Patent Grant
8875954
The present invention relates to a dispenser, i.e. a dosing device able to be applied to the neck of a bottle to dispense the liquid contained therein.
In particular, the present invention relates to a dispenser of the type comprising a containment body with substantially axial-symmetric geometry, internally hollow and able to be inserted in the neck of a bottle.
The containment body is provided in a first end with an orifice for the entry of the liquid product present in the bottle. Said orifice is opened or closed by a ball free to slide within the containment body, in particular within a dosing chamber included therein.
The dosing chamber is defined by the space present between a piston, guided by an internally hollow stem, able to slide within the containment body and the bottom portion (where the orifice is positioned) of the containment body.
Between piston and stem are present means for opening and closing the inner cavity of the stem in such a way as selectively to place in fluid communication the interior of the stem with the dosing chamber.
The stem is guided in its travel by a retaining ring, integral with the containment body, which also serves the abutment function for the travel of the piston.
In other words, the retaining ring defines the upper limit of the dosing chamber, preventing the piston from being able to exit from the dosing chamber itself.
When the piston creates an overpressure within the dosing chamber, the cavity of the stem is in fluid communication with the dosing chamber and the fluid present in the dosing chamber rises along the stem and is dispensed by a spout associated therewith.
In this configuration, the ball is lowered and occludes the aforementioned orifice because of the overpressure in the dosing chamber.
When the piston creates a vacuum within the dosing chamber the cavity of the stem is not in fluid communication with the dosing chamber and fluid is moved from the bottle into the dosing chamber.
In this configuration, the ball is raised and leaves open the aforementioned orifice because of the vacuum in the dosing chamber.
In this type of dispenser, the sliding of the piston within the containment body takes place contrasting the action of a spring whose function is to maintain the piston in raised position.
In particular, exercising a compression action on the stem, the piston slides within the dosing chamber, reducing its dimensions and hence creating an overpressure within it.
Ceasing the compression action on the stem, the aforementioned spring brings the piston back to the raised position, expanding the dimensions of the dosing chamber and hence creating a vacuum therein.
In these types of prior art dispensers, it is often preferred to prevent the spring from lying in the dosing chamber (thus acting between the stem or the piston and the bottom of the dosing chamber), in such a way as to prevent the spring from coming into contact with the fluid to be dispensed (which, as stated, moves from the bottle to the dosing chamber and thence to the dispensing spout through the cavity of the stem).
For this purpose, the spring is placed in so-called “external” position, in such a way that it acts between the stem and the retaining ring.
Therefore, the compression force exercised on the stem is unloaded on the retaining ring and thence it is transmitted to the containment body, and lastly to the bottle.
It should be noted that the retaining ring is made integral with the containment body thanks to the insertion of an annular edge of the ring within an undercut obtained in the containment body.
The retaining ring shall also assure a fluid tightness between its own outer wall and the wall of the containment body, to prevent the liquid contained in the bottle from escaping because of the overpressures that may be generated between the interior of the bottle and the environment in occasional situations (depressurized environment) or accidental situations (crushing of the bottle).
However, the prior art dispensers described above present some drawbacks.
During the operations for mounting the dispenser, in particular during the fitting of the dispensing spout, the compression forces necessary to insert the dispenser on the stem are contrasted by the retaining ring, i.e. they are unloaded on the containment body through the coupling between retaining ring and containment body itself.
In these conditions, to prevent an excessive pressure of the stem from thrusting the piston too deep into the dosing chamber, damaging it, the spring positioned between stem and retaining ring is arranged in such a way that the configuration of maximum compression of the spring coincides with the position of the maximum insertion of the piston in the dosing chamber (i.e. with the position of maximum lowering of the piston), with the disadvantage of an additional constraint in the selection of design parameters, e.g. diameter and number of coils, and the consequent use of oversized or excessively rigid springs, with respect to the simple function of exercising a returning action on the piston.
With solutions of this kind, if an excessive assembly force is exercised, the retaining ring could be damaged and not assure its functionalities (especially the fluid tightness with the inner wall of the containment body) for which it was designed.
In this context, the technical task at the basis of the present invention is to propose a dispense that overcomes the aforementioned drawbacks of the prior art.
In particular, an object of the present invention makes available a dispenser in which the retaining ring cannot be damaged accidentally because of excessive compression actions on the stem.
An additional object of the present invention is to propose a dispenser that does not require particular springs for its operation.
Yet another object of the present invention, lastly, is to prevent occasional malfunctions that can derive from the possible sticking of the ball in the structure that limits mobility.
The specified technical task and the objects specified are substantially achieved by a dispenser, comprising the technical characteristics exposed in one or more of the appended claims.
Further characteristics and advantages of the present invention shall become more readily apparent from the indicative, and therefore not limiting, description of a preferred but not exclusive embodiment of a dispenser, as illustrated in the accompanying drawings in which:
With reference to the accompanying drawings, a dispenser in accordance with the present invention is indicated with the number 1.
The dispenser 1 comprises a hollowing containment body 2 able to be inserted in a bottle.
The containment body 2 has axial-symmetric geometry and it comprises an upper portion 3 and a bottom portion 4.
The upper portion 3 is open and its function is to enable the insertion into the hollow body 2 of the elements (described farther on) which comprise the dispenser.
The bottom portion 4 is provided with an orifice 5 through which the liquid contained in the bottle enters the containment body 2.
The orifice 5 is engaged by a ball 5a whose function is to open or close the orifice 5 in ways that will be clarified farther on.
The containment body 2 is substantially shaped as a funnel.
In particular, the containment body 2 comprises a first section 2a that develops starting from the upper portion 3 towards the bottom portion 4, and a second section 2b positioned underneath the first section 2a.
The second section 2b defines a dosing chamber 6 for the dispenser 1.
Underneath the dosing chamber 6 develops a third section 2c from which the orifice 5 extends.
The three aforementioned sections have mutually different transverse dimensions, in such a way as to define the aforesaid funnel configuration of the containment body 2.
In particular, the second section 2b, the one defining the dosing chamber 6, is substantially cylindrical.
Within the hollow body 2 is provided a piston 7 movable between a raised position (illustrated in
The piston 7 comprises an outer surface 7a able to contact the inner wall of the second portion 2b of the hollow body 2.
The outer surface 7a of the piston 7 slides within the dosing chamber 6 between the aforementioned raised position in which the volume of the dosing chamber is greatest, and the aforementioned lowered position, in which the volume of the dosing chamber is smallest.
The outer surface 7a of the piston 7 slides providing fluid tightness along the inner wall of the second portion, in such a way that liquid present in the dosing chamber cannot escape through the sliding coupling between piston 7 and dosing chamber 6. The dispenser 1 further comprises a hollow stem 8 able to slide within the containment body 2 between a raised position (
The stem 8 commands the operation of the piston 7, i.e. it actuates it within the dosing chamber 6.
The stem 8 also serves the function of transferring, through its cavity, liquid present inside the dosing chamber 6 to a spout 9 that dispenses the liquid to a user.
In particular, opening and closing means 10 are active between the stem 8 and the piston 7 to place selectively in fluid communication the cavity of the stem 8 with the interior of the containment body 2, in particular with the dosing chamber 6.
The opening and closing means 10 comprise at least one window 11, preferably two opposite windows, for the passage of liquid obtained on the lateral wall of the stem 8.
The stem 8 is partially able to slide relative to the piston 7 to occlude the window 11 with a wall 7b of the piston 7 and to make the window 11 emerge relative to the piston 7.
In particular, the stem 8 is inserted in a through hole, delimited by the wall 7b, of the piston 7.
The stem is free to slide within the through hole by such a quantity as to make the window 11 emerge within the dosing chamber 6.
The terminal part of the stem 8 is therefore closed, in such a way that the liquid in the dosing chamber 6 can enter the cavity of the stem 8 only through the window 11. In the preferred embodiment, the relative motion between stem 8 and piston 7 is delimited by upper and lower abutments positioned on the stem 8.
In the illustrated embodiment of the invention, the stem 8 comprises two mutually joined half-parts 8a, 8b.
The first half-part 8a is fastened to the dispensing spout 9; the second half-part 8b bears the window 11.
In alternative embodiments, not illustrated herein, the stem 8 is made of a single piece.
To guide the stem 8 in its travel within the containment body 2, the dispenser 1 comprises a retaining ring 12 integral with the containment body 2 and inserted therein.
The retaining ring 12 is positioned in the first section 2a of the body 2 and it has a hole 13 for the passage of the stem 8.
Between the retaining ring 12 and the stem 8 are present elastic means 14 to contrast the free sliding of the stem (and hence of the piston) within the containment body 2. In particular, the elastic means 14 are constituted by a spring which is active between a shoulder 15 obtained on the stem 8 and a shoulder 16 obtained in the retaining ring.
The spring 14 is positioned concentrically to the stem 8 and externally thereto.
Acting on the spout 9, in particular pressing it, the stem 8 and the piston 7 translated within the dosing chamber 6.
In a first phase of said translation, the piston 7 remains motionless both because of the friction of the wall 7a of the piston with the wall of the dosing chamber 6, and as a result of the overpressure that is generated in the liquid contained in the dosing chamber because of the reduction in volume of said chamber.
In this phase the stem 8 translates relative to the piston 7 facing the window 11 (situated at the lower end of the stem 8).
The subsequent travel of the stem 8 drives with it the piston 7 determining a compression of the liquid present in the dosing chamber 6 which flows through the window 11 and hence through the spout 9 until it flows out to the exterior (operating configuration shown in
As a result of the release of the spout 9 by the user, the entire system returns to the resting position (shown in
During the rising phase, the stem 8 moves before the piston 7 (held by the friction with the walls of the dosing chamber 6) thereby closing the window 11.
In this way, the liquid present in the stem 8 and in the spout 9 is prevented from being aspirated into the dosing chamber 6 again.
The translation during the return travel of the piston 7 in the dosing chamber 6 creates a depression inside the dosing chamber 6 which determines the aspiration of liquid through the orifice 5 of the containment body 2.
At each dispensing operation, a volume of air equal to the dispensed liquid enters into the bottle through compensation passages obtained in the dispenser 1 (not illustrated) which place in communication the interior of the bottle with the external environment.
Advantageously, the dispenser 1 comprises an end stop structure 17 integral with the body 2 to define an end stop arrest for the sliding of the stem 8 within the containment body 2.
The end stop structure 17 contacts the stem 8 in the lowered position.
In this way, when the spout 9 is pressed, both during the mounting of the dispenser, and during its use, the compression force exercised is discharged through the stem 8 to the end stop structure and hence to the containment body 2.
This assures that the retaining ring 12 is not overloaded with stresses to be transferred to the containment body 2, preserving the integrity and functionality of the retaining ring 12.
It should also be noted that the end stop structure 17, exercising a mechanical arrest to the travel of the stem 8, allows to use springs 14 which do not necessarily have to reach a configuration of maximum compression in the lowered position of the stem 8.
In other words, the end stop structure 17 determines the maximum travel of the stem 8 within the containment body 2, whilst in prior art dispensers this function is performed by the spring 14 (as explained above), when it is not limited to the piston alone to avoid damaging it.
The end stop structure 17 is active on an end surface of the stem 8 (or of the second half-part 8b thereof), as shown in
In particular, the end stop structure 17 comprises at least one end stop element 18 that develops away from the bottom portion 4 of the containment body 2.
The end stop element 18 develops parallel to the axis of symmetry of the containment body 2, in such a way as to work with loads (transferred from the stem 8) directed parallel to its own development.
In this way, the force transmissible to the element 18 that works mainly with compression loads is maximized.
The end stop element 18 is fastened to the bottom portion 4 of the containment body 2 and it is preferably constructed in a single piece therewith.
The end stop element 18 develops within the third section 2c of the containment body 2 and it does not involve the dosing chamber 6.
In the preferred embodiment of the invention, the end stock structure 17 comprises three end stop elements 18 distanced from each other by 120°.
In particular, each end stop element 18 is substantially a prismatic, preferably right body.
Preferably, each end stop element 18 comprises a shoulder 19 to retain the ball in the bottom portion 4 of the containment body 2.
In particular, the shoulder 19 is obtained at one end of the end stop element 18 opposite to the end fastened to the containment body 2.
The shoulders 19 prevent the ball from entering into the dosing chamber 6, retaining it in the vicinity of the orifice 5 around which the end stop elements 18 develop.
In this way, a ready intervention of the ball 5a in the occlusion of the orifice 5 is assured.
It should be noted that the lower portion of the stem 8 is so shaped as to be able to be partially inserted into the end stop elements 18, in such a way as to remove the ball 5a from any blocking condition which may have occurred accidentally.
The invention achieves the proposed objects.
When the spout 9 is pressed, both during the mounting of the dispenser, and during its use, the compression force exercised is discharged through the stem 8 to the end stop structure 17 and hence to the containment body 2.
This assures that the retaining ring 12 is not overloaded with stresses to be transferred to the containment body 2, preserving the integrity and functionality of the retaining ring 12.
Moreover, the end stop structure 17, exercising a mechanical arrest to the travel of the stem 8, allows to use springs 14 which do not necessarily have to reach a configuration of maximum compression in the lowered position of the stem 8.
The invention also achieves an additional advantage.
The end stop structure 17 assures, if the stem is constituted by two half-parts, the completion of the coupling of the lower half-part on the upper half-part, if said fastening did not take place correctly or completely during the assembly of the piece.
| Number | Date | Country | Kind |
|---|---|---|---|
| RM2009A0152 | Apr 2009 | IT | national |
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/IT2010/000114 | 3/17/2010 | WO | 00 | 9/20/2011 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2010/113198 | 10/7/2010 | WO | A |
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| Number | Date | Country | |
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| 20120006854 A1 | Jan 2012 | US |
