EP2978584A1

EP2978584A1 - Container with a reinforced base, and method for manufacturing such a container

Info

Publication number: EP2978584A1
Application number: EP14716903.1A
Authority: EP
Inventors: Mikael Derrien
Original assignee: Sidel Participations SAS
Current assignee: Sidel Participations SAS
Priority date: 2013-03-27
Filing date: 2014-03-21
Publication date: 2016-02-03
Also published as: US10442128B2; FR3003793A1; FR3003793B1; US10611075B2; US20190315042A1; WO2014154974A1; CN105050796A; US20160288398A1

Abstract

Container (1) having a body (6) and a bottom (7) that together delimit an internal primary volume (11) of the container (1), this container (1) also comprising a protruding base (12) comprising an outer wall and an inner wall, the base (12) comprising a skirt which protrudes from the region (8) of the join between the body (6) and the bottom (7), and a foot which lies at a lower end of the skirt and defines a setting-down plane for the container (1), in which container: - the walls are locally welded together in the region of the skirt; - the foot forms a hollow bulge, and the outer wall, the inner wall and the setting-down plane together define a secondary volume isolated from the primary volume (11) by the weld.

Description

Reinforced base container and method of making such a container

The invention relates to the field of containers, especially bottles or jars, manufactured by blow molding or stretch blow molding from plastic blanks such as polyethylene terephthalate (PET).

The manufacture by blowing of a container usually consists in introducing into a mold, constituting the impression of the container, a blank (it may be a preform or an intermediate container obtained by pre-blowing a preform), previously heated to a temperature above the glass transition temperature of the material, and to inject into the blank a fluid (including a gas such as air) under pressure. The blowing can be completed by preliminary stretching of the blank by means of a sliding rod.

The double molecular orientation that the material undergoes during blowing (axial and radial, respectively parallel and perpendicular to the general axis of the container) gives the container a certain structural rigidity.

However, market economy requirements, or anti-pollution standards, lead manufacturers to use ever less material. The result is, at equal shape, a decrease in the mechanical performance of the containers, due in particular to a lower stiffness of the bottom which tends to sag under the hydrostatic pressure of the contents.

This is why a lot of work is done by manufacturers on the shape of funds to increase the rigidity.

It is thus known to stiffen the bottom by means of ribs, cf. eg. French patent FR 2 753435 (Sidel). This bottom retains its mechanical strength without turning as long as the conditions of volume and / or pressure in the container are normal. However, when these conditions are extreme, the bottom still tends to sag.

In addition, there are known vaulted funds known as "Champagne" funds, cf. for example the French patent FR 2,730,471 or its US equivalent US 6,153,145. This type of background, inspired by the bottoms of Champagne glass bottles, has the advantage of offering good strength and good stability, but however, it has the disadvantage of consuming a large amount of material. In practice, the most mechanically stable container bottoms are those whose shape is closest to the sphere because of a relatively uniform stress distribution. However a container with a spherical bottom can not be stable if it is not otherwise provided with a base. This is why the majority of the containers with spherical bottoms (intended in particular for carbonated beverages), generally comprise pedestals reported (in particular by snapping or gluing, see typically the US Pat. No. 4,553,275 Owens Illinois) or protruded from the background, cf. US Patent 5,122,325 Broadway Companies.

Plinths reported require additional manufacturing and reprocessing of waste, which make this type of container today undesirable on the market. As for the bases formed protruding, they seem promising but generate manufacturing difficulties, to the point that, in the aforementioned US Pat. No. 5,122,225, the base is already rough on the preform from which the container is formed. This technique is not without inconvenience. First, it requires additional material. Then, the final formation of the base during the blowing of the container is difficult to control.

Also known, especially for soft drinks applications, many petaloid-shaped bottoms comprising alternating valleys, hemispherical curvature, and protruding feet, the ends of which form a seat for the container, cf. eg. French patent application FR 2 959214 or its US equivalent US 2013/043255. The petaloid background appears as a relatively successful solution combining good resistance to high internal pressures in the container (due to the hemispherical curvature of the valleys) and relative lightness. However, the petaloid bottom has the disadvantage of being unstable during container handling operations on the packaging lines.

An object of the invention is to provide a method of manufacturing an integrated pedestal container (and such a container) responding, separately or jointly, to the following requirements:

offer good mechanical performance, in particular good bottom stability, offer good puffiness,

consume little material.

For this purpose, it is proposed, according to a first aspect, a method of manufacturing a container having a neck, a body and a bottom jointly delimiting an internal primary volume of the container, this container further comprising a base, formed protruding from a junction zone between the body and the bottom by a fold of material, and comprising an outer wall, formed in the extension of the body, and an inner wall formed in the extension of the bottom, the base comprising a skirt, projecting from the junction zone between the body and the bottom, and a foot, which extends at a lower end of the skirt, and defines a laying plane for the container, this method being conducted in a mold comprising, on the one hand, a peripheral wall delimiting a cavity whose internal surface constitutes the impression of the body of the container and that of the outer wall of the base and, on the other hand, a mold base which has a surface connects f whose shape is the footprint of the bottom of the container and the inner wall of the base and which cooperates with an open end of the cavity, the mold base and the peripheral wall being mounted movable relative to each other between an initial position, in which the raised surface is spaced from the cavity, and a final position, in which the raised surface closes the opening of said end to complete the impression of the container, which method comprises the operations of :

introducing a previously heated blank into the mold while the mold bottom and the peripheral wall are in the initial position,

injecting into the blank a fluid under pressure,

placing the mold base and the peripheral wall in the final position, in order to cause said fold of constituent material of the skirt,

extract the container thus formed from the mold,

solder locally (in particular by ultrasound - alternatively, the welding can be performed by other techniques such as laser or radiofrequency) the outer wall and the inner wall of the base at the level of the skirt, within a separate welding apparatus of the mold. Such a weld makes it possible to stiffen the base, to the benefit of the stability of the container obtained. The puffability of the container is not affected by this technique, which otherwise does not require additional material.

It is proposed, according to a second aspect, a container obtained by blow molding or blow-molding from a plastic blank, this container having a neck, a body and a bottom jointly delimiting an internal primary volume of the container, this container comprising in addition a base, formed projecting from a junction zone between the body and the bottom by a fold of material, and comprising an outer wall, formed in the extension of the body, and an inner wall, formed in the extension from the bottom, the base comprising a skirt, which protrudes from the junction zone between the body and the bottom, and a foot, which extends to a lower end of the skirt and defines a plane of installation for the receptacle, a receptacle in which:

the walls are welded locally to one another at the level of the skirt;

the foot forms a hollow bulge, the outer wall, the inner wall and the laying plane jointly defining a secondary volume isolated from the primary volume by the weld.

The skirt is for example frustoconical or annular.

Other objects and advantages of the invention will become apparent in the light of the description of an embodiment, given hereinafter with reference to the accompanying drawings, in which:

Figure 1 is a perspective view from below of an integrated pedestal container;

Figure 2 is a partial radial sectional view of the container of Figure 1;

Figure 3 is a detail view, on an enlarged scale, of the container of Figure 2, taken in the box III;

Figure 4 is a view similar to Figure 3, according to an alternative embodiment;

FIG. 5 is a sectional view showing a mold for the manufacture of the container of FIGS. 1 and 2, equipped with a wall and a mold base mounted movable with respect to the wall between a low position (as shown in Fig. 5) and a high position;

FIG. 6 is a detailed view of the mold of FIG. 6, showing, on the left, the low position of the mold base and, on the right, the high position of the mold base;

Figure 7 is a detail sectional view illustrating a welding operation performed on the base.

Throughout the present description, as well as, where appropriate, in the claims, the terms "lower", "upper", "high", "low", etc., are used with reference to the drawings for greater ease of understanding. They should not be understood as being limitations of the scope of the invention, particularly as to the orientation of the containers or molds for their manufacture. Indeed, the vertical orientation of the axis of the containers and the corresponding orientation of the molds of manufacture, with the mold bottoms disposed below the mold part or parts for molding the body of the containers is only a preferred embodiment.

FIG. 1 shows a container 1, in this case a bottle, produced by blow molding or stretch blow molding from a blank 2 (in this case a preform) made of thermoplastic material, in this case PET (polyethylene). terephthalate).

This container 1 comprises, at an upper end, a neck 3 opening on a rim 4. In the extension of the neck 3, the container 1 comprises in its upper part a shoulder 5 flaring in the direction opposite to the neck 3, this shoulder 5 being extended by a side wall or body 6, of generally cylindrical shape of revolution about a main axis X of the container 1 (shown in Figure 5).

The container 1 further comprises a bottom 7 which extends opposite the neck 3, from a lower end of the body 6 constituting an area 8 of junction between the body 6 and the bottom 7. As in the illustrated example, the zone 8 of junction between the body 6 and the bottom 7 may be narrowed relative to the remainder of the body 6. According to a particular embodiment, the diameter measured at the lower end of the body 6, at the of the zone 8 joining the bottom 7, is for example about 4/5 of the overall diameter of the body 6. In the example shown, the bottom 7 comprises a vault 9 which extends from the junction zone 8 to a central zone 10 projecting towards the inside of the container 1 in the direction of the X axis According to an embodiment illustrated in FIG. 2, the roof 9 is concavity-facing towards the inside of the container 1. In a variant, however, the roof could be concavity facing outwards.

The body 6 and the bottom 7 jointly delimit an internal primary volume 11 of the container 1, into which the contents (typically a liquid, especially a beverage, which may be carbonated) of the container 1 are intended to be introduced.

As seen in the figures, the container 1 further comprises a base 12 formed projecting from the junction zone 8, at the lower end of the body 6, by a fold of material coming blowing. It is by this base 12 that the container 1 can rest on a flat surface such as a table.

The base 12 has a double thickness and comprises an outer wall 13, formed in the extension of the body 6, and an inner wall 14 formed in the extension of the bottom 7 and folded against the outer wall 13.

More specifically, the base 12 comprises, in the first place, a skirt 15, which projects from the junction zone 8, and a foot 16 which extends at a lower end of the skirt and defines a plane 17 of annular laying for the container 1.

According to an embodiment illustrated in Figures 2 and 3, the skirt 15 is substantially conical flared outwardly of the container 1 (in other words, downwards). According to an alternative embodiment illustrated in Figure 4, the skirt 15 is annular and extends substantially in the manner of a flange around the axis X.

As can be seen in FIGS. 3 and 4, the foot 16 forms a hollow bulge projecting radially away from the axis X. In other words, the foot 16 substantially forms a torus of revolution around the X axis, substantially radial section d-shaped (as shown in Figures 3 and 4). In this way, the outer wall 13, the inner wall 14 and the laying plane 17, extending in a transverse plane perpendicular to the X axis, ensuring the junction between them, jointly define a secondary volume 18. At the level of the skirt 15, the outer wall 13 and the inner wall 14 are in mutual contact. More specifically, the outer wall 13 and the wall

14 internal are welded locally to one another at the level of the skirt

This weld 19 can be a spot weld made for example at mid-height of the skirt 15, or a weld extending over a larger surface between a vicinity of the junction zone 8 between the body 6. and the bottom 7 and a vicinity of the junction between the skirt 15 and the foot 16.

The weld 19 can achieve a local melting of the material of the outer wall 13 and the inner wall 14 which thus form locally, at the level of the skirt 15, a unitary body, or be in the form of a weld bead annular extending at the interface between the outer wall 13 and the inner wall 14.

In the foot 16, in contrast, the outer wall 13 and the inner wall 14 are spaced from each other to form the secondary volume 18 in which is trapped a toric air bubble. This air bubble, trapped in the foot 16 during blowing, is at a pressure greater than or equal to atmospheric pressure. However, since the welding is, as we shall see, carried out by an additional operation subsequent to blowing, there may be a relative equalization of the pressures between the primary volume 11 and the secondary volume 18 during degassing of the container 1 following blowing, by a leak at the interface between the outer wall 13 and the inner wall 14 before welding.

The weld 19 helps to stiffen the skirt 15 (and thus the base 12) by preventing the sliding of the walls 13, 14 one on the other. This results in particular better mechanical strength of the bottom 7 and a lower risk of turning it.

By its shape, the foot 16 offers a relatively wide laying plan 17, favorable to good stability of the container 1. In addition, the bulge of the foot 16, by its rounded shape, facilitates the transport of the container 1 on any type of carrier (Tape, rollers) and limits the risk of jamming of the base 12 to the gaps between adjacent conveyor elements.

There is shown in Figures 5 and 6 a mold 20 for the manufacture by blowing or stretching the container 1 from a blank 2 (in this case a preform). This mold 20 comprises a peripheral wall 21, defining a cavity 22, constituting the imprint of the body 6 of the container 1 and pierced with an opening 23 at one end, and, facing the opening, a bottom 24 of the mold having a surface 25 in relief whose shape is the imprint of the bottom 7 of the container 1. The bottom 24 of the mold and the peripheral wall 21 are mounted movable relative to each other between an initial position, in which the surface 25 in relief is spaced from the cavity 22, and a final position, in which the surface 25 in relief closes the opening 23 to complete the cavity of the container 1.

In the preferred embodiment, illustrated in FIG. 5, in a manner known per se, the peripheral wall 21 consists of at least two complementary pieces 21A, 21B (known by the name of half-molds or half-shells), which each define a portion of the cavity 22. The two parts can be spaced from each other during the insertion of a preform and the withdrawal of a container, while they are pressed against each other to form the cavity 22 during manufacture.

The mold 20 is oriented along a vertical axis, corresponding to that of the container 1, and the container 1 is formed neck up. For this, the cavity 22 is oriented with its opening 23 downwards and the bottom 24 of the mold is at the opening 23 of the cavity 22, with the surface 25 in relief facing upwards, so towards the inside the cavity. In addition, in order to confer relative mobility of the mold bottom 24 and the peripheral wall 21, it is the bottom 24 of the mold which is movably mounted relative to the peripheral wall 21 between a low position (illustrated in FIG. and left in FIG. 6), in which the raised surface 25 is spaced from the cavity 22, and a raised position, in which the raised surface 25 closes the opening 23 to complete the cavity of the container 1.

As can be seen in FIG. 6, the peripheral wall 21 defines, beyond the opening 23, an inner peripheral surface 26 constituting the imprint of the outer wall 13 of the base 12, including a frustoconical upper section 27 constituting the the external imprint of the skirt 15 and a lower toric section 28 forming the impression of the bulge of the foot 16. In a complementary manner, the bottom 24 of the mold has, in the extension of its surface 25 in relief, an outer peripheral surface 29 constituting the imprint of the wall 14 internal base 12, including a frustoconical upper section 30 constituting the external imprint of the skirt, and an annular lower section 31 constituting the footprint of the laying plane 17.

The container 1 is formed in the following manner. The blank 2 is first introduced into the mold 20 after being previously heated to a temperature above the glass transition temperature of the material (ie about 80 ° C for PET). The parts 21A and 21B are then spaced apart and the bottom 24 of the mold is in the low position. Then the parts 21A and 21B are brought together to form the cavity 22.

A fluid (in particular air) under pressure is then introduced into the blank 2 to form the container 1 by blowing. The material is expanded (possibly accompanied by stretching, by means of a drawing rod not shown) in the cavity 22 until it comes into contact with the peripheral wall 21 and the raised surface 25 of the bottom 24. mold, the latter being kept in the low position.

Under the pressure of the blowing, the material then flows into the volume formed between the inner peripheral surface 26 and the outer peripheral surface 29. At a predetermined time, the bottom 24 of the mold is moved to its upper position, which brings the material of the bottom 7 to its final shape and position and forms the base 12 by gripping the material at the level of the skirt 15, without as much as it results in a welding of the material in the skirt 15, the PET does not allow to achieve a single contact welding at the temperatures used for blowing, unlike PVC for example.

Once the container 1 has been formed, it is extracted from the mold 20 and an additional welding operation is carried out at the level of the skirt 15. This welding is carried out by means of a welding apparatus 32 distinct from the mold 20.

According to a particular embodiment, illustrated in Figure 7, the welding is performed by ultrasound. The apparatus 32 is then an ultrasonic welding apparatus, which comprises a sonotrode 33 connected to a converter 34 of electric energy mechanical energy, applied against the inner wall 14 at the skirt 15, and an anvil 35 applied to the opposite against the outer wall 13, also at the level of the skirt 15. The ultrasonic vibrations of the sonotrode sufficiently heat the material at the interface between the outer wall 13 and the inner wall 14 to achieve their local melting. Alternatively, the welding can be performed by means of a laser beam (laser welding), or by means of a radio frequency field (also called high frequency welding), the latter being particularly suitable for polymers such as PET .

In addition, although the welding operation described above is applied to a base 12 comprising a hollow foot 16 defining a secondary volume 18, this weld can be applied to a pedestal whose foot would be full, that is, that is to say that this foot would be formed by a lower end of the walls 13 and 14 which would be in contact with each other to the laying plane 17.

Claims

1. A method of manufacturing a container (1) having a neck (3), a body (6) and a bottom (7) jointly delimiting an internal primary volume (11) of the container (1), this container (1) further comprising a base (12) projecting from a junction zone (8) between the body (6) and the bottom (7), by a fold of material and comprising a wall

(13) external, formed in the extension of the body (6), and a wall

(14), formed in the extension of the bottom (7), the base (12) comprising a skirt (15) at which the outer wall (13) and the inner wall (14) are in mutual contact thereby defining a secondary volume (18), and a foot (16) in which is trapped an air bubble, which extends at a lower end of the skirt (15) and defines a laying plane (17) for the container (1). ), this method being conducted in a mold (20) comprising, on the one hand, a peripheral wall (21) defining a cavity (22) whose internal surface constitutes the impression of the body (6) of the container (1) and that of the outer wall (13) of the base (12), and, on the other hand, a bottom (24) of mold which has a surface (25) in relief whose shape constitutes the footprint of the bottom (7) of the container (1) and the inner wall (14) of the base (12) and which cooperates with an open end of the cavity (22), the bottom (24) of the mold and the wall (21) peripheral being mounted movable the a relative to the other between an initial position, in which the surface (25) in relief is spaced from the cavity (22), and a final position, wherein the surface (25) in relief closes the opening of the said end to complete the impression of the container, the method comprising the steps of:

introducing a previously heated blank (2) into the mold (20) while the mold bottom (24) and the peripheral wall (21) are in the initial position,

injecting into the blank (2) a fluid under pressure,

placing the bottom (24) of the mold and the peripheral wall (21) in the final position, in order to cause said folding of constituent material of the skirt (15) thus forming a foot (16) in which is trapped a bubble of air,

extracting the container (1) thus formed from the mold (20), a welding operation of welding the outer wall (13) and the inner wall (14) of the base (12) at the level of the skirt (15), in a separate welding apparatus (32) of the mold (20). )

this method being characterized in that it comprises:

an operation, prior to the welding operation, of bringing the inner wall (14) and the outer wall (13) into contact over the entire length of the skirt (15) so that the skirt (15) extends projecting from the zone (8) of junction between the body (6) and the bottom (7).

2. Method according to claim 1, characterized in that the weld (19) is performed by ultrasound.

3. Method according to claim 1, characterized in that the weld (19) is performed by laser.

4. Method according to claim 1, characterized in that the weld (19) is performed by radio frequencies.

5. Container (1) obtained by blow molding or stretch blow molding from a plastic blank (2), said container (1) having a neck (3), a body (6) and a bottom (7) defining together an internal primary volume (11) of the container (1), this container (1) further comprising a base (12) projecting from a junction zone (8) between the body (6) and the bottom ( 7), by a fold of material and comprising an outer wall (13) formed in the extension of the body (6), and an inner wall (14) formed in the extension of the bottom (7), the base (12). comprising a skirt (15) at which the outer wall (13) and the inner wall (14) are in mutual contact thereby defining a secondary volume (18) and a foot (16) extending at a lower end the skirt (15) forming a hollow bulge in which is trapped an air bubble, the foot (16) defining a laying plane (17) for the container (1), characterized in that:

the walls (13, 14) are welded to one another at the level of the skirt (15) between a vicinity of the junction zone (8) and a vicinity of the junction between the skirt (15) and the foot (16), the skirt (15) projecting from the region (8) of junction between the body (6) and the bottom (7).

6. Container according to claim 5, characterized in that the skirt (15) is frustoconical.

7. Container according to claim 5, characterized in that the skirt (15) is annular.