The present invention relates to the field of dispensing fluid by means of a pump. More particularly, but not exclusively, the device makes it possible to dispense a liquid for nose, eye, or mouth use, the user actuating the pump by exerting pressure laterally on the device.
Laterally-actuated spray devices are already known, such as the device described in Document FR 2 812 826. That device comprises a pump that is movable axially between a rest position and a liquid-dispensing position. That pump is caused to move by an actuating arm that is mounted to pivot on the device in such a manner as to move the pump into the dispensing position when the user presses the arm in the transverse direction.
The force that the user's hand must exert on the actuating arm can be relatively high, which makes the device awkward and difficult to use for elderly people or for children.
The present invention proposes to reduce the force necessary for actuating the device.
To this end, the invention provides a fluid dispenser device for dispensing fluid, said fluid dispenser device comprising: a pump for dispensing the fluid; a first arm referred to as the “main” arm, mounted to pivot on the device about an axis referred to as the “main” axis, which arm is provided with a press zone on which the user exerts pressure in order to actuate the pump; and a second arm, referred to as the “intermediate” arm, mounted to pivot on the main arm about an axis, referred to as the “intermediate” axis, this axis being disposed on the main arm between the press zone and the main axis, and the intermediate arm being configured to transmit the movement of the press zone to the pump.
Thus, the intermediate arm, mounted between the pivot axis and the press zone of the main arm, can generate a lever effect that makes it possible to reduce the force that needs to be exerted by the user on the press zone for the purpose of actuating the pump. In addition, since this lever is mounted to pivot on the main arm, the angular position of the intermediate arm relative to the main arm can vary while the main arm is pivoting. As a result, the free end of the intermediate arm, which end is opposite from the pivot axis of the intermediate arm, can move in translation in a direction corresponding to the axis of the pump, making it possible to move the pump into its dispensing position. In other words, by means of the proposed configuration, the free end of the intermediate arm does not necessarily move in rotation, it can advantageously move in translation, so that the movement in rotation generated by the user pressing on the main arm is transformed into a movement in translation of the free end of the intermediate arm, this movement in translation taking place in the axial direction (i.e. along the axis of the pump), so as to actuate the pump. By means of this movement in axial translation, a force exerted by the user on the press zone makes it possible to move the pump (or a support of the pump) over a longer stroke than if the intermediate arm were prevented from moving relative to the main arm, in which case the free end of the intermediate arm would move in rotation. In conclusion, by means of the pivotally-mounted intermediate arm, the user can exert a lower force for actuating the pump than when the dispenser device has a single pivotally-mounted arm actuating the pump directly.
Among the advantages of the dispenser device, it can be understood that it enables the user to exert a lower force on the press zone, or indeed, for the same force exerted by the user, to exert a higher force on the pump and thus to use a pump having a higher activation force, so as to achieve specific features, e.g. certain spray qualities. Or indeed, for the same pump, the above device can require the press zone to be moved to a smaller extent, thereby making it possible to increase the overall compactness of the device, in particular by reducing the inclination of the main arm relative to the general shape of the device, and thus by reducing the general diameter of the device.
It can be understood below that the term “movement” as applied to the pump is used to designate movement of the entire pump or of some portion thereof. Generally, the pump comprises an upstream portion and a downstream portion that are mounted to move relative to each other by sliding, and movement of the pump corresponds to movement of the upstream portion relative to the downstream portion.
The device may also have one or more of the following characteristics:
The device has two ends, namely a dispensing head and an end-wall, the main axis being provided in the vicinity of one of the ends and the press zone being provided in the vicinity of the opposite end. By means of this configuration, the press zone on which the user exerts pressure is as far away as possible from the pivot axis of the main arm, thereby optimizing the lever effect, and thus reducing to as small as possible the force that needs to be exerted on the press zone.
The intermediate arm has a free end opposite from its pivot axis, this free end co-operating with an abutment constrained to move with the pump, the abutment being arranged in such a manner that the pivoting of the intermediate arm causes the pump to be moved into a fluid-dispensing position. It can be understood that an abutment constrained to move with the pump moves with the pump. It can be provided directly on a portion of the pump or on a part fastened to the pump, e.g. on a link ring interconnecting the pump and the container of the device, or indeed on the container mounted such that it is prevented from moving relative to another portion of the pump.
The intermediate axis is mounted on the main arm at a distance relative to the main axis that is less than two-thirds of the distance between the main axis and the press zone. In this configuration, the effect brought by the intermediate arm is optimized. In particular, the stroke of the free end of the intermediate arm is sufficiently long in the axial direction, and the distance between the press zone and the intermediate axis is also sufficiently large to achieve a satisfactory reduction in the force to be exerted by the user. In order to minimize this force, the intermediate axis is mounted on the main arm as close as possible to the main axis, preferably at a distance relative to the main axis that is less than one half of the distance between the main axis and the press zone. It should, however, be noted that, for optimum operation of the device, the position of the intermediate axis on the main arm is not the only parameter to be taken into account, it being possible for the reduction in the force exerted by the user to depend, for example, on the inclination of the intermediate arm relative to the axis of the pump, or indeed to depend on other parameters.
The device is provided with declutching means in such a manner that the pressure exerted by the user causes the pump to return to its rest position after said pump has moved into a dispensing position. Thus, it is not the press zone being released by the user that causes the pump to return to the rest position, but rather it is the final stage of the pressing exerted by the user. This characteristic is particularly advantageous because it guarantees that the pump returns to the rest position, automatically and directly after a metered quantity of fluid has been dispensed, and not after a certain lapse of time, simultaneously with the press zone being released by the user. It is thus possible to guarantee that the pump returns to the rest position when the device is in the dispensing configuration, in particular when it is disposed head-down, and thus when the fluid contained in the container is to be found beside the pump. As a result, when the pump goes from its dispensing position to its rest position, the liquid is to be found beside the pump, which thus sucks in liquid, rather than air contained in the container and that might de-prime the pump.
The declutching means comprise an abutment past which the intermediate arm forces its way once the pump is in the dispensing position.
The device further comprises a dispenser head and can take up a “head-up” position or a “head-down” position, the device being designed to dispense liquid when it is in the head-down position, the device being provided with disabling means for disabling the device when it is in the head-up position. For the same reasons as above, these disabling means prevent the pump from de-priming, in the event that the user is tempted to press on the press zone while the device is in the head-up position.
It should be noted that the head-down position generally corresponds to a position in which the dispenser head is below the container in the direction of gravity.
The disabling means comprise a ball that can take up a disabling position and that, under the effect of gravity, can take up an enabling position.
The axis of the main arm is disposed in the vicinity of the dispenser head of the device.
The axis of the main arm is disposed in the vicinity of the end-wall of the device.
The invention can be better understood on reading the following description given merely by way of example, and with reference to the drawings, in which:
The pump 14 makes it possible to suck in the liquid contained in the container 12 in order to deliver it from the device, e.g. by spraying. To this end, the pump 14 comprises two portions that are mounted to slide relative to each other, namely, in this example, an upstream portion 24 and a downstream portion 26, shown in
The downstream portion 26 of the pump has a “dispensing” end 27. In this example, the spray direction of the device 10 is axial, and thus along the axis X. The dispensing end 27 is therefore provided with an orifice of axis X in its top surface, for the purpose of directing the liquid along the axis X. It can be understood that other fluid dispensing directions are possible.
The pump 14 is mounted on the container 12 via the link ring 16 that is constrained to move with the upstream portion 24 of the pump 14. Said link ring 16 therefore moves with the upstream portion 24 of the pump while said pump is taking up its dispensing position. In addition, the ring 16 is mounted on the container 12 in such a manner as to be prevented from moving relative thereto, e.g. by snap-fastening, so that the container can move with the ring and with the upstream portion 24 of the pump. Said ring 16 is tubular in general shape, and is mounted coaxially around the upstream portion 24 of the pump, e.g. by snap-fastening. The ring 16 co-operates with the upstream portion 24 of the pump to define a tubular recess designed to receive an outlet segment 28 of the container 12.
The outer casing 18 is cylindrical or conical in general shape. It carries a fluid dispenser head 30 that receives the dispensing end 27 of the pump 14. The head 30 is provided with an orifice 32, extending the orifice in the end 27. At the end opposite from the head 30, the end-wall 11 is mounted on the casing 18, e.g. by snap-fastening.
The device 10 is a laterally actuated device, i.e. the user exerts pressure in the direction indicated by arrow F in
To this end, the arm 20 constitutes a first arm that is referred to below as the “main” arm, and that is pivotally-mounted on the device 10, and more precisely on the casing 18, to pivot about a pivot axis 34, referred to below as the “main” axis 34, and represented by the letter 0 in
The main arm 20 is also provided with return means 42, making it possible to urge the arm 20 back into its rest position when the user ceases to press on the press zone 40. For example, these return means 42 comprise a resilient tongue.
In addition to having the main arm 20, the device 10 has a second arm 44, referred to below as the “intermediate” arm 44, that is mounted to pivot on the main arm 20 about an axis 46 referred to below as the “intermediate” axis and represented by the point A in
The intermediate arm 44 is also provided with return means 58, e.g. a resilient arm 58, arranged to urge the intermediate arm 44 back into the rest position after the pump has been actuated.
As can be seen in
It should be noted that, in this embodiment, the main axis 34 is provided in the vicinity of one end of the device 10, namely in the vicinity of the dispenser head 30, and the press zone 40 is provided in the vicinity of the opposite end of the device 10, namely in the vicinity of the end-wall 11 of the device. Therefore, the distance between the axis 34 and the press zone 40 is as large as possible on the device 10.
In addition, in this embodiment, the device 10 is provided with means for disabling the device when said device 10 is in the head-up position. The head-up position corresponds to a position in which the dispenser head 30 is above the end-wall 11 in the direction of gravity, indicated by arrow g in
Operation of the device 10 is described below.
While the device 10 is not being used, e.g. while it is standing on any support, without the user pressing on it, the device is in the configuration shown in
After declutching has taken place via the intermediate arm 44, with the user having pushed in the main arm 20 to the fullest extent, and with the metered quantity of liquid having been dispensed from the device, the user ceases to press on the intermediate arm, and puts the device 10 back into the head-up position. The user ceasing to exert pressure on the press zone 40 releases the main arm 20 that can thus resume its initial position, by means of the return means 42 bearing against the container 12 or against the link ring 16, as shown in
It can be understood that, by means, in particular, of the intermediate arm 44, the force F to be exerted by the user on the device 10, in order to actuate the pump 14, is lower.
As can be observed, the optimum configuration of the device 10 depends on certain parameters that vary as a function of type of device. Thus, it is possible, for example, to vary the length of the main arm 20, the length of the intermediate arm 44, the angle α (alpha) of the main arm 20 relative to the axis X of the device, the distance OA between the two pivot axes 34, 46, the horizontal position of the point C, i.e. of the end 50 of the intermediate arm 44, the force P or the stroke to be applied to the pump in order to actuate it, etc.
In order to determine the optimum configuration, the inventors have expressed the force F to be exerted by the user on the device 10 for the purpose of activating the pump. This force is expressed by the following equation:
In order to determine for which value of one or more of these parameters the force exerted by the user on the press zone 40 is at a minimum, it is possible to derive the above expression of the force F relative to one or more parameters of the equation, and to solve one or more equations corresponding to the situation when the derivatives are equal to zero.
In one embodiment, the following values are considered as being particularly advantageous for minimizing the force to be applied by the user on the press zone 40:
In another embodiment, shown in
It should be noted that the invention is not limited to the above-described embodiments.
In particular, the disabling means 60, 62, 64 are not necessarily provided on the device.
Similarly, the declutching means are optional. Thus, instead of providing declutching of the device by the end 50 of the intermediate arm 44 forcing its way past the abutment 54, it is possible to make provision for the end 50 to be continuously in abutment against the abutment 54 on the link ring 16, so that the pump 14 resumes its rest position once the user releases the main arm 20. In this configuration, the return means 42, 58 for the main arm 20 are no longer essential, because the intermediate arm 44 and the main arm 20 are urged back into the rest position by return means internal to the pump 14, bringing said pump back into the rest position.
In addition, it should be noted that the arms 20 and 44 are referred to as the “main arm” and as the “intermediate arm” to make it simpler to understand the description, but the use of such terms does not mean that the arm 20 is necessarily longer or more rigid than the arm 44. In other words, the arm 20 could be referred to as the “first arm” and the arm 44 could be referred to as the “second arm”.
It should also be noted that the pump 14 described by way of example is designed to dispense liquid, but it is possible for the pump to be a pump for dispensing gas, or indeed a pump for sucking in external fluid.
Among the advantages of the invention, it should be noted that the use of an arm that is activated transversely is advantageous as regards maximizing the compactness of the device in the axial direction.
Among the advantages of the above-described declutching means, it should be noted that the declutching guarantees that a metered quantity has been fully dispensed, and thereby avoids the user releasing the arm 20 before the metered quantity has been dispensed in full. Thus, the declutching guarantees, in simple manner, that the metered quantity is delivered, without over-complicating the mechanism of the device 10.
It should be noted that although combining the declutching means and the disabling means makes it possible to avoid any de-priming of the pump 14, they could be used independently from each other.
It should also be noted that the use of the disabling means or of the declutching means is particularly advantageous when a pump 14 is used without a dip tube.
Number | Date | Country | Kind |
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08 51996 | Mar 2008 | FR | national |
The present application is a continuation of pending International patent application PCT/FR2009/000358 filed Mar. 27, 2009, which designates the United States and claims priority from French patent application FR 0851996 filed Mar. 27, 2008, the content of which is incorporated herein by reference.
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Entry |
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French Search Report; Application No. FR 0851996; Oct. 28, 2008; 6 pages. |
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Number | Date | Country | |
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20110062186 A1 | Mar 2011 | US |
Number | Date | Country | |
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Parent | PCT/FR2009/000358 | Mar 2009 | US |
Child | 12891412 | US |