The present invention relates to beverage dispensers preparing beverages from a soluble powder stored in a tank and from which a dose of powder is dispensed to prepare a beverage.
Many beverages like espresso and other coffee beverages, milk beverages, chocolate beverages are prepared by mixing a soluble food or beverage powder with a diluent in a mixing device. The mixing device can comprise a dissolution chamber in which the soluble component and the diluent are fed. The diluent can be introduced into the dissolution chamber in order to create a whirlpool to efficiently dissolve the soluble powder in the hot water or the hot diluent can be introduced under the form of jets that provides mixing, dissolving and frothing. The mixture can also eventually be frothed by a whipper in the dissolution chamber to reconstitute the beverage and produce foam. The beverage is then usually evacuated into a receptacle for drinking. These devices can also mix the beverage soluble powder with the diluent in a drinking cup, usually a single use cup. In that case the soluble food component is introduced in the cup and the diluent is introduced under the form of jets that provides mixing, dissolving and/or frothing.
Whatever the way the powder and the diluent are mixed together the beverage soluble powder is usually stored in a tank placed above the dissolution chamber opened mouth and a dosing device like a screw or an auger doses and delivers the beverage soluble powder which falls in the dissolution chamber or the drinking cup. Diluent is simultaneously fed to the dissolution chamber so that dissolution occurs.
The tank storing the food or beverage powder comprises a storing chamber with a removable lid at the top. The tank can be refilled with powder by removing the lid and replenishing the storing chamber. This operation is usually implemented by means of simple powder refilling container of food of beverage powder. The top of the powder refilling container is cut or torn and the powder is emptied in the tank storing chamber.
This current practice present several disadvantages.
First the refilling can be very messy because powder can flow around the tank during the operation of transfer. If the operator manipulating the powder refilling container is clumsy, the place inside or around the machine can very rapidly becomes messy and dirty with the difficulty to efficiently removes powder and makes the place proper.
Secondly beverage dispensers often comprise several food or beverage tanks comprising different powders for preparing different beverages. For example, beverage dispensers often comprise an instant coffee powder tank and a milk powder tank. It is important to refill the tanks with always the same powder for different reasons. One reason is that no powder must be contaminated by other types of powders in order to not affect the final taste of the beverage ordered by the customer.
Another reason is that usually each tank is associated to a specific dosing device and the dosing device associated to one tank is set for dosing a particular amount of a particular powder in order to provide the expected dissolution with the diluent. Erroneously refilling a tank with a wrong powder leads to an incorrect preparation of the beverage by the dispenser.
There is a need for improving the refilling of powder tanks within a beverage dispenser.
An object of the present invention is to provide a system of a tank for storing powder in a beverage dispenser and a powder refilling container for refilling said tank.
It would be advantageous to provide a system that limits the spilling of powder during refilling.
It would be advantageous to provide a system that avoids the risk of erroneous refilling of powder tanks.
It would be advantageous to provide an ergonomic system to refill powder tanks.
In a first aspect of the invention, there is provided a system of a tank for storing a food or beverage powder and a powder refilling container for refilling said tank with powder, in which:
Generally the tank for storing the food or beverage powder is a tank that is part of a beverage dispenser. It is generally non disposable. Depending on the configuration of the dispenser, it can be removed from the dispenser, for example for maintenance or cleaning, and eventually for refilling.
The tank comprises a powder outlet, generally positioned at the bottom of the storing chamber of the tank.
Preferably the tank is a storing and dosing tank. Then it comprises a dosing device, generally positioned at the bottom of the storing chamber of the tank and delivering dose of powder through the powder outlet of the tank. The dosing device can be a rotatable volumetric dosing device like an endless screw or, alternatively, a helicoidal spring, also known as spring auger.
The tank with a dosing device is usually configured for enabling the connection of the dosing device with a motorized shaft at the rear end of the tank, said shaft being part of the beverage dispenser.
According to another embodiment the dosing device is not part of the tank. In that embodiment the dosing device can be part of the beverage dispenser and the tank is a simple storing tank that comprises a powder outlet for dispensing powder to a dosing device within a beverage dispenser. In this embodiment, preferably, the powder outlet comprises a device enabling the opening of the outlet of the tank during dosing operation.
Generally the storing chamber of the tank presents globally the shape of a parallelepiped. It usually presents two lateral walls and two end walls, usually one rear end wall and one front end wall. The walls extend between the bottom and the top of the storing chamber and are essentially vertical. By essentially vertical it is meant that some parts of the walls can be inclined, generally to create a funnel above the bottom of the tank. For example, when the tank comprises an endless dosing screw at its bottom, the inclination of the walls increases the storing volume of the storing chamber above the screw and creates a funnel that guides powder to the screw.
The top of the tank is closed by a lid. The lid can be a removable lid in order to be able to clean the tank or for maintenance of the dosing device for example.
Generally the powder refilling container for refilling the tank with powder is a disposable powder refilling container. It is preferably a pouch, usually made of flexible film sheets.
The powder outlet of the powder refilling container and the powder inlet of the tank are designed for cooperating together in order to create a connection and a closed path for powder between the powder outlet of the powder refilling container and the powder inlet of the tank. The connection usually enables either the powder inlet of the powder refilling container to fit in the powder inlet of the tank or vice versa. Preferably the powder inlet of the powder refilling container fits inside the powder inlet of the tank.
The connection between the powder outlet of the powder refilling container and the powder inlet of the tank is designed so that it enables the positioning of the powder outlet of the powder refilling container relatively to the powder inlet of the tank in at least two positions:
In the first position the powder outlet of the powder refilling container is oriented upwardly and the powder is not able to flow from the refilling container to the tank.
In the second position the powder outlet of the powder refilling container is oriented downwardly. Generally the flow path created in this second position is essentially straight. Accordingly the flow of powder is not hindered.
Preferably the flow path is essentially downwardly orientated from the powder outlet of the powder refilling container to the powder inlet of the tank. In the second position the flow path can present an angle of at most 60° with vertical, preferably at most 45°. The value of the angle can depend on the nature of the powder and its flowability.
Accordingly in the first position, the connection is created but there is no path for powder, that is to say the powder is not able to flow through the connection because, due to the upwardly orientation of the powder outlet, the powder stays in the container by gravity. This position enables the operator to correctly connect the powder outlet of the powder refilling container with the powder inlet of the tank without any risk that powder may fall around because there is no path for powder and powder is not induced to flow through the powder outlet.
And accordingly, once the powder outlet of the tank is positioned in the second position, a closed flow path is created for powder that is powder can flow from the powder refilling container to the tank by gravity.
Preferably the powder inlet is fixed and the powder outlet of the powder is able to move inside the fixed powder inlet between the two positions.
Preferably the connection between the powder outlet of the powder refilling container and the powder inlet of the tank is designed so that:
Accordingly the operator is induced to hold the powder outlet of the powder refilling container upwardly oriented when he/she connects said powder outlet to the powder inlet of the tank, and powder is prevented from falling from said powder outlet during the connecting operation.
Preferably the powder outlet of the powder refilling container is an essentially straight tube. Optionally the tube can be slightly angled at one end, preferably at the first end configured for being attached to the powder refilling container. Generally the presence and the angle of the bend in the tube can depend on the shape of the powder refilling container.
The powder outlet of the powder refilling container can comprise a removable cover.
According to one mode, the removable cover can be configured to be completely detached from the powder refilling container, for example like a screwed cap. The operator can manually completely remove the cap before the refilling operation.
According to another mode the powder outlet of the powder refilling container can comprise a removable cover, said cover being permanently attached to the powder refilling container, and the connection between the powder outlet of the powder refilling container and the powder inlet of the tank can be designed so that:
According to this last mode, the cover decreases the risk of powder falling from the powder refilling container during handling since the cover is removed only once the powder outlet is positioned within the powder inlet of the tank.
Generally the powder outlet of the powder refilling container moves from the first position to the second position according to a rotation. Preferably the powder outlet of the powder refilling container rotates inside the powder inlet of the tank.
According to one first mode the powder outlet of the powder refilling container is introduced in the powder inlet of the tank according to an upwardly translation up to the first position.
Accordingly the operator is induced to move the powder outlet upwardly during the step of connection of the powder outlet of the powder refilling container with the powder inlet of the tank, and for this reason, powder is prevented from falling from the powder outlet during this operation.
According to a less preferred second mode the powder outlet of the powder refilling container can be introduced in the powder inlet of the tank according to a downwardly translation down to the first position, the powder outlet of the pack being orientated upwards.
Preferably the powder outlet of the powder refilling container comprises a tube and the powder inlet of the tank comprises an area for receiving said tube, the receiving area and the tube being designed so that the tube of the powder outlet of the powder refilling container slides in the receiving area of the powder inlet of the tank if the tube is orientated upwardly only.
The tube of the powder outlet of the powder refilling container can slide in the receiving area according to a downwardly or upwardly translation movement. Yet whatever the translation, the tube can slide in the receiving area if it is orientated upwardly only.
Preferably the receiving area is designed so that the tube is orientated upwardly with an angle of about 45° with vertical. Such an angle provides a good handling of the powder refilling container for the operator.
Accordingly at the end of the introduction of the tube of the powder outlet of the powder refilling container in the receiving area according to a downwardly or upwardly translation movement, the first position is reached, in which there is no path for powder between the powder outlet of the powder refilling container and the powder inlet of the tank because the powder outlet is oriented upwardly and powder cannot flow therefrom, and preferably the tube of the powder outlet of the powder refilling container is closed by a wall of the receiving area and optionally by the cover of the powder outlet.
Preferably the receiving area and the tube are designed so that, once the tube of the powder outlet of the powder refilling container is positioned in the receiving area of the powder inlet of the tank, the tube is able to be rotated in the receiving area so that the powder outlet of the powder refilling container is oriented downwardly in the powder inlet of the tank.
Accordingly due to the rotation of the tube of the powder outlet of the powder refilling container in the receiving area, the second position is reached, in which there is a path for powder between the powder outlet of the powder refilling container and the powder inlet of the tank because the powder outlet is oriented downwardly inside the powder inlet of the tank and powder can flow therefrom.
The receiving area and the tube can present cooperating means for guiding the rotation movement of the tube in the receiving area. In a specific embodiment the receiving area and the tube can present corresponding guiding grooves and pins or bumps cooperating with these guiding grooves. The grooves can be on the internal surface of the receiving area and the pins or bumps can be on the external surface of the tube of the powder outlet or vice-versa.
Preferably the tube of the powder outlet of the powder refilling container presents two pins or bumps on each of its external lateral sides and the receiving area of the powder inlet of the tank presents two guiding grooves in its internal lateral sides configured for cooperating with at least one of the pins or bumps of the tube during the connection of the tube in the receiving area and during the movement between the first and the second positions.
One part of the guiding grooves can be straight in order to enable the introduction of the tube in the receiving area according to a downwardly or upwardly translation. Depending on the mode of introduction of the powder outlet in the powder inlet, another part of the guiding grooves in the receiving area can be curved in order to guide the rotation of the tube in the receiving area.
When the powder outlet comprises a removable cover permanently attached to the tube, the receiving area can comprise a retaining means for retaining the cover and uncovering the end of the powder outlet when the powder outlet is moved from the first position to the second position. The retaining means can be a lip.
Preferably the storing chamber comprises a removable cover for closing the powder inlet.
In a second aspect of the invention, there is provided a beverage dispenser comprising at least one tank for storing food or beverage powder, said tank being refillable by powder, wherein the tank comprises a storing chamber and a powder inlet and said powder inlet is designed for cooperating with the powder outlet of a powder refilling container in order to create a connection and a path for powder,
wherein the power inlet of the tank comprises a receiving area for connecting the powder outlet of the powder refilling container for refilling the tank, said receiving area being designed so that the powder outlet of the powder refilling container is able to be positioned relatively to the powder inlet of the tank in at least two positions:
Preferably the receiving area is designed so that the powder outlet of a powder refilling container, preferably presenting the shape of a tube, can be received in the receiving area of the powder inlet of the tank if the powder outlet is oriented upwardly only.
Preferably the receiving area of the tank comprises means for enabling:
Preferably the receiving area protrudes above the top of the storing chamber.
Preferably the receiving area is a socket, the internal walls of said socket comprising at least one guiding pin and/or groove for cooperation with at least one corresponding guiding groove and/or pin on the external wall of the powder outlet.
Preferably the receiving area comprises at least two pairs of symmetric guiding grooves on its internal walls.
Preferably the powder inlet of the tank is positioned at the front side of the dispenser.
The powder inlet of the tank can be positioned behind a front door.
The powder inlet of the tank can be positioned at the upper part of the front side of the dispenser.
Accordingly the operator can get access to the powder inlet of the tank by simply opening the front door of the dispenser or by simply opening a cover at the powder inlet of the tank to be refilled.
Generally the dispenser comprises at least two tanks storing different powders and the powder inlets of the tanks are designed differently for being connected to different corresponding powder refilling containers storing different powders.
Accordingly to the preferred embodiment the receiving areas of the different tanks can present different guiding grooves or guiding pins in order to be able to be connected to one corresponding powder refilling container powder outlet only
In a third aspect of the invention, there is provided a powder refilling container storing food or beverage powder comprising a powder outlet and said powder outlet being designed for cooperating with the powder inlet of a tank for storing powder of a beverage dispenser in order to create a connection and a path for powder, the power inlet of the tank comprising a receiving area for connecting the powder outlet of the powder refilling container, said receiving area being designed so that so that the powder outlet of the powder refilling container is able to be positioned relatively to the powder inlet of the tank in at least two positions:
Preferably the powder outlet comprises means for enabling:
Preferably the external wall of the powder outlet comprises at least one guiding groove and/or pin designed for guiding the powder outlet in the powder inlet and for moving the powder outlet in the powder inlet from the first position to the second position.
Preferably the powder outlet of the powder refilling container is an essentially straight tube.
Optionally the tube can be slightly angled at one end, preferably at the first end configured for being attached to the powder refilling container. Generally the presence and the angle of the bend in the tube can depend on the shape of the powder refilling container.
Generally the powder outlet is attached to a pouch, usually made of flexible film sheets, holding the powder.
In a fourth aspect of the invention, there is provided a range of powder refilling containers such as described above wherein said powder refilling containers differ by the nature of the powders they comprise and by the design of the powder outlets so that they can be connected to the powder inlet of dedicated powder tanks only.
In a fifth aspect of the invention, there is provided a method for refilling a tank for storing powder with a powder refilling container of a system such as described above wherein the following steps are implemented:
Preferably the powder outlet of the powder refilling container is rotated between the first and the second positions.
Then for stopping the refilling of the tank, the following steps are implemented:
Accordingly the removal corresponds to the inversed movements of the connection.
The method presents the advantage of enabling the operator to stop the filling of the tank properly even if powder remains in the powder refilling container. The operator is induced to orientate the powder outlet of the powder refilling container upwardly for removing the powder outlet from the powder inlet of the tank. Then the powder refilling container is in a position in which powder is prevented from falling around the tank. The risk is even weaker if the powder outlet comprises a removable cover.
In the present invention the term “powder” covers a bulk material like powder, free flowing particles, pellets, granulates, granules, grains (like coffee beans) or leaves (like tea leaves). Preferably, the food or beverage powder can be instant or roast and ground coffee, chocolate, instant tea, milk powder, soup or a coffee mix.
In the present application the terms “downwardly”, “upwardly”, “internal”, “external”, “rear”, “front”, “bottom”, “top” and “lateral” are used to describe the relational positioning of features of the invention. These terms should be understood to refer to the tank in its normal orientation when positioned in a beverage preparation dispenser for the production of a beverage as shown in
In the present application, the terms “the powder outlet of the powder refilling container is oriented upwardly” means that the external end of the powder outlet is oriented upwardly.
Similarly, in the present application, the terms “the powder outlet of the powder refilling container is oriented downwardly” means that the external end of the powder outlet is oriented downwardly.
The above aspects of the invention may be combined in any suitable combination. Moreover, various features herein may be combined with one or more of the above aspects to provide combinations other than those specifically illustrated and described. Further objects and advantageous features of the invention will be apparent from the claims, from the detailed description, and annexed drawings.
The characteristics and advantages of the invention will be better understood in relation to the following figures:
The tank 1 comprises a storing chamber 11 and a powder inlet 12 through which powder can be introduced for the refilling of the tank. Usually this tank 1 is a storing, and preferably dosing, tank of a beverage dispenser, also frequently called canister. Such a tank usually comprises a powder outlet positioned at the bottom of the storing chamber from which powder is dosed for preparing a beverage. Preferably the bottom of the storing chamber comprises a dosing device like a screw auger or a spring auger. Consequently, in this type of tank, powder is evacuated from the storing chamber through the bottom of the storing chamber and powder has to be refilled in the storing chamber regularly.
The powder refilling container 2 is conceived for storing a powder 3. It is usually a pouch. The powder refilling container comprises a powder outlet 21.
The powder outlet 21 of the powder refilling container and the powder inlet 12 of the tank are designed for cooperating together in order to transfer the powder of the powder refilling container to the storing chamber 11 and refill the tank. The cooperation consists in creating a connection and a path for powder between the powder outlet of the powder refilling container and the powder inlet of the tank.
As illustrated in steps a) and b) of
Once the powder outlet 21 is connected in the first position of step b), the powder outlet can be rotated so as to reach the position illustrated in step c1). In this position a path for powder is created and the end of the powder outlet 21 of the powder refilling container is oriented downwardly. As a result powder can flow due to gravity from the powder refilling container 2 to the storing chamber 11 of the tank as illustrated in step c2). Optionally the connection in this second position can enable a back and forth movement of the powder outlet 21 of the powder refilling container to accelerate and improve the filling of powder as illustrated in step c3).
To stop the refilling operation, the powder outlet 21 of the powder refilling container is rotated back in the first position as illustrated in step d). Powder present in the powder inlet 12 of the tank and in the powder outlet 21 of the powder refilling container flows respectively to the storing chamber 11 and the powder refilling container 2 due to the orientation of said elements. Simultaneously the path for powder is closed.
Finally the powder refilling container 2 can disconnected from the tank by pulling out the powder refilling container. The powder outlet 21 of the powder refilling container remains upwardly oriented during this step e) and powder is prevented from falling around the powder refilling container and the tank.
The powder outlet is generally a tube. The tube can present any sectional shape. Preferably the shape is conformal to the shape of the receiving area of the powder inlet of the tank.
The powder outlet comprises a cover 212 presenting a pair of symmetric guiding grooves 2121 on its external lateral sides (in
As shown in
Both first guiding slots 1221a and second guiding grooves 1221b of the powder inlet in the receiving area present a straight design orientated upwardly in order to guide the introduction of the tube 211 of the powder outlet with the end of the tube orientated upwardly.
Accordingly the cooperation between the tube guiding bumps 2113 and second pair of pins 2112 of the powder outlet with the first guiding grooves 1221a and the second guiding grooves 1221b respectively of the powder inlet enables guiding the introduction of the powder outlet in the receiving area with:
In the first position, the path of powder is closed, firstly, because the end of the tube 211 is closed by the cover 212 and the cover abuts against the end wall 1224 of the receiving area and, secondly, because the outlet in the tube faces the end wall 1224 of the powder inlet and becomes closed by said wall. Accordingly, even if the connector is deprived of cover, in this first position the second end is closed by the wall 1224 and no path for powder exists anyway. Moreover due to the upwardly position of the end of the tube, powder remains in the pouch 2 by gravity.
Once the powder outlet is in the first position, the second pair of pins 2112 of the powder outlet can cooperate with third guiding grooves 1222 present on the symmetric lateral internal wall (one of the pair is not represented due to the cross section). These third guiding grooves present a curved design so that the powder outlet can be rotated in the receiving area. During the rotation, the cover 212 of the powder outlet is retained by the lip 1223 within the receiving area and consequently a path for powder is created. During the removal of the cover, the pair of pins 2112 slide along the guiding grooves 1222 and the bottom guiding edge 2122 of the cover is guided along the cover guiding bump 2114 on the lateral side of the tube 211 as illustrated in
Accordingly while moving to the second position, the end of the tube 211 becomes oriented downwardly and the tube aligns itself on the internal tube of the powder inlet 12. Moreover, the cover is removed from the second end of the tube. As a consequence, a flow path is created for powder. Moreover, due to the new orientation of the tube, the operator is incited to move the pouch attached to the connector above the powder inlet so that powder can fill the tank 1 by gravity.
Consequently in this first mode, the system enables the introduction of the powder outlet of the powder refilling container in the powder inlet of the tank according to an upwardly translation up to the first position.
Different tanks 1 can be designed with slightly different design of guiding grooves 1221a, 1221b, 1222 so that only dedicated powder refilling containers 2 with corresponding designed pins 2111, 21112 and bumps 2113 are able to be engaged inside. For example the design can differ by the width, the length, the height, the position and/or the orientation of the grooves in the lateral walls of the receiving area 122. It becomes impossible for the operator to refill a tank dedicated to coffee powder with a powder refilling container containing milk powder for example.
In step a1), the cover 121 of the powder inlet of the tank is opened.
In step a2) the powder refilling container 2 is moved with the powder outlet 21 oriented upwardly and according to an upwardly translation within the powder inlet 21 of the tank until it teaches the first position of step b).
Between step b) and c) the powder refilling container is rotated so as to reach the second position of step c): here the path for powder is created and refilling happens. As illustrated in the magnified view of step c), the tube guiding bump 2113 is positioned transversely to the guiding groove 1221a of the receiving area meaning that in this second position the operator cannot remove the powder outlet of the powder refilling container from the powder inlet of the storing chamber without rotating back the powder outlet. There is no risk that the operator lets powder flows out of the powder refilling container by mishandling. He/she can even stop holding the powder refilling container during the refilling, no mess is created around the tank since the power outlet remains attached to the powder inlet of the tank.
In step c), the tube o the powder outlet 21 is inclined with respect to vertical according to an angle of about 45°. This angle may vary according to the nature of the powder refilled in the tank, and in particular the flowability property of the powder.
Between step c) and d) the powder refilling container is rotated back so as to reach again the first position of step d): here the path for powder is closed.
In step e), the powder refilling container powder outlet can be removed from the receiving area, the powder outlet 21 being oriented upwardly.
This system guarantees that no powder can fall from the powder outlet or the powder inlet during the refilling operation.
The powder outlet comprises a cover 212 presenting a pair of symmetric guiding grooves on its external lateral sides (in
The receiving area 122 of the powder inlet 12 of the tank comprises a first guiding slot 1221a on its lateral internal wall cooperating with the tube guiding bumps 2113 on the lateral sides of the tube of the powder outlet; a corresponding symmetric first guiding slot is present on the symmetric lateral internal wall (not represented due to the cross section). These guiding slots 1221a in the receiving area present a straight design for guiding the translation movement of the operator when he/she introduces the powder outlet of the powder refilling container in the receiving area with the powder outlet orientated upwardly.
Accordingly the cooperation between the tube guiding bumps 2113 with the guiding grooves 1221a of the powder inlet enables guiding the introduction of the powder outlet in the receiving area with:
In the first position, the path of powder is closed, firstly, because the end of the tube 211 is closed by the cover 212 and the cover abuts against the end wall 1224 of the receiving area and, secondly, because the outlet in the tube faces the end wall 1224 of the powder inlet and becomes closed by said wall. Accordingly, even if the connector is deprived of cover, in this first position the second end is closed by the wall 1224 and no path for powder exists anyway. Moreover due to the upwardly position of the end of the tube, powder remains in the pouch 2 by gravity.
Once the powder outlet is in the first position, the second pair of pins 2112 of the powder outlet can cooperate with second guiding grooves 1222 present on the symmetric lateral internal wall of the receiving area (one of the pair is not represented due to the cross section). These second guiding grooves present a curved design so that the powder inlet can be rotated in the receiving area. During the rotation, the bottom edge of the cover 212 of the powder outlet is retained by the lip 1223 within the receiving area and a path for powder is created. During the removal of the cover, the pair of pins 2112 slide along the guiding grooves 1222. During the rotation the pin 2111 is able to rotate in a corresponding round guiding groove of the receiving area.
Accordingly while moving to the second position, the end of the tube 211 becomes oriented downwardly and the tube aligns itself on the internal tube of the powder inlet 12. Moreover, the cover is removed from the second end of the tube. As a consequence, a flow path is created for powder. Moreover, due to the new orientation of the tube, the operator is incited to move the pouch attached to the connector above the powder inlet so that powder can fill the tank 1 by gravity.
Consequently in this second mode, the system enables the introduction of the powder outlet of the powder refilling container in the powder inlet of the tank according to a downwardly translation down to the first position.
In step a1), the cover 121 of the powder inlet of the tank is opened.
In step a2) the powder refilling container 2 is moved with the powder outlet 21 oriented upwardly and according to a downwardly translation within the receiving area of the powder inlet of the tank until it reaches the first position of step b).
Between step b) and c) the powder refilling container is rotated in a a vertical plane so as to reach the second position of step c): here the path for powder is created and refilling occurs.
Between step c) and d) the powder refilling container is rotated back so as to reach again the first position of step d): here the path for powder is closed.
In step e), the powder refilling container powder outlet can be removed from the receiving area, the powder outlet 21 being oriented upwardly.
This system guarantees that no powder can fall from the powder outlet or the powder inlet during the refilling operation.
Behind the front door 13, the dispenser usually comprises beverage preparation units placed under powder tanks 1. The outlets of the tanks are oriented so as to deliver the beverage powder in the beverage preparation for contacting a dose of beverage powder with a diluent. The diluent is supplied by a fluid system comprising usually a boiler, a pump and a heater placed in the back part of the dispenser (not illustrated). The beverage preparation unit 21 delivers the beverage in a cup placed in a dispensing area 42.
The dispenser usually comprises an input device 41 for enabling a customer to select and order a beverage.
The tanks 1 can cooperate with motor shafts at their rear end in order to actuate the dosing devices inside the tanks.
Advantageously it is possible to retrofit existing powder tanks for storing a food or beverage powder of existing dispensers by simply removing the lid and replacing it with a lid comprising a receiving area in order to cooperate with a connector for refilling. Eventually the front door of the dispenser may be adapted too.
The system of the present invention presents the advantage of enabling the movement of the powder outlet of the powder refilling container in the powder inlet of the tank. Yet the system does not comprises any moving part, the system only induces the operator to make the right movement to orientate the powder refilling container in a manner that avoids any spilling of powder.
Although the invention has been described with reference to the above illustrated embodiments, it will be appreciated that the invention as claimed is not limited in any way by these illustrated embodiments.
Variations and modifications may be made without departing from the scope of the invention as defined in the claims. Furthermore, where known equivalents exist to specific features, such equivalents are incorporated as if specifically referred in this specification.
As used in this specification, the words “comprises”, “comprising”, and similar words, are not to be interpreted in an exclusive or exhaustive sense. In other words, they are intended to mean “including, but not limited to”.
Number | Date | Country | Kind |
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15153051.6 | Jan 2015 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2016/051121 | 1/20/2016 | WO | 00 |