The present invention belongs to the field of oenology. It relates more specifically to glasses designed for wine tasting.
It is known in oenology that a single wine does not have the same smell and the same taste, with respect to the same taster, when poured and drunk in glasses of different shapes.
This effect is due to several physical and chemical phenomena. Wine is composed of multiple elements, including ethanol, acetaldehyde and glycerol molecules, tannins, phenolic and volatile compounds, esters, mineral and vegetable matter, volatile acids, etc. These different molecules are released into the air surrounding the wine more or less quickly depending on the geometry of the glass. For example, the ratio of the free surface of the wine, which partly determines the rate of release of flavors from and oxygenation of the wine, to the volume of wine in the glass thus partly explains the choice of balloon-, tulip- or flute-shaped, etc. glasses. A young red wine needs oxygenation, which justifies a greater free wine surface, whereas, on the contrary, an older wine requires this oxygenation less, and is preferably drunk in smaller diameter glasses.
The desire to keep the flavors in a slightly-ventilated volume of air justifies the choice of a diameter in the upper part of the glass, called “rim”, which is smaller than the container part of the glass, called “parison”.
Similarly, it is known that the taste buds located in different areas of the mouth of the taster are not dedicated to the perception of the same flavors: certain parts are particularly dedicated to the detection of bitterness, others to the perception of acidity, yet others to the perception of the sweet or salty nature of food, etc. The shape of the upper part of the glass thus directs the wine, when drunk, towards certain taste buds as a priority, creating something of a taste playback sequence of the wine that highlights one or another of its qualities.
The choice of a suitable glass for a premium wine, which required great effort to create, can thus be decisive in the taster's perception of its quality.
The internal shape of the glass therefore becomes the subject of studies and creation.
Glasses specifically designed to favor a particular type of wine have already been proposed in the prior state of the art.
Various means to bring out the flavors more quickly have been envisaged, most often by creating turbulence in the wine when the glass is subjected to a very traditional circular motion.
Of these, patent FR 2 684 534 from 1991 shows a glass comprising a stop edge protruding into the inner part of the parison, substantially at the free surface of the wine, to disrupt the rotational movement of the wine and create turbulence in the wine when the glass is moved in rotation and thus facilitate the release of the aromatic molecules.
Similarly, patent FR 2 817 134 from 2000 describes a glass comprising, on the inside of its parison, a rib extending along a generatrix of the parison surface, from the bottom of the glass to the rim. This rib is preferably in the shape of a facet locally perpendicular to the parison of the glass. It possibly consists of a local break away from the parison's peripheral contour. It also causes strong local turbulence in the wine, in order to bring out its aromatic molecules.
The drawbacks of these different implementations are either limited effectiveness or, on the contrary, real turbulence (exposed sharp edges of the ribs, break in the path of the wine), which is more likely to cause such effects as mixing of the wine and phenol breakdown amongst others, rather than light oxygenation and expression of the flavors.
The goal of this invention is to achieve an expression of the flavors of the wine by creating stirring movements within the glass.
In a second goal, the invention seeks to avoid breaking certain molecules present in the wine by overly forceful stirring, and rather to shake them in uniform manner.
To this end, the invention relates to a drinking glass, of the type comprising a parison with rotational symmetry around a vertical axis, comprising within said parison a set of at least two internal ribs evenly distributed on the periphery of the parison, each extending substantially along a generatrix of the parison, almost from the bottom of the glass, up to a height of the parison lower than the normal filling level of the glass, different for each of the internal ribs.
The internal ribs are angularly distributed in an even way to bring about a uniform stirring of the wine; this is not achieved with a single rib, which tends to disrupt the aromatic development of the wine, or with ribs protruding at too great an angle to the parison.
It can also be seen that it is desired here that the stirring effect stops beneath the level of the free surface of the wine to avoid surface turbulence effects.
According to an advantageous embodiment, the height of each internal rib corresponds to a normal fill level of the glass.
Here, the effect of stirring the contained wine is combined with easier visual measurement of the volume of wine poured into the glass.
Preferably, the glass comprises three internal ribs as described.
These three internal ribs then advantageously have heights corresponding respectively to seven, eleven and fifteen centiliter fillings of the glass, which correspond to the most traditional filling levels of a single glass.
According to a preferred embodiment, the internal ribs protrude from the inner surface of the parison.
This arrangement corresponds to a simpler realization of the glass and allows more complex rib sections to be realized.
Advantageously, the glass also includes, at the bottom of the parison, substantially along the vertical axis of symmetry of the glass, a protruding dome, called “nose-cap”, into which the internal ribs fuse.
It can be seen here that the objective is to push, to press the wine up against the inner wall of the glass, thus producing increased friction between the materials making up the glass and the wine. This principle facilitates all the more the release of the various flavors.
Alternatively, in the case of champagne glasses, the glass also comprises at the bottom of the parison a hollow dome on which the internal ribs fuse.
In this case, the hollow dome advantageously comprises between forty and eighty impacts, called “bubble hooks”, which allow the bubbles to rise uniformly at the center of the glass, in the shape of a chimney; this allows the formation of a real crown of foam at the periphery of the liquid.
In order to allow satisfactory development of the wine's flavors, the internal ribs preferably have a section similar to that of a propeller blade surface and of the nose-cap.
The invention also relates to a method for producing a glass as described, comprising steps in which:
The description that follows, given solely as an example of an embodiment of the invention, is made with reference to the figures included in an appendix, in which:
a to 6c detail the shape of the foot of the glass,
a-9c illustrate a goblet also fitted with internal ribs according to the invention,
As can be seen in
The term “rim” 5 is used in the remainder of the description to designate the upper lip of the parison. The glass 1 is also defined by the line 6 of its largest diameter.
This is a glass with a parison 2 of thirty-five centiliters, rounded and closed at the rim 5 to preserve the wine's flavors. This glass is particularly suited to all types of young still wines, by oxygenating the wine much more.
The dimensions of this glass 1 are as follows: total height of approximately twenty centimeters; parison 2 height of nine centimeters, for a maximum diameter of eight centimeters and a rim diameter of six centimeters. The portion of the parison 2 corresponding to the bottom of the glass has an inner radius of curvature of about four centimeters, while the upper part has a smaller radius of curvature, of the order of eleven centimeters.
The thickness of the parison 2 depends on the method of manufacture of this glass; it is assumed to be known to experts and beyond the scope of the present invention. Nevertheless, it will be thin at the rim and cracked-off.
The invention, however, remains unchanged for a flute- or goblet-type glass 1 or any other type of glass or liquid container with rotational symmetry.
The glass 1 comprises a set of three internal ribs 7a, 7b, 7c, substantially propeller blade-shaped, realized in relief inside the parison 2. These three internal ribs 7 are angularly distributed in an even way in the glass and therefore any two of them are approximately 120° apart.
The lower portion of each of these internal ribs 7 will fuse into a dome 8 protruding at the bottom of the parison 2, substantially along the vertical axis of symmetry Z of the glass 1. In this non-limiting case, the dome 8, shaped substantially as an airplane propeller or turbine “nose-cap”, has a height of about 5 mm above the bottom of the glass, and a radius of curvature of ten millimeters.
The internal ribs 7a, 7b, 7c extend substantially along a generatrix of the parison 2 of the glass 1, from the dome 8 at the bottom of the glass to a different height for each of the ribs, and equal in this example to 28, 35 and 42 mm above the bottom of the glass. In addition, these values correspond to seven, eleven and fifteen centiliter fillings of this tasting glass.
The largest internal rib 7b thus ends substantially at the largest diameter of the glass 6, which is also the normal filling level of the glass (the largest surface area for maximum oxygenation of the wine), here fifteen centiliters.
The choice of the propeller nose-cap shape of the dome 8 and of the three internal ribs 7 is intended to reproduce, to a certain extent, the shape and function of a propeller within the glass. This propeller is, as can be seen by looking at the figures, pressed against the inner edges of the glass 1.
The section of each inner rib 7 (
Viewed in cross-section, the width of the inner rib 7 is small in relation to its width, for example about one millimeter, and one to four millimeters when viewed higher up. The sides 9 of the straight section of the inner rib 7 are here shaped into an arc for simplicity of realization. Their sections are symmetrical. The upper part 10 of said inner rib 7 is flat or slightly concave.
In one embodiment, each rib has on its highest or thinnest part, an angle of + or −5 degrees in relation to a vertical plane.
The stem 3 of the glass here is a rod-type, known per se, and about ten centimeters high.
The foot 4 of the glass has the general shape of a thick disk of traditional dimensions in relation to the height and capacity of the glass (e.g. a diameter of seven centimeters for a thickness of seven millimeters), and its axis coincides with the vertical rotational axis Z of the glass.
It comprises, on its lower surface (which is designed to support the glass on its base surface), three substantially flat and coplanar support areas 12a, 12b, 12c, arranged on the periphery of the foot, at an angular separation of 120° to one another. These three support areas 12a, 12b, 12c form an isostatic base for the glass. They are about five millimeters wide and protrude by about two millimeters in relation to the lower surface of the foot 4.
The shape of the lower foot 4 (and that of the support areas 12) is obtained by removing, in a flat disk comprising the three support areas 12a, 12b, 12c, three cylinders sectors 13a, 13b, 13c, having the same radius equal to fifteen centimeters, horizontal axes angularly spaced at 120° from one another, and joining up at a same point of the vertical axis Z of the glass, located 148 mm below the plane formed by the support areas 12. These three cylinders sectors 13a, 13b, 13c are joined by rounded transition zones 14a, 14b, 14c.
This method of design of the lower surface of the foot of the glass explains the shape of the support areas 12, which comprise two ridges 15, 16 oriented at 120°, joined by a rounded portion 17.
This foot shape prevents water drops from stagnating in the lower surface of the foot when the glass is turned upside-down, as is the case for most existing stem glasses.
In this example, the glass according to the invention is realized in crystal. It can also be realized in glass, with or without minerals, crystalline or other material, preferably without lead oxide.
The method of realization of the glass is known per se. It is of machine-mechanical type and comprises, in this example, a step in which the parison 2 is created in a turned and blown mold, a step in which the stem 3 and the foot 4 are created in a fixed press mold, a step in which the stem and foot are assembled onto the parison and a step in which a seam running from the stem 3 to the foot 4 is glazed.
In one variant, the glass can also be realized as mouth-blown.
By giving a rotational movement, known per se, to the glass 1 by hand, traditionally anti-clockwise, the relative displacement produced in the glass is that of a three-bladed propeller stirring the wine.
During the rotation of the wine in the glass, the dome 8 causes a movement of wine towards the wall of the glass, by pressing it onto the inner parison of the glass. The wine will then gradually rise along the wall by being regularly mixed by the internal ribs 7 in the form of propeller-blades, and will release its primary, secondary and tertiary flavors in the free surface of the wine, i.e. between the level of the wine and the rim of the parison of the glass.
The choice of three internal ribs 7 of different heights, the largest of which ends at the normal free level of the wine in the glass, interestingly allows more vigorous stirring of the wine to be achieved at the bottom of the glass, which stirring diminishes with height.
Indeed, above the level of the least tall rib, only two ribs are acting on the stirring of the wine and then just one above the level corresponding to the height of the second rib. Thus the effect obtained is that a vigorous expression of the wine's flavors is maintained, without disrupting the free surface of the wine excessively.
It can be seen that the purpose of the tasting glass according to the invention is certainly not to create a blender by having the edges of internal ribs 7 too sharp, or internal ribs 7 extending too far above the free surface of the wine (this is the case of tasting glasses of the prior state of the art comprising internal ribs), but rather to allow the creation of a series of moderate movements within the wine, and of the wine along the inner wall of the parison 2, which will facilitate the exchange and release of the aromatic molecules of the wine without breaking them, but by shaking them uniformly.
The scope of this invention is not limited to the details of the forms of realization considered above as an example, but on the contrary extends to modifications in the reach of the expert.
The tasting glass as described comprises three internal ribs 7 distributed at 120° from one another. As a variant, it is possible to propose a glass with two internal ribs 7 at 180°, or, conversely, a larger number of internal ribs 7, for example, four internal ribs 7 located at 90°.
In one variant, the internal ribs 7 are hollowed out in the parison 2 of the glass, instead of being realized in relief, while retaining a substantially unchanged shape. In this case, the glass 1 has, of course, a sufficiently thick parison 2 locally, at each internal rib 7, to allow the creation of said internal rib 7.
The use of the glass in this variant remains substantially unchanged.
In another embodiment, providing the same effects of stirring the wine, the ribs 7 in the shape of the propeller blades are not stuck on the parison 2, but are simply substantially parallel to said parison 2, while being a few millimeters distant and just being attached to the glass 1 at the dome 8 at the bottom of the glass, or on a limited portion of their length.
In this case, the internal ribs 7 may advantageously be made of a material resistant to breakage, e.g. as a corrosion-resistant metal alloy.
This arrangement allows the glass 1 to be realized from separate members, including traditional half-parisons whose molds are known, with a final molding of the parison 2 around the dome 8. It also allows a more refined shape of the propeller blades. The stirring of the wine is also improved.
In a variant (
The purpose of these external ribs 11 is to function as a finger grip when the glass is picked up and thus create a distance between the fingers and the parison 2, so as to prevent the glass 1 being heated locally by the taster. For the three external ribs, one is calibrated and sized at 12.5 cl in order to obtain about six glasses of sparkling wine in a bottle
The presence of these external ribs 11 is particularly useful in the case of wines to be served chilled, such as white wines.
For champagne and sparkling wine, the presence of the internal ribs 7 is not desirable, except if it is desired to favor degassing the wine. Only the external ribs 11 are then present.
In a variant specifically dedicated to tasting champagne, illustrated for example in
In this case, the dome 8 is surface treated with a series comprising, typically but not limited to, forty to eighty impacts called “Moussier points”, whose function is to help create embryonic bubbles in the shape of a flange, thus contributing to the creation of a genuine crown of foam on the surface of the champagne. The creation of these Moussier points is known to experts and is therefore not detailed further here.
This champagne flute comprises three external ribs 11 as described above, but may possibly not have any internal ribs 7.
In yet another variant (
The description was made with internal ribs 7 with a substantially flat, symmetrical surface (their shape following that of the parison), ending in circular arcs (see
In one embodiment, illustrated in
Number | Date | Country | Kind |
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09 50126 | Jan 2009 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2010/050206 | 1/11/2010 | WO | 00 | 8/30/2011 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2010/079225 | 7/15/2010 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2627184 | Jones | Feb 1953 | A |
3341184 | Merrill | Sep 1967 | A |
4665035 | Tunac | May 1987 | A |
4880312 | Carlson | Nov 1989 | A |
7381559 | Ellis et al. | Jun 2008 | B2 |
20070267422 | Barducci | Nov 2007 | A1 |
Number | Date | Country |
---|---|---|
2005 239 717 | Jun 2006 | AU |
1 994 862 | Nov 2008 | EP |
2 684 534 | Jun 1993 | FR |
2 788 210 | Jul 2000 | FR |
2 817 134 | May 2002 | FR |
1 421 680 | Jan 1976 | GB |
Entry |
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International Search Report, dated Aug. 12, 2010, from corresponding PCT application. |
Number | Date | Country | |
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20110303680 A1 | Dec 2011 | US |