The present invention relates generally to beverage dispensing equipment, and in particular to specialized nozzles used in beverage dispensing equipment to provide for additive flavors, coloring and the like.
Fountain beverage dispensing equipment is well known in the art and includes various types of machines for dispensing liquid drinks and for making and dispensing slush ice drinks as well. Typically, drinks are dispensed from one or more dedicated valves, each structured to dispense only a single flavor. In order to save space and cost, it is known to have multiple flavor valves that have the capacity to dispense a plurality of flavors from the same nozzle, but such valves dispense only one flavor at a time.
Various carbonated drinks, particularly cola drinks, have long been available, especially in bottled form with various flavorings such as cherry, vanilla and lemon added to the basic syrup formulation of the drinks. While additive flavors can be included in the syrup formulations as supplied to the drink retailer, such an approach increases the number of dedicated valves that are required. Thus, for example, in addition to a basic cola flavor and its diet counterpart, there would need to be separate valves for cherry and vanilla versions of each, and so on. This number can be increased further if caffeinated and non-caffeinated versions of the beverages are desired. The problem becomes particularly acute for slush ice or so-called frozen carbonated beverage “FCB” dispensing equipment, which typically can only serve two or four flavors per machine and where the cost per flavor is considerably higher than with liquid beverage dispensing equipment.
Accordingly, it would be desirable to have a mechanism for optionally adding a flavor or flavors to a base drink in such manner that the number of valves, and hence the complexity and cost of the beverage dispensing equipment, can be reduced.
In accordance with the present invention, a device for injecting additive fluids into a stream of a primary fluid comprises a body having a central bore for flow therethrough of the stream of primary fluid, and a plurality of separate fluid flow channels extending through the body. Each fluid flow channel has an inlet for connection to an associated supply of additive fluid and a plurality of outlet orifices opening into the central bore for emission from the outlet orifices of additive fluid from the associated supply and for direction of the emitted additive fluid into the stream of primary fluid flowing through the central bore.
In accordance with another aspect of the apparatus of the invention, a beverage dispenser comprises a beverage dispensing valve having a nozzle for dispensing a stream of a beverage from the nozzle; and a device for injecting additive fluid flavorings into the stream of beverage. The device comprises a body having a central bore for flow therethrough of the stream of beverage dispensed from the nozzle and a plurality of separate fluid flow channels extending through the body. Each fluid flow channel has an inlet for connection to an associated supply of additive fluid flavoring and a plurality of outlet orifices opening into the central bore for emission from the outlet orifices of additive fluid flavoring from the associated supply of additive fluid flavoring and for direction of the emitted additive fluid flavoring into the stream of beverage flowing through the central bore.
The invention also contemplates a method of injecting additive fluids into a stream of a primary fluid. The method comprises the steps of providing a body having a central bore; forming a plurality of separate fluid flow channels extending through the body, such that each fluid flow channel has at one end an inlet and at an opposite end a plurality of outlet orifices opening into the central bore; and fluid coupling the inlet to each channel to an associated supply of additive fluid. Also included are the steps of flowing the stream of primary fluid through the central bore; in response to performance of the flowing step, delivering additive fluid from a selected supply thereof to the inlet to the associated channel for flow of the additive fluid through the channel and emission from the outlet orifices from the channel; and directing the additive fluid emitted from the outlet orifices into the stream of primary fluid flowing through the central bore.
In accordance with another aspect of the method of the invention, additive fluid flavorings are injected into a stream of a beverage dispensed from a nozzle of a beverage dispensing valve of a beverage dispenser. In this aspect of the invention, the method comprises the steps of providing a body having a central bore; forming a plurality of separate fluid flow channels extending through the body, such that each fluid flow channel has at one end an inlet and at an opposite end a plurality of outlet orifices opening into the central bore; and fluid coupling the inlet to each channel to an associated supply of additive fluid flavoring. Also included are the steps of operating the beverage dispensing valve to flow a stream of the beverage through the central bore; in response to performance of the operating step, delivering additive fluid flavoring from a selected supply thereof to the inlet to the associated channel for flow of the additive fluid flavoring through the channel and emission from the outlet orifices from the channel; and directing the additive fluid flavoring emitted from the outlet orifices into the stream of beverage flowing through the central bore.
A better understanding of the structure, operation and function of the present invention and the various objects and advantages thereof can be had by reference to the following detailed description which refers to the following figures wherein:
The multi-flavor injection device of the invention will be described for use in connection with a slush ice beverage dispensing machine. As is understood, a slush ice dispensing valve, generally indicated at 1 in
With reference also to
Referring also to
Layer II is thicker than layer I as it includes fluidly separate channel portions formed into both top and bottom surfaces thereof as well as a central nozzle receiving and product flow passage portion 15a that extends vertically therethrough and, along with the passage portion 15, forms a portion of flavor injection channel or passage 8 of flavor injection device 7. A top surface 16 of layer II includes a first flavor flow channel “half” B that is complementary in shape and corresponds to and is a mirror image of flavor channel A formed in bottom surface 14 of layer I, so that when layers I and II are brought or sandwiched together channels A and B register with each other. First flavor flow portion B thus includes a corresponding inlet portion B1, a partial circumferential portion B2 and four outlet channels B3 extending vertically through layer II. A bottom surface 18 of layer II includes a partial second flavor flow channel C formed therein. Channel C includes an inlet portion C1, a partial circumferential channel portion C2 and four outlet channels C3.
A corresponding bottom second flavor flow channel “half” D of second flavor flow channel portion C is formed in a top surface 20 of layer III and includes an inlet portion D1, a partial circumferential channel portion D2 and four outlet channels D3. Second flavor flow channel portion D also includes a vertical first flavor inlet channel D4 extending through layer III. A third flavor flow channel portion E is formed into a bottom surface 22 of layer III. Channel portion E includes an inlet portion E1, a partial circumferential channel portion E2 and four outlet channels E3. Layer III also includes a central nozzle receiving and product flow passage portion 15b that extends vertically therethrough and, along with the passage portions 15 and 15a, forms a portion of flavor injection channel or passage 8 for receiving dispenser nozzle 6.
In a similar manner, a corresponding third flavor flow channel half F of flavor flow channel E is formed in a top surface 24 of layer IV and includes an inlet portion F1, a partial circumferential channel portion F2 and four outlet channels F3. Third flavor flow channel portion F also includes a vertical inlet channel F4 extending through layer IV. A fourth flavor flow channel portion G is formed into a bottom surface 26 of layer IV and also includes an inlet portion G1, a partial circumferential channel portion G2 and four outlet channels G3. Layer IV also includes additive fluid channel extensions of the various vertical outlets as well as a passage portion 15c of passage 8.
In a similar manner as described above, a corresponding channel “half” H of flavor channel G is formed in a top surface 28 of layer V and includes an inlet portion HI, a partial circumferential channel portion H2 and four outlet channels H3. Layer V further includes additive flavor outlet channels (not shown) formed in a bottom surface 30 thereof and each such outlet channel includes a vertical channel extending through layer V and including the channel extensions of the other outlets. Layer V further includes a passage portion 15d of passage 8.
A top surface 32 of layer VI includes complementary corresponding “halves” of outlet channels OC that cooperate with those of layer V. Layer VI also includes a central passage portion 15e that together with the corresponding passage portions 15 and 15a–15d in layers I–V create the central nozzle receiving and flow channel 8. Together, channel halves OC of layers V and VI create sixteen additive flavor channels terminating at the sixteen flavor injection orifices or outlets lying in a common plane in and extending around a level perimeter on the inner surface of cylindrical channel portion 8b of passage 8.
A bottom surface 34 of Layer VI also includes a first flavor inlet connector bore 36, a second flavor inlet bore 38, a third flavor inlet bore 40 and fourth flavor inlet bore 42. Layer VII includes four bores therethrough that comprise extensions of bores 36, 3840 and 42 and are indicated like numerals. Layer VIII includes four further bores therethrough also comprising extensions of bores 36, 3840 and 42 and also indicated by like numerals.
It is contemplated that adhesive be used to secure layers I–VIII together, so that all of the various channel portions fit together and form fluidly separate flow channels, although other suitable means may be used. It is important that these layers be sandwiched together in a manner that they register one on top of the other accurately, and to ensure accurate registration when the layers are sandwiched together registration holes 50 extend through each layer for receiving a pair of vertical registration pins. The registration pins may be firmly anchored in an assembly block and are used to provide for accurate assembly of the layers. After the layers have been glued together any excess material and glue are removed to produce the injector 7.
When the layers I–VIII are adhered together to form injection device 7, four fluidly separate flavor injection channels are formed and exist within the injection device. The first flavor injection channel is formed by the combination of channel portions A and B, the second flavor injection channel by the combination of channel portions C and D, the third by the combination of channel portions E and F and the fourth by the combination of channel portions G and H. Bores 36, 38, 40 and 42 receive respective inlet hose connectors 60 for each of four additive flavors that provide for connection of the bores to pressurized sources of additive flavors (not shown).
An exemplary view of the path traveled through injection device 7 by the various flavors 1–4 can be had by referring to
Referring again to
It is understood that while the injection device 7 of the present invention has been described for use with a slush beverage dispensing machine, that particular environment is intended to be merely illustrative of one of many potential applications for the invention. The injected additive flavor need not be a syrup, but could conceivably be any of a variety of liquids whether potable or not. In fact, the added substance could be a gas as well as a liquid. The present invention also is not limited to injection of just four additives to a fluid stream, but could be used to inject any desired number of additives. Further, more than one such injection device could be used, stacked one on top of the other in order to increase the number of additive fluids that can be injected into a common stream. The invention can also be used to simultaneously inject more than one additive at a time or, if desired, be used in a manner to stagger the injection of multiple different additives during dispensing of a primary fluid. The injection device could also be used such that additive fluid is injected into a primary fluid as it passes, for example, through a pipe, since it is not necessary that the primary fluid be dispensed from the injection device itself.
While embodiments of the invention have been described in detail, various modification and other embodiments thereof may be devised by one skilled in the art without departing from the spirit and scope of the invention, as defined in the appended claims.
This application claims benefit of provisional application Ser. No. 60/506,391, filed Sep. 27, 2003.
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Number | Date | Country | |
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20050067433 A1 | Mar 2005 | US |
Number | Date | Country | |
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60506391 | Sep 2003 | US |