This disclosure relates generally to a dispensing system and method for the dispensing of beverages, e.g., for cafeterias, restaurants (including fast food restaurants), theatres, convenience stores, gas stations, and other entertainment and/or food service venues.
Various beverage dispensers, such as those at cafeterias, restaurants, theatres, and other entertainment and/or food service venues, typically have either a “drop in” dispenser apparatus or a counter top type dispenser apparatus. In a drop in dispenser apparatus, the dispenser apparatus is self-contained and may be dropped into an aperture of a counter top. In a counter top type dispenser apparatus, the dispenser apparatus is placed on a counter top. In conventional beverage dispensers, a dispensing head is coupled to a particular drink syrup supply source via a single pipe dedicated to supply the particular drink syrup to that dispensing head, wherein the particular drink syrup supply source is typically located near the counter top, i.e., directly under the counter top, or directly over the counter top.
A user will typically place a cup under the signage of the selected beverage and either press a button or press the cup against a dispensing lever to activate the dispenser so that the selected beverage is delivered from the dispensing head corresponding to the selected beverage and into the cup until pressure is withdrawn from the button or lever.
Conventional dispensing machines may dispense a number of beverages. Each of dispensed beverages may consist of a number of components, such as flavors, acidulants, sweeteners, and diluents (e.g., water). In conventional dispensing machines, the required components of a beverage are dispensed via a common dispensing nozzle and each component is typically delivered to the dispensing nozzle via a separate delivery pipe, as shown e.g., in
Conventional beverage dispensers are typically limited to dispensing drinks having flavoring supply sources located at their respective counters. Thus, a limited number of drinks are typically available at a conventional beverage dispenser. For example, drinks typically available at a conventional beverage dispenser are a regular cola beverage, a diet cola beverage, perhaps one or several non-cola carbonated beverages, such as a lemon-lime flavored carbonated beverage or some other fruit-flavored drink (e.g., orange flavored carbonated beverage, and/or root beer), and perhaps one more non-carbonated beverage(s), such as a tea and/or a lemonade.
Conventional dispensers are not typically configured to permit a user generate or receive from a single dispensing head a custom-ordered beverage that a consumer may wish to purchase, e.g., a cola flavored with cherry, vanilla, lemon, or lime, etc., or a tea flavored with lemon, orange, peach, raspberry, etc., or a tea having one or more teaspoons of sweetener (sugar, or some other nutritive sweetener or non-nutritive sweetener).
Conventional dispensers typically require servicing and resupply of flavoring sources at the counter.
Conventional dispensers typically require a dedicated dispensing head for each particular beverage.
What is needed is a beverage dispensing system that does not have the limitations and disadvantages of conventional beverage dispensers and methods.
Accordingly, there is provided a system or apparatus comprising a common delivery pipe.
In an aspect, an apparatus is provided, the apparatus comprising a first source of a first component, the first component one component for a finished free flowing food product and comprising a highly concentrated micro component. The apparatus comprises a second source of a second component, the second component being another component for the finished free flowing food product. The apparatus comprises a flow combiner. The flow combiner is configured to receive the first component from the first source. The flow combiner is configured to receive the second component from the second source. The flow combiner is configured to combine the first component with the second component to form a first mixture. The apparatus comprises a common delivery pipe, the common delivery pipe configured to receive the first mixture from the flow combiner. The apparatus comprises a third source of a diluent flow. The apparatus comprises a dispenser, the dispenser comprising a dispensing nozzle, the dispenser configured to receive diluent flow from the third source, receive the first mixture from the common delivery pipe, combine the diluent flow with the first mixture to form a second mixture, and dispense the second mixture through the dispensing nozzle, the second mixture comprising the finished free flowing food product.
In one aspect, an apparatus comprising an auxiliary diluent flow source may be provided. The apparatus may comprise a first source of a first component, the first component being a first component for a free flowing food product and comprising a highly concentrated micro component. The apparatus may comprise a second source of a second component, the second component being a second component for the free flowing food product, the second component selected from the group consisting of a second highly concentrated micro component and a macro component. The apparatus may comprise a first flow combiner, the first flow combiner configured to receive the first component from the first source, receive auxiliary diluent from the auxiliary diluent flow source, and combine the first component with the auxiliary diluent flow to form a first intermediate mixture. The apparatus may comprise a second flow combiner, the flow combiner configured to receive the first intermediate mixture from the first flow combiner, receive the second component from the second source, and combine the first intermediate mixture with the second component to form a second intermediate mixture. The apparatus may comprise a common delivery pipe, the common delivery pipe configured to receive the second intermediate mixture from the second flow combiner. The apparatus may comprise a main diluent flow source. The apparatus may comprise a dispenser. The dispenser may be configured to receive main diluent flow from the main diluent flow source, receive the second intermediate mixture from the common delivery pipe, combine the main diluent flow with the first mixture to form a finished free flowing food product, and dispense the second finished free flowing food product through the dispenser.
In one aspect, a method is the provided. The method may comprise conveying a first component of a free flowing food product through a common delivery pipe to a dispenser for a first period of time. The method may comprise conveying a second component of a free flowing food product through a common delivery pipe to a dispenser for a second period of time. The method may comprise stopping the conveying of the first component. The method may comprise stopping the conveying of the second component. The method may comprise, upon stopping the conveying of the first component and the second component, conveying a diluent for a third period of time through the common delivery pipe to wash any of the remaining first component and any of the remaining second component away from the common delivery pipe.
The above and other aspects, features and advantages of the present disclosure will be apparent from the following detailed description of the illustrated embodiments thereof which are to be read in connection with the accompanying drawings.
The embodiments discussed below may be used to form a wide variety of beverages, including but not limited to cold and hot beverages, and including but not limited to beverages known under any PepsiCo branded name, such as Pepsi-Cola®.
Those of skill in the art will recognize that in accordance with the disclosure a transfer unit or dosing system and/or portions thereof that feed a dispenser with a free flowing product may be located remotely from a counter, such as in a back room, or at the counter, such as below or over the counter.
In an aspect, an apparatus is provided, the apparatus comprising a first source of a first component, the first component one component for a finished free flowing food product and comprising a highly concentrated micro component. The apparatus comprises a second source of a second component, the second component being another component for the finished free flowing food product. The apparatus comprises a flow combiner. The flow combiner is configured to receive the first component from the first source. The flow combiner is configured to receive the second component from the second source. The flow combiner is configured to combine the first component with the second component to form a first mixture. The apparatus comprises a common delivery pipe, the common delivery pipe configured to receive the first mixture from the flow combiner. The apparatus comprises a third source of a diluent flow. The apparatus comprises a dispenser, the dispenser comprising a dispensing nozzle, the dispenser configured to receive diluent flow from the third source, receive the first mixture from the common delivery pipe, combine the diluent flow with the first mixture to form a second mixture, and dispense the second mixture through the dispensing nozzle, the second mixture comprising the finished free flowing food product.
In accordance with various aspects of the disclosure, the first source may be a first cartridge and the second source may be a second cartridge. The second component may be selected from the group consisting of a second highly concentrated micro component and a macro component. The finished free-flowing food product may comprise a beverage. The apparatus may comprise a sweetener source, wherein the dispenser is configured to receive sweetener from the sweetener source and combine the sweetener, the first mixture, and the main diluent flow to form the finished free-flowing food product. The apparatus may further comprise a first micro dosing device configured to dose the first component to the flow combiner. The apparatus may comprise a second micro dosing device configured to dose the second component to the flow combiner.
In an aspect, the first source may comprise a highly concentrated micro component having a ratio by weight to a diluent of at least about 30:1. In an aspect, the first source may comprise a highly concentrated micro component having a ratio by weight to a diluent of at least about 1000:1.
In an aspect, the apparatus may further comprise an auxiliary diluent flow source configured to convey an auxiliary diluent flow to the flow combiner.
In an aspect, an apparatus is provided comprising a first source of a first component, the first component one component for a finished free flowing food product and comprising a highly concentrated micro component. The apparatus may comprise a second source of a second component, the second component being another component for the finished free flowing food product. The apparatus may comprise a third source of a main diluent flow. The apparatus may comprise a fourth source of an auxiliary diluent flow. The apparatus may comprise a first flow combiner. The first flow combiner configured to receive the first component from the first source. The first flow combiner may be configured to receive auxiliary diluent flow from the fourth source. The first flow combiner may be configured to combine the first component with the auxiliary diluent flow to form a first intermediate mixture. The apparatus may comprise a second flow combiner. The second flow combiner may be configured to receive the first intermediate mixture from the first flow combiner. The second flow combiner configured to receive the second component from the second source. The second flow combiner configured to combine the first intermediate mixture with the second component to form a second intermediate mixture. The apparatus may comprise a common delivery pipe. The common delivery pipe may be configured to receive the second intermediate mixture from the second flow combiner. The apparatus may comprise a dispenser, the dispenser comprising a dispensing nozzle. The dispenser may be configured to receive main diluent flow from the third source. The dispenser may be configured to receive the second intermediate mixture from the common delivery pipe. The dispenser may be configured to combine the main diluent flow with the second intermediate mixture to form a finished free flowing food product, and dispense the finished free flowing food product.
In an aspect, the apparatus may further comprise a fifth source of a diluent flow and a flow splitter configured to split the diluent flow from the fifth source into the third source and the fourth source. The flow splitter may be configured to split about 5-25% of the diluent flow from the fifth source into the fourth source, and about 95-75% of the diluent flow from the fifth source into the third source. In an aspect, flow from the fourth source provides a washing flow that washes away any of the first component and the second component from the common delivery pipe.
In an aspect, the apparatus may comprise a first component dosing device. The apparatus may comprise a first component valve. The first component valve may be configured to be in an open position when desired to convey the first component from the first component dosing device to the first flow combiner. The first component valve may be configured to be in a closed position when desired to not convey the first component from the first component dosing device to the first flow combiner. The apparatus may comprise a second component dosing device, and a second component valve. The second component valve may be configured to be in an open position when desired to convey the second component from the second component dosing device to the second flow combiner, the second component valve configured to be in a closed position when desired to not convey the second component from the second component dosing device to the second flow combiner. The apparatus may comprise an auxiliary diluent valve. The auxiliary diluent valve may be configured to be in an open position when desired to convey the auxiliary diluent flow from the fourth source to the first flow combiner. The auxiliary diluent valve may be configured to be in a closed position when desired to not convey the auxiliary diluent flow from the fourth source to the first flow combiner.
In an aspect, the apparatus may comprise a gas source configured to convey a gas to the first flow combiner when desired to purge any of the first component, the second component, the auxiliary diluent flow, and mixtures thereof from the common delivery pipe. The gas source may comprise a gas valve. The gas valve may be configured to be in an open position when desired to convey the gas from the gas source to the first flow combiner. The gas valve may be configured to be in a closed position when not desired to convey the gas from the gas source to the first flow combiner. In an aspect, the apparatus may further comprise a third flow combiner configured to receive the gas from the gas valve and convey the gas to the first flow combiner when the gas valve is in the open position.
In an aspect of the disclosure, a method is provided, the method comprising conveying a first component of a free flowing food product through a common delivery pipe to a dispenser for a first period of time. The method comprises conveying a second component of a free flowing food product through the common delivery pipe to a dispenser for a second period of time. The method comprises stopping the conveying of the first component. The method comprises stopping the conveying of the second component. The method comprises upon stopping the conveying of the first component and the second component, conveying a diluent for a third period of time through the common delivery pipe to wash any of the remaining first component and any of the second component away from the common delivery pipe.
In an aspect, the method may further comprise conveying a gas for a fourth period of time to purge any of the remaining diluent away from the common delivery pipe after the third period of time ends and the conveying of the diluent stops.
In an aspect of the disclosure, an apparatus is provided, the apparatus comprising a cartridge comprising a highly concentrated free flowing micro component having a ratio by weight of the highly concentrated free-flowing micro component to a diluent of at least about 30:1. In an aspect, the ratio by weight of the highly concentrated free-flowing micro component to a diluent of at least about 1000:1 may be provided. The apparatus may comprise a dosing device, the dosing device configured to intermittently dose a predetermined amount of the highly concentrated free-flowing micro component at a predetermined flow rate. The apparatus may comprise a controller, the controller configured to control the intermittent dosing by the dosing device.
In an aspect of the disclosure, a dispensing system is provided comprising a common delivery pipe. In one aspect, a dispensing system is provided that has a simplified design over conventional dispensing systems. The dispensing system disclosed herein may be configured to dispense a number of components, including but not limited to flavors, acidulants, sweeteners, and diluents (e.g., water).
In an aspect, a single common delivery pipe is provided. The common delivery pipe may be configured for delivering (in sequence) a number of components of a free flowing product. The free flowing product may be a food product, including for example, a beverage.
The system 100 may further comprise one or more other components 112, 114, and 114′. Components 112, 114 and 114′ may each comprise a micro component or a macro component that is distinct from each other and micro component 104. As shown in
As shown in
As previously noted, components 112, 114, and 114′ may each comprise a micro component or a macro component that is distinct from each other and micro component 104. Components 112, 114, and 114′ may each have corresponding devices similar to devices that correspond to micro component 104. Thus, components 112 and 114 may each have a dosing device that is similar to micro dosing device 106, a pump similar to micro component pump 116, and a valve similar to micro component valve 118. Components 112, 114 and 114′ may each have a corresponding source, such as a cartridge, similar to source 102.
The flow through common delivery pipe 108 may be combined with additional components at dispenser 110. For example, as shown in
A main diluent valve 140 may be provided, through which main diluent 132 may be provided to dispenser 110. Main diluent 132 may be pumped by main diluent pump 142, to provide a main diluent flow 144 to dispenser 110. Main diluent 132 may be any suitable diluent, including but not limited to water, carbonated water, or a base of a free flowing product, such as a base for food product, including a beverage.
Dispensing system 100 may comprise dosing control unit 1203. Dosing control unit 1203 may comprise controller 1202. Controller 1202 may be operatively connected to dosing device 106. In accordance with an aspect of the disclosure, controller 1202 may be configured to control dosing by dosing device 106 of a highly concentrated micro component 104. As shown in
As shown in
Controller 1202 may be configured to control intermittent dosing of one or more other components 112, 114, and 114′ in a similar manner as for micro component 104, e.g., controlling via two way communication (not shown) between controller 1202 and a micro dosing device, a micro component pump, and/or a micro component valve corresponding to each component 112, 114, and 114′.
Controller 1202 may be configured to control dosing of a sweetener 134, in a similar manner as for micro component 104, e.g., controlling via two way communication (not shown) between controller 1202 and a dosing device, a pump, and/or a component valve corresponding to the sweetener 134. In accordance with the disclosure, dosing of the sweetener may be intermittent or not intermittent. In accordance with the disclosure, a dosing device, a pump, and/or a component valve corresponding to the sweetener 134 may be a micro dosing device, a micro component pump, and/or a micro component valve corresponding to sweetener 134, respectively.
Controller 1202 may be configured to control operation of water pump 142 and main diluent valve 140 via two way communication between controller 1202 and water pump 142 and main diluent valve 140, respectively.
In a conventional system, components are delivered to a dispenser using individual pipes, rather than a common delivery pipe. Thus, a dispenser of a conventional system may need to have certain structure, such as a larger and more complex dispenser to account for the need to mix the micro components at the dispenser, unlike the dispenser 110 of system 100 of the present disclosure. Similarly, the dispensing nozzle in a conventional system may need to be larger and more complex than the dispensing nozzle 138 of the system 100 of the present disclosure. A conventional system may produce a product that may have different characteristic and not be the same as the finished free flowing product 136 produced by system 100 of the present disclosure.
As shown in
Diluent 132 may be pumped by pump 142 to diluent flow splitter 306. Portion 302 may exit diluent flow splitter 306 through pipe 308 to flow combiner 304. In flow combiner 304, auxiliary portion 302 of diluent 132 may be combined with component 104 to form a mixture 312. Mixture 312 may then be conveyed through pipe 120 and through additional apparatus, such as flow combiner 122, etc. as shown in
As shown in
To wash components 104, 112, 114, and/or 114′ from flow combiners 304, 122, 124, and pipes 120, 128 and 108, and dispenser 110 and dispensing nozzle 138, the auxiliary portion 302 may be used. For example, for washing, valves corresponding to each micro component 104, 112, 114, and 114′ may be closed, and only auxiliary portion 302 may be sent through flow combiners 304, 122, 124, and pipes 120, 128 and 108, and dispenser 110 and dispensing nozzle 138 for a sufficient time to accomplish the washing of micro components therefrom. By washing micro components from the above elements of system 300, cross-contamination between micro components may be reduced or eliminated.
Controller 1202, as previously described with respect to
Gas flow 402 may be used to purge components 104, 112, 114, and/or 114′ from flow combiners 304, 122, 124, and pipes 120, 128 and 108, and dispenser 110 and dispensing nozzle 138. For example, for purging, valves corresponding to each micro component 104, 112, 114, and 114′ may be closed, and only gas flow 402 may be sent through flow combiners 304, 122, 124, and pipes 120, 128 and 108, and dispenser 110 and dispensing nozzle 138 for a sufficient time to accomplish the purging of micro components therefrom. By purging micro components from the above elements of system 400, cross-contamination between micro components may be reduced or eliminated. Purging can be done using gas flow 402 after washing using auxiliary portion 302.
Gas flow 402 may be combined with portion 302 in flow combiner 406 to form a mixture 408. Mixture 408 may be conveyed through pipe 308 to flow combiner 304.
Gas flow 402 may be used to increase the amount of carbonation for a finished beverage 412. Thus, when desired, gas flow 402 may be combined with portion 302 to form mixture 408, and mixture 408 may be combined with components 104, 112, 114, and/or 114,′ and conveyed through common delivery pipe 108 to dispenser 110. At dispenser 110, the mixture from pipe 108 may be combined with main diluent flow 144, and sweetener 134 to form a finished beverage 412. Finished beverage 412 may thus have more carbonation than finished beverage 136 produced using the system depicted in
Controller 1202, as previously described with respect to
In a conventional approach, macro components and micro components are each dispensed during the same time period through their respective individual delivery pipes to a dispenser.
In one aspect, a dispensing system is provided, the dispensing system comprising a first source of a first highly concentrated micro component, and a source of a second highly concentrated micro component. The dispensing system may comprise a first micro dosing device in fluid communication with the first source, the first micro dosing device configured to receive the first highly concentrated micro component from the first source and dose a predetermined amount of the first highly concentrated micro component. The dispensing system may comprise a second micro dosing device in fluid communication with the second source, the second micro dosing device configured to receive the second highly concentrated micro component from the second source and dose a predetermined amount of the second highly concentrated micro component. The dispensing system may comprise a flow combiner, the flow combiner configured to combine flow of the first highly concentrated micro component dosed by the first micro dosing device and flow of the second highly concentrated micro component dosed by the second micro dosing device to form a combined flow of the first and second highly concentrated micro components. The combined flow of the first and second highly concentrated micro components may be conveyed by a common micro components delivery pipe to a dispenser. The dispenser may be configured to receive additional components and mix the additional components with the combined flow of the first and second highly concentrated micro components to form a finished free flowing product. The dispenser may comprise a dispensing nozzle. The dispensing nozzle may be configured to dispense the finished free flowing product.
In one aspect, a method is provided, the method comprising dosing a predetermined amount of a first highly concentrated micro component by a first micro dosing device, and dosing a predetermined amount of a second highly concentrated micro component by a second micro dosing device. The method may comprise combining the predetermined amount of the first highly concentrated micro component and the predetermined amount of the second highly concentrated micro component and form a combined flow of the first and second highly concentrated micro components. The method may comprise conveying the combined flow of the first and second highly concentrated micro components in a common micro component delivery pipe to a dispenser. The method may comprise receiving additional components and mixing the additional components with the combined flow of the first and second highly concentrated micro components to form a finished free flowing product. The method may comprise dispensing the finished free flowing product from the dispenser.
In accordance with the disclosure, the overall number of the delivery pipes may be significantly reduced and the design of the dispensing nozzle may be considerably simplified. In addition, in order to prevent possible cross-contamination problems that may be associated with a common delivery pipe, the disclosure provides for the use of auxiliary flows of the existing diluent(s) or water for washing the common delivery pipe between dispensing of different beverages. In addition, after washing, the common delivery pipe may be purged to remove any residues of the washing agent along with the residues of the previously delivered components.
Benefits of the present disclosure include simplified design of dispensing systems or machines, including systems or machines for the dispensing of multiple beverages. For example, in accordance with the present disclosure, a reduced number of delivery pipes are necessary, and dispensers and/or dispensing nozzles need not have structure necessary to accommodate multiple delivery pipes for micro and macro components as in conventional systems. In accordance with the present disclosure, dispensers and/or dispensing nozzles need not have structure necessary to accommodate mixing of micro and macro components as conventional systems.
Carbon dioxide, nitrogen (N2) or other gas may be used to apply pressure to source 102, such as a cartridge or bottle of source 102 to push a highly concentrated micro component out of source 102 and through pipe 608 to dosing injector 604. The carbon dioxide or other gas may be supplied from gas flow 602. Gas flow 602 may split into additional gas flows or lines (not shown) in order to provide gas to other containers for components other than component 104. Thus, additional gas streams may be used to provide pressure and push components 112, 114, and 114′ to corresponding dosing injector 612 and flow mixer 614, and dosing injector 616 and flow mixer 618, as shown in
Cartridge 702 may be one of a plurality of sources. Those of skill in the art will recognize that in accordance with the present disclosure a transfer unit, plurality of sources and/or portions thereof that feed a dispenser with a free flowing product may be located remotely from a counter, such as in a back room, or at the counter, such as below or over the counter.
Pipe 708 may be used to transport highly concentrated micro component 704 to a dosing ramp 760. Dosing ramp 760 may be a stand-alone dosing ramp. As shown in
As shown in
Valve 762 and valve 730 may have the same or similar structure as valve 714.
As shown in
As shown in
As shown in
Gas may be sent to cartridge or bottle 802a. If the micro component of cartridge 802a is to be used to make a free flowing product to be dispensed from dispenser 810, then the micro component of cartridge 802a is allowed to be dosed by the corresponding built-in dosing device of cartridge 802a, and the effluent from cartridge 802a comprises the dosed micro component of cartridge 802a and auxiliary diluent from auxiliary pipe 828. Effluent from cartridge 802a is fed through pipe 815 of effluent manifold 862 to cartridge 802b. If the micro component of cartridge 802a is not needed to make a free flowing food product (e.g., a beverage) to be dispensed from dispenser 810, then no micro component of cartridge 802a is allowed to be dosed by the corresponding built-in dosing device of cartridge 802a, and the only effluent from cartridge 802a is the auxiliary diluent from auxiliary pipe 828. The process may continue until each micro component to be used to make the free flowing product has been dosed. Effluent 832, which may be a micro component, or a combination of auxiliary diluent and micro component(s), is then sent from apparatus 801 through common delivery pipe 808 to dispenser 810.
Diluent 818 may be pumped by diluent pump 820 through pipe 822. After being pumped by diluent pump 820 through pipe 822, diluent 818 may enter a diluent flow splitter 824. At diluent flow splitter 824, diluent 818 may be split into a main diluent flow pipe 826, and an auxiliary diluent flow pipe 828. In one embodiment, about 75-95% of the diluent 818 from pipe 822 goes to main diluent flow pipe 826, and about 5-25% of the diluent 818 goes to the auxiliary diluent flow pipe 828. Diluent 818 flowing through auxiliary diluent flow pipe 828 may flow through auxiliary diluent valve 830, and then flow to gas/diluent flow switcher 850. The effluent from gas/diluent flow switcher 850 may flow to built-in dosing device (not shown) of cartridge 802a, where it may be mixed with highly concentrated micro component of cartridge 802a.
As shown in
Built-in dosing devices, e.g., built-in dosing devices 814c, 814f, and 814i, of the cartridges shown in
Those skilled in the art will recognize that in accordance with the disclosure built-in dosing devices may comprise injectors and/or valves, for example, injector and/or valve 714 shown in
Those skilled in the art will recognize that in accordance with the disclosure while the cartridges shown in
As shown in
Pressure from the gas may compress bag 905, thereby forcing highly concentrated micro component 904 from bag 905 through valve 914 and line 915 to built-in dosing device 962. Built-in dosing device 962 may be configured to open or close due to direct current from direct current line 901.
Diluent from diluent line 928 may be mixed with highly concentrated micro component 904 in built-in dosing device 962 to form diluted micro component 932. Diluted micro component 932 may be sent from cartridge 902 through delivery pipe 908 to a dispenser 810. Delivery pipe 908 may correspond to delivery pipe 808 previously discussed in connection with
Cartridge 902 may correspond to any of the cartridges described above, including but not limited to the cartridges of
Those of skill in the art will recognize that, in accordance with the disclosure, cartridge 902 may have any suitable built-in micro dosing device appropriate for the micro component to be supplied from cartridge 902. Cartridges having different micro components may have different micro dosing devices. For example, injectors or electro-hydrodynamic (EHD) pumps may be deemed useful for micro dosing of a micro component, such as a flavor, having a ratio by weight of micro component to diluent in the range of about 150:1 to 200:1. A positive displacement (PD) pumps may be deemed useful for micro dosing of a micro component, such as a juice concentrate, or a sweetener, etc., having a ratio by weight of micro component to diluent in the range of about 100:1 to 150:1.
In an aspect of the disclosure, after the third period of time ends and the conveying of the diluent stops, the method may further comprise conveying a gas for a fourth period of time to purge any of remaining diluent away from the common delivery pipe.
Those of skill in the art will recognize that, in accordance with the disclosure, a controller, such as controller 1202 previously discussed, may be configured to control the operation of any of the apparatus and devices described above.
Dosing control unit 1203 may further include or be in communication with a system bus (not shown). A system bus may be any of several types of bus structures including a memory bus or memory controller, a peripheral bus, and a local bus using any of a variety of bus architectures. The structure of system non-transitory memory is well known to those skilled in the art and may include a basic input/output system (BIOS) stored in a read only memory (ROM) and one or more program modules such as operating systems, application programs and program data stored in random access memory (RAM). Dosing control unit 1203 may be configured to allow dosing control unit 1203 to communicate other devices in system 1200, for example, micro-component pump 1208, micro dosing device 1204, micro-component valve 1210, water pump 1212, and/or main diluent valve 1214. Dosing control unit 1203 may also include a variety of interface units and drives (not shown) for reading and writing data.
Those of skill in the art will recognize that, in accordance with the disclosure, any suitable network connections and other ways of establishing a communications link between dosing control unit 1203 and other devices in system 100 of
Those of skill in the art will recognize that, in accordance with the disclosure, dosing control unit 1203 may include an associated computer-readable medium containing instructions for controlling any of previously described systems 100, 300, 400, and 600, and implement the exemplary embodiments that are disclosed herein.
Dosing control unit 1203 may also include various input devices 1610. Input devices 1610 may include keyboards, track balls, readers, mice, joy sticks, buttons, and bill and coin validators.
Those of skill in the art will recognize that in accordance with the disclosure any of the features and/or options in one embodiment or example can be combined with any of the features and/or options of another embodiment or example.
The disclosure herein has been described and illustrated with reference to the embodiments of the figures, but it should be understood that the features of the disclosure are susceptible to modification, alteration, changes or substitution without departing significantly from the spirit of the disclosure. For example, the dimensions, number, size and shape of the various components may be altered to fit specific applications. Accordingly, the specific embodiments illustrated and described herein are for illustrative purposes only and the disclosure is not limited except by the following claims and their equivalents.
The present application is a U.S. National Phase of International Application No. PCT/US2013/057042, filed on Aug. 28, 2013, designating the United States of America and claiming priority to U.S. Provisional Application No. 61/695,143, filed Aug. 30, 2012, entitled “Dispensing System with a Common Delivery Pipe,” the entire disclosures of which are hereby incorporated by reference in their entireties and for all purposes.
Filing Document | Filing Date | Country | Kind |
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PCT/US2013/057042 | 8/28/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2014/036117 | 3/6/2014 | WO | A |
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