FLUID PRODUCT DISPENSER

Abstract

A dispenser having a fluid reservoir (1); a dispenser member (2) having a body (21) and an actuator rod (22) movable over a maximum rod stroke; a dispenser orifice (46); a rotary actuator member (4); a transmission member (5) that is engaged both with the dispenser member (2) and also with the rotary actuator member (4); and a cam mechanism (43, 55) for transforming turning of the rotary actuator member (4) into an axial movement of the actuator rod (22) or of the body (21). The cam mechanism (43, 55) defines a maximum cam stroke that is greater than the maximum rod stroke; and a resilient mechanism (56) acts axially to compensate for the extra amount of the maximum cam stroke and thus allow it to be followed so as to guarantee that the rod performs its maximum stroke in full.

Claims

1. A fluid dispenser, comprising: a fluid reservoir; a dispenser member through which the fluid is delivered, the dispenser member comprising a body and an actuator rod that is axially movable down and up relative to the body over a maximum rod stroke; a dispenser orifice where a user may recover the dispensed fluid; a rotary actuator member that the user can turn about its own axis; a transmission member that is engaged both with the dispenser member and also with the rotary actuator member; and cam means that are formed by the rotary actuator member and by the transmission member for transforming turning of the rotary actuator member into an axial movement of the actuator rod or of the body; the dispenser being characterized in that: the cam means define a maximum cam stroke that is greater than the maximum rod stroke; and resilient means act axially so as to compensate for the extra amount of the maximum cam stroke and thus allow it to be followed so as to guarantee that the rod performs its maximum stroke in full.

2. A dispenser according to claim 1, wherein the cam means comprise at least one cam path of axial height that varies, and at least one cam follower that follows the respective cam path.

3. A dispenser according to claim 1, wherein the transmission member comprises a central cap that is engaged with the actuator rod, and a cam ring that defines at least one cam path of axial height that varies.

4. A dispenser according to claim 3, wherein the resilient means are formed by the transmission member.

5. A dispenser according to claim 4, wherein the cam ring is connected to the central cap via a plurality of flexible bridges forming the resilient means and/or the cam ring is elastically deformable so as to form the resilient means.

6. A dispenser according to claim 3, wherein the rotary actuator member includes a plurality of profiles forming cam followers that come into engagement with the cam paths of the cam ring and that follow them.

7. A dispenser according to claim 3, wherein the rotary actuator member comprises a rotary actuator ring that a user can grip, and a collection dish in which the user can recover the fluid that has been dispensed.

8. A dispenser according to claim 7, wherein the rotary actuator ring does not move axially, and the collection dish is elastically deformable so as to follow the axial movement of the actuator rod.

9. A dispenser according to claim 8, wherein the collection dish is fastened to the central cap of the transmission member, which central cap advantageously forms a connection bushing that is connected to the actuator rod, and an endpiece that is connected to the collection dish.

10. A dispenser according to claim 1, wherein the resilient means are formed by the rotary actuator member.

11. A dispenser according to claim 1, wherein the transmission member is engaged with the fluid reservoir at its bottom.

Description

[0013] The invention is described more fully below with reference to the accompanying drawings which show three embodiments of the invention by way of non-limiting example.

[0014] In the figures:

[0015] FIG. 1 is an exploded perspective view of a dispenser constituting an embodiment of the invention;

[0016] FIGS. 2a and 2b are larger-scale perspective views of the FIG. 1 transmission member;

[0017] FIGS. 3a and 3b are vertical section views through the FIG. 1 dispenser, respectively in its rest position and in its actuated position;

[0018] FIG. 4 is a vertical section view through a rotary actuator member constituting another embodiment of the invention; and

[0019] FIG. 5 is a diagrammatic vertical section view through a dispenser constituting another embodiment of the invention.

[0020] Reference is made firstly to FIGS. 1 to 3b in order to describe a dispenser constituting a first embodiment of the invention. As can be seen in FIG. 1, the dispenser comprises a plurality of component elements, namely: a container body 11 that defines a shoulder 111 and a neck 112; a follower piston 12; a container bottom 13; a covering hoop 6; a dispenser member 2 that in this embodiment is a pump; a reception ring 3; a rotary actuator member 4; and a transmission member 5. The covering hoop 6 and the container bottom 13 are elements that are optional.

[0021] In FIGS. 2a and 2b, the transmission member 5 is shown on a much larger scale so that details can be seen. It includes a central cap 51 that defines a cylindrical portion 511 that is surmounted by a top wall 51 in the shape of a dome. At its center, the outside of the wall 51 forms an outer endpiece 52 having a function that is explained below. As can be seen in FIG. 2b, the inside of the top wall 51 forms a connection bushing 53 that is axially in alignment with the endpiece 52. The function of the connection bushing 53 is explained below. A duct extends through the outer endpiece 52 and the connection bushing 53.

[0022] The transmission member 5 also includes a cam ring 54 that is arranged coaxially around the central cap 51. Advantageously, the cam ring 51 is connected to the cylindrical portion 511 of the central cap 51 via a plurality of flexible tabs 56 that, in this embodiment, are four in number. As a result, the cam ring 54 can move axially relative to the central cap 51 over a limited axial height, e.g. in the range about a few tenths of a millimeter to about two millimeters. The cam ring 54 defines a plurality of cam paths 55 that, in this embodiment, are four in number. Each cam path 55 comprises two sloping ramps 55b that slope in opposite manner, so that they join together at a high point 55c. The sloping ramps of a cam path are connected to the sloping ramps of the adjacent cam paths at low points 55a, at which the flexible bridges 56 are advantageously formed. Thus, as can be seen more clearly in FIG. 2a, the cam ring 54 defines four cam paths 55 that together define eight sloping ramps 55b, four high points 55c, and four low points 55a.

[0023] The difference in axial height between the low points 55a and the high points 55b defines an axial cam stroke that, in the invention, is a little greater than the maximum rod stroke of the dispenser member 2.

[0024] It should also be observed that the high points 55b are situated mid-way between two flexible bridges 56. As a replacement for the flexible bridges 56 or in addition thereto, provision could also be made for each cam path 55 to be elastically deformable along its length, thereby creating resilient means that would complement the flexible bridges 56 or replace them.

[0025] The dispenser member 2 may be a pump or a valve. Either way, the dispenser member 2 comprises a body 21 and a valve rod 22 that are axially movable over a maximum rod stroke. In concrete terms, the maximum rod stroke corresponds to the distance travelled by the actuator rod 22 between its rest position and its position fully depressed inside the body 21. This is entirely conventional for a valve or a pump.

[0026] FIG. 3 shows the dispenser in the mounted state. The follower piston 12 is engaged inside the container body 11, and the bottom 13 is fitted to the bottom end of the body 11. In this way, a fluid reservoir 1 is created that, in this embodiment, is of volume that varies as a result of the follower piston 12 moving towards the dispenser member 2. The dispenser member 2 is mounted by means of its fastener ring 3 on the neck of the container body 1. The covering hoop 6 is snap-fastened on the container body 1. The transmission member 5 is mounted on the dispenser member 2 by engaging its connection bushing 53 around the free end of the actuator rod 22. The rotary actuator member 4 is mounted on the transmission member 5 via the inside of the covering hoop 6. More precisely, the rotary actuator member 4 comprises a rotary actuator ring 41 that a user can grip, and a collection dish 44 in which the user can recover the fluid that has been dispensed. The bottom end of the ring 41 is snap-fastened at 42 on a snap-fastener profile 62 that is formed on the inside of the covering hoop 6. In this way, the rotary actuator member 4 is held captive in the hoop 6 while being able to turn about its own axis. The inside of the rotary actuator ring 41 forms a plurality of downwardly-directed shoulders that act as cam followers 43. The cam followers 43 are situated axially just above the cam ring 54. There are as many cam followers 43 as there are cam paths 55. The collection dish 44 is arranged at the top end of the rotary ring 41 and is made out of a flexible material, such as an elastomer. By way of example, the rotary ring 41 and the collection dish 44 may be made by overmolding or bi-injecting different plastics materials. On its bottom face, the collection dish 44 defines a leaktight connection bushing 45 that is in leaktight engagement around the endpiece 52 of the transmission member 5. In this way, an outlet channel is defined that connects the actuator rod 22 to a dispenser orifice 46 defined in the collection dish 44.

[0027] In FIG. 3a, the dispenser is at rest, with the cam followers 43 arranged at the low points 55a of the cam paths 55. The collection dish 44 is at rest, with a shape that is substantially plane. When a user grips the dispenser, the rotary actuator ring 41 can be turned in one direction or the other: the cam followers 43 come into engagement with the sloping ramps 55b, thereby causing the transmission member 5 to move axially downwards, given that the rotary actuator member 4 is prevented from moving axially. The cam followers 43 thus move along the sloping ramps 55b into the proximity of the high points 55c. Just before reaching these tips 55c, the actuator rod 22 is normally fully depressed, thereby ensuring that the dose of fluid has been dispensed in full. In order to enable the cam followers 43 to continue up to the tips 55c and then cross over to the other side towards the descending ramp, resilient means are provided that act axially so as to compensate for this extra amount of cam stroke and thus allow it to be followed, thereby guaranteeing that the rod performs its maximum stroke in full. In this embodiment, the resilient means are in the form of the flexible bridges 56 and/or the capacity of each cam path 55 to deform.

[0028] FIG. 3b shows the dispenser in the actuated position, i.e. with the actuator rod 22 fully depressed and the cam followers 43 situated at the tips 55c. Deformation of the bridges 56 and/or of each cam path 55 is not shown, since this is difficult to represent.

[0029] Once the high points 55c have been passed, the cam followers 43 return easily to their low points 55a by following the descending ramps 55b. Simultaneously, the actuator rod 22 returns progressively towards its extended rest position. In this way, one complete actuation cycle is performed.

[0030] It should be kept clearly in mind that this first embodiment is not limiting in any way. Specifically, numerous different variants and versions exist that make it possible to achieve the same result, namely to compensate resiliently for a cam stroke that is longer than the maximum rod stroke. FIG. 4 shows an actuator member 4′ that is similar to the actuator member of the first embodiment. However, in this embodiment, the cam followers 43′ are formed by thin radial tabs that present sufficient springiness to compensate for, or to overcome, the extra amount of cam stroke. Thus, in this embodiment, the resilient means are formed by the rotary actuator member and not by the transmission member 5, as in the first embodiment.

[0031] FIG. 5 shows yet another embodiment in which the transmission member 5″ acts on the bottom 14 of a reservoir 1″. The transmission member 5″ may have an annular profile in the shape of saw teeth 55″ that are engaged with corresponding teeth 43″ of a cylinder 42″ having an outer periphery that is engaged in grooves 44″ formed by a rotary actuator member 4″. The cylinder 42″ is urged against the transmission member 5″ by a spring 45″.

[0032] In this embodiment also, the cam stroke that is defined by the height of the teeth 55″ is greater than the maximum rod stroke of the actuator rod 22. When the rotary actuator member 4″ is turned, the cylinder 42 is turned in such a manner as to move the tabs 43″ along the teeth 55″. This causes the actuator rod 22 to be depressed into the dispenser body 2 until the maximum rod stroke is reached. The extra amount of cam stroke formed by the teeth 55″ is accommodated or taken up by the spring 45″ that enables the cylinder 42′ to move axially downwards a little. That enables the teeth 43″ to pass over the tips of the teeth 55″.

[0033] In all of the embodiments, it is preferable for the resilient means to present a resistance to deformation that is greater than the force necessary to depress the actuator rod. As a result, the actuator rod is moved and fully depressed initially, and then only the resilient means (flexible bridges 56, cam path 55, flexible tabs 43′, spring 45″) move and deform.

[0034] Whatever the embodiment described and whatever the position of the transmission member and of the rotary actuator member relative to the actuator rod, provision is made for a cam stroke that is greater than the maximum rod stroke, with the extra amount of cam stroke being compensated for, accommodated, taken up, or merely allowed, by the presence of resilient means that may be incorporated in the transmission member and/or in the rotary actuator member, so as to guarantee that the dose is dispensed in full on each actuation.