DISCHARGING DEVICE

Abstract

A dispensing apparatus for a flowable component includes a storage container having a storage chamber for the reception of the component, a filling opening and a dispensing opening. A piston is displaceably arranged within the storage container in the direction of an expulsion direction. Moreover, dispensing apparatus includes an actuation element by which the piston can be displaced stepwise in the direction of the dispensing opening. After release of the actuation element actuation element is displaced from a final position into a starting position by a spring.

Claims

1. A dispensing apparatus for a flowable component, comprising: a storage container having a storage chamber for the reception of the component, a filling opening and a dispensing opening; a piston arranged so as to be displaceable in the direction of an expulsion direction within the storage container and being configured to expel the component from the storage chamber via the dispensing opening; an actuation element configured to displace the piston stepwise in a direction of the dispensing opening; and a spring configured to act on the actuation element, the actuation element and the piston being configured and arranged such that, on displacement of the actuation element from a starting position into a final position, the piston is displaced by one step in the direction of the dispensing opening, the actuation element being configured to be displaced by the spring from the final position into the starting position, the actuation element being arranged at the filling opening and the displacement of the actuation element is in the expulsion direction, and the piston having a piston base terminating the storage chamber in the direction of the filling opening and being made from a different material than a piston jacket.

2. A dispensing apparatus in accordance with claim 1, wherein the piston has at least two feed surfaces spaced apart in the expulsion direction, and the actuation element has at least one actuation surface, the feed surfaces and the actuation surface are configured and arranged such that, on a displacement of the actuation element from the starting position into the final position, a force is transmitted in the direction of the dispensing opening onto the piston via the actuation surface and the feed surface.

3. A dispensing apparatus in accordance with claim 2, wherein the actuation element has an actuation arm oriented in the direction of the dispensing opening and which has the actuation surface.

4. A dispensing apparatus in accordance with claim 3, wherein the actuation arm is flexibly transverse to the expulsion direction (16) and has a guiding surface configured to cooperate with a repelling surface of the piston such that the actuation arm is bent on displacement from the final position into the starting position transverse to the expulsion direction and relative movement is enabled between the piston and the actuation element.

5. A dispensing apparatus in accordance with claim 3, wherein the piston has an inner piston space open in the direction of the filling opening the inner piston space is bounded transverse to the expulsion direction by a piston jacket, wherein the feed surfaces are formed in the piston jacket, and the actuation arm projects into the inner piston space.

6. A dispensing apparatus in accordance with claim 5, wherein the piston jacket has a recess having a feed surface.

7. A dispensing apparatus in accordance with claim 6, wherein the piston jacket has two diametrically oppositely disposed recesses, each having a feed surface.

8. A dispensing apparatus in accordance with claim 1, wherein the piston has a surrounding sealing element lying at an inner wall of the storage chamber.

9. (canceled)

10. A dispensing apparatus in accordance with claim 1, wherein the piston is a one piece design.

11. A dispensing apparatus for a flowable component, comprising: a storage container having a storage chamber for the reception of the component, a filling opening and a dispensing opening; a piston arranged so as to be displaceable in the direction of an expulsion direction within the storage container and being configured to expel the component from the storage chamber via the dispensing opening; an actuation element configured to displace the piston stepwise in a direction of the dispensing opening; and a spring configured to act on the actuation element, the actuation element and the piston being configured and arranged such that, on displacement of the actuation element from a starting position into a final position, the piston is displaced by one step in the direction of the dispensing opening, the actuation element being configured to be displaced by the spring from the final position into the starting position, the actuation element being arranged at the filling opening and the displacement of the actuation element is in the expulsion direction, and the storage chamber and the spring being a one piece design.

12. A dispensing apparatus in accordance with claim 11, wherein the storage container and the spring are made of different materials.

13. A dispensing apparatus in accordance with claim 1, wherein the actuation element is arranged such so as to close the filling opening of the storage container.

14. A dispensing apparatus in accordance with claim 13, wherein the actuation element has a groove in which a bulge of the storage container is arranged.

15. A dispensing apparatus in accordance with claim 14, wherein in the final position of the actuation element, the bulge lies at an end flange of the groove oriented in the direction of the dispensing opening.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0034] In this connection there is shown:

[0035] FIG. 1 is a sectional illustration of a dispensing apparatus having an actuation element in a starting position;

[0036] FIG. 2 is the dispensing apparatus of FIG. 1 having the actuation element in a final position;

[0037] FIG. 3 is the dispensing apparatus of FIG. 1 and FIG. 2 having the actuation element reset again in the starting position; and

[0038] FIG. 4 is a piston of a dispensing apparatus in a second embodiment.

DETAILED DESCRIPTION OF EMBODIMENTS

[0039] In accordance with the FIGS. 1, 2 and 3 a dispensing apparatus 10 for a flowable component includes a storage container 11. The storage container 11 has a storage chamber 12 for a flowable component. The storage container 11 has a filling opening 13 and a dispensing opening 14 at its opposite end which dispensing opening can be closed by a removable cover 15. The component can be filled via the filling opening 13 into the storage chamber 12 and after removal of the cover 15 can be dispensed via the dispensing opening 14.

[0040] The storage chamber 12 sectionally has a hollow cylindrical inner contour, wherein the storage chamber 12 tapers in the direction of the dispensing opening 14 and expands in the direction of the filling opening 13.

[0041] A piston 17 is arranged displaceable along an expulsion direction 16 within the storage container 11. The piston 17 has a piston base 18 which terminates the storage chamber 12 in the direction of the filling opening 13. The piston base 18 has an outer contour extending in the expulsion direction 16 which outer contour corresponds to the inner contour of the storage chamber 12 extending in the expulsion direction 16 in the region of the dispensing opening 14. A sealing element in the form of an O-ring 20 is arranged at the piston base 18 such that it lies around at an inner wall 21 of the storage chamber 12 in a ring-like manner and so seals the piston base 18 with respect to the inner wall 21 of the storage chamber 12.

[0042] Moreover, the piston 17 has a piston jacket 19 which adjoins at the piston base 18 in the direction of the filling opening 13. The piston 17 is configured as an injection molded part and in this way is of one piece design. The piston jacket 19 generally has a tubular basic shape and in this way has an inner piston space 22 open in the direction of the filling opening 13. The piston jacket 19 has a total of six pairs of recesses, wherein for reasons of clarity only four recesses 23a, 23b; 24a, 24b of a second and third pair are provided with reference numerals. The recesses 23a, 23b of the second pair are arranged at the same axial position and diametrically lying opposite. The recesses 24a, 24b of the third pair are arranged in the direction of the circumference at the same positions, however, are displaced in the direction of the filling opening 13. The recesses 23a, 23b, 24a, 24b of the piston jacket 19 have feed surfaces 25a, 25b, 26a, 26b oriented in the direction of the dispensing opening 14 which feed surfaces are aligned perpendicular to the expulsion direction 16.

[0043] The feed surfaces 25a, 25b, 26a, 26b can cooperate with a first actuation surface 27a and a second actuation surface 27b of an actuation element 28. The actuation element 28 is arranged at the filing opening 13. It has a first actuation arm 29a and a second actuation arm 29b which project into the inner piston space 22 of the piston jacket 19 and each are flexible transverse with respect to the expulsion direction 16. The first and second actuation surface 27a, 27b respectively form the terminal of the first and second actuation arm 29a, 29b in the direction of the dispensing opening 14 and are likewise arranged substantially perpendicular with respect to the expulsion direction 16. The actuation arms 29a, 29b are configured and arranged at the filling opening 13 such that the ends oriented in the direction of the dispensing opening 14 which ends, having the actuation surfaces 27a, 27b, can project into the recesses 23a, 23b, 24a, 24b of the piston jacket 19. In this way, a force can be transmitted onto the feed surfaces 25a, 25b, 26a, 26b and in this way onto the piston 17 in the direction of the dispensing opening 14 via the actuation element 28, the actuation arms 29a, 29b and the actuation surfaces 27a, 27b. The force is applied by a user by displacing the actuation element 28 in the direction of the dispensing opening 14. The said force can be applied, in particular with the thumb of the hand. For supporting the force and fixing the dispensing apparatus 10 the storage container 11 has an outwardly oriented grip element 30. The grip element 30 is configured such that it can be supported, in particular at the trigger finger and the middle finger of the hand.

[0044] The actuation element 28 has a cap 31 besides the actuation arms 29a, 29b which cap has a substantially beaker-like basic shape. The cap 31 and in this way the actuation elements 28 are plugged onto the storage container 11 such that the cap 31 and the storage container 11 overlap. In this manner the actuation element 28 closes the filling opening 13 of the storage container 11. The cap 31 and in this way the actuation element 28 have a surrounding groove 32 at its inner side, in which a bulge in the form of a surrounding collar 32 of the storage container 11 is arranged. The groove 32 and the collar 33 are arranged such that the actuation element 28 can be displaced with respect to the storage container 11 and the collar 32 still remains in the groove 32. The actuation element 28 can be displaced with respect to the storage container 11 between a starting position illustrated in the FIGS. 1 and 3, in which the collar 33 contacts at an exit flange 34 oriented in the direction of the filling opening 13, and a final position illustrated in FIG. 2, in which the collar 33 contacts at an end flange 35 oriented in the direction of the dispensing opening 14.

[0045] A spring 36 adjoins at the storage container 11 at the filling opening 13 which can apply a force against the expulsion direction 16. The spring 36 is configured as a coil spring and is of one piece design with the storage container 11. The storage container 11 and the spring 36 are configured as a so-called two-component injection molded part, wherein the storage container 11 is made of polypropylene and the spring 36 is made of polyamide. Furthermore, also other types of material are possible.

[0046] The spring 36 is biased in the assembled state of the dispensing apparatus such that it exerts a force onto the actuation element 28 which force is oriented opposite to the expulsion direction 16, this means it presses the actuation element 28 in the direction of the starting position. The spring 36 is moreover configured such that it also exerts a force onto the actuation element 28 in the starting position and thereby fixes the actuation element 28 in the starting position.

[0047] The design of the recesses 23a, 23b, 24a, 24b in the piston jacket 19 and of the actuation arms 29a, 29b of the actuation element 28 enable a stepwise dispensing of the component via the dispensing opening 14 from the storage chamber 12. This will be described in the following by means of the differences shown in the FIGS. 1, 2 and 3 in more detail.

[0048] In FIG. 1 the actuation element 28 is present in the starting position and the actuation arms 29a, 29b dive into the second pair of recesses 23a, 23b such that the actuation surfaces 27a, 27b of the actuation arms 29a, 29b are positioned such that they can cooperate with the feed surface 25a, 25b of the recesses 23a, 23b. From the fact that the actuation arms 29a, 29b dive into the second pair of recesses 23a, 23b and not into the first pair of recesses it is clear that the piston 17 is already displaced by a step in the direction of the dispensing opening 14 and thereby already a defined amount of the component has been dispensed on the storage chamber 12.

[0049] Starting from the illustration of FIG. 1, if a further defined amount of the component should now be dispensed, then the cover 15 is initially removed and then the actuation element 28 is impinged with a pressure in the direction of the dispensing opening 14 and in this manner is pushed against the force of the spring 36 with respect to the storage container 11. The said displacement is symbolized in FIG. 2 by the arrows 37a, 37b. In this manner a force is transmitted onto the feed surface 25a, 25b and in this way onto the piston 17 in the direction of the dispensing opening 14 and the piston is displaced in the direction of the dispensing opening 14 which force is applied via the actuation element 28, the actuation arms 29a, 29b and the actuation surfaces 27a, 27b. Through the said displacement of the piston 17 a part of the component is dispensed via the dispensing opening 14. The actuation element 28 can be displaced so far until it arrives in the final position illustrated in FIG. 2, this means that the collar 33 of the storage container 11 abuts at the end flange 35 of the groove 32 of the actuation element 28 and a further displacement of the actuation element and in this way of the piston 17 is made impossible.

[0050] If now starting from the illustrated final position of the actuation element 28 illustrated in FIG. 2 a force is no longer applied in the direction of the dispensing opening 14 and in this way set free then it is pressed back again in the direction of the starting position by the spring force of the spring 36 this means it is pushed away from the dispensing opening 14. For enabling a further dispensing of the components, however, the piston 17 should remain in the achieved position such that a decoupling of the actuation element 28 and of the piston 17 becomes necessary. This decoupling is achieved by a cooperation between guiding surfaces 38a, 38b of the actuation arms 29a, 29b and repelling surfaces 39a, 39b of the piston jacket 19 and in this way of the piston 17. The guiding surfaces 38a, 38b adjoin at the actuation surfaces 27a, 27b and are inclined such that they have a smaller spacing with respect to the inner wall 21 of the storage chamber 12 at their end in the direction of the actuation surfaces 27a, 27b than at their opposite end. The repelling surfaces 39a, 39b are configured as edges of the recesses 23a, 23b extending perpendicular to the expulsion direction 16 in the direction of the filling opening 13. As soon as the actuation element 28 is released, the actuation element 28 is impinged by a force as described by the spring 36 in the direction of the starting position. Through the cooperation of repelling surfaces 39a, 39b of the piston 17 and the guiding surfaces 38a, 38b the actuation arms 29a, 29b are bent inwardly, this means away from the inner wall 21 of the storage chamber 12 so far that the actuation arms 29a, 29b can glide past at the piston 17. In this manner, a relative movement between the piston 17 and the actuation element 28 is possible such that the piston 17 remains standing and the actuation element 28 is again displaced backwards into the starting position. The then achieved starting position of the actuation element 28 is illustrated in FIG. 3. This differs from the position illustrated in FIG. 1 only thereby that the actuation arms 29a, 29b now dive into the third pair of recesses 24a, 24b. Starting from this starting position a further defined amount of the component can be dispensed by repeating the described sequence.

[0051] Due to the six pairs of recesses in the piston jacket 19 the piston 17 can be displaced in six steps in the direction of the dispensing opening 14, whereby a total of six defined amounts of the component can be dispensed.

[0052] In this manner, the piston 17 is likewise not displaced on pushing back the actuation element 28, a sufficiently high friction is required between the piston 17 and the inner wall 21 of the storage chamber 12. For the dispensing apparatus 10 in accordance with the FIGS. 1, 2 and 3 the said friction is ensured by the sealing element in the form of an O-ring 20.

[0053] However, it is also possible that the piston base is configured such that it has a sufficiently high friction with respect to the inner wall of the storage chamber without an additional sealing element.

[0054] Such an embodiment of a piston 117 is illustrated in FIG. 4. The piston 117 is generally of equal design to the piston 17 of FIGS. 1, 2 and 3 which is why reference is only made to the differences of the two pistons 17, 117.

[0055] The piston 117 is configured as a two-component injection molded part. A piston base 118 is made from a different softer material than a piston jacket 119. The piston base 118 is, for example, manufactured from a thermoplastic elastomer (abbreviation TPE) and the piston jacket 119 is, for example, made of polypropylene (abbreviation PP) or polyamide (abbreviation PA). The piston base 118 has an outer contour which corresponds to the inner contour of the storage chamber such that no additional sealing element is required.