CARTRIDGE FOR PREPARING A DRINK

专利摘要:
cartridge for preparing drinks. a cartridge (1, 201) for preparing a beverage is provided which is sealed before use and contains one or more beverage ingredients. the cartridge comprises: - a body (2) defining a beverage ingredient chamber (6) containing the one or more beverage ingredients; - a first filter (8) defining an outlet from the beverage ingredient chamber; - a second filter (9) downstream of, and spaced from, the first filter; and - a flow constriction (10) downstream of the second filter such that, in use, beverage produced from the one or more beverage ingredients passes, in order, through the first filter, the second filter and the constriction flow.
公开号:BR112016029231B1
申请号:R112016029231-6
申请日:2015-06-12
公开日:2021-08-31
发明作者:Tulay Massey；John Melrose；Tony Saunders；Simon Carr；Ian Alexander James Radcliffe；Willem Paul Beeker；Stuart James Curtis
申请人:Koninklijke Douwe Egberts B.V.；
IPC主号:

专利说明:

[001] The present disclosure relates to cartridges for preparing beverages and containing one or more ingredients for preparing beverages. BACKGROUND OF THE DISCLOSURE
[002] Home filter coffee machines have been widely available since the 1960s. Home coffee machines have been developed significantly since the introduction of the first filter machines and are now essential pieces of kitchen equipment in many homes. Some such machines dispense individual doses of a beverage directly into a drinking container, and derive the beverage from a bulk beverage ingredient source or from individual beverage ingredient packages such as cocoons, capsules or cartridges. . In the following specification, these packages will be referred to by the general term cartridges. Machines using such cartridges eliminate the need for cleaning and can allow the user to make a beverage selection. An example of a system for using such cartridges is described in EP-A-1440903. Beverages are formed from preparing, mixing, dissolving or suspending beverage ingredients in water. For example, for coffee beverages, hot water is forced through the cartridges to form the extracted solution. The use of cartridges in such machines has become increasingly popular due to their convenience and the quality of the beverage produced.
[003] To enable a user to produce a full range of beverages in the home it is not only necessary to provide means to prepare high quality beverages, such as filtered coffee and tea, it is also necessary to provide the user with means to produce foamed beverages or beverage components. This could be, for example, making beverages such as cappuccino. Traditionally frothed milk was produced in coffee shops, using a steam pipe to direct a jet of steam into a liquid milk reservoir. This is still the main method of producing milk foam in a commercial environment. However, it is inconvenient to use steam jet equipment at home as it can be dangerous if not used correctly and it can also be difficult to clean. This is particularly disadvantageous for equipment used with milk that requires careful cleaning to avoid contamination.
[004] An example of a cartridge for a home beverage machine that is suitable for producing milk foam from a concentrated liquid milk ingredient is known from EP-A-1716055. Frothy milk is produced from the cartridge by causing air to become entrapped in a stream of milk produced when water is mixed with the concentrated liquid milk ingredient contained within the cartridge. This is achieved by passing the beverage thus formed through an eductor inside the cartridge. The eductor includes an opening that forms a constriction in the flow path that is arranged to produce a jet of beverage and a consequent reduction in beverage pressure. The beverage jet exits the constriction and passes over an air inlet while still at subatmospheric pressure, causing the air to be trapped in the beverage thus creating a frothy beverage. Milk foam produced from such cartridges allows coffee shop-style beverages, such as cappuccino, to be easily brewed at home without the need for potentially dangerous and difficult-to-clean steam stick equipment.
[005] Foamed beverages can also be produced from cartridges of this type containing soluble and powdered beverage ingredients, for example powdered chocolate for a hot chocolate beverage or powdered milk for a cappuccino type beverage. However, there are a number of cartridge-specific problems with these soluble, powdered and liquid beverage ingredients.
[006] It is necessary to properly mix the beverage ingredient with water injected into the cartridge to provide a uniform beverage containing the desired amount of beverage ingredient. Improper mixing may result in some beverage ingredient remaining in the chamber or beverage ingredient coagulates forming in the beverage. In addition, coagulates of this type can block the constriction, preventing the beverage from flowing through the constriction to form a jet. This can cause undesirable back pressure on the cartridge behind the constriction, resulting in splitting or other cartridge failure and/or preventing the eductor from functioning properly, preventing the production of the beverage jet. It should also be appreciated that the soluble beverage mass may contain a minority of insoluble material (as found in chocolate powder) or large particles of soluble beverage ingredients (milk powder particles, for example) that may not fully dissolve in the Water. These particles can also function to block flow constriction.
[007] For these reasons, it is necessary to control the flow of water within the cartridge to ensure proper mixing and dispensing of pressure and frothing of the beverage.
[008] Consequently, there is a desire for a beverage cartridge that ensures proper mixing of the beverage ingredients, ensures adequate water flow in the cartridge, and prevents undesirable levels of back pressure when using a flow constriction to froth the beverage.
[009] It will be understood that the term "cartridge", as used herein, means a capsule, cocoon, package or container that contains one or more beverage ingredients in the manner described and is suitable for use with a beverage preparation machine. The cartridge may comprise a single component or an equivalent of multiple components. Preferably, the cartridge is adapted to produce a single dose of beverage. The cartridge can be rigid, semi-rigid or flexible. Cartridge inlet and outlet may be open or require opening in use, eg punching.
[010] In the following description, the terms "upper" and "lower" and equivalents will be used to describe the relational positioning of disclosure characteristics. The terms "top" and "bottom" and their equivalents are to be understood to refer to the cartridge (or other components) in its normal orientation for insertion into a beverage preparation machine and subsequent dispensing. In particular, "top" and "bottom" refer, respectively, to the relative positions closest or farthest away from a closed top 29 of the cartridge. In addition, the terms "inside" and "outside" and equivalents will be used to describe the relational positioning of disclosure features. The terms "inside" and "outside" and their equivalents should be understood to refer to relative positions on the cartridge (or other components) being, respectively, closer to or farther from a center or major axis of cartridge 1 (or other component ). DISCLOSURE SUMMARY
[011] In a first aspect of the disclosure, a cartridge is provided for preparing a beverage, the cartridge being sealed prior to use and containing one or more beverage ingredients, the cartridge being suitable for receiving in use in an aqueous medium that can be contacted with one or more beverage ingredients to produce a beverage that can be produced from the cartridge, the cartridge comprising: - a body defining a beverage ingredient chamber containing one or more beverage ingredients; - a first filter defining an outlet from the beverage ingredient chamber; - a second filter downstream of and spaced from the first filter; and - a flow constriction downstream of the second filter, such that in use beverage produced from the one or more beverage ingredients passes, in order, through the first filter, the second filter and the flow constriction.
[012] In the present disclosure, reference to "one or more beverage ingredients" and "beverage ingredient(s)" is intended to refer to one or more ingredients suitable for forming a beverage. The "one or more beverage ingredients"/"beverage ingredient(s)" may comprise a single substance or may comprise a beverage composition comprising two or more substances. Unless explicitly required by the context, references to "drinking ingredient" in the singular are intended to include the plural and vice versa.
[013] The first filter may comprise a first filter wall and the second filter may comprise a second filter wall.
[014] The first filter and the second filter may each comprise a rigid element having a plurality of filter openings located therein.
[015] The first filter can extend around the second filter.
[016] The first filter and the second filter can be arranged concentrically.
[017] The first filter may comprise a first tubular member having a plurality of first filter openings located therein and the second filter may comprise a second tubular member having a plurality of second filter openings located therein. The second tubular member may be disposed within the first tubular member.
[018] The cartridge may further comprise a spout for channeling the beverage, in use, towards an outlet of the cartridge. The first and second filters can be arranged around the discharge nozzle. The flow direction, in use, of beverage flowing from the second filter to the flow constriction may be opposite to a flow direction, in use, of beverage flowing out of the spout.
[019] A cartridge inlet may be provided, or formed in use, at or near a periphery of the capsule.
[020] The cartridge can be configured to direct the aqueous medium entering the beverage ingredient chamber to circulate around the first filter.
[021] The beverage ingredient chamber may be annular, with the first filter forming at least a part of an inner surface of the annular beverage ingredient chamber. The cartridge body may be configured to direct the aqueous medium entering the beverage ingredient chamber at an angle greater than 45°, preferably at 90° from a radial direction of the annular beverage ingredient chamber such that the Aqueous medium is circulated around the annular beverage ingredient chamber. One or more than one angled inlet may be provided to the annular beverage ingredient chamber.
[022] The beverage ingredient local bed thickness may be 1.5 to 2.2 times the beverage ingredient local bed width, more preferably about 2 times the beverage ingredient local bed width.
[023] A cartridge outlet may be provided, or formed in use, at or near a center of the capsule.
[024] Cartridge may be disc-shaped.
[025] A cartridge inlet may be provided, or formed in use, and a cartridge outlet may be provided, or formed in use on a same surface of the cartridge. The same surface can be a cartridge bottom surface when attached to a beverage preparation machine ready for dispensing.
[026] The first filter may comprise a plurality of first filter apertures and the second filter may comprise a plurality of second filter apertures and wherein a critical dimension of the first filter apertures may be greater than a critical dimension of the second apertures of filtering.
[027] The first filter and/or the second filter may comprise filter openings in the form of elongated slits respectively formed in an otherwise impermeable rigid wall element. The elongated slots can extend from a free edge of the respective wall element.
[028] The body may comprise a cup-shaped member housing the first filter and the second filter, an open mouth of the cup-shaped housing being sealed by a lid.
[029] The first filter and/or the second filter may comprise filter openings in the form of elongated slits formed, respectively, in an otherwise impermeable rigid wall element, wherein the elongated slits extend in contact with the cover .
[030] The first filter and the second filter can form a part of an inner member located inside the cup-shaped member. The first filter and the second filter can be formed as a unitary molding of a polymeric material.
[031] The flow constriction downstream of the second filter can be sized and/or shaped to produce a jet of beverage when the beverage passes through it.
[032] The cartridge may further comprise an air inlet opening located in the vicinity of the flow constriction and downstream thereof, such that the beverage jet passes through the air inlet opening.
[033] The cartridge may further comprise: - a second flow constriction downstream of the filter, wherein the cartridge comprises a first flow path from the second filter to the first flow constriction and a second flow path from the second filter for the second flow constriction, wherein the first and second flow constrictions are configured such that, in use, a first beverage jet emanates from the first flow constriction and a second beverage jet emanates from of the second flow constriction, and the first and second flow constrictions are configured so that the first and second beverage jets collide.
[034] The first and second flow constrictions can be located opposite each other such that the first and second beverage jets impact each other substantially forwardly.
[035] An air inlet opening can be located in the vicinity of each flow constriction and downstream thereof, such that the beverage jets each pass through an air inlet opening.
[036] In a second aspect of the present disclosure, a cartridge for preparing a beverage is provided, the cartridge being sealed prior to use and containing one or more beverage ingredients, the cartridge being suitable for receiving in use in an aqueous medium that can be contacted with the one or more beverage ingredients to produce a beverage that can be produced from the cartridge, the cartridge comprising: - a body defining a beverage ingredient chamber containing one or more beverage ingredients; - a filter defining an outlet from the beverage ingredient chamber; and - a first and a second flow constriction downstream of the filter, wherein the cartridge comprises a first flow path from the filter to the first flow constriction and a second flow path from the filter to the second flow constriction. flow, wherein the first and second flow constrictions are configured such that, in use, a first beverage jet emanates from the first flow constriction and a second beverage jet emanates from the second flow constriction, and the first and second flow constrictions are configured so that the first and second beverage jets collide.
[037] The first and second flow constrictions can be located opposite each other in such a way that the first and second beverage jets impact each other substantially oppositely.
[038] An air inlet opening can be located in the vicinity of each flow constriction and downstream thereof, such that the beverage jets each pass through an air inlet opening.
[039] The filter may comprise a filter wall.
[040] The filter may comprise a rigid element having a plurality of filter openings located therein.
[041] The filter may comprise a tubular member having a plurality of filter openings located therein.
[042] The cartridge may further comprise a spout for channeling the beverage, in use, towards an outlet of the cartridge.
[043] The filter can be arranged around the discharge nozzle.
[044] The flow direction, in use, of the beverage flowing from the filter to the flow constriction may be opposite to a flow direction, in use, of the beverage flowing out of the spout.
[045] A cartridge inlet may be provided, or formed in use, at or near a periphery of the capsule.
[046] The cartridge may be configured to direct the aqueous medium entering the beverage ingredient chamber to circulate around the filter.
[047] The beverage ingredient chamber may be annular, with the filter forming at least a part of an inner surface of the annular beverage ingredient chamber.
[048] The cartridge body may be configured to direct the aqueous medium entering the beverage ingredient chamber at an angle greater than 45°, preferably at 90° from a radial direction of the annular beverage ingredient chamber of such. so that the aqueous medium is circulated around the annular beverage ingredient chamber. One or more than one angled inlet may be provided to the annular beverage ingredient chamber.
[049] The local bed thickness of the beverage ingredient may be 1.5 to 2.2 times the local bed width of the beverage ingredient, more preferably about 2 times the local bed width of the beverage ingredient.
[050] A cartridge outlet may be provided, or formed in use, at or near a center of the capsule.
[051] Cartridge may be disc-shaped.
[052] A cartridge inlet may be provided, or formed in use, and a cartridge outlet may be provided, or formed in use, on a same surface of the cartridge. The same surface can be a cartridge bottom surface when attached to a beverage preparation machine ready for dispensing.
[053] The filter may comprise filter openings in the form of elongated slits formed in an otherwise impermeable rigid wall element.
[054] Elongated slots may extend from a free edge of the wall element.
[055] The body may comprise a cup-shaped member housing the filter, an open mouth of the cup-shaped housing being sealed by a lid.
[056] The filter may comprise filter openings in the form of elongated slits formed in an otherwise impermeable rigid wall element, wherein the elongated slits extend in contact with the cover.
[057] The filter can form a part of an inner member located inside the cup-shaped member.
[058] The filter can be formed as a unitary molding of a polymeric material.
[059] In any aspect of the present disclosure, the first filter may comprise a plurality of first filter apertures and the second filter, when present, may comprise a plurality of second filter apertures and in which a critical dimension (being the smallest dimension, eg the width) of the first and/or second filtering openings may be 0.4 to 0.6 millimeters, preferably 0.5 millimeters.
[060] In any aspect of the present disclosure, the cartridge may be disc-shaped having a central longitudinal axis, wherein an outlet of the cartridge may be oriented to emit, in use, the beverage substantially in a direction parallel to the axis. longitudinally, and wherein the first filter and the second filter can be oriented such that beverage passing through the first filter and the second filter passes between the first filter and the second filter in a direction substantially perpendicular to the longitudinal axis.
[061] In any aspect of the present disclosure, the one or more beverage ingredients may comprise one or more soluble beverage ingredients. The one or more beverage ingredients may comprise one or more powdered beverage ingredients. The one or more beverage ingredients can comprise low solubility or insoluble ingredients, for example cocoa particles.
[062] Other aspects of the present disclosure will now be established that may be applied to the first or second aspects described above, alone or in combination, or alternatively to other cartridges which may not necessarily possess all the features of the first or second aspect.
[063] In another aspect of the present disclosure, a duct upstream of the or each flow constriction may be configured to prevent deposition of undissolved or partially dissolved beverage ingredient. This configuration may comprise shaping the duct upstream of each flow constriction, in particular the portion of the duct immediately upstream of the flow constriction, to be smooth so as not to have dead spaces, sharp corners or sudden changes in concavity.
[064] In another aspect of the present disclosure, the beverage ingredient chamber may comprise one or more partition elements that act to delimit two or more zones within the beverage ingredient chamber, each of which contains one or more ingredients. of drink. Preferably, the one or more partition elements extend from the first filter towards the cartridge body. The one or more partitions can be flat and can be oriented radially towards the inside of the body. Alternatively, one or more partitions can be curved.
[065] The one or more partition elements may extend from a first filter located centrally in contact with a surrounding wall of the body, so as to fully separate zones from one another within the beverage ingredient chamber. Each separate zone will comprise at least one inlet allowing inlet of the aqueous medium to the zone and at least a portion of the first filter allowing outflow of the beverage from the zone.
[066] In an example, four partitions are provided.
[067] Advantageously, separating the beverage ingredient chamber into two or more zones can produce better dissolution of one or more beverage ingredients by focusing the mixing of the aqueous medium and the beverage ingredients in key areas and providing alternative flow patterns .
[068] In another aspect of the present disclosure, a flow path from the filter(s) to the flow constriction(s) may be configured to be spiral-shaped. For example, spiral ramp elements can be located within an annular space between the end filter (the second filter where present, or the first filter where only one filter is provided) and a cylindrical tube, into which the beverage is forced. to flow through the annular space on the way to the flow constriction(s). Spiral ramp elements spiral the beverage around the cylindrical tube creating additional mixing vortices and swirls within the beverage. Advantageously, this flow pattern can help to break up small, partially wetted clumps of beverage ingredient that may have made it through the filter(s). Additional obstructions, eg ribs, corners, etc., can be provided on the spiral ramp elements to help break up agglomerates.
[069] In another aspect of the present disclosure, the beverage ingredient chamber may contain a plurality of bristles. The bristles may advantageously act to interrupt the flow path with the beverage ingredient chamber to promote turbulence and better mixing of one or more beverage ingredients. The bristles can be arranged around, and spaced apart from, the first filter. The bristles can comprise elongated plastic pins. The bristles can extend the entire height of the beverage ingredient chamber. The bristles can be formed unitarily as part of an inner member also comprising the first filter received within the body.
[070] In another aspect of the present disclosure, the body defining the beverage ingredient chamber may have one or more lobes as part of an outer side wall of the beverage ingredient chamber. The one or more lobes can be smoothly, convexly curved (when viewed from a midpoint of the cartridge). A lobe can be provided between the pairs of inlet openings to the beverage ingredient chamber. Advantageously, the one or more lobes can improve the dissolution of one or more beverage ingredients by first confining the inlet aqueous medium to a smaller cross-sectional flow area leading to better shear forces and higher flow velocities that improve the dissolution. Second, the one or more lobes, when positioned between the pairs of inlet openings, tend to decrease the amount of "dead space" in the beverage ingredient chamber. By "dead space" is meant that part or parts of the volume of the beverage ingredient chamber where circulating flow of the aqueous medium and/or beverages tends not to reach. For example, with an annular beverage ingredient chamber having four equally spaced inlet openings directed radially at, say, 0°, 90°, 180°, and 270°, it has been found that locations by the sidewall at 45°, 135 °, 225°, and 315° tend to be "dead spaces" that tend not to be reached by the circulation flow.
[071] In another aspect of the present disclosure, the beverage ingredient chamber may comprise two or more separate chambers, each of which contains a different beverage ingredient(s). For example, a first chamber may contain sugar or a sugar-containing beverage ingredient(s) and a second chamber may contain a chocolate-containing beverage ingredient(s). Each separate chamber will comprise at least one inlet that permits entry of the aqueous medium into the interior of the chamber and at least a portion of the first filter that permits the exit of the beverage from the chamber. Advantageously, such an arrangement can be used to adapt the size and number of inlet openings and the size and number of filtering openings for each beverage ingredient(s).
[072] In another aspect of the present disclosure, the beverage ingredient chamber may comprise a dedicated flow conditioning chamber that receives incoming aqueous medium in a first condition and discharges the aqueous medium into a remainder of the beverage ingredient chamber. in a second condition. The first and second conditions may include one or more of the following: first and second flow rates, first and second flow directions, and first and second flow compositions (i.e., the flow composition in terms of the relative amounts of water, dissolved beverage ingredient(s) and/or undissolved beverage ingredient(s) at that location). For example, the flow conditioning chamber may comprise an angled wall for conditioning an inlet aqueous medium having a first condition of a relatively low flow velocity in a radial flow direction and a pure water composition for a second condition of a flow having a relatively high flow velocity, a tangential flow direction and a composition of water mixed with one or more beverage ingredients.
[073] In another aspect of the present disclosure, the beverage ingredient chamber may comprise a plate member that initially rests on a bed of one or more beverage ingredients. The use of the plate member finds particular application where the inlet(s) to the beverage ingredient chamber is located at or towards a bottom of the beverage ingredient chamber. In use, when the one or more beverage ingredients are incrementally dissolved away from under the plate member the weight of the plate member (which can be freely moveable within the beverage ingredient chamber) forces undissolved beverage ingredient further up into the beverage ingredient chamber down into the inlet aqueous medium path. The plate member may comprise openings to allow the circulation of the aqueous and/or beverage medium above and below the plate member in use.
[074] In another aspect of the present disclosure, the beverage ingredient chamber may contain a rotary mixer blade assembly. The rotary blender blade assembly may comprise one or more vanes or paddles which act to break clumps of powdered beverage ingredient when the rotary blender blade assembly rotates within the beverage ingredient chamber.
[075] In another aspect of the present disclosure, the beverage ingredient chamber may comprise one or more baffles oriented to induce vertical vortices within the beverage ingredient chamber.
[076] In any of the above embodiments or aspects the first filter may comprise a plurality of first filter apertures and the second filter, when present, may comprise a plurality of second filter apertures and in which a critical dimension (the smallest dimension being , for example, the width) of the first and/or second filtering openings can be 0.4 to 0.6 millimeters, preferably 0.5 millimeters. BRIEF DESCRIPTION OF THE DRAWINGS
[077] Embodiments of the present invention will now be described by way of example only, with reference to the accompanying drawings, in which: Figure 1 is a perspective view of a first embodiment of cartridge according to the present invention with a sealing laminate omitted to show interior details; Figure 2 is a perspective view of an inner member of the cartridge of Figure 1; Figure 3 is a perspective view of the inner member of Figure 2 from another angle; Figure 3a is an enlarged view of a portion of Figure 3; Figure 4 is a cross-sectional view of the inner member of Figure 2; Figure 5 is a plan view of the cartridge of Figure 1;
[078] Figure 6 is a cross-sectional view of the cartridge of Figure 1 with the sealing laminate attached; Figure 7 is a perspective view of an alternative inner member for use in the cartridge of Figure 1; Figure 8 is a cross-sectional view of the inner member of Figure 7; Figure 9 is a perspective view of another embodiment of a cartridge in accordance with the present invention with a sealing laminate omitted to show interior details; Figure 10 is a perspective view of an inner member of the cartridge of Figure 9; Figure 11 is a plan view of the cartridge of Figure 9; Figure 12 is a perspective view of a comparative cartridge; and Figure 13 is a perspective view of another example of the cartridge of the present invention; Figures 14 to 32 show views of cartridges incorporating additional aspects of the present disclosure. DETAILED DESCRIPTION
[079] In the following description, the description will be illustrated by way of example with reference to a cartridge for forming a beverage (otherwise known as a beverage capsule), in particular, a cartridge that is a machine-insert cartridge seal that can be used with a beverage preparation system to dispense one of a variety of types of beverages on demand, preferably in a home environment.
[080] Figures 1 to 6 show a first embodiment of a cartridge according to the present disclosure. For clarity, a cartridge containing no beverage ingredient is illustrated so that the features of the cartridge 1 can be more easily seen. However, prior to use, and during assembly, the cartridge 1 would receive one or more beverage ingredients therein and then be sealed by means of a cap 5 as will be described below, and as shown in Figure 6.
[081] The cartridge 1 generally comprises a body 2, an inner member 3 and the cap 5. The body 2, inner member 3 and the cap 5 are assembled to form the cartridge 1.
[082] The body 2 may generally comprise a cup-shaped member defining a beverage ingredient chamber 6 within an interior thereof. The body 2 may have a curved sidewall 21, a closed top 29 and an open bottom 30 defining an open mouth of the body 2 which is surrounded by a collar 46 and a flange 42 extending radially outward from the collar. 46. In addition, the body 2 may further define an optional annular void 44 between an inner wall 43 of the container and the flange 42. In this case, a free edge of the inner wall 43 may define the rim 46. The closed top 29 of the body 2 may comprise, as shown in Figure 6, a centrally located cylindrical hole 40 which forms a depression in the outer surface of body 2. A closed end of cylindrical hole 40 may comprise a cylindrical extension 24 of narrower diameter compared to the hole cylindrical 40, the function of which will be described further below.
[083] The cartridge 1 further comprises an entry point 13 and an exit point 14, as shown in Figure 6. The entry point 13 and the exit point 14 define the location of an entry to the aqueous medium, such as water, to come into use from the cartridge 1 and the location of an outlet for the beverage to exit the cartridge 1 during dispensing. Preferably, the inlet and outlet are initially sealed by the cap 5 such that the inlet 13 and the outlet 14 are simply predetermined areas of the cap 5 to be pierced, cut or otherwise opened in use. Alternative forms of inlet and outlet can be provided, for example, in the form of valve elements or detachable elements that can be removed manually or by a beverage preparation machine.
[084] The body 2 of the cartridge 1 may be generally circular or disc-shaped, with a diameter of the cartridge 1 being greater than its height. Typically, the overall diameter of the body 2 is 74.5 millimeters ± 6 millimeters and the total height is 29 millimeters ± 3 millimeters. Typically, the interior volume of the cartridge 1 capable of receiving beverage ingredient(s) when assembled is a maximum of 55 ml (although it is not necessary for the interior volume to be filled with the beverage ingredient(s) capacity). The diameter of the body 2 may be smaller at the closed top 29 compared to the diameter at the bottom 30, resulting from a widening of the curved sidewall 21 from the closed top 29 to the bottom 30.
[085] The body 2 may comprise an inlet chamber 32 adjacent to the curved side wall 21 aligned with the inlet point 13. The inlet chamber 32 comprises a cylindrical wall structure having a blast slit 33 on one side configured for blasting. in use, the aqueous medium enters the inlet chamber 32 from the inlet point 13 to the beverage ingredient chamber 6 such that the aqueous medium energetically circulates around the beverage ingredient chamber 6. jet 33 can be an elongated slot or groove. Preferably, the blasting slit 33 is oriented so that the aqueous medium enters the beverage ingredient chamber 6 at an angle greater than 45°, preferably at 90°, from a radial direction of the beverage ingredient chamber. 6.
[086] The inner member 3 is located within the body 2. The inner member 3 is connected to the body 2 and comprises a mounting flange 50, a first filter 8, a second filter 9, a flow constriction and a discharge nozzle 12. The inner member 3 may be located centrally within the body 2 so that a central axis of the inner member 3 is coincident with and aligned with a central axis of the body 2. The mounting flange 50 may be connected to a surface. inside the closed top 29 of the body 2, for example by ultrasonic welding. In assembly, the inner member 3 extends between the closed top 29 of the body 2 and the cap 5, as shown in Figure 6. The cap 5 is sealed to distal rims of the inner member 3, as well as the body 2 as will be described below.
[087] With the inner member 3 in position within the body 2, the beverage ingredient chamber 6, which contains the beverage ingredient before dispensing, takes the form of an annular chamber extending between the curved side wall 21 of the body. 2 and the inner member 3.
[088] The inner member 3 can be formed as a single integral molding.
[089] As shown in Figures 2 to 4, the first filter 8 may take the form of a tubular member extending from the mounting flange 50 and defines a first cylindrical filter wall 81 that forms an outer surface of the inner member 3 The first cylindrical filter wall 81 is provided at a distal end of the mounting flange 50 with a plurality of first filter openings 82.
[090] The second filter 9 is arranged inside the first cylindrical filter wall 81 and takes the form of a second cylindrical filter wall 91. The second cylindrical filter wall 91 extends from a transverse connecting flange 17 that joins the second cylindrical filter wall 91 to the first cylindrical filter wall 81. The second cylindrical filter wall 91 is provided at a distal end of the mounting flange 50 with a plurality of second filter openings 92.
[091] As shown in Figure 4, the transverse connecting flange 17 may be provided with a plurality of radial reinforcing ribs 60 on its underside that extend between the first cylindrical filter wall 81 and the second cylindrical filter wall 91. Furthermore, even more radially inwards, the transverse connecting flange 17 can be provided with a plurality of radial reinforcing ribs 62 on its underside which extend between the second cylindrical filter wall 91 and a cylindrical tube 16 surrounding the spout 12 .
[092] As shown in Figures 3 and 3a, the transverse connecting flange 17 may also be provided with a plurality of radial reinforcing ribs 64 on its upper face extending between the first cylindrical filter wall 81 and a cylindrical wall 66 which is aligned with the second cylindrical filter wall 91, but extends upwards from the transverse connecting flange 17 in the opposite direction to the direction of the second cylindrical filter wall 91. In other words, the cylindrical wall 66 and the second filter wall cylindrical 91 seat on opposite sides of the cross connecting flange 17.
[093] Furthermore, even more radially inward, the transverse connecting flange 17 can be provided with a plurality of radial reinforcing ribs 65 on its upper face that extend between the cylindrical wall 66 and the cylindrical rim 20 surrounding a top end of discharge nozzle 12.
[094] The first filter openings 82 and the second filter openings 92 are preferably formed as slits that are relatively thin in a peripheral direction of the first cylinder filter wall 81 and the second cylinder filter wall 91 and relatively long in a their longitudinal direction. The slits can be configured to filter beverage ingredient particles having a dimension of at least 0.5 millimeters, preferably in the range of 0.5-2 millimeters. A critical dimension (the smallest dimension being, for example, the width) of the slits of the first cylindrical filter wall 81 and the second cylindrical filter wall 91 may be 0.4 to 0.6 millimeters, preferably 0.5 millimeters, to in order to capture the larger particles, but allow the beverage to flow out of the beverage ingredient chamber 6 without a substantial undesirable increase in back pressure. The slits may extend from a free edge (i.e., the rim) of each of the first cylindrical filter wall 81 and the second cylindrical filter wall 91. The slits in the first cylindrical filter wall 81 may have 3.0 millimeters long. The slits in the second cylindrical filter wall 91 can be 1.8 millimeters long.
[095] The first filter 8 and the second filter 9 may each be formed from a rigid, impermeable material, such as a plastic material, such that none of the beverage, aqueous medium or beverage ingredient can pass through the first filter 8 and second filter 9, except through first filter openings 82 and second filter openings 92.
[096] As shown in Figure 2, the second cylindrical filter wall 91 is disposed within the first cylindrical filter wall 81. The second filter 9 is thus disposed downstream of, and spaced from, the first filter 8, even that the first filter 8 and second filter 9 can both be formed as an integral part of the inner member 3. The first cylindrical filter wall 81 and second cylindrical filter wall 91 can be arranged concentrically with each other and also be centered on the central axis of body 2 when assembled.
[097] The spout 12 of the inner member 3 is arranged to channel the beverage to the outlet point 14 of the cartridge 1. As illustrated in Figure 6, the outlet point 14 can be provided at or near the central axis of the cartridge. 1. The spout 12 can be surrounded by the cylindrical tube 16 which extends part of the way along the length of the inner member 3 of the cross-connecting flange 17. The spout 12 and the cylindrical tube 16 can be arranged concentrically inside the second cylindrical filter wall 91. Thus, preferably all of the first cylindrical filter wall 81, second cylindrical filter wall 91, the cylindrical tube 16 and the discharge spout 12 are arranged concentrically with each other and centered on the cartridge central axis 1.
[098] An annular space 18 is defined between an inner face of the second cylindrical filter wall 91 and an outer face of the cylindrical tube 16. The cylindrical tube 16 is not provided with any openings and does not allow fluid to pass through its wall. Instead, fluid communication between the annular space 18 and the spout 12 is provided by a channel 19, as shown in Figures 3 to 5. The channel 19 defines a passage, similar to a chimney, which extends parallel to the central axis. of cartridge 1 from the vicinity of the second filter openings 92 and through the transverse connecting flange 17. The channel 19 is defined by two curved walls 19a and 19b which extend, on the underside of the transverse connecting flange 17, between the second cylindrical filter wall 91 and cylindrical tube 16 and extends, on the upper side of transverse connecting flange 17, between cylindrical wall 66 and cylindrical rim 20. The lower end of the two curved walls 19a and 19b to near the rims of the second cylindrical filter wall 91 and cylindrical tube 16 so as to form an inlet point 67 of channel 19. An outlet point of channel 19 at the upper end of channel 19 is in fluid communication with the flow constriction, as if will be described later.
[099] The cartridge 1 can be provided with means for entraining air in the beverage, for example, in the form of an eductor. As used herein, the term eductor refers to the use of a flow constriction in the form of an opening, or similar structure, to form a beverage jet, the opening being located in the beverage flow path upstream of an air inlet 27 and an expansion chamber, said opening being arranged to produce a jet of beverage which jets into the expansion chamber for producing a low pressure zone in the vicinity of the air inlet 27, which makes air is drawn in through the air inlet 27 and becomes entrained in the beverage stream as a plurality of bubbles.
[100] In the first embodiment of Figures 1 to 6, the flow constriction is arranged downstream of the second filter 9, which is downstream of the second cylindrical filter wall 91. As shown in Figures 3, 3a and 6, the cylindrical ring 20 surrounds an inlet for the discharge spout 12. An inwardly directed shoulder 26 is provided immediately within the cylindrical ring 20. At a point around the circumference of the cylindrical ring 20 a slit 25 is provided, the slit 25 extending therefrom. from an upper edge of the cylindrical rim 20 to a point slightly below the level of the inwardly directed shoulder 26. As shown in Figure 6, when the cartridge 1 is assembled, the cylindrical extension 24 of the body 2 is seated within the cylindrical rim 20 and rests against the inwardly directed shoulder 26. The cylindrical extension 24 substantially closes the inlet of the spout 12 including closing the upper end of the slit 25. Because the slit 25 in the cylindrical rim 20 extends below it. the level of the shoulder 26, directed inwards, the opening to form a jet of beverage remains open to provide a fluid path through the cylindrical rim 20. Thus, in assembly, the slit 25 together with the body 2 defines the constriction of flux in the form of the resulting opening. The resulting aperture can be 0.65mm x 1.00mm in dimension with a cross-sectional area of 0.65 square millimeters.
[101] Preferably, the location of slit 25 is aligned with the exit point of channel 19, as shown in Figure 3a.
[102] As shown in Figure 3a, the air inlet 27 is located immediately downstream of the opening resulting from the partial closure of the slit 25. The air inlet 27 may comprise a round hole, but in the illustrated embodiment it comprises an elongated slit which extends through the transverse connecting flange 17 so as to provide gas communication between a point above the transverse connecting flange 17 within an upper part of the discharge spout 12 and a void space below the transverse connecting flange 17 between the tube cylindrical 16 and discharge nozzle 12. Preferably, air inlet 27 is circumferentially aligned with slit 25. Air inlet 27 is provided within a tapered channel 70 formed in line with slit 25. it comprises a floor and two side walls that converge towards a flap 72. The air inlet 27 can be located towards a root of the tapered channel 70 adjacent to the cylindrical rim 20.
[103] The upper end of the spout 12 may also be provided with a plurality of vertical projections 71 which extend upwards from the transverse connecting flange 17 and surround a mouth of the spout 12 outlet port.
[104] The diameter of the first cylindrical filter wall 81 can be relatively large compared to the inside diameter of the beverage ingredient chamber 6. For example, the diameter of the first cylindrical filter wall 81 can be 29mm and the inside diameter Max of 6 beverage ingredient chamber can be 57mm. Therefore, each side of the resulting annular beverage ingredient chamber 6, as shown in Figure 6, has a width, w, of 14 millimeters and a height, h, of 29 millimeters. In this way, an empty space is provided which allows the beverage ingredient(s) to be filled into the cartridge 1, where the local bed thickness of the beverage ingredient (5) is about 2 times the local bed width of the beverage ingredient(s).
[105] The lid 5 can be formed from a composite material. The composite material may comprise an aluminum layer. The composite material may comprise one or more polymer layers, for example a polypropylene layer and/or a polyethylene terephthalate (PET) layer.
[106] When sealed to the body 2, the cap 5 forms a seal with the flange 42 of the body 2 and also an inlet chamber rim 32. Furthermore, the cap 5 is sealed to the distal end of the inner member 3, namely the rims formed by the free edges of the first cylindrical filter wall 81, the second cylindrical filter wall 91 and the cylindrical tube 16.
[107] Cartridge 1 may contain one or more beverage ingredients in beverage ingredient chamber 6. Cartridge 1 of the present invention finds particular application where the one or more beverage ingredients are one or more soluble beverage ingredients. For example, the one or more beverage ingredients may comprise one or more powdered beverage ingredients. The one or more beverage ingredients may comprise particles of reduced solubility or insoluble, for example, cocoa powder or powder blends containing coarsely ground spices (for example, cinnamon). A non-exhaustive list of beverage ingredient examples includes powdered chocolate, powdered milk, creams, instant coffee, fruit and vegetable powders, condiments, herbs and spices partially/coarsely ground including but not limited to cinnamon, ginger, cardamom , etc.
[108] In use, the sealed cartridge 1 is inserted into, or otherwise coupled to, a beverage preparation machine in order to dispense a beverage (or beverage portion) from the cartridge 1. During operation of the beverage cycle. dispensing an inlet is formed at the inlet point 13 and an outlet is formed at the outlet 14, for example by perforating the lid 5 by elements of the beverage preparation machine. A beverage flow path can then be defined connecting the inlet point 13 to the outlet 14 along which an aqueous fluid, which will be exemplified in the following as hot water, can pass. The beverage flow path is defined by spatial interrelationships between the body 2, the inner member 3 and the cap 5.
[109] The beverage flow path passes, in order, from the inlet point 13, through the inlet chamber 32, out of the blasting slit 33, around the annular beverage ingredient chamber 6, through the first filter openings 82 of the first cylindrical filter wall 81, through the second filter openings 92 of the second cylindrical filter wall 91, into the annular space 18, into and above the channel 19, through the opening of the eductor, over the air inlet 27 of the eductor, to the spout 12 and finally arrives at the outlet point 14. From the outlet at the outlet point 14 the beverage can be discharged into a suitable container.
[110] The orientation of the blasting slit 33 causes the hot water entering the annular beverage ingredient chamber 6 to rotate and circulate around the inner member 3 potentially a large number of times. In doing so, hot water is better able to dissolve soluble beverage ingredients. In particular, the energetic nature of the hot water jet from the jetting slit 33 and the circulation of hot water around the full circumference of the annular beverage ingredient chamber 6 helps to break up any agglomerates of soluble beverage ingredient within. of cartridge 1. Furthermore, while not wishing to be bound by theory, the configuration where the local bed thickness of the beverage ingredient is 1.5 to 2.2 times the local bed width of the beverage ingredient is believed to aid with breaking down soluble beverage ingredient agglomerations by firstly confining the circulating water to a relatively narrow annular volume which results in maintaining higher water velocities within the beverage ingredient chamber 6 and secondly , by providing a greater circumferential surface area of the beverage ingredient that can be directly exposed to water.
[111] While not wishing to be bound by theory, the dispersion and dissolution of the soluble beverage ingredients is understood to be triggered by shear stress applied to break up the wet powder mass of the soluble beverage ingredients as it is brought into contact by the Water. By using the first cylindrical filter wall 81, which can be relatively large compared to the inside diameter of the beverage ingredient chamber 6, the shear rate of the water can be increased and thus the shear stress applied to the mass. of wet powder of the beverage ingredient mix can be increased leading to better dissolution of the soluble beverage ingredients. For an inlet area of 3-2 square millimeters and operating at pressures of 0.6 to 1.2 bar (60 to 120 kPa) the pump in a test system was found to provide a flow rate of 5.5 to 3 .6 ml/s for entry point 13. The fluid velocity, V, through entry point 13 was in the range of 0.9-1.8 m/s. When the annular width of the beverage ingredient chamber is 9.5 millimeters, dividing the inlet velocity by this gap provides estimates of applied chamber shear rates of between 95-190 1 / s.
[112] The beverage thus formed from the hot water and the dissolved beverage ingredients is then able to pass out of the beverage ingredient chamber 6 through the first filter openings 82 of the first cylindrical filter wall 81 and then the second filter openings 92 spaced apart from the second cylindrical filter wall 91. The first and second filter openings 82, 92 act to filter out of the beverage any insoluble particles that may have been present in the beverage ingredients and also particles that have a reduced solubility such that, for whatever reason, the particles are not dissolved during the dispensing cycle.
[113] Thus, the first filter 8 defines an outlet from the beverage ingredient chamber 6 and the second filter 9 forms a secondary filter that allows to improve the filtering performance of the cartridge 1. The size of the second filter openings 92 can be smaller than the size of the first filter openings 82 so that the first filter 8 acts as a 'coarse' filter and the second filter 9 acts as a 'fine' filter.
[114] By providing the first and second filter openings 82, 92 to be arranged around a larger portion of the circumference, respectively, of the first and second cylindrical filter walls 81, 91 dispensing performance of the cartridge 1 is maintained even when the first and second cylindrical filter walls 81, 91 retain and contain particles on their upstream sides. This could be for two reasons. Firstly, the relatively large surface area of the first filter 8 and the second filter 9 (since they extend around a larger portion of the circumference) means that even if some filter openings 82, 92 become blocked enough others filter openings 82, 92 are present to allow adequate beverage flow through without creating a very high level of back pressure within the cartridge 1. Secondly, the cylindrical shape of, in particular, the first filter 8 means that there is a tendency for filtered particles trapped by the first filter openings 82 to be "washed" from the first filter 8 by the hot water/beverage mixture circulating within the annular beverage ingredient chamber 6, so that the filtered particles tend to be driven away from back into circulating fluid flow rather than remaining trapped against the first filter openings 82.
[115] A particular advantage is that the first filter 8 and the second filter 9 prevent beverage ingredient particles larger than a predetermined desired size from reaching the flow constriction, preventing the flow constriction from becoming fully or partially blocked by such particles.
[116] The beverage backpressure collecting in the beverage ingredient chamber 6 forces the beverage under pressure through the first filter 8, the second filter 9, the annular space 18 and the channel 19. The beverage then passes through the eductor. In doing so, the beverage jet passes over the air inlet 27. As a result air is entrained into the beverage stream in the form of a plurality of small air bubbles when air is drawn over the air inlet 27. The beverage jet exiting the opening flows turbulently inside the top of the spout 12, where collisions with the vertical projections 71 help to modify the size of the bubbles within the beverage. The beverage is then channeled down through the outlet port of the spout 12 to the outlet when the beverage is discharged into a receptacle such as a cup in which the air bubbles form the desired foamy appearance.
[117] Various modifications can be made to the cartridge 1 of the present invention as described above without departing from the scope of the present disclosure. In the following passages of the description a number of modifications and alternatives will be described which can be done singly or in any combination, unless the context explicitly indicates otherwise. In what follows only the changes will be described in detail. In other aspects, cartridges 1 are as described above. In the following description, like numbers are used for like features and components.
[118] Figures 7 and 8 show an alternative form of inner member 103 that can be used with body 2 as described above to form another embodiment of cartridge 101. Inner member 103 is similar to inner member 3 described above, except that it comprises a second flow constriction, and a second air inlet 127 is provided on the cross connecting flange 17. The second flow constriction and the second air inlet 127 have the same shape as the flow constriction and the air inlet 27. In each case, the size of the resulting opening of the eductor is half the size compared to the first modality - each opening having a cross-sectional area of 0.65mm x 0.5mm = 0.33mm square. Thus, the combined open area of the two eductor openings is the same as the open area of the single eductor opening of the first modality.
[119] The second air inlet 127 is circumferentially aligned with the second flow constriction. In addition, the second air inlet 127 and the second flow constriction are spaced apart from the air inlet 27 and the first flow constriction around the circumference of the annular flange 17. Preferably, they may be located diametrically opposite the inlet. air 27 and the flow constriction 10, as shown in Figure 8.
[120] Another difference is that the second cylindrical filter wall 91 extends directly from the mounting flange 50 rather than from the cross-connecting flange 17. Thus, the cross-connecting flange 17, in this embodiment, only extends radially inwardly from the second cylindrical filter wall 91. As a result, the radial reinforcing ribs 160 between the first cylindrical filter wall 81 and the second cylindrical filter wall 91 are higher than in the first embodiment described above.
[121] As well as channel 19, a second channel 119 is provided to provide fluid communication between the annular space 18 and the discharge nozzle 12. The second flow constriction is arranged downstream of the second channel 119 such that two paths flows from the annular space 18 to the spout 12 are defined, the first flow path passing through the channel 19 which now forms a first channel and first flow constriction and the second flow path passing through the second channel 119 and the second flow constriction.
[122] Since the second flow constriction is spaced from the first flow constriction around the circumference of the annular flange 17 in use the beverage jets emerging from the first flow constriction and the second flow constriction collide at the top of the 12 spout, resulting in improved mixing and frothing of the beverage. In the preferred arrangement, where the two eductors are diametrically opposed to each other, the beverage jets impact each other substantially head-on. The inclusion of the second flow constriction has been found to result in reduced back pressure within the cartridge 101 in use.
[123] In use, the back pressure of beverage collecting in the beverage ingredient chamber 6 forces the beverage under pressure through the first filter 8 and the second filter 9 as described above. The beverage flow then separates into two flows the first flow passing through the first channel 19 and the first flow constriction and the second flow path passing through the second channel 119 and the second flow constriction, emerging from each constriction. flow as a jet to the upper end of the spout 12. A first beverage jet emerges from the first flow constriction and passes over the air inlet 27. A second beverage jet emerges from the second flow constriction and passes over the second air inlet 127. As a result air is entrained in both beverage streams in the form of a plurality of small air bubbles when air is drawn through the air inlets 27, 127. The two jets collide at the discharge nozzle 12 before they are funneled down to the outlet.
[124] Figures 9 to 11 show another alternative shape of the inner member 203 that can be used with the body 2 described above or a modified body 202 described below, to form another embodiment of the cartridge 201.
[125] As before, the cartridge 201 comprises an inlet chamber 32. However, the inlet chamber 32 is not provided with a blast slit 33 communicating directly with the beverage ingredient chamber 6. Instead, the chamber inlet 32 is provided with opposing slits 133 which communicate with the annular void 44. In addition, the inner wall 43 is provided with a pair of inlets 213 disposed on opposite sides of the beverage ingredient chamber 6 as shown in Figure 9 The pair of inlets 213 may be diametrically opposed to one another and may be in the form of small slits in the inner wall 43.
[126] Cartridge 201 further comprises the alternative form of inner member 203. Inner member 203 comprises a filter 208, a first flow constriction, a second flow constriction, and a discharge nozzle 12. The filter 208 defines an outlet from the beverage ingredient chamber 6. The filter 208 performs the same function as the first filter 8 described above. In this mode there is no second filter. The first flow constriction and second flow constriction are disposed downstream of the filter 208.
[127] Filter 208 comprises a cylindrical filter wall 281 having a plurality of filter openings 282 located therein. The cylindrical filter wall 281 is in the form of a tubular member comprising filter openings 282. The filter openings 282 are preferably formed as slits that are relatively thin in a peripheral direction of the cylindrical filter wall 281 and relatively long in a longitudinal direction thereof. The slits can be configured to filter beverage ingredient particles having a dimension of at least 0.5 millimeters, preferably in the range of 0.5-2 millimeters. A critical dimension (the smallest dimension being, for example, the width) of the slits of the cylindrical filter wall 281 may be 0.4 to 0.6 millimeters, preferably 0.5 millimeters, in order to capture the larger particles. , but allowing the beverage to flow out of the beverage ingredient chamber 6 without an unwanted substantial increase in back pressure. The slits may extend from a free edge (i.e., the rim) of the cylindrical filter wall 281. The slits in the cylindrical filter wall 281 may be 3.0 millimeters long.
[128] The discharge spout 12 and the cylindrical tube 16 of the inner member 203 are disposed within the cylindrical filter wall 281 and connected thereto by the transverse connecting flange 17 as before.
[129] An annular space 218 is defined between an inner face of the cylindrical filter wall 281 and an outer face of the cylindrical tube 16. Fluid communication between the annular space 218 and the discharge nozzle 12 is provided by channel 19, which now forms a first channel and a second channel 119, as in the embodiment described above. The arrangement of the first flow constriction, second flow constriction and the discharge nozzle 12 is as described for the inner member 103.
[130] The diameter of the cylinder filter wall 281 may be smaller than the first cylinder filter wall 81 of the embodiments described above. For example, the diameter of the cylindrical filter wall 281 may be 18.5 millimeters. As before, the maximum inside diameter of the beverage ingredient chamber 6 can be 57 millimeters. Therefore, each side of the resulting annular beverage ingredient chamber 6 has a width, w, of 19 millimeters and a height, h, of 29 millimeters. In this way, an empty space is provided which allows beverage ingredient to be filled into the cartridge 1, where the local bed thickness of the beverage ingredient is about 1.5 times the local bed width of the beverage ingredient.
[131] Use of cartridge 201 is the same as described above with reference to cartridge 101 including inner member 103 except for the differences described below.
[132] On hot water injection into the inlet chamber 32, the water passes through the opposing slits 233 to the annular void 44 until it reaches the pair of inlets 213. The water is then diverted to be blasted into the chamber of beverage ingredient 6 in a radial direction towards the inner member 203. The water impacts the inner member 203 and then rebounds and establishes a circulatory pattern within the annular beverage ingredient chamber 6. As before, water passage heat inside the 6 ring beverage ingredient chamber acts to dissolve the soluble beverage ingredients.
[133] The beverage collection back pressure in the annular beverage ingredient chamber 6 forces the beverage under pressure through the filter 208. The beverage passes directly into the annular space 218. The beverage flow then separates. in two flows, the first flow passing through the first channel 19 and the first flow constriction and the second flow path passing through the second channel 119 and the second flow constriction as in the inner member 103. Then dispensing is such as was described earlier.
[134] As noted, modifications and alternatives described above can be done alone or in any combination, not just the above-mentioned combinations explicitly in the described modalities. For example, as used in some of the examples worked below, cartridge embodiments in accordance with the present description may combine the body 2 of Figure 1 (having the blast slit 33) with an inner member (not shown) having a single wall. cylindrical filter 281 having filter openings 282 and a single eductor. Or in another example, the cartridge may combine the body 202 of Figure 9 (having opposing slots 133) with an inner member (not shown) having a single cylindrical filter wall 281 having filter openings 282 and a single eductor. EXAMPLES
[135] In the following examples cartridges were prepared and then distributed in a beverage machine using hot water at ~85°C.
[136] In each test the same beverage ingredient composition was used - which was a conventional soluble chocolate beverage ingredient mix, comprising: sugar (-45-50%) cocoa powder (~5-10%) milk powder (-5-10%) skim milk powder (~ 15-25%) whey powder (0-15%) cream (0-10%) with the balance of other smaller ingredients such as flavors ( <1%).
[137] In all cases, the soluble powdered chocolate beverage ingredient mixture was loaded into the cartridge in fill weights ranging from 2533 g. The cartridge was then sealed with cap 5. The cartridge was dispensed into a Tassimo ® T-20 / Amia beverage preparation machine running at 240V. “purge” were measured and recorded. The “brew” stage is the period of the dispensing cycle where most of the hot water is injected into the cartridge to mix with the beverage ingredients and be directed into the receptacle The "purge" stage follows the "prime" stage and involves injecting steam through the cartridge (although some residual water may also be present) in order to drive out as much liquid as possible from the cartridge to the inside the receptacle. At the end of beverage dispensing, the weight of beverage delivered into the receptacle and the weight of the wet cartridge were recorded. Finally the wet cartridges were placed in an oven at ~103-105°C for three hours or until full The water has evaporated. The dry residue in grams was measured by weighing the dry cartridges and then the % solids in the cup was calculated and expressed as % yield in the cup. All tests were repeated 100 times and the results for each cartridge type were averaged.
[138] A summary of the results is shown in Table 1 below, where: For Example 1 - a comparative example of a cartridge as shown in Figure 12 was used having a body 202 of the same type as shown in Figure 9, a inner member 303 having a cylindrical wall 381 of 18.5 millimeters in diameter and provided with large openings 382 (not filtering openings), and having a single eductor. The filling weight of beverage ingredient is 33g. For Example 2 - a cartridge as shown in Figure 13 was used having a body 202 of the same type as shown in Figure 9, an inner member 403 similar to the inner member 203 as shown in Figure 10, in which it has a single wall 281 cylindrical filter 18.5mm in diameter, but only a single eductor. The filling weight is 33g. For Example 3 - a cartridge was used which comprises a body 2, as shown in Figure 1, an inner member having a single cylindrical filter wall 29mm in diameter and having filter openings and a single eductor. The filling weight is 25g. For Example 4 - a cartridge was used comprising a body 2 as shown in Figure 1 and an inner member 103 as shown in Figures 7 and 8 having first and second cylindrical filter walls 81, 91 having filter openings in the same with the first cylindrical filter wall 81 having a diameter of 29 millimeters. The filling weight is 25g. For Example 5 - the cartridge used is the same as in Example 2, but with a filling weight of 26 g.
[139] In each example, the cartridge is sealed with a cap. Table 1

[140] As can be seen from the results, the cartridges of Example 1, which do not have a first filter 8 or second filter 9 according to the present invention and have only a single flow restriction in the form of a single eductor suffer of relatively high peak pressures - during the 1.6 bar (160 kPa) preparation stage and during the 2.1 bar (210 kPa) purge stage. While not wishing to be bound by theory, it is believed that the high peak pressures are caused by a partial or complete blockage (by at least some of the dispensing cycle) of the single flow restriction at the narrowest point of the eductor gap. by particles of the beverage ingredient(s) which are either relatively insoluble or which have not sufficiently dissolved before reaching the flow restriction. The yield from cartridges is also relatively low at 82%.
[141] The cartridges of Example 2, which have only a single filter and a single flow restriction in the form of a single eductor benefit from slightly reduced peak pressures compared to Example 1 - during the 1 preparation stage, 0 bar (100 kPa) and during the purge stage 1.6 bar (160 kPa). However, the yield from capsules is low at 77%.
[142] On the other hand the cartridges of Examples 3 to 5 benefit from significantly reduced peak pressures in combination with better yields. More preferably, the cartridges of Example 4 have low peak pressures - during the 0.6 bar (60 kPa) preparation stage and during the 0.9 bar (90 kPa) purge stage in combination with the yield of the capsules. being increased to 91%.
[143] While not wishing to be bound by theory, it is believed that the improvements, in particular to the cartridges in Examples 3 to 5, come from a combination of factors. The provision of at least one filter in the form of a filter wall with filter openings is believed to help prevent partial or complete blocking of the flow restriction(s) at the narrowest point of the eductor gap(s) by particles of the ingredient(s). ) of beverage that are either relatively insoluble or that have not dissolved enough, as these particles are retained by the filter openings upstream of the flow restriction. Furthermore, configuring the filter as a cylindrical filter with a large number of individual filter openings in the form of slits means that even if some are blocked, others remain to allow the beverage to flow forward towards the exit point. Furthermore, the circulating, rotating flow within the annular beverage ingredient chamber 6 may have a tendency to "wash" the particles from the surface of the filter wall leading to reopening of blocked filter openings. This beneficial effect is enhanced when the inner member has a relatively large diameter compared to the body so that the local bed width of the beverage ingredient is 1.5 to 2.2 times the local bed width of the beverage ingredient.
[144] Various other modifications that can be made to any of the cartridges of the present invention as described above (or other cartridges) will now be described, without departing from the scope of the present disclosure. In the following passages of the description a number of modifications and alternatives will be described which can be done singly or in any combination, unless the context explicitly indicates otherwise. In what follows only the changes will be described in detail. In other aspects, the cartridges may be as described above or as defined in the appended claims. In the following description, like numbers are used for like features and components.
[145] As shown in Figures 14 and 14b a duct upstream of the or each flow constriction can be configured to prevent deposition of undissolved or partially dissolved beverage ingredient. As can be seen in the cartridge version shown in Figure 14a, the shape and sizing of the centrally located protrusion 40 with its cylindrical extension 24 can result in the existence of a "dead space" 50 at an upper end of channel 19 immediately upstream of each flow constriction 10. In the modified cartridge shown in Figure 14b, the portion of channel 19 immediately upstream of the flow constriction 10 has been smoothed by extending the centrally located protrusion 40 so that it ends flush with the upper edge of the slit 25 of the flow restriction 10. This results in not having any dead spaces, sharp corners, or sudden changes in concavity upstream of the flow restriction that may encourage particle deposition.
[146] As shown in Figures 15 to 18, the beverage ingredient chamber 6 may comprise one or more partition elements 151 that act to demarcate two or more zones 6a to 6d within the beverage ingredient chamber 6, each of which contains one or more beverage ingredients. Preferably, the one or more partition elements 151 extend from the first filter 8 towards the body 2 of the cartridge 1. The one or more partitions 151 may be flat, as shown in Figure 16, and may be oriented radially towards the inside of the body 2. In the example shown in Figures 15 and 16 there are four partitions 151 provided equally spaced around the circumference.
[147] Figure 17 shows an alternative where the one or more partitions 152 are curved. This can help tunneling the drink to the first filter 8.
[148] The one or more partitions 151, 152 may extend from the first centrally located filter 8 towards the surrounding wall of body 2. Alternatively, as shown in Figure 18, partitions 153 may be provided that extend in contact with the wall. surrounding the body so as to completely separate the zones 6a to 6d from one another within the beverage ingredient chamber 6. Each separate zone 6a to 6d will comprise at least one inlet 33 allowing entry of the aqueous medium into the zone and, at least a portion of the first filter 8 allowing the beverage to escape from the zone.
[149] Advantageously, separating the beverage ingredient chamber 6 into two or more zones 6a to 6d can produce better dissolution of the one or more beverage ingredients by focusing the mixture of aqueous medium and beverage ingredients in key areas and providing patterns flow alternatives.
[150] As shown in Figures 19 to 21, a flow path from the filter(s) 8, 9 to the flow constriction(s) 10 can be configured to be spiral shaped. For example, spiral ramp elements 154 may be located within the annular space 18 between the end filter (the second filter 9 where present, or the first filter 8 where only one filter is provided) and the cylindrical tube 16, at that the beverage is forced to flow through the annular space 18 on the way to the flow constriction(s) 10. The spiral ramp elements 154 spiral the beverage around the cylindrical tube 16 creating additional mixing vortices and eddies within the drink. Advantageously, this flow pattern can help break up small, partially wet clumps of beverage ingredient that may have made it through the filter(s). Additional obstructions 155, eg ribs, corners, etc., can be provided on the spiral ramp elements 154 to help break up agglomerates. In the illustrated example, four spiral ramp elements 154 are provided equidistant around the circumference with each spiral ramp element 154 rotating approximately 90 degrees.
[151] As shown in Figures 22 to 24, beverage ingredient chamber 6 may contain a plurality of bristles 156. Bristles 156 may advantageously act to interrupt the flow path with beverage ingredient chamber 6 to promote turbulence and better mixing of one or more beverage ingredients. Bristles 156 may be disposed around and spaced apart from first filter 8. Bristles 156 may comprise elongated plastic pins. The bristles may extend the entire height of the beverage ingredient chamber 6. The bristles 156 may be formed unitarily as part of the inner member 3 also comprising the first filter 8 received within the body 2. In the example shown, the bristles 156 extend downwardly. from the mounting flange 50. The bristles 156 are arranged in three concentric rings on the first filter 8. The spacing between neighboring bristles 156 is such that the bristles 156 do not perform a filtering function, but act to break up ingredient clumps. of powdered drink.
[152] As shown in Figure 25, the body 2 of the annular beverage ingredient chamber 6 may comprise multiple inlet points 33, each of which can be angled so that the inflow of aqueous medium is prevented from radially entering. , but it is instead angled at more than 45° and preferably at 90°. As shown in Figure 25, angulation can be achieved by providing an L-shaped cover 160 for each inlet slit 33 so that the flow is rotated 90° before entering the annular beverage ingredient chamber. As shown the body comprises four entry points 33 spaced 90° apart. Other entry point numbers can be provided.
[153] As shown in Figure 26, the body 2 defining the beverage ingredient chamber 6 may have one or more lobes 162 as part of an outer side wall of the beverage ingredient chamber 6. The one or more lobes 162 may be gently convexly curved (when viewed from a center point of the cartridge) with a smooth inwardly directed face 163. A lobe 162 can be provided between pairs of inlet openings 33 to the beverage ingredient chamber 6. Advantageously, the one or more lobes 162 can improve dissolution of the one or more beverage ingredients by first confining the inlet aqueous medium to a smaller cross-sectional flow area leading to improved shear forces and higher flow velocities that improve dissolution. Second, the one or more lobes 162, when positioned between pairs of inlet openings 33, tends to decrease the amount of "dead space" in the beverage ingredient chamber 6. By "dead space" is meant that part or parts of the volume of the beverage ingredient chamber 6 where circulating flow of the aqueous medium and/or beverage tends not to reach. For example, with an annular beverage ingredient chamber 6 with four equally spaced radially directed inlet openings 33 at, for example, 0°, 90°, 180° and 270°, it has been found that the locations by the sidewall at 45° , 135°, 225°, and 315° tend to be "dead spaces" that tend not to be reached by the circulation flow.
[154] As shown in Figure 27, the beverage ingredient chamber 6 may comprise two or more separate chambers 164, 165 each of which has a different beverage ingredient. For example, a first chamber 165 may contain sugar or a sugar containing ingredient and a second chamber 164 may contain a chocolate containing ingredient. Each separate chamber will comprise at least one inlet 33a, 33b allowing entry of the aqueous medium into the interior of the chamber and at least a portion of the first filter 8 allowing outflow of the beverage from the chamber. Advantageously, such an arrangement can be used to adapt the size and number of inlet openings and the size and number of filter openings for each ingredient.
[155] As shown in Figure 28, the beverage ingredient chamber 6 may comprise a dedicated flow conditioning chamber 168 that receives incoming aqueous medium in a first condition and discharges the aqueous medium into a remainder of the beverage ingredient chamber. in a second condition. The first and second conditions can include one or more of the following: first and second flow rates, first and second flow directions, and first and second flow compositions. For example, the flow conditioning chamber 168 may comprise an angled wall 167 for conditioning an inlet aqueous medium having a first condition of a relatively low flow rate, a radial flow direction 169 and a pure water composition for a second. condition of a flow having a relatively high flow velocity, a tangential flow direction 166 and a composition of water mixed with one or more beverage ingredients.
[156] As shown in Figure 29, the beverage ingredient chamber 6 may comprise a plate member 175 that initially rests on a bed of the one or more beverage ingredients. The use of the plate member 175 finds particular application where the inlet(s) 33 to the beverage ingredient chamber is located at or towards a bottom of the beverage ingredient chamber. In use, when the one or more beverage ingredients are incrementally dissolved away from below the plate member 175 the weight of the plate member 175 (which can be freely moveable within the beverage ingredient chamber 6) forces the ingredient to undissolved beverage further up in the beverage ingredient chamber down to the inlet aqueous medium path. Plate member 175 may comprise openings 176 to allow circulation of the aqueous and/or beverage medium above and below the plate member in use, as shown by arrows 177.
[157] As shown in Figure 30, the beverage ingredient chamber 6 may contain a rotary blender blade assembly 178. The rotary blender blade assembly 178 may comprise one or more vanes or blades 179 that act to break up agglomerations of powdered beverage ingredient when the rotary mixer blade assembly 178 rotates within the beverage ingredient chamber 6. Rotation of the rotary mixer blade assembly 178 is caused by the movement of the aqueous medium, and in this case, the rotation can be increased by jetting the aqueous medium into the beverage ingredient chamber 6 with a tangential directional component so as to generate a swirl flow within the beverage ingredient chamber 6.
[158] As shown in Figures 31 and 32, the beverage ingredient chamber 6 may comprise one or more baffles oriented to induce vertical vortices within the beverage ingredient chamber. In the example of Figure 31 a curved baffle 190 is provided as part of the inner member 3 and received aqueous inlet medium which is blasted into the beverage ingredient chamber at the bottom of the chamber. The curved baffle 190 directs the flow upward so that a vertical flow vortex is created as shown by arrow 191. In the example of Figure 32, a baffle 193 is provided at the base of the beverage ingredient chamber 6 near the inlet point. 33 which causes the inlet fluid to be directed upward initially to create a vertical vortex, as shown by arrow 194.
[159] The disclosure has been described above by way of example as having a body 2, 202 and inner member 3, 103, 203 formed as separate components that are joined during cartridge assembly. Alternatively, the body 2, 202 and inner member 3, 103, 203 can be formed as a single component.
[160] The disclosure has been described above by way of example incorporated into a cartridge formed from, inter alia, an outer member 2 and an inner member 3. In particular, the flow constriction has been described as delimited by body portions 2, 202 and inner member 3, 103, 203. However, it should be understood that the description is also applicable to openings formed in a single component, rather than from the joining of two components.
[161] The one or more beverage ingredients can be a powder, a concentrated liquid, or a gel. The described cartridge is suitable for any product which forms coagulates or agglomerates or which comprises particles susceptible to remain undiluted by the aqueous medium. For example, beverage ingredients can be concentrated chocolate, flavor enhancing syrups, vitamin supplements or powdered chocolate mix, containing insoluble cocoa particles, which are typically 0.5 to 2 millimeters in size.
[162] Cartridge 1, 101, 201 can be rigid, semi-rigid or flexible. Body 2 can be formed as a single integral piece from high density polyethylene, polypropylene, polystyrene, polyester, or a laminate of two or more of these materials. The body 2, 202 can be opaque, transparent or translucent. The body 2, 202 and/or inner member 3, 103, 203 can be formed from a biodegradable polymer.
[163] The body 2, 202 described above is generally circular or disc-shaped. Alternatively, body 2, 202 may be otherwise suitable for insertion into an on-demand beverage machine, for example, body 2, 202 may be frustroconical or cup-shaped.
[164] Cartridge 1, 101, 201 can be closed by a rigid or semi-rigid cap instead of a flexible laminate.

权利要求:
Claims (8)
[0001]
1. Cartridge for preparing a beverage, the cartridge being sealed prior to use and containing one or more beverage ingredients, the cartridge being suitable for receiving in use an aqueous medium that can be brought into contact with one or more beverage ingredients for producing a beverage emitting from the cartridge, the cartridge comprising: - a body (2) defining a beverage ingredient chamber (6) containing one or more beverage ingredients; characterized in that it further comprises: - a first filter (8) defining an outlet from the beverage ingredient chamber (6); - a second filter (9) downstream of and spaced from the first filter (8); and - a flow constriction downstream of the second filter, such that in use beverage produced from the one or more beverage ingredients passes, in order, through the first filter (8), the second filter (9) and the flow constriction wherein the first filter (8) extends around the second filter.
[0002]
2. Cartridge according to claim 1, characterized in that the first filter (8) comprises a first filter wall (81) and the second filter (9) comprises a second filter wall (91) and/or in that the first filter (8) and the second filter (9) each comprise a rigid element having a plurality of filter openings (82, 92) located therein.
[0003]
3. Cartridge according to claim 1 or 2, characterized by the fact that the first filter (8) and the second filter (9) are arranged concentrically.
[0004]
4. Cartridge according to any one of claims 1 to 3, characterized in that the first filter (8) comprises a first tubular member having a plurality of first filter openings (82) located therein and the second filter (9 ) comprises a second tubular member having a plurality of second filter openings (92) located therein, and preferably the second tubular member is disposed within the first tubular member.
[0005]
5. Cartridge according to any one of claims 1 to 4, characterized in that it further comprises a spout (12) for channeling the beverage, in use, towards an outlet of the cartridge, and preferably the first and second filters (8, 9) are arranged around the spout (12); wherein preferably a flow direction, in use, of the beverage flowing from the second filter (9) to the flow constriction is opposite to a flow direction, in use, of the beverage flowing out of the spout (12.
[0006]
6. Cartridge according to any one of claims 1 to 5, characterized in that the cartridge is configured to direct the aqueous medium entering the beverage ingredient chamber (6) to circulate around the first filter (8).
[0007]
7. Cartridge according to any one of claims 1 to 6, characterized in that the beverage ingredient chamber (6) is annular, with the first filter (8) forming at least a part of an interior surface of the beverage chamber. annular beverage ingredient (6), and preferably, the body (2) of the cartridge is configured to direct the aqueous medium entering the beverage ingredient chamber (6) at an angle greater than 45°, preferably 90° to starting from a radial direction of the annular beverage ingredient chamber (6) such that the aqueous medium is circulated around the annular beverage ingredient chamber (6).
[0008]
8. Cartridge according to any one of claims 1 to 7, characterized in that the first filter (8) comprises a plurality of first filter openings (82) and the second filter (9) comprises a second plurality of filter openings. filtering (92) and wherein a critical size of the first filtering openings (82) is greater than a critical size of the second filtering openings (92).

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ES2282804T3|2007-10-16|CARTRIDGE FOR THE PREPARATION OF DRINKS.

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TWI629033B|2018-07-11|Tea swirling machine

同族专利:

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公开号 | 公开日

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CA3011614A1|2015-12-13|

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RU2666512C2|2018-09-07|

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WO2015189689A3|2016-02-18|

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RU2016148239A3|2018-07-13|

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CA3011614C|2021-02-16|

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MX2016016385A|2017-10-31|

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KR20170009905A|2017-01-25|

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CA2894436C|2019-04-09|

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US20150360854A1|2015-12-17|

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JP2017524395A|2017-08-31|

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CA2894436A1|2015-12-13|

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WO2015189689A2|2015-12-17|

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GB201410615D0|2014-07-30|

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AU2015273190A1|2016-12-22|

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ES2810273T3|2021-03-08|

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PH12016502473A1|2017-04-10|

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PL3154875T3|2021-03-08|

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CN106660700B|2019-08-06|

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KR101920985B1|2018-11-21|

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EP3154875A2|2017-04-19|

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TWI580623B|2017-05-01|

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IL249167D0|2017-01-31|

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US20180093820A1|2018-04-05|

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TW201601984A|2016-01-16|

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GB2527292A|2015-12-23|

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BR112016029231A2|2018-07-10|

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EP3154875B1|2020-08-05|

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CN106660700A|2017-05-10|

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RU2016148239A|2018-07-13|

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法律状态:
2018-10-30| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

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2020-01-28| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

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2021-08-03| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

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2021-08-31| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 12/06/2015, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

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申请号 | 申请日 | 专利标题

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GB1410615.7|2014-06-13|

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GB1410615.7A|GB2527292A|2014-06-13|2014-06-13|Cartridge for the preparation of beverages|

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PCT/IB2015/001013|WO2015189689A2|2014-06-13|2015-06-12|Cartridge for the preparation of beverages|

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