FR3036103A1 - BOTTLE TIP WITH BOTTLES - Google Patents

Abstract

There is provided a removable and one-piece nozzle (10) for a bottle (40) of liquid. The nozzle comprises two spouts (14) adapted to be in fluid communication with the bottle when the tip is connected to the bottle by the connecting element and each provided with an outlet (16), the geometry of each pouring spout and its outlet being adapted to the pouring of the liquid from the bottle in a curve substantially parallel to the plane of symmetry (P) of the nozzle when the bottle is inclined in the plane of symmetry (P) of the nozzle, in wherein the gap (60) between the outlet (16) of the two spouts is adapted to the simultaneous pouring of the liquid from the bottle into two drinking glasses, and pouring the liquid from the bottle into a single drinking glass.

Description

The present invention relates to the field of liquid bottles, and more specifically the pouring of the liquid contained in such bottles into a drinking glass.

In some contexts, it may be useful to be able to serve glasses faster and / or more simply than by the conventional way of pouring the liquid from a bottle directly into one-to-one glasses by a purely manual operation. tilt of the bottle. This is for example the case in a context where the guests are numerous and can get impatient. This can also be the case in the context of a brewery or a restaurant. Thus, some establishments use machines or devices that allow such a saving of time. One can think for example devices in bars, where the bottles are returned to the device for an immediate and simple liquid pouring by pressing a button or by operating a lever. These machines are however relatively complex and not very transportable.

In addition, various bottle tips are known. For example, some tips can serve wine by aerating beforehand. Other tips connecting to oil bottles can serve fine threads of the oil in question. However, no tip is known to accelerate globally the payment of liquid in the case where there are several glasses to serve.

The object of the present invention is to provide a solution at least partially overcoming the aforementioned drawbacks. More particularly, the invention aims to accelerate and simplify the pouring of the liquid from a bottle in a situation where several glasses would potentially be used, without requiring complex equipment, for example requiring a fixed mounting or little transportable.

To this end, the present invention provides a removable and one-piece nozzle for a liquid bottle. The tip is adapted, when the tip is connected to the bottle, pouring the liquid from the bottle into at least one drinking glass by inclining the bottle in a vertical plane of symmetry of the tip. The tip includes a sealing member of the tip to the bottle, and two spouts. The pouring spouts are adapted to be in fluid communication with the bottle when the nozzle is connected to the bottle by the connecting member and are each provided with an outlet. The geometry of each pouring spout and its outlet is adapted to the pouring of the liquid from the bottle along a curve substantially parallel to the plane of symmetry of the nozzle when the bottle is inclined in the plane of symmetry of the tip. The gap between the outlet of the two spouts is adapted to the simultaneous pouring of the liquid from the bottle into two drinking glasses when the bottle is inclined so that the outlet of each of the two spouts is above a glass to drink respectively, and pouring the liquid from the bottle into a single drinking glass when the bottle is tilted so that the outlet of the two spouts is above the only drinking glass.

Removable and monoblock, such a nozzle is very easy to use, and great flexibility in the place of use (the tip being transportable). The presence of two spouts and their geometry allows simultaneous pouring into two drinking glasses, which simplifies and accelerates the task of the person handling the bottle to pour glasses. The gap between the two spouts also allows the pouring of the liquid in a single glass if necessary, and in a natural way and without the need for any additional operation of separation of the tip of the bottle. The geometry of the pouring spouts allows the pouring into a drinking glass to be done by simply positioning a spout 5 above the drinking glass and tilting of the bottle, in exactly the same way as in the classic case of a bottle without tip. The payment is intuitive and is easily done without splashing or splashing out of the glass. Such an end piece can therefore be used in any method of pouring into one or more drinking glasses of liquid contained in a bottle (for example champagne or other sparkling wine, soda, water, wine or any other spirit). ), if the mouthpiece is connected to the bottle. The method may comprise one or more iterations corresponding to successive inclinations of the bottle, with one or two new glasses positioned under the spouts at each iteration / inclination. The method may comprise an initial step of connecting the tip to the bottle (for example by depressing, as will be mentioned later), if such a connection is not already made. According to preferred embodiments, the nozzle comprises one or more of the following characteristics: The difference between the outputs of the two spouts is less than 5 cm, preferably less than 4 cm.

At least one of the outlets of the two spouts has a minimum diameter greater than 0.5 cm, preferably greater than 1 cm. At least one of the outlets of the two spouts has a beak portion. The nozzle portion is oriented towards the plane of symmetry of the tip or parallel to the plane of symmetry (P) of the tip.

The internal geometry of each spout comprises a sharp edge forming a gutter. Both spouts have an inclination relative to the vertical plane orthogonal to the plane of symmetry of the nozzle when the nozzle is connected to the bottle by the coupling element. At least one of the outlets of the two pouring spouts has a shape corresponding to an angled section of a conduit. - The two spouts form a V. - The top of the interior of the two branches of the V forms a sharp edge. Other features and advantages of the invention will appear on reading the following description of a preferred embodiment of the invention, given by way of example and with reference to the appended drawing. - Figures 1 to 6 illustrate the tip. - Figure 7 illustrates the coupling element. - Figures 8 and 9 illustrate a cross section of a spout of the nozzle. Figures 1 to 6 show an example referenced 10 of the nozzle according to the invention.

The tip 10 is removable. This means that it can be connected to a bottle, then removed, and then connected to yet another bottle. It also means that it can be transported. Indeed, depending on the material used, the tip 10 may have a lower mass ABA.00212-2015.05.06-5PEC 3036103 3 to 500 grams, preferably less than 100 grams, preferably of the order of one or a few ten (s) of grams. With reference to FIG. 5, and considering the right parallelepiped having the smallest volume and containing the tip, its dimensions can be less than 10 cm for the largest width 50, for example between 4 to 6 cm, less than 10 cm. cm for the greatest length 52, for example between 5 to 7 cm, and of the order of one centimeter for the thickness, for example between 1 and 3 cm. This allows a simple and flexible use, and therefore public (the tip can thus be a consumer good or kitchen utensil). The tip 10 is further monobloc, that is to say made in one piece (i.e. without any internal connecting element). This simplifies its use (which can therefore remain public) and 10 its manufacture. The manufacture can be done in a conventional manner, in particular by molding (for example by thermo-molding), or even by 3D printing. The material used can be any as long as it is waterproof. As a pure example, any plastic or stainless steel are suitable. The tip 10 is intended for a bottle of liquid (as can be seen in FIG. 4 which shows the tip 10 as connected to a bottle 40) and is adapted when the tip is connected to the bottle ( and that the bottle contains liquid), pouring the liquid from the bottle into at least one drinking glass by inclining the bottle. Thus, the tip 10 comprises a connecting element 12 allowing a sealing connection (at least substantially) between the tip and the bottle, so that the tip can form (in case of such a connection), an extension of the bottle, the liquid pouring then being via the nozzle (that is to say, by borrowing the multi-branch tubular conduit formed by the tip). The coupling element of the nozzle can be any, and all the solutions conventionally used by the bottle tips of the prior art may be suitable. In the case of the example, and as can be seen in FIGS. 2, 3, and 5, as well as in FIG. 7 which shows the coupling element 12 while ignoring the remainder of the nozzle 10, the connecting element 12 consists of a duct-forming duct, which may be of generally cylindrical shape, provided with rings 77. The rings 77 (ie radial annular protrusions) may be in a number between 1 and 5, for example 3 as in the example of the figures, and in the same material as the remainder of the connecting element 12 and the nozzle 10. Such a connecting element 12 allows the sealing connection of the nozzle with a bottle by simple depression (ie insertion of the connecting element in the neck of a bottle), as can be seen in FIG. 4 which shows that the connecting element of the endpiece 10 is pressed into the bottle 40 and therefore not apparent in the figure, provided that the dimensions of the fitting member correspond to they the neck of the bottle 40 envisaged for the tip 10. This allows a mounting of the tip simple and fast. To facilitate the depression, the connecting element 12 may have a bias 78 at its bottom. As regards the dimensions which depend on those of the contemplated bottle, with reference to FIG. 7 and FIG. 5, the external diameter of the duct 72 is generally between 10 and 20 mm, for example of the order of 15 mm. . The internal diameter 73 depends on the flow rate envisaged. It may be between 12 and 18 mm, for example of the order of 14 mm. It can be independent of the outer diameter. The rings 77 can have a width of between 0.8 mm and 1.2 mm. The upper ring 79 may be wider than the others, which allows it to wedge horizontally on the upper edge of the neck of the bottle rather than sinking into it, and thus stop ABA.00212-2015.05. 06-5PEC 3036103 4 the depression. The height 74 may be between 0.5 cm and 2 cm, preferably between 0.8 cm and 1.3 cm. The tip is of substantially symmetrical general shape (i.e. modulo possible point asymmetries that could be added and unrelated to the features discussed with reference to the figures). Thus, the plane P of symmetry can be defined as seen in Figures 1 to 3. The plane P is vertical when the nozzle 10 is connected to the bottle 40 and the bottle 40 is vertical. Therefore, if the bottle is inclined in the plane P (that is to say, according to a rotation whose axis of rotation is orthogonal to the plane P), there comes a moment when the liquid is poured out of the bottle ( depending on the filling rate 10 of the bottle and the exact geometry of the tip). Indeed, the tip 10 comprises the two spouts 14, which are in fluid communication with the bottle 40 when the tip is connected to the bottle 40 by the connecting member 12, which means that the tip forms a branch pipe (generally tubular, as shown in the figures) extending the conduit formed by the neck of the bottle 40. Each spout 14 15 is further provided with a respective output referenced 16 (ie a simple upper opening), the duct thus formed allows the spill of the liquid contained in the bottle 40 below the spouts. As it appears immediately in the figures, the geometry of the spouts 14 and their respective outlets 16 is adapted to pour the liquid from the bottle 20 along a curve substantially parallel to the plane of symmetry P of the tip 10 when the bottle is inclined in this plane P. In other words, the net of liquid which is poured follows a curve contained in a plane substantially parallel to the plane P when the bottle is inclined "normally", that is to say as indicated ci -above. By "substantially parallel" is meant here that the curves formed by the streams of poured liquid (or the planes containing them) each form an angle with the plane P less than 30 °, preferably less than 15 °, advantageously less than at 10 °. These pouring nets are therefore substantially parallel to each other (and to the plane P) with an intuitive standard use of the bottle 40 provided with the tip 10, the liquid flowing towards the front of the bottle (the "forward" direction corresponding to the direction of inclination of the bottle), rather than going in opposite directions for example. Thus, the bottle has a pouring behavior in accordance with that of a bottle without such a tip 10, except (practically) that the single trickle of the "classic" case is divided into two substantially parallel threads when the tip 10 is used. This allows a simple and intuitive use, and thus to properly pour the liquid in a single glass or two glasses, depending on the choice, without the fact that the outputs 16 are inserted into the glass (s) thus filled (s). ) or a geometric mental calculation is done by the user. Indeed, the tip 10 is adapted to a correct payment when the pouring spouts are a few centimeters above the opening of the glass (s), or they rest on the edge of the glass (s) ) as in the classic case of pouring with a bottle without tip, or the neck of the bottle can bear 40 on the edge of the glass. Shown in FIG. 6, the gap 60 between the outlet 16 of the two pouring spouts is, as previously indicated, not only adapted to the simultaneous pouring of the liquid from the bottle 40 into two drinking glasses when the bottle 40 is inclined in such a way that the outlet 16 of each of the two spouts 14 is above a respective drinking glass, but still pouring the liquid from the bottle into a single drinking glass when the bottle is ABA.00212-2015.05.06-SPEC 3036103 inclined so that the outlet 16 of the two spouts 14 is above the only drinking glass. The tip 10 is thus suitable for undifferentiated use for pouring two glasses simultaneously or a single glass with the same type of inclination of the bottle, without any manipulation of its connection to the bottle 40. This makes the tip 10 very practical because it can be left connected to the bottle 40 as long as the bottle 40 is used. The gap 60 is shown in FIG. 6 as the gap between the two upper points which will be discussed later. This is in fact the distance between the two centers of the outlets 16. The center of an outlet 16 is defined in the example of the figures as the center of the circle inscribed in the outlet 16 having the largest diameter. It is more generally (substantially) the center of the geometric figure represented by the outlet 16. The gap 60 may be for example less than 5 cm, preferably less than 4 cm. Studies show that such values permit simple use of the mouthpiece in the most common cases of drinking glasses, including champagne flutes with relatively small diameters.

Similarly, the gap 50 between the outer edges of the two outlets 16 and illustrated in the figure may be less than 7 cm, preferably 5 cm. Indeed, at least one of the outlets 16 (preferably both) of the two spouts 14 may have a minimum diameter greater than 0.5 cm, preferably greater than 1 cm. This allows a pleasant flow (with sufficient flow) in the case of liquids such as champagne or other sparkling wine, soda, water, spirits and wine. In the example, the outlets 16 of the two pouring spouts each have a portion 32 forming a spout, highlighted in FIG. 3, as well as in FIG. 9 which presents in a solid line the cross section of a spout 14 at the level of the spout. from its outlet 16 and dotted line the cross section of a spout at a branch, for example half way (also illustrated in Figure 8). The portion 32 constitutes the main zone of the edge of the outlet 16 through which the liquid is poured, and this portion 32 is formed by two straight planes which meet, projecting into a point in FIG. 9, thus defining a semi-pyramid (rather than a cylinder area, as on the rest of the edge of the exit 16). This allows a more precise payment. In addition, this gives the user a visual cue enabling him to grasp at first glance the "natural" sense of use of the mouthpiece 10 (with reference to FIG. 4, this sense consists in inclining the bottle in the counterclockwise to the projection of the figure). In addition, the internal geometry of each spout 14 (ie mainly a generally cylindrical duct) comprises a live edge 34 forming a gutter, as illustrated in FIGS. 3 and 8. The sharp edge 34 follows a curve on along each spout (inside the conduit formed by the spout 14, that is to say, on the inner wall of the spout 14) which guides the flow of the liquid upon pouring, in the manner of 'a gutter. This allows a more precise payout, with less splashing and splashing, and this provides a visual cue, as explained above. As in the example of the figures, the sharp edge 34 can reach the base 40 of the portion 32. With reference to FIG. 2, the two pouring spouts 14 have an inclination a (non-zero) with respect to the vertical plane P ' orthogonal to the plane of symmetry P of the tip 10, when the tip 10 is connected to the bottle 40 by the connecting member 12 (and the bottle 40 is vertical). The angle α may be greater than 5 ° and / or less than 45 °, preferably greater than 20 ° and / or less than 25 °. This facilitates the flow (provided that the bottle 40 is properly inclined, that is to say not only in the right plane but also in the right direction), and this provides a visual cue, as explained above. We will now discuss characteristics of the nozzle 10 present or not in the example that make it particularly suitable for the pouring of bubble liquids, including foaming, for example sparkling wines such as champagne or soda. In the example of the figures, the portion 32 forming a nozzle is oriented parallel to the plane of symmetry P of the nozzle, thus projecting perfectly straight on a horizontal plane, as shown in FIG. 9. Alternatively, the portions 32 may be oriented towards the plane P, thus making a "return to the interior". Thus, the sharp edge 34, connected to the portion 32, makes a torsion bringing it inwardly between the two pouring spouts 14. The portions 32 point therefore in a direction towards the plane P (for example a direction making a angle less than 30 ° with plane P). This allows a tightening of the two liquid pouring nets, facilitating the pouring into the same glass, which is particularly useful for champagne glasses whose diameter is relatively small. As seen in the figures, the two spouts 14 form a V. In other words, the conduit formed by the two spouts 14 has a generally tubular shape in two straight branches meeting at a sharp angle. This allows a flow without too much shock of the liquid in the mouthpiece, thus minimizing any unwanted softness in the case of such liquids. This also makes it possible to better visualize the dimensions of the mouthpiece, to better distinguish the two spouts 14 and thus to better position it when it is desired to pour two glasses simultaneously. As illustrated in FIG. 3, the top of the inside of the two branches of the V can form, in particular, a sharp edge 36. This allows a clear division of the liquid, which meets during the division into the two branches of the endpiece. 10 stops it sharp 36 rather than, for example, a saddle horse, which reduces a possible inadvertent foaming. In the figures, it can be seen that the outlets 16 of the two pouring spouts 14 have a shape corresponding to a cross section of tubular ducts orthogonal to the direction of the duct (when the nozzle is considered to be connected to a vertical bottle). However, the shape may alternatively correspond to an angled section, in the direction accentuating the beak formed by the portion 32. This makes it possible to offer the vision a larger surface of the liquid at the outlet of the nozzle 10 when pour it. ABA.00212-2015.05.06-5PEC

Claims (10)

REVENDICATIONS1. Cap (10) removable and monobloc for bottle (40) of liquid, adapted, when the nozzle is connected to the bottle, pouring the liquid from the bottle into at least one drinking glass by inclining the bottle in a plane of vertical symmetry (P) of the nozzle, the nozzle comprising: - a connection element (12) sealed from the tip (10) to the bottle, - two spouts (14) adapted to be in fluid communication with the bottle when the tip is connected to the bottle by the connecting element and each provided with an outlet (16), the geometry of each pouring spout and its outlet being adapted to pour the liquid of the bottle along a curve substantially parallel to the plane of symmetry (P) of the nozzle when the bottle is inclined in the plane of symmetry (P) of the nozzle, wherein the gap (60) between the outlet (16) of the two spouts is adapted to the simultaneous pouring of the liquid from the bottle into two drinking glasses when ue the bottle is tilted so that the outlet of each of the two pouring spouts is above a respective drinking glass, as well as pouring the liquid from the bottle into a single drinking glass when the bottle is tilted so that the outlet of the two spouts is above the only drinking glass. 2. End piece according to claim 1, characterized in that the distance between the outlets (16) of the two spouts is less than 5 cm, preferably less than 4 cm. 3. Tip according to claim 1 or 2, characterized in that at least one of the outlets (16) 25 of the two spouts has a minimum diameter greater than 0.5 cm, preferably greater than 1 cm. 4. End piece according to claim 1, 2 or 3, characterized in that at least one of the outlets (16) of the two spouts has a portion (32) forming a spout. 30 5. Tip according to claim 4, characterized in that the nozzle portion is oriented towards the plane of symmetry (P) of the tip or parallel to the plane of symmetry (P) of the tip. 6. Tip according to one of claims 1 to 5, characterized in that the internal geometry of each spout comprises a sharp edge (34) forming a gutter. ABA.00212-2015.05.06-5PEC 3036103 8 7. Tip according to one of claims 1 to 6, characterized in that the two spouts (14) have an inclination (a) relative to the vertical plane (P ') orthogonal to the plane of symmetry (P) of the nozzle when the tip is connected to the bottle by the connecting member. 5 8. Tip according to one of claims 1 to 7, characterized in that at least one of the outlets (16) of the two pouring spouts has a shape corresponding to a cross section of a conduit. 9. Tip according to one of claims 1 to 8, characterized in that the two spouts 10 form a V. 10. Tip according to claim 9, characterized in that the top of the inside of the two branches of the V forms a sharp edge (36). ABA.00212-2015.05.06-5PEC