EP3634883A1

EP3634883A1 - Metering valve and fluid product dispensing device comprising such a valve

Info

Publication number: EP3634883A1
Application number: EP18735630.8A
Authority: EP
Inventors: Ludovic Petit; Ségolène SARRAILH
Original assignee: Aptar France SAS
Current assignee: Aptar France SAS
Priority date: 2017-05-05
Filing date: 2018-05-04
Publication date: 2020-04-15
Anticipated expiration: 2038-05-04
Also published as: US10968033B2; FR3065891A1; WO2018203013A1; FR3065891B1; JP2020518521A; EP3634883B1; US20200071062A1; JP7178364B2; CN110603207A

Abstract

The invention relates to a metering valve for a fluid product, comprising a valve body (10) containing a metering chamber (20), a valve member (30) sliding axially inside the valve body (10) between a rest position and a dispensing position, for selectively dispensing the contents of the metering chamber (20), said valve member (30) being urged into the rest position by a spring (8) that cooperates with both the valve body (10) and the valve member (30), said valve member (30) comprising a central axial channel (35) provided with an axial outlet (301) and a radial inlet channel (302) disposed inside the metering chamber (20) when the valve member (30) is in the dispensing position, said radial inlet channel (302) comprising, in the fluid product dispensing direction, an inlet (3021) and an outlet (3022) opening into the central axial channel (35), the diameter of the radial inlet channel (302) being between 0.30 and 0.40 mm and advantageously approximately 0.35 mm, the diameter of the outlet (3022) being equal to the diameter of the radial inlet channel (302) and the diameter of the inlet (3021) being greater than the diameter of the radial inlet channel (302).

Description

Dosing valve and fluid dispenser device comprising such a valve

The present invention relates to a metering valve and a fluid dispenser device comprising such a valve.

The so-called metering valves, in which each actuation of the valve, a precise dose of fluid is dispensed, are well known in the state of the art, and are generally assembled on a reservoir containing the fluid and a propellant used to achieve the expulsion of the dose.

Two types of metering valves are mainly known.

The so-called retention valves comprise a valve which, in the rest position, partially closes the metering chamber. More specifically, the outside of the valve cooperates sealingly with the chamber seal of the metering chamber, so that the metering chamber is connected to the reservoir, in this rest position, only via the internal channel of the valve.

The dosing chambers of so-called priming valves are filled only just before the actual actuation.

In both cases, filling the reservoir with the fluid to be dispensed is usually done after assembly of the metering valve on the reservoir, through said metering valve.

An important parameter for a metering valve is the share of fine particles distributed at each actuation. Indeed, these fine particles are particularly effective from a therapeutic point of view.

Another important parameter is the filling time of the tank through the metering valve, which must not be too long to slow down the manufacturing process.

The documents WO2014199182, US2007272767 and US2015023883 describe devices of the state of the art.

The present invention aims to provide a metering valve that does not reproduce the aforementioned drawbacks. The present invention thus aims to provide a metering valve that optimizes the portion of the fine particles distributed at each actuation, while ensuring an acceptable filling rate through said valve.

The present invention is intended in particular to provide a metering valve that is simple and inexpensive to manufacture and assemble, and reliable operation.

The subject of the present invention is therefore a metering valve for fluid dispensing, comprising a valve body containing a metering chamber, a valve sliding axially in said valve body between a rest position and a dispensing position, for selectively dispensing the contents of said metering chamber, said valve being biased towards its rest position by a spring cooperating on the one hand with said valve body and on the other hand with said valve, said valve comprising a central axial channel provided with a axial outlet port and a radial inlet channel which is disposed in said metering chamber when said valve is in the dispensing position, said radial inlet channel having, in the dispensing direction of the fluid product, an opening of an inlet and an outlet opening opening into said central axial channel, the diameter of said radial inlet channel being between 0.30 and 0.40 mm, advantageously approximately 0.35 mm, the diameter of said outlet opening being equal to the diameter of said radial inlet channel and the diameter of said inlet opening being greater than the diameter of said radial inlet channel.

Advantageously, said radial inlet channel is cylindrical over a major part of its length from said outlet opening.

Advantageously, the diameter of said inlet opening is between 0.6 and 0.8 mm, advantageously about 0.7 mm.

Advantageously, the radial depth of said inlet opening is about 0.2 mm.

The present invention also relates to a fluid dispensing device comprising a metering valve as defined above fixed on a reservoir. These and other features and advantages of the present invention will appear more clearly in the following detailed description thereof, with reference to the accompanying drawings, given by way of non-limiting examples, and in which:

FIG. 1 is a diagrammatic cross-sectional view of a dispensing valve in the rest position of the valve, in the right storage position of the valve,

FIG. 2 is a view similar to that of FIG. 1, in the position of actuation of the valve

FIG. 3 is a detail view in vertical section of the valve valve of FIGS. 1 and 2,

FIG. 4 is a detail view in horizontal section along the sectional plane A-A of FIG. 3,

FIG. 5 is a graph illustrating the amounts of fine particles expelled as a function of the diameter of the lateral hole of the valve, and

Fig. 6 is a graph illustrating the filling times of the reservoir through the valve as a function of the diameter of the lateral hole of the valve.

In the description below, the terms "up", "down", "down", "vertical" and horizontal "refer to the straight position shown in the figure

1, and the terms "axial" and "radial" refer to the longitudinal central axis of the valve shown in FIGS. 1 and 2.

The metering valve shown in Figure 1 comprises a valve body 10 extending along a longitudinal central axis. Inside said valve body 10, a valve 30 slides between a rest position, which is that shown in Figure 1, and a dispensing position, shown in Figure 2, in which the valve 30 is depressed at inside the valve body 10.

This valve is intended to be assembled on a reservoir 1 (of which only the neck is shown schematically in FIG. 1), preferably by means of a fastening element 5, which may be a crimp, screw or to snap, and advantageously with the interposition of a neck seal 6. Optionally, a ring 4 may be assembled around the valve body 10, in particular to reduce the dead volume in the inverted position and to limit the contact of the fluid with the neck seal 6. This ring 4 may be of any shape, and The example of Figure 1 is not limiting. In general, the tank 1 contains the fluid product and the propellant gas, in particular a formulation consisting of one or more active principle (s) active (s) in suspension and / or in solution in a liquefied propellant gas, as well as possibly excipients.

The valve 30 is biased towards its rest position by a spring 8, which is arranged in the valve body 10 and which cooperates on the one hand with this valve body 10, and on the other hand with the valve 30, preferably with a radial collar 320 of the valve 30. A metering chamber 20 is defined inside the valve body 10, said valve 30 sliding inside said metering chamber 20 to allow the distribution of the contents of the latter. when the valve is actuated.

The metering chamber 20 is preferably defined between two annular seals, a valve seal 21 and a chamber seal 22, as is well known.

The valve body 10 comprises a cylindrical portion 15 in which the spring 8 is disposed and in which the collar 320 slides between its resting and dispensing positions. In the position of Figure 1, this cylindrical portion 15 is the lower portion of the valve body. This cylindrical portion 15 has one or more longitudinal openings 1 1, such as slots, extending laterally in said cylindrical portion 15 of the valve body, over a portion of the axial height of the valve body in the direction of the axis. central longitudinal. These openings 1 1 allow the filling of the metering chamber 20 after each actuation, when in the inverted position of use (with the valve disposed under the reservoir), the valve 30 returns from its dispensing position to its rest position.

Figure 1 shows the valve in the upright storage position, i.e. the position in which the metering chamber 20 is disposed above the reservoir. The valve 30 includes a central axial channel 35 provided with an axial outlet port 301 and a radial inlet channel 302 which is disposed in the metering chamber 20 when the valve 30 is in the dispensing position. This radial inlet channel 302 comprises, in the dispensing direction of the fluid product, an inlet opening 3021 and an outlet opening 3022, the latter opening into said central axial channel 35.

Surprisingly, it has been determined that the dimensions of said radial inlet channel 302 have an impact on the amount of fine particles distributed at each dose,

The graph in Figure 5 illustrates test results that demonstrate this effect.

Thus, FIG. 5 demonstrates that the smaller the diameter of the radial inlet channel 302, the greater will be the share of fine particles distributed through the outlet opening 3022 of the valve 30. These results can be explained by the by decreasing the diameter of the radial inlet channel 302, the passage time of the formulation therein increases due to the increase in strength. As a result, the formulation is dispensed with a lower flow rate, which limits the deposition of fine particles in the throat area, thus allowing deeper deposition in the bronchi.

Figure 5 also shows that above 0.40 mm, the change in diameter has no impact on the fine particles.

The test of FIG. 5 consisted of evaluating the Aerodynamic Particle Size Distribution (APSD) from a metering valve. This test was carried out with a specific equipment called pharmaceutical impinger, and more precisely the NGI ("Next Generation Impactor", described in the pharmacopoeia under the name of apparatus E). The tests were carried out at a rate of 30 liters per minute. The graph in Figure 5 shows the sum of the fine particles entering the impactor. It is observed that the smaller the diameter of the radial inlet channel 302, the more efficient the valve is in terms of the size of the particles expelled during a spray. The values shown in the graph in Figure 5 are particle amounts fine, ie of so-called "small" size. In the context of the test of FIG. 5, these are particles whose aerodynamic diameter is less than 6.4 μιη. It is particularly interesting that this value is the greatest possible, because the fine particles of adequate size are particularly effective from a therapeutic point of view.

The tests were carried out with a formulation containing a high percentage of ethanol (15% w / w), an excipient, an active ingredient (salbutamol sulfate) and HFA 134a as a propellant. The tanks tested were all filled with the same formulation,

Of course, the smaller the diameter of the radial inlet channel 302, the longer the filling time of the tank 1 through the valve will be long. However, a filling time that is too long may prove unacceptable.

FIG. 6 is a graph showing filling times according to the diameter of the radial inlet channel 302. The time indicated is the filling time only, and does not take into account the entire cycle (setting up the reservoir in the machine , lowering of the filling head, etc.). The purple line represents the typical time for a standard valve, from which it is desirable not to go too far.

Figure 6 shows that below 0.30 mm, the filling time becomes too important

Therefore, according to the invention, the diameter of the radial inlet channel 302 is between 0.30 and 0.40 mm, advantageously about 0.35 mm. This makes it possible to optimize the rate of distributed fine particles, without unacceptably slowing down the filling time of the tank. The therapeutic efficacy of the distributed fluid product is therefore improved.

In the preferred embodiment shown in the figures, the radial inlet channel 302 is cylindrical over a major portion of its length from said outlet opening 3022 to said inlet opening 3021.

The diameter of said outlet opening 3022 is equal to the diameter of said radial inlet channel 302 while the diameter of said inlet opening 3021 is greater than the diameter of said radial inlet channel 302, in particular between 0.6 and 0.8 mm, advantageously about 0.7 mm, while the radial depth of said inlet opening 3021 is preferably about 0.2 mm. This is particularly visible in FIGS. 3 and 4. This implementation is advantageous during molding in order to reduce the length of the small diameter spindle in order to produce radial inlet channel 302, which is fragile. In addition, this implementation makes it possible not to have such a fragile pin tangent to the outer circular edge of the valve. This further strengthens the robustness of the molding means and thus improves the manufacturing reliability of the valve.

In known manner, the valve 30 can be made in two parts, namely an upper part 31 (also called high valve) and a lower part 32 (also called bottom valve). The upper part 31 comprises said central axial channel 35, said axial outlet orifice 301 and said radial inlet channel 302. In this embodiment, the lower part 32 is assembled inside the upper part 31.

An internal channel 33 is provided in the valve 30, in particular in the lower part 32, which makes it possible to connect the metering chamber 20 to the reservoir 1, to fill said metering chamber 20 when, after each actuation of the valve, the valve 30 returns to its rest position under the effect of the spring 8. This filling is done when the device is still in the inverted position of use, with the valve disposed below the tank 1.

In the example of Figure 1, when the valve 30 is in the rest position, the metering chamber 20, outside the valve 30, is substantially isolated from the tank 1 by the cooperation between the lower part 32 of the valve 30 and the chamber seal 22. In this rest position, the metering chamber 20 remains connected to the reservoir 1 only via said inner channel 33. The valve shown in Figures 1 and 2 is a retention valve. The invention is, however, also applicable to other types of valves, including ACT type valves.

Although the present invention has been described with reference to a particular embodiment thereof, it is understood that it is not limited by the example shown. On the contrary, the skilled person can bring all useful modifications without departing from the scope of the present invention as defined by the appended claims.

Claims

claims

1. - Fluid dispensing metering valve, comprising a valve body (10) containing a metering chamber (20), a valve (30) axially slidable in said valve body (10) between a rest position and a position of distribution, for selectively dispensing the contents of said dosing chamber (20), said valve

(30) being urged towards its rest position by a spring (8) cooperating on the one hand with said valve body (10) and on the other hand with said valve (30), said valve (30) having an axial channel central (35) having an axial outlet (301) and a radial inlet channel (302) which is disposed in said metering chamber (20) when said valve (30) is in dispensing position, said radial inlet channel (302) having, in the dispensing direction of the fluid product, an inlet opening (3021) and an outlet opening (3022) opening into said central axial channel (35), characterized in that the diameter of said radial inlet channel (302) is between 0.30 and 0.40 mm, advantageously about 0.35 mm, the diameter of said outlet opening (3022) being equal to the diameter of said radial inlet channel (302) and the diameter of said inlet opening (3021) being larger than the diameter of said radial inlet channel (302).

The valve of claim 1, wherein said radial inlet channel (302) is cylindrical over a major portion of its length from said outlet opening (3022). 3. Valve according to claim 1 or 2, wherein the diameter of said inlet opening (3021) is between 0.6 and 0.8 mm, advantageously about 0.7 mm.

4. Valve according to any one of the preceding claims, wherein the radial depth of said inlet opening (3021) is about 0.2 mm. 5. Fluid dispensing device characterized in that it comprises a metering valve according to any one of the preceding claims fixed on a reservoir (1).

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