JP3540516B2 - Multi-valve soft drink dispenser - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
According to the present invention, one syrup is selected from a plurality of syrups (concentrated liquids) having different types of flavors, flavors, colors, and the like, and the selected one syrup is mixed with a diluting water such as carbonated water or cold water to be supplied. It relates to a multi-valve soft drink dispenser.
[0002]
[Prior art]
As a conventional multi-valve applied to a soft drink dispenser, for example, there is one shown in FIG. 12 (for example, Japanese Patent Application Laid-Open No. 7-309398). The multi-valve 10 is provided with a diffuser 13 in which each syrup flow path 11 of a plurality of syrups and a dilution flow path 12 of dilution water are independently formed, and mounted on an outer periphery of the diffuser 13 via an O-ring 14, A spout 16 having a supply port 15 for supplying syrup and dilution water fed from each of the flow channels 11 and 12, and formed on the outflow end side of the syrup flow channel 11 so as to protrude from the lower surface 13 a of the diffuser 13. The tip of the syrup nozzle 17 has a sloped shape, and the tip of the slope is located on the center side of the spout 16.
[0003]
According to such a configuration, the tip of the syrup nozzle 17 projecting separately for each syrup is inclined, so that the syrup adhering to the nozzle surface hangs down and another syrup is selected next. By the time, almost all of the syrup is dropped, and the mixing of other syrups can be prevented.
[0004]
[Problems to be solved by the invention]
However, according to the conventional multi-valve 10, since the syrup flow path 11 is formed in the vertical direction, the syrup is discharged from the syrup flow path 11 directly below during the syrup supply, scatters to the spout 16, and is then supplied. There is a disadvantage that the syrup is mixed into the syrup.
[0005]
Accordingly, an object of the present invention is to provide a multi-valve soft drink dispenser capable of supplying a high-quality soft drink by preventing other syrups from being mixed.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a multi-valve soft drink that selects one syrup from a plurality of different syrups, and supplies the selected one syrup and a diluting water such as carbonated water and cold water. In the dispenser, a plurality of syrup nozzles provided corresponding to the plurality of syrups, a dilution water supply outlet for supplying the dilution water, and one syrup nozzle selected from the plurality of syrup nozzles. A supply port for supplying a beverage obtained by mixing the one syrup to be supplied and the dilution water supplied from the dilution water supply outlet, wherein the plurality of syrup nozzles each have an axial direction extending syrup flow path is formed, the shape on the outflow end side of the syrup flow path to supply said one of syrup in the center or in the vicinity of the supply port to the A nozzle tip that is, that provided at the center side of the supply port protrudes from the end face of the syrup flow path extending in the axial direction at an angle to face the center of the supply opening the nozzle tip protrusion Wherein the syrup supplied from the syrup flow path is supplied along the projection toward the center of the supply port, thereby providing a multi-valve soft drink dispenser. According to the above configuration, the syrup is supplied from the tip of the syrup nozzle to the center of the supply port or in the vicinity thereof. This prevents the syrup from scattering around the supply port. In addition, the mixed state of the syrup and the dilution water becomes uniform.
[0007]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a front view of a multi-valve soft drink dispenser according to an embodiment of the present invention, and FIG. 2 is a side view thereof.
The dispenser 1 includes a carbonated beverage supply system 2 for supplying carbonated beverages such as oolong tea and juice, and a carbonated beverage supply system 3 for supplying carbonated beverages such as cola from the multi-valve 100 according to the present invention. have.
The dispenser 1 has a substantially box-shaped device main body 4, and a door provided with a start switch 5 a for activating the dispenser 1 and a selection switch 5 b for selecting a beverage to be supplied on the upper front surface of the device main body 4. 5 is provided, and a drip tray 7 on which three paper cups 6 can be placed is provided at a lower front part of the apparatus main body 4.
[0008]
The non-carbonated beverage supply system 2 has a cool box 20 in the upper front part of the apparatus main body 4. The cool box 20 includes a pair of left and right BIBs (Bag In Boxes) 21A and 21B containing syrups (concentrated liquids) for non-carbonated beverages, and a cooler 22 in which a continuous S-shaped cooling water pipe 22a is formed. The cooling water in the cooling water tank 330 is circulated in the cooling water pipe 22a of the cooler 22 by a circulating pump 334 described later, thereby keeping the syrup for non-carbonated beverages cool.
The non-carbonated beverage supply system 2 is pressure-fed by a pair of left and right tube pumps 23A and 23B for pumping syrup for non-carbonated beverage and cold water as dilution water from the BIBs 21A and 21B. The syrup nozzles 24A and 24B for discharging the syrup to the paper cup 6 placed directly below, and the dilution nozzles 25A and 25B for discharging the dilution water pumped by the tube pumps 23A and 23B to the paper cup 6 placed directly below. Have.
[0009]
The carbonated beverage supply system 3 includes a multi-valve 100 according to the present invention, a flow control valve, various solenoid valves 320, and the like arranged at the front center of the apparatus main body 4. A pressurizing pump 321 for pressurizing and supplying tap water from 350, a cooling water tank (hereinafter abbreviated as “water tank”) 330 containing cooling water, and cooling water in the water tank 330. A cooling unit 340 is provided.
[0010]
In the water tank 330, a carbonator 331 that mixes water and carbon dioxide gas to generate carbonated water (see FIG. 6), an agitator motor 333 that agitates cooling water by an agitator propeller 332, and an agitator motor 333 are attached. A circulation pump 334, a syrup coil for passing syrup, a coil unit 335 including a carbonated water coil for passing carbonated water, and a tap water coil for passing tap water, and an evaporating pipe 343 constituting a cooling unit 340 are provided. ing.
[0011]
The circulating pump 334, the inlet of the cooling water pipe 22a of the cooler 22, the outlet of the cooling water pipe 22a of the cooler 22, and the cooling water inlet (see FIGS. 3, 4 and 5) 146 of the multi-valve 100 are respectively connected to the cooling water pipes. A cooling water pipe 336C returning to the water tank 330 is connected to a cooling water outlet (see FIGS. 3, 4, and 5) 147 of the multi-valve 100, which is connected by 336A and 336B. Thereby, the agitator motor 333 agitates the cooling water in the water tank 330, sends the cooling water in the water tank 330 to the cold storage 20 side via the cooling water pipe 336A, and further, via the cooling water pipes 336B and 336C. The multi-valve 100 is circulated.
[0012]
The cooling unit 340 compresses the refrigerant, a condenser 342 that condenses the refrigerant compressed by the compressor 341, and evaporates the refrigerant condensed by the condenser 342, and cools the surroundings during the evaporation. And an evaporator 343 made of a copper pipe.
[0013]
FIG. 3 is a cross-sectional view showing a configuration of the multi-valve 100 according to the present invention, FIG. 4 is a plan view thereof, and FIG. 5 is a perspective view of a main part showing a cooling structure of the multi-valve 100.
The multi-valve 100 screwes the carbonated water inflow connector 110 into which the carbonated water flows, and reduces the pressure of the carbonated water from the inflow port 111 of the carbonated water inflow connector 110. A resistance piece case 130 which accommodates the resistance piece 120 and has a chilled water inlet 131 into which chilled water flows in an oblique direction, and a plurality of syrup inlets 141 attached to the resistance piece case 130 and through which syrup flows from the middle stage. Is formed in a horizontal direction, and a diffuser 140 for dispersing the syrup from the syrup inflow port 141 and the carbonated water and the cold water from the resistance piece case 130 is mounted on an outer periphery of the diffuser 140 via an O-ring 150. Spout 160 that mixes syrup and carbonated water or cold water and supplies the mixture to paper cup 6 from supply port 161 , And the this spout 160 and the resistive strip casing 130 comprises a base 180 attached by screws 170.
[0014]
The resistor piece 120 has a plurality of grooves 121 formed on the peripheral surface along the axial direction. By changing the depth of the groove 121, the resistance value can be changed. With this resistance, the carbonated water is decompressed and a high-quality carbonated beverage can be supplied.
[0015]
The resistance piece case 130 forms a carbonated water flow path 132 that communicates with the inflow port 111 of the carbonated water inflow connector 110, and accommodates the resistance piece 120 in the carbonated water flow path 132.
[0016]
The diffuser 140 projects a plurality of syrup nozzles 142 downward from the vicinity of the lower center, and the syrup inlets 141 and the syrup nozzles 142 communicate with each other through an independent syrup channel 143, and downward from the upper center. A dilution channel 144 of carbonated water and cold water is formed in an inverted T-shape. Further, a dilution water supply outlet 144 a communicating with the dilution channel 144 is formed between the diffuser 140 and the spout 160.
Each syrup nozzle 142 has a nozzle tip 142a formed at an angle so as to supply syrup to the center of the supply port 161 or in the vicinity thereof. That is, the outflow end side of each syrup channel 143 is formed so as to face the center of the supply port 161 of the spout 160.
The nozzle tip 142a has a protrusion 142b for dropping the rear dripping syrup supply port 161, the center diameter D ₁ of the syrup nozzle 142 is smaller than the opening diameter D ₂ of the supply port 161 of the spout 160.
[0017]
The spout 160 is narrowed toward the supply port 161 to form a flat step 161 a around the supply port 161. By forming the flat step portion 161a, one-sided flow can be prevented. Further, by forming the shape narrowed toward the supply port 161, the syrup and the dilution water can be mixed better, and the flow after the discharge can be improved. Further, the spout 160, the volume V ₂ of the space from the tip of the syrup nozzle 142 to the stepped portion 161a of the supply port 161, carbonated water solenoid valve volume flow path from (see FIG. 6) 362 to the cold water inlet 132a V _It is larger than ₁ .
[0018]
As shown in FIG. 5, an annular cooling water pipe 145 is provided on the outer periphery of the diffuser 140, and a cooling water inlet 146 and a cooling water outlet 147 project from the cooling water pipe 145.
[0019]
FIG. 6 is a supply system diagram of the carbonated beverage supply system 3.
Tap water from the city water supply 350 flows into the cold water inlet 131 of the multi-valve 100 via the water filter 351, the pressure pump 321, the coil unit 335, the distributor 352, the flow control valve 353, and the solenoid valve 354. A conduit 355 is configured.
The carbon dioxide gas from the carbon dioxide gas cylinder 356 is supplied to syrup tanks 357A, 357B, 357C, 357D which respectively store a plurality (for example, four) of syrups I, II, III, IV having different types of flavor, taste, color and the like. The syrups I, II, III, and IV sent from the syrup tanks 357A, 357B, 357C, and 357D by the carbon dioxide gas are supplied to the multi-valve 100 via the coil unit 335 and the solenoid valves 358A, 358B, 358C, and 358D. A conduit 359 is configured to flow into the syrup inlet 141.
The carbonator 331 is arranged in the cooling water in the water tank 330. Thereby, carbonated water can be efficiently generated. The carbonator 331 is supplied with carbon dioxide gas from a carbon dioxide gas cylinder 356, and is supplied with cold water from a distributor 352 via a carbonator water supply solenoid valve 360. The pipeline 363 is configured so that the carbonated water generated by the carbonator 331 flows into the carbonated water inflow connector 110 of the multi-valve 100 via the flow rate adjustment valve 361, the coil unit 335, and the solenoid valve 362.
[0020]
FIG. 7 is a block diagram showing a main part of a control system of the dispenser 1.
The dispenser 1 includes a control unit 8 that controls the entire dispenser 1. The control unit 8 includes a start switch 5 a, a selection switch 5 b, first to fourth syrup solenoid valves 358 A, 358 B, 358 C, 358 D, The carbonated water electromagnetic valve 362, the cold water electromagnetic valve 354, the pressurizing motor 321, the agitator motor 333, the circulation pump 334, the cooling unit 340, and the tube pumps 23A and 23B are connected respectively.
[0021]
Next, the operation of the present dispenser 1 will be described.
When the operator presses the start switch 5a, the control unit 8 controls the pressurizing motor 321, the agitator motor 333, the circulation pump 334, and the cooling unit 340 to cool the cooling water in the water tank 330, and Perform cooling.
When the cooling water in the water tank 330 and the syrup in the cool box 20 have been cooled to a temperature sufficient to supply, the operator presses the selection switch 5b in response to a request from the user. The control unit 8 controls the supply of the non-carbonated beverage or the carbonated beverage based on the depression of the selection switch 5b.
Here, the case of supplying a carbonated beverage will be described.
The control unit 8 controls the corresponding solenoid valves 358A to 358D, 362, and 354 based on the pressing of the selection switch 5b to control any one of the syrups I, II, III, and IV, the carbonated water, and the cold water. , A beverage consisting of any one syrup and carbonated water, or a beverage consisting of any one syrup and cold water is pumped to the multi-valve 100, and the syrup, carbonated water or cold water dilution water is drip-dried. Inject into the paper cup 6 placed in the center of the tray 7.
[0022]
8 is a cross-sectional view of a main part showing a phenomenon during syrup supply of the multi-valve 100, FIG. 9 is a cross-sectional view of a main part after syrup supply, and FIGS. 10 and 11 are cross-sectional views of a main part showing a phenomenon at the time of cold water supply. It is.
[0023]
The locus 80 of the syrup supplied from each syrup nozzle 142 passes through substantially the same position near the center of the spout 160 as shown in FIG.
[0024]
Even after the syrup is supplied, the syrup is pressurized with carbon dioxide gas, so that the gas is gradually absorbed, so that the gas is separated from the syrup in the syrup pipe that has been opened to the atmosphere at the time of supply standby, as shown in FIG. Then, the syrup 81 falls down by the amount of the separated gas and drops, but the syrup 81 dropped from the syrup nozzle 142 falls without contacting the spout 160.
[0025]
When supplying cold water, as shown in FIG. 10, the cold water 82 stays at the supply port 161 of the spout 160, and the inside of the spout 160 is sealed. In this state, when the carbonated water in the carbonated water pipe under atmospheric pressure connected to the multi-valve 100 is gas-separated and flows into the spout 160, as shown in FIG. A phenomenon is seen in which the stagnant liquid 82 in the spout 160 increases, causing the water level in the spout 160 to rise. Volume V ₂ of the space from the tip of the syrup nozzle 142 to the stepped portion 161a of the supply port 161 to be larger than the volume V ₁ of the flow path from the carbonated water solenoid valve 362 to the cold water inlet 132a, cold water supply Even when the water level in the spout 160 rises, the liquid does not come into contact with the syrup nozzle 142, so that mixing of other syrups can be prevented. When supplying carbonated water, since no cold water remains in the cold water pipe, there is no inflow of cold water from the cold water supply side, so that the water surface in the spout 160 does not rise.
[0026]
According to the dispenser 1 configured as described above, the following effects can be obtained.
Since the outflow end side of each syrup channel 143 is formed so as to face the center of the supply port 161 of the spout 160, it is possible to prevent the syrup from scattering around the supply port 161. And the mixing state of the syrup and the dilution water can be uniform. In addition, the protrusion 142b provided at the nozzle tip 142a prevents the drooping of the syrup from dropping into the spout 160 and remains, thereby preventing the syrup from being mixed due to the drooping. Further, since the multi-valve 100 is cooled, the generation of carbonated water can be better prevented. As a result, it is possible to supply a high-quality carbonated beverage that is low in foaming and is well cooled.
In addition, since a part of the circulating water is guided to the multi-vibe 100 to cool the valve 100, a special cooling device for cooling the valve 100 is not required, so that it can be manufactured easily and inexpensively.
[0027]
Note that the present invention is not limited to the above embodiment, and various embodiments are possible. For example, a dedicated cooling unit for cooling the multi-valve 100 may be provided.
[0028]
【The invention's effect】
As described above, according to the present invention, since the syrup is supplied from the nozzle tip of the syrup nozzle to the central portion of the supply port or in the vicinity thereof, the syrup does not scatter around the supply port, and other syrups are not scattered. Since the mixture is prevented and the mixed state of the syrup and the dilution water is made uniform, a high-quality soft drink can be supplied.
[Brief description of the drawings]
1 is a front view of a multi-valve soft drink dispenser according to the present invention; FIG. 2 is a side view of a multi-valve soft drink dispenser according to the present invention; FIG. 3 is a cross-sectional view of a multi-valve soft drink dispenser according to the present invention; FIG. 5 is a perspective view showing a cooling structure of the multi-valve according to the present invention; FIG. 6 is a supply system diagram of a carbonated beverage supply system according to the present invention; FIG. FIG. 8 is a block diagram showing a control system of the multi-valve soft drink dispenser. FIG. 8 is a cross-sectional view of a main part showing a phenomenon during supply of syrup of the multi-valve according to the present invention. FIG. 10 is a cross-sectional view of a main part of a multi-valve according to the present invention at the time of cold water supply. FIG. 11 is a main part of a multi-valve according to the present invention showing a phenomenon at the time of cold water supply. Sectional view [Figure 12] Sectional view of a conventional multi-valve EXPLANATION OF REFERENCE NUMERALS
1 Multi-valve soft drink dispenser 100 Multi-valve 140 Diffuser 142 Syrup nozzle 142a Nozzle tip 142b Projection 142c Vertical straight line 143 passing through the center of the outflow end of syrup flow passage Syrup flow passage 144 Dilution flow passage 144a Dilution water supply outlet 145 Cooling water pipe Channel 146 Cooling water inlet 147 Cooling water outlet 160 Spout 161 Supply port 161a Restrictor 330 Cooling water tank 334 Circulating pump 335 Coil unit 362 Carbonated water solenoid valve

Claims (5)

In a multi-valve soft drink dispenser that selects one syrup from a plurality of different syrups and mixes and supplies the selected one syrup and diluting water such as carbonated water and cold water.
A plurality of syrup nozzles provided corresponding to the plurality of syrups,
A dilution water supply outlet for supplying the dilution water,
A supply for supplying a beverage obtained by mixing the one syrup supplied from one syrup nozzle selected from the plurality of syrup nozzles and the dilution water supplied from the dilution water supply outlet; With mouth and
Said nozzle for multiple syrup is a syrup flow path extending in the axial direction is formed, wherein formed on the outflow end of the syrup flow path to supply said one of syrup in the center or in the vicinity of the supply port a nozzle tip was, said protruding at an angle to face the center of the supply port that is provided on the center side of the supply port of the nozzle tip projecting from the end face of the syrup flow path extending in the axial direction Has,
A multi-valve soft drink dispenser, wherein the syrup supplied from the syrup flow path is supplied along the protrusion so as to face the center of the supply port . The multi-valve soft drink dispenser according to claim 1, wherein the dilution water supply outlet is connected to a dilution water supply passage cooled by cooling water in the vicinity thereof. The multi-valve soft drink dispenser according to claim 2, wherein the cooling water is cooling water for cooling a dilution water coil formed in the middle of the dilution water supply flow path. The supply port has a space of a predetermined volume between the syrup nozzle and the dilution water supply outlet, and after supplying carbonated water, the space is provided on the supply side of the carbonated water supply valve. The multi-valve soft drink dispenser according to claim 1, wherein the predetermined volume is set so as to be larger than the volume of carbonated water remaining in the flow path. The supply port, the has a space of a predetermined volume between the syrup nozzle and the dilution water supply outlet, said space have a stepped portion on its inner wall surface, opening of the supply port The multi-valve soft drink dispenser according to claim 1 , wherein the caliber is larger than a center diameter of the syrup flow path extending in the axial direction and smaller than an outer diameter of the syrup flow path .

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