JPS6225828Y2 - - Google Patents

Description

[Detailed Description of the Invention] This invention relates to a dispensing device for a drinking water vending machine that can freely dispense either cold water or carbonated water.

As a drinking water dispensing device like the one mentioned above, Tokukosho
There is one described in Publication No. 51-33630.

The device described in this publication introduces pressurized water by a pump into a carbonator tank pressurized with carbon dioxide gas to produce carbonated water, and the device is equipped with piping so that the carbonated water can be taken out from a weakly carbonated drink supply valve, and the supply valve In an apparatus configured such that carbonated water taken out from the pump is diluted with pressurized water by the pump, piping is provided so that the carbonated water passes through a first check valve and the diluted water joins through a second check valve; A third check valve and an automatic flow regulator are sequentially provided in a dilution water passage through which pressurized water of the pump flows to the second check valve, and the pressure in the passage between the second check valve and the automatic flow regulator is A pressure switch is provided which senses a pressure P ₂ which is generated in the passage when the supply valve is opened higher than a pressure P ₁ in the carbonator tank so as to control the operation of the pump. The pump is then controlled to start, and the pump is controlled to stop at a pressure _P3 that is higher than the pressure _P2 and lower than the pressure trapped in the passage when the supply valve is closed.

The above-mentioned known device discharges strongly carbonated water, in which the carbonated water made in the carbonator tank is directly discharged from the discharge pipe of the supply valve without mixing dilution water, and weakly carbonated water mixed with dilution water is discharged. It is designed so that it can be switched freely depending on the situation. Also, although many check valves are used in this known device,
These check valves have an extremely complex structure with the functions of preventing dilution water from flowing to the strongly carbonated water supply valve and carbon dioxide gas from flowing back into the pump and water pipes. .

Because of this complex configuration, there are many opportunities for failure to occur, and a check valve is provided on the discharge side of the pump to prevent carbon dioxide from flowing back into the pump or water supply even if other check valves fail. There is a problem in that it is necessary to prevent this from happening.

Furthermore, there is a device shown in FIG. 1 that does not use a check valve at all.

In this figure, 1 is a water bath and cooling water 2
It is cooled by a refrigerant passing through an evaporator (not shown).

3 is a cooling coil, which pressurizes water in a reservoir tank 4 to about 10 kg/cm ² by a water supply pump 5, passes it through the cooling coil 3, and supplies it to one mouth of a three-way solenoid valve 6.

The other port of the solenoid valve 6 is the carbonator tank 7.
It is connected to a water supply pipe 8 that supplies fresh water to the drain, and the remaining port is connected to one end of a communication pipe 9.

Further, the carbonator tank 7 is connected with a supply pipe 11 for carbon dioxide gas at a pressure of about 3.5 kg/cm ² supplied from a carbon dioxide gas cylinder 10 and a carbonated water take-out pipe 12, and this take-out pipe 12 is connected to a two-way electromagnetic It is connected to the other end of the communication pipe 9 via a valve 13. Further, a drinking water dispensing pipe 14 is connected to the communication pipe 9.

In the conventional device described above, the pressure of fresh water supplied to the carbonator tank 7 is set at approximately 10 kg/cm ² because the inside of the tank 7 is pressurized to approximately 3.5 kg/cm ² by carbon dioxide gas, and A level detector is installed in the tank 7 to control the pump 5 to keep the water level constant so that a fixed amount of carbon dioxide gas at a constant pressure is present in the upper part of the tank 7. Constant flow valves 15 and 16 are provided.

Further, although not shown, a syrup tank is provided in the water bath 1, and syrup is mixed with the water discharged from the discharge pipe 14 by a circuit not shown.

In the case of the conventional device as described above, when a fresh water dispensing signal is input, the three-way solenoid valve 6 switches for a certain period of time to connect the communication pipe 9 to the cooling coil 3 and to cut off the communication pipe 9 from the water supply pipe 8. , the solenoid valve 13 closes, and the pump 5 rotates. As a result, fresh water that does not pass through the carbonator tank 7 is transferred to the constant flow valve 1.
The pressure is reduced at step 5 and flows into the tap 17 from the discharge pipe 14, and after a certain period of time, the cooling coil 3 is cut off from the communication pipe 9 and becomes in communication with the water supply pipe 8.

When dispensing carbonated water, as described above, the three-way solenoid valve 6 keeps the communication pipe 9 isolated from the cooling coil 3, and the solenoid valve 13 opens for a certain period of time, so that the carbonated water in the carbonator tank 7 tank 7
Extruded by the internal pressure, the extraction pipe 12 → solenoid valve 1
3→Flows through the communication pipe 9 and is depressurized by the constant flow valve 16,
It flows into the tap 17 from the dispensing pipe 14.

The operation of the conventional device shown in FIG. 1 is as described above, and requires one three-way solenoid valve 6, one two-way solenoid valve 13, and two constant flow valves 15, 16.
There are also problems such as the circuit being complicated.

In order to solve the problems of the conventional device as described above, this invention has a communication pipe that connects the water supply pipe leading to the carbonator tank and the carbonated water take-out pipe leading to the carbonator tank, and the outlet of the cooling coil. and the delivery pipe are connected to a three-way solenoid valve, and the solenoid valve allows only the cooling coil and delivery pipe to communicate, and the delivery pipe is cut off from the communication pipe, and the cooling coil is cut off from the delivery pipe. At the same time, the cooling coil can be freely switched between communicating with the communication pipe and cutting off the cooling coil from the discharge pipe and the communication pipe and communicating the discharge pipe and the communication pipe, and connecting the cooling coil with the water supply pump and the carbonator tank. A check valve to prevent backflow to the water supply pump provided in the water supply pipe is provided in the water supply pipe between the communication pipe and the carbonator tank, and a check valve to prevent backflow to the carbonator tank is also provided in the carbonated water extraction pipe. , the discharge pipe is provided with a constant flow valve.

Since this device has the above-mentioned configuration, when the solenoid valve is switched to connect only the cooling coil and the discharge pipe and cut off the discharge pipe from the communication pipe, and the water supply pump is operated, fresh water cooled by the cooling coil is discharged. discharged from the tube.

Next, when the solenoid valve is switched so that the cooling coil is cut off from the discharge pipe and the cooling coil is communicated with the communication pipe, the discharge of fresh water from the discharge pipe is stopped. Also, when the pump is operated in this state, water is supplied to the carbonator tank.

Further, when the solenoid valve is switched so as to cut off the cooling coil from the delivery pipe and the communication pipe and to make the delivery pipe and the communication pipe communicate with each other, the carbonated water in the carbonator tank is delivered from the delivery pipe by the pressure inside the tank.

An embodiment of this invention will be described below in detail with reference to FIG.

In this case, the cooling coil 3 is connected to one port of the three-way solenoid valve 6, and the other port is connected to a communication pipe that communicates the water supply pipe 8 and the carbonated water extraction pipe 12,
The water supply pipe 8 is provided with a check valve 18 that allows water to pass only in the direction of the tank 7, and the take-out pipe 12 is provided with a check valve 19 that blocks water from flowing back in the direction of the tank 7.

Further, a discharge pipe 14 having a constant flow valve 20 is provided at the remaining port of the solenoid valve 6. Other parts are first
Same as the figure.

In the embodiment described above, the discharge of fresh water is switched for a certain period of time so that the solenoid valve 6 communicates the cooling coil 3 and the discharge pipe 14 and cuts off the cooling coil 3 from the communication pipe leading to the pipes 8 and 12. Water pressurized by the pump 5 is cooled by the cooling coil 3, passes through the solenoid valve 6, and enters the constant flow valve 2.
The pressure is reduced to 0, and it flows into the tap 17 from the delivery pipe 14.

After that, the solenoid valve 6 connects the cooling coil 3 to the pipe 8,
By connecting the cooling coil 3 and the dispensing pipe 14 to the communication pipe 12, dispensing of fresh water is stopped. Further, when the water supply pump 5 is operated in this state, water is supplied to the tank 7.

Next, when the solenoid valve 6 is switched so that the cooling coil 3 is cut off from the communication pipe communicating with the pipes 8 and 12 and the discharge pipe 14, and the communication pipe communicating with the pipes 8 and 12 is connected to the discharge pipe 14, the carbonator tank 7 The carbonated water in the tank opens the check valve 19 of the take-out pipe 12 due to the pressure in the same tank, passes through the solenoid valve 6, and passes through the constant flow valve 2.
The pressure is reduced to 0 and the liquid is injected into the pot 17 from the dispensing pipe 14.

In this embodiment, the check valve 18 allows carbonated water to come out only from the take-out pipe 12 when dispensing carbonated water, and the check valve 19 allows fresh water to flow out from the tank 7.
This prevents fresh water from flowing into the take-out pipe 12 when the water is supplied to the outlet pipe 12.

The structure of this invention is extremely simple because fresh water or carbonated water can be freely dispensed by simply installing one three-way solenoid valve and two check valves in the piping as described above. In addition, since it is only necessary to control one solenoid valve, the control circuit is simple, and since there is only one constant flow valve, adjustment is easy, and since both fresh water and carbonated water pass through the same flow rate adjustment valve, the water supply This has the advantage of eliminating the need for adjustment when the cycle of the power source for the pump drive motor changes or for changes in the pressure of carbon dioxide gas.

[Brief explanation of the drawing]

Figure 1 is a circuit diagram of a conventional drinking water dispensing device;
The figure is a circuit diagram showing an embodiment of the drinking water dispensing device of this invention. 1... Water bath, 2... Water, 3... Cooling coil, 5... Water supply pump, 6... 3-way solenoid valve, 7... Carbonator tank, 8... Water supply pipe, 11... Carbon dioxide gas Supply pipe, 12... carbonated water take-out pipe, 14... discharge pipe, 18, 19... check valve, 20... constant flow valve.

Claims (1)

[Scope of utility model registration request] A cooling coil and a carbonator tank are installed in a water bath filled with cooling water, and there are cases in which the cooled water is directly discharged from the dispensing pipe through the cooling coil, and in other cases, it is poured into the carbonator tank to make carbonated water and then discharged from the dispensing pipe. A check valve is installed in the middle of the water supply pipe that connects the water supply pump and the carbonator tank to prevent backflow to the water supply pump, and the water supply pressure from the water supply pump is set higher than the pressure inside the carbonator tank. In the drinking water vending machine, a communication pipe that connects a water supply pipe leading to the carbonator tank and a carbonated water take-out pipe leading to the carbonator tank, an outlet of the cooling coil, and the discharge pipe are connected to each other. When connected to a side solenoid valve, this solenoid valve can be used to communicate only the cooling coil and the delivery pipe and to cut off the delivery pipe from the communication pipe, or to cut off the cooling coil from the delivery pipe and to connect the cooling coil to the communication pipe. The cooling coil can be freely switched between connecting the cooling coil with the discharge pipe and the communication pipe, and connecting the discharge pipe and the communication pipe with each other. The check valve for preventing backflow is provided in the water supply pipe between the communication pipe and the carbonator tank, and the check valve for preventing backflow to the carbonator tank is also provided in the carbonated water take-out pipe, and the check valve is provided in the discharge pipe. Drinking water dispensing device equipped with a flow valve.