JPH08119390A - Ice-cooled drink-supplying apparatus - Google Patents

Abstract

PURPOSE: To provide an ice-cooled drink-supplying apparatus wherein a concentration of carbon dioxide gas is high and carbonated drink of a predetermined concentration can be obtained by cooling a carbonator stored in an ice bin and feeding cold water cooled through a cold plate to the carbonator. CONSTITUTION: A carbonator 7 is built into an ice bin 11, and cold water cooled through a cold plate built into the ice bin 11 is split by a three-way valve so that one way is connected to the carbonator 7 and the other way to a drink supply tower 10.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ice-cooled beverage supply device having a table body having a carbonator and a water pump incorporated therein.

[0002]

2. Description of the Related Art FIG. 3 is a block diagram of a main part of a conventional example.
In FIG. 3, 1 is a carbon dioxide cylinder, 2 is a carbon dioxide regulator, 3 is a water faucet, 4 is a syrup tank, 5 is a water pump, 6 is a check valve, 7 is a carbonator, and 8 is A carbonator kit is shown. 9 is ice
Is a beverage supply tower, 11 is an ice bottle, 12 is a cold plate, 13 is a drain bucket, 14 is a drain port of the ice bottle 11, and 15 is a table body. With this configuration, the syrup in the syrup tank 4 is sent out by the pressure of the carbon dioxide gas supplied from the carbon dioxide gas cylinder 1 to the syrup tank 4 through the one carbon dioxide gas regulator 2, and the syrup is cooled through the cold plate 12 to drink. The beverage solenoid valve (not shown) in the supply tower 10 has been supplied and is in a supply standby state.
Also, a part of the carbon dioxide gas supplied from the carbon dioxide gas cylinder 1 to the carbonator 7 through the other carbon dioxide gas regulator 2 is dissolved in the water supplied to the carbonator 7 through the water tap 3, the water pump 5 and the check valve 6 to generate carbon dioxide. The carbonated water is sent out from the carbonator 7 by the pressure of the remaining carbon dioxide gas which has become water and is not dissolved in the cold plate 12
It is cooled through and is supplied to a carbonated water solenoid valve (not shown) in the beverage supply tower 10 and is in a supply standby state.

Water is branched from between the water pump 5 and the check valve 6 and cooled through the cold plate 12, and a cold water solenoid valve (not shown) in the beverage supply tower 10 is provided.
Has been supplied and is in a supply standby state, but when supplying cold water to the nozzle, a cold water solenoid valve (not shown)
And the water pump 5 is driven. The carbonated water in the carbonator 7 is automatically supplied to the water pump 5 by a water level switch (not shown) provided in the carbonator 7.
Is manufactured and replenished, and is always kept within the range of the response difference of the water level switch (not shown).

In this state, when a beverage is supplied, when a beverage selection switch (not shown) is pressed, a selected syrup solenoid valve (not shown) in the beverage supply tower is selected according to the selected formulation. Either the carbonated water solenoid valve (not shown) or the cold water solenoid valve (not shown) will open and the nozzle of the beverage supply tower 10 will be supplied with either the selected syrup and carbonated water or cold water from the nozzle. It is jetted into a cup (not shown) placed on the cup holder of the beverage supply tower 10.

In the cold plate 12, a plurality of syrup pipes (not shown) and a plurality of diluent liquid pipes (not shown) are cast in a material having a high thermal conductivity, and supply and discharge pipe ports are provided respectively. It is formed into a block that has, is installed in an ice bottle 11 that is insulated by a heat insulating material and stores ice 9, and is cooled by the ice 9 therein. The melted water of the ice 9 in the ice bottle 11 is stored in the drain bucket 13 through the drain port 14 provided in the lower portion of the ice bottle 11 and is drained at a proper time.

Among the above-mentioned members, the ice bottle 11 containing the ice 9 and the cold plate 12, the drain bucket 13, and the beverage supply tower 10 are contained in the table body 15 and the water pump. 5, the check valve 6 and the carbonator 7 are housed in a carbonator kit 8 and separately placed near the table body 15 together with the carbon dioxide cylinder 1 and the syrup tank 4.

[0007]

In the structure of the conventional ice-cooled beverage supply apparatus, the carbonator 7 is housed in the carbonator kit 8 together with the water pump 5 and the check valve 6, and the ice-cooled beverage supply apparatus is provided. Since it is exposed to the same atmospheric temperature as the place where is installed, it is against the phenomenon that when the carbon dioxide is dissolved in water, the solubility of carbon dioxide in water increases as the temperature in the water and carbonator decreases. As a result, there is a problem that it is difficult to obtain carbonated water having an appropriate carbon dioxide concentration.

Further, since the water supplied to the carbonator is the same as the water temperature of the water faucet and is not cold water, there is a problem that it is difficult to obtain carbonated water having an appropriate carbon dioxide concentration as described above. Further, there is a problem that the carbon dioxide gas concentration changes with a change in the water temperature of the water faucet, and a constant concentration of carbonated water cannot be obtained. The purpose of this invention is
To provide an ice-cooled beverage supply device that has a high carbon dioxide concentration and can obtain a constant concentration of carbonated water by storing a carbonator in an ice bottle and cooling it, and supplying cold water to the carbonator by cooling it with cold plates. Especially.

[0009]

According to a first aspect of the present invention, a carbon dioxide gas cylinder having carbon dioxide gas and carbon dioxide gas sent from the cylinder are taken in and a part of the carbon dioxide gas is sent through a water pump connected to a water tap. A carbonator that dissolves in water to make carbonated water and sends out carbonated water with the pressure of the remaining carbon dioxide gas that does not become carbonated water, carbonated water sent from the syrup tank and carbonator with the pressure of carbon dioxide gas, sent from the water pump A cold plate that cools water and beverages such as syrup sent from a syrup tank, ice that cools the cold plate, an ice bottle that stores the ice and the cold plate, and a beverage that has been cooled through the cold plate is supplied to the cup. An ice-cooled beverage supply device comprising: Housed in a bottle, the water water into the carbonator from the water pump to an ice-cooled beverage supply system chilled water which has been cooled through the cold plate is water.

According to a second aspect of the present invention, in the ice-cooled beverage supply device according to the first aspect, the water to be fed to the carbonator is branched from the water pump through the cold plate to the two-way valve. An ice-cooled beverage supply device is used for water supply via the water. According to a third aspect of the invention, in the ice-cooled beverage supply device according to the second aspect, the water to be fed to the carbonator is fed from the water pump through the cold plate through the three-way valve. Beverage supply device.

[0011]

[Action] The pressure of the carbon dioxide gas cylinder is 10 kg / cm ^2, is sent to the carbonator is reduced to 5 kg / cm ² with carbon dioxide gas regulator. In the carbonator, the water from the water pump is atomized and sprayed onto the carbon dioxide gas filling the carbonator to dissolve the carbon dioxide into carbonated water, but the solubility of carbon dioxide is equal to the temperature of carbon dioxide. It is inversely proportional and proportional to pressure. If the temperature of the carbon dioxide gas in the carbonator is lowered to a constant temperature by incorporating the carbonator into an ice bottle, carbonated water having a high concentration and a constant concentration is produced.

[0012]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a block diagram of an embodiment of the present invention.
In FIG. 1, members given the same reference numerals as those in the conventional example have substantially the same functions, and thus the description thereof will be omitted. In FIG. 1, 1 is a carbon dioxide gas cylinder, 2 is a carbon dioxide gas regulator, 3 is a water faucet, 4 is a syrup tank, 5 is a water pump, 6 is a check valve, and 7 is a carbonator. 9 is ice, 10 is a beverage supply tower, 11
Is an ice bottle, 12 is a cold plate, 13 is a drain bucket, 14 is a drain port of the ice bottle 11, and 15 is a table body. With this configuration, the syrup is cooled through the cold plate 12 by the pressure of the carbon dioxide gas supplied from the carbon dioxide cylinder 1 to the syrup tank 4 through the one carbon dioxide gas regulator 2, and the beverage solenoid valve (not shown) in the beverage supply tower 10 is shown. Is not supplied) and is in a supply standby state. Further, a part of the carbon dioxide gas supplied from the carbon dioxide gas cylinder 1 to the carbonator 7 housed in the ice bottle 11 through the other carbon dioxide gas regulator 2 is partially stopped by the water tap 3, the water pump 5, the cold plate 12, the two-way valve 16 and the check valve. The carbonated water is discharged from the carbonator 7 under the pressure of the remaining carbon dioxide gas which is dissolved in the cold water supplied to the carbonator 7 through the valve 6 and becomes carbonated water and is not dissolved in the water, and is cooled through the cold plate 12 to supply the beverage. A carbonated water solenoid valve (not shown) in the tower 10 has been supplied and is in a supply standby state.

Water is cooled from the water pump 5 through the cold plate 12 and branched at the outlet side of the cold plate 12, one to the carbonator side and the other to the cold water solenoid valve in the beverage supply tower 10 (shown in the figure). It has not been)
Has been supplied and is in a supply standby state, but when supplying cold water to the nozzle, a cold water solenoid valve (not shown)
And the water pump 5 is driven.

The carbonated water in the carbonator 7 is automatically manufactured and replenished by automatically driving the water pump 5 by a water level switch (not shown) provided in the carbonator 7 so that the water level switch (not shown) is always provided. It is kept within the range of the response difference of (No). When a beverage is supplied in this state, when a beverage selection switch (not shown) is pressed, the selected syrup solenoid valve (not shown) in the beverage supply tower and the carbonated water solenoid are selected according to the selected formulation. Either a valve (not shown) or a cold water solenoid valve (not shown) is opened and the nozzle is supplied with the selected syrup and either carbonated water or cold water, and the nozzle is supplied with the cup holder of the beverage supply tower 10. Ejected into a cup (not shown) placed on top.

In the cold plate 12, a plurality of syrup pipes (not shown) and a plurality of diluent liquid pipes (not shown) are cast in a material having a high thermal conductivity, and supply / discharge pipe ports are provided respectively. It is formed into a block that has, is installed in an ice bottle 11 that is insulated by a heat insulating material and stores ice 9, and is cooled by the ice 9 therein. The melted water of the ice 9 in the ice bottle 11 is stored in the drain bucket 13 through the drain port 14 provided in the lower portion of the ice bottle 11 and is drained at a proper time.

Among the above-mentioned members, the check valve 6, the carbonator 7, the ice 9, the ice bottle 11 containing the cold plate 12, the water pump 5, and the drain bucket 13 are provided.
And the beverage supply tower 10 are housed in the table body 15, the carbon dioxide gas cylinder 1 and the syrup tank 4
And are separately placed near the table body 15. Figure 2
Shows a block diagram of another embodiment of the present invention. 2 is different from FIG. 1 in that cold water cooled by the cold plate 12 is branched by a three-way valve 17 so that one is on the carbonator 7 side and the other is a cold water solenoid valve (not shown) in the beverage supply tower 10. ) Side is connected to the point.

[0017]

According to the present invention, a carbonator is built in an ice bottle to lower the temperature of carbon dioxide in the carbonator, and the water sent from the water pump to the carbonator is cold water cooled through a cold plate. Since the temperature is kept constant in this way, there is an effect that carbonated water having a high concentration and a constant concentration is produced.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a main part of an embodiment of the present invention.

FIG. 2 is a configuration diagram of a main part of another embodiment of the present invention.

FIG. 3 is a configuration diagram of a main part of a conventional example.

[Explanation of symbols]

1 ... Carbon dioxide cylinder, 2 ... Carbon dioxide regulator, 3 ...
Water tap, 4 ... Syrup tank, 5 ... Water pump, 6 ... Check valve, 7 ... Carbonator, 9 ... Ice, 10 ... Beverage supply tower, 11 ... Ice bottle, 12 ... Cold plate, 13
… Drainage bucket, 14… Drainage port, 15… Table body, 1
6 ... 2-way valve, 17 ... 3-way valve.

Claims (3)

[Claims] 1. A carbon dioxide gas cylinder having carbon dioxide gas, and carbon dioxide gas sent from this cylinder is taken in and a part of the carbon dioxide gas is dissolved in water sent through a water pump connected to a water tap to make carbonated water. The carbonator that sends out carbonated water with the pressure of the remaining carbon dioxide that does not become, the carbonated water sent from the syrup tank and the carbonator with the pressure of carbon dioxide, the water sent from the water pump and the syrup sent from the syrup tank, etc. Ice cooling with a cold plate for cooling the beverage, ice for cooling the cold plate, an ice bottle for storing the ice and the cold plate, and a beverage supply tower for supplying the beverage cooled through the cold plate to the cup Type beverage supply apparatus, the carbonator is stored in the ice bottle, and the Water that is water to over other ice-cooled beverage supply system, characterized in that cold water is cooled through the cold plate is water. 2. The ice-cooled beverage supply device according to claim 1, wherein the water to be supplied to the carbonator is branched from the water pump on the outlet side through the cold plate and is then supplied via a two-way valve. An ice-cooled beverage supply device characterized by the above. 3. The ice-cooled beverage supply device according to claim 2, wherein the water supplied to the carbonator is supplied from a water pump through a cold plate through a three-way valve. Ice-cooled beverage supply device.