System and method for the preparation of cooled edible products

Abstract

Provided is a novel system, machines and consumables, and method for preparation of cooled edible products from their ingredients, for example, in a portioned amount constituting a defined number of servings which may be 1, 2, 3, etc. are provided. One example of such an edible product is ice cream.

Claims

1. An appliance for the preparation of a single serving of cooled edible product from ingredients, said appliance comprising a processor and two or more pods, each containing ingredients for the preparation of said single serving of cooled edible product, the processor comprising: a mixing chamber and a cooling arrangement for mixing the ingredients and cooling a mixture of the ingredients to thereby obtain the cooled edible product, a port configured for receiving at least one of said pods, and configured for coupling the at least one pod to the mixing chamber and transferring at least the majority of the content of the pod to the mixing chamber, and comprising a data reader; each of the two or more pods containing some of the ingredients for the preparation of said single serving of cooled edible product, such that the combination of the ingredients from said two or more pods are utilized by the appliance for the preparation of said single serving of cooled edible product, having a pierceable closure sealing an opening and configured for coupling with the processor and for emptying its content through the opening after the seal is ruptured, and comprises data indicative of process parameters and steps for processing the ingredients by the processor to obtain the cooled edible product after their extraction from the pods, the process parameters being specific for the ingredients, the data being formatted in a manner permitting its identification by said data reader to thereby induce the processor to apply said process parameters.

2. The appliance of claim 1, wherein each of said two or more pods contains different ingredients.

3. The appliance of claim 1, wherein at least a first of the two or more pods contains a fluid and at least second of said two or more pods contains edible ingredients different from said fluid.

4. The appliance of claim 1, wherein said port is configured to receive at least a first of the two or more pods for transferring the ingredients contained therein to the mixing chamber, and configured to deliver the content of at least a second of said two or more pods to an outlet port of the mixing chamber.

5. The appliance of claim 1, wherein said two or more pods constitute a pod assembly that comprises at least one first receptacle and at least one second receptacle, each containing different ingredients for the preparation of said cooled edible product.

6. The appliance of claim 5, wherein said first and said second receptacles are configured for association one with the other before inserting them into the appliance.

7. The appliance of claim 5, wherein said first receptacle is configured for association with different types of second receptacles.

8. The appliance of claim 1, comprising a plurality of data readers, each configured for obtaining data from a different pod of said two or more pods.

9. The appliance of claim 1, comprising a controller configured for receiving data from each of said two or more pods for acquiring and applying the process parameters for the preparation of said single serving of cooled edible product.

10. The appliance of claim 9, wherein the combination of data carried by said two or more pods determines the process parameters for the preparation of a single serving of cooled edible product.

11. The appliance of claim 1, wherein the processor is configured for introducing into said mixing chamber at least one additional ingredient from a source other than said two or more pods.

12. The appliance of claim 1, further comprising a deforming mechanism for deforming the pods after use thereof, to thereby reduce the volume of a used pod.

13. An appliance for the preparation of consecutive single servings of cooled edible product from ingredients, said appliance comprising a processor and a plurality of pods, each pod in said plurality contains ingredients for the preparation of a single serving of said cooled edible product, the processor comprising: a mixing chamber and a cooling arrangement for mixing the ingredients and cooling a mixture of the ingredients to thereby obtain the cooled edible product, a port configured for receiving a pod from said plurality of pods, and configured for coupling the pod to the mixing chamber and transferring at least the majority of the content of the pod to the mixing chamber, configured for successively receiving and processing one pod at a time from said plurality of pods for successively producing consecutive single servings of the cooled edible product, each single serving being produced from one pod out of said plurality, and comprising a data reader; each of the pods having a pierceable closure sealing an opening and configured for coupling with the processor and for emptying its content through the opening after the seal is ruptured, and comprises data indicative of process parameters and steps for processing the ingredients by the processor to obtain the cooled edible product after their extraction from the pod, the process parameters being specific for the ingredients, the data being formatted in a manner permitting its identification by said data reader to thereby induce the processor to apply said process parameters.

14. The appliance of claim 13, further comprising a deforming mechanism for deforming the pods after use thereof, to thereby reduce the volume of a used pod.

15. The appliance of claim 13, wherein each pod comprises data indicative of all process parameters and steps for processing the ingredients by the processor to obtain the cooled edible product after their extraction from the pod.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In order to understand the invention and to see how it may be carried out in practice, embodiments will now be described, by way of non-limiting example only, with reference to the accompanying drawings, in which:

(2) FIG. 1 is a schematic cross-sectional view of a machine according to the subject matter of the present application;

(3) FIG. 2 is a schematic enlarged view of detail A shown in FIG. 1;

(4) FIG. 3 is a schematic cross-sectional view of a pod used in the machine shown in FIGS. 1 and 2;

(5) FIGS. 4 and 5 are schematic cross-sectional views of two variations of the pod shown in FIG. 3;

(6) FIG. 6 is a schematic cross-sectional view of a variation of the machine shown in FIG. 1, demonstrating insertion of a pod therein;

(7) FIG. 7 is a schematic cross-sectional view of another modification of the machine shown in FIG. 1;

(8) FIGS. 8 and 9 are schematic cross-sectional views showing a possible opening configuration of an outlet port of the machine shown in FIG. 1;

(9) FIGS. 10 and 11 are schematic cross-sectional views showing another example of a possible opening configuration of an outlet port of the machine shown in FIG. 1;

(10) FIGS. 12 and 13 are schematic cross-sectional illustrations of examples of orientation of a cooling chamber of the machine shown in FIG. 1;

(11) FIG. 14A is a schematic side view of a machine according to another example of the disclosed subject matter;

(12) FIG. 14B is a schematic isometric view of the machine shown in FIG. 14A;

(13) FIG. 15A is a schematic front view of a wet pod according to another example of the disclosed subject matter;

(14) FIG. 15B is a schematic front view of the wet pod shown in FIG. 15A, including hidden lines; and

(15) FIG. 16 is a schematic front view of a dry pod according to another example of the disclosed subject matter;

(16) FIG. 17 is a schematic diagram of a temperature regulating module according to the disclosed subject matter of the present application;

(17) FIG. 18A is a schematic isometric view of one example of the machine according to the subject matter of the present application;

(18) FIG. 18B is a schematic rear isometric view of the machine shown in FIG. 18A;

(19) FIG. 18C is a longitudinal schematic cross-sectional view of the machine shown in FIG. 18A;

(20) FIG. 18D is a schematic enlarged view of a portion of the cross-section shown in FIG. 18C;

(21) FIGS. 19A and 19B are schematic bottom isometric and cross-sectional views of a first example of a pod used in the machine shown in FIGS. 18A to 18D;

(22) FIGS. 20A and 20B are schematic bottom isometric and cross-sectional views of a second example of a pod used in the machine shown in FIGS. 18A to 18D;

(23) FIG. 21A is a schematic isometric view of another example of the machine according to the subject matter of the present application during a first position thereof, with a housing thereof being partially removed for illustration purposes;

(24) FIG. 21B is a longitudinal schematic cross-sectional view of the machine shown in FIG. 21A;

(25) FIG. 21C is a schematic isometric view of the machine shown in FIG. 21A during a second position thereof, with a housing thereof being partially removed for illustration purposes;

(26) FIG. 21D is a schematic enlarged view of a portion of the machine shown in FIG. 21C;

(27) FIG. 21E is a schematic isometric cross-sectional view of the machine shown in FIG. 21D; and

(28) FIG. 22 is a schematic isometric view of a pod used in the machine shown in FIGS. 21A to 21E.

DETAILED DESCRIPTION OF EMBODIMENTS

(29) Attention is first drawn to FIG. 1, in which a system for the domestic preparation of a cooled edible product (e.g. ice cream) is shown, generally designated as 1. The system 1 comprises a housing 10, a mixing module 20, and cooling module 30, both modules 20, 30 being contained within the housing 10. The system 1 further comprises a pod 40 (shown in FIG. 3) containing at least one ingredient of the cooled edible product, the pod 40 configured for being received within the housing 10.

(30) The housing 10 also comprises a cooling arrangement 12 configured for removing heat from the cooling module 30, and a drive motor 14 configured for driving ingredients of both the mixing module 20 and the cooling module 30. It is appreciated that individual motors can be provided for each of the mixing module, cooling module etc.

(31) The housing 10 further comprises a cover 17 located over an inlet 21 of the mixing module, a user fluid inlet 15 and a built-in fluid inlet 16, both inlets 15, 16 leading to the mixing module 20.

(32) With additional reference being made to FIG. 2, the mixing module 20 is formed with a cavity 22 configured for receiving therein a pod 40 (shown in FIG. 3) via the inlet 21. The mixing module 20 further comprises a valve 24 configured for selectively allowing/preventing fluid communication between the mixing module 20 and the cooling module 30.

(33) It is appreciated that the arrangement can be such that the pod 40 comprises the valve itself while the machine is formed with a corresponding engagement port configured for operating the valve.

(34) The mixing module 20 also comprises a mixing arrangement (not shown) powered by the drive unit 14 and configured for revolving the pod 40 about a central axis X.sub.1 thereof in order to allow mixing of the substance contained therein.

(35) The cooling module comprises a chamber 31 having a main cavity fitted with a dasher having a central shaft 32 and mixing elements 34. The shaft 32 and mixing elements 34 are configured for revolving about the axis X.sub.2 of the shaft in order to provide further mixing of the substance contained therein.

(36) The chamber 31 is cooled by the cooling arrangement 12 so that the substance contained within the cooling module 30 and coming in contact with the wall of the chamber 31 is reduced in temperature. In this connection, it is important to note that the mixing element 34 are also configured for scraping off portions of the mixture which stick to the inner wall of the chamber 31, as they freeze.

(37) The cooling module 30 also comprises an outlet port 36 configured for providing the cooled edible product to the user of the system 1.

(38) The operation of the cooling arrangement 12 and the drive motor 14 is configured for being controlled by a controller 18. The controller can be further configured for receiving data signals from a transmit-unit 19 associated with the mixing module 20, and issuing corresponding commands to the cooling arrangement 12 and the drive motor 14.

(39) Turning now to FIG. 3, a basic design of a pod 40 is shown, comprising a body 42 with a central cavity 41, an outlet port 44 and inner side winglets 46 and top winglet 48, configured for mixing the ingredients contained within the pod 40.

(40) In addition, the pod 40 comprises a data unit 49 which is configured for providing the system 1 with data regarding preparation parameters of the cooled edible product. The parameters in the data unit 49 are specific for the edible substance contained within the pod 40 and its state (solid, slurry, fluid etc.).

(41) The data unit 49 is configured for communication with the transmit-unit 19 of the housing 10 in order to provide it with the necessary parameters which can then be transmitted to the controller 18.

(42) Reference is now made to FIG. 5, in which the outlet port 44 can be formed with a thread 45 configured for secure attachment of the pod 40 to the mixing module 20, which is, in turn, formed with a corresponding threaded portion.

(43) With particular reference to FIG. 5, the pod 40 illustrates a “wet-pod”, i.e. a pod comprising an edible substance which is mixed with fluid, so that at least the majority (if not all) of the ingredients required for the preparation of the edible product are already contained within the pod 40. In this case, the pod can be inserted into the mixing module 20 and no additional fluid may be required for producing the cooled edible product.

(44) Alternatively, with reference to FIG. 4, the pod 40′ can be a “dry-pod”, only containing some of the edible ingredients for the preparation of the edible product. In this case, the user can be provided with an additional member 50, configured for providing the “dry-pod” 40′ with the required fluids for the preparation of the edible product. In particular, the user can fill the additional member 50 with a desired fluid of his/her choice and then attach the additional member 50 to the dry-pod 40′, thereby forming a pod assembly similar to that of the pod 40.

(45) The dry-pod 40′ and the portion 50 can be configured for engagement with one another via a thread 47′, 55, but it is appreciated that various means of connection therebetween can be provided, not limited to threading. In case of the dry-pod 40′, the pod 40′ resembles a capsule (similar to that which can be found in coffee machines).

(46) With reference to FIGS. 6 and 7, another embodiment of the machine is shown in which the dry-pod 40′ is configured for insertion into the machine (without an additional member 50), similar to a pod for a coffee machine. In this case, the required fluids are provided directly into the mixing chamber 20 of the machine to be mixed with the substance of the dry-pod 40′.

(47) In particular, FIGS. 6 and 7 demonstrate two configurations of insertion of the pod 40′ into the machine, one from the side (FIG. 6) and one from the top (FIG. 7).

(48) In both the wet-pod 40 and the dry-pod 40′, the arrangement is such that the pod 40, 40′ is configured for constituting a part of the mixing cavity 22.

(49) In addition, regardless of which pod is used, fluid can be provided to the mixing cavity 22 either manually by the user via opening 15 or via a built-in inlet 16 which can be connected to the domestic water supply, bottle-port, etc.

(50) In operation, the pod 40, 40′ is first inserted into the mixing chamber 20. Once inserted, the data unit 49 provides the transmit unit 19 with the necessary preparation parameters which are then transmitted to the controller 18.

(51) The processing parameters can be either one of a variety of parameters, for example: mixing time of the at least one ingredient; quantity of an additional ingredient; introduction time of an additional ingredient; aeration time of a mixture of the at least one ingredient; amount of gas introduced into a mixture of the at least one ingredient during its aeration time; cooling time of an aerated mixture of the at least one ingredient; temperature reduction of an aerated mixture of the at least one ingredient; diameter of an outlet through which said edible product is provided; and provision rate of said edible product through an outlet.

(52) Once the process parameters are acquired by the controller 18, preparation of the cooled edible product can commence.

(53) The controller 18 first determines whether or not an additional fluid is required, and in the positive, either alerts the operator of the machine to add the fluid via the inlet 15 or automatically provides it via the inlet 16.

(54) Once all the ingredients are contained within the mixing chamber 20, the drive unit 14, controlled by the controller 18, begins its operation and the edible ingredients are mixed together to form a mix. The mixing time, mixing rate etc. are all determined by the process parameters previously provided to the controller 18.

(55) Once the ingredients are properly mixed within the mixing module 20, the controller 18 operates the valve 24 in order to allow the mix to flow into the mixing chamber 31 of the cooling arrangement 30.

(56) The mix is then aerated and cooled to the necessary temperature (also determined based on the process parameters) and once it reaches a desired temperature/pressure/texture etc., the cooled edible product can be delivered to the user via the opening 36.

(57) It is appreciated that for different types of ice cream, different process parameters are required in order to properly accentuate the flavors of that particular ice cream type, including texture, temperature sensation on the tongue and palate, stability of the ice cream before melting etc.

(58) Several examples are provided below: when making chocolate ice cream having a high sugar/dextrose level, it may be desired that the ingredients are cooled for a longer duration of time; The same may hold true for the preparation of a sorbet with an alcoholic substance; and when making a nut ice cream with a high fat percent, it may be desired to reduce the revolution speed of the dasher.

(59) In addition: A “wet-pod” will normally require a shorter/slower mixing process, then a “dry-pod” which content is mixed with additional materials. A product based on a mix calculated for a low freezing point, may require a longer cooling process and or a higher level of temperature reduction. A product based on a high level of solids, and planned for a low level of over-run, may require slower turning of the dasher and or a longer process.

(60) With reference being made to FIGS. 8 to 11, the opening 36 can be of various configurations, for example, in the case of FIGS. 8 and 9 to tilt about a pivot point and in case of FIGS. 10 and 11, to slide up and down.

(61) It is noted that the cooling module 30 comprises a mixing arrangement (shaft 32 and elements 34) which is configured so as to propel the product towards the opening 36. So long as the opening is closed, pressure is applied to the edible product and, when a desired pressure is reached (also determined by the process parameters), the controller can signal the outlet 36 to open.

(62) With reference to FIGS. 12 and 13, provision of the cooled edible product to the user can be made either solely by pressure applied on the product by the mixing shaft 32 and elements 34. In particular, the shaft 32 and elements 34 can be configured for propelling the edible product towards the opening as indicated by arrow 37. In addition, in case the chamber 31 is slightly tilted (FIG. 13) to use gravitational forces to let the product come out.

(63) It may be desired to clean the system 1 and/or rinse it between the preparation of different types of cooled edible products. For this purpose, there can be provided a cleaning pod (not shown) having a shape similar to that of the pod 40, 40′, and containing a cleaning agent which is configured to flow through the system 1 (similar to the edible ingredients and product) when the pod is connected to the machine.

(64) Turning now to FIGS. 14A and 14B, another design of a system for the preparation of a cooled edible product is shown, generally designated as 101, and comprising, similar to the previously described system 1, a main housing 110 accommodating therein a mixing chamber 120, a cooling chamber 130, a drive motor 115, a reader 118 and a controller 116.

(65) The housing 110 is provided with a dispenser opening 136 configured for providing the cooled edible product (once prepared), a base 138 configured for positioning thereon a receptacle for receiving therein the cooled edible product dispensed from the opening 136 and a handle 111 for operating the system 101.

(66) In operation, a receptacle portion 144 of a pod 140 (see FIGS. 15A, 15B) is provided through a top opening 113 of the housing into the mixing chamber 120 and positioned so as to be aligned with the position of the reader 118. The reader 118 is then configured for obtaining from the pod the required process parameters for the preparation of the cooled edible product, and provide the same to the controller 116.

(67) Once all the required information is obtained by the controller 116, the latter can regulate operation of the mixing chamber 120, cooling chamber 130 and drive motor 115 for producing the edible product.

(68) When the edible product is ready, the operator of the machine can be prompted by the system 101 (either by a visual or auditory aid) to operate the handle 111 of the system 101 in order to open the dispensing opening and allow the cooled edible product to be dispensed therefrom into a designated receptacle (not shown) placed on the base 138.

(69) As appreciated from above, since the entire information regarding process parameters is provided by the pod itself, the entire system 101 can include a single handle (and possibly an on/off button) required for operating it, making the system 101 extremely simple and user friendly.

(70) Turning now to FIGS. 15A and 15B, a ‘wet pod’ is shown generally being designated as 140, and comprising a receptacle portion 144 and a cap 142. The receptacle portion 144 is formed with a cavity 141 configured for containing therein ingredients for the production of the cooled edible products and a mixing port 146 configured for operating in conjunction with the mixing chamber 120. The cap 142 is formed with a cavity configured for accommodating, almost fully, the receptacle portion 144.

(71) It is appreciated that the term ‘wet pod’ refers to a receptacle which does not necessarily require the addition of a fluid to its contained ingredients in order to produce the cooled edible product. In other words, the wet pod can contain therein all the required ingredients for producing the cooled edible product, without requiring any additional ingredients.

(72) In operation, the cap 142 of the pod can be removed before its insertion into the housing 110, and be placed on the base 138 to be used as the receptacle configured for receiving therein the cooled edible product. It is also appreciated that while the volume of the cap 142 is smaller than that of the receptacle portion 144, it is still appropriately sized for receiving therein the cooled edible product, similar to an ice cream cup/cone which normally accommodates a greater amount of ice cream than its volume.

(73) With reference to FIG. 16, another design of a ‘dry pod’ is shown, generally designated as 140, which is configured, contrary to the ‘wet pod’, for containing therein only some of the ingredients for the preparation of the cooled edible products, and required the addition of a fluid and/or further ingredients. On the other hand, the use of a ‘dry pod’ allows reducing the overall volume of the pod.

(74) Attention is now turned to FIGS. 18A to 18D, in which another example of the machine is shown, generally being designated as 200. As in previous examples, the machine 200 includes a housing 210 accommodating therein a mixing chamber 220 configured for receiving therein a pod 240, 240′ containing at least some ingredients for the preparation of the chilled edible product, a cooling chamber 230 for cooling the edible product/ingredients and a compressor 214.

(75) The machine 200 is further provided with a dispensing opening 236 configured for dispensing of the chilled edible product to a user of the machine and a receptacle tray 238 for positioning thereon a receptacle for the chilled edible product. Control over dispensing is performed using a utility handle 211 articulated to the dispensing opening.

(76) With particular reference to FIG. 18C, the mixing chamber 220 has a cavity 222 configured for receiving therein the pod 240 and is fitted with data reader 219 configured for receiving data from a data source 249 of the pod 240 and transmit the data to the control unit 218.

(77) Reference is now made to FIG. 18D in which a cross-section of the machine 200 is shown. It is observed that the mixing chamber 220 comprises at the bottom end thereof a piercing element 228 configured for puncturing a closure of the pod 240 when received within the mixing chamber 220 (see also FIGS. 19A to 20B), to allow extraction of the ingredients from the pod into the cooling chamber 230 after mixing takes place in the mixing chamber 220. For this purpose, the piercing element 228 is of a tapering shape ending with a tip sharp enough to pierce the closure.

(78) The piercing element 228 is mounted on a rotor plate 224 configured for revolving the pod 240 and/or mixing the ingredients therein. It is also noted that the piercing element 228 is designed to be wide enough to assist in the mixing of the ingredients contained within the pod 240 during the mixing stage. Mixing is further facilitated by winglets 246 formed within the receptacle 240.

(79) The passageway between the mixing chamber 220 and the cooling chamber 230 is provided with a valve 229 configured for regulating passage of mixed ingredients between the chambers 220, 230. The valve 229 is also associated with the controller 218 and the operation of which is regulated thereby.

(80) As in previous examples, the cooling chamber 230 comprises a mixing motor and a mixing element 234, and is slightly inclined towards the outlet nozzle 236 so as to utilize gravitational forces in dispensing of the cooled edible product. In addition, the cooling chamber 230 is provided with a valve 239 configured for regulating dispensing of the cooled edible product therefrom. In particular, the valve can be configured for preventing emission of the cooled edible product from the cooling chamber 230 before it is fully ready.

(81) Turning now to FIGS. 19A and 19B, an integral pod 240 is shown being in the form of a receptacle 242 defining therein a cavity for containing the required ingredients for producing the cooled edible product.

(82) The receptacle 242 is formed with a threaded attachment port 245 and has an opening sealed by a foil closure 244. When the pod 240 is received within the mixing chamber 220 of the machine 200 (see FIG. 18D), the piercing element 228 is configured for puncturing the foil, allowing the ingredients to be received within the mixing chamber 220.

(83) It is appreciated that the mixing of the ingredients within the mixing chamber 220 actually takes place within the pod 240, as the pod is sized and shaped to be precisely received within the mixing chamber 220. It is noted here that the mixing chamber 220 is only configured, in the example, for operating in conjunction with a genuine pod 240 of the machine.

(84) The pod 240 has fitted thereto and/or integrally formed therewith a data label 249 configured for communicating with the data reader 219 of the machine 200, for providing the controller 218 with the required information for producing the cooled edible products.

(85) With attention being turned now to FIGS. 20A and 20B, a pod assembly 240′ is shown comprising a first receptacle 242′ and a second receptacle 252′, being configured for attachment to one another. The receptacle 242′ is essentially similar to the receptacle 242 with the difference being in the size (it is smaller) and in the amount and/or type of ingredients contained therein.

(86) However, as opposed to the previously described pod 240, the receptacle 242′ has a top foil closure 248′ and an auxiliary attachment port 247′ configured for attachment with a corresponding port 255 of the receptacle 252.

(87) The receptacle 252 is an open receptacle and is configured for containing therein any desired liquid medium by choice of the user, which can be mixed with the ingredients of the receptacle 242′ (e.g. juices, water etc.). The receptacle 252 is also formed with a piercing member 259 configured for puncturing the foil closure 248′ of the receptacle 242′ when the receptacles 242′, 252 are properly attached to one another.

(88) In assembly, the receptacle 252 can be an open end receptacle which can be filled with the desired liquid of choice and then the receptacle 242′ can be mounted on the receptacle 252.

(89) When attached, the receptacles 242′, 252 form together a pod assembly which is very similar in shape and size to the original pod 240 and may thus function in the same way within the machine 200 and the mixing chamber 220, while providing the user with a greater variety of options and flavors.

(90) Attention is now drawn to FIGS. 21A to 21E in which another example of the machine is shown, generally being designated as 200″. As in the previous example, the machine 200″ includes a housing 210″ accommodating therein a mixing chamber 220″ configured for receiving therein a capsule 240″ (see FIG. 22) containing at least some ingredients for the preparation of the chilled edible product, a cooling chamber 230″ for cooling the edible product/ingredients and a compressor 214″.

(91) However, as opposed to the previously described example, the machine 200″ is configured for receiving therein a capsule 240″ containing mostly ‘dry’ ingredients (solids, powders etc.) and the mixing chamber 220″ is provided with a cover 217″ configured for sealing the chamber 220″ and a fluid inlet 215″ leading thereto through the cover 217″.

(92) With particular attention being drawn to FIG. 21B, the capsule 240″ is smaller than the mixing chamber and does not fill the entire cavity thereof (like the previously described pods 240, 240′). Instead, fluid is configured for being passed through the cover 217″ and into the capsule, so that a mix of the external fluid and ingredients from the capsule 240″ are provided into the mixing chamber 220″ where they are then mixed.

(93) In order to provide better diffusion and mixing of the external fluid with the ingredients within the pod, the cover 217″ is provided with multiple fluid outlets leading into the capsule 240″. The outlets are also designed to puncture a top foil closure of the capsule 240″ once placed within the mixing chamber 220″ and the cover 217″ is properly closed.

(94) Once the mix of external fluid and ingredients are provided into the mixing chamber 220″, mixing takes place there and from then on the manufacture process is very similar to the previously described process of producing the cooled edible product. However, it is appreciated that during mixing, some of the ingredients may remain within the capsule and be mixed there as well, though, not as efficiently as within the mixing chamber.

(95) Attention is now drawn to FIG. 22, in which a capsule 240″ is shown comprising a housing 242″, a top foil closure 244″, a bottom closure 243″ (seen in FIG. 21B) and a data label 249″. The capsule 240″ is considerably smaller than the pods 240, 240′ previously descried and is similar, in general, to coffee capsules. The capsule 240″ is configured for being placed within the mixing chamber 220″ so that the bottom foil closure 243″ thereof is punctured by the piercing element 228 while the top foil cover thereof 244″ is configured for being punctured by the outlets formed in the cover 217″ when it is properly closed. Turning now to FIG. 17, a domestic water supply piping P is shown comprising a faucet F and a hot and cold regulation handles H and C respectively. According to the disclosed subject matter there is provided a water temperature regulation module 300 being in fluid communication with the piping P.

(96) The module 300 comprises an inlet for receiving fluid from the main piping P, an heating/cooling unit (not shown) and a plurality of ports 310 configured for outputting the received fluid at a desired temperature.

(97) The module 300 is configured for allowing a plurality of different kitchen appliances (e.g. coffee machine, cooler, the systems 1, 101 of the present application) to connect to the ports 310 and receiving from the module the fluid at a desired temperature.

(98) At present, each of these kitchen appliances is provided with its own heating/cooling module and/or heating body etc. Employing the use of the temperature regulating module 300 allows eliminating the need for a corresponding module in each of the kitchen appliances. This may allow reducing the size and shape of each of these appliances.

(99) The module 300 can also be provided with a controller (not shown) configured for regulating the temperature of the incoming fluid and controlling provision of the heated/cooled fluid to the relevant port.

(100) It should be understood that the controller can also be configured for being in communication with each of the connected kitchen appliances, so that the user is not required to operate the module 300, but rather only the desired appliance.

(101) Those skilled in the art to which this invention pertains will readily appreciate that numerous changes, variations, and modification can be made without departing from the scope of the invention, mutatis mutandis.