CROSS-REFERENCE TO RELATED APPLICATIONSThe present application claims the benefit of U.S. Utility Application Ser. No. 10/551,618, filed Sep. 30, 2005 entitled “FLEXIBLE LIQUID CONTAINER”, now U.S. Ser. No. 12/883,771; which in turn claims priority from PCT Application Number PCT/IB04/00736; which claims priority from Swiss National Applications 0564/03 filed Apr. 1, 2003 and 0214703 filed Dec. 16, 2003; the disclosures of which are expressly incorporated by reference herein.
The present invention relates to a flexible container for a liquid, provided with a self-sealing pouring spout.
Flexible containers for holding a beverage or some other liquid offer several advantages over rigid containers and, more particularly: their low cost of manufacture, the use of a minimal amount of material and a small bulk after use. However, once opened and if no rigid pouring spout is provided, either separate or welded/bonded to the flexible sheets of the container, they cannot be easily closed once opened and they tend to allow the liquid to escape. Once the container is opened, the user must hold the container to prevent the liquid from being involuntarily spilled and he cannot leave it to stand on a table or on some other surface, unless it is completely empty.
Various flexible containers with a self-sealing spout have been suggested for overcoming this problem. Generally, either an increase in the resistance to the flow of the liquid is suggested by providing the containers with long thin channels in fluid communication with the spout developing a high resistance to flow, as described in the GB patent 769 810 and the U.S. Pat. No. 4,988,016, or a narrowing or some other obstacle in the vicinity of the spout developing a strong resistance to the flow of the liquid, such as described in the U.S. Pat. No. 5,411,178.
In the U.S. Pat. No. 4,988,016 and in the GB patent 769 810, the self-sealing effect depends mainly on the elasticity characteristics of the material of which the container is made, on the dimensions of the spout as well as on the characteristics of the liquid. In those systems which rely on a strong local resistance, such as those described in the U.S. Pat. No. 5,411,178, the self-sealing effect is strongly dependant upon the dimensions of the passage as well as on the characteristics of the liquid and in particular on its surface tension. In all the prior solutions, the self-sealing effect is strongly dependant on the characteristics of the liquid and/or on the properties of the material of the flexible container and a given spout geometry can often be used only for a specific liquid, owing to the fact that the self-sealing effect is affected by variations in the dimensions of the channel or of the restriction. Another important disadvantage of these systems is that, in order to achieve a reliable self-sealing effect, it is necessary to have a high resistance in the outflow channel which limits strongly the flow rate and necessitates that a considerable compressive force be applied by the user to empty the container. Furthermore, after a first use of the container, the self-sealing effect tends to subside, which results in involuntary leaks.
The same holds true for the container described in the patent application WO 98/01361 which discloses the use of spouts which are shaped differently depending on the liquid held in the container.
Other known sealing means rely on the formation of folds after use by the user, such as described in the U.S. Pat. Nos. 3,278,085, 5,228,782 and 6,244,468. These solutions have the drawback of not providing a self-sealing effect and of requiring an intervention by the user.
Accordingly, an objective of the invention is to provide a flexible container for a liquid, with a self-sealing spout, which is improved by comparison with those already known.
Preferably, the self-sealing effect depends only little on the properties of the liquid held in the container, it is reliable and it allows an outflow without requiring an excessive pressure by the user.
Preferably, the pouring spout of the container has a form, which is simple and easily manufactured, using a minimal amount of material and at a minimal cost.
In order to achieve the objectives of the invention, a flexible container is provided, which has the characteristic features set out in claim1. Specific embodiments are described in the dependant claims.
A specific embodiment is described hereafter, with reference to the appended drawing, including figures, in which:
FIG. 1 is a top view of the container according to the invention;
FIG. 2 is a front view of the container of the previous figure placed on a flat surface;
FIG. 3 is a side view of the same container placed on a flat surface;
FIG. 4 is a top view of a container according to a second embodiment of the invention; and
FIG. 5 is a perspective view of the second embodiment.
FIG. 6 is a top view of a container according to another embodiment of the invention; and
FIG. 7 is a perspective view of the container according toFIG. 6.
The container1 illustrated in the figures is made from twosheets10,11 of a flexible material, which have the same shape and the same dimensions, and which are fixed together by a weld seam or anadhesive seam12 running along the periphery of the container1. In addition to running along the periphery of the container proper, the assemblage seam provided as aweld seam12 also surrounds aspout13, protruding from a portion of the periphery of the container. Thus, thespout13 is made from the same sheets of flexible material as those forming the container1 and it includes anoutflow channel130 opening inside the flexible container1. Furthermore, thespout13 can include aweakening groove131, which makes it possible to tear off a portion thereof, thus opening thespout13 and thechannel130.
Inside the flexible container1, in the vicinity of the location where thechannel130 opens inside the flexible container, the twoflexible sheets10 and11, made from a polymer or from some other flexible material, are welded or bonded together in such a manner as to form anobstacle14 located facing the outflow channel. Thewelded obstacle14 has an elongated shape and extends between twoends15 which overlap theperipheral weld12 on both sides of the outflow channel, while leaving free twopassages140,141 in the direction of thechannel130. The length L of the overlap is relatively small, compared with the overall length of theperipheral weld12 and it corresponds, preferably, to less than 10% thereof. Preferably, the longitudinal obstacle runs substantially parallel to the portions of theperipheral weld12 on the two sides of the outflow channel and approximately perpendicularly to the general direction of the protruding spout.
When the container1 is filled via a filling spout (not illustrated) and sealed permanently after the filling, the large central parts of the twowalls10 and11 forming the container1 move away from each other as the container swells, as can be seen inFIGS. 2 and 3.
When the container1 is filled and thewalls10 and11 are, accordingly, pushed away from each other, two folds are formed on each one of thewalls10 and11, extending transversally with respect to thenarrowed passages140 and141, approximately along theaxes142 and143 shown inFIG. 1. The deformation of thewalls10 and11 in the vicinity of the ends of theobstacle14—namely of two portions of eachwall10 and11, which adjoin the two sides of thenarrowed passages140 and141 and which are prevented from moving away from each other—creates a fold approximately along theaxes142 and143.
Thefolds142,143, as well as the generallyelongated obstacle15, define along approximately thedotted nip line144, shown inFIG. 1, with thesection12aof the seam extending between thefold lines142,143 a portion of the surface, which tends to curve (deflect) as illustrated inFIGS. 2 and 3. The deflection of thearea145 including the spout, between thefolds142,143, results in the two flexible sheets in this area being urged against each other and thus forming a valve which prevents the flow of liquid through thepassages140,141 and via the orifice of the protrudingspout130.
When the flexible container is laid on a flat surface as illustrated inFIGS. 2 and 3 and a vertical force Fvis applied approximately on the large central part of theupper wall10, thefolds142,143 and the deflection of thecentral deflection area145 tend to reinforce, thus increasing the tightness of the valve.
This reinforcement of thefolds142,143 in the vicinity of thepassages140,141, as well as the increase in the deflection of thearea143 which increases with the application of a force Fv which is substantially perpendicular to the plane of the flexible sheets are extremely advantageous, since they prevent effectively the escape of liquid when the flexible container is laid in its natural position on a surface which is substantially flat, even when another object, which increases the pressure in the container, is placed on top of the container.
It is to be noted, that the deflection of thearea145 is non symmetrical, since thearea145 is deflected on one side or on the other side of the container. The deflection is a consequence of the particular geometry of theobstacle15 which is either welded or bonded, and of its position with respect to the protrudingspout portion130 and theseam portion12a, which, together, determine the formation of thefolds142,143. In particular, thefolds142 and143, as well as theobstacle15, define anip line144 between the two flexible sheets. This line is not straight, but has a generally curved shape of which the ends cut across the peripheral seam. This nip line about the protruding spout, which is not straight, makes it possible to cause the deflection of thespout area145.
In order to enable the liquid to flow via thespout13, the user simply needs to exert a certain pressure on the container, in particular by pressing the container at least partly along a direction Fh, which is substantially perpendicular to the plane of the weld of theobstacle14, thus opening the lips closing the narrowed passage orpassages140,141. The interruption of this compressive action closes the narrowed passages and closes the container.
The exertion of a compressive force on the container in the direction FH, i. e. substantially perpendicularly to the plane of the weld of the obstacle results in a decrease of the deflection and of the effect of thefolds142,143, accompanied by an increased pressure of the liquid in the container which opens slightly the lips of the sheets at the entrance to thepassages141,140, to enable an outflow of the liquid. In fact, when a compressive force FHis applied approximately on thelateral sections12bof the seam, which is accompanied by an increase of the pressure inside the container, a pulling force FTand a torque FRact on the portion of the seam in the vicinity of the spout which tends to flatten, i. e. to reduce the deflection of thespout area145.
The figures show a container1 having a substantially circular shape; it is however understood, that this container can assume any shape adapted to its use. In the case of a container of a design having one side with a straight edge, the container can be formed from a single sheet of a flexible material folded over along this straight edge, with the remaining edges being welded together to form the container. For example, and as shown inFIGS. 6 and 7, a container according to the invention is shown wherein thewalls10′,11′ of the container are made from a single sheet of flexible material which is folded (along12′) to form twooverlying walls10′,11′.
Also, a given flexible packaging can contain any type of liquid, the only limitation being the chemical compatibility of the liquid with the material forming the container.
The figures show a container1 having a substantially circular shape; it is however understood, that this container can assume any shape adapted to its use. In the case of a container of a design having one side with a straight edge, the container can be formed from a single sheet of a flexible material folded over along this straight edge, with the remaining edges being welded together to form the container.
Furthermore, the embodiment of the flexible container illustrated and described has anobstacle14 defining two narrowedpassages140 and141. One could also have one end of theobstacle14 in contact with the neighbouring portion of theweld12, thus leaving only one narrowed passage, with a single fold being then formed on thewalls10 and11 upon the filling of the container.
In another embodiment, such as that illustrated inFIGS. 4 and 5, the container has a shape, which is substantially rectangular, and thespout13 is positioned in a corner of the rectangle to protrude in a direction along an oblique axis approximately along the median line between the edges of the adjoining rectangle. In this embodiment, a weldedobstacle14′ is arranged facing the spout as in the previous embodiments, except that this obstacle is provided with acentral passage146. In this embodiment, the deflection of thespout area145 defined by thenip line144 is substantially the same as in the case of the embodiment described previously. However, because of the rectangular shape of the container and of the position of the spout in a corner thereof, a compressive force applied by the user to the central part ofopposite edges12bof the container creates a pulling force and a torque which are less pronounced on thespout area145 by comparison with the embodiment described previously. However, owing to the rectangular shape of the container and of the position of the spout in one corner thereof, a compressive force exerted by the user upon the central part of theopposite edges12bof the container generates a pulling force and a torque which are less pronounced on thespout area145 than in the embodiment described previously.
In the case of such elongated shapes in which the compressive force is exerted on the container at a relatively long distance from the spout and where the spout is in a non symmetrical position of the container with respect to the compressive forces applied to the container, thecentral passage146 provided in the welded obstacle makes it possible to initiate and facilitate the flow of liquid in the passage of the spout.