RU2604485C2 - Metering device - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to metering device for dispensing defined doses of flowable material (12), with cylindrical body (14), interior of which forms a cavity for receiving flowable material (12), wherein cylindrical body (14) has first open end (16) and opposite thereto discharge opening (18). Metering device (10) further comprises piston (20) for axial insertion into first open end (16) of cylindrical body (14) such that flowable material (12) displaced by piston (20) and from output port (18) is pressed. Piston (20) in radial direction is configured to press stop elements (22a-221) arranged with an axial distance from one another, wherein stop element (22a) in non-depressed condition extends in radial direction beyond inner diameter (i) of cylindrical body (14) also extends, and forms a stop for edge (24) of cylindrical body (14), surrounding its open end (16) in such a way that piston (20) in this stop position in cylindrical body (14) is insertable, and stop member (22a) in pushed-in state in radial direction does not extend beyond inner diameter (i) of cylindrical body (14), so that piston (10) via this stopper member (22a) out into cylindrical body (14) can be introduced.

EFFECT: metering device according to invention has simple design and ensures complete dispensing of fluid material.

1 cl, 6 cl, 4 dwg

Description

The invention relates to a metering device for issuing predetermined doses of a fluid material.

Such a material may have, for example, an adhesive substance, that is, spontaneously adhere to the surface.

It is known to apply flowable materials, for example gels, by means of a metering device to the inside of the toilet bowl and thereby clean or disinfect the toilet.

EP 1901972 B1 describes a similar metering device by which a predetermined amount of flowing material can be applied to the inside of a toilet bowl. This document describes a cylindrical body for accommodating a fluid material. A piston may be introduced into this body, through which fluid material is squeezed out of the cylindrical body. The piston and the cylindrical body can be fixed in different positions relative to each other, so that the piston can slide into the body by a predetermined size. An outer sleeve is connected to the piston, which surrounds the cylindrical body. The latches are provided on the cylindrical body and on the piston or outer sleeve.

The device described in this document is well suited for dispensing fluid materials. However, it has a complex structure, since both the cylindrical body and the piston and the outer sleeve have an expensive structure, so that it can be ensured that the piston at each control step can be inserted into the cylindrical body only by a predetermined size.

The objective of the invention is to develop a metering device for issuing predetermined doses of a fluid material, which has a simplified design and ensures the completeness of a fluid material.

According to the invention, the problem is solved by the features of paragraph 1 of the claims.

The proposed metering device has a cylindrical body, the inner space of which forms a hollow space for accommodating a fluid material. This fluid material can be, for example, a gel in the colloquial sense of the word or other fluid material with a higher or lower viscosity. It is essential that the flowing material is designed in such a way that it does not spontaneously leave the metering device and, moreover, has a sticky consistency, so that when applied it spontaneously holds on the inside of the toilet bowl. In addition, the material may have such a viscosity that after application, it retains its shape if it is not deformed under external influences.

According to the invention, the cylindrical-shaped body has a first open end and a dispensing opening located opposite it. The body of the cylindrical shape may be, for example, in the form of a circular cylinder, but may also have other cylinder shapes.

In addition, the metering device has a piston for axial insertion into the first open end of the cylindrical body. The introduction is performed in such a way that the fluid material is displaced by the piston and squeezed out of the dispensing opening.

In addition, the metering device has the elements described below to ensure that the piston at each control step can be introduced into the cylindrical body by a predetermined size, so that a predetermined dose of fluid material is delivered through the dispensing opening in the cylindrical body.

According to the invention, the piston has thrust-resistant elements. They can be pressed in the radial direction of the piston and are located at an axial distance relative to each other. The concept of “axial” refers to the axial direction of the piston, which, in a preferred manner, coincides with the axial direction of the body of a cylindrical shape. The piston has essentially the same basic shape as the cylindrical body and, in addition, has a slightly smaller diameter so that when inserted into the cylindrical body, it touches its inside. Thus, the outer diameter of the piston essentially corresponds to the inner diameter of the cylindrical body.

Thus, the thrust elements made with the possibility of indentation are preferably arranged in the longitudinal direction of the piston.

According to the invention, the stop element in the non-depressed state extends radially beyond the inner diameter of the cylindrical body and thereby forms a stop for the edge of the cylindrical body that surrounds the open end of the cylindrical body. This causes the piston to be irreducible into the cylindrical body beyond this stop.

In the depressed state, the thrust element in the radial direction does not extend beyond the inner diameter of the cylindrical body, so that the piston is introduced further than this thrust element into the cylindrical body. Thus, the pressed-in thrust element does not form a stop.

In addition, the cylindrical body has at least three spacers that extend axially from the cylindrical body beyond the dispensing opening. Due to this, there is a hollow space in the axial direction between the distal end of the spacers, that is, the end of the spacers, which is directed from the cylindrical body, and the hole for issuing. These spacers serve to lower the front end of the dispensing device onto the inside of the toilet bowl, so that the distance in the axial direction from the inside of the toilet to the dispensing opening can be observed. In the resulting hollow space, fluid material can be dispensed. Due to this, it is ensured that when applying the fluid material, the metering device does not exert pressure on the fluid material, so that it can be issued in a visually attractive form. In addition, due to the spacers, it can be ensured that the dispensing device and, above all, the dispensing opening are always placed at a predetermined distance from the inside of the toilet bowl during dispensing of the flowing material.

The invention allows for the issuance of a fluid material, in particular a gel, to pass parts of the fluid material in the radial direction between two adjacent spacers. Thus, the individual spacers provided by the invention do not limit the amount of applied fluid material in the radial direction.

The proposed metering device has a particularly simple design. This is due to the fact that the cylindrical body should not have devices that serve for a given introduction of the piston into the cylindrical body. Only the piston itself has similar devices in the form of said thrust elements. These thrust elements interact with the edge of the cylindrical body, which surrounds the open end of the cylindrical body, so that at each control step a predetermined introduction of the piston into the cylindrical body is possible.

In one preferred embodiment, the stop elements are arranged in two rows, respectively, in the axial direction, one after the other. Preferably, the two rows extend in the axial direction, i.e. in the longitudinal direction of the piston. Two axial thrust members following each other in the axial direction are displaced relative to each other along the circumference of the piston. Their axial displacement relative to each other is half the axial displacement of two thrust elements adjacent to each other in the same row. In other words, two thrust elements adjacent to each other in the same row have double axial displacement in comparison with two axial thrust elements that are next to each other in axial direction, which are in different rows. Thus, if we proceed from one stop element in the first row, then the next stop element in the axial direction is in the second row, after which the third stop element in the axial direction is again in the first row.

This means that with each control step, that is, with each repeated delivery of a predetermined dose of a fluid material, a stop element in a different row is activated. For example, if the first stop element of the first row is actuated during the first dispensing of a given dose, then the second stop element of the second row is actuated in the second dose dispensing, after which the second stop element of the first row and the like are actuated in the third dose dispensing. Thereby, the thrust elements are alternately actuated in both rows. Such a displaced arrangement of the stop elements provides the advantage that the stop elements can be of sufficient size to be conveniently actuated by the fingers of the user without simultaneously causing the piston to be inserted too much into the cylindrical body. Due to the indicated embodiment of the thrust elements, when each thrust element is actuated, the piston is introduced into the cylindrical body into a section that corresponds to half the axial displacement of two thrust elements located adjacent to each other in the same row.

As an alternative to arranging the stop elements in two rows, they can also be arranged in three or more rows, while the axial displacement of the two stop elements located one after the other in the axial direction in this case is one third, one quarter, etc. axial displacement of two adjacent in the same row of thrust elements.

Due to the indicated displaced arrangement of the thrust elements, a piston and a cylindrical body with a relatively large diameter can be used, so that more fluid material can be placed in it.

Alternatively, the thrust elements can also be arranged in one single row, so that after actuating each thrust element, the piston is introduced into the cylindrical body by the axial length of the thrust element. The amount of fluid material that is squeezed out of the cylindrical body is approximately two times greater than when the thrust elements are arranged in two rows. In order to squeeze the same small amount of flowing material when the thrust elements are arranged in only one row, as when the thrust elements are arranged in two rows, it is possible, for example, to reduce the diameter of the cylindrical body and piston.

Preferably, one side of each thrust member is rotatably connected to the piston. The opposite side is rotatable inwardly around the side connected to the piston in the radial direction of the piston. That is, this opposite side can be pressed into the piston. The opposite side can be detachably connected to the piston, for example, by means of one or two jumpers. The disconnectable connection in this regard means that these jumpers are disconnected when the thrust element is first pressed in, so that the connection of the opposite side with the piston is disconnected.

In addition, it is preferable that the thrust members have an L-shaped protrusion that extends radially outward from the thrust members. In this case, the shoulder of the L-shaped protrusion in each row of thrust elements is located in the direction of another row of thrust elements. In other words, thereby each stop element has a protrusion, the first shoulder of which is located in the direction of another row of stop elements. The second shoulder of the L-shaped protrusion is located in the direction of the cylindrical body. The L-shaped protrusion serves to make it easier for the user to press the stop elements and the user's thumb does not slide off the stop elements. At the same time, the L-shaped protrusion can serve as a stop with a non-pressed stop element for the edge of the body of a cylindrical shape.

The L-shaped protrusion should prevent spontaneous deformation of the thrust element due to the piston being pressed into the cylindrical body without being actuated by the user. Thus, due to the L-shaped protrusion, spontaneous indentation of the thrust element, which can occur when the piston is pressed into the cylindrical body, can be prevented. To prevent this, the L-shaped protrusion is designed so that it in one place of the thrust element, for example, approximately in the center of the thrust element, when viewed in the direction of the circle, radially extends spasmodically from the thrust element upward.

Due to the first shoulder of the L-shaped protrusion, which is located in the direction of another row of thrust elements, it is possible to prevent that the pressed-in thrust element again spontaneously moves outward in the radial direction and thereby prevents the piston from entering the cylindrical body.

In addition, it is preferable that the dispensing opening has in its center a circular opening or a polygon-shaped opening, for example a hexagonal opening, to which several drop-shaped openings are connected radially outwardly. Thus, the opening for issuing has approximately, more simply, the shape of a snowflake. Due to this embodiment of the dispensing opening, it is possible to achieve that the fluid material is dispensed in a visually attractive shape. The flowing material may, for example, give the impression of a flower.

In addition, it is preferable that at least three spacers between the radial elongation from the respectively two drop-shaped recesses are located primarily along the circumference of the cylindrical body. This means that at least three spacers are located respectively in one place of the cylindrical body, which is located between the mental radial extension of the respectively two made in the form of a drop indentations. Due to this, it can be ensured that one part of the flowable material during application can flow between two spacers respectively, radially outward, so that the diameter of the applied flowable material is not limited to the spacers and thereby the diameter of the cylindrical body. However, it is preferred that the flowable material during dispensing does not touch the spacers.

Next, preferred forms of carrying out the invention are described by the example of the drawings.

The drawings show:

FIG. 1 is a side view of one embodiment of the proposed dispensing device,

FIG. 2 - image of the hole for issuing the proposed dosing device,

FIG. 3 is a front view of one embodiment of a piston of a metering device,

FIG. 4 is an exemplary depiction of a form in which fluid material can be dispensed through a metering device.

In FIG. 1 shows a side view of one embodiment of the proposed dispensing device. The piston 20 is introduced into the cylindrical body 14. Both the piston 20 and the cylindrical body 14 are made in the shape of a round cylinder. The cylindrical body 14 has at its lower end a slightly widened edge 24, which, to limit the introduction of the piston 20 into the cylindrical body 14, interacts with the abutment elements 22a-22l.

In FIG. 2 shows in detail one embodiment of the dispensing hole 18 in the cylindrical body 14. The dispensing hole 18 has at its center a substantially hexagonal hole 18a with which six drop-shaped holes 18b-18g are connected in a radially outward direction. Through a similar dispensing hole 18, fluid material 12 can be dispensed in the form that is shown by way of example in FIG. four.

According to FIG. 1, the cylindrical body 14 has three spacers 28a-28c, which at its front end in the axial direction extend outward from the cylindrical body 14 beyond the opening 18 for delivery. When applying a fluid material, it can extend radially outward between two adjacent spacers. Thus, the spacers 28a-28c when applying the fluid material are in the positions shown in FIG. 4 with a dashed line.

In FIG. 3 shows details of one embodiment of the piston 20. In this embodiment, the piston has 12 thrust elements 22a-22l, with the first axial direction of the left rows 22a of the left rows being slightly larger than the remaining thrust elements 22b-22l. The thrust elements are signed in the order in which they should be actuated. For example, the first stop element 22a has the signature "Start", while the remaining stop elements 22b-22l are numbered from 2 to 12.

To increase the roughness, the surface of the stop elements has corrugations 30. This prevents the user's finger from slipping when the stop elements are actuated.

In addition, it is preferable if the abutment elements have an L-shaped protrusion 26, which extends radially outward from the abutment elements. The first shoulder 26a of the L-shaped protrusion in each row of thrust elements is located in the direction of the other row of thrust elements. The second shoulder 26b is located in the direction of the cylindrical body 12, that is, in the drawings up. At the end of the second shoulder 26b there is a protrusion 32, which extends in the direction of the cylindrical body 14. A part of the second shoulder 26b, which extends from the L-shaped protrusion in the direction of the outer side 22b ″, can be made so that in the radial direction it does not protrude thrust member 22b. Thus, in the region of the protrusion 32 due to the first shoulder 26a of the L-shaped protrusion 26 on the thrust element there is an abrupt rise in the radial direction. Due to this, you can prevent accidental, spontaneous indentation of the thrust elements. The same effect is achieved due to the protrusion 32, which is the first place to which the edge 24 of the cylindrical body adjoins with the introduction of the piston 20.

The axial distance between two thrust elements 22c, 22e located side by side in the same row is marked with the letter l.

The stop elements 22a-22l are arranged in two rows, while the stop elements on their outer side 22b ′ are pivotally or pivotally connected to the piston 20. On the opposite side 22b, the stop elements 22a-22l can be detachably connected to the piston 20 by means of jumpers 34a, 34b .

Between the two rows of thrust elements 22a-22l in the axial direction of the piston 20 extends a Central jumper 36.

In FIG. 4 illustrates, by way of example, in what form the fluid material 12 can be dispensed through the metering device 10 according to the invention. In this case, the fluid material has six droplet-shaped elevations 38a-38f. When applying the fluid material 12 to the inside of the toilet bowl, the spacers 28a-28c fit in the positions shown in FIG. 4 with a dashed line.

Claims (6)

1. A metering device for dispensing predetermined doses of a fluid material (12) with a cylindrical body (14), the inner space of which forms a hollow space for accommodating the fluid material (12), while the cylindrical body (14) has a first open end (16) and an opposite opening (18) for dispensing,
wherein the metering device (10) also has a piston (20) for axially introducing into the first open end (16) of the cylindrical body (14) so that the fluid material (12) is displaced by the piston (20) and extruded from the hole (18) for extradition
however, the metering device (10) also has elements to ensure that the piston (20) at each control step can be introduced into the cylindrical body (14) by a predetermined size, so that through the hole (18) to issue the cylindrical body (14) a predetermined dose of fluid material (12) is issued,
characterized in that the piston (20) has thrust elements (22a-22l) arranged with the possibility of indentation in the radial direction, which are located at an axial distance relative to each other,
in this case, the stop element (22a) in the non-depressed state extends radially beyond the inner diameter (i) of the cylindrical body (14) and thus forms a stop for the edge (24) of the cylindrical body (14), which surrounds its open end (16) with in such a way that the piston (20) is then not further inserted into the cylindrical body (14), and in the depressed state, the stop element (22a) does not radially extend beyond the inner diameter (i) of the cylindrical body (14), so that the piston (10 ) is further introduced by this thrust element that (22a) into a cylindrical body (14),
wherein the cylindrical body (14) has at least three spacers (28a-28c) that extend axially from the cylindrical body (14) beyond the opening (18) so that in the axial direction between the distal end of the spacers (28- 28c) and a hollow space is formed for the dispensing opening (18). 2. A metering device according to claim 1, characterized in that the stop elements (22a-22l) are arranged in two rows, one after the other, in the axial direction, and the two stop elements following each other in the axial direction (22b, 22c) are arranged with displacement relative to each other in the direction of the circumference of the piston (20) and their axial displacement relative to each other is half the axial displacement of two stop elements located next to each other in the same row (22b, 22d). 3. Dosing device according to claim 1, characterized in that one side (22a′-22l ′) of each thrust element (22a-22l) is rotatably connected to the piston (20), and the opposite side (22a ″ -22l ″) made with the possibility of turning inward in the radial direction around the side connected to the piston (20) (22a′-22l ′), while, first of all, the opposite side (22a ″ -22l ″) is detachably connected to the piston (20). 4. A dosing device according to claim 2, characterized in that the stop elements (22a-22l) have an L-shaped protrusion (26), which extends radially outward from the stop elements (22a-22l), with the first shoulder (26a ) The L-shaped protrusion (26) is located in each row of thrust elements in the direction of the other row of thrust elements, and the second shoulder (26b) of the L-shaped protrusion (26) is located in the direction of the cylindrical body (12). 5. A dispensing device according to claim 1, characterized in that the dispensing hole (18) in its center has a round or polygonal hole (18a) with which several drop-shaped holes (18b-18g) are connected in a radial outward direction . 6. A dispensing device according to claim 5, characterized in that at least three spacers (28a-28c) are located between the radial extension of the respective two drop-shaped recesses (18b-18g), primarily along the circumference of the cylindrical body (14) .

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