Container with a reinforced base and method for manufacturing such a container

Abstract

Container having a body and a bottom that together delimit an internal primary volume of the container, this container also comprising a protruding base comprising an outer wall and an inner wall, the base comprising a skirt which protrudes from the region of the join between the body and the bottom, and a foot which lies at a lower end of the skirt and defines a setting-down plane for the container, 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 by the weld.

Claims

1. A container (1) obtained by blow molding or stretch-blow molding from a parison (2) of plastic material, said container (1) comprising: a neck (3), a bottom (7), and a body (6) between the neck (3) and the bottom (7) and connecting the neck (3) with the bottom (7), the neck (3) the body (6) and the bottom (7) jointly delimiting an inner primary volume (11) of the container (1); and a base (12) projecting from a joining area (8) where the body (6) joins with the bottom (7), the base (12) formed of a fold of material that includes an outer wall (13) formed from an extension of the body (6), and an inner wall (14) formed from an extension of the bottom (7), the base comprising a skirt (15) where the outer wall (13) and the inner wall (14) extend from the joining area and are in mutual contact with each other, and a foot (16) that extends from an end portion of the skirt (15) and contains a hollow bulge in which an air bubble is trapped, the foot (16) defining a standing plane (17) for the container (1), wherein the inner and outer walls (13, 14) are welded to one another at a portion of the skirt (15) between the joining area (8) and a junction of the skirt (15) with the foot (16), and wherein the bottom (7) of the container, from the joining area (8) to a central area (10) surrounded by the joining area (8), forms an arch that is concave facing an interior of the container.

2. The container according to claim 1, wherein the skirt (15) has a shape of a truncated cone.

3. The container according to claim 1, wherein the skirt (15) is annular.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Other objects and advantages of the invention will be brought out in the description of an embodiment, given below with reference to the accompanying drawings in which:

(2) FIG. 1 is a bottom perspective view of a container with an integrated base;

(3) FIG. 2 is a partial radial cutaway view of the container of FIG. 1;

(4) FIG. 3 is a detail view, on an enlarged scale, of the container of FIG. 2, taken from the insert III;

(5) FIG. 4 is a view similar to FIG. 3, according to a variant embodiment;

(6) FIG. 5 is a cutaway view showing a a mold for the manufacture of the container of FIGS. 1 and 2, equipped with a wall and a mold bottom that is mounted to move relative to the wall between a low position (as illustrated in FIG. 5) and a high position;

(7) FIG. 6 is a detail view of the mold of FIG. 6, showing, on the left, the low position of the mold bottom and, on the right, the high position of the mold bottom;

(8) FIG. 7 is a detail cutaway view illustrating a welding operation performed on the base.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(9) Throughout this description, as well as, where appropriate, in the claims, the terms lower, upper, top, bottom, etc., are used with reference to the drawings for greater ease of understanding. They must not be understood as being limitations of the scope of the invention, particularly regarding the orientation of the containers or molds for their manufacture. Actually, the vertical orientation of the axis of the containers and the corresponding orientation of the manufacturing molds, with the mold bottoms located below the mold part or parts being used for the molding of the body of the containers, is only one preferred embodiment.

(10) Shown in FIG. 1 is a container 1, in this particular case a bottle, made by blow molding or stretch-blow molding from a parison 2 (in this case a preform) of thermoplastic material, in this case of PET (polyethylene terephthalate).

(11) This container 1 comprises, at an upper end, a neck 3 that opens toward a rim 4. In the extension of the neck 3, the container 1 comprises in its upper part a shoulder 5 that flares out in the direction opposite to the neck 3, this shoulder 5 being extended by a lateral wall or body 6, with a generally rotationally-cylindrical shape around a main axis X of the container 1 (illustrated in FIG. 5).

(12) The container 1 further comprises a bottom 7 that extends away from the neck 3, from a lower end of the body 6 that constitutes a joining area 8 between the body 6 and the bottom 7. As in the illustrated example, the joining area 8 between the body 6 and the bottom 7 can be narrowed relative to the rest of the body 6. According to a particular embodiment, the diameter measured in the area of the lower end of the body 6, at the site of the joining area 8 with the bottom 7, is, for example, about of the overall diameter of the body 6.

(13) In the example illustrated, the bottom 7 comprises an arch 9 that extends from the joining area 8 up to a central area 10 forming a projection toward the interior of the container 1 in the direction of the axis X. According to an embodiment illustrated in FIG. 2, the arch 9 is concave and faces toward the interior of the container 1. As a variant, however, the arch could be concave and face outward.

(14) The body 6 and the bottom 7 together delimit an inner primary volume 11 of the container 1, into which the contents (typically a liquid, particularly a beverage, which can be carbonated) of the container 1 are intended to be introduced.

(15) As is seen in the figures, the container 1 further comprises a base 12 that is formed projecting from the joining area 8, at the lower end of the body 6, by a fold of material that is produced by blow molding. It is by this base 12 that the container 1 can rest on a flat surface such as a table.

(16) The base 12 exhibits 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.

(17) More specifically, the base 12 comprises, in the first place, a skirt 15, which extends projecting from the joining area 8, and a foot 16, which extends at a lower end of the skirt and defines an annular standing plane 17 for the container 1.

(18) According to an embodiment illustrated in FIGS. 2 and 3, the skirt 15 has an approximately conical shape that is flared outward from the container 1 (in other words, downward). According to a variant embodiment illustrated in FIG. 4, the skirt 15 is annular and extends approximately in the manner of a collar around the axis X.

(19) As is seen clearly in FIGS. 3 and 4, the foot 16 forms a hollow bulge in radial projection opposite the axis X. In other words, the foot 16 forms approximately a circular ring around the axis X, with a radial cross-section approximately in the shape of a d (as shown in FIGS. 3 and 4). In this way, the outer wall 13, the inner wall 14, and the standing plane 17, while extending in a transverse plane that is perpendicular to the axis X ensuring the junction between them, jointly define a secondary volume 18.

(20) In the area 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 inner wall 14 are locally welded to one another in the area of the skirt 15 by a weld 19. This weld 19 can be a spot weld made, for example, halfway up the skirt 15, or a weld that extends over a more extensive surface between a surrounding area of the joining area 8 between the body 6 and the bottom 7 and a surrounding area of the junction between the skirt 15 and the foot 16.

(21) The weld 19 can form a local bond between the material of the outer wall 13 and that of the inner wall 14, thus forming locally, in the area of the skirt 15, a single body, or else be an annular weld extending to the interface between the outer wall 13 and the inner wall 14.

(22) In the foot 16, however, the outer wall 13 and the inner wall 14 are separated from one another to form the secondary volume 18 in which a toroidal air bubble is trapped. This air bubble, trapped in the foot 16 during blow molding, is at a pressure that is higher than or equal to the atmospheric pressure. However, since the weld is, as we will see, produced by an additional operation after the blow molding, a relative equalization of the pressures between the primary volume 11 and the secondary volume 18 can occur during the degassing of the container 1 following the blow molding, by a release at the interface between the outer wall 13 and the inner wall 14 before their welding.

(23) The welding 19 contributes to making the skirt 15 (and therefore the base 12) rigid by preventing the sliding of the walls 13, 14 over one another. A better mechanical strength of the bottom 7 and a slighter risk of inverting it in particular results from it.

(24) By its shape, the foot 16 offers a relatively wide standing plane 17, favorable for good stability of the container 1. Further, the bulge of the foot 16, by its rounded shape, facilitates the conveying of the container 1 over any type of conveyor (belt, roller) and limits the risks of wedging of the base 12 in the gaps between adjacent conveyor elements.

(25) In FIGS. 5 and 6, a mold 20 for the manufacture by blow molding or stretch-blow molding of the container 1 from a parison 2 (in this case a preform) has been shown.

(26) This mold 20 comprises a peripheral wall 21, defining a cavity 22, that constitutes the impression of the body 6 of the container 1 and that is pierced with an opening 23 at one end, and opposite the opening, a mold bottom 24 having a raised surface 25 whose shape constitutes the impression of the bottom 7 of the container 1. The mold bottom 24 and the peripheral wall 21 are mounted to move in relation to one another between an initial position, in which the raised surface 25 is separated from the cavity 22, and a final position, in which the raised surface 25 blocks the opening 23 to complete the impression of the container 1.

(27) In the preferred embodiment, illustrated in FIG. 5, in a way known in the art, the peripheral wall 21 is made up of at least two mating parts 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 separated from one another during the insertion of a preform and during the withdrawal of a container, even though they are flattened against one another to form the cavity 22 during the manufacture.

(28) The mold 20 is oriented along a vertical axis, corresponding to that of the container 1, and the container 1 is formed neck up. To do this, the cavity 22 is oriented with its opening 23 downward, and the mold bottom 24 is found in the area of the opening 23 of the cavity 22, with the raised surface 25 oriented upward, therefore toward the interior of the cavity. Further, to impart the relative mobility of the mold bottom 24 and the peripheral wall 21, it is the mold bottom 24 that is mounted to move in relation to the peripheral wall 21 between a low position (illustrated in FIG. 5 and on the left in FIG. 6), in which the raised surface 25 is separated from the cavity 22, and a high position, in which the raised surface 25 blocks the opening 23 to complete the impression of the container 1.

(29) As can be seen in FIG. 6, the peripheral wall 21 defines, beyond the opening 23, an inner peripheral surface 26 constituting the impression of the outer wall 13 of the base 12, including a truncated cone-shaped upper cross-section 27 constituting the outer impression of the skirt 15 and a toroidal lower cross-section 28 constituting the impression of the bulge of the foot 16. In a complementary manner, the mold bottom 24 exhibits, in the extension of its raised surface 25, an outer peripheral surface 29 constituting the impression of the inner wall 14 of the base 12, including a truncated cone-shaped upper cross-section 30 constituting the outer impression of the skirt, and an annular lower cross-section 31 constituting the impression of the standing plane 17.

(30) The container 1 is formed in the following manner. The parison 2 is first inserted into the mold 20 after having been previously heated to a temperature greater than the glass transition temperature of the material (or about 80 C. for PET). The parts 21A and 21B are then separated, and the mold bottom 24 is in low position. Then, the parts 21A and 21B are brought together to form the cavity 22.

(31) A pressurized fluid (particularly air) is then introduced into the parison 2 to form the container 1 by blow molding. The material undergoes an expansion (optionally accompanied by a stretching, by means of a stretching rod, not shown) in the cavity 22 until coming in contact with the peripheral wall 21 and with the raised surface 25 of the mold bottom 24, the mold bottom being kept in low position.

(32) Under the pressure of the blow molding, the material then flows into the volume made between the inner peripheral surface 26 and the outer peripheral surface 29. At a predetermined time, the mold bottom 24 is moved to its high position, which brings the material of the bottom 7 to its final shape and position and forms the base 12 by pinching the material in the area of the skirt 15, although no welding of the material in the skirt 15 results, the PET not making it possible to perform a welding by simple contact at the temperatures used for the blow molding, in contrast to PVC, for example.

(33) Once the container 1 is formed, it is extracted from the mold 20, and an additional welding operation is performed in the area of the skirt 15. This welding is performed by means of a welding device 32 that is separate from the mold 20.

(34) According to a particular embodiment, illustrated in FIG. 7, the welding is performed ultrasonically. The device 32 is then an ultrasonic welding device, which comprises a sonotrode 33 connected to a converter 34 of electrical energy into mechanical energy, applied against the inner wall 14 in the area of the skirt 15, and a contact anvil 35 applied on the other side against the outer wall 13, also in the area 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 form their local bond.

(35) As a variant, the welding can be performed by means of a laser beam (laser welding), or else by means of a radiofrequency field (also called high-frequency welding), the latter being particularly suited to polymers such as PET.

(36) Further, although the welding operation described above is applied to a base 12 comprising a hollow foot 16 defining a secondary volume 18, this welding can be applied to a base whose foot would be solid, i.e., this foot would be formed by a lower end of the walls 13 and 14 that would be in contact with one another up to the standing plane 17.