The present application relates generally to a beverage dispenser and more particularly relates to a juice dispenser or any other type of beverage dispenser that may be capable of dispensing a number of beverage alternatives on demand from a number of micro-ingredients and other types of ingredients.
Commonly owned U.S. Pat. No. 4,753,370 concerns a “Tri-Mix Sugar Based Dispensing System,” This patent describes a beverage dispensing system that separates the highly concentrated flavoring from the sweetener and the diluent. This separation allows for the creation of numerous beverage options using several flavor modules and one universal sweetener. One of the objectives described therein is to allow a beverage dispenser to provide as many beverages as may be available on the market in prepackaged bottles or cans. U.S. Pat. No. 4,753,370 is incorporated herein by reference in full.
These separation techniques, however, generally have not been applied to juice dispensers and the like. Rather, juice dispensers typically have a one (1) to one (1) correspondence between the juice concentrate stored in the dispenser and the products dispensed therefrom. As such, consumers generally can only choose from a relatively small number of products given the necessity for a significant amount of storage space for the concentrate. A conventional juice dispenser thus requires a large footprint in order to offer a wide range of different products.
Another issue with known juice dispensers is that the last mouthful of juice in the cup may not be mixed properly such that a large “slug” of undiluted concentrate may remain. This problem may be caused by insufficient agitation of the viscous juice concentrate. The result often may be an unpleasant taste and an unsatisfactory beverage.
Thus, there is a desire for an improved beverage dispenser that may accommodate a wide range of different beverages. Preferably, the beverage dispenser may offer a wide range of juice-based products or other types of beverages within a footprint of a reasonable size. Further, the beverages offered by the beverage dispenser should be properly mixed throughout.
The present application and the resultant patent thus provide a beverage dispenser. The beverage dispenser may include a number of micro-ingredients, a water stream, and a rotary chamber. The rotary chamber may include a first element in communication with the micro-ingredients and the water stream and a second element maneuverable to a dispense position and a sealed position.
The present application and the resultant patent further provide a method of operating a beverage dispenser with micro-ingredients therein. The method may include the steps of rotating a rotating element of a rotary combination chamber to a dispense position, flowing a first number of micro-ingredients through the rotary combination chamber, rotating the rotating element to a wash position, flowing a flow of water through the rotary combination chamber, rotating the rotating element to the dispense position, and dispensing a second number of micro-ingredients through the rotary combination chamber.
The present application and the resultant patent further provide a beverage dispenser. The beverage dispenser may include a number of micro-ingredients, a rotary chamber with a fixed element in communication with the plurality of micro-ingredients and a rotating element, and a number of dispensing nozzles in communication with the rotating element of the rotary chamber.
These and other features and improvements of the present application and the resultant patent will become apparent to one of ordinary skill in the art upon review of the following detailed description when taken in conjunction with the several drawings and the appended claims.
Referring now to the drawings, in which like numerals refer to like elements throughout the several views,
The dispenser 100 may use any number of different ingredients. By way of example, the dispenser 100 may use plain water 120 (still water or noncarbonated water) from a water source 130; carbonated water 140 from a carbonator 150 in communication with the water source 130 (the carbonator 150 and other elements may be positioned within a chiller 160); a number of macro-ingredients 170 from a number of macro-ingredient sources 180; and a number of micro-ingredients 190 from a number of micro-ingredient sources 200. Many other types of ingredients and combinations thereof also may be used herein.
Generally described, the macro-ingredients 170 have reconstitution ratios in the range from full strength (no dilution) to about six (6) to one (1) (but generally less than about ten (10) to one (1)). The macro-ingredients 170 may include juice concentrates, sugar syrup, HFCS (“High Fructose Corn Syrup”), concentrated extracts, purees, or similar types of ingredients. Other ingredients may include dairy products, soy, rice concentrates. Similarly, a macro-ingredient based product may include the sweetener as well as flavorings, acids, and other common components. The juice concentrates and dairy products generally may require refrigeration. The sugar, or other macro-ingredient base products generally may be stored in a conventional bag-in-box container remote from the dispenser 100. The viscosities of the macro-ingredients may range from about one (1) to about 10,000 centipoise and generally over 100 centipoise.
The micro-ingredients 190 may have reconstitution ratios ranging from about ten (10) to one (1) and higher. Specifically, many micro-ingredients 190 may have reconstitution ratios in the range of 50:1 to 300:1 or higher. The viscosities of the micro-ingredients 190 typically may range from about one (1) to about six (6) centipoise or so, but may vary from this range. Examples of micro-ingredients 190 include natural or artificial flavors; flavor additives; natural or artificial colors; artificial sweeteners (high potency or otherwise); additives for controlling tartness, e.g., citric acid or potassium citrate; functional additives such as vitamins, minerals, herbal extracts, nutricuticals; and over the counter (or otherwise) medicines such as pseudoephedrine, acetaminophen; and similar types of materials. Various types of alcohols may be used as either micro or macro-ingredients. The micro-ingredients 190 may be in liquid, gaseous, or powder form (and/or combinations thereof including soluble and suspended ingredients in a variety of media, including water, organic solvents and oils). The micro-ingredients 190 may or may not require refrigeration and may be positioned within the dispenser 100 accordingly. Non-beverage substances such as paints, dies, oils, cosmetics, etc. also may be used and dispensed in a similar manner.
The water 120, the carbonated water 140, the macro-ingredients 170 (including the HFCS), and the micro-ingredients 190 may be pumped from their various sources 130, 150, 180, 200 to a mixing module 210 and a nozzle 220 as will be described in more detail below. Each of the ingredients generally must be provided to the mixing module 210 in the correct ratios and/or amounts.
The dispenser 100 also may include a clean-in-place system 222. The clean-in-place system 192 cleans and sanitizes the components of the dispenser 100 on a scheduled basis and/or as desired. By way of example, the clean-in-place system 222 may communicate with the dispenser 100 as a whole via two locations: a clean-in-place connector 224 and a clean-in-place cap (not shown). The clean-in-place connector 224 may tie into the dispenser 100 near the macro-ingredient sources 180. The clean-in-place connector 224 may function as a three-way valve or a similar type of connection means. The clean-in-place cap may be attached to the nozzle 220 when desired. The clean-in-place cap may circulate a cleaning fluid through the nozzle 220 and the dispenser 100. Other types of cleaning techniques may be used herein.
When dispensing, the water 120 may be delivered from the water source 130 to the mixing nozzle 210 via a water metering system 230 while the carbonated water 140 is delivered from the carbonator 150 to the nozzle 220 via a carbonated water metering system 240. As is shown in
The water then flows to the water metering system 230. The water metering system 230 includes a flow meter 270 and a proportional control valve 280. The flow meter 270 provides feedback to the proportional control valve 280 and also may detect a no flow condition. The flow meter 270 may be a paddle wheel device, a turbine device, a gear meter, or any type of conventional metering device. The flow meter 270 may be accurate to within about 2.5 percent or so. A flow rate of about 88.5 milliliters per second may be used although any other flow rates may be used herein. The pressure drop across the chiller 160, the flow meter 270, and the proportional control valve 280 should be relatively low so as to maintain the desired flow rate.
The proportional control valve 280 ensures that the correct ratio of the water 120 to the carbonated water 140 is provided to the mixing module 210 and the nozzle 220 and/or to ensure that the correct flow rate is provided to the mixing module 210 and the nozzle 220. The proportional control valve may operate via pulse width modulation, a variable orifice, or other conventional types of control means. The proportional control valve 280 should be positioned physically close to the mixing nozzle 210 so as to maintain an accurate ratio.
Likewise, the carbonator 150 may be connected to a gas cylinder 290. The gas cylinder 290 generally includes pressurized carbon dioxide or similar gases. The water 120 within the chiller 160 may be pumped to the carbonator 150 by a water pump 300. The water pump 300 may be of conventional design and may include a vane pump and similar types of designs. The water 120 is carbonated by conventional means to become the carbonated water 140. The water 120 may be chilled prior to entry into the carbonator 150 for optimum carbonization.
The carbonated water 140 then may pass into the carbonated water metering system 240 via a carbonated waterline 310. A valve 315 on the carbonated line 310 may turn the flow of carbonated water on and off. The carbonated water metering system 240 may also include a flow meter 320 and a proportional control valve 330. The carbonated water flow meter 320 may be similar to the plain water flow meter 270 described above. Likewise, the respective proportional control valves 280, 330 may be similar. The proportional control valve 280 and the flow meter 270 may be integrated in a single unit. Likewise, the proportional control valve 330 and the flow meter 320 may be integrated in a single unit. The proportional control valve 330 also should be located as closely as possible to the nozzle 220. This positioning may minimize the amount of carbonated water in the carbonated waterline 310 and likewise limit the opportunity for carbonation breakout. Bubbles created because of carbonation loss may displace the water in the line 310 and force the water into the nozzle 220 so as to promote dripping.
One of the macro-ingredients 170 described above includes High Fructose Corn Syrup (“HFCS”) 340. The HFCS 340 may be delivered to the mixing module 210 from an HFCS source 350. As is shown in
The HFCS 340 then may pass through a HFCS metering system 380. The HFCS metering system 380 may include a flow meter 400 and a proportional control valve 410. The flow meter 400 may be a conventional flow meter as described above or as that described in commonly owned U.S. Pat. No. 7,584,657, entitled “FLOW SENSOR” and incorporated herein by reference. The flow meter 400 and the proportional control valve 410 ensure that the HFCS 340 is delivered to the mixing module 210 at about the desired flow rate and also to detect no flow conditions and the like.
Although
The macro-ingredient pump 450 may be a progressive cavity pump, a flexible impeller pump, a peristaltic pump, other types of positive displacement pumps, or similar types of devices. The macro-ingredient pump 450 may be able to pump a range of macro-ingredients 170 at a flow rate of about one (1) to about sixty (60) milliliters per second or so with an accuracy of about 2.5 percent. The flow rate may vary from about five percent (5%) to one hundred percent (100%) flow rate. Other flow rates may be used herein. The macro-ingredient pump 450 may be calibrated for the characteristics of a particular type of macro-ingredient 170. The fittings 430, 440 also may be dedicated to a particular type of macro-ingredient 170.
A flow sensor 470 may be in communication with the pump 450. The flow sensor 470 may be similar to those described above. The flow sensor 470 ensures the correct flow rate therethrough and detects no flow conditions. A macro-ingredient line 480 may connect the pump 450 and the flow sensor 470 with the mixing module 210. As described above, the system can be operated in a “closed loop” manner in which case the flow sensor 470 measures the macro-ingredient flow rate and provide feedback to the pump 450. If the positive displacement pump 450 can provide a sufficient level of flow rate accuracy without feedback from the flow sensor 470, then the system can be run in an “open loop” manner. Alternatively, a remotely located macro-ingredient source 181 may be connected to the female fitting 430 via a tube 182 as shown in
The dispenser 100 also may include any number of micro-ingredients 190. In this example, thirty-two (32) micro-ingredient sources 200 may be used although any number may used herein. The micro-ingredient sources 200 may be positioned within a plastic or a cardboard box to facilitate handling, storage, and loading. Each micro-ingredient source 200 may be in communication with a micro-ingredient pump 500. The micro-ingredient pump 500 may be a positive-displacement pump so as to provide accurately very small doses of the micro-ingredients 190. Similar types of devices may be used herein such as peristaltic pumps, solenoid pumps, piezoelectric pumps, and the like.
Each micro-ingredient source 200 may be in communication with a micro-ingredient mixing chamber 510 via a micro-ingredient line 520. Use of the micro-ingredient mixing chamber 510 is shown in
As is shown in
At the start of a dispense, the on/off valve 547 opens and the water 120 may begin to flow into the micro-mixing chamber 510 at a low flow rate but with high linear velocity. For example, the flow rate may be about one (1) milliliter per second. Other flow rates may be used herein. The micro-ingredient pumps 500 then may begin pumping the desired micro-ingredients 190. As is shown in
At the end of the dispense, the micro-ingredient pumps 500 may then stop but the water 120 continues to flow into the micro-ingredient mixer 510. At this time, the pneumatic channel 590 may alternate between a pressurized and a depressurized condition via the three-way valve 555. As is shown in
The micro-ingredients displaced after the end of the dispense then may be diverted to a drain as part of a post-dispense flush cycle. After the post-dispense flush cycle is complete, the valve 547 closes and the central water channel 605 is pressurized according to the setting of the regulator 541. This pressure holds the membrane valve 600 tightly closed. Other components and other configurations may be used herein.
The rotary combination chamber 610 may include a fixed element 640 and a rotating element 650. The elements 640, 650 may have any desired size, shape, or configuration. The fixed element 640 and the rotating element 650 may meet at interface 660. The fixed element 640 and the rotating element 650 may be made out of materials that offer low friction and smooth sealing properties such as ceramics and the like. Other components and other configurations may be used herein.
The rotary combination chamber 610 also may include a drive mechanism 670 for driving the rotating elements 650. The drive mechanism 670 may be any type of mechanism that imparts rotary motion and the like to the rotating element 650 such as a pinion and gear mechanism 680. Other types of drive mechanisms may be used herein. The pinion and gear mechanism 680 may include a pinion 690 attached to a driveshaft 700. The driveshaft 700 may be driven by a conventional electric motor (not shown) and the like. The pinion 690 may cooperate with a number of gear teeth 710 mounted on a flange 720 of the rotating element 650 for rotation therewith. The drive mechanism 670 may be operated under the command of a controller 730. The controller 730 may be any type of conventional programmable microprocessor and the like. Other components and other configurations may be used herein.
The flange 720 of the rotating element 650 may have one or more position indicators 740 located thereon. Although one such position indicator 740 is shown, any number of positions indicator 740 may be used herein. The rotary combination chamber 610 also may include a number of sensors 750 positioned about the rotating element 650 so as to cooperate with the position indicator 740. Again, although only three of the sensors 750 are shown, any number of sensors 750 may be used. The sensors 750 interact with the position indicators 740 so as to detect the rotary position of the rotating element 650. When the position indicator 740 aligns with a sensor 751, the dispense position is indicated. When the position indicator 740 aligns with a sensor 752, the sealed position is indicated. When the position indicator 740 aligns with a sensor 753, the wash position is indicated. The sensors 750 and the position indicator 740 may include Hall effect sensors, magnets, optical sensors, reflectors or slots, and the like. The controller 730 thus may operate the drive mechanisms 670 as indicated by the sensors 750 and the positioned indicator 740.
The fixed element 640 may have a water inlet 760. The water inlet 760 may be in communication with a flow of water 120 from a water source 130 via a waterline 780. The water inlet 760 may lead to a vertical water channel 790. The vertical water channel 790 in turn may lead to one or more horizontal water wash channels 800. The horizontal water wash channel 800 may be in the form of an open indentation on a bottom side of the fixed element 640. The horizontal water wash channel 800 may have any size, shape, and configuration.
The fixed element 640 also includes a number of micro-ingredient inlets 810. Although a first micro-ingredient inlet 811, a second micro-ingredient inlet 812, and a sixth micro-ingredient inlet 816 are shown, any number of the micro-ingredients inlets 810 may be used. The micro-ingredient inlets 810 may be in communication with the micro-ingredient sources 200 via a number of the micro-ingredient lines 520. As above, although a first micro-ingredient line 521, a second micro-ingredient line 522, and a sixth micro-ingredient line 526 are shown, any number of the micro-ingredient lines 520 may be used. The micro-ingredient inlets 810 lead to a number of upper vertical channels 830 extending through the fixed elements 640. Although a first upper vertical channel 831, a second micro-ingredient channel 832, and a sixth upper vertical channel 836 are shown, any number of the upper vertical channels 830 may be used. The upper vertical channels 830 may have any size, shape, or configuration. Other components and other configurations may be used herein.
The rotating elements 650 may include a number of lower vertical channels 840. Although a first lower vertical channel 841, a second lower vertical channel 842, and a sixth lower vertical channel 846 are shown, any number of the lower vertical channels 840 may be used. The lower vertical channels 840 may have a similar size, shape, and/or configuration so as to communication with the upper vertical channels 830 of the fixed element 840. The lower vertical channels 840 may lead to a horizontal channel 850 which may lead to a vertical outlet channel 860 and an outlet 870. The outlet 870 may be in communication with the mixing module 210, the nozzle 220, and the like. Other components and other configurations may be used herein.
In use, the controller 730 instructs the drive mechanism 670 to the dispense position 620 of
The controller 730 then may instruct the drive mechanism 870 to maneuver the rotating element 650 to a wash position 880 where the positioning indicator 740 aligns with the sensor 753. The wash position 880 is shown in
The rotating element 650 may remain in the wash position 880 for a predetermined amount of time for a timed wash or the wash position 880 may be a transient operation while the rotating element 650 is moving. The flow of water 120 may be continually pressurized in the transient operation with the interface 660 between the fixed element 640 and the rotating element 650 acting as a valve so as to allow only the flow of water 120 into the lower vertical channels 840 when the horizontal water wash channel 800 aligns with the lower vertical channels 840. Given the use of this transient operation, the sensor 753 may not be required. In the non-transient operation, the flow of water 120 may be turned on and off for a predetermined amount of time.
The flow of water 120 thus flows through all of the lower vertical channels 840 of the rotating element 650 so as to wash away all of the traces of the micro-ingredients 190 remaining therein. The upper vertical channels 830 of the fixed element 640 may remain filled with the micro-ingredients 190 and may remain sealed via the interface 660 between the fixed element 640 and the rotating elements 650.
The controller 730 then may instruct the drive mechanism 670 to maneuver the rotating element 650 to a sealed position 900 when the position indicator 740 aligns with the sensor 752. As is shown in
When the controller 730 again instructs the drive mechanism 670 to maneuver the rotating element 650 to the dispense position 620, the water 120 that remained in the lower vertical channels 840 may flow to the outlet 870 with the incoming flow of the micro-ingredients 190. The volume of this extra water, however, may be considered minor and therefore insignificant as compared to the incoming micro-ingredient flow. Any water remaining in any of the lower vertical channels 840 that may not be in the current dispensing flow may remain therein so as to act as a buffer to prevent any micro-ingredients 190 in the non-dispensing upper vertical channels 830 from contacting the dispensing stream. Although the non-dispensed micro-ingredients 190 in the upper vertical channels 830 may contact the water in corresponding lower vertical channels 840, the contact time may be sufficiently brief so as to prevent the diffusion of the micro-ingredients 190 through the lower vertical channels 840.
As the rotating element 650 moves from one dispense position 620 to the next, any one of the lower vertical channels 840 may be aligned with any one of the upper vertical channels 830 such that the lower vertical channel 840 may dispense different micro-ingredients 190 on different dispense cycles. Carryover or cross-contamination, however, may be eliminated given the wash position 880. Other components and other configurations may be used herein.
The beverage dispenser 950 also may include a number of micro-ingredient sources 1030 in communication with the nozzles 960. Although a first micro-ingredient source 1031, a second micro-ingredient source 1032, and a third micro-ingredient source 1033 are shown, any number of the micro-ingredient sources 1030 may be used herein. A non-nutritive sweetener source 1034 and the like also may be used herein. Other types of ingredients also may be used herein. Each of the micro-ingredient sources 1030 may be in communication with the nozzles 960 via a rotary switching chamber 1040. Similar to that described above, the rotary switching chamber 1040 may include a fixed element 1050, a rotating element 1060, and a drive mechanism 1070. A number of position indicators 1080 and sensors 1090 also may be used herein.
The fixed element 1050 may include a number of inlets 1100. Although a first inlet 1101, a second inlet 1102, a third inlet 1103, and a fourth inlet 1104 are shown, any number of the inlets 1100 may be used. Each of the inlets 1100 may be in fluid communication with one of the micro-ingredient sources 1030 via an inlet line 1110. Although a first inlet line 1111, a second inlet line 1112, and a third inlet line 1113 are shown, any number of the inlet lines 1110 may be used herein. Each of the inlets 1100 may lead to an upper vertical channel 1120 that extends through the fixed element 1050. Although a first upper vertical channel 1121, a second upper vertical channel 1122, and a third upper vertical channel 1123 are shown, any number of the upper vertical channels 1120 may be used herein. Other components and other configurations may be used herein.
The rotating element 1060 may have a number of lower vertical channel groups 1130. Although a first lower vertical channel group 1131, a second lower vertical channel group 1132, and a third lower vertical channel group 1133 are shown, any number of the vertical channel groups 1130 may be used. Each of the lower vertical channel groups 1130 may have a number of lower vertical channels 1140 therein. Although a first lower vertical channel 1141, a second lower vertical channel 1142, and a third lower vertical channel 1143 are shown, any number of the lower vertical channels 1140 may be used. Each of the lower vertical channels 1140 may be in communication with an outlet 1150. Although a first outlet 1151, a second outlet 1152, and a third outlet 1153 are shown, any number of the outlets 1150 may be used herein. Each outlet 1150 may be in communication with one of the nozzles 960 via, an outlet line 1160. Although a first outlet line 1161, a second outlet line 1162, and a third outlet line 1163 are shown, any number of the outlet lines 1160 may be used herein. Other components and other configurations may be used herein.
The mixing module 210 may include a water entry port 1174 and a carbonated water entry port 1176 positioned about the nozzle 220. The water entry port 1174 may include a number of water duckbill valves 1178 or similar types of sealing valves. The water entry port 1174 may lead to an annular water chamber 1180 that surrounds a mixer shaft (as will be described in more detail below). The annular water chamber 1180 may be in fluid communication with the top of a mixing chamber 1182 via five (5) water duckbill valves 1178. The water duckbill valves 1178 may be positioned about an inner diameter of the chamber wall such that the water 120 exiting the water duckbill valves 1178 washes over all of the other duckbill valves 1170 to insure that proper mixing will occur during the dispensing cycle and proper cleaning will occur during a flush cycle. Other types of distribution means may be used herein.
A mixer 1184 may be positioned within the mixing chamber 1182. The mixer 1184 may be an agitator driven by a motor/gear combination 1186. The motor/gear combination 1186 may include a DC motor, a gear reduction box, or other conventional types of drive means. The mixer 1184 rotates at a variable speed depending on the nature of the ingredients being mixed, typically in the range of about 500 to about 1500 rpm so as to provide effective mixing. Other speeds may be used herein. The mixer 1184 may thoroughly combine the ingredients of differing viscosities and amounts to create a homogeneous mixture without excessive foaming. The reduced volume of the mixing chamber 1182 provides for a more direct dispense. The diameter of the mixing chamber 1182 may be determined by the number of macro-ingredients 170 that may be used. The internal volume of the mixing chamber 1182 also is kept to a minimum so as to reduce the loss of ingredients during a flush cycle. The mixing chamber 1182 and the mixer 1184 may be largely onion-shaped so as to retain fluids therein because of centrifugal force when the mixer 1184 is running. The mixing chamber 1182 thus minimizes the volume of water required for flushing.
As is shown in
The macro-ingredients 170 (including the HFCS 340), the micro-ingredients 190, and the water 140 thus may be mixed in the mixing chamber 1182 via the mixer 1184. The carbonated water 140 may then be sprayed into the mixed ingredient stream via the flow deflector 1190. Mixing continues as the stream flows down the nozzle 220.
At the completion of a dispense, the flow of the ingredients 120, 140, 170, 190, 340 stops and the mixing chamber 1182 may be flushed with water with the mixer 1184 turned on. The mixer 1184 may run at about 1500 rpm for about three (3) to about five (5) seconds and may alternate between forward and reverse motion (known as Wig-Wag action) to enhance cleaning. Other speeds and times may be used herein depending upon the nature of the last beverage. About thirty (30) milliliters of water may be used in each flush depending upon the beverage although other amounts could be used. While the mixer 1184 is running, the flush water will remain in the mixing chamber 1182 because of centrifugal force. The mixing chamber 1182 will drain once the mixer is turned off. The flush cycle thus largely prevents carry over from one beverage to the next. Other components and other configurations may be used herein.
The ingredient mixing module 1200 also may include a micro-ingredient entry port 1260. The micro-ingredient port 1260 may be positioned about a top surface 1270 of the ingredient mixing module 1200. The micro-ingredient port 1260 may accommodate the flow of the micro-ingredients 190 from the micro-ingredient mixing chamber 510, from the rotary combination chamber 610, the rotary switching chamber 1040, or elsewhere. A duckbill valve 1250 and the like also may be used herein.
The middle entry ports 1210 and the micro-ingredient entry port 1260 may lead to a mixing chamber 1280. The mixing chamber 1280 may have an onion-like configuration 1290 formed by the walls 1300 thereof. The middle entry ports 1210 may enter the mixing chamber 1280 radially about the walls 1300 of the mixing chamber 1280 to promote good mixing. Other components and other configurations may be used herein.
A mixer 1310 may be positioned within the mixing chamber 1280. The mixer 1310 also may have a complimentary onion-like configuration 1290 with respect to the mixing chamber 1280. The mixer 1310 acts as an agitator within the mixing chamber 1280. The ingredient mixing module 1200 may thoroughly combine ingredients of different viscosities and amounts to create a homogeneous mixture without excessive foaming. The reduced volume of the mixing chamber 1280 provides for a more direct dispense. The use of the onion-like configuration 1290 of the mixing chamber 1280 and the mixer 1310 helps to maintain the fluids therein because of centrifugal force.
The mixer 1310 may be driven by a brushless motor 1320. The brushless motor 1320 thus magnetically drives the mixer 1310 within the mixing chamber 1280. Specifically, the mixer 1310 acts as a rotor 1330 for the brushless motor 1320. As such, the mixer 1310 includes a central shaft 1340. The central shaft 1340 may be surrounded by a laminated soft iron core 1350. Likewise, a number of permanent magnets 1360 may surround the laminated soft iron core 1350. The brushless motor 1320 further may include a laminated soft iron stator 1370. The laminated soft stator 1370 may be positioned outside the walls 1300 of the mixing chamber 1280. A number of electromagnetic windings 1380 may be positioned about the laminated soft iron stator 1370. Other components and other configurations may be used herein.
Electrification of the windings 1380 of the laminated soft iron stator 1370 thus attracts the permanent magnets 1360 of the mixer 1310 acting as the rotor 1330. This magnetic attraction thus drives the mixer 1310. In this example, the use of four (4) of the permanent magnets 1360 makes the mixer 1310 function as a two (2) pole rotor. The brushless motor 1320 may be connected to a brushless DC controller (not shown). The use of the brushless motor 1320 provides additional space within the mixing chamber 1280. The brushless motor 1320 also provides reliability with increased sanitation. Specifically, the brushless motor 1320 eliminates the need for shaft seals therein to drive the mixer 1310. The brushless motor 1320 also allows for RPM control without the need of an encoder. Other components and other configurations may be used herein.
The mixer 1310 may be positioned between a top bearing surface 1390 and a bottom bearing surface 1400. The top and bottom bearing surfaces 1390, 1400 allow the fluids within the mixing chamber 1280 to contact all surfaces of the mixer 1310 and the bearing surfaces 1390, 1400 themselves. The mixing chamber 1280 thus may have a flow through configuration without dead legs or sharp corners so as to be compatible with the clean-in-place sanitizing process.
A number of carbonated water entry ports 1410 may be positioned about the bottom bearing surface 1400 at the bottom of the mixing chamber 1280. The carbonated water entry ports 1410 may be integrated into the walls 1300 of the mixing chamber 1280 that supports the bottom bearing surface 1400. Although three (3) carbonated water entry ports 1410 are shown, any number of the carbonated water entry ports 1410 may be used herein. Varying levels of carbonation may be used herein. The carbonated water entry ports 1410 may be angled away from the mixing chamber 1280 so as to create a central flow with a reduced velocity. Reducing the velocity may limit the decarbonation of the flow therethrough. Other components and other configurations may be used herein.
A nozzle 1420 may be positioned downstream of the mixing chamber 1280. The nozzle 1420 may be removable for cleaning. The nozzle 1420 may have a number of internal fins 1430 positioned therein. The internal fins 1430 may include number of complete fins 1440 and a number of partial fins 1450. The fins 1430 may have any size, shape, or configuration. Although nine (9) fins 1430 are shown herein, any number of the fins 1430 may be used. The fins 1430 serve to straighten the flow therethrough while reducing the amount of foam. Other components and configurations may be used herein.
The macro-ingredients 170, the HFCS 340, and the micro-ingredients 190 and water 120 thus may be mixed within the ingredient mixing module 1200 via the mixer 1310. The mixer 1310 may rotate at varying speeds depending upon the type of ingredients being mixed. The carbonated water 140 then may be added to the stream upstream of the nozzle 1420. The ingredients continue to mix as the stream continues down the nozzle 1420 and into the consumer's cup. The timing of the entry of the macro-ingredients, the HFCS, the micro-ingredients 190, the water 120, and the carbonated water 140 may be varied to achieve the homogeneous flow and prevent foaming.
It should be apparent that the foregoing relates only to certain embodiments of the present application and the resultant patent. Numerous changes and modifications may be made herein by one of ordinary skill in the art without departing from the general spirit and scope of the invention as defined by the following claims and the equivalents thereof.
The present application is a continuation-in-part of U.S. patent application Ser. No. 11/777,309, filed on Jul. 13, 2007, entitled “DISPENSER FOR BEVERAGES INCLUDING JUICES”, now pending, which, in turn, is a continuation-in-part of U.S. patent application Ser. No. 11/276,549, filed on Mar. 6, 2006, entitled “JUICE DISPENSING SYSTEM”, now pending. U.S. patent application Ser. Nos. 11/777,309 and 11/276,649 are incorporated by reference herein in full.
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Entry |
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Lancer, Title: “Redirect your store traffic from the cooler to your more profitable post-mix fountain area by adding fun and creating excitement!”; FS Series, dated Apr. 2003; pp. 1-4. |
Number | Date | Country | |
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20120228328 A1 | Sep 2012 | US |
Number | Date | Country | |
---|---|---|---|
Parent | 11777309 | Jul 2007 | US |
Child | 13477119 | US | |
Parent | 11276549 | Mar 2006 | US |
Child | 11777309 | US |