JP6727808B2 - Beverage supply device - Google Patents

Description

The present invention relates to a beverage supply device that supplies drinking water.

As a beverage supply device capable of supplying water and carbonated water as drinking water, for example, Japanese Patent Laid-Open No. 9-267896 discloses a cold water tank for storing water and carbon dioxide gas for the water supplied from the cold water tank. And a carbonation tank that generates carbonated water by adding the above, and that delivers water as drinking water from the cold water tank and delivers carbonated water as drinking water from the carbonation tank.

Further, generally, in a beverage supply device, it is necessary to sterilize periodically, and as a sterilization method of a beverage supply device capable of supplying water as drinking water, Japanese Patent Application Laid-Open No. 2013-180803 discloses that hot water is passed through a pipeline. A technique for sterilizing the pipeline by flowing it is described.

JP, 9-267896, A JP, 2013-180803, A

However, in a beverage supply device capable of supplying water and carbonated water as drinking water respectively like the present invention, when sterilizing the water supply path for supplying water from the cold water tank to the carbonation tank, hot water is passed through. It is inconvenient to let it sterilize. That is, if hot water is allowed to continuously flow through the water supply passage, hot water will also continuously enter the carbonation tank. Then, not only the amount of carbonated water in the tank becomes unnecessarily large, but also the carbonated water has a low carbon dioxide absorption rate due to the high temperature and carbonated water with a low carbonic acid content is generated, or the temperature of the carbonated water in the tank is raised. As a result, the quality of the carbonated water will be degraded, such as the carbonic acid being lost. As a result, the carbonated water in the tank is forced to be discarded, resulting in waste. Thus, an effective sterilization method suitable for the structure of the beverage supply device capable of supplying water and carbonated water as drinking water has not yet been considered.

Therefore, it is desired to realize a beverage supply device that can effectively sterilize a beverage supply device that can supply water and carbonated water as drinking water.

The beverage supply device according to the present invention,
A cold water tank for storing water,
A carbonation tank for generating carbonated water by adding carbon dioxide gas to the water supplied from the cold water tank through a water supply path, and a carbonated tank for storing the carbonated water,
A conduit heater provided in the water supply passage.

According to this configuration, the water in the water supply passage can be heated and sterilized by heating the water in the water supply passage with the heater for pipes. This makes it possible to heat and sterilize the water supply path without wasting the warm water and the carbonated water in the carbonation tank, which is caused by the hot water flowing through the water supply path. As described above, according to this configuration, the beverage supply device capable of supplying water and carbonated water as drinking water can be effectively sterilized.

Hereinafter, the suitable aspect of the beverage supply apparatus which concerns on this invention is demonstrated. However, the scope of the present invention is not limited by the preferred embodiments described below.

As one aspect, it is preferable that a heating device for a cold water tank that heats the water in the cold water tank is provided.

According to this configuration, it is possible to heat and sterilize the cold water tank by heating the water in the cold water tank with the cold water tank heating device.

As one aspect, it is preferable to include a cooler that cools the water in the cold water tank.

According to this structure, the water in the cold water tank can be cooled. In particular, when combined with a configuration including a cold water tank heating device, the hot water in the cold water tank after sterilization can be efficiently cooled.

As one aspect, it is preferable to include a heater for a carbonation tank that heats the carbonated water in the carbonation tank.

According to this configuration, the carbonated water in the carbonation tank can be heated to heat and sterilize the carbonation tank.

As one aspect, a cold water tank side sterilization operation for performing heat sterilization using the cold water tank heating device and the conduit heater, and a carbonation tank side for heat sterilization using the carbonation tank heater It is preferable to include a control unit capable of switching between sterilization operation and execution.

According to this configuration, the cold water tank side sterilization operation and the carbonation tank side sterilization operation can be switched and separately executed.

As one aspect, it is preferable that the control unit executes the cold water tank side sterilization operation at a higher frequency than the carbonation tank side sterilization operation.

Since carbonated water generally has the effect of suppressing the growth of bacteria, the frequency of sterilization on the side of the carbonation tank may be somewhat less than that on the side of the cold water tank. On the other hand, according to this configuration, since the cold water tank side sterilization operation is executed at a higher frequency than the carbonation tank side sterilization operation, the sterilization operation can be performed at a frequency suitable for each.

Schematic diagram of beverage supply device Illustration of the beverage supply device in the cold water tank side sterilization operation Illustration of the beverage supply device in the cold water tank side sterilization operation Illustration of the beverage supply device in the cold water tank side sterilization operation Illustration of the beverage supply device in the sterilization operation on the carbonation tank side Illustration of the beverage supply device in the sterilization operation on the carbonation tank side

Embodiments of a beverage supply device according to the present invention, and a management method and a sterilization method thereof will be described with reference to the drawings. The beverage supply device according to the present embodiment generates a carbonated water 60 by adding carbon dioxide gas to the cold water tank 20 that stores water 50 and the water 50 that is supplied from the cold water tank 20 through the water supply passage 24. And a carbonation tank 30 for storing the carbonated water 60. Further, the beverage supply device includes a cold water tank heating device that heats the water 50 in the cold water tank 20, and a pipeline heater 25 provided in the water supply passage 24. This makes it possible to effectively sterilize the beverage supply device that can supply water and carbonated water as drinking water. Hereinafter, the beverage supply device according to the present embodiment will be described in detail.

[Basic configuration of beverage supply device]
As shown in FIG. 1, the beverage supply device according to the present embodiment mainly includes a water supply source 10, a cold water tank 20 that cools and stores water 50 supplied from the water supply source 10, and a cold water tank 20. A carbonation tank 30 that adds carbon dioxide gas to the supplied water 50 to generate carbonated water, and a hot water tank 40 that takes out a part of the water 50 in the cold water tank 20, heats it, and stores it.

The water supply source 10 supplies water 50 such as mineral water to the cold water tank 20. In the present embodiment, the water supply source 10 is illustrated as a container for storing mineral water, but the water supply source 10 may be a water supply or the like and is not particularly limited as long as the water 50 can be supplied to the cold water tank 20. In the present embodiment, the water supply source 10 is arranged above the cold water tank 20, and the water supply unit 11 provided at the bottom of the water supply source 10 is connected to the cold water tank 20. Then, the water 50 is supplied from the water supply source 10 to the cold water tank 20 via the water supply unit 11.

The cold water tank 20 has, as a cooler for cooling the water 50 in the cold water tank 20, a cooling coil 21 which is spirally arranged on the outer surface thereof and circulates a refrigerant therein by opening the electromagnetic valve 21a. The cooling coil 21 cools the water 50 supplied from the water supply source 10, and the cold water tank 20 stores the cooled water 50. A check valve 21b is provided in a part of the flow path of the used refrigerant to prevent the used refrigerant from flowing backward. The cold water tank 20 also includes a temperature sensor (not shown), and the temperature sensor detects the temperature of the water 50. The cold water tank 20 has a water delivery passage 22 for delivering the water 50 from the cold water tank 20 as drinking water, and by opening the electromagnetic valve 22 a provided in the water delivery passage 22, the cold water tank 20 is passed through the water delivery passage 22. Water 50 is provided from the inside. Further, the cold water tank 20 has a water supply passage 24 for supplying the water 50 to the carbonation tank 30, and by operating the high-pressure pump 24b provided in the water supply passage 24, the cold water tank 20 changes to the carbonation tank 30. Water 50 is supplied. A check valve 24c for preventing reverse flow of water 50 and carbon dioxide gas to the cold water tank 20 side is provided on the water supply passage 24 on the side of the carbonation tank 30 from the high pressure pump 24b.

The carbonation tank 30 is connected to a carbon dioxide gas cylinder 31 via a carbon dioxide gas supply passage 32. The carbon dioxide gas is supplied from the carbon dioxide gas cylinder 31 to the carbonation tank 30 by the opening operation of the solenoid valve 32a provided in the carbon dioxide gas supply passage 32, and the pressure is adjusted by a pressure adjusting valve (not shown) Is filled with carbon dioxide gas at a predetermined pressure. On the carbon dioxide gas cylinder 31 side of the carbon dioxide gas supply passage 32 from the solenoid valve 32a, a check valve 32b for preventing the reverse flow of carbon dioxide gas to the carbon dioxide gas cylinder 31 side is provided. Further, a bypass passage 33, in which a safety valve 33a is interposed, is connected to the carbon dioxide tank 30 side of the carbon dioxide gas supply passage 32 from the opening/closing valve 32a, and when the internal pressure of the carbonation tank 30 rises above a prescribed value, the bypass passage Carbon dioxide gas escapes from the carbonation tank 30 via 33, thereby lowering the internal pressure and ensuring safety.

The carbonation tank 30 is connected to the water supply passage 24 from the cold water tank 20, and the carbon dioxide supplied from the carbon dioxide supply passage is added to the water 50 supplied from the water supply passage to generate the carbonated water 50. Store carbonated water. More specifically, the water 50 supplied from the water supply passage 24 is atomized into the carbonation tank 30 via the spray nozzle 34. The water 50 sprayed from the spray nozzle 34 absorbs carbon dioxide gas in the carbonation tank 30 to generate carbonated water 60. The carbonation tank 30 has a carbonated water delivery passage 26 for delivering the carbonated water 60 as drinking water from the carbonation tank 30, and the carbonated water 60 is provided from the carbonated water delivery passage 26 by opening the solenoid valve 26a. It Since the internal pressure of the carbonation tank 30 is high, if the electromagnetic valve 26a provided in the carbonated water delivery passage 26 is opened, the carbonated water is discharged from the inside of the carbonation tank 30 via the carbonated water delivery passage 26 due to the pressure difference. 60 is provided. The end of the carbonated water delivery path 26 on the side of the carbonation tank 30 is extended to near the bottom of the carbonation tank 30 so that the carbonated water 60 in the tank can be delivered to the limit. Further, the carbonation tank 30 has a water level sensor 35 for measuring the water level of the carbonated water 60, and when the water level sensor 35 detects a decrease in the water level, the high pressure pump 24b is activated so that the water 50 flows into the carbohydrate. The carbonated water 60 is newly generated by being sprayed into the nation tank 30 (in FIG. 1, the carbonated water 60 is taken out by opening the solenoid valve 26a, and the water level sensor 35 detects a decrease in the water level and the high pressure The state where the pump 24b is operating and the carbonated water 60 is newly generated is shown).

Further, the carbonation tank 30 is provided as a cooler for cooling the carbonated water 60 in the carbonation tank 30 in a spiral shape on the outer surface thereof, and has a cooling coil 36 for circulating a refrigerant therein by opening the solenoid valve 36a. Have. A check valve 36b is provided in a part of the flow path of the used refrigerant to prevent the used refrigerant from flowing backward. Further, the carbonation tank 30 includes a heater (corresponding to a carbonation tank heater) 37 that heats the carbonated water 60 in the carbonation tank 30. When the carbonated water 60 is heated by the heater 37, a considerable amount of carbonic acid is removed from the carbonated water 60. For this reason, a second bypass passage 38 is provided in the carbon dioxide gas supply passage 32, and by opening the solenoid valve 38a, carbon dioxide generated when the carbonated water 60 is heated is released to the outside from the second bypass passage 38. Is done.

The hot water tank 40 is for storing the hot water 70 as drinking water, and also for storing the hot water 70 for sterilizing the hot water in the cold water tank 20. The warm water tank 40 includes a heater (corresponding to a warm water tank heater) 41 that heats the water in the warm water tank 40, a second water supply passage 42 that supplies the water 50 in the cold water tank 20 to the warm water tank 40, A hot water supply passage 43 for supplying the hot water 70 in the hot water tank 40 to the cold water tank 20. The hot water supply passage 43 includes an electromagnetic valve 43a and a hot water circulation pump 43b. In the hot water tank 40, in the sterilization process of the cold water tank 20 described later, the water 50 in the cold water tank 20 is sent to the hot water tank 40 via the second water supply passage 42, and the hot water tank 40 is stored in the hot water tank 40 as much as the water 50 is received. The hot water 70 is sent to the cold water tank 20 through the hot water supply passage 43. In parallel with this, the heater 41 heats the water (the water 50 and the hot water 70) in the hot water tank 40 including the water 50 received from the cold water tank 20. That is, the water 50 in the cold water tank 20 can be circulated through the second water supply path 42, the hot water tank 40, and the hot water supply path 43 while heating the water (the water 50 and the hot water 70) by the heater 41. .. By continuing this, the water 50 in the cold water tank 20 is substantially heated by the heater 41, and the cold water tank 20 can be filled with the hot water 70. Thus, the hot water tank 40, the heater 41, the second water supply passage 42, and the hot water supply passage 43 function as a cold water tank heating device that heats the water 50 in the cold water tank 20. By heating the cold water tank 20, the cold water tank 20 can be sterilized. Further, in the present embodiment, since the hot water 70 in the hot water tank 40 can be used to heat the water 50 in the cold water tank 20, the water in the cold water tank 20 can be efficiently heated. The hot water tank 40 is provided with a hot water delivery path 44 for delivering the hot water 70 from the hot water tank 40 as drinking water, and by opening an electromagnetic valve 44a provided in the hot water delivery path 44, the hot water 70 is removed from the hot water tank 40. It is possible to provide.

Further, the beverage supply device of the present embodiment is provided with a bypass passage 27 that connects the water supply passage 24 and the carbonated water delivery passage 26. Further, an electromagnetic valve 24a is provided on the upstream side of the bypass passage 27 of the water supply passage 24. As a result, the carbonated water delivery passage 26, the bypass passage 27, and the water supply passage 24 function as a circulation passage for circulating the carbonated water 60 in the carbonation tank 30, and the high pressure pump 24b is operated with the electromagnetic valve 24a closed. By operating, the carbonated water 60 in the carbonation tank 30 circulates through the carbonated water delivery passage 26, the bypass passage 27, and the water supply passage 24.

Further, in the beverage supply device of the present embodiment, the pipe heater 25 is provided in the water supply passage 24. Specifically, one is provided on each of the upstream side and the downstream side of the check valve 24c. By heating the water in the water supply passage 24 by operating the pipe heater 25, the water supply passage 24 can be heat-sterilized.

The beverage supply device has a control unit (not shown) and switches and timers (not shown) for various operations, and the control unit performs operation of each switch of each unit of the beverage supply device and operation described later according to the timer. It is like this. The detection signals of the temperature sensor, the pressure sensor, and the water level sensor 35 described above are sent to the control unit, and the control unit executes the operation of each unit corresponding to the detection result.

Next, the operation of this beverage supply device will be described with reference to the drawings. 2 to 6, the solenoid valves in the open state are colored. First, the preparatory operation before use will be described.

[Preparatory operation]
For example, the preparatory operation is started by pressing a main switch (not shown) of the beverage supply device. First, in the preparatory operation, water 50 is supplied from the water supply source 10 to the cold water tank 20 in the preparatory operation. When the cold water tank 20 is filled with water 50, cooling by the cooling coil 21 is started, and the water 50 in the cold water tank 20 is cooled to a set temperature (5 to 10° C. or the like). Further, in parallel with the supply and cooling of the water 50, the electromagnetic valve 32a of the carbon dioxide gas supply passage 32 is opened, the supply of carbon dioxide gas to the carbonation tank 30 is started, and the internal pressure of the carbonation tank 30 is equal to or higher than a predetermined value. Carbon dioxide gas is supplied to the carbonation tank 30 until it becomes. The lower the temperature of water and the higher the pressure of carbon dioxide, the higher the absorption rate of carbon dioxide with respect to the water. Therefore, the water 50 is cooled to the set temperature and the internal pressure of the carbonation tank 30 reaches a predetermined value. When the temperature rises, the high-pressure pump 24b operates and the cooled water 50 (water) is sprayed into the carbonation tank 30. By supplying water 50 to the carbonation tank 30 filled with carbon dioxide under high pressure, and further atomizing it, the contact area of the water 50 with carbon dioxide increases, and as a result, it is effective. Carbonated water 60 is generated in the. Then, the carbonated water 60 is generated until reaching a predetermined water level. Further, by opening the electromagnetic valve 43a and activating the hot water circulation pump 43b, the water 50 in the cold water tank 20 is supplied to the hot water tank 40 via the second water supply passage 42, and the hot water tank 40 is supplied with the water 50. After filling with, the heating by the heater 41 is performed thereafter. When the temperature is detected by a temperature sensor (not shown) and the temperature is raised to a predetermined temperature (for example, 80° C.) or higher, the heating by the heater is stopped and the preparatory operation is completed.

〔Normal operation〕
After the completion of the preparatory operation, the normal operation state is entered, for example, by pressing the switch for supplying water, the water 50 is provided from the water delivery path 22, and by pressing the switch for supplying carbonated water, the carbonated water delivery path 26 is supplied. The carbonated water 60 is provided from the above, and the hot water 70 is provided from the hot water delivery passage 44 by pressing the switch for supplying the hot water. Further, in the normal operation state, the water 50 in the cold water tank 20, the carbonated water 60 in the carbonation tank 30, and the hot water 70 in the hot water tank 40 are detected by a temperature sensor (not shown) so as to be maintained within a predetermined temperature range. Depending on the temperature to be applied, the cooling by the cooling coils 21 and 36 and the heating by the heater 41 are performed at any time. Further, in order to prevent the carbonated water 60 from being desorbed, carbon dioxide gas is supplied into the carbonation tank 30 by a pressure adjusting valve (not shown) so that the internal pressure in the carbonation tank 30 is maintained within a predetermined pressure range.

In addition, for example, when a predetermined switch is operated, the carbonated water 60 in the carbonation tank 30 is recharged with carbonic acid again. Specifically, the high pressure pump 24b is operated in a state where the carbon dioxide gas is supplied from the carbon dioxide gas supply passage 32 to the carbonation tank 30 and the electromagnetic valve 24a is closed. Thus, the carbonated water 60 in the carbonation tank 30 is circulated through the carbonated water delivery passage 26, the bypass passage 27, and the water supply passage 24, and carbon dioxide gas is added to the carbonated water 60 again. By doing so, the carbonated water 60 can be efficiently made to contain carbonic acid.

[Sterilization operation]
The control unit periodically performs a sterilization operation at a time interval that is set in advance by a timer. Specifically, the control unit performs heat sterilization by using the warm water tank 40 as a heating device for the cold water tank, the heater 41, the second water supply path 42 and the warm water supply path 43, and the conduit heater 25. The cold water tank side sterilization operation to be performed and the carbonation tank side sterilization operation for performing heat sterilization using the heater 37 are switched to be executable, and the cold water tank side sterilization operation and the carbonation tank side sterilization operation are performed as sterilization operations. Is done. Then, the control unit executes the cold water tank side sterilization operation at a higher frequency than the carbonation tank side sterilization operation. This is because the carbonated water 60 generally has the effect of suppressing the growth of bacteria, and therefore the frequency of sterilization on the side of the carbonation tank 30 may be less than that on the side of the cold water tank 20. It is also possible to provide a switch for each sterilization operation and perform each sterilization operation by operating the switch. First, the cold water tank side sterilization operation will be described with reference to FIGS.

[Cold water tank side sterilization operation]
In the cold water tank side sterilization operation, first, as shown in FIG. 2, the electromagnetic valve 43a of the hot water supply passage 43 is opened, and the hot water circulation pump 43b is activated to send the hot water 70 from the hot water tank 40 to the cold water tank 20. Then, the water 50 is sent from the cold water tank 20 to the hot water tank 40. Then, at the same time, the heater 41 also operates, and in parallel, the heater 41 heats the water in the hot water tank 40 including the water 50 received from the cold water tank 20. As a result, the water (water 50 and hot water 70) circulates between the cold water tank 20 and the hot water tank 40 while being heated by the heater 41, and accordingly, the water 50 in the cold water tank 20 is substantially heated. The temperature of water in the cold water tank 20 rises. Further, the pipe heater 25 is operated to heat the water 50 in the water supply passage 24. At this time, as described in the normal operation, the carbonation tank 30 is kept at a high internal pressure in order to prevent the carbonated water 60 from desorbing carbonic acid, so that the water 50 heated from the water supply passage 24 is heated in the carbonation tank. It does not flow into 30.
By performing this operation to some extent, as shown in FIG. 3, the water temperature in the cold water tank 20 and the water supply passage 24 sufficiently rises (for example, 80° C.). Then, by maintaining this state for a certain period of time, the cold water tank 20 and the water supply passage 24 are heat-sterilized. After sterilization, as shown in FIG. 4, the heater 41 and the conduit heater 25 are stopped, and the refrigerant is circulated in the cooling coil 21 to cool the hot water 70 in the cold water tank 20. The water supply passage 24 is naturally cooled. As a result, the cold water tank side sterilization operation ends. As described above, in the beverage supply device of the present embodiment, the water supply passage 24 that supplies the water 50 to the carbonation tank 30 can be sterilized.

[Carbonation tank tank side sterilization operation]
In the sterilization operation on the carbonization tank side, first, the electromagnetic valve 32a of the carbon dioxide gas supply passage 32 is closed to interrupt the supply of carbon dioxide gas, and then the heater 37 is operated to heat the carbonated water 60. At this time, since a considerable amount of carbonic acid is released from the carbonated water 60, the electromagnetic valve 38a is opened to allow the generated carbon dioxide gas to escape from the second bypass passage 38 to the outside. Then, when the carbonated water 60 has warmed to some extent, the high pressure pump 24b is operated with the carbonated water 60 in the carbonation tank 30 being heated by the heater 37 and with the solenoid valve 24a closed. As a result, the heated carbonated water 60 (warm water 70) in the carbonation tank 30 is circulated through the carbonated water delivery passage 26, the bypass passage 27, and the water supply passage 24. By continuing this for a predetermined time, the carbonation tank 30, the carbonated water delivery passage 26, the bypass passage 27, and the water supply passage 24 are heat-sterilized.

After the sterilization, the heater 37 and the high-pressure pump 24b are stopped, the refrigerant is circulated in the cooling coil 36, and the carbonated water 60 (warm water 70) in the carbonation tank 20 is cooled by the cooling coil 36. After the sterilization, the carbonated water 60 in the carbonation tank 30 is in a state in which the carbonated water has been depleted by heating, so after the carbonated water 60 in the carbonation tank 20 is cooled, the carbonated water 60 is added again Drive. Specifically, the high-pressure pump 24b is operated with the solenoid valve 32a opened and the carbon dioxide gas supplied from the carbon dioxide gas supply passage 32 to the carbonation tank 30, and with the solenoid valve 24a closed. Thus, the carbonated water 60 in the carbonation tank 30 is circulated through the carbonated water delivery passage 26, the bypass passage 27, and the water supply passage 24, and carbon dioxide gas is added to the carbonated water 60 again. As a result, the sterilization operation on the side of the carbonation tank is completed. As described above, in the beverage supply device according to the present embodiment, not only the carbonation tank 30, but also the carbonated water delivery passage 26, the bypass passage 27, and the water supply passage 24 can be heat-sterilized. Sterilization can be performed by efficiently utilizing the device configuration. Further, although heating the carbonated water 60 causes the carbonate to escape from the carbonated water 60, it is possible to efficiently add the carbonate again.

[Other Embodiments]
In the above-described embodiment, a configuration in which the hot water tank 40, the heater 41, the second water supply passage 42, and the hot water supply passage 43 are used as a heating device for a cold water tank that heats the water 50 in the cold water tank 20 will be described as an example. did. However, the embodiment of the present invention is not limited to this. The heating device for the cold water tank may be a heater that directly heats the cold water tank 20 and can be appropriately changed.

In addition, it should be understood that the embodiments disclosed in the specification are exemplifications in all respects, and the scope of the present invention is not limited thereby. Those skilled in the art will easily understand that appropriate modifications can be made without departing from the spirit of the present invention. Therefore, other embodiments modified without departing from the spirit of the present invention are naturally included in the scope of the present invention.

INDUSTRIAL APPLICABILITY The present invention can be used, for example, to sterilize a beverage supply device.

20 Cold water tank 21 Cooling coil (cooler)
22 Water Delivery Channel 24 Water Supply Channel 25 Pipe Heater 30 Carbonation Tank 37 Heater (Carbonation Tank Heater)
40 Hot water tank (heating device for cold water tank)
41 Heater for hot water tank (heater for cold water tank)
42 Second water supply channel (heating device for cold water tank)
43 Hot water supply channel (heating device for cold water tank)
44 Hot water delivery path 50 Water 60 Carbonated water 70 Hot water

Claims (6)

A cold water tank for storing water,
A carbonation tank for generating carbonated water by adding carbon dioxide gas to the water supplied from the cold water tank through a water supply path, and a carbonated tank for storing the carbonated water,
A beverage supply device comprising: a heater for a pipe provided in the water supply passage. The beverage supply device according to claim 1, further comprising a cooler that cools the water in the cold water tank. The beverage supply device according to claim 1 or 2, further comprising a cold water tank heating device that heats the water in the cold water tank. The beverage supply device according to claim 1, further comprising a heater for a carbonation tank that heats the carbonated water in the carbonation tank. A cold water tank side sterilization operation for performing heat sterilization using the cold water tank heating device and the conduit heater, and a carbonation tank side sterilization operation for heat sterilization using the carbonation tank heater. The beverage supply device according to claim 4, which includes a control unit that can be switched and executed. The beverage supply device according to claim 5, wherein the control unit executes the cold water tank side sterilization operation at a higher frequency than the carbonation tank side sterilization operation.

Images