RU2350529C1 - Beverage containers - Google Patents

Abstract

FIELD: household goods and personal effects; packaging materials.

SUBSTANCE: beverage container consists of a central axis vessel with an elastic lid fitted to close it. The vessel has an apertured neck with the neck having a closure plate integrated in the pendant skirt encircling the neck from the outside. The skirt ring flange comes in sealing contact with the underside of the downwards turned ring-shaped collar positioned on the neck outside surface. The ring flange connected to the above skirt via a swivel joint is elongated as viewed in axial section with the butt surface of its loose end coming in sealing contact with the collar underside. On the above skirt inside there is a ring-shaped embossment that comes in sealing contact with the ring flange first side surface, the ring flange second side surface coming in sealing contact with the neck outside. The skirt inside, the above ring flange first side surface, the embossment and the swivel element confine a ringed cavity with a gas duct, the gas circulating between the ringed cavity and the ambient environment.

EFFECT: innovative lid design reliably ensuring pressure-tight sealing and capable of withstanding relatively high pressures.

5 cl, 9 dwg

Description

The present invention relates to containers for drinks, in particular for carbonated drinks, and relates to the type of container that is described in international patent application No. PCT / GB2005 / 000986, which is not part of the prior art. In particular, the invention relates to such containers that have a wide neck, that is, a neck with a diameter of about 25 mm or more, preferably more than 38 mm or 45 mm, although not limited to this.

Typically, beverage bottles have a narrow neck with a diameter of about only 28 mm or less. Various methods are known for sealing a bottle in the neck region, but it is understood that the difficulties associated with creating a seal on a carbonated beverage container grow exponentially with an increase in the neck diameter, since the area of the lower side of the cap or its upper part increases in proportion to the square of the radius. If the container cap or seal is damaged, leakage of gas under pressure can occur, and the cap can even “shoot” into the air, causing harm to others, and the amount of drink may decrease. In addition, similar problems associated with compaction can occur with non-carbonated drinks, since if the container is exposed to elevated temperature), for example, in direct sunlight, the pressure of the gas in the free space above the liquid will increase, and if the container is not properly sealed, this will result in a gas leak. Essentially, this is not a problem in itself, but if the container cools down again, negative pressure can occur in the free space above the liquid, which will lead to the formation of atmospheric oxygen. This may cause oxidation of the contents of the container, which becomes unfit for drinking.

Next, with reference to the drawings, a beverage container is described in PCT / GB 2005/000986, where:

Figure 1 depicts a vertical section of the first embodiment of a bottle for drinks with a lid in a transitional position during attachment to the bottle;

Figure 2 depicts a vertical section of the lid of the container before connecting to the bottle;

Figure 3 depicts a fragment of a cross section of the upper part of the bottle, showing the cap in the attached and sealed position;

Figure 4 depicts a side view of the upper part of the bottle shown in Figure 3;

Figure 5 depicts a fragment of a bottom view of a portion of the lid depicting a tear tab

6 depicts a fragment of a cap and a bottle according to a second embodiment.

As shown in FIG. 1, the bottle 2 has a generally cylindrical shape with an axis 3 and at least one extended portion 4, the diameter of which is larger than the diameter of the lid 6, for the reason which is explained below. In this case, the bottle is molded from plastic and has a wide neck with a diameter of more than 28 mm, limited by the neck of the 8 bottle. The neck 8 terminates in a rim which is bounded by an inner surface 10 inclined up and out relative to the axis 3, and also an outer surface 12 inclined up and out relative to the axis 3. Thus, surfaces 10 and 12 converge, and the outer diameter of the bottle, in particular its the rim initially increases from top to bottom. However, then said diameter sharply decreases at the downwardly directed annular shoulder 14 extending substantially perpendicular to axis 3. However, the inner diameter of the rim first decreases from top to bottom.

2, it is best seen that the lid is an integral part, preferably molded as a unit of elastic plastic, for example polypropylene. The cap has a shaped closure plate, with which a jumper 16 is made as a whole, which, when the cap is connected to the bottle, passes over the rim of the bottle. The hanging skirt 18, which runs downward around the outer portion of the upper part of the bottle, is made integrally with a jumper 16. With the lower edge of the skirt 18 or with its inner surface adjacent to its lower edge, is connected and made with it for one whole annular holding flange 20. In axial section, the flange 20 has an elongated shape and is connected to the skirt 18 with an elastic connecting jumper 22, which has a reduced thickness and, thus, represents an annular line of weakening, or a predetermined break point. The tear-off tab 24, which extends downward beyond the lower edge of the skirt 18, is connected to the lid in one circumferential location. On the sides, said tongue is connected to the skirt 18 by two weakening lines 26, i.e., portions having a reduced thickness.

The cover plate of the cap is concave and thus, when the cap is connected to the bottle, extends into the neck of the bottle. This plate has a wall portion 30, which, in general, extends downward and inward and is connected with its lower edge to the base 32, which is curved downward, in other words, has a convex downward shape.

2, the lid is presented in the form in which it is molded. In this form, the flange 20 extends downward and inward, and the diameter of its lower edge is smaller than the diameter of the upper edge of the rim of the bottle, while the diameter of its upper edge is larger than the diameter of the upper edge of the rim of the bottle.

The cap is attached to the bottle and sealed on it with a simple snap-on. This can be easily achieved by lowering the cap onto the rim of the bottle and then pressing it down. When the cover is lowered, the lower edge of the flange 20 is in contact with the rim. This leads to the fact that the flange rotates inward relative to the jumper 22. As the cover is further lowered, the flange 20 moves downward, in contact with the surface 12, as shown in FIG. 1, and an increase in the diameter of this surface in the downward direction leads to a further rotation of the flange, thus moving it even closer to the inner surface of the skirt 18. Then, the lower side of the jumper 16 is in contact with the upper surface of the rim of the bottle. However, the pressure on the cap continues, and this leads to a slight deformation of the jumper 16. The cap and bottle are sized so that a slight further lowering of the cap caused by deformation of the jumper 16 is sufficient to allow the free end of the flange 20 to pass past the shoulder 14. After this flange rotates in the opposite direction, that is, inward, due to the elastic properties of the jumper 22 and, thus, is fixed behind the shoulder, as shown in Fig.3. Now the cap is fixed on the bottle and cannot be removed without damage or deformation. Due to stretching, the lower side of the jumper 16 remains in contact with the upper surface of the rim, while the contact pressure is sufficient to provide a first gas-tight seal along the ring line of contact. In addition, due to the tension arising in the skirt 18, the free end of the flange 20 remains in cooperation with the surface of the shoulder 14, while the contact pressure is sufficient to provide a second gas-tight seal along the ring line of contact. Moreover, the elastic properties of the jumper 22 cause the side surface of the free end of the flange 20 to come into contact with the side surface of the bottle, and the contact pressure on the contact surface is preferably sufficient to form a third gas-tight seal. If necessary, you can provide additional reliability of the first gas-tight seal by performing an annular thickening or protrusion 17, which is shown only in the left part of Figure 2 by a dashed line and which interacts with the side surface of the rim of the bottle and creates an additional lip seal. The specified thickening 17 is located in such a way and has such dimensions that due to the contact with the rim of the bottle, it is deformed in the lateral direction and, therefore, due to its elasticity tends to contact with the side surface of the rim and, thus, forms an additional seal. If the pressure in the bottle rose to a value sufficient to deform the cap directed from the rim of the bottle, thereby destroying the first gas-tight seal, the pressurized gas would flow into the space bounded by the outer surface of the rim, skirt 18 and flange 20. The indicated pressure would be tightly press the flange 20 to the side surface of the rim, thereby increasing the reliability of the third gas-tight seal.

If even greater sealing reliability is required, another additional gas-tight seal can be provided, as in the present embodiment, between the rim surface 10 and the opposite surface 34 of the wall portion 30. Thus, in this embodiment, these two surfaces are complementary sealing surfaces located in sealing interaction with each other. If the pressure in the bottle became higher than atmospheric pressure (which could have occurred either as a result of the release of carbon dioxide from a carbonated drink, or as a result of the expansion of the gas located in the free space of the bottle above the liquid, which occurs due to an increase in temperature), the central part of the concave base 32 is deformed would be upward, and this would essentially lead to the fact that the outer edge of the base 32 and, accordingly, the lower edge of the wall part 30 would move slightly outward. This will cause an increase in contact pressure between the sealing surfaces 10 and 34 and, therefore, will increase the reliability of this additional gas-tight seal. Thus, the beverage container made in accordance with the invention not only has both a primary and secondary gas-tight seal, but also has an additional gas-tight seal. The reliability or sealing ability of said additional seal increases as the gas pressure inside the container increases.

If you want to open the bottle, the user just grabs the lower edge of the tear tab 24 and pulls it outward. The weakening lines 26 immediately break or stretch, and the upper edge of the tongue 24, which is connected to the jumper 16, rotate, thereby breaking the second and third gas-tight seals. This rotation is transmitted to the jumper 16, which accordingly moves from the rim of the bottle, thereby destroying the first gas-tight seal. In addition, the specified movement of the jumper 16 causes local removal of the sealing surfaces 10 and 34 from each other, thereby also destroying the additional gas-tight seal. Therefore, the container is depressurized. Moving the tongue 24 in the outward direction initiates the rupture of the thin connecting jumper 22, which can be easily continued by applying force to the tongue 24 in the outward direction until the cap is completely disconnected from the flange 20, which remains in place around the neck of the bottle. Now the lid can be removed, and the contents of the bottle to pour or drink.

As mentioned above, the bottle body has one or more bulges 4 that are wider than the cap when viewed in the axial direction. This means that if several such bottles are packed together side by side, they will touch each other only in areas of the bulges, and the lids of adjacent bottles will not touch each other, thereby eliminating the risk of unintentional displacement of the lids and opening of adjacent containers. In addition, the base of the bottle has a shape that is complementary to the shape of the top surface of the cap, so that the bottles can be easily and reliably mounted on top of each other.

In the modified embodiment of FIG. 6, the outer surface of the wall portion 30 has an annular bulge 40 that interacts with a recess surface formed on the inner surface of the rim. If the gas pressure inside the bottle rose to a level sufficient for the degree of upward deformation of the lid to break up the first gas-tight seal, as illustrated in the drawing, the contact pressure would increase on the contact surface of the upper portion of the thickening with the surface of the recess, thereby increasing the reliability of the additional gas-tight seal and compensating for the weakening of the first gas-tight seal. In addition, the thickening could be on the inner surface of the rim, in which case the recess would be made on the wall portion 30. With a significant increase in the pressure of the gas inside the container, the contact pressure on the contact surface of the lower portion of the thickening will increase.

Despite the fact that the container described in the previous application is extremely effective and forms a reliable gas-tight seal, it is assumed that defects can still occur if the container is heated to too high a temperature, for example, as a result of prolonged exposure to the sun, especially if inside The container is a carbonated drink. In this case, the pressure of the gas located in the free space above the liquid inside the container can rise to such a high level that the cover plate can be deformed upward to a considerable height. Such deformation could lead to a significant deformation of the hanging skirt, leading to its significant displacement from the neck of the container. Subsequently, the elasticity of the integral rotary element will cause the annular sealing flange to rotate relative to both the overhanging skirt and the container until the flange occupies the position shown in a schematic fragment of one half of the upper portion of the container shown in FIG. 7. Any further movement beyond this point will lead to the fact that the sealing flange will spontaneously turn down under significant gas pressure acting on its upper surface and, thus, to explosive depressurization of the container, leading to a possible “firing” of the lid into the air under action of gas pressure. In addition to the danger of harm to others, the contents of the container will be unsuitable for use, and it is very likely that it will spill out of the container.

Thus, it is an object of the present invention to provide a beverage container, in particular with a wide mouth, having a lid with a reliable seal that can withstand the pressure that typically arises in a carbonated drink, even at a relatively high ambient temperature, but which when an extremely high temperature occurs internal pressure will reduce the pressure inside the container to a lower value, which can be easily restrained without damaging the lid or contents of the container, and preventing falling pressure to atmospheric.

According to the present invention, the beverage container comprises a container having a central axis and closed by a lid made of resilient material, the container having a neck defining an opening, and the lid having a closure plate integrally formed with a hanging skirt extending around the outer surface of the neck and having an annular flange, which is in sealing interaction with the lower side of the downwardly directed annular shoulder located on the outer surface of the neck, and teiner is characterized in that the annular flange is connected to the skirt by a rotary connection and has an elongated axial section, the end surface of the free end of the annular flange is in sealing interaction with the lower side of the shoulder, the inner surface of the skirt has an annular thickening, which is in sealing interaction with one side the surface of the annular flange, while the other lateral surface of the annular flange is in sealing interaction with the outer surface of the th a flap, wherein the inner surface of the skirt, said one lateral surface of the annular flange, the bulge, and the pivoting element define an annular cavity, and a gas passage is provided between the annular cavity and the external environment.

Thus, the container made in accordance with the present invention is essentially the same as the container proposed in the previous application, but has two additional features. The first of these is an annular thickening or rib on the inner surface of the overhanging skirt, which is so sized that it is brought into contact with the outer side surface of the sealing flange and thus forms a gas tight seal with it. This further enhances the reliability of the container seal. Moreover, the pressure exerted by the thickening formed on the outer surface of the sealing flange will further increase the contact pressure on the contact surface between the inner surface of the sealing flange and the outer surface of the neck, thereby further enhancing the reliability of sealing the container. The presence of an annular thickening, which forms a seal with an annular sealing flange, also essentially means that the inner surface of the skirt, the outer lateral surface of the annular sealing flange, the thickening and the pivoting element define an annular cavity. The specified cavity is usually isolated from the interior of the container, but communicates with the external environment through one or more gas passages. The gas passage (s) can (can) be made in any element defining an annular cavity, but is preferably made (made) in the form of one or more small holes in a rotary element made in one piece. If the gas pressure inside the container rose to too high a level, which would cause the hanging skirt to move from the container neck, then the cover would also be forced out of the contact position with the container neck, the thickening on the inner surface of the skirt would cease to contact the sealing flange, and the annular cavity would communicate with the interior of the container. However, the cavity also communicates with the external environment, and thus, gas will be released from the interior of the container into the external environment. Consequently, the pressure in the container will begin to drop, but after it reaches a certain lower level, the elastic properties of the lid will lead to the restoration of various seals, and in particular in the annular thickening, restoring its seal with a sealing flange. Then, the gas discharge from the container will be completed, and the pressure inside the container will remain at the same level, although lower, but more acceptable, and the risk of damage to the container lid or contents will be eliminated.

Preferably, the rotary element made in one piece has elastic properties, and its elasticity pushes its specified other side surface to the outer surface of the neck. Preferably, the cover plate is concave downward and thus extends into the neck and also includes a base with which the wall portion extending upwardly connected to the hanging skirt is made in one piece. In addition, it is preferable that the upwardly extending wall portion is connected to the overhanging skirt by means of an annular bridge, the lower side of which extends above the surface of the neck and remains in sealing interaction with it.

Additional features and details of the invention will be apparent from the following description of one of the characteristic embodiments, which is made solely by way of example with reference to Fig. 8 and Fig. 9, in which:

Fig. 8 is a schematic view of one half of a container lid similar to that shown in Fig. 6;

Fig.9 depicts a similar schematic view of one half of the cover when connecting it to the container.

The container and lid made in accordance with the present invention are essentially the same as the container and lid described with reference to FIGS. 1 to 6, and therefore, their description will not be repeated. However, there are two main differences.

Firstly, the rotatable element 22 made in one piece has one or several small holes 50 made in it. Secondly, the annular rib, or bulge 52, is made integrally on the inner surface of the hanging skirt 18. When the lid is snapped onto the container, the flange rotates upward by about 180 ° with the transition to the configuration shown in Fig. 9. The thickening 52 is forced into contact with the outer surface of the sealing flange 20 and forms a seal with it. The force with which the thickening presses on the sealing flange also causes an increase in contact pressure at the point of contact of the inner surface of the sealing flange and the outer surface of the neck 8, and thus, the sealing of the container is improved simultaneously in two separate sections. Moreover, a bulge 52, a sealing flange 20, a pivoting member 22, and a hanging skirt 18 define an annular cavity 54. This cavity communicates with the external environment through aperture (s) 50, but is usually isolated from the interior of the container. However, if the pressure inside the container rises to an extremely high level, the lid is deformed due to pressure, and the seals on the upper and inner surfaces of the neck are broken. The skirt 18 is also deformed outwardly and, thus, the seal between the bulge 52 and the sealing flange 20 is broken. Thus, the inner space of the container communicates with the external environment through the hole (s) 50 and thereby gas is removed from it. Further, the pressure drops until it reaches a level at which the elastic properties of the lid will be sufficient to restore its shape, overcoming the reduced pressure of the gas inside the container. After that, these or those seals are restored, and the gas removal from the inner space of the container is completed, while the pressure of the gas in the container is still quite high. Thus, the contents of the container are stored in it and are usable.

Claims (5)

1. A beverage container comprising a container that has a central axis and is closed by a lid made of an elastic material, the container has a neck defining a hole, and the lid has a closing plate integrally formed with a hanging skirt extending around the outer surface of the neck and having an annular flange in sealing interaction with the lower side of the downwardly directed annular shoulder located on the outer surface of the neck, characterized in that the annular flange connected to the specified skirt by a rotary connection and is made elongated in axial section, and the end surface of its free end is in sealing interaction with the lower surface of the shoulder, and the inner surface of the specified skirt has an annular thickening, which is in sealing interaction with one side surface of the annular flange, when this other side surface of the annular flange is in sealing interaction with the outer surface of the neck, and the inner surface skirt, the said one side surface of the annular flange, and thickening the pivot member an annular cavity, and has a gas passage extending between the annular cavity and the external environment. 2. The container according to claim 1, in which the gas passage has one or more holes located in a rotary element made in one piece. 3. The container according to claim 1, in which the rotary element made in one piece is elastic, and its elastic properties ensure that its specified other lateral surface is pressed against the outer surface of the neck. 4. The container according to any one of claims 1 to 3, in which the closing plate is concave in the lower direction and, thus, enters the neck and has a base made in one piece with the upwardly extending wall portion that is connected to the hanging skirt. 5. The container according to claim 4, in which the upwardly extending wall portion is connected to the hanging skirt by means of an annular bridge, the lower side of which extends above the surface of the neck and is held in sealing interaction with it.

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