FR2562444A1 - Device for manual dispensing of a liquid product - Google Patents

Abstract

A manual dispensing device intended to deliver a dose of liquid equivalent to a determined number of drops. The device comprises a mobile shutting member 4 intended to close off an entry conduit 3, a dispensing chamber 3 whose volume can be varied as a function of the dose to be delivered and members 10, 11, for adjusting the quantity of liquid to be delivered. The dispensing chamber communicates alternately with the inside and the outside of the flask. The device can be employed for dispensing liquids, especially medications.

Description

MANUAL DOSING DEVICE FOR A LIQUID PRODUCT
The present invention relates to a manual dosing device for a liquid product contained in a bottle, for delivering a dose equivalent to a given number of drops.

In order to dispense small quantities of a liquid, in particular a pharmaceutical product or a dye, various devices are currently available with which the volume of the dose is generally quantified in number of drops.

The usual droppers, being in the form of a pipette or a spout, allow to properly dose the product by the drop count. On the other hand, they are particularly inconvenient for the distribution of doses reaching several tens of drops. The user must demonstrate a concentration and a manual skill that may be lacking to people who are sick or elderly. Dosing errors are frequent and can not be controlled. In addition, various muffler incidents may occur with these devices, including breakage of a glass pipette, obstruction of small diameter channels due to product drying, overturning of an open bottle, etc.

It has been sought to obtain greater operational safety by producing a device in which a push button actuates a piston pump that draws the product into the bottle and dzlivre by a spout, or in the form of drops if the button is pressed small & BR <small, either in the form of a single dose corresponding to the maximum stroke of the piston. However, if this device actually avoids various disadvantages of traditional devices, it is relatively complex and expensive since it includes ten different parts. If it were to be further adapted to the delivery of adjustable doses, it would become even more complex.

The object of the present invention is therefore to overcome the aforementioned drawbacks of the prior art by establishing a manual dosing device which is adaptable to a small conventional bottle, which allows to safely deliver a determined dose of a liquid content in this bottle and which is sufficiently simple and inexpensive to be able, if necessary, to be provided with the liquid bottle in the form of Jeter doser.

The invention also aims to provide an adjustable device for delivering at once a dose whose volume can vary between one and several tens of drops.

For this purpose, the device according to the present invention is characterized in that it comprises a metering chamber whose volume is predetermined, a body and a closure member which is movable relative to this body, the corpus and the closure member comprising, with respect to each other, a first position in which the metering chamber is in communication with the inside of the bottle via an inlet duct of sufficient cross-section to allow gravity to flow by gravity between the bottle and the metering chamber and at least a second position in which the metering chamber is in communication with the outside and wherein the inlet duct is closed by the closure member.

Preferably, the device is provided with volume control members of the dose to be delivered, comprising a graduation representative of the volume of the dose and an index cooperating with this graduation.

According to a first advantageous embodiment, the closure member is substantially cylindrical in shape, rotatable about a longitudinal axis whose direction is substantially perpendicular to that of the inlet duct, while the metering chamber is located inside a lateral recess formed in the closure member. Preferably, this lateral recess is of cylindrical shape, with an axis perpendicular to the axis of the closure member, and the volume adjustment members of the metering chamber comprise an adjustment piston housed in this lateral recess of The adjusting members further comprise a threaded rod integral with this piston, engaged in a threaded bore of the closure member and provided with an index, and a tongue bearing a graduation, secured to the closure member and arranged parallel to the threaded rod. The piston advantageously comprises a concave surface on the side of the metering chamber in order to avoid the presence of blind spots in this chamber.

According to another advantageous embodiment, the device comprises a / a body which encloses a metering chamber of substantially cylindrical shape, and a discharge duct connecting the metering head to the outside, bI a closure member comprising a discharge piston disposed in the body so as to slide axially in the metering chamber, and an operating piston integral with the discharge piston, and c / a return spring disposed between the body and the closure member so as to to urge them towards their first position, the closure member being arranged to alternately close the inlet duct by means of the discharge piston and the ejection duct by means of the closing piston.

This embodiment can be in various aspects depending on whether the device is mounted on the bottle by the body or by the closure member. In one aspect, the body is attached to the vial, and the inlet conduit opens onto the side surface of the metering chamber. In another aspect, the closure member is fixed on the bottle, and the inlet conduit opens on one end of the metering chamber.

For the adjustment of the volume of the dose to be delivered, the closure member may comprise several parallel grooves arranged axially, the various lengths of which correspond to various doses, while the body comprises a pin arranged to engage in one any of these grooves and to limit the stroke of the discharge piston as a function of the length of the groove. The closure member is then provided with a graduation representative of the respective doses corresponding to the various lengths of the grooves, said nipple bearing the index which cooperates with this graduation.

According to another form of the volume adjustment members of the dose, the body may comprise a series of tongues arranged axially and having various lengths, while the closure member comprises baffles which cooperate with the ends of these tongues to limit the stroke of the discharge piston, and with the sides of these tongues to guide the shutter member.

With such adjustment devices, the maximum dose can be a multiple of the minimum dose, this multiple being for example equal to or greater than five.

The present invention will be better understood with reference to the description given below of a preferred embodiment and to the appended drawing, in which:
Fig. 1 is a sectional view of a first embodiment of a device according to the invention, the closure member being in its first position,
Fig. 2 is a view similar to FIG. 1, the shutter member being in its second position,
Fig. 3 is a longitudinal sectional view of another embodiment of the device according to the invention, the closure member being in its first position,
Fig. 4 is a view similar to FIG. 3, the shutter member being in its second position,
Fig. 5 is an axial sectional view of another embodiment of the device according to the invention,
Fig. 6 is an axial sectional view of another embodiment of the device according to the invention,
Fig. 7 is a cross-sectional view along the line VII-VII of FIG. 6, and
FIG. 8 is a view of the end of the closure member of FIG. 6.

The metering device shown in Figures 1 and 2 comprises a body 1 which is integral with a bottle 2 containing the liquid to be delivered. In its central part, the body 1 is traversed by an inlet duct 3 which opens towards the inside of the flask. A closure member 4, having the general shape of a cylinder whose axis is substantially perpendicular to the direction of the inlet duct 3, is housed in a correspondingly shaped cavity of the body 1. This cylindrical cavity has a depth slightly greater than its radius, so that the closure member 4 is retained within this cavity while being pivotable about its longitudinal axis.

Each end of the closure member 4 is supported by a side wall 5 of the body 1.

The body 1 and the shutter member 4 are both made of synthetic material having a certain elasticity, so that the shutter member can be placed on the body by forcing it into the interior of the cavity and that it then closes the inlet duct 3 in a sealed manner.

The shutter member 4 comprises a lateral recess 6 of cylindrical shape, whose axis is perpendicular to that of the shutter member. At the bottom of this lateral recess, the closure member 4 is pierced with a threaded bore 7. A cylindrical piston 10 secured to a threaded rod 11 is mounted so as to be able to slide axially in the lateral recess 6. For this purpose, the rod 11 is engaged through the threaded bore 7 of the closure member S so that when the rod 11 is rotated, the piston 10 moves axially in said recess. On the opposite side to the threaded rod 11, the piston 10 has a front surface 12 which delimits, in the lateral recess 6, a metering chamber 13 whose volume varies when the piston 10 is displaced. The latter thus constitutes a movable wall of the dosing chamber.

In order to identify the position of the piston, that is to say the volume of the metering chamber 13, the closure member 4 comprises a tongue 15 which is arranged parallel to the threaded rod and on which is marked A graduation 16. Next to this graduation, the rod 11 comprises an index 17 made here in the form of a peripheral groove. Moreover, the head 18 of this rod is knurled to allow the user to rotate it easily.

Fig. 1 illustrates a first position of the closure member, wherein the metering chamber 13 is in communication with the interior of the bottle 2 through the inlet conduit 3. In this position, the metering chamber 13 communicates not with the outside of the bottle, thanks to the sealed contact between the closure member 4 and the body 1. This first position is determined by a stop 19 which protrudes on the peripheral surface of the closure member 4 and which abuts against the body 1 so as to limit the rotation of the closure member.

Fig. 2 illustrates a second position of the closure member 4 in which the metering chamber 13 is in communication with the outside of the bottle, while the closure member 4 sealingly closes the inlet duct 3 When the metering chamber 13 occupies this position, it is in front of a spout 20 incorporated in the body 1 so as to direct the flow of the liquid.

This second position is determined by a notch 21 which is formed in the body 1 as shown in FIG. 1, and in which the stem 11 abuts.

The operation of the device is clear from Figures 1 and 2.

The volume of the dose to be delivered is adjusted by rotating the rod 11 until the index 17 is next to the mark of the graduation 16 corresponding to the dose to be delivered. In doing so, the volume of the metering chamber 13 is in fact adjusted. It should be noted that, if the user takes the same dose of liquid each time, he does not have to repeat this adjustment operation.

The shutter member being placed in the first position illustrated in FIG. 1, the vial 2 is sufficiently inclined so that the metering chamber 13 fills with liquid and the air that it still contains escapes through the inlet duct 3 towards the inside of the vial 2. Without straightening the vial, the closure member 4 is pivoted, for example by pushing the tongue 15 until it is in its second position illustrated in FIG. 2. The liquid contained in the metering chamber 13 then escapes outwards by flowing on the spout 20. The complete evacuation of the liquid is facilitated by the concave shape of the front surface 12 of the piston, which prevents that drops remain suspended at the bottom of the chamber. The bottle can then be straightened and the shutter member placed in its first position.

So that the dose corresponds exactly to the volume of the metering chamber 13, it is important that at no time this room is in communication at the same time with the inside of the bottle and with the outside. For this purpose, the distance separating the points 22 and 23 of the cylindrical cavity of the body 1 must be greater than the diameter of the metering chamber 13. Thus, in any position, the device insulates the inside of the vial 2 with respect to the outside and thus also fulfills the function of a cap of the vial.

In this embodiment, the device may advantageously be made of three molded plastic parts, namely the body 1, the shutter member 4 integrally molded with the tongue 15, and finally the piston 10 and the rod 11 grouped in one piece.

This last piece is mounted in the closure member 4 by screwing it into the threaded bore 7, then the assembly is fitted into the body 1. Thanks to this very simple and inexpensive construction, the device can be designed as a disposable dispenser, for example delivered with a bottle of pharmaceutical product. The manufacturer can then adapt to this product the range of doses that the device can deliver, which avoids many dosing errors.

Figures 3 and 4 illustrate another embodiment of the manual dosing device according to the invention. A body 31, integral with a bottle 32, comprises a cylindrical cavity in which a closure member 34 is slidably mounted. This closure member comprises a discharge piston 35 and a closure piston 36, these two pistons being arranged coaxially and made integral by an axial rod 37. The discharge piston 35 delimits, inside the body 31, a metering chamber 38 whose volume is variable according to the position of the closure member 34. Inside the body 31, an inlet conduit 33 connects the metering chamber inside the bottle 32. Depending on its position, the discharge piston 35 can sealingly close the outlet of the inlet duct 33 in the metering chamber.

On the other hand, the body 31 comprises an excretory duct 40 connecting the metering chamber 38 with the outside. In fact, this conduit does not open directly into the metering chamber 38, but into a cylindrical cavity 41 which is adjacent to it and in which slides the shutter piston 36. Thus, according to its position, the shutter piston 36 can sealing the outlet of the ejection duct 40 from the side of the metering chamber. The two pistons 35 and 36 are arranged relative to each other so that in any position of the closure member 34, only one of the two pistons closes the orifice corresponding thereto.

Thus, in a first position shown in FIG. 3, the shutter piston 36 closes the ejection duct 40, while the delivery piston 35 leaves open the inlet duct 33 so that the metering chamber 38 communicates with the interior of the flask 32.

Conversely, in a second position shown in FIG. 4, the delivery piston 35 closes the inlet port 33, while the shutter piston 36 leaves open the ejection duct 40, so that the metering chamber 38 is in communication with the outside by this leads.

A helical spring 44 disposed in the metering chamber around the axial rod 37 tends to return the closure member 34 to its first position.

 Due to this construction, the volume of the metering chamber 38 varies when sliding the closure member 34 in the body 31. It is then possible to obtain an adjustment of the volume of the dose by adjusting the length of the stroke shutter member inside the body.

For this purpose, the closure member 34 comprises, at its end opposite the metering chamber, a cylindrical sleeve 45 which slides freely around the body 31 during the movements of the closure member. The inner face of this sleeve comprises a series of parallel grooves arranged axially, which all have the same section but different lengths from the edge 46 of the sleeve.

FIGS. 3 and 4 represent, for example, a groove 47 of short length and a groove 48 of maximum length equal to that of the sleeve 45. The body 31 has on its outer surface a pin 50 which engages in any one of these grooves. When the closure member 34 is in its first position, the stud 50 is outside the sleeve 45. When the shutter member is displaced axially, that of the grooves which is opposite the stud 50 engages on this nipple, which then plays the role of a stop when it stops against the bottom of the groove. The stroke of the shutter member is limited in this way depending on the length of the groove. Thus, the groove 47 of relatively short length corresponds to a small variation in the volume of the metering chamber 38, so to a small dose. On the contrary, the groove 48 corresponds to the maximum stroke of the closure member, therefore to the maximum dose.

The outer surface of the sleeve 45 has a series of marks which correspond to the grooves and which constitute a graduation. For example, these marks may be constituted by an indication of the number of drops corresponding to the volume of each dose. Using the pin 50 as an index, the user can rotate the closure member 34 about its longitudinal axis to bring in front of the stud 50 the indication of the desired dose, which also places the corresponding groove in front of the nipple. To then deliver the desired dose, the bottle is turned over in the position illustrated in FIG.

3, so that the metering chamber 38 fills with liquid and the air that it still contains escapes to the flask through the inlet duct 33. Then press on the end of the organ shutter 34 to slide it in the body 31 against the effect of the spring 44, which reduces the volume of the metering chamber 38 and delivers to the inside of the bottle, through the inlet conduit 33, a part of the liquid it contains. As soon as the delivery piston 35 has reached the line 52 shown in FIG. 4, it closes the inlet duct 33, and simultaneously the shutter piston 36 leaves open the ejection duct 40. The displacement of the member 34 then causes the ejection of the liquid through the ejection duct 40 until this organ reaches its second position illustrated in FIG.

4. In this position, its stroke is stopped by the stud 50 which abuts against the end of the groove 47. Thus, the dose delivered is a function of the useful stroke L of the closure member 34 and the respective sections of the two pistons 35 and 36.

As soon as the shutter member 3X is released, it automatically returns to its first position under the effect of the spring 44. During this return path, a volume of air equal to the volume of liquid delivered is sucked into the chamber 38, the device is ready to deliver a new dose.

Fig. 5 represents another embodiment of the metering device according to the invention, similar to the previous form as to the operation, but different in its arrangement. Here, the body 61 is movable and it is the closure member 64 which is integral with the bottle 62. As in the previous case, the closure member 64 comprises a discharge piston 65 and a closure piston 66, these two pistons being arranged coaxially and secured by a rod 67. The body 61 comprises a metering chamber 68 of cylindrical shape, in which the discharge piston 65 can engage and an ejection duct 70 in which the The end plunger 71 which is situated on the side of the metering chamber 68 has a section identical to that of the shut-off piston 66, whereas the remainder of this duct has a larger cross-section. , to allow the liquid to bypass the piston. The rod 67 has a lateral recess 67a allowing the passage of the liquid through the end 71 of the ejection duct 70.

The body 61 has an inlet duct 63 of enlarged shape, to allow it to slide on the rear portion 72 of the closure member, the rear portion surrounding the neck of the bottle. The inlet duct 63 communicates with the interior of the flask through openings 73 formed in the closure member.

To deliver a dose of liquid, the operation of the device illustrated in FIG. 5 is identical to that described with reference to FIGS. 3 and 4. The volume adjustment members of the dose also comprise a sleeve 75 secured to the closure member, grooves 77, 78, a solidarity teton 80 body 61, arranged to engage in the grooves and to serve as an index face a graduation doses.

FIG. 5 shows the device in its first position where the metering chamber 68 is in communication with the bottle through the inlet duct 63 and the openings 73, while the end 71 of the ejection duct is closed by the piston When pressed on the body 61 towards the bottle 62, the body moves relative to the closure member and the discharge piston reaches the inlet of the metering chamber, in the position represented by the line 82, thereby closing the inlet duct 63 of this chamber. Simultaneously, from this position, the shutter piston 66 reaches the widened portion of the ejection duct 70, so that the metering chamber is in communication with the outside via the ejection duct 70 and the nozzle. lateral recess 67a of the rod 67.

As in the previous embodiment, the second position of the device is determined by the chosen dose, that is to say by the length of the corresponding groove. When the body 61 is then released, a return spring 74 removes the two parts of the device again.

Figs. 6 to 8 show another embodiment of the device, similar to the previous one in principle. As in the case of fig. 5, the device comprises a body 101 which is movable and a closure member 104 which is integral with the bottle 102. The closure member comprises a delivery piston 105 arranged to close an inlet duct 103 and to slide in a metering chamber 108, and a closure piston 106 arranged to close off an end 111 of an ejection duct 110. These two pistons are integral and are arranged to alternately close the inlet duct 103 and the duct 110. A rod 107 connecting the two pistons comprises a recess 107a which allows a communication between the metering chamber 108 and the ejection duct 110. A heli cotidal spring 114 urges the body 101 and the shutter member 104 towards their first relative position, illustrated in FIG. 6.

To deliver a dose of liquid, the operation of this device is identical to that of the device of FIG. 5. However, the volume adjustment members of the dose conform differently.

The body 101 comprises a series of six tongues 130 to 135 arranged axially and extending towards the inside of the bottle 102.

These tongues have various lengths that correspond to six different doses. The shutter member 104 has a cylindrical rear portion 139 which carries a transverse baffle 136 serving as a stop at the end of the tongue which corresponds to the chosen dose, for example the tongue 133 in the position illustrated by the FIGS. The closure member further comprises three transverse baffles 140, 141 and 142 which are arranged at 120 degrees from each other and which are rigidly connected to the delivery piston 105 by three legs 144. When a dose is selected, the baffles 140 to 142 are each opposite an interval separating two tongues 130 to 135. Thus, during the operation of the device, the tabs 130 to 135 pass by baffles 140 to 142 being guided by these baffles, which prevents any pivoting of the body 101.

The selection of a dose is effected as in the preceding example, using a teton 120 formed on the body 101 and serving as an index face to a graduation formed by relief numerals 121, 122 on the shutter member 104.

This embodiment of the device according to the invention is particularly convenient to use. It can be noted that the device is partially protected at the bottom of the bottle. As a result, the cylindrical portion 139 of the closure member has lateral openings 145 which allow the bottle to be emptied completely.

It can be seen that the construction illustrated in Figures 3 to 8 allows great freedom of choice of the dimensions of the device, including the length of the grooves 47, 48, 77, 78 and tabs 130 to 135 which determine the volume of the dose. Thus, these lengths can be determined so that the maximum dose is equal to a multiple of the minimum dose, this multiple being in practice at least equal to five. For example, the device can be designed to deliver doses of between 10 and 60 drops.

Claims (13)

claims  l. Manual dosing device for a liquid product contained in a bottle, for delivering a dose equal to a given number of drops, characterized in that it comprises a metering chamber (13, 38, 68, 108f whose volume is predetermined , a body (1, 31, 61, 101) and a closure member (4, 34, 64, 104) which is movable relative to this body, the body and the shutter member comprising, one relative to another, a first position in which the metering chamber is in communication with the interior of the bottle by an inlet duct (3, 33, 63, 103) of sufficient section to allow a flow of the liquid by gravity between the bottle and the dosing chamber, and at least a second position in which the metering chamber is in communication with the outside and wherein the inlet duct is closed by the closure member. 2. Device according to claim 1, characterized in that it is provided with adjusting members (10, 11, 46, 50, 77, 80) of the volume of the dose to be delivered. 3. Device according to claim 2, characterized in that the volume adjustment members of the dose to be delivered comprise a graduation representative of the volume of the dose and an index cooperating with this graduation. 4. Device according to claim 1, characterized in that the closure member (4) is substantially cylindrical in shape, rotatable about a longitudinal axis whose direction is substantially perpendicular to that of the inlet duct ( 3), and in that the metering chamber is inside a lateral recess (6) formed in the closure member. 5. Device according to claims 2 and 4 characterized in that said lateral recess (6) is of cylindrical shape, axis perpendicular to the axis of the closure member (4) and that the adjusting members the volume of the metering chamber (13) comprises an adjusting piston (10) housed in this lateral recess, so as to constitute a movable wall of the metering chamber. 6. Device according to claim 5, characterized in that it comprises a threaded rod (11) integral with said piston (10), engaged in a threaded bore (7) of the closure member and provided with an index ( 17), and a tongue (15) carrying a graduation (16), integral with the closure member and arranged parallel to the threaded rod. 7. Device according to claim 5, characterized in that the piston has a concave surface (12) on the side of the metering chamber. 8. Device according to claim 1, characterized in that it comprises a / a body (31, 61, 101) which contains a metering chamber (38, 68, 1u8) of substantially cylindrical shape, and a duct excretion <40 , 70, 110) connecting the metering chamber to the outside, b / an obturating member (34, 64, 104) having a delivery piston (35, 65, 105) arranged to slide axially in the chamber metering piston, and a closing piston (36, 66, 106) integral with the discharge piston, and c / a return spring (44, 74, 114) disposed between the body and the closure member so as to urging them towards their first position, the closure member (34, 64, 104) being arranged to alternately close the inlet duct (33, 63, 103) by means of the discharge piston, and the ejection duct (40, 70, 110) by means of the shutter piston. 9. Device according to claim 8, characterized in that the body (31) is fixed on the bottle, and in that the inlet duct (33) opens on the side surface of the metering chamber (38). 10. Device according to claim 8, characterized in that the sealing member (64, 104) is fixed on the bottle, and in that the inlet duct (63, 103) opens onto an end of the metering chamber (68, 108). 11. Device according to claims 3 and 8, characterized in that the closure member (34, 64) comprises, for adjusting the volume of the dose to be delivered, several parallel grooves (47, 48, 77, 78). arranged axially, the various lengths of which correspond to various doses, and in that the body (31, 61) comprises a stud (50, 80) arranged to engage in any one of these grooves and to limit the stroke of the discharge piston (35, 65) depending on the length of the groove, the closure member being provided with a graduation representative of the respective doses corresponding to the various lengths of the grooves, and said nipple of an index which cooperates with this graduation. 12. Device according to claims 3 and 8, characterized in that the body (101) comprises a series of tongues (130 to 135) arranged axially and having various lengths and in that the shutter member (104) comprises baffles (136; 140 to 142) which cooperate respectively with the ends of these tongues to limit the stroke of the discharge piston (105) and with the sides of these tongues to guide the closure member. 13. Device according to one of claims 11 or 12, characterized in that the maximum dose is equal to at least five times the minimum dose.