MIXING AND FOAMING DEVICE

Abstract

The invention refers to a mixing and foaming device (300) for mixing a powder food or beverage product with a fluid and further foaming said mixture, the device (300) comprising a mixing, pumping and foaming unit (102), an air entry (30) and a fluid inlet (21); the mixing, pumping and foaming unit (102) comprising a pumping element (110) whose rotation allows both powder and fluid to enter a foaming chamber (121) of the mixing, pumping and foaming unit (102), where a foaming element (120) rotates relatively within the foaming chamber (121), subjecting the mixture of fluid, powder and optionally air to a certain level of shear stress which allows this mixture to mix and/or to foam. The invention further refers to a method for providing foam from a food or beverage product powder using such a device (300).

Claims

1. Mixing and foaming device for mixing a powder food or beverage product with a fluid and further foaming the mixture, the device comprising: a mixing, pumping and foaming unit, an air entry and a fluid inlet; and the mixing, pumping and foaming unit comprising a pumping element whose rotation allows both powder and fluid to enter a foaming chamber of the mixing, pumping and foaming unit, where a foaming element rotates relatively within the foaming chamber, subjecting the mixture of fluid and powder to a certain level of shear stress which allows this mixture to mix and/or to foam.

2. Mixing and foaming device according to claim 1 wherein the pumping element and the foaming element are both rotatable around a shaft and are entrained in rotation by driving means.

3. Mixing and foaming device according to claim 1 wherein the foaming element comprises a rotatable element with respect to a stationary part in the foaming chamber defining a gap where the mixture of fluid and powder is driven under shear stress.

4. Mixing and foaming device according to claim 3 wherein the rotatable element has a form selected from the group consisting of a cylinder, a cone, and a disc.

5. Mixing and foaming device according to claim 3 wherein the gap in the foaming chamber is between 0.2 and 1 mm.

6. Mixing and foaming device according to claim 1 wherein the pumping element comprises gears.

7. Mixing and foaming device according to claim 6 wherein the module and/or number and/or height of the teeth configuring the gears in the pumping element, and the shape and/or size of the foaming element are calculated so as to have a specific balance of the mixing performance, the pumping performance and the foaming capability, respectively, provided by the device.

8. Mixing and foaming device according to claim 1 wherein the pumping element and the foaming element rotate at a speed comprised between 2000 and 10000 rpm.

9. Mixing and foaming device according to claim 1 comprising a valve regulating the amount of air introduced through the air entry.

10. Mixing and foaming device according to claim 1 comprising a check valve connected to the air entry preventing any back-pumping of fluid and/or powder.

11. Mixing and foaming device according to claim 1 comprising a heating unit allowing heating the foam from the mixing, pumping and foaming unit before it is delivered.

12. Mixing and foaming device according to claim 1 wherein the powder food or beverage product is in a container together with the fluid, the rotation of the pumping element pumping both fluid and powder from the container into the foaming chamber.

13. Mixing and foaming device according to claim 1 wherein the powder food or beverage product is comprised in a reservoir.

14. Mixing and foaming device according to claim 13 wherein the rotation of the pumping element pumps fluid into the reservoir where it is diluted with powder, the rotation of the pumping element further pushing fluid and powder into the foaming chamber.

15. Method for providing foam from a food or beverage product powder using a device, comprising the steps of: a) pumping fluid and powder from a container into a foaming chamber by rotating a pumping element; b) mixing fluid and powder in the foaming chamber by relatively rotating the foaming element within the foaming chamber and sending this mixture to the container; c) repeating steps a) and b) one or a plurality of times; d) opening the air entry to a certain level; e) pumping from the container into the foaming chamber the mixture of fluid and powder, together with air from the air entry by rotating the pumping element; and f) subjecting the mixture of fluid and powder, together with air, to shear stress in the foaming chamber so that it foams.

16. Method for providing foam from a food or beverage product powder using a device for mixing a powder food or beverage product with a fluid and further foaming the mixture, the device comprising: a mixing, pumping and foaming unit, an air entry and a fluid inlet; and the mixing, pumping and foaming unit comprising a pumping element whose rotation allows both powder and fluid to enter a foaming chamber of the mixing, pumping and foaming unit, where a foaming element rotates relatively within the foaming chamber, subjecting the mixture of fluid and powder to a certain level of shear stress which allows this mixture to mix and/or to foam, comprising the steps of: a) pumping fluid into a reservoir by rotating the pumping element, so that the powder is diluted with the fluid; b) mixing fluid and powder in the foaming chamber by relatively rotating the foaming element within the foaming chamber and sending this mixture to a fluid container; c) repeating steps a) and b) one or a plurality of times; d) opening the air entry to a certain level; e) pumping from the fluid container into the reservoir and then sending to the foaming chamber the mixture of fluid and powder, together with air from the air entry by rotating the pumping element; and f) subjecting the mixture of fluid and powder, together with air, to shear stress in the foaming chamber so that it foams.

17. Method for providing foam from a food or beverage product powder according to claim 15, comprising a step where the foam is heated in the heating unit before it is finally delivered.

18. Method for providing foam from a food or beverage product powder according to claim 16, comprising a step where the foam is heated in the heating unit before it is finally delivered.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0033] Further features, advantages and objects of the present invention will become apparent for a skilled person when reading the following detailed description of non-limiting embodiments of the present invention, when taken in conjunction with the appended drawings, in which:

[0034] FIG. 1 shows a schematic view of a mixing and foaming device according to a first possible embodiment of the present invention.

[0035] FIG. 2 shows a schematic view of a mixing and foaming device according to a second possible embodiment of the present invention.

[0036] FIG. 3 shows a schematic view of a mixing and foaming device according to a third possible embodiment of the present invention.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

[0037] The present invention addresses a device 300 for efficiently mixing, pumping and foaming a powder for the preparation of beverages or food products. As it will be further explained in detail, the device 300 allows for efficiently foaming the mixture of fluid and powder using the Couette Flow effect.

[0038] With reference to FIG. 1, the device 300 of the invention typically comprises a container 20 where a powder and a fluid (typically water) are arranged: the powder and fluid are not well mixed yet, so the powder is roughly dispersed in the fluid. The container 20 can also be a glass, a cup or similar not being part of the device. The device 300 further comprises a mixing, pumping and foaming unit 102 where the fluid and powder will be pumped and also foamed. The mixing, pumping and foaming unit 102 comprises a pumping element 110 and a foaming element 120, effecting pumping and foaming functions, respectively. The device 300 further comprises a fluid inlet 21 communicating the mixing, pumping and foaming unit 102 with the container 20 and an air entry 30 communicating with the fluid inlet 21: preferably, the air entry 30 comprises a check valve 33 preventing any pumping of fluid and/or powder into the air entry 30, and a valve 31 for regulating the amount of air introduced through the air entry 30 into the fluid inlet 21. Optionally, the device 300 can further comprise a heating unit 103 for heating the foam before it is delivered through a foam outlet 40. Driving means 104 are needed to drive the mixing, pumping and foaming unit 102: these driving means 104 can be either provided in the device 300 itself or they can be arranged externally, in a machine to which the device is connected.

[0039] The device 300 of FIG. 1 works as it will be explained in what follows. Preferably, the pumping element 110 is configured as a pair of gears, such that their rotation is able to suck/pump fluid and powder from the container 20 through the fluid inlet 21, and possibly also air from the air entry 30. The foaming element 120 comprises a rotating element with respect to an external fixed element, configuring a thin gap between the two elements (foaming chamber 21) through which a mixture is subjected to high shear stress and can therefore be foamed. The typical configurations of the foaming element 120 are of a cylinder, or of a cone or of a disc. First, the valve 31 closes the air entry 30 so, when the gears rotate, only powder and fluid are pumped from the container 20 into the pumping and foaming unit: as there is no air, the powder and fluid are actually not foamed but only mixed in the pumping element 110 and further in the foaming element 120. Further loops can be made with no air being added into the mixture, in order to efficiently mix powder and fluid, which are then sent to the container 20 through the foam outlet 40. The mixture of powder and fluid is now considered as a fluid itself. In a later stage, the valve 31 is opened and regulates a certain amount of air introduced into the fluid inlet 21 (further, the check valve 33 avoids any fluid or powder going into the air entry 30, as represented in FIG. 1. The rotation of the gears now pumps the mixture of fluid and powder from the container 20 and also air from the air entry 30: this mixture is foamed by Couette Flow effect in the foaming chamber 121 of the foaming element 120, and it is delivered into the container 20 through the foam outlet 40. As the foam is of less density than the rest of the mixture (fluid and powder), it is deposited on the top part of the container 20, over the mixture of fluid and powder: further iterations allow that the pumping element 110 (as shown in FIG. 1, the fluid inlet 21 is connected to the bottom part of the container 20) pumps the mixture of fluid and powder, which is foamed in the foaming element 120 and is deposited on top in the container 20, until the whole content of the container has been foamed (or the amount of it that is desired). Optionally, the foam can be heated before being delivered in the container 20, by means of a heating unit 103 connected before the foam outlet 40.

[0040] One advantage of the invention is that one single driving means 104 entrain in rotation both the pumping element 110 and the foaming element 120, so with one rotation the actions of pumping and mixing (when no air is added through the air entry 30) or pumping and foaming (when air is added through the air entry 30) are achieved.

[0041] With reference now to FIG. 2, a device 300 according to a second preferred embodiment is disclosed: the device 300 comprises a container 20 where fluid (typically water) and powder are arranged, communicating with a mixing, pumping and foaming unit 102 through a fluid inlet 21. Similarly, the mixing, pumping and foaming unit 102 comprises a foaming element 120 with a foaming chamber 121 and a pumping element 110. Driving means 104 entrain in rotation both the foaming element 120 and the pumping element 110; these driving means 104 can be part of the device 300 or can be arranged externally, as part of a machine to which the device 300 is connected. The device 300 further comprises an air entry 30 through which air is introduced in the fluid inlet 21 and from there into the mixing, pumping and foaming unit 102, the quantity of air being regulated by means of a valve 31. The air entry 30 is preferably further provided with a check valve 33 allowing the entry of air through the air entry 30 and into the fluid inlet 21, but preventing any backflow of fluid from the fluid inlet 21 into the air entry 30. Further, the device 300 according to this second embodiment comprises a three-way valve 42 and an optional heating unit 103, the three-way valve 42 allowing communication of the exit of the mixing, pumping and foaming unit 102 either with a container outlet 41 or with the heating unit 103 and, from there, with the foam outlet 40. According to this second embodiment of the invention, there is a container outlet 41 communicating the outlet of the mixing, pumping and foaming unit 102 with the container 20 and a final foam outlet 40 (once the foam is prepared and is finally delivered) communicating directly with a cup or container, ready for consumption.

[0042] The device 300 of FIG. 2 works as it will be now explained in detail. The pumping element 110 is preferably configured as gears: their rotation pumps powder and fluid from the container 20 through the fluid inlet 21: the valve 31 is closed so no air is added through the air entry 30: the mixture of fluid and powder pumped is mixed by passing through the pumping element 110 and further through the foaming element 120: the three-way valve 42 is in a position where the container outlet 41 is open and the foam outlet 40 is closed. Therefore, the mixture of fluid (typically water) and powder is sent again into the container 20 through the container outlet 41. Further iterations as the one described are effected so that the fluid and the powder are intimately and properly mixed. Moreover, as the fluid inlet 21 is configured as a pipe connected to the bottom of the container 20, the remaining powder (which is heavier and therefore tends to be arranged at this bottom) will be pumped into the mixing, pumping and foaming unit 102 until the whole content of the container 20 has been properly mixed. Once the mixture has been prepared, the valve 31 is opened and regulated according to the desired amount of air that has to be introduced through the air entry 30: therefore, by the rotation of the pumping element 110, both the mixture (fluid and powder) from the container 20 and the air from the air entry 30 are pumped into the foaming element 120, particularly into the foaming chamber 121 where the mixture together with air is foamed. The three-way valve 42 is now in a position where the container outlet 41 is closed and the foam outlet 40 is opened. Therefore, once the mixture and air is foamed in the foaming element 120, it can optionally be heated in the heating unit 103 and then, heated or not, is sent through the foam outlet 40 directly into cup.

[0043] Reference is made now to FIG. 3, where a device 300 according to a third preferred embodiment of the invention is shown. In FIG. 3 it is shown another possibility of the device 300 that uses a sachet or pouch 50 where powder is arranged, which is further diluted with fluid (preferably with water) coming from a container 20. The sachet 50 is connected to the device 300 in order to produce the foam, as represented in FIG. 3. Even if a pouch or sachet has been depicted, other possible containers 50 such as a capsule or the like can be similarly used, comprising the powder. Preferably, these containers (pouch, sachet, capsule, etc.) are made disposable but they can also be configured as a cavity for example that will be filled with powder by the user. The device 300 of FIG. 3 comprises similar elements as those in FIG. 1 or 2: a mixing, pumping and foaming unit 102, comprising a foaming element 120 with a foaming chamber 121 and a pumping element 110, driving means 104 entraining in rotation both the foaming element 120 and the pumping element 110, and a heating unit 103 for optionally heating the foam before it is delivered through the foam outlet 40. The device 300 further comprises a fluid inlet 21 and an air entry 30, the air entry being regulated through a valve 31 and preferably also comprising a check valve 33.

[0044] The device shown in FIG. 3 works as it will be now explained. The sachet or pouch 50 comprising the powder is connected to the mixing, pumping and foaming unit 102 of the device. First, the valve 31 regulating the air into the air entry 31 is closed, so when the pumping element 110 (typically configured as gears) rotates, only fluid is pumped from the container 20 through the fluid entry 21 into the sachet 50, so the powder is diluted with the fluid coming from the container 20. Further, both powder and fluid are sent into the foaming element 120 and, when passing through the foaming chamber 121, fluid and powder are mixed and are then sent back to the container 20 through the foam outlet 40. This operation is repeated a plurality of times, until powder and fluid are intimately and properly mixed. Once the mixture has been obtained in the container 20, the valve 31 opens and, when the pumping element 110 rotates, it pumps the mixture from the container 20 and also air from the air entry 30 into the pouch or sachet 50 and, from there, into the foaming element 120. When this mixture of fluid and powder together with air goes through the foaming chamber 121 and is subjected to shear forces, it is foamed. The resulting foam can then be optionally heated in the heating unit 103 before being delivered into the container 20 through the foam outlet 40. As disclosed for FIG. 1, the produced foam has low density and is therefore arranged on top of the container 20: the fluid stays on the lower bottom of the container 20, so that the fluid inlet 21 pumps fluid from the bottom of the container 20 and the foam outlet delivers prepared foam over it, until the desired ratio of fluid and foam is reached or until the whole of the fluid has been foamed.

[0045] According to the invention, a device is provided that works in different phases: in a first phase, proper mixing of the powder and fluid is achieved and, in a second phase, foaming of this prepared mixture is done by using Couette flow effect subjecting the mixture to high shear stress a foaming chamber.

[0046] Further, the device 300 of the invention is able to produce very high quality foam on demand, having a simple architecture and being easily cleanable. Typically, the parts which are in contact with the fluid (typically milk or a food or beverage product) can be easily detached and cleaned or are made disposable (as the pouch or sachet 50 in FIG. 3).

[0047] The driving means 104 of the invention typically comprises an electrical motor.

[0048] The pumping element 110 and the foaming element 120 are both driven by a single driving means 104: typically, they are both driven in rotation by a same single shaft 130 connected to both, as shown in FIG. 1. The shaft 130 is entrained in rotation by a single motor configuring the driving means 104.

[0049] The pumping element 110 is typically configured as gears (gear elements) rotating at high speed. Preferably, the rotation speed of the pumping element 110 (and also of the foaming element 120 as they rotate at the same speed) is typically comprised between 2000 and 10000 rpm, preferably between 4000 and 8000 rpm. The module (i.e. the size), the number and the height of the teeth configuring the gears in the pumping element 110 need to be carefully chosen, together with the shape and size of the foaming element 120, so as to have a good balance between the pumping performance of the pumping element 110 and the foaming capability of the foaming element 120 (i.e. so as to obtain the desired balance of pumping and foaming in the device). Typically, a too efficient pumping would result in bad quality foam.

[0050] The foaming element 120 in the device of the invention comprises a rotatable part with respect to another part, preferably static, such that a small gap is created between the two configuring the foaming chamber 121, subjecting a product that passes through this gap to high shear forces creating a Couette Flow effect. The rotatable part in the foaming element 120 can be configured as a cone, as a disc or as a cylinder, for example.

[0051] Optionally, the device 300 of the invention can also comprise control means which will manage and control the foaming process parameters in the device 300. It is also possible that the device comprises no control means, meaning that the user will then adjust manually part or all of the parameters of the foaming process in the device.

[0052] Therefore, for a given type of fluid (i.e., the fat and protein content and the processing conditions during the fluid manufacture are fixed values), the properties of the foam obtained (quantity/size of bubbles, stability and overrun) for this fluid will be determined by the foaming process carried out in the device of the invention, specifically by the process parameters detailed as follows. [0053] Fluid flow rate passing from the container 20 into the device 300 which depends on the rotational speed of the mixing, pumping and foaming unit 102 and on the diameter of the fluid inlet 21 providing fluid from the container 20. [0054] Amount of air coming through the air entry 30, also depending on the rotational speed of the pumping element 110 and on the regulation of the adjustable valve 31.

[0055] The sachet or pouch 50 can also comprise a code, typically a bar code, comprising the information of process parameters, which is provided to the control means in the machine to carry out the foaming process in an optimal way.

[0056] In the Couette flow effect carried out in the foaming element 120, the shear stress experienced by the mixture of fluid and powder together with air depends largely on the width of the gap formed between the external surface of the foaming element 120 and the inner walls of the foaming chamber 121: this width is chosen depending on the type of foamable fluid or foamable food or beverage product to be foamed, chosen in such a way that optimal foaming effect by shear (Couette flow) is obtained. Typically, the width of the gap is larger as more viscous the fluid or food to be foamed is: for example, milk would require a smaller gap than liquid yogurt and these last a smaller gap than foamable food or beverage products. Typically, the width of the gap for milk is around 0.3 mm and the width for liquid yogurt and for foamable food or beverage products is bigger.

[0057] The device of the invention is advantageously configured as cleanable, cleaning being able to be made in a very easy way. The container 20 can be separated from the rest of the device for its easy cleaning. The pumping element 110 (gears) and the foaming element 120 (cylinder, cone, disc or the like) can also be separated from the rest of the device 300 in order to be cleaned. As previously explained, no other parts are in contact with foamable fluid or food that need to be cleaned for hygienic reasons.

[0058] Some of the main advantages of the device of the invention are: [0059] Superior micro foam being delivered [0060] Efficient mixing of powder and fluid is provided [0061] Adjustable foam density, by acting on the air entry and optionally on the adjustable air valve [0062] Simple architecture (only one motor to drive the pumping and foaming axis) [0063] In-line system [0064] Embodiments allowing a very easy cleaning [0065] Variety of foamable products to be foamed (from fluid to food liquid products)

[0066] Although the present invention has been described with reference to preferred embodiments thereof, many modifications and alterations may be made by a person having ordinary skill in the art without departing from the scope of this invention which is defined by the appended claims.