EP1368245B1 - Drop cap for dosing the amount of liquid in a drop and container comprising a drop lid - Google Patents

Abstract

The invention relates to a drop cap for dosing the amount of liquid in the form of drops in a container, whereby the contents thereof which are to be dosed can be put under pressure. A throttling device is arranged in the direction of flow upstream from the input opening of the output channel arranged in the body of the cap in order to ensure that a predetermined drop volume is maintained in a reliable manner particularly when large drops are present, whereby said volume should be independent from the pressure applied from the liquid. Said throttling device can be embodied as a permeable opening in an additional separating wall. The invention also relates to a container comprising a drop cap.

Description

The invention relates to a drip cap for dosing out liquid in drop form from a container whose contents are to be dosed out is pressurizable, with a cap body in which a Outlet channel and a throttle device is arranged, in Flow direction before the inlet opening of the outlet channel fixed is arranged. The invention also relates to a container A drip cap according to claims 9 and 10.

Drugs that are used in liquid form are used in Tubes or vials provided from which they are in drop form be dosed. Since the medication is linked to the number of drops It is crucial that the drop volume during Dosing is always constant and not by the user can be influenced.

When liquid medicines are provided in glass vials, If the drip insert has, in addition to the outlet channel, an air channel, through the air during dosing into the vial interior can.

For bottles or tubes of flexible plastic material has the Drop cap only one outlet channel, through which the liquid through Pressure is dosed on the container wall. This is what matters on that the outlet channel exactly defines the drop size.

Such a dropper tip for eye drops, for example, in the EP 0 431 885 A1. The outlet channel has a Inlet opening whose cross-section is smaller than that of the Outlet opening, wherein substantially the size of the outlet opening the drop size determines. To determine the optimal dimensions Extensive experiments were carried out to prevent the liquid exits as a jet rather than as a drop when the user if necessary exerts too much pressure on the container wall. This has happened proved that in addition to the conical shape of the outlet channel also the outer shape of the drip tip is particularly influential when the container is held at an angle.

EP 0 956 904 A1 describes a dropper insert which is inserted in a Container can be used. This dropper should be independent always provide constant drop sizes from the pressure on the liquid. Starting from an outlet channel with an inlet opening, the smaller than the outlet opening, are next to conical Outlet channels including those with cylindrical sections proposed.

Although EP 0 956 904 A1 states that the drop shape is independent of the pressure exerted on the liquid pointed out that this does not always succeed. It has been shown that especially at higher pressures in connection with the production larger drops from a certain pressure value Outlet jet forms or the drops an uncontrolled shape and thus assume an undefined volume. The dosing safety is not guaranteed.

Other disadvantages of these known drip caps are that do not adjust for all liquids constant drop sizes. In Dependence on the viscosity and wettability of the To be dispensed liquids can also at low Diameters of the outlet, which are usually less than 2 mm, Set uncontrolled drop shapes.

These adverse effects occur at larger exit openings, e.g. with diameters of 5 to 10 mm, reinforced on.

But big drops are always needed when larger Quantities of the liquid should be dosed and the tedious Counting a large number of small drops should be avoided.

From US 5,356,052 is a plastic container with a drip tip known, which has a throttle device in the outlet channel. This throttle device consists of two adjacent Wall sections that press against each other at rest. As soon as inside the container by squeezing the container walls Pressure is built, which are forming the throttle device Wall sections pressed apart and give an opening for the Dosing of fluid free. The disadvantage of this Throttling device is that initially an additional pressure must be applied to open the throttle device and by further pressure increases only the metering can be done. On the liquid therefore acts a relatively large pressure, which This causes the liquid to start abruptly at great speed is discharged. But there are drops and no liquid flow are to be dosed, the drop size depends very much on the user applied pressure. The reproducibility of Drop size is usually not given. At what pressure the Throttle device opens depends essentially on the elastic Properties of the container material from, so that at different Materials also different pressures have to be applied, each time the operator has to readjust. It is therefore desirable that a metering with constant Drop size is made possible by the chosen container material is independent.

DE-AS 10 63 755 describes a plastic dropper bottle, especially for drugs whose drip opening is a dazzling Insert is upstream, which is a hole with a small diameter having. The liquid to be dosed enters directly into the Outlet channel, wherein in particular at high pressures a Beam can form, which continues in the outlet channel and there a targeted dosage and dripping prevents.

It is therefore an object of the invention to provide a drip cap, the especially with large drops reliably the given Drip volume ensured, this volume regardless of the pressure applied to the fluid should be maintained. It It is also an object of the invention to provide a container with a provide appropriate drip cap.

The task is with a drip cap for dosing Liquids dissolved in the form of drops, in which the throttle device spaced apart from the inlet opening, and at between the inlet opening and the throttle device an intermediate chamber is arranged, by the bottom wall of the cap body and a Chamber wall is limited.

The pressure exerted by the user on the fluid must not be allowed to propagate into the exit channel, but before the Outlet channel must be reduced so far that the Pressure conditions in the region of the outlet channel a drop formation allow. By arranged in front of the inlet opening Throttling device can be the maximum pressure on the liquid to be dispensed acts before or in the outlet channel, be set. The throttle device also ensures at high pressure exerted on the liquid, that in the outlet channel always constant pressure conditions are maintained.

Because at high pressures applied to the liquid, the liquid through the throttle device with high flow velocity The liquid could pass directly into the jet as a jet Penetrate the inlet opening, wherein the jet in the outlet channel which prevents the formation of constant droplet sizes could. By the spaced arrangement of the throttle device is ensures that the flowing through the throttle device First liquid can distribute before entering the inlet arrives.

This effect is further improved by the fact that between the Inlet opening and the throttle device an intermediate chamber is arranged. The intermediate chamber has the advantage of being First, you can collect the liquid here before putting it in the Ingress opening of the outlet channel penetrates.

Preferably, the volume of the intermediate chamber is greater than or equal to Volume of the outlet channel. This will ensure that that entire volume necessary for a drop in the Intermediate chamber is provided under suitable pressure.

Preferably, the intermediate chamber of the cap body and limited to a chamber wall.

The throttle device is preferably in the chamber wall arranged.

The throttle device may have at least one passage opening in the Chamber wall, whose cross-section is smaller than that Cross section of the inlet opening of the outlet channel. Other Throttling devices, such as valve flaps or the like can also be used.

The passage opening may be opposite to the inlet opening. It is but advantageous if the passage opening offset from the Inlet opening is arranged, because thereby by the Passage opening formed liquid jet first a diversion and thus undergoes a further pressure reduction.

The chamber wall preferably consists of an annular wall and a Partition wall. The ring wall can be adapted to the dimensions of the Be adapted cap body. The throttle device is preferably arranged in the partition wall.

Preferably, the chamber wall is integrally formed on the cap body.

The drip cap and container can be combined in different ways become.

The drip cap according to the invention can be an integral part of the Be container.

For manufacturing reasons, however, you will container and Make drip cap separately and then the drip cap in the Insert container neck or in the spout opening of the container.

This can be realized in two variants. According to a first Variant is the drop cap according to the invention as an insert for Made available in the container neck any conventional Container is used.

According to a second variant of the container in the spout opening a conventional drip cap with outlet channel, wherein the Drip cap has a bottom wall with an inlet for the Has outlet channel. The throttle device is in this embodiment arranged in a partition of the container, said partition spaced apart from the bottom wall in the interior of the container is and where between the partition and the bottom wall a Intermediate chamber is located.

The partition wall is preferably arranged in the container neck.

Preferably, the partition is perpendicular to the container axis arranged. The partition can be used in the container or be an integral part of the container.

The throttle device is preferably in this partition arranged.

The throttle device comprises at least one passage opening in the partition whose cross section is smaller than the cross section of Inlet opening of the outlet channel. By choosing the cross section This opening can be the maximum pressure on the outlet channel acts, be adjusted. It ensures that the to be dispensed liquid under the same pressure in the Outlet channel occurs, so that no influence on the of User applied pressure on the drop shape can take place. The passage opening is preferably located at the inlet opening across from. In this case it is important that the distance between the throttle opening and the inlet opening is as large as possible, so that the incoming liquid is not directly into the outlet channel which in turn leads to a radiation hazard at the end of the Outlet opening of the outlet channel could result.

To bring about further improvement in this area is the passage opening preferably offset from the inlet opening arranged.

Preferably, the volume of the space between the Drip cap and the partition greater than or equal to the volume of Outlet channel.

Preferably, the conventional or inventive Container a flexible container wall, for example made of plastic can exist. The container can be a tube, a vial or a be another suitable container. Through the flexible container wall is it is possible, for example, by hand, the contents of the container below To put pressure and so make the dosing.

But it can also be a printing device on or in the container be provided or the container may be to a printing device be connectable. A printing device would be e.g. one Pumping mechanism with the example air into the container interior is pressed, so that thereby the liquid through the Throttle device is pressed.

The drip cap can be liquid or pressure tight in the container neck be usable. There is a possibility, for example, by Welding the drip cap a tight connection with the container manufacture.

Exemplary embodiments of the invention are described below explained in more detail with reference to the drawings.

Figur 1

einen Vertikalschnitt durch einen Behälter mit einer eingesetzten Tropfkappe gemäß einer ersten Ausführungsform,

Figur 2

einen Vertikalschnitt durch einen Behälter mit einer eingesetzten Tropfkappe gemäß einer zweiten Ausführungsform und

Figur 3

einen Vertikalschnitt durch einen erfindungsgemäßen Behälter mit einer herkömmlichen Tropfkappe.

Show it:

FIG. 1

a vertical section through a container with an inserted drip cap according to a first embodiment,

FIG. 2

a vertical section through a container with an inserted drip cap according to a second embodiment and

FIG. 3

a vertical section through a container according to the invention with a conventional drip cap.

In the figure 1, the area of the container neck 3 of a container 1 in Vertical section shown. The container wall 2, the interior of the 6th limited to the container 1 is shown only partially to the in Container neck 3 and the spout opening arranged drip cap 10th to be able to represent enlarged.

On the outside of the container neck 3 is an external thread. 4 molded, so that on the container neck 3, a cap (not shown) can be applied. The container neck 3 is cylindrical formed and serves to accommodate the drip cap 10, which has a in main cup-shaped cap body 11 with bottom wall 13 and Peripheral wall 14 has.

The cap body 11 has a metering nozzle 12 in the middle, in the an outlet channel 20 is arranged. The metering nozzle 12 extends from the horizontally arranged bottom wall 13 vertically upwards and projects beyond the peripheral wall 14, which at its upper end a Ring flange 15, with which the drip cap 10 on the end face the container neck 3 rests and can be fixed there.

The outer diameter of the peripheral wall 14 corresponds to the Inner diameter of the container neck 3, so that the drip cap 10th liquid-tight in the container neck 3 can be used.

The exit channel 20 has at the lower end, i. around Bottom wall 13 an inlet opening 21 with a small Diameter, wherein the diameter is smaller than the diameter the outlet opening 25 at the upper end of the Dosierstutzens 12. To the Inlet 21 is followed by a cylindrical inlet section 22, which merges into a conical section 23 which extends in the direction Outlet opening 25 expands. At the conical section 23 closes again a cylindrical portion 24, which the outlet opening 25 forms. The diameter of the outlet opening 25 may, for example range between 5 and 10 mm. The cross section of the Outlet opening 25 defines the drop size.

The outlet channel 23 may also have other cross-sectional shapes as shown for example in EP 0956904 A1 and is described. It is not mandatory that the inlet opening has a smaller cross-section than the outlet opening. Depending on Type of liquid can also be drops with cylindrical Create exit channel.

On the bottom wall 13, a chamber wall 32 is formed down, which limits an intermediate chamber 35. The chamber wall 32 is in the embodiment shown here of an annular wall 33, whose Outer diameter of the inner diameter of the container neck. 3 corresponds, and one aligned perpendicular to the container axis Partition wall 34.

In the partition wall 34 is centrally a throttle device 30 in the form of a Passage opening 31 is arranged, whose cross-section is smaller than that Cross section of the inlet opening 21.

The chamber wall 32 is an integral part of the drip cap 10, the with the intermediate chamber 35 over the entire length of the Container neck 3 extends. For containers with a shorter one Container neck 3, the intermediate chamber 35 also in the interior. 6 protrude the container. In the embodiment shown here is the volume of the intermediate chamber 35 is greater than the volume of the Outlet channel 20.

FIG. 2 shows a further embodiment in which the Container neck 3 is made shorter than that in the container 1 according to Figure 1 is the case. The intermediate chamber 35 is also cylindrical formed, however, wherein the volume of the intermediate chamber 35th is lower than in the embodiment according to the figure 1. Also at In this embodiment, the volume of the intermediate chamber 35 greater than the volume of the exit channel 20.

In contrast to the embodiment according to the figure 1 is the Passage opening 31 arranged off-center and thus offset from Inlet opening 21 of the outlet channel 20 is arranged. This is with this Embodiment insofar advantageous because the distance of the partition 34 to the inlet opening 21 is significantly lower than in the Embodiment according to the figure 1, so that an immediate transfer the inflowing liquid from the passage opening 31 in the Entry opening 21 is prevented.

In both embodiments, the container wall 2 is made of flexible Material, so that by squeezing the container wall 2 the To be dispensed liquid through the passage opening 31 in the Intermediate chamber 35 and thus pressed into the outlet channel 20 can be.

3 shows a further embodiment is shown, wherein the innovation relates to the container 1 '. The drip cap has none Chamber wall, as shown in Figures 1 and 2, but consists of a substantially conventional drip cap 10 ', the is inserted into the container neck 3.

To the throttle device 30 spaced from the inlet opening 21 of the To arrange outlet channel 20 is in the lower part of the Container neck 3 a partition wall 34 'fed, the off-center the Throttle device 30 in the form of a passage opening 31 has. Between the partition wall 34 'and the bottom wall 13 of the drip cap 10 'is the intermediate chamber 35'. In this embodiment Thus, the throttle device 30 is part of the container and not Part of the drip cap 10 '.

Due to the inventive design of the container 1, it is possible to use conventional drip caps 10 '.

It is in all embodiments according to FIGS. 1 to 3 also the possibility of several of the passage openings 31 in the partition 34, 34 'to be arranged, wherein the sum of the cross sections of Passage openings 31 should be smaller than the cross section of Inlet opening 21 of the outlet channel 20th

reference numeral

1, 1 '

container

2

container wall

3

container neck

4

external thread

5

pouring

6

Interior of the container

10, 10 '

drip cap

11

cap body

12

dosing nozzle

13

bottom wall

14

peripheral wall

15

annular flange

20

outlet channel

21

inlet opening

22

Cylindrical inlet section

23

Conical section

24

Cylindrical outlet section

25

outlet opening

30

throttling device

31

passage opening

32

chamber wall

33

ring wall

34, 34 '

partition wall

35, 35 '

intermediate chamber

Claims (18)

1. Dropper cap for metering fluids in droplet form from a container whose contents can be pressurised in order to be metered out, having a cap body in which an outlet channel and a throttle device are arranged, which throttle device is securely arranged upstream of the inlet opening (21) of the outlet channel (20) in the direction of flow, characterised in that the throttle device (30) is arranged with spacing from the inlet opening (21), and in that an intermediate chamber is arranged between the inlet opening (21) and the throttle device (30) and is delimited by the base wall of the cap body (11) and a chamber wall (32).
2. Dropper cap according to claim 1, characterised in that the volume of the intermediate chamber (35) is greater than/equal to the volume of the outlet channel (20).
3. Dropper cap according to claim 1 or claim 2, characterised in that the throttle device (30) is arranged in the chamber wall (32).
4. Dropper cap according to any one of claims 1 to 3, characterised in that the throttle device (30) comprises at least one through-hole (31) whose cross-section is smaller than the cross-section of the inlet opening (21) of the outlet channel (20).
5. Dropper cap according to any one of claims 1 to 4, characterised in that the through-hole (31) is located opposite the inlet opening (21).
6. Dropper cap according to any one of claims 1 to 5, characterised in that the through-hole (31) is arranged offset relative to the inlet opening (21).
7. Dropper cap according to any one of claims 1 to 6, characterised in that the chamber wall (32) comprises an annular wall (33) and a dividing wall (34), the throttle device (30) being arranged in the dividing wall (34).
8. Dropper cap according to any one of claims 1 to 7, characterised in that the chamber wall (32) is formed on the cap body (11).
9. Container for receiving fluid which can be pressurised in order to be metered out from the container, having a container neck (3) having a dropper cap (10) for metering fluids in droplet form according to any one of claims 1 to 8.
10. Container for receiving fluid which can be pressurised in order to be metered out from the container, having a container neck for receiving a dropper cap (10') for metering fluid in droplet form, the dropper cap (10') having a cap body, in which an outlet channel is arranged, a dividing wall (34') being arranged in the inner space (6) of the container (1), in which dividing wall (34') a throttle device (30) is provided, characterised in that the dropper cap (10') has a base wall (13) having an inlet opening (21) for the outlet channel (20), in that the dividing wall (34') is arranged with spacing from the base wall (13), and in that an intermediate chamber (35') is located between the dividing wall and the base wall (13).
11. Container according to claim 10, characterised in that the dividing wall (34') is arranged in the container neck (3).
12. Container according to either claim 10 or claim 11, characterised in that the dividing wall (34') is arranged perpendicularly to the container axis.
13. Container according to any one of claims 10 to 12, characterised in that the throttle device (30) comprises, in the dividing wall (34'), at least one through-hole (31) whose cross-section is smaller than the cross-section of the inlet opening (21) of the outlet channel (20).
14. Container according to claim 13, characterised in that the through-hole (31) is located opposite the inlet opening (21).
15. Container according to either claim 13 or claim 14, characterised in that the through-hole (31) is arranged offset relative to the inlet opening (21).
16. Container according to any one of claims 10 to 15, characterised in that the dividing wall (34') is arranged in such a manner that the volume of the intermediate space between the dropper cap (10') and the dividing wall (34') is greater than/equal to the volume of the outlet channel (20).
17. Container according to claims 9 to 16, characterised by a flexible container wall (2).
18. Container according to any one of claims 9 to 17, characterised in that it has a pressure device or can be connected to a pressure device.

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