CH718417B1 - Dispensing device for dispensing a liquid from a pressurized container - Google Patents

Abstract

The invention relates to a dispensing device (100) for dispensing a liquid from a container (200) under excess pressure. The dispensing device comprises a dispensing opening (20) for dispensing the liquid, an inlet opening (30) and a shut-off device (40) which prevents the liquid from flowing through between the inlet opening (30) and the dispensing opening (20). A hydrophilic filter element (50) is arranged at the inlet opening (30), which closes the inlet opening (30).

Description

The present invention relates to a dispensing device for dispensing a liquid from a pressurized container according to the preamble of the independent claim.

A common type of container under pressure or excess pressure are, for example, containers for spray paints, hair sprays or deodorants. These can typically be summarized under the term aerosol sprays.

In such aerosol sprays, a liquid filling material which is located in the container is dispensed from the container using compressed air or propellants (propellants or propellant gases). For this purpose, the containers typically have a dispensing device which is connected to the interior of the container with an inlet opening and is connected to the environment with an outlet opening. The inlet opening and the outlet opening are typically connected to one another with a valve which blocks the path between the inlet opening and the outlet opening.

However, such aerosol sprays have the disadvantage that they may not be able to be completely emptied. The inlet opening is typically extended with a riser pipe to below the level of a liquid in the container, so that the liquid is pressed into the riser pipe or into the inlet opening by a propellant gas filling above the liquid level and is accordingly dispensed through the outlet opening when the valve is actuated can be. However, if the user holds the aerosol spray upside down or at an angle, it can happen that the propellant gas flows directly into the inlet opening and therefore no liquid is dispensed when the valve is actuated, but only the propellant gas. This results in the propellant gas supply within the container being emptied within a very short time without, however, dispensing the liquid from the container. Once the propellant gas in the container has been completely used up, there is no longer any possibility of dispensing the liquid still in the container from the container.

[0005] This is both economically and ecologically disadvantageous and regularly leads to customer dissatisfaction. Propellant gas that is dispensed without having any use harms the environment and the liquid remaining in the container may have to be disposed of along with the aerosol spray. In other words, the customer has to dispose of part of the product he purchased without having had any use for it.

In order to accommodate the customer, the proportion of propellant gas in the container can be increased, but this leads to an additional ecological burden. In the worst case, after the container has been completely emptied, a residue of propellant gases remains in the container or is released into the environment by the customer without pumping any further liquid.

In order to circumvent these disadvantages, various solutions have already been proposed. For example, there are aerosol containers in which the liquid to be dispensed is separated from the propellant gas, for example by filling the liquid into a separate, flexible container, so-called bag in box solutions. Attempts were also made to separate the liquid from the propellant gas using a movable piston within the container. These solutions are typically complicated to manufacture and/or must be manufactured very precisely, particularly with regard to displaceable pistons.

It is the object of the invention to eliminate at least one or more disadvantages of the prior art. In particular, a dispensing device for dispensing a liquid from an overpressured container should be created, which is easy to manufacture, prevents excessive consumption of propellant gas and, in particular, can be used in all situations.

This object is achieved by the dispensing device and container defined in the independent patent claims. Further embodiments result from the dependent patent claims.

A device according to the invention for dispensing a liquid from a container under excess pressure comprises a dispensing opening for dispensing the liquid, an inlet opening and a shut-off device which prevents the liquid from flowing through between the inlet opening and the dispensing opening. A hydrophilic filter element is arranged at the inlet opening and closes the inlet opening. The hydrophilic filter element is connected to the inlet opening.

In the present case, a filter element is understood to mean an element that has a large number of capillaries, in particular a component with a capillary pore structure. The filter element can, for example, be formed from a three-dimensional structure or merely from a substantially two-dimensional membrane.

Hydrophilic elements have a strong interaction with water, so they are water-loving.

Such hydrophilic filter elements have the property that, as soon as they are wetted with water, they prevent gas from passing through, since the water is held in the pores by capillary forces and blocks them for gases.

[0014] This means that the hydrophilic filter element can reliably prevent the escape of propellant gas. If the container is positioned incorrectly, for example at an angle or upside down, where the filter element is no longer in the liquid, no propellant gas will flow out even after the shut-off device has been opened.

The propellant gas filling in the container can therefore be adjusted very precisely to the amount of liquid to be dispensed.

[0016] In addition, such a hydrophilic filter element makes it possible to keep excess propellant gas in the container, even if all of the liquid to be dispensed has been emptied from the container.

[0017] Since excess propellant gas is still in the container even after it has been emptied, it can easily be recycled. For example, all you have to do is return the emptied containers to the point of sale or to specific collection points. The remaining propellant gases still in the container can be removed and recycled.

The fact that the inlet opening is closed means nothing other than that all of the liquid that is to be dispensed or can be completely passed through the hydrophilic filter element.

Preferably, the hydrophilic filter element has a contact angle that is smaller than 60°, preferably smaller than 30° and particularly preferably smaller than 10°. The contact angle is in particular between 0° and 3°.

The lower the contact angle, the more hydrophilic the filter element is and, with the pore size remaining the same, the higher the counter pressure that must be built up in order to force air through the wetted hydrophilic filter element. In other words, in order to force air through the hydrophilic filter element, the liquid held in the capillaries must be displaced from the liquid-wetted pores or capillaries of the hydrophilic filter element

[0021] This counterpressure can be determined using the so-called bubble pressure test (bubble point test). The differential pressure or back pressure is calculated as follows: Δp = (4σ × cosθ) / D Δp = differential pressure σ = surface tension of the liquid 9 = contact angle D = pore diameter

The parameters are preferably chosen such that the resulting pressure is higher than 1 × 10^5Pa, preferably higher than 2 × 10^5Pa, in particular higher than 5 × 10^5Pa. When arranging several hydrophilic filter elements, a resulting pressure of 10 × 10^5Pa is advantageous.

The hydrophilic filter element preferably has a pore size of 0.01 μm to 10 μm. On the one hand, this enables a sufficiently high throughput of liquid, and on the other hand, with the appropriate contact angle, the liquid is reliably held in the membrane, even if the container is exposed to vibrations, for example.

To create the hydrophilic properties, the hydrophilic filter element can be provided with a hydrophilic coating.

Additionally or alternatively, the material from which the hydrophilic filter element is created can already have hydrophilic properties.

A coating that is hydrophilic makes it possible, for example, to produce a blank that has a specific shape and then to coat it so that the hydrophilic function is preserved.

The hydrophilic filter element can be formed as a filter element from the group comprising flat membrane, candle filter, pocket filter or hollow fiber module. Depending on the product or liquid that is to be dispensed through the filter element, a corresponding design is advantageous.

The hydrophilic filter element can have a material from the group of polymer membrane, glass frit, ceramic frit or sintered metal, in particular consist of one of the materials mentioned.

The materials can also be selected according to the product to be delivered.

The dispensing device preferably has a riser pipe, with the inlet opening being formed at one end of the riser pipe. The riser pipe is arranged on the dispensing device. In particular, the riser pipe is connected to the dispensing device with a second opening.

In other words, the inlet opening of the dispensing device with the riser pipe is displaced from the original position.

This also allows the hydrophilic filter element to be placed at a distance from the dispenser.

The hydrophilic filter element therefore has a fluid connection to the dispensing device via the riser pipe, this fluid connection being closed to the environment.

The hydrophilic filter element can be connected to the riser pipe or the inlet opening, for example, by a press connection, by means of a cohesive connection such as ultrasonic welding, gluing, screwing or shrinking.

The dispensing device can have a second inlet opening which is in fluid communication with the inlet opening. A further hydrophilic filter element is arranged at the second inlet opening and closes the second inlet opening.

The further hydrophilic filter element is designed in accordance with the hydrophilic filter element already described. However, it is not mandatory that both hydrophilic filter elements are designed the same. The further hydrophilic filter element can be designed, for example, as a polymer membrane and the first hydrophilic filter element can consist, for example, of a sintered metal. All combinations are freely selectable.

By providing a second inlet opening, the liquid to be dispensed can be dispensed from another area of the interior of the container. This allows the container to be used in different positions. Through a second inlet opening, which is also provided and closed with a hydrophilic filter element corresponding to the first inlet opening, liquid can be dispensed from different areas inside the container or different areas inside the container can be closed from a gas outlet by the dispensing device.

The second inlet opening can be formed at the end of a second riser pipe which is designed analogously to the first riser pipe and is also arranged on the dispensing device. The second riser pipe can be directly connected to the first riser pipe or can be arranged separately on the dispensing device.

The second riser pipe is preferably designed to be shorter than the first riser pipe. This allows liquid to be dispensed from two different levels within the container.

The shut-off device can be designed as a spring-operated ball valve, as a conventional spray can valve or, for example, as a conventional slide or ball valve.

Depending on the application, a preferred form of the shut-off device can be selected.

[0042] It can also be provided that an atomizer nozzle is arranged at the dispensing opening to generate a spray mist.

A further aspect relates to a container which comprises a dispensing device as described herein.

[0044] It is therefore possible to provide completely pre-assembled containers, for example aerosol sprays, in which the product is already accommodated and which are provided with hydrophilic filter elements that are tailored to the specific application and/or the specific product.

It can be provided that the riser pipe ends in the area of a container bottom and the second riser pipe ends in the area of a container neck.

This enables the container to be used in an upright position as well as upside down. If both hydrophilic filter elements are wetted, the second filter element is exposed to the propellant gas in the upright position, but is impermeable to the propellant gas due to the wetting. When the shut-off device is actuated, the liquid to be dispensed is released through the hydrophilic filter element arranged in the bottom area in the direction of the dispensing opening.

If the container is now upside down, the hydrophilic filter element that was previously immersed in the liquid is now exposed to the propellant gas and the hydrophilic filter element located in the area of the container shoulder or the container neck is immersed in the liquid to be dispensed. The liquid can now be discharged through the second hydrophilic filter element towards the dispensing opening when the shut-off device is opened. Since the hydrophilic filter element located in the bottom area is wetted, this hydrophilic filter element prevents the release of propellant gas.

The container can be made of metal, in particular the dispensing device being connected to the container with a press connection. This enables a secure and permanent connection between the container and the dispensing device.

[0049] Alternatively, it is possible for the container to be made of plastic, in particular PET. The dispensing device is connected to the container in particular via a press connection or a screw connection.

Such containers are highly recyclable. In particular, containers and dispensing devices connected via a screw connection can be disposed of separately and therefore completely recycled.

Individual exemplary embodiments of containers with shut-off devices are described below using only schematic figures. It shows: Figure 1: A container with a dispensing device; Figure 2: a container with an alternative dispensing device.

1 shows a container 200 with a dispensing device 100. The dispensing device 100 has a dispensing opening 20 and an inlet opening 30. The inlet opening 30 is extended with a riser pipe 31. One end of the riser pipe 31 is thus connected to the dispensing device 100 and the second end of the riser pipe 31 is connected to a hydrophilic filter element 50.

The hydrophilic filter element 50 is firmly connected to the riser pipe 31. A liquid F is arranged within the container 200 and can be dispensed from the container 200 when the dispensing device 100 is actuated. In the present illustration above the liquid there is a propellant gas T which is under pressure. When the dispensing device 100 is actuated and thus when the shut-off device 40 (not shown) is opened, the liquid F is pressed through the hydrophilic filter element 50 into the riser pipe 31 by the pressure of the propellant gas T. The liquid F rises in the riser pipe 31 towards the discharge opening 20 and exits through it. An atomizer nozzle is arranged in the dispensing opening 20.

The container 200 has a container base 201 and a container neck 202, also known as the container shoulder. The container 200 according to Figure 1 is designed to dispense the liquid F in the position shown here. It can be seen that when the container 200 is held upside down, the hydrophilic filter element 50 is no longer in the liquid F, but has propellant gas T flowing around it. However, since the hydrophilic filter element 50 is wetted with liquid F, the passage of gas through the hydrophilic filter element is prevented. When the shut-off device 40 is actuated, no reaction will take place; neither propellant gas T nor liquid F will be released.

2 shows a container 200 with an alternative dispensing device 100. The container 200 also has a container base 201 and a container neck 202 and is designed essentially the same as the container described in FIG. A dispensing device 100 with a dispensing opening 20 and an inlet opening 30 is arranged on the container. The inlet opening 30 is extended to the container bottom 201 with a riser pipe 31. The inlet opening 30 simultaneously represents a second inlet opening 60, which is extended with a short piece of a second riser pipe 61. This second riser pipe ends in the area of the container neck 202. In other words, the inlet opening 30 with the riser pipe 31 is extended in the direction of the container bottom 201 and the inlet opening 60 with the second riser pipe 61 is extended in the direction of the container shoulder or the container neck 202. There is a hydrophilic filter element 50 at each end of the riser pipes 31 and 61. In the original state, both hydrophilic filter elements 50 are wetted with the liquid F, which is located in the container 200. The container contains the liquid F and in the position shown in FIG. 2 above the liquid F there is a propellant gas T. It can be seen that the second hydrophilic filter element 50 is exposed to the propellant gas. However, since the second hydrophilic filter element 50 is wetted with the liquid F, it represents a barrier for the passage of the propellant gas T in the direction of the discharge opening 20. However, the liquid F can pass unhindered through the riser pipe after the shut-off device 40, not shown here, has been actuated 31 flow in the direction of the dispensing opening 20. If the container 200 according to FIG. 2 is now used upside down, the second hydrophilic filter element is in contact with the liquid F. The container 200 according to FIG. 2 can therefore also be used upside down.

Both containers 200 according to FIG. 1 and FIG wetted hydrophilic filter 50 a barrier for gaseous substances is formed. The containers can thus be recycled, whereby the individual substances and in particular propellant gases can then be separated separately and reused.

Claims (15)

1. Dispensing device (100) for dispensing a liquid from a pressurized container (200), comprising a dispensing opening (20) for dispensing the liquid, an inlet opening (30) and a shut-off device (40) which allows the liquid to flow through between the inlet opening (30) and the dispensing opening (20), characterized in that a hydrophilic filter element (50) is arranged at the inlet opening (30), which closes the inlet opening (30). 2. Dispensing device according to claim 1, characterized in that the hydrophilic filter element (50) has a contact angle smaller than 60°, preferably smaller than 30°, particularly preferably smaller than 10°. 3. Dispensing device according to claim 1 or 2, characterized in that the hydrophilic filter element (50) has a pore size of 0.01 µm to 10 µm. 4. Dispensing device (100) according to one of claims 1 to 3, characterized in that the hydrophilic filter element (50) is provided with a hydrophilic coating to create the hydrophilic properties and / or is made of a material with hydrophilic properties. 5. Dispensing device (100) according to one of claims 1 to 4, characterized in that the hydrophilic filter element (50) is formed as a filter element from the group comprising flat membrane, candle filter, pocket filter, hollow fiber module. 6. Dispensing device (100) according to one of claims 1 to 5, characterized in that the hydrophilic filter element (50) has a material from the group of glass frit, ceramic frit, sintered metal or polymer membrane, in particular consists of one of these materials. 7. Dispensing device (100) according to one of claims 1 to 6, characterized in that the dispensing device (100) has a riser pipe (31) and the inlet opening (30) is formed at one end of the riser pipe (31). 8. Dispensing device (100) according to one of claims 1 to 7, characterized in that the dispensing device (100) has a second inlet opening (60) which is in fluid communication with the inlet opening (30), wherein at the second inlet opening (60) a further hydrophilic filter element (50) is arranged, which closes the second inlet opening (60). 9. Dispensing device (100) according to claim 8, characterized in that the dispensing device (100) has a second riser pipe (61) and the second inlet opening (60) is formed at one end of the second riser pipe (61). 10. Dispensing device (100) according to claims 9 and 7, characterized in that the second riser pipe (61) is shorter than the riser pipe (31). 11. Dispensing device (100) according to one of claims 1 to 10, characterized in that the shut-off device (40) is designed as a spring-operated ball valve, as a spray can valve or as a ball valve. 12. Container (200) comprising a dispensing device (100) according to one of claims 1 to 11. 13. Container (200) according to claim 12 comprising a dispensing device (100) according to claim 10, characterized in that the riser pipe (31) ends in the area of a container bottom (201) and the second riser pipe ends in the area of a container neck (202). 14. Container (200) according to claim 12 or 13, characterized in that it is made of metal, in particular the dispensing device (100) being connected to the container neck (202) with a press connection. 15. Container (200) according to claim 12 or 13, characterized in that it is made of plastic, in particular PET, and in particular the dispensing device (100) is connected to the container neck with a press connection or a screw connection.