RU1813058C - Container for carbonized beverages - Google Patents

Abstract

Use: for packaging, storage and transportation of drinks containing carbon dioxide. SUMMARY OF THE INVENTION: the container is blown from plastic material and contains a cylindrical body with side walls and a base including a bottom wall and hollow legs, the supporting surfaces of which are inclined so that their inner edges are placed above the outer ones. The supporting surfaces of the legs are rotatable relative to the outer edges until their inner edges are placed flush with the latter, with the formation of a horizontal surface under the action of the contents of the container. The container is resistant to the effects of dynamic loads during transportation, and has high strength. 6 C.p. f-ls, 9 ill.

Description

The invention relates to a one-piece plastic bottle for drinks, and more specifically, to an improved bottle of this type, which has flat horizontal surfaces of increased area that rigidly hold the bottle in an upright position when it is full.

The aim of the invention is to increase the strength and stability of the container.

Fig. 1 is a side view of a carbonated beverage container; figure 2 is also a bottom view; in Fig.3 - section aa in Fig.2; figure 4 is an enlarged view of the cross section aa in figure 2; Figs. 5,6 show exemplary embodiments of a container with various base structures; figure 7 - container plan; on Fig is a bottom view of the containers depicted in Fig.5,6; Fig.9 is a section bB in Fig.8.

The carbonated beverage container is blown under pressure from a plastic material, preferably oriented along two axes of saturated polyester, for example polyethylene terephthalate, and contains a cylindrical body 1 with side walls 2 and a base 3 including a bottom wall 4 curved in an arc downward from the bottom edges 5 of the side walls 2. The donna wall 4 has a constant radius of curvature, this radius being greater than the radius of the cylindrical body.

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The lower edge of the side wall 2 is connected to the bottom wall 4 in a relatively small radius. A horizontal central portion 6 is connected to the bottom wall A, the container has at least three hollow legs 7 located radially at the same distance from the other and from the central portion 6 of the bottom wall A and including inclined outer walls 8 formed by the sections of the side walls 2 of the housing; protruding therein, and supporting surfaces 9 with inner and outer edges 10 and 11, respectively.

The supporting surfaces of the legs are located around the circumference, while the outer diameter of the housing 1. is greater than the diameter of the circle along which the outer edges 11 of the supporting surfaces 9 of the hollow legs are located. The supporting surfaces of the hollow legs are arranged obliquely so that their inner edges 10 are placed above the outer edges 11, while the supporting surfaces are rotatable relative to the outer edges 11 until their inner edges are placed at the same level with the latter to form a horizontal surface - under the action of the contents container.

The hollow legs 7 of the container can be made in such a way that their outer walls 8 taper down from the top to bottom. The outer wall of each leg can be bent in an arc from top to bottom.

It is possible to make the container in such a way that the central portion 6 of the bottom wall 4 is connected to the inner edges 10 of the supporting surfaces 9 of the legs 7 by means of inclined sections 12 arranged radially.

It is preferable that the container be formed in such a way that the outer walls 8 of the hollow legs 7 are connected to the outer edges 11 of their supporting surfaces 9, each leg having a pair of side walls 13 connected to the bottom wall A and the supporting surface 9 of the leg, the side walls 13 of adjacent legs 7 are located at an angle to one another and together with the bottom wall A form ribs 14 serving to separate the legs. The supporting surface 9 of the legs 7 may have a trapezoidal shape.

The base 3 of the container may have five legs.

The upper part 15 of the housing is constricted and comprises a flange 16 and a threaded neck 17.

Each abutment surface 9 forms a flat surface that is inclined radially inward and upward so that the outer edge 11 of each abutment surface of the leg 7 is lower than the inner edge 10. The outer edges 11 of the abutment surfaces are adjacent to the lower edges of the outer walls 8 of the legs 7 and are connected with them by means of rims having a relatively small radius. The outer edges 11 of the supporting surfaces form, the contact zones of the supporting surfaces of the container having a diameter only slightly smaller than the diameter of the side

walls 2. By arranging the outer edges of the supporting surfaces of the legs 7 as far as possible in the radial direction outward, the stability of the bottle is increased.

When the container is filled with a carbonic acid drink; the pressure inside the container causes the central portion 6 to tilt down to the position indicated by dash-dot lines in Figure 3. AT

the result of this central movement

of section b, the supporting surfaces 9 of the legs 7 also move downward, turning generally around the outer edges 11 to the horizontal position indicated by position 18. In this turned position, the supporting surfaces are now in close contact with the horizontal surface on which the container is held. The outer edges 11 of the supporting surfaces 5 remain in place, therefore, the diameter of the contact zones of the supporting surface does not decrease when the central portion 6 deviates. Thus, the stability of the container does not decrease when it is full.

The angle at which the supporting surfaces 9 are deviated from the horizontal supporting surface depends on the size of the container and the thickness of the base material 3. These

5, two factors will determine the amount of base deflection caused by internal pressure.

Along with maintaining the stability of the base 3, when the supporting surfaces of the legs are deflected to a horizontal position, a reduction in the oscillation of the container is also provided. A vertical container will tend to oscillate forward and backward during tipping if it is not

5 is subjected to a very strong track leading to its overturning. Obviously, this oscillation will be damped and the container will come to rest. When the abutment surfaces 9 are in close contact with the horizontal abutment surface, greater damping is provided than when the container is empty and rests along the outer edges 11 of the inclined abutment surfaces 9.

Another embodiment of the construction according to this invention is presented in the form of a blown molded plastic container of FIGS. 5-9. The container includes an integrally tapered tapering upper portion 15 having a flange 16 and a threaded neck 17. The container also has a hollow tubular side wall 2 and made in one whole base 3, legs 7 with supporting surfaces 9 placed obliquely with the possibility of rotation relative to the outer edge 11.

In both embodiments of the structure according to the invention, having legs radially as far apart as possible, the legs can have relatively large flat support surfaces to form contact zones with a horizontal support surface. The outer walls of the legs taper or bend outward in a downward direction to facilitate removal of the container from the mold. This narrowing or curvature is minimized as much as possible, so that the diameter of the non-continuous contact zone of the abutment surface formed by the outer edges of the abutment surfaces of the legs is only slightly less than the diameter of the tubular side wall of the container. In addition, this distance allows the radius of the curved parts of the base to be relatively large compared to many known containers. This reduces or eliminates the possibility of stresses at the base leading to cracking. It has been found that for two liter and sixteen ounce (452.8 g) containers, five legs are optimal for creating large supports and base parts having a larger radius of curvature.

The containers are formed in the usual way by blowing from pre-pressurized preliminary plastic molds. The preform is heated to a temperature at which it can be blow molded and then placed in a hollow mold having an inner surface of the desired container configuration. Compressed air is introduced into the preform in order to expand it outwardly to bring it into contact with the inner surface of the mold cavity. Air inside the cavity is discharged through the ventilation holes in the lower end of the mold cavity to allow the plastic to be completely blown into the leg portion at the base of the mold cavity. These ventilation holes are made in the form of narrow slots in the mold cavity, which form the largest, but noticeable lines on the surface of the container, indicated by lines 19 in FIG. 2, lines 20 in FIG. 8 and lines 21 in FIG. 5 and 6.

Hollow legs are formed by blowing plastic bottom material

5 walls down from the bottom wall. The legs terminate in substantially flat contact areas of the abutment surface which are blown out from the bottom wall. Inclined contact zones are rotated by

0 internal pressure in the container to form coplanar zones to contact a horizontal surface to hold the container thereon. The invention creates made in

5 as a single part by blow molding a plastic container that has a self-supporting base. The base has a bottom wall extending from the lower end of the side wall of the container.

0 A large number of legs pass down from the bottom wall with the formation of hollow but-. jig with flat supporting surfaces that are inclined up and inward from their outer edges. When filling a drink with carbon dioxide, the internal pressure in the container causes the bottom wall of the base to move down, turning the supporting surfaces to a horizontal position with the formation of coplanar

0 contact zones of the supporting surface for holding the container: This deviation does not lead to a decrease in the diameter of the contact zones of the supporting surface of the container, hence the stability of the container

5. when filled, it does not decrease. In addition, the base of the container is formed with parts having a relatively large radius of curvature to reduce the magnitude of the stresses leading to

0 cracking of the base, thereby increasing the strength of the base and reducing the possibility of rupture.

Claims (7)

1. A container for carbonated drinks5 made by blasting from a plastic material, comprising a cylindrical body with side walls and a base including a bottom wall curved in an arc downward from the lower edges of the side walls, a horizontal central portion connected thereto and at least three hollow legs located radially at the same distance from one another and from the central portion of the bottom wall, including inclined outer walls formed by portions of the side walls of the body protruding downward and circumferential surfaces with inner and outer edges, the outer diameter of the body exceeds the circumference of the circle along which the outer edges of the supporting surfaces of the legs are located, which are different in that, in order to increase the strength and stability of the container, the supporting surfaces of the hollow the legs are inclined so that their inner edges are placed above the outer edges, while the supporting surfaces are made to rotate relative to the outer edges until their inner edges are placed one level with the latter with the formation of a horizontal surface under the action of pressure of the contents of the container, 2. The container according to claim 1, characterized in that. that the hollow legs are made so that their the outer walls taper from top to bottom. 3. The container according to paragraphs. 1 and 2, characterized in that the outer wall of each leg is curved in an arc from top to bottom. 4. A container according to claims 1 to 3, characterized in that the central portion of the bottom wall is connected to the inner edges of the supporting surfaces of the legs by means of inclined sections located radially. 5. The container according to claim 1, characterized in that the outer walls of the hollow legs are connected to the outer edges of the supporting surfaces, each leg having a pair of side walls connected to the bottom wall and the supporting surface of the leg, and the side walls of adjacent legs are at an angle to one another and form, together with the bottom wall, ribs for separating the legs. 6. The container according to claim 1, wherein the supporting surfaces of the legs are trapezoidal. 7. The container according to claim 1, wherein the base has five legs.