Beverage dispensing with cold carbonation

Information

  • Patent Grant
  • 6626005
  • Patent Number
    6,626,005
  • Date Filed
    Thursday, November 21, 2002
    22 years ago
  • Date Issued
    Tuesday, September 30, 2003
    21 years ago
Abstract
Methods and apparatus for cold carbonation are provided in which a carbonator (13) having one or more segments is provided within a relatively horizontal cold plate (12). A sensor (14) is provided that can be accessed from a side of a dispenser (10).
Description




TECHNICAL FIELD OF THE INVENTION




This invention relates generally to beverage dispensing, and in particular to methods and apparatus for beverage dispensing with cold carbonation.




BACKGROUND OF THE INVENTION




In “post-mix” beverage dispensing, beverage syrups are mixed with plain or carbonated water to form finished beverages. With respect to carbonated beverages, issues surrounding carbonation significantly affect the quality of the finished beverage.




For high quality beverages, for example, it is important that the specified carbonation level be consistently produced, regardless of system variations, such as ambient temperature. As another example, it is important that, in the dispensing of the finished product, foaming be minimized.




Efficient and cost-effective production of such high quality beverages is, of course, desirable. It has been discovered that lowering the temperature of water to be carbonated increases carbonation efficiency, and can allow for lower CO


2


pressures. Accordingly, prior art efforts have been made to increase carbonation efficiency by using colder water. For example, U.S. Pat. No. 4,754,609 discloses pre-cooling water before carbonation. As further examples, U.S. Pat. Nos. 5,319,947, 5,419,461, and 5,524,452 disclose chilled carbonators. However, significant improvements can be made to the efficiency, cost, and space utilization (among other aspects) of the prior art.




Therefore, a need has arisen for an improved beverage dispenser and methods that make use of cold carbonation.




SUMMARY OF THE INVENTION




In accordance with the teachings of the present invention, methods and apparatus for beverage dispensing with cold carbonation are provided that substantially eliminate or reduce problems associated with prior art systems.




A dispenser is provided that includes a cold source (such as a cold plate or an ice/water bath) and a carbonator that comprises one or more conjoined segments located substantially within the cold source. The conjoined segments may form a continuous or discontinuous hollow structure.




In a particular embodiment, a carbonator is provided that includes a toroidal tank, a water inlet, a carbon dioxide inlet, and a sensor for measuring water level within the tank. The tank may form a continuous or discontinuous structure.




Furthermore, a dispenser is provided that has a first side, and includes a cold plate, a carbonator at least partially within the cold plate, and a sensor coupled to the carbonator, the sensor being accessible from the first side of the dispenser. In a particular embodiment, the first side is the front side of the dispenser at which beverages are dispensed.




Also provided is a dispenser having a horizontal plane, the dispenser including a cold plate, and a carbonator at least partially within the cold plate, the carbonator being tilted with respect to the horizontal plane.




Also provided is a carbonator that includes a first tank section, a second tank section, and a third tank section. The first and third sections are coupled with the second section, the third section extending outward from said second section.




In particular embodiments, a dispenser includes a substantially flat carbonator tank and a substantially horizontal cold plate, with the carbonator tank located substantially within the cold plate. Also, the dispenser may include a plurality of water inlets into the carbonator tank. Also, the dispenser may include a probe assembly substantially parallel to the carbonator tank.




Methods of carbonating water are also provided, including a method of carbonating water that comprises providing a carbonator tank within a cold plate, injecting carbon dioxide into the tank, chilling water, injecting the chilled water into the tank, and chilling soda received from the tank.




With each of the embodiments, a pre-carbonation chilling circuit may be coupled to the carbonator. Similarly, a post-carbonation chilling circuit may be coupled to the carbonator.




An important technical advantage of the present invention is that it greatly improves carbonation efficiency by including a carbonator integrally formed with a cold plate.




Another important technical advantage of the present invention is the use of carbonation tank segments or toroid shapes to achieve geometries that provide efficient carbonation in small shapes.




Another important technical advantage of the present invention is the use of integral pre-carbonation cooling circuits and/or post carbonation cooling circuits.




Another important technical advantage of the present invention is the use of multiple water inlets to a cold carbonator. Still another important technical advantage of the present invention is its easy access to sensors for measuring water level in the carbonator.











BRIEF DESCRIPTION OF THE DRAWINGS




Reference is made in description to the following briefly described drawings, wherein like reference numerals refer to corresponding elements:





FIG. 1

is an illustration of a dispenser with cold carbonation according to the teachings of the present invention;





FIG. 2

is a side view of the dispenser shown in

FIG. 1

;





FIG. 3

is a schematic conceptual diagram of one embodiment of a cold plate with an integral carbonator according to the teachings of the present invention;





FIG. 4

illustrates one embodiment of a carbonator according to the teachings of the present invention;





FIG. 5

illustrates a top view of one embodiment of a carbonator and pre- and post-carbonation chilling circuits according to the teachings of the present invention;





FIG. 6

illustrates a side view of one embodiment of a carbonator and carbonator probes according to the teachings of the present invention;





FIG. 7

illustrates a detail of the embodiment shown in

FIG. 6

;





FIG. 8

illustrates another embodiment of a carbonator according to the teachings of the present invention;





FIG. 9

illustrates still another embodiment of a carbonator according to the teachings of the present invention;





FIG. 10

illustrates another embodiment of a carbonator according to the teachings of the present invention; and





FIG. 11

illustrates one embodiment of cold carbonation in a mechanically cooled dispenser according to the teachings of the present invention.











DETAILED DESCRIPTION OF THE INVENTION





FIG. 1

illustrates a beverage dispenser


10


according to the teachings of the present invention. The particular dispenser


10


shown in

FIG. 1

is adapted to be placed on the top of a counter and dispenses both beverages and ice. However, it should be understood that the present invention is not limited to this particular embodiment, and applies to all dispensers, including those that have areas underneath the counter, and whether or not they also dispense ice.




Included within dispenser


10


is a cold plate


12


, a carbonator tank


13


within the cold plate


12


, and carbonator probe assembly


14


. The carbonator probe assembly


14


is used for measuring water levels within the carbonator


13


, and is easily accessible through the front of dispenser


10


. The cold plate


12


and probe assembly


14


may also be configured for access through the rear or sides of dispenser


10


. Configuration of the probe assembly


14


for horizontal access is a significant improvement of the present invention over prior art systems, as it facilitates easy access for maintenance and repair.




Importantly, the carbonator tank


13


of one embodiment of the present invention is located within the cold plate


12


, and is generally substantially horizontal in its orientation. This provides significant advantages. In particular, the carbonator probe assembly can be easily accessed, as discussed above. Also, the carbonation occurs at a low temperature, thus increasing carbonation efficiency and allowing for lower (and thus easier to work with) CO


2


pressures. With carbonation occurring in the cold plate, instead of without cooling, the carbonation level is substantially constant as ambient temperatures change, thus eliminating the need to change carbonation pressures in different seasons. Also, because carbonation occurs in the dispenser, installation and manufacturing are made easier as there is no separate carbonator. Similarly, asset tracking is made easier, and asset loss is reduced, as there is no separate carbonator to keep up with.




Furthermore, the relatively horizontally-oriented carbonator of one embodiment of the present invention, located substantially within the cold plate, provides significant advantages in that space is used very efficiently, in contrast to certain prior art attempts, where carbonators are located adjacent to or extend substantially from a relatively horizontal cold plate.




To achieve appropriate carbonation capacity, and to accommodate the other elements of the cold plate (cooling circuits for syrups and plain water), the geometry of the carbonator of the present invention is designed as one or more continuous or discontinuous tank segments. These segments allow room for the other cooling circuits. And, because of the relatively high surface area to volume ratio (thus efficient heat transfer) that results from using segments, very efficient carbonation is achieved.




Dispenser


10


also includes nozzles


16


through which finished products are dispensed. These nozzles mix either non-carbonated water (plain water) or carbonated water (soda) with beverage syrups and/or syrup flavors from valves


18


to produce finished beverages. The particular embodiment illustrates multiflavor nozzles


16


each coupled to a plurality of valves


18


; however, single flavor setups are within the present scope. Ice chute


20


is also provided for dispensing ice. Drip tray


22


is positioned below the nozzles. In operation, finished products are dispensed into cups placed between the nozzles


16


and the drip tray


22


.




The present invention also includes an integral pump


24


for pumping water to the carbonator tank


13


. Also illustrated is motor


26


, used to drive a mechanism for moving ice from the interior of the dispenser


10


to the ice chute


20


, as will be discussed below in connection with FIG.


2


.




It should be understood that, in a final dispenser, one or more cover plates are included to cover, from the user's view, items such as the valves


18


, the pump


24


, and the motor


26


. However, such cover plates are easily removed (such as with a few screws), to facilitate easy maintenance. As shown, most of the elements of the dispenser


10


are located at the front of the dispenser, thus allowing for easy access and improved maintenance.




Removal of the drip tray


22


reveals the front of the cold plate


12


, allowing easy access to the carbonator probe assembly


14


. Also illustrated is CO


2


relief valve


28


and cold plate inlets


30


and outlets


32


. Inlets


30


receive water and syrup to be chilled through the cold plate


12


, and also water to be carbonated in the carbonator tank


13


. The outlets


32


transmit chilled syrups and water (both plain and carbonated water) to the valves


18


. The cold plate


12


is cooled with ice that can be manually dropped into ice bin


33


of the dispenser


10


, or, alternatively, an icemaker can be placed atop or adjacent to the dispenser


10


to produce ice and convey it into the ice bin


33


. As another alternative, a remote icemaker can be used to generate ice which can then be conveyed automatically, such as through a pneumatic tube, to the ice bin


33


.





FIG. 2

shows a side cut away view of the dispenser


10


shown in FIG.


1


. As shown in

FIG. 2

, the cold plate


12


includes integral carbonator


13


. The carbonator probes of carbonator assembly


14


extend through the cold plate


12


and into the carbonator


13


.




As shown in

FIG. 2

, the dispenser


10


includes insulation


31


surrounding the central ice bin


33


of the dispenser. The motor


26


drives a paddle wheel


35


used to convey ice from the ice bin to the ice dispenser chute


20


. The paddle wheel conceptually shown in

FIG. 2

is illustrative only, and other mechanisms may also be used. As discussed above, it should be understood that the cold plate of the present invention does not have to be used in connection with a dispenser that also dispenses ice.




In operation, ice cools the cold plate


12


, which is formed from a conductive material, such as aluminum. Water and syrup are thus cooled as they flow through their respective water and syrup circuits within the cold plate


12


. Importantly, the carbonator


13


, and the water within the carbonator


13


, are cooled in this same way, thus allowing for higher carbonation efficiency. With this higher carbonation efficiency, lower CO


2


pressures can be used, resulting in a more reliable, less expensive dispenser.




As shown in

FIG. 2

, cold plate


12


is tilted with respect to a horizontal plane of the dispenser


10


. This tilting allows for the sensor of probe assembly


14


to more easily read changes in the water level, because, for some geometries, the more nearly horizontal the carbonator tank


30


and cold plate


12


are, the smaller the change in the water level is when soda is discharged from the carbonator tank


30


. However, no such tilting is necessary. When, in this description, the carbonator


13


of the present invention is referred to as substantially, or relatively, horizontal, it includes orientations with some tilting. Also, the tilting can be accomplished by tilting the cold plate in which the carbonator tank is cast, or by tilting the carbonator within an otherwise horizontal cold plate. Although any tilting angle can be used, preferably a tilting angle of less than about 20 degrees with respective horizontal plane is used.





FIG. 3

illustrates a top view schematic of a cold plate


12


with integral carbonator


13


according to the teachings of the present invention. As shown in

FIG. 3

, carbonator tank


13


includes four conjoined segments


34


,


36


,


38


, and


40


. The cross section of any of these segments is preferably a circle, however any shape may be used. Similarly, the quadrilateral shape of carbonator tank


13


is exemplary only. Any shape can used that will provide the carbonation capacity required for the particular application. The particular geometric shape of the carbonator tank can be changed as desired to create the desired ratio of water to CO


2


headspace in the carbonator, and to accommodate the amount of space needed in the cold plate for plain water and syrup cooling circuits.




Although the particular carbonator


13


shown in

FIG. 3

includes segments that are continuously connected, such continuous shapes are not required, and as will be discussed below in connection with other embodiments, one or more continuous or discontinuous segments can be used.





FIG. 3

also illustrates pre-chill circuit


42


. Pre-chill circuit


42


allows plain water to be chilled before entering carbonator tank


13


. In a preferred embodiment, the pre-chilled water is injected through a plurality of orifice blocks into the carbonator tank


13


. However, only one injection point may also be used. Soda is conveyed from the carbonator tank


13


through one or more ports to a post-carbonation chilling circuit


44


. This post-carbonation chilling circuit


44


, like the pre-chill circuit


42


, is preferably integrally formed within the cold plate


12


. The post-chilled soda is then conveyed to a manifold


46


for transmission to the valves


18


.




In a preferred embodiment, the pre-chill circuit


42


chills the plain water to approximately 40 degrees Fahrenheit. The post-chill circuit


44


chills the soda to a temperature in the range of preferably 34-40 degrees Fahrenheit. In addition to chilling the soda, the post-chill circuit


44


stabilizes the flow from the carbonator


13


into a less turbulent flow. Thus, more CO


2


remains in stream because of this more laminar flow, resulting in less foaming at dispense and higher carbonation (and therefore higher quality in the finished beverage product). However, it should be understood that either or both of the chilling circuits


42


and


44


may or may not be included as part of the present invention.





FIG. 4

illustrates details of the carbonator tank


13


for the particular embodiment discussed in connection with FIG.


3


. As shown in

FIG. 4

, CO


2


is supplied to the carbonator through fitting


50


. Connected to fitting


50


is safety relief valve


28


. The CO


2


is injected into the carbonator tank


13


at connection


52


. Although only one connection


52


is shown, a plurality of injection points may be used. Soda is conveyed from the carbonator tank


13


through outlet fittings


54


, which transmit the soda to the post cooling circuit


44


shown in FIG.


3


.





FIG. 5

illustrates the embodiment shown in

FIGS. 3 and 4

, with examples of pre- and post-chill circuits


42


and


44


. As shown in

FIG. 5

, in a particular embodiment, two post-chill circuits


44


begin at the outlet connection points


54


and convey soda to the soda manifold


46


. In the particular embodiment shown, two separate circuits


44


are shown, one beginning from each connection point


54


. However, it should be understood that only one, or more than two, circuits may be used without departing from the intended scope of the present invention. Also shown in

FIG. 5

are two pre-carbonation chilling circuits


42


. These pre-carbonation chilling circuits


42


begin at a T-connection


56


that splits a single stream of plain water into two streams for the two separate chilling circuits


42


. It should be understood, however, that only one, or more than two, circuits may be used without departing from the intended scope of the present invention. As discussed earlier, the pre-carbonation chilling circuits


42


cool the plain water before injection into the carbonator tank


13


. The pre-chilled plain water is injected into the carbonator tank


13


at orifice blocks


58


. In a particular embodiment shown, two orifice blocks


58


are used for generating two streams of water into the carbonator tank


13


. The use of two streams improves efficiency over the use of a single stream by causing more turbulence within the carbonator tank. However, it should be understood that only one stream, or more than two streams, may be used without the departing from the intended scope of the present invention.





FIGS. 6 and 7

show a side view of the carbonator tank


13


being discussed in connection with

FIGS. 3-5

. As shown in

FIGS. 6 and 7

, the plain water streams enter through orifice blocks


58


parallel to the segment


38


of the carbonator tank


13


. However, it should be understood that other entry angles may be used without departing from the intended scope of the present invention. As is seen in

FIGS. 6 and 7

, the carbonator probe assembly


14


is an assembly that comprises two particular probes


60


and


62


. These probes measure the water level within the carbonator


13


and are used to control the pump


24


that pumps plain water into the pre-chill circuits


42


and into the carbonator tank


13


. In particular, when both probes


60


and


62


are under water (as designated by the high water level mark in

FIGS. 6 and 7

) the signals from the probes will be used to turn the pump


24


off. Similarly, if probes


60


and


62


are both uncovered, as shown by the low water level, then the pump


24


will be turned on to inject more plain water into the carbonator tank


13


. Although probe assembly


14


, with probes


60


and


62


, is illustrated, any kind of sensor for measuring water levels may be used, including, without limitation, those that reside outside of the carbonator tank and measure the levels indirectly (such as, without limitation, ultrasound-based sensors).




The following descriptions of

FIGS. 8

,


9


, and


10


illustrate that the present invention is not limited to any particular geometric shape or layout. In particular, continuous geometric shapes, such as toroids, or those formed with conjoined segments, may be used. Similarly, individual or conjoined segments that are not continuous may also be used. Also, embodiments with vertically displaced segments or sections can also be used.




The particular carbonator embodiments discussed to this point are substantially flat embodiments. However, the present invention may also be used with carbonator geometries that have segments that are vertically (with respect to the dispenser) displaced. Thus, as seen in

FIG. 8

, a particular carbonator


70


is illustrated that includes segments


72


,


74


, and


76


. Segments


72


and segments


76


are joined through vertical segment


74


. The water level can be measured in segment


74


(as well as in segments


72


and


76


) with carbonator probes that are either parallel, perpendicular, or at some other angle to the segment


74


. Plain water is preferably injected into segment


72


or


74


of the carbonator


70


, but can also be injected into segment


76


. Soda is receive out of the segment


76


and then sent to one or more post-chill circuits as discussed in connection with previous FIGUREs. Similarly, water injected into the carbonator


70


can be sent through one or more pre-chill circuits as discussed in connection with the previous embodiments. Also, the carbonator shown in

FIG. 8

is preferably cast into a cold plate.





FIG. 9

illustrates a carbonator


80


that is in the shape of a toroid, cast into a cold plate


82


. As discussed above in connection with the other embodiments, plain water is injected into the carbonator tank


80


through one or more inlet ports after being chilled through a pre-chill circuit


84


. Similarly, soda is taken out of the carbonator tank


80


through a post-carbonation chill circuit


86


. Although a toroid shape is shown in

FIG. 9

, other shapes can also be used, such as, without limitation, a single segment with an irregular shape (for example, like a snake), a single segment with a varying radius (for example a spiral or ovoid), and need not form a continuous hollow structure (for example, a “C” shape or spiral). For convenience, all such single segment shapes are referred to herein as toroids.





FIG. 10

illustrates a discontinuous carbonator tank


90


according to the teachings of the present invention. As shown in

FIG. 10

, carbonator tank


90


comprises a plurality of segments, some of which are joined but do not continuously join others. For example, segments


92


and


94


do not join together at their ends, but are stubs. Plain water is injected into carbonator tank


90


through inlet ports after being chilled through a pre-chill circuit


96


. Also, soda is taken out of the carbonator tank


90


through a post-chill circuit


98


. The carbonator tank


90


, and pre-chill circuit


96


and post-chill circuit


98


are preferably integrally formed within cold plate


100


.





FIG. 11

illustrates the dispenser


110


according to another embodiment of the present invention. Generally speaking, the teachings above apply to dispenser


110


, except that rather than cooling with ice and a cold plate, dispenser


110


is cooled with a mechanical cooling unit, such as a vapor compression refrigeration unit


112


. Refrigeration unit


112


generates an ice/water bath to cool the carbonator tank assembly


120


. In the particular embodiment shown, the carbonator tank assembly


120


is similar to that shown above in connection with

FIG. 5

, and includes carbonator tank


130


. Also shown in

FIG. 11

are circuits


132


,


134


, and


136


. These circuits are used for cooling syrup, or plain water for non-carbonated beverages. These circuits reside in the chilled water bath created by refrigeration unit


112


. Although not illustrated in connection with previous embodiments, such syrup and plain water circuits are also used and cast in the cold plates discussed above in connection with the cold plate embodiments.




Although not shown, an electronic control system is also provided for controlling operation of the various embodiments dispensers discussed herein. The control system includes a microprocessor or micro-controller, and various input/output ports to effect the control. The control system interfaces with the carbonator probe assembly to determine, based on the carbonator water level, when to turn on and off the water pump that supplies the carbonator. Also, the control system interfaces with a customer interface for turning on valves to produce the desired beverage, and for dispensing ice, if included.




In this description, certain geometric shapes have been described in detail. However, it should be understood that these are illustrative examples, and other shapes can be used. Also, features described in connection with particular embodiments can be interchanged with features in other examples.




Although the present invention has been described in detail, it should be understood that changes, alterations, substitutions, additions, and modifications can be made without departing from the intended scope of the invention, as defined in the following claims.



Claims
  • 1. A dispenser, comprising:a first carbonator tank section; a second carbonator tank section; and a third carbonator tank section, the first and third sections being coupled with the second section, the third section extending outward from the second section, the first, second, and third sections forming a common space for carbonating water.
  • 2. The dispenser of claim 1, and further comprising a cold plate formed substantially around the carbonator tank sections.
  • 3. The dispenser of claim 1, and further comprising a sensor for measuring water level within the second section.
  • 4. The dispenser of claim 1, and further comprising a pre-carbonation chilling circuit coupled to one of the carbonator tank sections.
  • 5. The dispenser of claim 1, and further comprising a post-carbonation chilling circuit coupled to one of the carbonator tank sections.
  • 6. The dispenser of claim 1, and further comprising a pre-carbonation chilling circuit coupled to one of the carbonator tanks sections and a post-carbonation chilling circuit coupled to one of the carbonator tank sections.
  • 7. A dispenser, comprising:a cold source; and a carbonator tank comprising a plurality of conjoined tank segments located substantially within the cold source and arranged in a non-linear configuration.
  • 8. The dispenser of claim 7, and further comprising a probe assembly coupled to at least one of the conjoined tank segments.
  • 9. The dispenser of claim 7, wherein the conjoined tank segments form a continuous structure.
  • 10. The dispenser of claim 7, wherein the conjoined tank segments form a discontinuous structure.
  • 11. The dispenser of claim 7, wherein the cold source comprises a cold plate.
  • 12. The dispenser of claim 7, wherein the cold source comprises an ice/water bath.
  • 13. The dispenser of claim 7, and further comprising a pre-carbonation chilling circuit coupled to the carbonator tank.
  • 14. The dispenser of claim 7, and further comprising a post-carbonation chilling circuit coupled to the carbonator tank.
  • 15. The dispenser of claim 7, and further comprising a pre-carbonation chilling circuit coupled to the carbonator tank and a post-carbonation chilling circuit coupled to the carbonator tank.
  • 16. A dispenser, comprising:a cold source; and a carbonator tank comprising at least a segment with a curved central axis and located substantially within the cold source.
  • 17. The dispenser of claim 16, and further comprising a pre-carbonation chilling circuit coiled to the carbonator tank.
  • 18. The dispenser of claim 16, and further comprising a post-carbonation chilling circuit coupled to the carbonator tank.
  • 19. The dispenser of claim 16, and further comprising a pre-carbonation chilling circuit coupled to the carbonator tank and a post-carbonation chilling circuit coupled to the carbonator tank.
  • 20. The dispenser of claim 16, wherein the tank is a continuous structure.
  • 21. The of claim 16, wherein the tank is a discontinuous structure.
  • 22. The dispenser of claim 16, wherein the cold source comprises a cold plate.
  • 23. The dispenser of claim 16, wherein the cold source comprises an ice/water bath.
  • 24. A dispenser, comprising:a first carbonator tank section; a second carbonator tank section; a third carbonator tank section, the first and third sections being coupled with the second section, the third section extending outward from the second section; and a sensor for measuring water level within the second section.
CONTINUING APPLICATION INFORMATION

This application is a continuation of U.S. patent application Ser. No. 09/961,668, filed Sep. 24, 2001, entitled Beverage Dispensing With Cold Carbonation, now U.S. Pat. No. 6,574,981.

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Continuations (1)
Number Date Country
Parent 09/961668 Sep 2001 US
Child 10/301479 US