a, 10a, 13a, 13b and 14a are axial sections through capsules (1) comprising a shell (4) according to the invention, the said capsules being crimped onto a neck (2), while
The left part of
The capsules (1) in
a to 5, 13a and 13b relate to methods of making a capsule (1) in which the insert (3) is an insert (3′) with an inner skirt (31) said to be “short” with height h1<20 mm, so as to face the thread (20) of the neck (2).
a to 10b relate to capsules (1) in which the insert (3) typically shown in
a and 14b relate to capsules (1) in which the insert (3) is an insert (3′″) with a so-called “very long” skirt with height h1>50 mm.
Other Figures
c shows an enlarged partial view of the top right corner in
a to 12d show axial sections through the device (9) or portion of device (9) for manufacturing metallic shells (4) from cylindrical blanks (4).
a and 11b correspond to two variants of the device (9).
c shows the initial state (before radial expansion) and
a to 12b correspond to
c and 12d diagrammatically show a radial expansion according to the state of prior art,
b shows a partial view of the capsule according to
c and 14d are enlarged views of the said expanded part (43) in the case in which the insert (3) comprises a flexible annular tab (302).
a to 15f and 17a to 17b are partial side views of the said shell (4) and ornamental or manual gripping means (430) of the said expanded part (43).
a to 16f and 18d are top views of the said shell (4) or capsule (1, 1′).
c and 17d are axial half-sections (left side) of a capsule (1′) placed on a neck before crimping in
a to 18c are views of a shell (4) in which the said cylindrical part (42) comprises a deformation with amplitude a′/b′ very much less than the amplitude a/b of the deformation of the said expanded part (43).
a is a view of the shell (4), while
c is a perspective partial side view of a portion of the cylindrical part (42′) of the outer skirt (41).
According to the invention, the said expanded part (43) may typically form an annular, continuous or discontinuous ring, its upper part being connected typically to the said outer head (40) or possibly to the said cylindrical part (42), and its lower part being connected to the said cylindrical part (42).
In many Figures related to capsules, for example
In this case, this radial overthickness firstly enables firmer manual gripping of the capsule, and secondly forms a very distinctive outer symbol.
The said expanded part (43). delimits an annular radial cavity (48) between cylinders with diameter D1 and diameter D2.
Typically, all or part of the said inner skirt (31) of the said insert (3) may cooperate with all or part of the said typically cylindrical part (42) of the said outer skirt (41), particularly so as to form the said assembly means.
As is clear in the Figures related to the capsules (1), the insert (3) and the said typically cylindrical part (42) of the shell are approximately the same diameter D1, such that the said insert (3) may be inserted into the said shell (4) without excessive play.
As shown in the Figures related to capsules (1), all or part of the said inner head (30) of the said insert (3) may be facing the said expanded part (43) of the said shell (4). However, as shown in
According to the invention, the said height H2 of the said radially expanded part (43) may be at least 2 mm and may typically vary from 3 mm to 15 mm. In many examples illustrated by the Figures, this height is 4 mm, 4.5 mm and 6 mm.
The said diameter D1 of the cylindrical part (42) may typically vary from 15 mm to 60 mm.
According to the invention, the ratio D2/D1 may vary from 1.02 to 1.15. and may typically vary from 1.05. to 1.10. This ratio is approximately 1.085 for the shells (4) in the examples and the FIGS.
As shown particularly in
As also shown in
According to one embodiment of the invention, the said expanded part (43) may be adjacent to the said outer head (40) in its upper part, and to the said cylindrical part (42) of the said outer skirt (41) in its lower part, the said outer head (40) and the said expanded part (43) being connected by a radius of curvature R1 varying from 1.5 mm to 5 mm as shown in
According to another embodiment of the invention shown in
The said outer skirt (41) may comprise several expanded parts (43, 43′, 43″) as shown for example in
It may be advantageous for the said inner head (30) of the said insert (3) to partly or completely face the said expanded part (43, 43′) so that the inner thread (32) of the said threaded inner skirt (31) of the said insert (3) is facing the said cylindrical part (42) of the said outer skirt (41).
This may be advantageous in the case in which the expanded part (43) is very tall, with a height H2. Since the shell (4) acts as a hoop around the insert, it is preferable that the part of the insert (3) carrying the said thread (32) is in direct contact with the said cylindrical part (42) with approximately the same diameter and therefore acting as a hoop, particularly to avoid any radial deformation of the said thread (32) when screwing or unscrewing under stress, particularly in the case in which a thin walled insert is used.
As shown in
Typically, when the said capsule (1) seals the said neck (2) by screwing, the axial height of the said expanded part (43) may be such that it is above the said outer thread (20) of the said neck (2) and possibly above the said locking ring (22) of the said neck (2).
According to the invention, the thickness of the said inner skirt (31) of the said insert (3) at the bottom of the groove may vary between 0.1 mm and 0.5 mm.
In the case of an insert with a “short” skirt (3′), this thickness can vary between 0.1 and 0.3 mm.
The thickness of inserts with longer skirts (3″) and (3′″) may vary from 0.25 to 3 mm.
The said insert (3) may be an insert (3′) for which the inner skirt (31) is said to be “short”, the said insert having a height h1 typically varying from 6 mm to 20 mm, the said height h1 typically corresponding to the height of the said neck from the said locking ring (22) as far as the bottom of the said outer thread (21). In this case, the ratio H/h1 may vary from 1.1 to 4 and preferably from 2 to 3.
This type of insert is shown in
In this case, the said outer skirt (41) may include the said tamper-evident means (6), the said outer skirt (41) being capable of forming a crimped zone (60) under the said tamper-evident ring (21), and the said first opening means (7), the said outer skirt (41) comprising a line of weakness (70) fixing a guarantee strip (71) above the said line of weakness by narrow connecting strips, and capable of forming the said crimped zone (60).
The said insert (3) may also be an insert (3″) for which the inner skirt (31) is said to be “long”, the said insert having a height h2 typically varying from 20 mm to 50 mm, the said height h2 typically corresponding to the height of the said neck from the said locking ring (22) as far as the bottom of the said tamper-evident ring (21) of the said neck (2), the ratio H/h2 typically varying from 0.8 to 1.1.
This case was shown in
As shown in
Regardless of whether the said insert (3) is an insert (3″) with a “long” skirt or an insert (3′″) with a “very long” skirt, the said inner skirt (31) may include the said tamper-evident means (6) and the said first opening means (7), the said inner skirt (31) comprising a guarantee strip (71) in its lower part connected by a line of weakness (70) provided with several narrow connecting strips, the said guarantee strip (71) cooperating with the said tamper-evident ring (21) by means of attachment tabs (61), so that the said tamper-evident ring (21) blocks the said tabs (61) and the said guarantee strip (71) in the axial direction, and thus first opening of the said capsule causes a visible rupture of the said narrow connecting strips along the said line of weakness (70).
The said guarantee strip (71) may comprise an outer projection (62) forming a rim for the said outer skirt, typically a stop rim with a width varying from 0.5 to 5 times the thickness Ep of the said outer skirt (41).
The said attachment tabs (61) may be connected to the said guarantee strip (71) or possibly to the said outer projection (62).
Each of the said attachment tabs (61) may be fixed to the said guarantee strip (71) or to the said projection (62) by a thinned part (610) of the said tab (61) making it flexible.
Thus, all that is necessary during capping of the said neck is to screw the said capsule (1) to the said neck so that the plurality of flexible tabs (61) are automatically blocked under the tamper-evident ring (21), these tabs being oriented so as to block any axial displacement.
According to one insert embodiment (3) shown in
According to the invention and as shown in
However, the said outer skirt (41) may form a surface of revolution over all or part of its height H, with a constant or variable radius depending on the height considered, or it may have a symmetry of rotation with angle 360°/N where H varies from 4 to 80, the said outer skirt (41) typically forming a plurality of N notches so as to facilitate manual gripping and rotation of the said capsule.
The non-expanded part (42) of the said outer skirt (41) may be non-cylindrical. In this case, the corresponding insert (3) must have the same profile.
It is thus possible to further accentuate the distinctive nature of the capsule (1) and facilitate manual gripping of it.
According to the invention, the said assembly means fixing the said inner part (3) and outer part (4) in rotation and axially may comprise any known type of means and particularly a mechanical or chemical anchor means, typically by gluing the said inner part (3) and outer part (4).
Thus, the said inner skirt (31) of the insert (3) may cooperate with the said cylindrical part (42) facing the shell (4), over all or part of the said height h, due to an adhesive layer fixing the said inner skirt (31) and the said cylindrical part (42).
Typically, the said outer part or shell (4) may be made of aluminium, tin or a metalloplastic multi-layer material with a deformation under stress similar to the deformation of aluminium or tin.
The said outer part (4) may be made of aluminium treated on the surface, typically brushed or anodised, to create a “metallic” appearance or colour.
Similarly, the said inner part (3) may be an insert moulded from a thermoplastic material, typically PE, PP, PET, SEBS or PS, possibly comprising one or several mineral fillers and typically talc.
In general, the said sealing means (5) of the said capsule (1) may typically comprise an add-on seal (50) or a sealing insert (51), or possibly a circular sealing lip.
The said sealing means (5) may comprise the said add-on seal (50) with a sufficiently large diameter to at least cover the locking ring (22) of the neck (2) and a compression means, carried by the inner surface of the said insert, to apply the said seal (50) to seal the said neck (2) during the said capping and typically on the locking ring (22) of the said neck (2).
According to the invention, the said compression means may be composed of or may comprise an axial compression means, the said axial compression means typically comprising a rib or an annular overthickness (300) formed on the inner wall of the said inner head (30) or the said inner skirt (31), and designed to compress the said add-on seal (50) along the said axial direction (10) on the upper part (220) of the said locking ring (22), part typically plane: or inclined by up to 45°.
According to the invention and as shown in
As shown in the left part of the
The said annular overthickness (300) may be in the form of a step formed at the inner junction of the inner head (30) and the inner skirt (31) so as to compress the said seal (50) in the radial direction.
As shown in
As shown in
As shown also in
According to the invention, the said compression means may comprise an axial compression means and a radial compression means, the said axial and/or radial compression means forming an integral part of the said insert (3) or forming an add-on part.
As shown in
In the capsule (1) according to the invention, a spout (8) and/or a so-called “anti-fill” device (8′) may be fixed reversibly to the said insert (3) or possibly to the said sealing means (5, 50, 51), typically due to an inner ring (35) of the said insert (3) temporarily cooperating with a peripheral skirt of the said spout (8) and/or the said anti-fill device (8′).
a, 5 and 9a show the case in which a spout (8) is fixed to the capsule (1) through the said sealing means (51), and particularly through a connecting ring (510).
a, 4a, 10, 13a and 13b show the case in which an “anti-fill” device (8′) is fixed to the capsule (1) through the said sealing means (51).
The connecting ring (510) fixes the devices (8) and (8′) to the capsule (1) such that when the capsule (1) is screwed to the neck, the devices (8) and (8′) are forced fitted into the neck and remain fixed to the neck due to the ribs (81)—these ribs (81) are shown in their original position in the figures, before insertion into the neck, these ribs being curved upwards in contact with the inner wall of the neck when these devices (8) and (8′) are inserted into the neck (2).
As shown in
Shock resistance tests called the “Charpy impact test” carried out with different aluminium alloys and thicknesses, with and without tabs (302), gave the following results on an arbitrary scale varying from 1 (poor resistance) to 5 (excellent resistance):
Alloy 8011—0.23 mm—without tab (302): 1
Alloy 3105—0.21 mm—without tab (302): 2
Alloy 3105—0.23 mm—without tab (302): 2.5
Alloy 8011—0.23—with tab (302): 5—no trace of shock.
Note that the only absolutely unacceptable mark is 1, level 5 corresponding to excellent resistance, and products with mark 2 or more could be marketed because they have satisfactory shock resistance.
However, as shown in
In all cases, regardless of whether a tab (302) is used, regardless of whether an adhesive material is inserted and regardless of whether an insert with an outer rim is used as shown in
According to the invention and as shown in
A circular section is shown in
Firstly, it is possible to have a plurality of relief or indentations formed on a circular section, as shown for example in
Secondly, other possibilities of non-circular sections are shown in
As shown in
The deformations (420) are said to be low amplitude (a′/b′) in opposition to a high amplitude deformation (a/b) related to the said expanded part (43), where “a” and “b” correspond to ΔD (D2-D1) and H2 described above.
Low amplitude deformations (420) are typically and traditionally formed by an elastomer punch, the amplitude (a′/b′) being low enough so that there is slight local expansion of the metal without a significant risk of thinning of the wall and the initiation of cracks (44). Typically a′/b′<0.2×a/b.
Another purpose of the invention shown in
Another purpose of the invention consists of a method for manufacturing capsules (1). In this method:
a) the said inner part or insert (3) may be procured, possibly including the said add-on seal, and possibly the said spout or “anti-fill” device (8, 8′),
b) a blank (4′) of the said outer part (4) can be formed, the said blank (4′) comprising a skirt (41′) with diameter D1 and height H′>H, typically by drawing, extrusion or spinning, from a typically metallic strip material,
c) the said blank (4′) can be transformed into the said outer part (4) by making a local radial expansion of the said outer skirt (41′) over the said height H2 ,
d) the said sealing means (50, 51) and/or the said insert (3) may possibly be assembled to the said outer part (4), typically by deposition of an adhesive between the said outer skirt (41) or onto the said cylindrical part (42), and then force fitting the said inner part (31) into the said outer part (41).
To manufacture the capsules (1) according to
The said blank (4′) is formed or procured and then the said outer part or shell (4) comprising the said expanded part (43) is formed by local deformation according to the invention.
The insert (3) is then assembled to the shell (4), typically by gluing.
However, capsules (1′) according to
As in the previous case, the said blank (4′) is formed or procured and then the said outer part or shell (4) comprising the said expanded part (43) is formed by local deformation according to the invention.
The seal (50) or the sealing insert (51) is then assembled to the shell (4).
In step c) of this method, the said local radial expansion may be obtained by axial compression of an expandable punch (95) in the said blank (4′) placed in a shaping die (91, 91′) forming a radial cavity (92) with a profile similar to the profile of the said expanded part (43), the said expandable punch (95) forcing a part of the said outer skirt (41′) into contact with the said inner wall of the said radial cavity (92), due to the said axial compression, typically obtained by axial displacement of a slide (96).
Advantageously, and as shown in
Otherwise, in other words when the metallic skirt does not creep freely on the side opposite the head as shown in
It is important to note that the said expanded part (43) has approximately the same thickness as the said cylindrical part (42) of the outer skirt (41) such that this expanded part, relatively exposed to shocks, does not have any mechanical weakness.
As shown in
According to the invention, the said expandable punch may be formed from an elastomer material capable of deforming under the said radial compression, the said elastomer material having a Shore hardness chosen as a function of the mechanical characteristics of the said material from which the said blank (4′) is made, typically metallic, the said hardness being greater than a given value depending on the mechanical characteristics and the thickness of the said material forming the said skirt (41′), such that the said axial compression develops a radial force of the said elastomer material greater than the local resistance of the said skirt (41′) to deformation by radial expansion.
Thus for example, an elastomer with a Shore A hardness of 80 to 85 will be sufficient if the said blank (4′) is made from a 0.23 mm thick 8011 aluminium alloy according to the Aluminum Association nomenclature, , while an elastomer with a Shore A hardness of 85 to 90 is necessary when the aluminium alloy is a 0.23 mm thick 3105 alloy according to the same nomenclature, since a 3105 alloy has higher mechanical characteristics than an 8011 alloy.
As shown in
As shown in
The method according to the invention is not limited to capsules alone, it may be applied to the transformation of any hollow cylindrical body with a metallic skirt, particularly in the packaging sector.
The method according to the invention has been set up on an industrial production line and used at normal production rates.
The shells (4) were made from aluminium alloy blanks (4′) in the 8000 and 3000 series:
a 0.23 mm thick 8011 alloy strip which, for the blank (4′) and shell (4), produces a thickness Ep of the skirt (41) varying from 0.23 mm at its upper part adjacent to the said head (40) to 0.245 mm at its lower part opposite the said head (40) and corresponding to opening of the shell (4) or the blank (4′).
The thickness Ep of the expanded part (43) was found to be equal to 0.23 mm, so that no thinning was observed.
a 0.21 mm thick 3105 alloy strip which, for the blank (4′) and shell (4), produces a thickness Ep of the skirt (41) varying from 0.21 mm at its upper part adjacent to the said head (40) to 0.220 mm at its lower part opposite the said head (40) and corresponding to opening of the shell (4) or the blank (4′).
The thickness Ep of the expanded part (43) was found to be equal to 0.21 mm, so that no thinning was observed.
a 0.23 mm thick 3105 alloy strip which, for the blank (4′) and shell (4), produces a thickness Ep of the skirt (41) varying from 0.23 mm at its upper part adjacent to the said head (40) to 0.240 mm at its lower part opposite the said head (40) and corresponding to opening of the shell (4) or the blank (4′).
The thickness Ep of the expanded part (43) was found to be equal to 0.23 mm, so that no thinning was observed.
The inserts (3) were made by injection moulding of PE or PP and the inserts (3) were assembled in the shells (4) usually using an adhesive available in the shops.
All Figures—except for
In the example in
b is a side view of the crimped capsule (1) in
In the example in
In the example in
b shows a side view of the uncrimped capsule (1) in
The example in
In the example in
The case in which the outer head (40) and the inner head (30) of the insert (3, 3′) are convex instead of being concave, is shown in dashed lines.
The example in
b shows a side view of the insert (3) in
c shows an enlarged partial view of the top right corner of
The examples in
The example in
b shows a side view of the capsule (1) in
The example in
Capsules were also manufactured with a second expanded part (43″), shown in dashed lines in the right part of
b is a side view of the capsule (1) in
The example in
In
The example in
In
a to 12b show an axial section along the axial direction (10) illustrating the method for forming the said expanded part (43) according to the invention, using a deformation device (9). This device (9) comprises:
a fixed part (90) typically comprising two dies, a lower die (91) and an annular upper die (91′) that cooperate particularly to form a radial cavity (92).
and a mobile part (93) typically comprising a rigid central part (94) comprising a foot (940), a slide (96) free to move in the axial direction with respect to the said rigid central part (94), and an expandable elastomer punch (95) capable of being radially deformed by displacement of the slide (96).
In
In
The right part of this Figure shows a variant in which the slide (96) comprises a shouldered part (960) that at the end of the travel distance bears on the end of the outer skirt (41) of the shell (4), so as to contribute to “spinning” the metal to force it into contact with the inner wall of the dies (91, 91′) particularly when the radii of curvature R1 and R2. are small (<1.5 mm).
c and 11d diagrammatically show deformations of the elastomer punch (95):
c shows the blank of the shell (4′) in position in the dies (91) and (91′) before deformation starts, the mobile part (93) being lowered, the slide (96) still being in the “high” position so as not to compress the said elastomer punch (95),
c shows the blank of the shell (4′) partially deformed by partial compression of the said elastomer punch (95), in dashed lines, the slide (96) being in an intermediate axial position,
d shows the shell (4) comprising an expanded part (43) formed by total compression of the said elastomer punch (95), the slide (96) being in the bottom axial position.
d shows a variant of the slide (96) that comprises a lower part (96′)—the part in contact with the elastomer punch (95)—formed from an elastomer with a Shore A hardness greater than the Shore A hardness of the elastomer punch, so as to form a “shock absorber” between the typically metallic slide (96) and the elastomer punch (95).
a and 12b correspond to
c and 12d illustrate the situation according to prior art in which compression of an elastomer punch (95′) causes isotropic compression (97) that blocks the shell blank metal around the periphery of the said cavity (92), like a blank holder, such that the metal part (47) facing the cavity (92) is expanded, thinning the metal and causing metal breakage and the formation of cracks (44).
The example in
The example in
The example in
b is a side view of the capsule (1) in
The examples in
The tab (302) in
The examples in
a shows a “smooth” expanded part without any ornaments or complementary manual gripping means (430).
b to 15f and 17a to 17b show examples of ornament or manual gripping means (430):
shaped like a series of vertical sticks in
shaped like a series of circles in
shaped like a series of triangles, alternately upside down, in
shaped like a series of inclined ovals in
shaped like a series of finger nails in
shaped like a series of “laurel leaves” in
shaped like a series of “offset laurel leaves” in
These ornamental and/or manual gripping means (430) may be recessed or raised printed, as shown in the case in
a to 16f and 18d show different sections of the said expanded part, the central circle in dashed lines corresponding to the section of the said non-expanded cylindrical part (42):
circular section in
polygonal section with 6 sides in
polygonal section with 10 sides in
circular section cut out by a plurality of grooves in
expanded part formed by a plurality of relief, in
expanded part comprising a plurality of relief, in
expanded part with oval section in
c and 17d show another purpose of the invention, a capsule (1′) without a threaded insert, but provided with an add-on seal. This capsule (1′) after having been placed on a neck (see
a to 18c show the case of a shell (4) of a capsule (1), in which the said cylindrical part (42) is a cylindrical part (42′) with a low deformation amplitude (a′/b′), capable of facilitating manual gripping of the capsule and forming a decorative pattern.
Advantages of the Invention
The invention has many advantages.
Firstly, it discloses a means of obtaining deformations with a large amplitude (a/b) on the skirt of the capsule (1) by local radial expansion of the skirt, but without these deformed parts being weakened or having defects such as cracks.
This means is an economic method compatible with industrial production rates, and that can easily be integrated into a conventional production line, the local radial expansion step being a complementary step following the conventional step for formation of the blank of the shell (4′).
It should be noted that this complementary step requires means with which those skilled in the art will be familiar and does not require a large investment.
Furthermore, this method has very broad applications, since it can be used not only to modify any type of capping capsule with a metallic skirt, but also any hollow body, typically (but not necessarily) cylindrical, with a metallic skirt or capable of behaving like a metal.
Finally, the capsules (1, 1′) obtained according to the invention have many advantages, to the extent that:
they have a metal shell (4) in which the outer skirt (41) has an approximately constant thickness Ep despite local radial deformations, which provides capsules with a shell free of defects and good mechanical shock resistance,
these radial deformations facilitate manual gripping and rotation of the capsule (screwing and unscrewing), particularly during the first opening of the capsule, such that it is not necessary to use a tool that requires breakage of the narrow connecting strips of the guarantee strip during this first opening,
these radial deformations form decorative, identification and customisation means of capsules, which is very useful in practice.
Number | Date | Country | Kind |
---|---|---|---|
03/08027 | Jul 2003 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/FR04/01667 | 6/29/2004 | WO | 5/25/2006 |