FR2961795A1 - DOSING VALVE FOR PRESSURIZED BOTTLE - Google Patents

Abstract

The invention relates to a metering valve (1) for a pressurized bottle, comprising a valve body (9) in which a valve (4), a metering chamber (7) and means for moving the valve (4) can slide. ) between a closed position in which, when mounted on a vial, the metering chamber (7) is in contact with the interior of the vial and isolated from the outside of the vial, and an open position in which, at in the assembled state, the metering chamber (7) is isolated from the inside of the bottle and in contact with the outside of the bottle. According to the invention, the metering chamber (7) is fixed by its upper end to the a portion of the valve body (9), in the assembled state, inside the vial, an inlet passage (99, 981, 714, 712) being provided which contacts the inside of the vial and the chamber metering device and an outlet passage (712, 714, 442, 443, 51b, 45, 42) bringing the dosing chamber into contact with the outside of the valve, the inlet obstruction means being provided for obstructing the inlet passage when the valve (4) is in the open position and outlet obstruction means being provided for obstructing the outlet passage when the valve (4) is in closed position.

Description

Description

The invention relates to a metering valve for a pressurized bottle, comprising a valve body in which a valve, a metering chamber and means for moving the valve between a closed position in which, when mounted on a vial, the metering chamber is in contact with the interior of the vial, and an open position in which, in the mounted state, the metering chamber is isolated from the inside of the vial.

The metering valve of the invention is intended for a pressurized bottle. Dosage devices for pressurized vial valves are commonly used to deliver a predetermined amount of a product. The product to be dispensed is in a bottle containing a propellant. The product is either in direct contact with the propellant gas or contained in a flexible bag immersed in the propellant gas.

Different types of metering devices are known for valves of pressurized flasks.

For example, EP 1 099 647 A1 proposes a metering device provided with a metering chamber located downstream of the valve, placed on the stem of the valve of the vial. The metering chamber consists of a cylinder in which a piston slides. The bottom of the cylinder is provided with an orifice which is in direct contact with the outlet of the valve stem. The piston is also provided with an orifice which continues with an axial tube which slides in a safety element in which there is a second valve. To take a dose of product, it is first necessary to move the cylinder of the metering chamber downwards so that it presses on the stem of the valve and thus opens the latter. The pressurized product exiting the vial valve enters the metering chamber by pushing the piston upwards. The product also enters the tube that leads to the outlet valve of the security element. Once the metering chamber is full, the cylinder is returned to the rest position to close the valve of the bottle. It is now possible to actuate the valve of the safety element by pressing a traditional diffuser. In order to move the cylinder downwards in order to fill the metering chamber, a ring must be rotated in which two inclined guide grooves are formed and into which two peripheral projections of the cylinder penetrate. Thus, when the projections are in the upper part of the grooves of the ring, the cylinder is in the up position and does not rest on the stem of the valve of the bottle. On the contrary, when they are in the lower part, the cylinder is translated downwards and it presses on the stem causing the opening of the valve of the bottle. Therefore, to take a dose, it is first necessary to turn the ring a first time to fill the metering chamber, then a second time to close the valve of the bottle. It is then necessary to press a diffuser located in the upper part of the security element to open the second valve. This device is not a very simple use. In addition, it requires two different valves.

EP 0 642 992 A1 discloses a metering device intended to be mounted in the opening of the neck of a container containing the product to be dispensed. The metering device is equipped with a valve comprising a metering chamber and a stem. In a first position of the stem, the metering chamber is in contact with the interior of the container and fills with a given amount of product. In a second position of the stem, the metering chamber is isolated from the interior of the container and is brought into contact with the outside, allowing the product contained therein to be expelled. For this, the metering chamber is delimited axially on one side by an annular valve seal and on the other by a chamber seal also annular. The stem crosses the two joints. It comprises a first distribution channel arranged axially and open towards the bottom and upwards by two radial openings. It comprises a second axial distribution channel, which has on the side facing the first channel a radial opening and the side of the free end of the stem an axial opening. In the resting position, maintained by a spring, the stem is positioned so that the upper opening of the first channel is located inside the metering chamber, between the two seals while the radial opening of the second channel is obstructed by the valve seal. The lower opening of the first channel opens into the vial. In this position, the metering chamber fills with the product contained in the container via the first channel as soon as the bottle is put upside down. If the user presses the stem against the effect of the spring, the radial openings are displaced. The upper opening of the first channel is obstructed by the chamber seal while the radial opening of the second channel opens into the metering chamber. The product, mixed with the propellant, is expelled from the metering chamber under the effect of pressure via the second channel. This device requires that the bottle is upside down to be used.

The object of the invention is to develop a dosing device for a pressure bottle valve that is simple to handle. It must be able to be used in all positions of the bottle.

This object is achieved according to the invention in that the dosing chamber is fixed at its upper end to the part of the valve body located, in the mounted state, inside the bottle, an inlet passage being provided to contact the interior of the bottle and the metering chamber and an outlet passage contacting the metering chamber and the outside of the valve, input obstruction means being ~ o provided to obstruct the passage when the valve is in the open position and outlet obstruction means being provided to obstruct the outlet passage when the valve is in the closed position. Thus, the metering chamber is located inside the bottle, upstream of the valve, and not inside the valve itself.

It may sometimes be necessary for the valve normally intended to deliver a precise dose of product to also be able to deliver a larger dose without it being necessary to actuate the valve several times in succession. For this, the valve can be moved beyond the open position in a third position called short-circuited position, a third passage, called short-circuit passage, being provided to bring the inside of the bottle into contact with the outside the valve, preferably without passing through the dosing chamber, short-circuit obstruction means being provided to obstruct the short-circuit passage when the valve is in the closed position or in the open position, the means for the inlet obstruction and / or the outlet obstruction means preferably being in the closed position when the valve is in the short-circuited position if the short-circuit passage does not pass through at least a portion of the passageway. entrance and / or exit passage. In the short-circuited position, it is possible to take a larger quantity of product than that imposed by the volume of the dosing chamber.

It is preferred that the inlet obstruction means and the outlet obstruction means are independent of one another.

In a preferred embodiment of the invention, the inlet passage is constituted by at least one hole made in the wall of the valve body, in a zone in contact with the inside of the bottle or pocket, a orifice formed in a wall located inside the valve body and an orifice made in the wall of the metering chamber and in that the inlet obstruction means are constituted by the lower end of the valve having the shape of a cylindrical post and whose radial section corresponds to the inner dimensions of the wall opening so that, when the post penetrates into this opening, it closes it hermetically, the wall preferably having the shape of a collar ending in funnel-shaped directed towards the metering chamber. In order to reinforce the sealing of the inlet obstruction means, it is preferable to place sealing means, preferably an O-ring, below the orifice made in the wall. Thus, when the pin comes into contact with the orifice of the wall of the valve body, it also bears against the O-ring.

The outlet passage is preferably constituted by an orifice made in a wall of the metering chamber, an orifice made in a wall located inside the valve body, a lower central channel and an upper central channel made in the valve. and separated from each other by a barrier, at least one orifice being made in the wall of the valve bringing the inside of the upper central channel into contact with the outside of the valve and at least one orifice being made in the wall of the valve contacting the interior of the lower central channel with the outside of the valve, a contacting passage being provided for bringing the orifice or openings into contact with the orifice or openings, and in that the outlet obstruction means are constituted by a chamber seal constituted by an annular wall inside which the valve can slide, the inner face of the chamber seal having at least one go annular rge whose height is at least equal to the vertical distance separating the orifice or openings made in the upper central channel and the orifice or orifices made in the lower central channel, the orifices of the upper central channel and / or the or orifices of the lower central channel being obstructed by the inner face of the annular wall when the valve is in the closed position, thereby obstructing the outlet passage, and the orifices of the upper central channel and the orifices of the lower central channel opening on the annular groove when the valve is in the open position, thus releasing the outlet passage.

It is preferable that the metering chamber comprises a cylinder whose opposite end to the valve body, said lower, is closed by a radial wall, said lower, and the end facing the valve body, said upper, is closed by a radial wall, said upper, a piston being able to slide inside the cylinder between these two radial walls by defining a dosing volume. In this case, the upper radial wall of the metering chamber may be provided with a opening, the piston being able to slide between the two radial walls of the cylinder, a spring being provided between the lower radial wall of the metering chamber and the piston to push the latter, in the absence of other constraints, against the upper radial wall equipped with the opening.

In order to allow the insertion of the piston into the dosing chamber, it is preferable that the cylinder forming the dosing chamber on the one hand and its upper radial wall and / or its lower radial wall on the other hand constitute different parts. ~ o can be assembled or separated from each other, means being provided for fixing said wall on the cylinder.

In order to separate the propellant and the product, it is possible to weld a flexible bag on the valve body by enclosing the metering chamber and the beginning of the inlet, outlet and, if appropriate, short-circuit paths. . Thus, when a pocket is provided, the inlet, outlet and short-circuit paths open upstream, not in the bottle, but in the pocket. With such a pocket, the valve can be used regardless of the position of the bottle.

In concrete terms, the valve may consist of a first so-called upper cylindrical wall forming a first axial channel, said upper, and a second cylindrical wall forming a second axial channel, the two axial channels being isolated from one another. the other by a barrier, the upper channel being open at its upper end by an axial opening and the side of the barrier by at least one radial opening opening on the outer face of the valve, the lower channel being open at its end lower by an axial opening and the side of the barrier by at least one radial opening opening on the outer face of the valve, the valve being preferably provided with at least one annular stop on its circumference to limit its movement inside. valve body to the outside or inside. At the same time, the valve body may be provided with a chamber seal disposed in the valve body so that in the closed position of the valve, the radial hole or holes in the upper channel of the valve are at the seal of the valve. chamber, obstructed by the latter, the annular abutment bearing sealingly against the chamber seal. When the valve must allow short-circuiting of the metering chamber, it is preferable to provide the valve with a third cylindrical wall partially surrounding at least the first cylindrical wall and concentric with it, forming an annular channel, which annular channel is isolated from the other two and provided with an axial opening at its upper end and at least one radial hole bringing into contact the inside of the annular channel and the outside of the valve. The valve body and the valve are then sized so that the valve can be moved beyond the open position into a so-called shorted position, and the valve body is provided with a valve seal placed opposite of the metering chamber relative to the chamber seal and positioned ~ o so that in the mounted state of the valve, the radial hole or holes of the annular channel are, in the closed position of the valve, to the outside the bottle, that in the open position of the valve, the radial hole or holes of the annular channel are located opposite the valve seal, obstructed by the latter, or outside the bottle, and that in short position Valve circuit or the radial holes of the annular channel are on the side of the valve seal 15 opposite the outer side.

At least one side channel may be provided on the outer face of the valve body, said side channel being provided with a first opening opening, in the assembled state, inside the bottle or the pocket, and a second opening opening into the valve body between the valve seal and the chamber seal. When the valve is provided with a flexible pouch, it is welded to the valve body by enclosing the first opening of the lateral channel (s) of the valve body so that the lateral channel (s) make contact with the inside of the valve body. the pocket and the inside of the valve body between the valve seal and the chamber seal. The invention is described in more detail below with the aid of an exemplary embodiment presented in the following figures which show:

Figure 1 is a sectional side view of the metering valve as a whole; Figure 2: an exploded view of the metering valve; Figure 3: an enlarged sectional view (a) front view and (b) side view of the valve in the closed position; Figure 4: an enlarged sectional view (a) front view and (b) side view of the valve in the open position; Figure 5 is an enlarged sectional view (a) front view and (b) side view of the valve in a shorted position; Figure 6: the spacer (a) seen in perspective and (b) seen in section; Figure 7: the chamber seal (a) seen in perspective and (b) seen in section. Figure 8: the lid of the metering chamber (a) seen in perspective from above and (b) seen in perspective from below; Figure 9: the bottom of the metering chamber (a) perspective view from above and (b) perspective from below; Figure 10: the valve body seen (a) in perspective from above, (b) in perspective from below, (c) in front section, (d) in side section and (e) in plunging perspective; ~ o Figure 11: the stem seen (a) in front section, (b) side section, (c) in perspective; Figure 12: the piston (a) seen in perspective from above, (b) seen in perspective from below and (c) seen in section.

For the sake of clarity of the description, spatial references such as "lower" and "upper" or "inside the vial" and "outside the vial" are used. It should be noted that the valve is manufactured and sold independently of the bottle and that the protection relates in particular to the valve alone, without bottle. Therefore, these references are made with respect to the valve as intended to be used assembled on a vial whose valve is placed above the vial. This does not prevent the valve from being used in the inverted position, i.e. with the valve under the vial, or in any other position.

The valve (1) is intended to be fixed on a rigid bottle, not shown, by means of fastening means such as a cup (2). An outer seal (21) is placed between the neck of the vial and the cup (2) to seal. In a conventional manner, the valve (1) is fixed on the dome (22) of the cup (2).

The valve (1) consists essentially of: - a valve body (9) fixed to the dome (22) of the cup (2); A valve, generally called stem (4), located in the valve body (9) in which it can move axially between a closed position and at least a first open position; - a spacer (3); - two internal seals (5a, 5b); A dosing chamber (7).

The valve generally comprises an inner bag (11) for separating the product from the propellant.

The valve body (9) consists of an upper portion (91) having the shape of a cylindrical ring which is intended to be fixed in the dome (22) of the cup (2). An inner valve seal (5a) is placed between the end face of this upper portion (91) and the bottom of the dome (22) to provide sealing. This seal is improved thanks to the frustoconical shape of the front face of this upper part (91).

~ o This upper ring (91) of the valve body (9) is extended by a substantially cylindrical main portion (92).

The main part (92) is traversed right through by an axial channel (95). This channel is divided into an upper section and a lower section separated by an inwardly directed radial flange (98) provided with a central opening. The upper section is provided with two sets of radial ribs directed towards the center of the axial channel (95). The first set of ribs (96), of lower radial length, on the one hand, forms, in its upper part, a stop for a second internal seal, said chamber seal (5b) described below, and on the other hand a guiding for the sliding of the stem (4). The second set of ribs (97) further forms a stop for a shoulder of the stem (4). The product can circulate between the ribs.

Two radial orifices (99) are formed in the wall of the main element (92), above the flange (98) formed inside the valve body. This flange (98) continues with a funnel portion (981) narrowing downwardly. The inner diameter of the narrow portion of the funnel corresponds to the outer diameter of the stud (44) of the stem (4).

The outer face of the valve body (9) has two radial fins (93). These fins have, in the radial plane of the valve body, a V-shaped section, the wings of the V resting more or less tangentially on the cylindrical portion of the main element (92). These two fins (93) are arranged opposite to each other and are hollow. A side channel (931) is thus formed inside each fin (93) open in its lower part (opposite to the upper crown) and closed on the top. Each channel (931) is provided in its upper part with an orifice (94) which opens into the upper section of the axial channel (95) slightly below the upper ring (91), but above the seat for the internal chamber seal (5b). The orifices (94) thus make contact with each channel (931) located inside the fins and the space located inside the upper ring (91).

The flexible bag (11) is fixed, for example by welding, on the outer face of the main part (92). The pocket (11) is closed on all sides and can communicate with the outside only through the valve. With this pocket, it is possible to separate the product to diffuse propellant gas located outside thereof. However, it would be quite possible to give up this pocket.

The stem (4) has an essentially cylindrical outer shape and has a first cylindrical wall (41) forming an upper central channel (42) and a second cylindrical wall (44) forming a lower central channel (442). The two central channels (42, 442) are isolated from each other by a barrier (43). The second cylindrical wall forms a cylindrical post (44). The upper part of the outer face of the pin, that is to say the side of the barrier (43), has a circular shoulder (441).

A first set of two radial holes (45) is made in the first wall (41) of the stem (4), near the lower end of the central channel (42). These first radial holes (45) thus bring into contact the interior of the central channel (42) and the outer face of the stem (4). Similarly, the second cylindrical wall forming the tenon (44) is open in its lower part by an axial hole and in its upper part, near the barrier (43), by a second set of two radial holes (443).

The stem (4) is further provided with a third cylindrical wall (46) concentric with the first (41) surrounding it so as to form an annular channel (47) concentric with the upper central channel (42). This annular channel (47) is open upwards by an axial opening and closed downwards, and its length is such that the first radial holes (45) do not pass through. A third set of two radial holes (48) passes through the third cylindrical wall (46) so as to contact the interior of the annular channel (47) and the outside of the stem (4).

The stem (4) is provided with more than two circular stops (49a, 49b) located on its periphery. The outer diameter of the first stop (49a) substantially corresponds to the diameter of the cylinder formed by the inner ends of the first portion of the ribs (96) of the axial channel (95) of the valve body (9). The outer diameter of the second stop (49b) substantially corresponds to the inner diameter of the spacer (3).

In the mounted state, the stem is in the valve body within the axial channel (95) in which it can move. The movement of the stem is limited between two extreme positions, the high or closed position and the low position or shorting position. Downwards, that is to say in the short-circuiting position, the movement is limited by the first stop (49a) which bears on the upper part of the second set of ribs (97) while upwards , that is to say in the closed position, the movement is limited by the second stop (49b) which abuts against the internal valve seal (5a) located in the dome (22) of the cup ( 2). In this position, the movement is also limited by the first stop (49a) which bears on the internal chamber seal (5b).

The spacer (3) is formed by a hollow cylinder provided in its upper part with radial ribs (31) directed outwards.

A metering chamber (7) is fixed by suitable means on the valve body (9), preferably at the lower section. The metering chamber consists essentially of a cover (71) and a bottom (72) within which a piston (73) slides. This piston is subjected to the pressure of a spring (74) (which only the end turns are shown) which tends, in the absence of other effort, to push against the cover (71).

The lid (71) of the metering chamber consists essentially of a radial wall (711) provided with a central opening (712) and two cylindrical walls (713, 714). The first cylindrical wall (713) extends down the radial wall (713). The second cylindrical wall (714), concentric with the first, extends upwardly around the central opening (712) of the radial wall (711). In the mounted state, the upper end of the second cylindrical wall (714) abuts against the underside of the funnel portion (981) of the valve body, preferably by interposing an O-ring (717) or any other suitable sealing means. A third cylindrical wall (715) concentric with the first two and surrounding the second is provided to receive the means for fixing the chamber (7) on the valve, preferably on the lower end of the valve body. In the example presented here, the fastening means consist on the one hand of two radial tenons in an arc of circle placed on the outer face of the valve body (9), at its lower end, and two radial shoulders (718 ) directed towards the center and placed at the upper end of the inner face of the third cylindrical wall (715). In the mounted state, the two pins of the valve body snap behind the two shoulders (718) of the third radial wall of the metering chamber cover. The seal is reinforced by the presence of the O-ring (717).

The bottom (72) of the metering chamber is constituted by a cylindrical wall (721) closed at the bottom by a radial wall (723). The inside diameter of the cylindrical wall ~ o (721) of the bottom (72) corresponds substantially to the outside diameter of the first cylindrical wall (713) of the cover (71). These two elements of the metering chamber can be connected together by any appropriate means. In the example presented here, they are connected by means of four quadrants (723) regularly distributed on the periphery of the cylindrical wall (721) of the bottom (72) and as many shoulders (716). ) 15 made in the first cylindrical wall (713) of the cover (71) and behind which the tenons (723) are snapped. It goes without saying that it is also possible for the lower radial wall of the metering chamber to be separate from the rest of the metering chamber.

The piston (73) consists essentially of a solid radial wall (731) (thus without passage opening unlike the valve EP 1 099 647 A1), fixed on a cylindrical ring (732), the spring (74) penetrating inside this cylindrical ring to bear on the underside of the radial wall, or in the case presented here, on radial ribs (733) shorter than the cylindrical ring (732) and extending from the radial wall. A shoulder (734) formed on the outer face of the cylindrical ring (732) seals between the piston (73) and the inner face of the cylindrical wall (721) of the bottom (72) of the metering chamber. The air contained inside the bottom (72) below the piston (73) is compressed when the chamber fills. The annular valve seal (5a) is located in the bottom of the dome, between the latter and the top face of the valve body.

The chamber seal (5b) is placed inside the axial channel (95) of the valve body, bearing against the upper face of the ribs of the first set (96). It is held in this position by the spacer (3). The chamber seal (5b) has an annular shape. Its outside diameter corresponds to the inside diameter of the axial channel (95) above the first set of ribs (96). Its inside diameter corresponds to the outer diameter of the stem (4) at the first radial holes (45) and the second radial holes (443). On its inner face, the chamber seal (5b) has two parallel radial grooves (51b, 52b) located one above the other. The height of the lower groove (51b) is greater than or equal to the axial distance between the first radial holes (45) and the second radial holes (443) of the stem. In practice, it would be possible to give up the second radial groove (52b) which plays no role. Its presence is justified only for reasons of simplification of the assembly of the valve: the part being symmetrical ~ ~ relative to the radial median plane, it can be mounted in one direction or the other in the valve body .

In the mounted condition of the valve, the dosing chamber (7) fixed on the lower section of the valve body (9) is found from bottom to top. The stem (4) is located inside the valve body (9), pushed upwards by a spring (8) which is supported on one side on the shoulder (441) of the stem (4). and the other on the upper face of the flange (98). The chamber seal (5b) is locked inside the axial channel (95) between the top of the ribs of the first set (96) and the spacer (3) which is itself placed in the upper part of the channel axial (95). Finally, the upper ring (91) of the valve body is secured to the cup (2) for example by crimping by interposing the valve seal (5a) which surrounds the upper section of the stem (4). This seal ensures in particular the seal between the area below it and the area above it.

In order to allow the product contained in the bag (11) or in the bottle to penetrate into the metering chamber, and then to emerge from it, an inlet passage and an outlet passage are provided in the valve. input obstruction and output obstruction means being provided respectively in the input path and in the output path to obstruct these passages when necessary. When the respective obstructing means are open, the inlet passage contacts the inside of the bag, or the inside of the bottle if there is no bag, and the dosing chamber, while the outlet passage contacts the interior of the metering chamber and the upper central channel (42) of the stem.

The inlet passage is constituted by the inlet ports (99) made in the valve body, the orifice formed by the funnel portion (981) of the flange (98) of the valve body and the second wall cylindrical (714) then the orifice (712) of the lid (71) of the metering chamber. The entry passage is clearly visible for example in Figure 3b, where it is indicated by an arrow. The means of obstruction of this inlet passage are constituted by the lower end tenon of the second cylindrical wall (44) of the stem which, when the stem (4) is sufficiently lowered, closes sealingly the opening the funnel portion (981) of the valve body and the O-ring (717). The obstruction of the inlet passage by the inlet obstruction means is clearly visible in Figures 4b and 5b.

The outlet passage is constituted by the second cylindrical wall (714), the lower central channel (442) of the stem, the second set of radial holes (443), the first annular groove (51b) of the chamber seal (5b). ), the first set of radial holes (45) and the upper central channel (42). The exit passage is clearly visible in Figure 4b where it is marked by an arrow. The means of obstruction of this outlet passage are constituted by the inner face of the cylindrical wall of the chamber seal (5b) which, as soon as the two sets of radial holes (45, 443) are no longer aligned with the first annular groove (51b), provides a sealed barrier between these two sets of holes, thereby obstructing the outlet passage. The obstruction of the outlet passage is clearly visible in FIGS. 3b and 5b.

When the valve is in the closed position, the radial holes (48) of the third cylindrical wall (46) of the stem are located above the valve seal (5a), i.e. the valve. The radial holes (45) located at the bottom of the upper central channel (42) are in front of the top groove (52b) of the chamber seal (5b) (or against the wall of the chamber seal which obstructs them if there is no second annular groove) while the second radial holes (443) are opposite the lower groove (51b). The two sets of radial holes are thus isolated from each other and there is therefore no communication between the lower central channel (442) and the upper central channel (42) of the stem (4). The pin (44) of the stem penetrates into the orifice of the flange (98) but does not come into contact with the bottom of the funnel portion (981) and with the O-ring (717). The passage between the inside of the pocket (11) and the metering chamber is thus cleared. This passage is made through the radial holes (99), said inlet ports, then the space between the funnel portion (981) of the flange (98) and the lower end of the post (44) and the central orifice (712) of the metering chamber cover.

In this position, the product placed inside the pocket and compressed for example to about 8 bar by the gas located outside thereof enters through the orifices (99) in the axial channel (95), passes through the funnel portion (981) bypassing the end of the pin (44) and passes through the central opening (712) of the metering chamber lid (71) by pushing the piston (73) against the effect spring (74). On the side of the valve body, the product rises in the lower axial channel (442) of the stem and fills the lower section of the valve body. However, it is blocked in the valve body by the chamber seal (5b) and at the stem inside the lower groove (51b) of the chamber seal. The product can not leave the valve, but the dosing chamber is filled.

~ o When the valve is actuated, that is to say that a pressure is exerted on the summit part of the stem, it moves downwards. To empty the dosing chamber, it is planned to lower the stem in an intermediate position between the high position, closing, and the low position, short-circuiting.

In this intermediate position, the stem is lowered so that the radial holes (48) of the third cylindrical wall of the stem are again above the valve seal (5a). The radial holes (45) located in the bottom of the upper central channel (42) of the stem, just like the radial holes (443) located at the top of the lower central channel (442), face the lower annular groove ( 51 b): they are therefore in communication. The lower end of the pin (44) now penetrates into the funnel portion (981) of the collar and thus seals the central orifice of the collar.

In this position, the product can no longer pass from the bag (or vial) into the metering chamber since the inlet passage between the radial inlet holes (99) and the metering chamber is obstructed by the closure. hermetic center hole of the collar by the pin (44). By against the metering chamber being in contact with the outside, the pressure drops and the spring (74) pushes the piston (73) to the top of the metering chamber. The product is thus expelled. It first passes through the outlet opening (712) and the channel formed in the second cylindrical wall (714) of the cover (71), back into the lower channel (442) of the post (44), through the holes (443) of the tenon, circulates in the lower groove (51b) of the chamber seal (5b), through the holes (45) located at the bottom of the upper central channel (42) of the stem, up the latter and is found out of the valve. Only the amount of product placed in the metering chamber can be expelled in this way. At most, at the first use, it lacks the amount of product needed to fill the dead volume formed by the path located in the lower central channel (442) and the upper central channel (42). In the following uses, this dead volume being already filled with product, the volume expelled corresponds exactly to the volume of the metering chamber (7).

When the pressure exerted on the valve is released, the spring (8) pushes the stem (4) upwards, which returns to its initial position and the metering chamber fills up again.

It should be noted that whatever the position of the stem, the product contained in the ~ o pocket can penetrate into the side channels (933) of the fins (93) of the valve body and through their orifices (94) to enter the space between the valve seal (5a) and the chamber seal (5b). However, this space is hermetically sealed and the product contained therein can not leave it.

In some cases, it may be useful to short-circuit the metering chamber (7), for example to take a much larger dose of product. In this case, it is possible to exert an even greater pressure on the summit face of the stem to force it to descend to the extreme low position, beyond the intermediate position mentioned above. In this case, the radial holes (48) of the third cylindrical wall (46) of the stem pass below the valve seal (5a): they are thus open. The radial holes (45) face the lower groove (51b) of the chamber seal, while the radial holes (442) are at the first and second sets of ribs (96, 97). The upper central channel (42) and the lower central channel (442) are thus again isolated from each other. The post (44) further penetrates into the funnel portion of the flange (98) maintaining the airtight closure of the center hole of the flange.

In this extreme position, the inlet and outlet passages are obstructed and the dosing chamber is not only isolated from the pocket (11), but is also isolated from the outside: it can not be filled or empty. On the other hand, the product contained in the bag (or in the bottle) escapes through the valve via the lateral channels of the fins. It is pressed into the side channels (931) of the fins (93), passes through the orifices (94) contacting the top of the channels (931) and the inside of the upper ring (91), enters the crown, passes between the ribs (31) of the spacer 35 (3), through the holes (48) made in the third cylindrical wall (46) of the stem and out through the annular channel (47).

It should be noted that in the extreme low position of short-circuiting of the dosing chamber, it is also possible to fill the bag during the manufacture of the pressurized bottle.

If the short-circuiting position is not necessary, it is possible to give up the third cylindrical wall (46) of the stem as well as the lateral channels (931) of the valve body, even if the fins can be kept for facilitate the welding of the pocket (11). The stem no longer moves while between the upper closing position and the ~ o intermediate opening position, which then becomes the second extreme position.

The pocket is not necessary either. We can consider taking the product directly into the bottle. As such, the valve can be used upside down (valve placed below the bottle). If, on the other hand, it is necessary to use it in the normal position (valve above the bottle), it will be necessary to provide a dip tube connected to the radial openings (99) of the lower section of the valve body.

In the exemplary embodiment presented here, the radial holes (45, 443, 48, 99) are present in pairs. It would be quite possible to have one each time, or on the contrary more than two.

The metering valve of the invention, in particular associated with a pocket (11) can be used in all positions. The presence of the spring (74) constraining the piston (73) ensures a rapid and complete exit of the product from the metering chamber. The fact that the metering chamber fills at the top, by the path taken by the product to exit, it is not likely to empty between two uses, even when the use of a pocket is abandoned .

List of references:

1 dosing valve 11 soft pocket

2 Cup 21 Outer seal 22 Dome 30 35 17 3 Spacer 31 Radial ribs facing outwards 4 Stem 41 First cylindrical wall 42 Upper central channel 43 Barrier 44 Second cylindrical wall / post 441 Circular shoulder 442 Lower central channel 443 Second set of holes radial 45 First set of radial holes 46 Third cylindrical wall 47 Annular channel 48 Third set of radial holes 49a First stop 49b Second stop 5 a) Valve seal b) Chamber seal 51 b Lower ring groove 52b Upper ring groove 7 Dosing chamber 71 Cover First cylindrical wall Second cylindrical wall Third cylindrical wall Bottom mounting shoulders O-ring Mounting shoulders on the valve body 35 72 711 712 713 714 715 716 717 718 Bottom 721 Cylinder wall Radial wall Center hole

Claims (14)

REVENDICATIONS1. Dosing valve (1) for a pressurized bottle, comprising a valve body (9) in which a valve (4) can slide, a metering chamber (7) and means for moving the valve (4) between a closed position wherein, when mounted on a vial, the metering chamber (7) is in contact with the interior of the vial and isolated from the outside of the vial, and an open position in which, in the assembled state, the metering chamber (7) is isolated from the inside of the bottle and in contact with the outside of the o-bottle, characterized in that the metering chamber (7) is fixed at its upper end to the part of the body of the valve (9), in the mounted state, inside the vial, an inlet passage (99, 981, 714, 712) being provided which contacts the inside of the vial and the dosing chamber and a outlet passage (712, 714, 442, 443, 51b, 45, 42) bringing the dosing chamber into contact with the outside of the valve, means 15 for obstructio an inlet is provided for obstructing the inlet passage when the valve (4) is in the open position and outlet obstruction means being provided for obstructing the outlet passage when the valve (4) is in the closed position. 2. Dosing valve (1) according to the preceding claim, characterized in that the valve can be moved beyond the open position in a third position called short-circuited position, a third passage (931, 94, 31, 48, 47), said short-circuit passage, being designed to bring the inside of the bottle into contact with the outside of the valve, preferably without passing through the dosing chamber, short-circuit obstruction means (5a) being provided to obstruct the short-circuiting passage 25 when the valve (4) is in the closed position or in the open position, the inlet obstruction means and / or the outlet obstruction means being preferably in the closed position when the valve is in the short-circuited position if the short-circuit passage does not pass through at least a portion of the inlet passage and / or the output passage. 30 3. Dosing valve (1) according to one of the preceding claims, characterized in that the inlet obstruction means and the outlet obstruction means are independent of each other. 35 4. Dosing valve (1) according to one of the preceding claims, characterized in that the inlet passage is constituted by at least one hole made in the wall of the valve body, in a zone in contact with the interior of the bottle or pocket (11), an orifice formed in a wall (98) located inside the valve body (9) and an orifice (712) made in the dosing chamber (7) and in that the inlet obstruction means are constituted by the lower end of the valve having the shape of a cylindrical post (44) and whose radial section corresponds to the internal dimensions of the orifice of the wall (98) so that when the tenon enters this orifice, it closes it hermetically, the wall (98) preferably having the shape of a funnel-shaped collar (98) directed towards the metering chamber (981) ( 7). 5. Dosing valve (1) according to the preceding claim, characterized in that sealing means, preferably an O-ring (717), are placed below the orifice formed in the wall (98). 6. Dosing valve (1) according to one of the preceding claims, characterized in that the outlet passage is constituted by an orifice (712) formed in the metering chamber (7), an orifice made in a wall (98). ) located inside the valve body (9), a lower central channel (442) and an upper central channel (42) formed in the valve (4) and separated from each other by a barrier (43). ), at least one orifice (45) being formed in the wall of the valve bringing the inside of the upper central channel (42) into contact with the outside of the valve and at least one orifice (443) being made in the wall of the the valve (4) bringing the interior of the lower central channel (442) into contact with the outside of the valve (4), a contacting passage (51b) being provided for bringing the orifice (s) into contact ( 443) with the orifices (45), and in that the outlet obstruction means are constituted by a chamber seal ( 5b) constituted by an annular wall inside which the valve can slide, the inner face of the chamber seal (5b) having at least one annular groove (51b) whose height is at least equal to the vertical distance separating the or the orifices (45) made in the upper central channel (42) and the orifices (443) made in the lower central channel (442), the orifices (45) of the upper central channel and / or the one or more orifices (443) of the lower central channel being obstructed by the inner face of the annular wall when the valve is in the closed position, thereby obstructing the outlet passage, and the orifices (45) of the upper central channel and the orifices (443) of the lower central channel opening on the annular groove (51b) when the valve is in the open position, thus releasing the outlet passage. 7. dosing valve (1) according to one of the preceding claims, characterized in that the metering chamber comprises a cylinder (721) whose end opposite the valve body, said lower, is closed by a radial wall ( 722), said lower, and the end facing the valve body, said upper, is closed by a radial wall (711), said upper, a piston (73) slidable within the cylinder (721) between these two radial walls by defining a dosing volume. 8. Dosing valve (1) according to the preceding claim, characterized in that the upper radial wall (711) of the metering chamber is provided with an opening (712), the piston being slidable between the two radial walls (722). , 711) of the cylinder, a spring (74) being provided between the lower radial wall (722) of the metering chamber and the piston (73) to push the latter, in the absence of other constraints, against the radial wall upper (711) provided with the opening. 9. dosing valve (1) according to claim 7 or 8, characterized in that the cylinder (721) forming the dosing chamber on the one hand and its upper radial wall (711) and / or its lower radial wall ( 722) on the other hand constitute different parts that can be assembled or separated from each other, means (716, 723) being provided for fixing said wall on the cylinder (721). 10. Dosing valve (1) according to one of the preceding claims, characterized in that a flexible bag (11) is welded to the valve body (9) enclosing the metering chamber (7) and the beginning input, output and, where appropriate, short-circuit paths. 11. Dosing valve (1) according to one of the preceding claims, characterized in that the valve (4) consists of a first cylindrical wall (41), said upper, forming a first axial channel (42), said upper, and a second cylindrical wall (44) forming a second axial channel (442), the two axial channels being isolated from each other by a barrier (43), the upper channel (42) being open to its upper end by an axial opening and the side of the barrier (43) by at least one radial opening (45) opening on the outer face of the valve, the lower channel (442) being open at its lower end by an axial opening and on the side of the barrier (43) by at least one radial opening (443) opening on the outer face of the valve, the valve being preferably provided with at least one annular stop (49a, 49b) on its circumference to limit its moving inside the body of valve (9) towards the outside or the inside. 12. Dosing valve (1) according to the preceding claim, characterized in that the valve (4) is provided with a third cylindrical wall (46) partially surrounding at least the first cylindrical wall (41) and concentric to that- ci by forming an annular channel (47), which annular channel (47) is isolated from the other two and provided with an axial opening at its end said upper and at least one radial hole (48) bringing into contact the inside the annular channel (47) and the outside of the valve, in that the valve body (9) and the valve (4) are sized so that the valve (4) can be moved beyond the position open in a so-called short-circuited position, and in that the valve body (9) is provided with a valve seal (5a) located opposite the dosing chamber and positioned so that the mounted state of the valve, the radial hole or holes (48) of the annular channel (47) are, in the closed position of the valve, at 15 l outside the bottle, in the open position of the valve, the radial hole or holes (48) of the annular channel are located opposite the valve seal (5a), obstructed by the latter, or outside the bottle, and in the short-circuited position of the valve the radial hole or holes (48) of the annular channel (47) are located on the side of the valve seal (5a) opposite the outer side. 20 Metering valve (1) according to Claim 11 or 12, characterized in that the valve body (9) is provided with a chamber seal (5b) arranged in the valve body (9) so that closed position of the valve, the radial hole (s) of the upper channel (42) of the valve are located at the chamber seal (5b), obstructed by the latter, the annular abutment (49a) sealingly abutting against this chamber seal (5b). 14. Dosing valve (1) according to one of claims 2 or following, characterized in that at least one side channel (931) is provided on the outer face of the valve body (9), said side channel (931 ) being provided with a first opening 30 opening, in the mounted state, inside the bottle or the bag (11), and a second opening (94) opening inside the valve body between the valve seal (5a) and the chamber seal (5b).