The invention relates to a flow reducer for a pressurized product dispenser, in particular for an aerosol generator of the type provided with a diffuser and a valve equipped with a stem.
Pressurized product dispensers are commonly used in many areas. To distribute their content, they are equipped with valves provided with a stem. Depending on the needs, these valves can be one-way valves or two-way valves. Two-way valves are used when two products must be kept separate until the time of their simultaneous application. For this purpose, the products are stored in two different reservoirs, which are generally two pouches, arranged side by side or one in the other, or one product in a pouch and the other product in the aerosol can. Two-way valves can also be used to distribute the product contained in the dispenser through a first path and the propellant gas through the other path, the product being contained, if needed, in a pouch protected from the propellant gas. To actuate the valve, a diffuser is placed at the top of the stem. When the diffuser is used with a two-way valve, the two products come in contact with each other only at the outlet of the stem, or even at the outlet of the diffuser. To introduce the product or products into the pressurized product dispensers, it is common practice to make them enter their respective reservoirs (pouches or cans) via the valve, and therefore, via the paths extending through the stem. The less viscous the products, and the larger the transverse cross-sections of the paths, the simpler and quicker this operation. However, if entry of the product is facilitated, its exit is also made easier. But in order to obtain a good aerosol or a good foam, it can be necessary to limit the flow rate of the product leaving the valve. In the case of two-way valves, it can also be necessary that the two products do not come out at the same flow rate. Likewise, when the two products have different viscosities, it can be necessary to adapt the transverse cross-sections of the paths to obtain the desired flow rate for each of the products. Until now, the adaptation of the transverse cross-sections of the paths to guarantee the desired flow rate of the product or of each of the two products has been done in the stem, through the choice of size and number of orifices giving access to the paths of the stem, and in the diffuser, via the nozzle outlet. This means that each stem and each nozzle must be adapted on a case-by-case basis, which requires different molds for their manufacture, and large stocks. In addition, the choice of size and number of orifices in the stems can limit the filling speed when the container is filled via the valve, and thus through the stem.
The objective of the invention is to make it possible to adjust the flow rate of a valve, whether a one-way or a two-way valve, to the requirements linked to the products to be applied, while keeping a stem having the largest possible paths. Preferably, the reducer will be designed to make it possible to also keep the other standard components.
This objective is achieved in that the flow reducer is constituted by a part which is separate from the stem and preferably from the diffuser, and which comprises
the outer face of the reducer, on the side opposite to the opening of the recess, preferably having a contour which is in part substantially identical to that of the portion of the stem protruding from the valve and intended to be covered by the reducer.
When the flow reducer is intended for a two-way valve equipped with a two-way stem having a first path and a second path, the flow reducer can further comprise
Once mounted on the stem, the reducer extends the path, or the two paths which remain isolated from one another until the outlet orifices. It is sufficient to adapt the number and/or the cross-section of the outlet orifices to adjust the flow rate of the products in each path. This way, it is possible to keep stems having paths of large cross-sections, and standard diffusers. Only the reducer, an element which is simple to manufacture, is adapted on a case-by-case basis. The reducer can be used both for stems with a single path and for stems with two concentric paths or two parallel paths.
Whether a stem with a single path or a stem with two concentric paths, the stem has generally a first tubular wall defining the first path. In this case, the reducer preferably comprises:
To allow the flow reducer to have, on its outer face opposite to the opening of the recess, the shape of the first tubular wall of the stem for which it is intended, it is preferable that
When the reducer is intended for a valve with two concentric paths whose stem has a first tubular wall defining the first path and a second tubular wall partly surrounding the first tubular wall and defining the second path, it is preferable that the flow reducer further comprises
Such a flow reducer allows the products to remain separated until they leave the reducer. If the separation must continue until within the diffuser, or even until the outlet of the diffuser, the top cylindrical wall and the separation of the top closure wall into a first top closure wall and a second top closure wall will be provided, as indicated previously. If, on the contrary, a separation of the products beyond the stem is not necessary, it is possible to dispense with the top cylindrical wall.
In order to carry out the extension of the second path, it can be provided to make one or more channels in the first path cylindrical wall, which channels extend to the top closure wall or to the first top closure wall, each channel opening into one or more of the second outlet orifices.
To ensure sealing, on the one hand, at the junction between the flow reducer and the stem, and on the other hand, between the extension of the first path and the extension of the second channel, it is preferable to provide
It is preferable that the outer contour of the first path cylindrical wall is adapted to cooperate with a diffuser, preferably with a diffuser adapted to cooperate with a stem for which the flow reducer is intended. In particular, the outer contour of the top cylindrical wall can be adapted to cooperate with a diffuser for single-way or two-way valve, in particular a diffuser adapted to cooperate with a stem for which the flow reducer is intended. In such a case, the outer contour of the reducer at the first path cylindrical wall and, where appropriate, at the top cylindrical wall, is preferably substantially identical to the contour of the stem on which it is mounted, so that it cooperates with the diffuser as the stem would have done. This way, it is possible to use the same diffusers for the bare stems or for the stems equipped with a reducer. If using the same diffusers is not required, and specific diffusers can be produced, this identity of form can be dispensed with.
The flow reducer can be sold separately. It can also be sold associated with the valve and/or the diffuser for which it is intended, in particular in the form of a set. It is also conceivable that the reducer is sold pre-assembled on the diffuser for which it is intended.
The invention is explained in more detail below with the assistance of the figures which show:
The invention concerns a flow reducer (10) for a stem (20) of a one-way or two-way valve (30) used with a can (40) in pressurized containers. Such stems (20) are sometimes referred to as valve rods. The flow reducer is intended to be placed between the free end of the stem (20) protruding outside the valve and the diffuser (50), itself usually placed directly on this protruding end.
In the case of two-way valves, the stems (20) may be of the type with concentric paths, as in the example presented here (see in particular
A two-way valve stem can be used in a two-way valve (30) with parallel pouches, such as that shown by way of example in
The stem and the flow reducer of the invention usually have a certain rotational symmetry about a main axis (A) passing through the stem and the flow reducer. It will be seen that this rotational symmetry is not absolute, as certain portions of the reducer deviate from it. The adjectives “axial” or “radial” refer to this main axis (A) and define an element respectively parallel or perpendicular to this axis. To simplify the description, the spatial references such as “top” and “bottom”, or “upper” and “lower”, refer to the flow reducer and to the stem as shown in
A stem for a one-way valve generally comprises a first tubular wall forming a cylindrical channel that is open upwards and forms part of the single path. When the valve is open, this single path communicates with the inside of the can or with a reservoir placed inside the can, such as a flexible pouch.
When the stem is intended for a two-way valve, this first tubular wall (21) is surrounded in part by a second tubular wall (22) forming an annular channel that is open upwards and forms part of the second path. The second tubular wall (22) generally does not extend as high as the central first tubular wall (21). When the valve is open, each path of the stem communicates with its respective reservoir, generally a flexible pouch or the inside of the can, in a known manner via the valve. It is also possible that the product to be dispensed is contained directly in the can with the propellant gas, the product exiting by the first path and the propellant gas by the second path. To simplify the remainder of the description, reference will be made generally to pouches, without this being a limitation, as these pouches may be replaced by any other type of reservoir capable of fulfilling the same function.
The flow reducer (10) of the invention is fitted over the protruding end of the stem and can maintain the separation of the paths when it is intended for a two-way valve.
The invention is explained in more detail below with the aid of a reducer for concentric two-way valve. In the example presented here, the flow reducer (10) is constituted by three main portions: a first cylindrical wall (11), corresponding to the second path cylindrical wall, a second cylindrical wall (12), corresponding to the first path cylindrical wall, and a third cylindrical wall (13), corresponding to the top cylindrical wall, each defining a cylindrical inner space.
The first end (lower end) of the first cylindrical wall (11) is open and constitutes the lower end of the flow reducer (10). The second end (upper end) of the first cylindrical wall (11) and the first end (lower end) of the second cylindrical wall (12) are connected together by a first radial wall (111), corresponding to the intermediate closure wall. The second end (upper end) of the second cylindrical wall (12) and the first end (lower end) of the third cylindrical wall (13) are connected together by a second radial wall (121), corresponding to the first top closure wall. Finally, the third cylindrical wall (13) is closed at its second end (upper end) by a third radial wall (131), corresponding to the second top closure wall. These three radial walls participate in closing the inner spaces defined by the three cylindrical walls and constitute closure walls. The cylindrical walls and the radial walls all together define a recess corresponding to the three cylindrical spaces. The recess is open at the free end of the first cylindrical wall (first end opposite to the first closure wall (111)). It will be seen that this recess is adapted to be fitted by the opening of the recess over a two-way stem, without the stem necessarily penetrating into the back end of the recess. In particular, the stem is not intended to penetrate into the top cylindrical space. The three main walls (11, 12, 13) of the flow reducer (10) are not necessarily absolutely cylindrical. They can be slightly frustoconical, generally in a non-perceptible manner, to facilitate demolding. This deviation from a perfectly cylindrical shape is expressed by the term “substantially” cylindrical, simplified below by the adjective “cylindrical”. Likewise, the closure walls (111, 121, 131) are here radial, but they could be inclined or of any other suitable shape.
The inner diameter of the first cylindrical wall (11) of the flow reducer is substantially equal to or slightly smaller than the outer diameter of the second tubular wall (22) of the stem. The inner diameter of the second cylindrical wall (12) is substantially equal to or slightly smaller than the outer diameter of the first tubular wall (21) of the stem. This is clearly visible in
In addition, the outer diameter of the second cylindrical wall (12) of the flow reducer is substantially equal to the outer diameter of the second tubular wall (22) of the stem, and the outer diameter of the third cylindrical wall (13) is substantially equal to the outer diameter of the first tubular wall (21) of the stem. This is also visible in
When the flow reducer is mounted on a stem (20), the first tubular wall (21) of the stem penetrates into the second cylindrical wall (12) of the reducer and the second tubular wall (22) of the stem penetrates into the first cylindrical wall (11) of the reducer. The inner diameters of the first and of the second cylindrical wall (11, 12) are therefore chosen to ensure permanent contact between the inner face of this cylindrical wall (11, 12) and the outer face of the corresponding tubular wall (21, 22) of the stem (see in particular
The height of the outer face of the third cylindrical wall (13) is preferably substantially equal to the difference in height between the top of the first tubular wall (21) and the top of the second tubular wall (22) of the stem. The inner height of the first cylindrical wall (11) and that of the second cylindrical wall (12) are chosen so that the two tubular walls (21, 22) of the stem are each in contact with at least a portion of the inner face of the corresponding cylindrical wall (22/11, 21/12) when the flow reducer is mounted on a stem, also ensuring, on the one hand, the continuity of the two paths, and on the other hand, their sealed separation. It is not necessary for the first cylindrical wall (11) of the flow reducer to be as high as the protruding portion of the second tubular wall (22) of the stem.
In order to ensure sealing between the two paths, the third cylindrical wall (13) can be extended downwards, inside the second cylindrical wall (12), by a first path sealing end-piece (132), whose outer diameter is substantially equal to the inner diameter of the first tubular wall (21) of the stem. Likewise, the second cylindrical wall (12) of the reducer can be extended downwards, inside the first cylindrical wall (11), by a second path sealing end-piece (122), whose outer diameter is substantially equal to the inner diameter of the second tubular wall (22) of the stem. Due to the tight fit of the first cylindrical wall (11) over the second tubular wall (22) of the stem, on the one hand, and of the second cylindrical wall (12) over the first tubular wall (21) of the stem, on the other hand, it would be possible to dispense with the second path sealing end-piece (122).
To facilitate the installation of the reducer on the stem, it is preferable to chamfer the inside of the first and the second cylindrical wall (11, 12) at their respective lower ends in order to enable a self-centering effect of the reducer with respect to the stem. When a second path sealing end-piece (122) is provided, it is sufficient to chamfer its inner face, without the chamfer necessarily reaching the inner face of the second cylindrical wall (12). Likewise, it can be provided to chamfer the outer face of the two sealing end-pieces (121, 131).
A central channel (133) of substantially constant diameter passes through the third cylindrical wall (13) from its lower end, or from the lower end of the sealing end-piece (132) when there is one, to the third radial wall (131) that close the third cylindrical wall (13). A central outlet orifice (134) is made in the third radial wall to bring the central channel (133) in contact with the outside of the reducer. This outlet orifice (134) corresponds to one of the first outlet orifices. Rather than a single orifice, it would be possible to provide several orifices in the third radial wall (131). Likewise, one or several side channels (123), here, two side channels, can be made in the thickness of the second cylindrical wall (12). These channels extend from the lower end of the second cylindrical wall, or from the second path sealing end-piece (122) when there is one, to the second radial wall (121) that closes the second cylindrical wall. Each side channel (123) ends with one or more outlet orifices (124) made in the second radial wall (121) that closes the second cylindrical wall. These outlet orifices (124) correspond to the second outlet orifices. The side channels (123) can be made entirely within the mass of the cylindrical wall (12), or they can be included only partially in this wall, as is the case in the example presented here. This is clearly visible in
The flow reducer (10) is preferably made of a plastic material, for example, a flexible polyolefin to facilitate the assembly with a tight fit and to participate in the sealing of the flow reducer (10) on the stem (20).
When the flow reducer is mounted on a stem, the product contained in the first reservoir (generally a first pouch) leaves the valve by the first path, which ends in the central channel located in the first tubular wall (21) of the valve stem. The product leaving the stem via this first path enters the central channel (133) of the third cylindrical wall of the flow reducer and leaves through the outlet orifice (134) at the top of the flow reducer. The central channel (133) therefore constitutes an extension of the first path. The product contained in the second pouch (or in the can) leaves the valve via the second path, which ends in the annular channel defined between the first tubular wall (21) and the second tubular wall (22) of the stem. The product leaving the stem via this second path enters the two side channels (123) and exits through the outlet orifices (124) located on the second radial wall (121) at the junction between the second and third cylindrical walls (12, 13). The side channels (123) therefore constitute an extension of the second path. Upon leaving the orifices (124, 134), the products enter the diffuser as they would have done if they had come directly from the stem. The first path sealing end-piece (132) ensures the separation of the two products. The second path sealing end-piece (122) participates in sealing the second path from the outside.
The transverse cross-section of the outlet orifices (124, 134) and/or the number of side channels (123) are chosen according to needs, namely, the ratio between the two products to be dispensed, taking into account the viscosity of each. It is thus possible to have several different flow reducers for the same set of stem and diffuser. A stem having two paths of large transverse cross-sections is kept, which allows filling the pouches quickly, while being able to adapt the output flow rate thanks to the reducer of the invention. Due to its outer contour having the same dimensions as those of the stem, it is not necessary to modify the diffusers, which can be fitted over the reducer as they would be over a stem. At most, the height of the diffuser skirt can be adapted to compensate for the additional height due to the presence of the flow reducer, if this skirt needs to extend down to the valve cup or to the can. The reducer can be supplied alone, mounted in a diffuser, or even temporarily placed on a two-way valve.
If separating the paths is no longer necessary when leaving the valve, it is possible to dispense with the third cylindrical wall (13). In this case, the second radial wall (121) closing the top of the second cylindrical wall (12) extends over the entire transverse cross-section of the channel defined by the cylindrical wall (12), the central outlet orifice (134) being produced in the center of this radial wall (121) so as to face the first path of the stem defined by the first tubular wall (21). It can even be envisioned to dispense with the first path sealing end-piece 132.
The person skilled in the art understands that the system can be adapted to stems with parallel rather than concentric paths. In this case, the flow reducer is provided with two non-concentric parallel paths, each with one or more outlet orifices whose transverse cross-section is adjusted on a case-by-case basis.
It should be noted that the flow reducer of the invention has almost no effect on pressure and does not fulfill the function of a pressure reducer.
When the flow reducer is intended for a single-way valve, it is not necessary to provide the first cylindrical wall (11), nor the channels (123), nor the second orifices (124).
The person skilled in the art also understands that it would be possible to adapt the flow reducer to stems comprising more than two paths, for example, stems with three parallel or concentric paths.
The reducer of the invention can be used for any type of aerosol, for the application of pasty products, for foams, gels or liquids. It can be applied to bag-on valves, whose pouches can be welded or snapped onto the valve body.
Number | Date | Country | Kind |
---|---|---|---|
1852090 | Mar 2018 | FR | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2019/055451 | 3/5/2019 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/174970 | 9/19/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3982668 | Riccio | Sep 1976 | A |
5385303 | Gosselin et al. | Jan 1995 | A |
9192948 | Bodet et al. | Nov 2015 | B2 |
20080230566 | Frutin | Sep 2008 | A1 |
20130284293 | Bodet et al. | Oct 2013 | A1 |
Number | Date | Country |
---|---|---|
9510463 | Apr 1995 | WO |
2005082743 | Sep 2009 | WO |
2009134129 | Nov 2009 | WO |
2012045562 | Apr 2012 | WO |
2016181823 | Nov 2016 | WO |
Entry |
---|
International Search Report and Written Opinion dated Jun. 4, 2019 in corresponding application No. PCT/EP2019/055451; w/ English partial translation and partial machine translation (total 20 pages). |
Number | Date | Country | |
---|---|---|---|
20210107727 A1 | Apr 2021 | US |