AT395356B - DOSING DEVICE FOR LIQUIDS - Google Patents

Description

AT 395 356 B

The invention relates to a metering device for liquids.

For this purpose, a metering device is desirable which can be introduced into the neck of a bottle containing liquid or better forms part of the packaging, for example consisting of one piece with the bottle cap. 5 From DE-PS12 02 672 a dosing device that can be introduced into the neck of a bottle is known

Dosing space which is filled when the bottle is inverted and has a collecting space which is fed by the dosing space when the bottle is returned to its normal position and which communicates with the outlet opening of the bottle. The dosing and the collecting room have axes parallel to the bottle axis and are separated from each other. The metering chamber has two openings which communicate with the interior of the bottle in Fig. 10, the first opening for filling being in the vicinity of the outlet opening and the second opening being located near the opposite end of the measuring chamber for discharging the air during filling

When the liquid level in the dosing chamber reaches the level of the second opening, the filling ends, but an additional quantity of liquid occurs, the so-called "free liquid", the volume of which is a function of several variables, for example the specific weight of the liquid and the degree of filling of the liquid

Bottle. Although this free liquid runs back into the bottle due to the negative pressure in the bottle when it is brought into its normal position, the inaccuracy resulting therefrom is not negligible because of the metering device.

The accuracy of the dosing also depends on the inclination of the axis of the measuring space with respect to the 20 vertical; accurate dosing is only possible if these two axes are parallel.

The object of the invention is therefore to provide an improved metering device with which very precise measurements can be carried out and which can be produced simply and inexpensively.

This object is achieved in a dosing device for packaged liquids in a bottle soda-like container, which can be introduced into the neck of a bottle and has a dosing space, as it can be filled 25 at the top of the bottle, and a collecting space which is fed from the dosing space via a connection when the hash is in is brought into its normal position, and since the outlet opening is connected to the bottle, the dosing space and the collecting space having axes running parallel to the bottle axis and being separated from one another, and the dosing space having two openings which are connected to the inside of the bottle, of which the ast opening for filling the dosing space near the outlet opening since the bottle stains and 30 the second opening is arranged near the opposite end of the dosing space for discharging air when filling, solved according to the invention in that the second opening of the dosing space as an overflow for the Sam serves and is arranged in the area of the connection between the dosing room and the collecting room in a common area between the two rooms, that the collecting room has a capacity approximately corresponding to the dosing room and in this way the dosing started in the dosing room can be completed. 35 Advantageous refinements of the invention result from the subordinate claims.

The invention is described in more detail below with reference to figures. Show it:

Fig. La, lbund lc schematically shows a metering device in three functional stages; 2 and 3 an axial section of an embodiment of a dosing device consisting of two elements; Figures 5 and 6 are cross sections along lines (4-4) and (5-5) in Figures 2 and 3; Fig. 6 is a partial view of another embodiment of the element shown in Fig. 40; Figures 7 and 8 are perspective views corresponding to Figures 2 and 3; and FIG. 9 shows a perspective view of the metering device after assembly since the elements according to FIGS. 7 and 8.

The principles and functions of the dosing device (D) are described in Figures 1a, 1b and 2c. They are designed so that they can be inserted into the neck of a bottle (F) and at the same time serve as their closure.

The dosing device (D) has a flat end part (1) which is rigidly connected to an apron (2) 45 and which covers the neck of the bottle (F) with it. With the final part (1) a first tube (3) is connected, the

End is connected to one end of a second tube (S), which has a smaller cross-section and is closed at its opposite end. The first tube (3) is divided by a partition (6) which extends from the end part (1) just into the second tube (5) and the tube (3) into a dosing chamber (A) and a connecting passage (6a) divided. The second tube (5) forms a collecting space (B) which is arranged vertically below an outlet opening (7) and is connected to this via the connecting passage (6a). The dosing chamber (A), the axis of which is offset laterally opposite the outlet opening (7), begins essentially at the height of the outlet opening (7) and forms, tapering at the opposite end, with a diverging area of the collecting chamber (B) at the point since the connection between the two rooms is a common area (C) with the collecting room (B). The tapering end of the dosing space (A) and the diverging area of the collecting space (B) is realized by an inclined wall (4), which thus delimits the common area (C) connecting the dosing space (A) to the collecting space (B) . The outlet opening (7) provided in the end part (1) and connected via the connecting passage (6a) in the vertical direction to the collecting space (B) can be closed by a flap (8). -2-

AT 395 356 B

A first opening (9) is made in the side wall of the dosing chamber (A), which connects the dosing chamber (A) to the rest of the bottle (F) .The opening (9) is close to the connection between the dosing chamber (A) and the Final part (1). A second opening (10) serving as an overflow connects the dosage space (A) with the rest of the bottle (F) and is located at one end of a tube (11) at the level of the connection S of the inclined wall (4) with the Outside wall of the dosing room (A). The tube runs through the inclined wall (4). A small hole (12) is provided in the partition (6), which is somewhat closer to the end part (1) than the second opening (10).

The dosing device works in the following way:

The bottle (F) is tilted with its open flap (8) relative to its normal position so that it assumes the position shown in FIG. 10. The liquid contained in the bottle (F) then passes through the first opening (9) into the Dose space (A) and thereby displaces the air there through the tube (11) into the interior of the bottle (F). The liquid rises until the liquid level reaches the second opening (10); a small excess of liquid is referred to as "free liquid"

The bottle (F) is then brought back into its normal position according to FIG. 1b. The liquid in the metering space IS (A) then enters the collecting space (B) along the partition (6), the volumes of the two spaces being selected in this way that the liquid level reaches a point somewhat above the connection of the inclined wall (4) to the second tube (5), that is to say somewhat above the second opening (10). The small excess of liquid above the second opening (10) runs through this second opening (10) and the tube (11) back into the bottle (F), the tube (11) thus serving as an overflow Partition (6) 20 holes (12) »lightened. This air inlet ensures a balance between the level in the collecting space (B) and the level in the dosing space (A) up to the level of the second opening (10).

The volume of the collecting space (B), measured up to the second opening (10), corresponds to the required size, while the volume of the dosing space (A), as described above, is somewhat larger.

In order to achieve a sufficient volume accuracy of the measured product, the area (C) connecting the dosing chamber 25 (A) and the collecting chamber (B) has the smallest possible volume; the shape of this area (C) is chosen so that the liquid can easily pass into the collecting space (B).

Now the bottle (F) can be closed again using the flap (8). The measured amount of liquid is in the collection room (B) and is ready for use. To use the liquid, the bottle (F) is turned neck down as shown in FIG. 1c. The measured amount of liquid stored in the collecting space (B) flows out through the outlet opening (7). At the same time, the dosing chamber (A) is refilled, as described above with reference to FIG.

After the first use, in which the collecting space (B) has to be filled for the first time, the metering device (D) can be used by turning the bottle (F) only once.

Since the dosing process in the above-described dosing device (D) is carried out in two stages in the dosing chamber (A) and 35 in the collecting chamber (B), the amount of liquid is measured very precisely. The metering device (D) can also be manufactured very easily and inexpensively, for example by molding a plastic material.

2 to 9, a practical embodiment is shown

The dosing device (D) is made of two elements to facilitate the molding process. The first 40 element is shown in FIGS. 2, 4 and 7, the second element in FIGS. 3, 5, 6 and 8. In FIG. 9, the two assembled elements are shown in perspective

The first element initially has a device for closing the bottle (F), namely the end part (1) with a »apron (2) and a» flap (8) serving as a closure, which can be pivoted on the lid (1) is fastened and snaps into a cover area (13). The flap (8) is provided with a stopper (21) which fits tightly 45 in the outlet opening (7) and closes it

The closure device designed in this way can have a screw or snap-in area (14) on the underside of the apron (2) and, if desired, can be provided with an alignment nut (15) which has an area provided on the outside of the bottle neck can be brought into engagement

An inner apron (16) is preferably provided in the closure device, which is shorter than the outer apron (2) and securely seals on the inside of the upper part of the bottle neck

In addition to the closure device, the first element has the first tube (3) provided with the most opening (9) and the partition (6) with the hole (12), which, as shown in FIG. 2 and exactly in FIG. 7 can be designed as a slot. Preferably, as shown, the partition (6) is curved so that the liquid can easily flow from the dosing space (A) into the collecting space (B) and is prevented from running back into the dosing space (A) 55 when the bottle ( F) is used.

The inner end of the first tube (3) is provided with a latching device (17), the counterpart (17a) of which is on the second element, and a device (18) for preventing rotation, the counterpart (18a) of which is also on the second element located. -3-

Claims (8)

AT 395 356 B The second element is formed by the second tube (5), the inclined wall (4) and the tube (11) with the second opening (10), all parts being made in one piece. S and 8 it can be seen that the second tube (5) is closed at its base and is formed from a half circular cylinder and a curved segment, the cylindrical wall area (19) being the continuation of the cylindrical wall area of the first tube (3) forms, which represents the outer boundary of the connection passage (6a), and the concave side of the curved wall region (20) is directed inwards. The curved wall area (20), which can also be flat, adjoins the tube (11) and is rigidly connected to the inclined wall (4). As shown, it is curved such that the cross section of the passage from the metering chamber (A) to the collecting chamber (B) between it and the partition wall (6) is enlarged. In a second exemplary embodiment shown in FIG. 6, in the side wall of the metering chamber ( A) near the connection of the metering chamber (A) with the end part (1) no first opening (9) is provided. Instead of this opening, an inlet pipe (9a) is provided which extends axially from the inclined wall (4) into the metering chamber (A) and ends there approximately at the height of the outlet opening (7) when the two elements are locked into one another. From the above it follows that with the help of the invention a very precise metering device (D) is created, which is easy to apply to a bottle (F) and at the same time represents a closure device, and which is also easy to produce because it consists of two easily formable and assembled elements. 1. Dosing device for liquids packed in bottles or similar containers, which can be introduced into the neck of a bottle and has a dosing space which can be filled by the head of the bottle, and a collecting space which is fed from the dosing space via a connection when the bottle is brought into its normal position, and which communicates with the outlet opening of the bottle, the dosing space and the collecting space having axes parallel to the bottle axis and being separated from one another, and the dosing space having two openings which communicate with the interior of the bottle, the first of which Opening for filling the dosing space is located near the outlet opening of the bottle and the second opening is arranged near the opposite end of the dosing space for discharging air when filling, characterized in that the second opening (10) of the dosing space (A) is an overflow for the collection serves space (B) and at the level of the connection between the metering room (A) and the collecting room (B) in a common area (C) between the two rooms (A, B) that the collecting room (B) a the metering room ( A) has approximately the corresponding capacity and in this way the dosing started in the dosing room (A) can be completed. 2. Dosing device according to claim 1, characterized in that - as known per se - the collecting space (B) is arranged vertically below the outlet opening (7) and is connected to this via a connecting passage (6a), the dosing space (A) , whose axis is laterally offset from the outlet opening (7), begins essentially at the height of the outlet opening (7) and, at the opposite end, starts with a diverging area of the collecting space (B) at the point of connection between the two spaces forms the area (C) common to the collecting space (B). 3. Dosing device according to claim 2, characterized in that the common area (C) is delimited by an inclined wall (4) and has a small axial extent, its volume, measured by the volume of the dosing space (A) or the collecting space (B), being small and that the second opening (10) serving as an overflow is arranged at the level of the connection of the inclined wall (4) to the outer wall of the metering space (A) at one end of a tube (11) which is passed through the inclined wall ( 4) runs and the other end of which is inside the bottle (F) 4. Dosing device according to one of claims 1 to 3, characterized by a first tube (3), the end of which is connected to one end of a second tube (5) with a smaller diameter, which forms the collecting space (B), AT 395 356 B, and by an axially extending partition (6) which separates the dosing chamber (A) and the connecting passage (6a) from one another in the first tube (3) and extends somewhat into the second tube (5) starting from the outlet opening (7). 3. Dosing device according to claim 4, characterized in that the partition (6) approximately at the level of the overflow serving as the second opening (10) has a slot or a small hole (12) for pressure equalization between the spaces on both sides of it 6. Dosing device according to one of claims 3 to 5, characterized in that an inlet tube (9a) extends axially 10 from the inclined wall (4) into the dosing chamber (A) and ends there approximately at the height of the outlet opening (7) the corresponding pipe opening replaces the first opening (9) of the dosing chamber (A) 7. Dosing device according to one of claims 4 to 6, characterized in that the first tube (3) is cylindrical and the partition (6) is preferably curved, the concave side facing the dosing chamber (A) that 15 the second tube ( 5) is formed from a half Kieis cylinder and a flat or preferably curved segment, its cylindrical wall area (19) adjoining the wall area of the first tube (3), which forms the outer boundary of the connection passage (6a), and the concave side of the flat wall region (20) rigidly connected to the inclined wall (4) is directed inwards 8. Dosing device according to one of claims 4 to 7, characterized in that the first tube (3) has a closing part (1) with an outlet opening (7) that two aprons (2,16) are arranged so that the neck of the bottle (F) can be brought into engagement between them, and that a flap (8) having a stopper (21) for the outlet opening (7) is pivotably attached to the connecting part (1). 9. Dosing device according to one of claims 4 to 8, characterized in that the first tube (3) and the second tube (5) are molded separately from plastic material and locked into one another. 30 With 3 sheets of drawing «! 35 40 45 50 55