NL9000050A - Drink dispensing mechanism fitting into bottle neck - liquid flows by gravity into cavity which contains flushing syphon bell - Google Patents

Abstract

The dispenser (1) fits into the neck (2) sealed by a flexible collar (3). When the bottle is tipped over a glass, the liquid flows from the bottle, between an internal cylindrical 'bell' and a concentric sleeve, into a body of the device and the inside of the bell. The displaced air in the device is expelled via a relief pipe (11). Air also flows into the bottle, via a tube (16), to replace the liquid. When the level of liquid in the device reaches a level (8) near the top of the bell, a syphoning action drains the measured quantity of liquid out through the centrall spout (10). @(12pp Dwg.No.1/4)@.

Description

Device for the accurate dosing of liquids.

The invention relates to a device for accurately dosed dispensing of liquids. This device is sealingly arranged on a container with liquid, for instance a bottle, and is designed and designed such that if the container is placed or held upside down, with the pouring spout fitted on the device downwards, the liquid from the container is adjusted in a dimensioning of the device amount flows into another container, such as a glass.

A somewhat comparable device, with regard to the purpose of the invention in question, is known from Dutch patent no. 184213 entitled "Storage container with a device for dosed dispensing of liquid". The patent in question aims to describe a storage container with a device for dosed dispensing of liquids, which device is sealingly connected to the opening at the bottom of the storage container and which is provided for this purpose with a dosing chamber and one movable sliding member, which can be connected alternately with the interior of the storage container and with the discharge opening by means of the dosing chamber, the dosing chamber being connected to the environment via a vertical tube located above it.

The feature of this device described in patent number 184213 consists in that the storage container is of closed design and contains an aeration space which is delimited relative to the filling space of the storage container by a cap-shaped partial data on the dosing chamber. facing side is open and that this aeration chamber is connected to the atmosphere via a channel, which, like the vertical tube, opens into the aeration chamber.

The described device has drawbacks, such as, inter alia, that the device is complicated in design and construction. Furthermore, the effect is based on the functioning of moving (sealing) parts. For example, the metering chamber should be moved by mechanical means or by electromagnetic means, the sealing effect of the annular seal becoming dubious over time due to contamination and / or aging.

The present invention aims to provide a device for dispensing liquids without the above-mentioned drawbacks. The device according to this invention consists of a reservoir, which is placed on a liquid container, such as for instance a bottle, the connection between the storage container and the reservoir being provided with a pouring pipe and a ventilation channel. In this reservoir there is a venting possibility and a clock accessible to the liquid, with an overflow drop pipe therein for a deliberately effected siphoning of the liquid contents of the reservoir, preferably via a pouring spout, in another container. The aeration channel to the container of the liquid opens into the clock and the channel is closed as soon as a liquid lock is formed by the liquid that is transferring into the reservoir or rising in the reservoir.

The great advantage of a dosing device according to this invention is the surprisingly simple construction without moving parts, and without other seals than those necessary for obtaining a seal between the bottle and the doser, which works well under all circumstances.

Furthermore, the device according to the invention has been developed such that the bell in the preferred embodiment has a (roughly) cylindrical shape and is directed downwards, towards the bottom of the reservoir and that the overflow down pipe extends below the bell to the same the bell cap and that the dump pipe comes out close to the bottom of the reservoir while the vent pipe opens at the top of the reservoir and the vent pipe from the bottle-shaped container opens into the space inside the overflow down pipe.

The advantage of this is a good, reliable and stable operation of the device.

In a first embodiment of the device according to the invention, the opening of the aeration channel is positioned such that the level of the liquid in the reservoir can rise above the edge of the overflow downpipe, after which the siphon action empties the reservoir while at the same time the aeration channel to the liquid container. liquid lock is closed.

The advantage of this is that a dosing device has been created in which the liquid lock makes seals and moving parts superfluous.

A further important advantage of a dosing device according to this invention is that a very precisely measured amount of liquid is dosed at short intervals as long as the dosing device in its first embodiment (described here) is kept in the position necessary for the flow through that is, with the spout outflow opening downwards.

In a second embodiment of the device according to the invention, the outlet of the aeration channel of the liquid container is arranged below the level of and outside the overflow down pipe and an auxiliary device is arranged to increase the liquid in the reservoir to such a level that the siphon to the overflow down pipe is operated.

This auxiliary device comprises, for example, a floating body with accessories which initially rests on the liquid level in the reservoir. This floating body can be submerged, for example, with the aid of levers.

A further development is that this floating body can be provided with a (soft iron) core so that it can be submerged by electromagnetic means. Furthermore, other ways of moving the floating body by means of influencing from the outside are conceivable, such as, for example, by means of a remote control, whether or not computer-controlled.

In a further developed embodiment of this second embodiment of the device, the reservoir itself, for example with the aid of a glass placed against it, is moved relative to a submersible body, so that the liquid level rises to above the overflow down pipe and the siphoning action begins.

The advantage of this is that a dosing device has been created with a limited number of parts and without seals other than what is necessary for obtaining a seal between the bottle and the doser.

Furthermore, when it comes to the device according to the invention for placement on most conventional bottles, a stop has been developed that is adaptable in a simple manner to the usual bottle necks, from small to large. A compressible and stretchable, flexible sleeve is slid into a (cylindrical) tube. This sleeve is designed such that the outer diameter becomes larger when its length is forced to be shortened by squeezing this sleeve in the longitudinal direction.

The tube around which the sleeve fits relatively tightly can be threaded over part of it and in this way the desired length change can be achieved by tightening a nut. In a further preferred embodiment a nut and a disc are included between the sleeve, with the aid of which the friction between the nut and the sleeve is so great that a sleeve clamped in the bottle neck loosens the nut by a rotary movement on the dosing device, so that the length is greater and so the outer diameter of the sleeve becomes smaller.

The advantage of this is that the device provided with this stopper can be fixed firmly and airtight on bottle necks of small to large size and that it can also be removed in a simple manner.

For an automated processing of the number of dispensed doses, the different embodiments as described above can be provided with a sensor that measures the liquid level. This information can be electronically or wirelessly communicated to a processing system.

The advantage of this set-up is that an automated and reliable device has been created for the dosed dispensing of liquids, whereby no energy is required for determining the amount of liquid to be dispensed.

With reference to the exemplary embodiments shown in the drawings, the first discussed device according to the invention will now be further discussed and explained.

Figure 1: Shows a longitudinal section of the first embodiment of the metered liquid dispenser, which does not have to be repositioned if more than one dose is to be performed successively.

Figure 2: Shows a longitudinal section of the first embodiment of the device according to the invention, provided with a floating body.

Figure 3: Shows a longitudinal section of the second embodiment of the device according to the invention with movable reservoir.

Figure 4: Shows a longitudinal section of the stopper of the device according to the invention regarding the connection to the bottle.

Figure 1 shows a longitudinal section of the first embodiment of the device (1) according to the present invention, which is mounted on a bottle (2) by means of a sealing and stop construction (3). The liquid (4) is located in the bottle (2). In the position shown in this figure, the liquid flows through the pouring pipe (5) into the reservoir (7). The reservoir (7) is vented through a vent pipe (11). The liquid rises to a level (8) determined by the construction and the reservoir content (7) of the doser (1). The clock (9) with the overflow downpipe (10) is located in the reservoir (7). When the liquid in the reservoir (7) rises, it is bled by a venting pin (11). When the liquid has reached the pre-programmed level (8), the siphon action starts via the overflow down pipe (10), while at the same time a liquid lock is created, which closes the aeration pipe (12) to the container (2). The supply of liquid (4) from the bottle (2) through the pouring pipe (5) stops as soon as the bottle (2) is no longer aerated because the liquid level (8) has been reached. The liquid contained in the reservoir (7) leaves the device through the siphon action via the overflow downpipe (10). If the siphon stops due to a lack of liquid, the liquid lock is also released and liquid (4) can flow from the bottle (2) back into the reservoir. As long as the bottle (2) is not inverted, a new dose is then halved until the bottle (2) is completely empty.

Figure 2 shows in longitudinal section a second embodiment of the device according to the present invention. The device (1), which is attached to a bottle (2) by means of the stop construction (3), is permanently upside down. The bottle contains liquid (4). In the position shown, the liquid (4) flows through a pouring pipe (5) into the reservoir (7). The reservoir (7) is bled through a vent pipe (11). When the liquid reaches a predetermined level (8) programmed in the manufacture of the measuring doser (1), a liquid lock is created, which closes the aeration pipe (12). The supply of liquid (4) from the bottle (2) through the pouring pipe (5) stops, because the bottle (2) is no longer aired. There is a clock (9) in the reservoir (7) with an overflow fall pipe (10) underneath. After immersion of a floating body (13), for example via a lever system or by electromagnetic means or moved in any way, the siphon action begins, whereby the liquid level is slightly increased and thus the lifting action is initiated. The liquid (4) contained in the reservoir (7) leaves the device (1) through the siphon action via the overflow downpipe (10). If the siphoning action stops due to lack of liquid, the liquid lock is also released and weather liquid can flow from the bottle into the reservoir.

In the special embodiment shown in Figure 3 of the present invention, the reservoir (7) is movably mounted relative to the lid (6). A submersible body (13) is attached to the lid (6). By moving the reservoir (7) upward, this body (13) moves enough fluid to raise the fluid level (8) above the edge of the overflow downcomer (10) to initiate the siphon action.

The plug (3) shown in Figure 4 of the present invention consists of a compressible and stretchable sleeve (14) which is slid over a cylindrical part (15). A part of the cylindrical part is threaded (16). The desired length and circumference of the sleeve can be set by tightening a nut (17). Since the sleeve is enclosed between a nut and a rotatable disc (18), a sleeve clamped in the bottle neck can be widened by rotating the dosing device. When the nut (17) loosens, the length increases and the outer diameter of the housing becomes smaller.

Claims (14)

Device for dosed dispensing of liquids, characterized in that the device must be placed on a liquid container by means of a sealing device and that this liquid container is connected via a pouring pipe to a reservoir in which there is an aeration pipe and a front the liquid accessible clock, within which there is again an overflow down pipe and a liquid pipe aeration pipe for the purpose of effecting a siphoning overflow of the reservoir contents to the outside of the assembly of liquid container and dosing device if the assembly of liquid container and dosing device is kept in the position intended for outflowing, in that in case the liquid flows out of the above-mentioned assembly via a pouring spout, while at the same time a liquid lock is formed in the aeration channel towards the liquid container by the liquid draining from the bell and this, by preventing the aeration from the fluid container, the supply of a new amount of fluid from the fluid container to the reservoir is prevented as long as the fluid lock is maintained by the outflowing and / or the clock fluid. Device according to claim 1, characterized in that the clock has a global cylindrical shape and is directed downwards towards the bottom of the reservoir and that the overflow down pipe extends below the clock to just below the clock cap. 3. Device as claimed in claim 1, characterized in that the aeration channel of the container with liquid opens into the space inside the clock outlet. 4. Device as claimed in claim 1, characterized in that the level of the liquid in the reservoir rises above the edge of the overflow down pipe, after which the reservoir is drained by siphoning, while the aeration channel to the liquid container is closed by a liquid lock. 5. Device as claimed in claim 1, characterized in that the aeration of the liquid container can also open briefly below the level of and outside the overflow downpipe and in that case a device is arranged to raise the liquid in the reservoir so as to enable the siphon can be operated via the overflow down pipe. 6. Device as claimed in claim 5, characterized in that the device for raising the liquid in the reservoir includes a floating body which initially floats on the liquid in the reservoir. Device as claimed in claim 5, characterized in that the reservoir can be moved relative to an immersible body, so that the liquid level rises and the siphoning action begins. 8. Device according to claim 6, characterized in that the floating body is also submersible by an electrically energizable device. Device as claimed in claim 3, characterized in that the indication that the siphon is activated can be electronically transmitted to a processing unit. 10. Attachment device for sealingly placing a pouring device on a liquid container, characterized in that this attachment device consists of a sleeve designed in such a way that the outer diameter thereof can be increased or decreased by change in length, which length change is also reversible if the stopper catches in the bottle neck in order to remove the pouring device from the bottle again. Devices according to the preceding claims, characterized in that they are preferably made of plastic. Devices according to the preceding claims, characterized in that they can also be made in other materials. 13. Device, characterized in that it substantially follows the device described in claims 1-11. 14. Device as claimed in claim 8, characterized in that in the electric coil a chip with microprocessor can be placed, whereby the number of times the coil is energized can be counted on the spot or by transmitting the number of pulses to a remote counting device. .