FR2956649A1 - FLUID PRODUCT DISPENSING DEVICE AND FLUID PRODUCT DISPENSING DEVICE COMPRISING SUCH ORGAN. - Google Patents

Abstract

Fluid dispensing member (10), comprising a body (11) and manually operated dispensing means (20) movable in said body (11) between a rest position and a dispensing position, said dispensing means (20) ) being biased resiliently towards their rest position by an elastic member (100), said elastic member (100) having a plurality of elastic cells (C) arranged in parallel about a longitudinal axis (X) of said elastic member (100) , forming a level of elasticity (N), and said elastic member (100) comprises a plurality of levels of elasticity (..., N-1, N, N + 1, ...) superimposed along said axis longitudinal (X).

Description

The present invention relates to a fluid dispenser member and a fluid dispenser device comprising such a dispenser member. Fluid dispensing members are well known, in particular for selectively dispensing fluid products, such as liquids or powders, especially in the field of pharmacy, perfumery and cosmetics. These fluid dispensing members may be for example pumps, valves or air flushes. They are generally associated with a reservoir containing the fluid product to form a fluid dispensing device. In a conventional manner, a fluid product dispensing member comprises a body and dispensing means which are moved in said body manually by the user between a rest position and a dispensing position, said displacement permitting the dispensing of the fluid product. An elastic member, such as a spring, is generally used to urge said dispensing means to their rest position, so that the user must exert a force to effect the displacement towards the dispensing position, and when release this effort, said elastic member automatically returns the dispensing means in their rest position. Generally, metal spiral springs are used as return springs. This can present a number of disadvantages. Thus, the metallic material can interact with the fluid product, especially when it is a pharmaceutical product, which can have a detrimental effect on said fluid product to be dispensed. Furthermore, the elastic properties of the spiral springs are not always optimal, which requires having springs of a size large enough to ensure safe and reliable operation of the dispensing member. However, in some applications, it may be desirable to reduce the dimensions of said elastic member. In addition, the spiral springs, which consist of a plurality of turns in series one behind the other, do not exhibit an optimum resistance to stress creep. Similarly, a malfunction on one of the series turns can generate a strong loss of performance of the spiral spring, which can also be a disadvantage especially in devices for dispensing a large number of doses and therefore intended to be operated a large number of times. number of times. The present invention aims to provide a fluid dispenser member and a fluid dispenser device comprising such a member, which do not reproduce the aforementioned drawbacks. In particular, the present invention aims to provide a fluid dispenser member which decreases or eliminates the risk of harmful interaction between the fluid and the constituent parts of said dispensing member. Another object of the present invention is to provide such a fluid dispenser member which makes it possible to achieve optimum elasticity properties with a minimum space requirement. Another object of the present invention is to provide such a fluid dispenser member which exhibits improved properties of stress creep resistance. The present invention also aims to provide such a fluid dispenser member that allows a wide range of load control and deformation depending on the type of device in which it is used. Another object of the present invention is to provide such a fluid dispenser member which is simple and inexpensive to manufacture and assemble, and safe and reliable to use. The present invention therefore relates to a fluid dispenser member, comprising a body and dispensing means manually actuated movable in said body between a rest position and a dispensing position, said dispensing means being resiliently biased towards their position. rest position by a resilient member, said resilient member having a plurality of resilient cells disposed in parallel about a longitudinal axis of said resilient member, forming a level of resilience, and said resilient member comprises a plurality of levels of elasticity superimposed along said longitudinal axis.

Advantageously, a level of elasticity comprises a multiple corrugated upper corrugated ring and a lower undulated corrugated ring, arranged with respect to each other such that said upper and lower corrugated rings are in contact at several points. contact members distributed around said longitudinal axis, an elastic cell being defined between two adjacent contact points of said elasticity level. Advantageously, the upper corrugated ring of a level of elasticity forms the lower corrugated ring of the elasticity level disposed directly above, and the lower corrugated ring of said elasticity level forms the upper corrugated ring of the level of elasticity arranged directly below. Advantageously, the contact points of a level of elasticity are offset with respect to the points of contact of the elasticity levels directly above and directly below, a contact point of the elasticity level being arranged in the middle two points of contact of the level of elasticity directly above and in the middle of two points of contact of the level of elasticity directly below. Advantageously, the upper and lower axial edges of said elastic member are formed by flat rings. Advantageously, said elastic member is made, in particular by injection, of synthetic material, such as polyoxymethylene (POM). Advantageously, said synthetic material is loaded with reinforcing materials and / or creep resistance, such as glass fibers and / or carbon nanotubes. Advantageously, said fluid product is a liquid or powdery medicine. Advantageously, said dispensing member is a pump or a valve, said dispensing means being the pump piston or the valve valve, and said resilient member forming the return spring of said pump or valve.

Advantageously, said dispensing member is a flush of compressed air, said dispensing means being the plunger of the air flush, and said resilient member forming the return spring of said flush. The present invention also relates to a fluid dispenser device, comprising a reservoir containing said fluid product, and comprising a dispensing member as described above. These and other features and advantages of the present invention will become more apparent from the following detailed description thereof, with reference to the accompanying drawings, given as non-limiting examples, and in which: FIG. FIG. 2 is a schematic cross-sectional view of a portion of a fluid dispenser member according to a first embodiment of the present invention. FIG. 2 is a view similar to FIG. 1, showing another variant embodiment. of a fluid dispenser member according to the present invention, and Figure 3 is a schematic perspective view of detail of an elastic member according to an advantageous embodiment of the present invention. Referring to FIG. 1, there is shown a first alternative embodiment of a fluid dispenser member 10 according to the present invention. In this first embodiment, the fluid dispenser member 10 is a pump comprising a pump body 11 in which slides a piston 20 forming dispensing means manually actuated. This piston 20, when moved in said body 11 to its dispensing position, will expel a dose of fluid through a dispensing port 12 of the pump, which is generally connected to a dispensing head (not shown) which comprises the spray orifice through which the fluid product will be permanently distributed to the user. The piston 20 is urged by a resilient member 100 towards its rest position 30 and when the user manually actuates the pump, he depresses the piston 20 inside the pump body 11 by compressing the elastic member 100. When it relaxes its actuating force, said elastic member 100 compressed automatically returns the piston 20 of the pump 10 in its rest position, which is that shown in Figure 1. The pump shown in Figure 1 is a pump of a particular type, and it is understood that the present invention is not limited to this particular pump, but that any type of pump may be concerned. It should also be noted that a valve could also be used as a fluid dispenser member according to the present invention. In this case, it is not a piston but a valve valve that moves against the force of the elastic member within a suitable valve body. Figure 2 shows another alternative embodiment of a fluid dispenser member 10 according to the present invention. In this second variant, the fluid dispenser member 10 is a flush of air, comprising a body 11 in which a piston 20 moves to compress air and thus create a flush of compressed air. This compressed air will dispense a dose of fluid, generally powder, disposed downstream of said flush. When the user presses on the air discharge piston 20, he will compress the elastic member 100 and the air contained inside the air flushing body 11, until this compressed air is dispensed, for example from a given compression threshold or from a mechanical opening of a suitable orifice 12. When the user then releases his actuating force on the flushing piston 20, it is automatically returned to its rest position by the resilient member 100 compressed. The user can then change the fluid cartridge, or the like, of the fluid dispensing device with which the flush is associated, to dispense the next dose. Again, Figure 2 shows only a particular embodiment, and the present invention is obviously not limited by this variant as shown. According to the invention, the elastic member 100 has a particular structure 30 very different from a spiral spring usually used in this type of devices. FIG. 3 represents a schematic perspective view of an advantageous embodiment of the elastic member 100.

This comprises a plurality of elastic cells C which are arranged in parallel around the longitudinal axis X of the elastic member 100. This plurality of elastic cells C in parallel forms a level of elasticity N. According to the invention, the elastic member 100 comprises a plurality of levels of elasticity, in this case the N-2, N-1, N, N + 1, N + 2 and N + 3 levels in FIG. 3. Of course, a different number of levels of elasticity can be used. These levels of elasticity are superimposed on each other along said longitudinal axis X. Referring more particularly to the level of elasticity N, it comprises a corrugated upper ring 110 with multiple corrugations and a lower corrugated ring 120 also multiple ripple. These upper and lower corrugated rings 110, 120 are arranged in such a way that they touch each other at several contact points P which are distributed around said longitudinal axis X. Thus, a hollow of the upper corrugated ring will come into contact with a top of the lower corrugated ring to form a contact point P. In this way, between two adjacent contact points P, an elastic cell C will be formed, and thus a plurality of elastic cells C will be distributed around the At the periphery of said N elasticity level. As seen in FIG. 3, the upper corrugated ring of the N elasticity level forms the lower corrugated ring of the elasticity level disposed directly above N + 1 and the ring undulating corrugation of the elasticity level N forms the upper corrugated ring of the level of elasticity arranged directly below N-1. In other words, each elasticity level has the same number of elastic cells C and contact points P. In particular, the points of contact of the elasticity level N are offset with respect to the contact points of the levels. of elasticity directly above N + 1 and directly below N-1, with a point of contact of the level of elasticity N which is arranged in the middle of two points of contact of the level of elasticity directly above N +1 and in the middle of two points of contact of the level of elasticity directly below N-1. In other words, the points of contact of a level of elasticity form the vertices of the elastic cells of the levels of elasticity directly above and below, and vice versa. Preferably, the upper and lower axial edges of the elastic member 100 are formed by flat rings 130, 140. Thus, the first levels of elasticity from the top and the bottom of the elastic member 100 are not complete elasticity levels since their elastic cells C are not formed by two corrugated rings but only by a corrugated ring associated with a flat ring. In the example of FIG. 3, the elastic member 100 has six complete levels of elasticity, plus the two partial levels defined by the upper and lower axial edges 130. This multi-level structure of multiple cells in parallel is particularly advantageous. On the one hand, it makes it possible to produce elastic members with small dimensions. Indeed, compared to a conventional spiral spring 15, the same compressive force can be obtained by the elastic member of the present invention for about a space corresponding to 50% of the axial space. The elastic member of the present invention is therefore particularly suitable for small strain strokes, for example up to about 20 mm of strain, which are characteristic of pumps or valves used in the pharmaceutical industry. Furthermore, the elastic member 100 of the present invention has improved characteristics of stress creep resistance, since it consists of several series of cells arranged in parallel, unlike the spiral springs which consist of cells or turns arranged only in series. Furthermore, depending on the thickness of the rings, their round or rectangular section or other, the material and the size of the elastic cells, a large amplitude of charge control and deformation can be achieved depending on the type of device in which the elastic member will be used. The present invention is therefore particularly applicable to fluid dispensing devices of the pharmaceutical field, and especially for dispensing liquid or powder-form drugs by means of pumps, valves, powder inhalers, single dose etc. Preferably, the elastic member 100 is made of synthetic material, in particular by injection. This avoids the risk of harmful interaction between the elastic member and the fluid to be dispensed. For example, the elastic member 100 may be made of polyoxymethylene (POM). Other materials are also possible. Advantageously, the synthetic material may be loaded with one or more materials that enhance the elasticity and / or creep resistance, such as glass fibers or carbon nanotubes. Although the present invention has been described with reference to the accompanying drawings, it is not limited by them, but on the contrary the person skilled in the art can make any useful modification without departing from the scope of the present invention as defined by the appended claims.

Claims (1)

1. fluid fluid distribution member (10), comprising a body (11) and manually actuated dispensing means (20) movable in said body (11) between a rest position and a dispensing position, said means for distribution (20) being biased elastically towards their rest position by an elastic member (100), characterized in that said elastic member (100) comprises a plurality of elastic cells (C) arranged in parallel around a longitudinal axis (X ) of said elastic member (100), forming a level of elasticity (N), and said elastic member (100) comprises a plurality of levels of elasticity (..., N-1, N, N + 1,. ..) superimposed along said longitudinal axis (X). An element according to claim 1, wherein a level of elasticity (N) comprises a corrugated upper ring (110) with a multiple undulation and a corrugated lower ring (120) with a plurality of corrugations, arranged with respect to the other such that said upper and lower corrugated rings (110, 120) are in contact at a plurality of contact points (P) distributed around said longitudinal axis (X), an elastic cell (C) being defined between two points of contact adjacent contact (P) of said level of elasticity (N). 3. An organ according to claim 2, wherein the upper corrugated ring of a level of elasticity (N) forms the undulated corrugated ring of the level of elasticity arranged directly above (N + 1), and The lower corrugated ring of said elasticity level (N) forms the upper corrugated ring of the level of elasticity disposed directly below (N-1). 4. An article according to claim 3, wherein the contact points of a level of elasticity (N) are offset with respect to the contact points of the elasticity levels directly above (N + 1) and 9 5i0 directly below (N-1), a point of contact of the level of elasticity (N) being disposed in the middle of two points of contact of the level of elasticity directly above (N + 1) and in the middle of two points of contact of the level of elasticity directly below (N-1). 5. An organ according to any one of the preceding claims, wherein the upper and lower axial edges of said elastic member (100) are formed by flat rings (130, 140). io 6. Body according to any one of the preceding claims, wherein said elastic member is made, in particular by injection, of synthetic material, such as polyoxymethylene (POM). 15 7. An organ according to claim 6, wherein said synthetic material is loaded with elasticity reinforcing and / or creep resistant materials, such as glass fibers and / or carbon nanotubes. 20 8. Body according to any one of the preceding claims, wherein said fluid product is a liquid or powdery medicine. An organ according to any one of the preceding claims, wherein said dispensing member is a pump or a valve, said dispensing means being the pump piston or the valve valve, and said resilient member forming the spring of recall of said pump or valve. 30 10. An organ according to any one of the preceding claims, wherein said dispensing member is a flush of compressed air, said dispensing means being the piston of the air flush, and said elastic member forming the return spring said air flush. 11. Fluid dispensing device, comprising a reservoir containing said fluid, characterized in that it comprises a dispensing member (10) according to any one of the preceding claims.