NL1012395C2 - Dosing device used in beverage preparation apparatus, has gear pump in liquid flow path connecting housing inlet and outlet, while housing inlet is connected to storage space of holder - Google Patents

Abstract

A housing (6a) has a liquid flow path connecting an inlet (2) and an outlet (4) through which the liquid flows. The diluted viscous concentrate contained in the storage space of holder linking with housing inlet, is dispensed in a metered manner. A gear pump (8) in the liquid flow path is driven by a rotor (16) by the magnetic field change. Independent claims are also included for the following: (a) Dilute concentrate filled holder; (b) Beverage preparing apparatus

Description

Title: Dosing device arranged for dosed dispensing of a viscous concentrate from a container.

The invention relates to a metering device comprising at least one inlet, at least one outlet and a liquid flow path extending from the inlet to the outlet, the metering device being arranged for metered delivery of a viscous concentrate from a container in which the concentrate is incorporated, wherein the concentrate in diluted form gives a product suitable for consumption, the container is provided with a storage space in which the concentrate is incorporated and wherein the inlet of the dosing device is arranged to, in use, storage space of the container.

Such a device is known from British patent application 2103296. The dosing device described herein is provided with a hollow cylindrical body which is made of a flexible elastic material. The affected body encloses a pump volume. Furthermore, the device is provided with an operating element for compressing the body in an axial direction. The device also comprises a hollow cylindrical housing which is arranged to include said body on its outside at least during the phase in which the pump volume is reduced. The flexible body is deformed cyclically in an axial direction, with the result that a predetermined amount of extract is released with each cycle. The control element is driven for this purpose by means of a pulsating magnetic field. To drive the operating element, the metering device is placed in a unit for generating a pulsating magnetic field. With a pulsating magnetic drive, the position of the metering device relative to the unit in the axial direction of the metering device has a great influence on the force to be delivered.

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This makes placing the dosing device in the unit very critical.

The known dosing device also has the drawback that its operation depends on the viscosity of the concentrate. A further drawback is that the dosing device is relatively expensive. It is also a disadvantage that the known dosing device is provided with a relatively heavy metal operating element. This metal control element. poses an additional burden on the environment when the dosing device is designed as a disposable article.

The object of the invention is to provide a solution to the problems outlined above. The metering device according to the invention is to this end characterized in that the metering device is provided with a gear pump incorporated in the liquid flow path.

Because the dosing device is provided with a gear pump included in the liquid flow path, it is no longer necessary, as with the known device, to use a pulsating drive. Since a pulsating drive can be omitted, placing the dosing device in a dispensing machine need not be critical.

Furthermore, the metering device can be designed economically and in an environmentally friendly manner thanks to the gear pump. It is no longer necessary to use relatively heavy metal parts.

Finally, the rotating parts of the gear% pump function as a stirrer for the concentrate. If the concentrate threatens to thicken, the concentrate leaving the dosing device will again have a homogeneous structure thanks to the gear pump.

A further advantage of the device according to the invention is that the dosage can be infinitely adjusted. In addition, the dosing device can be designed with a low construction height.

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According to a more advanced embodiment, the dosing device upstream of the gear pump is provided with a rotor mechanically connected to the gear pump for driving the gear pump by means of a changing magnetic field. A first advantage is that the changing magnetic field does not have to be high frequency. A second advantage is that the rotor can be included in the liquid flow path so that it also has the function of a stirrer. In particular, it holds that the dosing device is driven by a drive shaft, an axial axis of which is directed towards the inlet and the outlet. Because a dynamic fluid seal of the drive shaft can be lacking, there is a relatively little energy loss and there is a very small chance of leakage or contamination. The rotor also ensures a good start-up with sediment. The rotor then loosens the sediment.

The specific direction of the drive shaft also ensures that the dosing device can be placed rotationally independently in a dispensing machine. If the dosing device is connected to a container filled with the concentrate, this connection can also be made rotation-independent.

According to the preferred embodiment, it holds that the dosing device is provided with a substantially rotationally symmetrical housing, an axial axis of which extends in the direction from the inlet to the outlet. In particular, it holds that the metering device downstream of the gear pump includes a valve included in the fluid flow path which opens when the fluid pressure upstream of the valve exceeds a predetermined threshold. The use of a gear pump in combination with a pressure relief valve has the advantage that there is no leakage current through internal clearances in the non-driven state. In addition, the lid provides a 4 microbiological seal, which is important for drinks suitable for consumption.

The container according to the invention is characterized in that it is filled with the concentrate which is suitable for consumption in dilute form, the container being provided with a dosing device according to the invention as described above.

Because the dosing device according to the invention can be made low in axial direction, less length is required to drive than with the known linear magnet. This creates the possibility of making the dosing device pull-out instead of folding out, so that a tear strip in the holder, when it is designed as a so-called back in box, can be dispensed with. In particular, it therefore holds that the container is provided with a bag formed of a flexible sheet-shaped material in which the concentrate is received and a housing in which the bag is received.

The invention also relates to a device for preparing a drink suitable for consumption, the device being arranged to be loaded with a container as mentioned above. The device is provided with a magnetization unit for generating at least one magnetic field that changes so that the rotor is driven for dispensing concentrate from the container dosed by the dosing device. The device is also provided with means "k" for diluting the dispensed concentrate with water to obtain the drink suitable for consumption. The magnetization unit may include a magnet and drive means for rotating a magnet to generate the changing magnetic field. However, it is also possible that the magnetization unit is provided with a plurality of coils to generate the changing magnetic field. The invention also relates to an assembly comprising a device for preparing the beverage suitable for consumption and a container as described above. The device is hereby arranged to be loaded with the container, the device being provided with drive means for driving the dosing device for dispensing concentrate from the container dosed by the dosing device and means for diluting the dispensing of concentrate with water to obtain the beverage suitable for consumption.

The invention will now be further elucidated with reference to the drawing. Herein shows

Fig. 1 is a possible fragmented embodiment of a dosing device according to the invention, which is connected to a container according to the invention. Fig. 1 also shows a magnetization unit of an apparatus for preparing a drinkable beverage; Fig. 2 shows a number of parts of the dosing device according to Fig. 1; Fig. 3 shows a number of parts of the dosing device and the device for preparing a drink suitable for consumption according to Fig. 1; and Fig. 4 shows a container with a dosing device according to the invention, a device for preparing a drinkable beverage according to the invention and an assembly comprising the device and the container according to the invention.

In Figs. 1-4, reference numeral 1 denotes a dosing device according to the invention. The dosing device is provided with an inlet 2 and at least one outlet 4.

The liquid flow trajectory extends from the inlet 2 to the outlet 4. In this example, the metering device is provided with a two-part housing 6a and 6b, which is rotationally symmetrical. It is arranged about an axis in the direction of the liquid flow path.

A gear pump i8 is included in the housing 6a, 6b. The gear pump 8 is provided on its top side 5 with a cover plate 10 with an inflow opening 12. The inflow opening 12 is in fluid communication with a space where the teeth of in this case two gears 14a and 14b interlock. The gear wheel 14b is driven by a drive shaft 16 which, in mounted condition, extends through an opening 18 of the cover plate 10. The gear pump 2 is provided on its underside with an outflow opening 20 for dispensing liquid. The drive shaft 16 is oriented such that an axial axis of this drive shaft is directed towards the inlet 2 towards the outlet 4. In this example, the housing 6a, 6b is substantially rotationally symmetrical about the axial axis which also extends in the direction of the inlet 2 to the outlet 4.

Upstream of the gear pump 8, the metering device is provided with a rotor 22 mechanically connected to the gear pump, in this example mechanically connected to the rotary shaft 16. This rotor 22 is mounted above the cover plate 10. The rotor can be moved by means of be driven from an external drive for rotating the gear pump 8. Preferably, however, the rotor is adapted to be driven by means of a changing magnetic field to drive the gear pump 8.

In this example, it further holds that the rotor 22 is included in the said liquid flow stage. In this example, the rotor is provided with a permanent magnet for driving the rotor without contact by means of at least one magnetic field. In particular, in this example, the rotor comprises a plurality of arms 24 extending in the radial direction of the axis of rotation (drive shaft 16). The ends of the arms form poles of the said permanent magnet. The poles of the permanent magnet will want to follow the changing magnetic field, causing the rotor and drive shaft 16 to rotate. The device described up to this point works as follows. Suppose that the inlet 2 of the dosing device is connected to a container 26 schematically shown in Figs. 1 and 4 in which an amount of concentrate, such as, for example, coffee concentrate, is present. The container 26 is, as is well shown in Fig. 4, provided with the dosing device according to Fig. 1. In this example, the container 26 is provided with a bag 28 formed by a flexible sheet-shaped material in which the concentrate is received and a housing 30 in which the bag 28 is received. The housing 30 is preferably made substantially rigid and therefore more rigid than the bag 28. The inlet 2 of the dosing device is in fluid communication with the inside of the bag 28. By now creating a magnetic field that changes in a predetermined manner waking will rotate in a predetermined manner by rotor 22. This will also cause the gear pump 8 to rotate, with the result that concentrate flows through the inflow opening 12 and the space between the teeth of the gears to the said outflow opening 20. This corresponds to the amount of concentrate dispensed in a dosed manner with the angle of rotation over which the rotor 22 is rotated. The relationship is essentially linear.

In Fig. 4, reference numeral 31 designates another device for preparing a beverage suitable for consumption. The device 31 is arranged to be loaded with the holder 26. The device includes a magnetization unit 32 for generating said changing magnetic field for driving the rotor. The device is further provided with means 34 for diluting the concentrate supplied by the dosing device 1 with water. These means 34 comprise a hot water generator 36 and a mixing unit 1012395 ^ 8 38. In use, the housing 6a, 6b of the dosing device is inserted through an opening 40 of the magnetizing device such that the outlet 4 of the dosing device reaches into an opening 42 of the mixing device 38 extends. The control unit 44 of the device 31 controls the magnetization unit 32 via line 45 such that a changing magnetic field is generated such that the rotor 22 rotates along a predetermined angle of rotation. As a result, a predetermined amount of concentrate is dispensed from the container 26 to the mixing device 38. The control unit 44 also activates the hot water unit 36 and the mixing unit 38 via electrical lines 46 and 48, respectively. This causes hot water to be sent from the hot water unit 36 to the mixing unit 38. In the mixing unit the hot water is mixed with the dispensed concentrate, after which the concentrate leaves an outlet opening 50 of the device 31 in a diluted state and therefore in a state of a drink suitable for consumption.

In this example, the magnetization unit 32 for 20 is shown to have a plurality of coils 52 to generate the changing magnetic field.

The invention is by no means limited to the above-described embodiments. For example, the rotor 22 can also only be provided with soft iron. In that case, the rotor 22 can be driven in a manner known per se, as is known for an eddy current motor. In that case, the soft iron is magnetized with the aid of a first magnetic field and the magnetized soft iron 30 is controlled by means of a second changing magnetic field so that the rotor starts to rotate.

It is also possible for the coils 52 to be replaced by permanent magnets, these magnets being rotated mechanically to generate the changing magnetic field.

A further valve 54, which opens when the JC s s r *, can further be included in said outflow opening 20. t, ·. ·. The fluid flow pressure upstream of the valve exceeds a predetermined threshold value. This is a so-called unidirectional valve, which in this example is designed as an umbrella valve.

In this example, the housing 6a and 6b is made of a suitable plastic. The gears 14a and 14b and the drive shaft 16 are also made of plastic. The only metal part is therefore the rotor 22. Such variants are each considered to fall within the scope of the invention.

Claims (21)

1. Metering device comprising at least one inlet, at least one outlet and a liquid flow stage extending from the inlet to the outlet, the metering device being arranged for metered dispensing of a viscous concentrate from a container in which the concentrate is received wherein the concentrate in diluted form gives a product suitable for consumption, the container is provided with a storage space in which the concentrate is incorporated, and the inlet of the dosing device is arranged to become, in use, with the storage space of the container connected, characterized in that the metering device is provided with a gear pump incorporated in the liquid flow stage. 2. Dosing device according to claim 1, characterized in that the dosing device is driven by a drive shaft of which an axial axis is directed in a direction from the inlet to the outlet. 3. Dosing device according to claim 1 or 2, characterized in that the dosing device is provided with a substantially rotationally symmetrical housing, an axial axis of which extends in the direction from the inlet to the outlet. Metering device according to any one of the preceding claims, characterized in that the metering device downstream of the gear pump is provided with a valve included in the liquid flow stage which opens when the liquid pressure upstream of the valve exceeds a predetermined threshold value. A metering device according to any one of the preceding claims, characterized in that the metering device upstream of the gear pump is provided with a rotor mechanically connected to the gear pump for driving the gear pump by means of a changing magnetic field. Metering device according to claim 5, characterized in that the rotor is included in the liquid flow stage. Metering device according to claim 5 or 6, characterized in that the rotor is provided with a magnetizable material such as soft iron. Metering device according to claim 5, 6 or 7, characterized in that the rotor comprises a permanent magnet for driving the rotor without contact by means of at least one magnetic field. 9. Dosing device according to any one of claims 5-8, characterized in that the rotor comprises a plurality of arms extending in radial direction of the axis of rotation. Metering device according to claims 8 and 9, characterized in that the ends of the arms form poles of the permanent magnet. 11. Container filled with concentrate which is suitable for consumption in a diluted form, wherein the container is provided with a dosing device according to any one of the preceding claims. 12. Container according to claim 11, characterized in that the container is provided with a bag formed of a flexible sheet-shaped material in which the concentrate is accommodated and a housing in which the bag is accommodated. Container according to claim 12, characterized in that the • V inlet of the dosing device is connected to the bag. 14. Holder as claimed in any of the claims 11-13, characterized in that the housing is more rigid than the bag. 15. Device for preparing a drink suitable for consumption, the device being arranged to be loaded with a container according to any one of the preceding claims 11-14, which is provided with a dosing device according to any one of claims 5-10 of claims 1 The device being provided with a magnetization unit for generating at least such a changing magnetic field that the rotor is ape-driven '4 for dispensing 5 concentrates dosed by the dosing device from the container and means for diluting the dispensing concentrate with water to obtain the beverage suitable for consumption. 16. Device as claimed in claim 15, characterized in that the magnetization unit is provided with a magnet and drive means for rotating the magnet for generating the changing magnetic field. Device according to claim 15, characterized in that the magnetization unit is provided with a plurality of coils. 18. Assembly provided with a device for preparing a drinkable beverage and a container according to any one of the preceding claims 12-14, wherein the device is arranged to be loaded with the container and wherein the device is provided with drive-20 means for driving the metering device for dispensing concentrate dosed from the container by the metering device and means for diluting the dispensed concentrate with water to obtain the beverage suitable for consumption. 19. Assembly as claimed in claim 18, wherein the holder is provided with a dosing device according to any one of claims 5-10, characterized in that the device is further provided with a magnetization unit for generating at least such a changing magnetic field that the rotor is driven for dispensing concentrate from the container in a dosed manner. 20. An assembly according to claim 19, characterized in that the magnetization unit is provided with a magnet and driving means for rotating the magnet to generate the changing magnetic field. 21. An assembly according to claim 19, characterized in that the magnetization unit is provided with a plurality of coils. V • ^ ‘s i · · V