EP2361850A1 - Metering device - Google Patents

Abstract

The dosing device (10) has a cylindrical body (14), whose inner space forms a hollow space for receiving the flowing material (12). The cylindrical body has an open end and opposite-lying outlet opening (18). A piston (20) has stoppers that are pressed in radial direction. The stoppers are arranged with an axial distance to each other.

Description

The invention relates to a metering device for dispensing defined doses of a flowable material.

Such a material may, for example, have a sticky consistency, i. automatically stick to a surface.

It is known to attach flowable materials, such as gels, by metering device on the inside of a toilet bowl and thus to achieve a cleaning or disinfection of the toilet.

EP 1 901 972 B1 describes such a dosing device, by which a defined amount of a flowable material can be applied to the inside of a toilet bowl. In the cited document, a cylindrical body for receiving the flowable material is described. Introducing into this body is a piston through which the flowable material is forced out of the cylindrical body. The piston and the cylindrical body are locked in different positions against each other, so that the piston can be pushed by a defined amount in the body. Connected to the piston is an outer sleeve which surrounds the cylindrical body. The locking elements are provided on the cylindrical body and the piston or the outer sleeve.

The device described in the cited document is well suited for dispensing flowable materials. However, it has a complex structure, since both the cylindrical body and the piston and the outer sleeve are elaborately constructed, so that it can be ensured that the piston can be pushed in each operating step only by a defined amount in the cylindrical body.

The object of the invention is to provide a metering device for dispensing defined doses of a flowable material, which has a simplified structure.

The object is achieved according to the invention by the features of claim 1.

The metering device according to the invention has a cylindrical body whose interior forms a cavity for receiving the flowable material. This flowable material may be, for example, a gel in the colloquial sense or another flowable material with high or low viscosity. It is essential that the flowable material is formed such that it does not automatically emerge from the metering device and also has a sticky consistency, so that it automatically adheres to the inside of a toilet bowl when applying. Furthermore, the material may have a viscosity such that it retains its shape after application, unless it is deformed by external influences.

According to the invention, the cylindrical body has a first open end and a dispensing opening opposite thereto. The cylindrical body may be formed, for example circular cylindrical, but may also have other cylindrical shapes,

The metering device further comprises a piston for axial insertion into the first open end of the cylindrical body. The insertion takes place such that the flowable material is displaced by the piston and pressed out of the discharge opening.

The metering device further includes the elements described below to ensure that the piston can be inserted by a defined amount in the cylindrical body during each operating step so that a defined dose of the flowable material is dispensed through the dispensing opening of the cylindrical body.

According to the invention, the piston has compressible stop elements. These are pressed in the radial direction of the piston and arranged with an axial distance from each other. The term "axial" here refers to the axial direction of the piston, which preferably coincides with the axial direction of the cylindrical body. The piston has substantially the same basic shape as the cylindrical body and also has a slightly reduced diameter, so that it touches the inside when inserted into the cylindrical body. The outer diameter of the piston thus substantially corresponds to the inner diameter of the cylindrical body.

The crushable stop elements are thus preferably arranged in the longitudinal direction of the piston.

According to the invention a stop member extends in the non-pressed state in the radial direction beyond the inner diameter of the cylindrical body and thus forms a stop for the edge of the cylindrical body surrounding the open end of the cylindrical body. This causes the piston is not inserted beyond this stop in the cylindrical body.

In the pressed-in state, a stop element does not extend beyond the inner diameter of the cylindrical body in the radial direction, so that the piston can be inserted beyond this stop element into the cylindrical body. An indented stop element thus forms no stop.

The metering device according to the invention has a particularly simple structure. This is made possible by the fact that the cylindrical body does not have to have devices which serve for a defined insertion of the piston into the cylindrical body. Only the piston itself has such devices due to the aforementioned stop elements. These stop elements cooperate with the edge of the cylindrical body which surrounds the open end of the cylindrical body, so that a defined insertion of the piston into the cylindrical body is possible with each operating step.

In a preferred embodiment, the stop elements are arranged in two rows one behind the other in the axial direction. The two rows preferably extend in the axial direction, ie in the longitudinal direction of the piston. Two successive stop elements in the axial direction are offset from each other in the circumferential direction of the piston. Their axial offset from each other is half the axial offset of two in a series of adjacent stop elements. In other words, two adjacent stop elements in a row have twice the axial offset, as two axially successive stop elements, which are in different rows. If one thus assumes a stop element in the first row, the next stop element in the axial direction is in the second row, whereupon the third stop element in the axial direction is again in the first row.

This means that at each operating step, i. upon each re-dispensing of a defined dose of the flowable material, an abutment member in another row is actuated. For example, when the first stopper member of the first row is actuated at the first dispensing of a defined dose, the first stopper member of the second row is actuated upon the second dispensing of a dose, whereupon the third stopper member of the first row is actuated upon the third dispensing of a dose, etc. It thus finds an alternating actuation of the stop elements in the two rows instead. This staggered placement of the stop members offers the advantage that the stop members may be of sufficient size to be conveniently operated by the fingers of a user, without at the same time causing too great an insertion of the piston into the cylindrical body Stop elements is introduced upon actuation of each stop element of the piston by a distance in the cylindrical body, which corresponds to half of the axial offset of two in a series of adjacent stop elements.

Alternatively to the arrangement of the stop elements in two rows, these can also be arranged in three or more rows, in which case the axial offset of two axially successive stop elements is a third, a quarter, etc. of the axial offset two in a series of adjacent stop elements.

By said staggered arrangement of the stop members, it is possible to use a piston and cylindrical body with a relatively large diameter, so that more flowable material is receivable therein.

Alternatively, the stop elements may also be arranged in a single row, so that after the actuation of each stop element of the piston to the axial length of a stop element in the cylindrical Body is inserted. The amount of flowable material, which is hereby forced out of the cylindrical body, is about twice as large as in an arrangement of the stop elements in two rows. In order to dispense with an arrangement of the stop elements in only one row, the same smaller amount of flowable material as in the arrangement of the stop elements in two rows, for example, the cylindrical body and the piston can be reduced in diameter.

Preferably, one side of each stop element is pivotally connected to the piston, the opposite side is pivotable about the side connected to the piston in the radial direction of the piston inwardly. That this opposite side can be pressed into the piston. The opposite side can for example be connected by one or two webs releasably connected to the piston. A releasable connection in this context means that these webs are cut when first pressing the stop element, so that the connection of the opposite side is released with the piston.

Furthermore, it is preferred that the stop elements have an L-shaped projection which extends in the radial direction of the stop elements to the outside. In this case, one leg of the L-shaped projection is arranged in each row of the stop elements in the direction of the other row of the stop elements. In other words, each stop element thus has a projection whose first leg is arranged in the direction of the other row of stop elements. The second leg of the L-shaped projection is arranged in the direction of the cylindrical body, The L-shaped projection serves to make it easier for the user to push in the stop elements without the user's thumb slipping off the stop elements -shaped projection serve as a stop at a non-depressed stop element for the edge of the cylindrical body.

The L-shaped projection is intended to prevent a stopper member from deforming itself by being pushed in by the piston into the cylindrical body without being operated by a user. By the L-shaped projection thus an automatic pushing in of a stop element can be prevented, which can occur when the piston is pushed into the cylindrical body. To prevent this, the L-shaped projection is formed such that it extends at a location of the stop element, for example, approximately in the middle of the stop element in the circumferential direction, in the radial direction jumped away from the stop element upwards.

By the first leg of the L-shaped projection, which is arranged in the direction of the other row of stop elements, it can be prevented that a depressed stop element automatically moves outwardly in the radial direction and thus prevents insertion of the piston into the cylindrical body.

It is further preferred that the cylindrical body has at least three spacers extending in the axial direction away from the cylindrical body beyond the dispensing opening. This creates a cavity in the axial direction between the distal end of the spacers, ie the end of the spacers facing away from the cylindrical body, and the dispensing opening. These spacers serve to be able to place the front end of the metering device on the inside of a toilet bowl, so that a distance in the axial direction from the inside of the Tailettenschtissel can be complied with the dispensing opening. In the resulting cavity, the flowable material can be output. It is thus ensured that when applying the flowable material no pressure is exerted by the metering device on the flowable material, so that it can be issued in a visually appealing form. By the spacers can further ensured be that the metering device and in particular the discharge opening is always positioned at a defined distance from the inside of the toilet bowl, while the flowable material is discharged.

Furthermore, it is preferred that the dispensing opening has in its center a round or polygonal, for example hexagonal, opening, with which a plurality of teardrop-shaped openings are connected in the radial direction outwards. Thus, in simplified terms, the dispensing opening has approximately the shape of a snowflake. As a result of the aforementioned embodiment of the dispensing opening, it can be achieved that the flowable material is dispensed in a visually appealing form. For example, the flowable material can give the impression of flowering.

Furthermore, it is preferred that the at least three spacers between the radial extension of each two drop-shaped recesses are arranged in particular along the circumference of the cylindrical body. This means that the at least three spacers are each arranged at a position of the cylindrical body, which lies between the imaginary radial extension of each two drop-shaped recesses. In this way, it can be ensured that a part of the flowable material can flow outwards in the radial direction during application between every two spacers, so that the diameter of the applied flowable material is not limited by the spacers and thus not by the diameter of the cylindrical body. Nevertheless, it is preferable that the flowable material does not contact the spacers when dispensed.

In the following, preferred embodiments of the invention will be explained with reference to figures.

Figur 1

eine Seitenansicht einer Ausführungsform der erfindungsgemäßen Dosiervorrichtung,

Figur 2

eine Darstellung der Ausgabeöffnung einer erfindungsgemäßen Dosiervorrichtung,

Figur 3

eine Frontansicht einer Ausführungsform des Kolbens der Dosiervorrichtung, und

Figur 4

eine beispielhafte Darstellung der Form, in der das fließfähige Material durch die Dosiervorrichtung ausgegeben werden kann.

Show it:

FIG. 1

a side view of an embodiment of the metering device according to the invention,

FIG. 2

a representation of the discharge opening of a metering device according to the invention,

FIG. 3

a front view of an embodiment of the piston of the metering device, and

FIG. 4

an exemplary representation of the form in which the flowable material can be output by the metering device.

FIG. 1 shows a side view of an embodiment of the metering device according to the invention. The piston 20 is inserted into the cylindrical body 14. Both piston 20 and cylindrical body 14 are formed circular cylindrical. The cylindrical body 14 has at its lower end a slightly widened edge 24, which cooperates to limit the insertion of the piston 20 into the cylindrical body 14 with the stop elements 22a to 221.

In FIG. 2 an embodiment of the discharge opening 18 of the cylindrical body 14 is shown in detail. The dispensing opening 18 has at its center a substantially hexagonal opening 18a, to which six drop-shaped openings 18b to 18g are connected in the radially outward direction. By such a discharge opening 18, the flowable material 12 can be output in a form, as shown for example in Figure 6.

According to FIG. 1 The cylindrical body 14 has three spacers 28a to 28c which extend at its front end in the axial direction away from the cylindrical body 14 beyond the discharge opening 18. When applying the flowable material, this can be between two The spacers 28a to 28c are thus in the application of the flowable material in the position shown in dashed lines in Figure 6 positions.

In the FIG. 3 Details of an embodiment of the piston 20 are shown. The piston has in this embodiment, 12 stopper members 22a to 221, wherein the first stop member 22a of the left rows in the axial direction is slightly larger than the other stop members 22b to 221. The stop members are in the order in which they are to be operated , labeled. For example, the first stop element 22a has the label "Start", while the other stop elements 22b to 221 are numbered from 2 to 12.

To increase the grip, the surface of the stop elements grooves 30. As a result, slippage of the thumb of an operator during actuation of the stop elements is prevented.

The stop elements further each have an L-shaped projection 26 which extends in the radial direction of the stop elements to the outside. A first leg 26a of the L-shaped projection is arranged in each row of the stop elements in the direction of the other row of stop elements. The second leg 26b is arranged in the direction of the cylindrical body 12, ie in the figures upwards. At the end of this second leg 26b is a projection 32 which extends in the direction of the cylindrical body 14. The part of the second leg 26b which extends from the L-shaped projection in the direction of the outer side 22b "may be formed such that it does not protrude in the radial direction with respect to the stop element 22b Leg 26a of the L-shaped protrusion 26 is a sudden elevation in the radial direction on the stop element present.Thus, an inadvertent, automatic pressing of the stop elements can be prevented, the same The effect is achieved by the projection 32, which represents the first point at which the edge 24 of the cylindrical body rests upon insertion of the piston 20.

The axial distance between two in a series of adjacent stop elements 22c, 22e is marked with 1.

The stop elements 22a to 221 are arranged in two rows, wherein the stop elements on its outer side 22b 'are pivotally or pivotally connected to the piston 20. On the opposite side 22b ", the stop elements 22a to 221 can be detachably connected to the piston 20 via two webs 34a, 34b.

Between the two rows of stop elements 22a to 221 extends in the axial direction of the piston 20, a central web 36th

FIG. 4 shows by way of example in which form the flowable material 12 can be output by the metering device 10 according to the invention. The flowable material in this case has six drop-shaped elevations 38a to 38f. When applying the flowable material 12 on the inside of a toilet bowl, the spacers 28a to 28c in the in FIG. 4 dashed lines shown positions.

Claims (7)

Dosing device for dispensing defined doses of a flowable material (12),
with a cylindrical body (14), the interior of which forms a cavity for receiving the flowable material (12),
the cylindrical body (14) having a first open end (16) and an output port (18) opposite thereto,
the metering device (10) further comprising: a piston (20) for axially inserting into the first open end (16) of the cylindrical body (14) such that the flowable material (12) is displaced by and out of the piston (20) Discharge opening (18) is pressed,
characterized in that
the piston (20) has stop elements (22a to 221) which can be pressed in the radial direction and which are arranged at an axial distance from one another,
wherein a stop element (22a) extends in the non-depressed state in the radial direction beyond the inner diameter (i) of the cylindrical body (14) and so a stop for the edge (24) of the cylindrical body (14), the open end ( 16), forms such that the piston (20) can not be inserted beyond this stop into the cylindrical body (14),
and a stop element (22a) in the pressed-in state does not extend beyond the inner diameter (i) of the cylindrical body (14) in the radial direction so that the piston (10) passes over it Stop element (22 a) out into the cylindrical body (14) is insertable. Dosing device according to claim 1, characterized in that the stop elements (22a to 221) are arranged in two rows one behind the other in the axial direction and two axially successive stop elements (22b, 22c) in the circumferential direction (u) of the piston (20) to each other are arranged offset and their axial offset from one another half of the axial offset of two adjacent series stop elements (22b, 22d). Dosing device according to claim 1 or 2, characterized in that one side (22a 'to 221') of each stop element (22a to 221) is pivotally connected to the piston (20) and the opposite side (22a "to 221") to the with the piston (20) connected side (22a 'to 221') in the radial direction is inwardly pivotable, in particular the opposite side (22a "to 221") is releasably connected to the piston (20). Dosing device according to claim 2, characterized in that the stop elements (22a to 221) have an L-shaped projection (26) which extends in the radial direction of the stop elements (22a to 221) to the outside, wherein a first leg (26a) the L-shaped projection (26) is arranged in each row of the stop elements in the direction of the other row of stop elements and a second leg (26b) of the L-shaped projection (26) is arranged in the direction of the cylindrical body (12). Dosing device according to one of claims 1 to 4, characterized in that the cylindrical body (14) at least three spacers (28a to 28c) extending in the axial direction of the cylindrical body (14) away beyond the discharge opening (18) extend so that a cavity in the axial direction between the distal end of the spacers (28 a to 28 c) and the discharge opening (18) is formed. Dosing device according to one of claims 1 to 5, characterized in that the discharge opening (18) has in its center a round or polygonal opening (18a), with the radially outwardly a plurality of teardrop-shaped openings (18b to 18g) are connected. Dosing device according to claim 5 and 6, characterized in that the at least three spacers (28a to 28c) are arranged between the radial extension of two respective drop-shaped recesses (18b to 18g), in particular along the circumference of the cylindrical body (14),

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