JP2017105489A - Beverage supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To simplify cleaning of a beverage supply path in a beverage supply device.SOLUTION: A beverage supply device 10 is applied to a beverage dispenser providing a beverage to a cup C, and has a beverage supply path supplying a milk beverage to the cup C. The device has a cleaning part 60 which generates a cleaning liquid, when a cleaning directive is issued, by mixing a cleaning stock solution supplied from a cleaning stock solution storage parts 66, 67, and a cleaning hot water supplied from a hot water tank 25; supplies the cleaning liquid to the beverage supply path made into a communication state; and then supplies the hot water supplied from the hot water tank 25 to the beverage supply path as a rinse hot water.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a beverage supply device, and more particularly to a beverage supply device that is applied to a beverage dispenser that provides a beverage to a beverage container and has a beverage supply path that supplies milk beverage to the beverage container. .

  2. Description of the Related Art Conventionally, in a beverage dispenser that provides a coffee beverage such as cappuccino, for example, as proposed in Patent Document 1, for example, a beverage dispenser having a beverage supply path for supplying a milk beverage such as milk is known. ing.

Japanese Patent No. 5242907

  By the way, although not explicitly indicated in the cited reference 1 described above, when the beverage supply path is washed, a milk beverage storage section for storing milk beverages such as milk is separated from the beverage supply path, and a desired concentration is obtained in advance. A cleaning liquid reservoir for storing the diluted cleaning liquid is connected to the beverage supply path. Accordingly, the cleaning liquid is supplied from the cleaning liquid storage unit to the beverage supply path. After the supply of the cleaning liquid is completed, the cleaning liquid storage unit is disconnected from the beverage supply path, and the rinse water storage unit that stores the rinse water is connected to the beverage supply path. As a result, the rinse water is supplied from the rinse water storage section to the beverage supply path, whereby the cleaning liquid is washed away from the beverage supply path, and the beverage supply path is cleaned.

  However, in the washing of the beverage supply path as described above, the milk beverage storage part must be disconnected from the beverage supply path, and then the cleaning liquid storage part must be connected and disconnected, and the rinse water storage part must be connected and disconnected. The cleaning work was complicated. In particular, in the cleaning of the beverage supply path, it is common to first pass the alkaline cleaning liquid and then the acidic cleaning liquid, and the complication of the cleaning operation is more remarkable.

  An object of this invention is to provide the drink supply apparatus which can perform the washing | cleaning of a drink supply path | route easily in view of the said situation.

  In order to achieve the above object, a beverage supply apparatus according to the present invention is applied to a beverage dispenser that provides a beverage to a beverage container, and has a beverage supply path that supplies milk beverage to the beverage container. When a cleaning instruction is given, the cleaning stock solution supplied from the cleaning stock solution storage unit storing the cleaning stock solution and the hot water storage unit storing hot water for generating pressurized steam constituting the milk beverage are supplied. Washing water that is hot water is mixed to produce a cleaning liquid, the cleaning liquid is supplied to the beverage supply path that is in communication, and then the hot water supplied from the hot water storage unit is used as rinsing hot water to the beverage supply path. It is characterized by comprising a cleaning unit for supplying to the slab.

  In the beverage supply apparatus according to the present invention, the cleaning unit mixes the alkaline cleaning stock solution supplied from the cleaning stock solution storage unit with the cleaning hot water to generate an alkaline cleaning solution, and enters the communication state. After supplying the alkaline cleaning liquid to the beverage supply path, the rinsing hot water is supplied, and then, the acidic cleaning stock solution supplied from the cleaning stock solution storage unit and the cleaning hot water are mixed to generate an acidic cleaning liquid. The rinse water is supplied after supplying the acidic cleaning liquid to the beverage supply path.

  In the beverage supply apparatus according to the present invention, the cleaning unit intermittently supplies the cleaning liquid to the beverage supply path.

  According to the present invention, when a cleaning instruction is given, the cleaning unit stores the cleaning stock solution supplied from the cleaning stock solution storage unit that stores the cleaning stock solution, and hot water that generates pressurized steam constituting the milk beverage. The hot water supplied from the hot water storage section is mixed with the hot water supplied from the hot water storage section to produce a cleaning liquid, and the cleaning liquid is supplied to the beverage supply path that is in communication, and then the hot water supplied from the hot water storage section is used as the rinse water Since it is supplied to the beverage supply path, it is not necessary to connect and disconnect the cleaning liquid storage section and connection and disconnection of the rinse water storage section as in the prior art, and the beverage supply path is cleaned simply by giving a cleaning command. Can do. Therefore, the beverage supply path can be easily cleaned.

FIG. 1 is a perspective view of a beverage dispenser to which a beverage supply device according to an embodiment of the present invention is applied. FIG. 2 is a schematic diagram schematically showing the configuration of the beverage supply apparatus according to the embodiment of the present invention. FIG. 3 is a side view showing the mixing container shown in FIG. FIG. 4 is a perspective view showing the mixing container shown in FIG. FIG. 5 is a longitudinal sectional view of the mixing container shown in FIGS. 3 and 4. FIG. 6 is a plan view of the mixing container shown in FIGS. 3 and 4. FIG. 7 is a flowchart showing the processing content of the cleaning control processing performed by the control unit. FIG. 8 is a flowchart showing the processing contents of the pre-rinsing process shown in FIG. FIG. 9 is a flowchart showing the contents of the alkali cleaning process shown in FIG. FIG. 10 is a flowchart showing the processing contents of the alkaline cleaning liquid supply processing shown in FIG. FIG. 11 is a flowchart showing the processing contents of the alkaline cleaning rinsing processing shown in FIG. FIG. 12 is a flowchart showing the contents of the acid cleaning process shown in FIG. FIG. 13 is a flowchart showing the contents of the acid cleaning liquid supply process shown in FIG. FIG. 14 is a flowchart showing the contents of the acid cleaning rinsing process shown in FIG. FIG. 15 is a flowchart showing the processing contents of the finishing rinse process shown in FIG.

  Exemplary embodiments of a beverage supply device according to the present invention will be described below in detail with reference to the accompanying drawings.

  FIG. 1 is a perspective view of a beverage dispenser to which a beverage supply apparatus according to an embodiment of the present invention is applied, and FIG. 2 is a schematic diagram schematically showing a configuration of the beverage supply apparatus according to an embodiment of the present invention. FIG. The beverage dispenser 1 illustrated here provides a coffee beverage to a cup C (see FIG. 2) which is a beverage container.

  The beverage supply device 10 according to the present embodiment is applied to the beverage dispenser 1 and supplies milk, which is a milk beverage, to the cup C in a foamed state. The beverage supply device 10 includes a vapor supply unit 20, a stock solution supply unit 30, an air supply unit 40, a mixing unit 50, a forming unit 52, a nozzle unit 54, and a cleaning unit 60.

  The steam supply unit 20 includes a steam tank 21, a first steam supply pipe 22, and a second steam supply pipe 23. The steam tank 21 is connected to the hot water tank 25 through the hot water supply pipe 24. Here, the hot water tank 25 is a storage part for storing hot water, and heats water supplied from a water supply means (not shown) and stores it as hot water. The hot water supply pipe 24 has one end connected to the hot water tank 25 and the other end connected to the steam tank 21, and connects the hot water tank 25 and the steam tank 21. A hot water supply pump 24 a is provided in the middle of the hot water supply pipe 24. The hot water supply pump 24a is driven by a command given from the control unit 100 (see FIG. 2), and supplies hot water from the hot water tank 25 to the steam tank 21 when driven.

  The control unit 100 comprehensively controls the operation of each unit of the beverage supply device 10 according to a program and data stored in a memory (not shown).

  The steam tank 21 generates pressurized steam by heating the hot water supplied from the hot water tank 25 through the hot water supply pipe 24. Thereby, the hot water tank 25 stores hot water that generates pressurized steam.

  The first steam supply pipe 22 has one end connected to the steam tank 21 and the other end connected to the mixing unit 50, and connects the steam tank 21 and the mixing unit 50. In the middle of the first steam supply pipe 22, a first steam supply valve 22a and a first steam check valve 22b are arranged. The first steam supply valve 22a opens and closes according to a command given from the control unit 100. When the first steam supply valve 22a is opened, the pressurized steam is allowed to pass through the first steam supply pipe 22. The first steam supply valve 22a restricts the passage of pressurized steam through the first steam supply pipe 22 when closed. The first steam check valve 22 b allows passage of fluid (pressurized steam) from the steam tank 21 to the mixing unit 50, while restricting passage of fluid from the mixing to the steam tank 21.

  One end of the second steam supply pipe 23 is connected to the steam tank 21, and the other end is connected to the first connection part 26 that can be connected to the stock solution supply part 30 and the cleaning part 60. The unit 26 is connected. Here, the first connection portion 26 is attached to one end of the liquid supply pipe 27 connected to the mixing portion 50. The liquid supply pipe 27 is provided with a liquid check valve 27a. The liquid check valve 27 a allows passage of fluid from the first connection portion 26 to the mixing portion 50, while restricting passage of fluid from the mixing portion 50 to the first connection portion 26.

  In the middle of the second steam supply pipe 23, a second steam supply valve 23a and a second steam check valve 23b are arranged. The second steam supply valve 23a opens and closes according to a command given from the control unit 100. When the second steam supply valve 23a is opened, the pressurized steam is allowed to pass through the second steam supply pipe 23. The second steam supply valve 23a restricts the passage of pressurized steam through the second steam supply pipe 23 when closed. The second steam check valve 23b allows passage of fluid (pressurized steam) from the steam tank 21 to the first connection portion 26, while restricting passage of fluid from the first connection portion 26 to the steam tank 21. Is.

  The stock solution supply unit 30 includes a bag-in-box (hereinafter also referred to as BIB) 31, a tube pump 32, and a second connection unit 33.

  The BIB 31 is configured by accommodating a bag-like container enclosing a milk beverage (foamed milk) supplied to the cup C (hereinafter also referred to as milk stock solution) in a box-like container. This BIB 31 is arranged in the cold storage of the beverage dispenser 1. Here, the cool box is a chamber having a heat insulating structure provided inside the dispenser main body 1 a of the beverage dispenser 1.

  The tube pump 32 is provided on the lower side of the BIB 31 inside the cool box. The tube pump 32 is driven by a command given from the control unit 100. In the case of driving, the tube 34 connected to the BIB 31 is crushed by a plurality of rollers and the milk solution of the BIB 31 is pumped. It is something to be issued. The second connection portion 33 is attached to the tip of the tube 34 connected to the BIB 31 and is a connector that can be connected to the first connection portion 26.

  The air supply unit 40 includes an air supply pipe 41. The air supply pipe 41 has one end connected to the air pump 42 and the other end connected to the mixing unit 50, and connects the air pump 42 and the mixing unit 50. The air pump 42 is driven in accordance with a command given from the control unit 100. When driven, the air pump 42 compresses air and sends out compressed air through the air supply pipe 41.

  In the middle of the air supply pipe 41, an air check valve 41a is disposed. The air check valve 41 a allows passage of fluid (compressed air) from the air pump 42 to the mixing unit 50, while restricting passage of fluid from the mixing unit 50 to the air pump 42.

  The mixing unit 50 mixes the pressurized steam supplied through the first steam supply pipe 22 and the milk stock solution supplied through the liquid supply pipe 27 to heat the milk stock solution, and further supplied through the air supply pipe 41. By mixing compressed air, a milk beverage in a slightly foamed state is produced.

  The forming unit 52 is connected to the mixing unit 50 via the beverage delivery pipe 51. The forming unit 52 is for foaming the milk beverage delivered from the mixing unit 50 through the beverage delivery tube 51.

  The nozzle part 54 is connected to the forming part 52 via a beverage outlet passage (not shown). This nozzle part 54 supplies the milk drink (milk-milk drink in a foamed state) sent from the forming part 52 through the beverage outlet passage to the cup C.

  Thus, in this Embodiment, the 1st connection part 26, the liquid supply pipe | tube 27, the mixing part 50, the drink delivery pipe | tube 51, the forming part 52, the drink extraction channel | path, and the drink supply path | route through which the nozzle part 54 supplies milk beverage Is configured.

  The cleaning unit 60 includes a mixing container 61, a first cleaning stock solution supply pipe 62, a second cleaning stock solution supply pipe 63, a cleaning liquid supply pipe 64 and a cleaning hot water supply pipe 65.

  3 and 4 show the mixing container 61 shown in FIG. 2, respectively. FIG. 3 is a side view and FIG. 4 is a perspective view. The mixing container 61 will be described with reference to FIGS. 3 and 4 as appropriate.

  The mixing vessel 61 has a bottomed cylindrical shape, and has a cylindrical side portion 61a and a conical shape whose central portion is the lowest in such a manner that its cross-sectional area gradually decreases as it goes downward. And a bottom portion 61b having a form. The upper surface opening of the mixing container 61 is closed by a lid 61c.

  One end of the first cleaning stock solution supply pipe 62 is connected to a first cleaning stock solution storage section 66 that stores an alkaline cleaning stock solution (hereinafter also referred to as alkaline cleaning stock solution), and the other end is connected to the side surface of the bottom 61 b of the mixing container 61. The first cleaning stock solution storage unit 66 and the mixing container 61 are connected. The 1st washing | cleaning stock solution accommodating part 66 is arrange | positioned at the washing | cleaning stock solution storage 110 provided separately from the drink supply apparatus 10. FIG.

  A first cleaning stock solution supply pump 62 a is disposed in the middle of the first cleaning stock solution supply pipe 62. The first cleaning stock solution supply pump 62a is driven by a command given from the control unit 100, and supplies the alkaline cleaning stock solution from the first cleaning stock solution storage unit 66 to the mixing container 61 when driven.

  One end of the second cleaning stock solution supply pipe 63 is connected to a second cleaning stock solution storage portion 67 that stores an acidic cleaning stock solution (hereinafter also referred to as acidic cleaning stock solution), and the other end is connected to the side surface of the bottom 61 b of the mixing container 61. The second cleaning stock solution storage unit 67 and the mixing container 61 are connected. Similar to the first cleaning stock solution storage unit 66, the second cleaning stock solution storage unit 67 is disposed in the cleaning stock solution storage 110.

  In the middle of the second cleaning stock solution supply pipe 63, a second cleaning stock solution supply pump 63a is disposed. The second cleaning stock solution supply pump 63a is driven by a command given from the control unit 100. When driven, the second cleaning stock solution supply pump 63a supplies the acidic cleaning stock solution from the second cleaning stock solution storage unit 67 to the mixing container 61.

  The cleaning liquid supply pipe 64 has one end connected to the mixing container 61 and the other end connected to the third connecting portion 68, and connects the mixing container 61 and the third connecting portion 68. Here, as shown in FIG. 5, one end of the cleaning liquid supply pipe 64 is connected to the mixing container 61 in a mode communicating with the discharge port 611 provided in the bottom 61 b of the mixing container 61. The third connection portion 68 is a connector that can be connected to the first connection portion 26.

  In the middle of the cleaning liquid supply pipe 64, a cleaning liquid pump 64a is disposed. The cleaning liquid pump 64a is driven by a command given from the control unit 100, and supplies liquid from the mixing container 61 to the third connection unit 68 when driven.

  One end of the hot water supply pipe 65 is connected to the hot water supply pipe 24 upstream of the hot water supply pump 24a. The other end of the cleaning water supply pipe 65 is branched into two, one is connected to the cleaning liquid supply pipe 64 upstream of the cleaning liquid pump 64a, and the other is connected to the side 61a of the mixing container 61. The mixing vessel 61 is connected to the upper hot water supply port 612 provided in the upper portion. Here, the hot water supply pipe 65 communicating with the upper hot water supply port 612 extends in a substantially tangential direction of the side portion 61a of the mixing container 61 at the upper hot water supply port 612, as shown in FIG.

  A cleaning water pump 65 a is disposed upstream of the branch point on the other end side of the cleaning water supply pipe 65. The washing hot water pump 65a is driven by a command given from the control unit 100, and supplies hot water from the hot water tank 25 to the mixing container 61 when driven.

  In the beverage supply apparatus 10 having the above-described configuration, milk can be supplied to the cup C in a state where the milk is foamed as follows.

  It is assumed that the first steam supply valve 22a is opened by the control unit 100 and the tube pump 32 and the air pump 42 are driven. The second steam supply valve 23a is closed. Further, it is assumed that the first connection portion 26 and the second connection portion 33 are connected, and the third connection portion 68 is disconnected from the first connection portion 26.

  By driving the tube pump 32 in this way, the stock solution supply unit 30 pumps out the milk stock solution of the BIB 31. The milk stock solution pumped out from the BIB 31 passes through the liquid supply pipe 27 after passing through the tube 34. The milk stock solution passing through the liquid supply pipe 27 reaches the mixing unit 50.

  By the way, the pressurized steam generated in the steam tank 21 by the opening of the first steam supply valve 22 a passes through the first steam supply pipe 22 and reaches the mixing unit 50. In addition, by driving the air pump 42, the compressed air passes through the air supply pipe 41 and reaches the mixing unit 50.

  In the mixing unit 50, the milk stock solution is heated by the pressurized steam. Moreover, in this mixing part 50, a milk drink is produced | generated by mixing with the milk undiluted solution heated by the pressurized steam when compressed air approachs. The milk beverage produced here is in a state of being slightly foamed by compressed air. Thus, the milk beverage generated by the mixing unit 50 passes through the beverage delivery pipe 51 and reaches the forming unit 52.

  In the forming unit 52, the amount of foaming of the milk drink is increased and the foamed foam comes into contact with the wall surface or the like. The foamed milk beverage passes through the beverage outlet passage and is delivered to the nozzle portion 54, and is discharged from the nozzle portion 54 to the cup C, whereby the milk beverage is supplied.

  Next, as shown in FIG. 2, in a state where the second connection portion 33 is disconnected from the first connection portion 26 and the third connection portion 68 is connected to the first connection portion 26, a predetermined input means ( When a cleaning command is given to the control unit 100 as a result of performing an input operation through (not shown), the control unit 100 performs a cleaning control process. In the following, it is assumed that each valve is closed and each pump is stopped.

  FIG. 7 is a flowchart showing the processing content of the cleaning control process performed by the control unit 100. In this cleaning control process, the control unit 100 performs a pre-rinse process (step S100).

  FIG. 8 is a flowchart showing the processing contents of the pre-rinsing process shown in FIG. In this pre-rinsing process, the control unit 100 sends a drive command to the cleaning water pump 65a (step S101), starts measuring time through a built-in clock unit (not shown), and waits for elapse of a preset drive time. (Step S102).

  As a result, hot water is supplied from the hot water tank 25 to the mixing container 61 through the cleaning hot water supply pipe 65 as cleaning hot water. As described above, since the other end side of the cleaning water supply pipe 65 is branched into two, a part of the hot water is discharged upward from the discharge port 611. In addition, as described above, the washing hot water supply pipe 65 communicating with the upper hot water supply port 612 extends in the substantially tangential direction of the side portion 61a of the mixing container 61 at the upper hot water supply port 612. It is discharged from the upper hot water supply port 612 and passes spirally downward along the inner wall surface of the side portion 61 a of the mixing container 61.

  When the drive time has elapsed (step S102: Yes), the control unit 100 sends a drive stop command to the hot water pump 65a (step S103), starts measuring time through the clock unit, and sets a standby time that is set in advance. (Step S104). Here, the waiting time is a time provided for the hot water sent out by the washing water pump 65a to reach the mixing container 61 with certainty.

  When the standby time has elapsed (step S104: Yes), the control unit 100 sends a driving command to the cleaning liquid pump 64a (step S105), starts measuring time through the clock unit, and elapses of a preset driving time. The process waits (step S106). Thereby, the hot water in the mixing container 61 is used as washing hot water, the first connection part 26, the liquid supply pipe 27, the mixing part 50, the beverage delivery pipe 51, the forming part 52, and the beverage derivation constituting the beverage supply path from the cleaning liquid supply pipe 64. It passes through the passage and nozzle part 54.

  When the drive time has elapsed (step S106: Yes), the control unit 100 sends a drive stop command to the cleaning liquid supply pump and gives an open command to the second steam supply valve 23a (step S107, step S108). Thus, the control part 100 which gave the opening instruction | command to the 2nd steam supply valve 23a starts time measurement through a timepiece part, and waits for progress of the preset opening time (step S109).

  Accordingly, the second steam supply valve 23a is opened until the opening time elapses, so that the pressurized steam that has passed through the second steam supply pipe 23 is converted into the first connection part 26, the liquid supply pipe 27, the mixing part 50, The hot water supplied in step S105 can be blown through the beverage delivery pipe 51, the forming portion 52, the beverage outlet passage and the nozzle portion 54.

  When the opening time has elapsed (step S109: Yes), the control unit 100 sends a close command to the second steam supply valve 23a (step S110), and then returns the procedure to end the current pre-rinsing process.

  Thus, the control part 100 which implemented the pre-rinsing process performs an alkali washing process (step S200).

  FIG. 9 is a flowchart showing the contents of the alkali cleaning process shown in FIG. In this alkali cleaning process, the control unit 100 sends a drive command to the first cleaning stock solution supply pump 62a (step S201), starts measuring time through the clock unit, and waits for elapse of a preset driving time ( Step S202).

  When the drive time has elapsed (step S202: Yes), the control unit 100 sends a drive stop command to the first cleaning stock solution supply pump 62a (step S203).

  As a result, the first cleaning stock solution supply pump 62a is driven for the above driving time, and the alkaline cleaning stock solution stored in the first cleaning stock solution storage unit 66 is supplied to the mixing container 61 by a predetermined amount. The alkaline cleaning stock solution supplied to the mixing container 61 is stored in the lower part of the mixing container 61.

  Then, the control unit 100 sends a drive command to the hot water pump 65a (step S204), starts measuring time through the clock unit, and waits for elapse of a preset drive time (step S205). As a result, hot water is supplied from the hot water tank 25 to the mixing container 61 through the cleaning hot water supply pipe 65 as cleaning hot water. As described above, the other end of the cleaning water supply pipe 65 is branched into two, a part of the hot water is discharged upward from the discharge port 611, and the remaining hot water is mixed from the upper hot water supply port 612. Since it passes spirally downward along the inner wall surface of the side portion 61a of the container 61, the already stored alkaline cleaning stock solution and hot water (cleaning hot water) can be satisfactorily stirred. A cleaning liquid can be generated.

  When the drive time has elapsed (step S205: Yes), the control unit 100 sends a drive stop command to the hot water pump 65a (step S206), starts measuring the time through the clock unit, and sets a preset standby time. (Step S207). This standby time is a time provided for the hot water sent out by the washing hot water pump 65a to reach the mixing container 61 reliably, as in the pre-rinsing process described above.

  When the standby time has elapsed (step S207: Yes), the control unit 100 performs an alkaline cleaning liquid supply process (step S208).

  FIG. 10 is a flowchart showing the processing contents of the alkaline cleaning liquid supply processing shown in FIG. In this alkaline cleaning liquid supply process, the control unit 100 sends a drive command to the cleaning liquid pump 64a (step S208a), starts measuring time through the clock unit, and waits for elapse of a preset set time (step S208b). .

  Thereby, the alkaline cleaning liquid of the mixing container 61 is supplied from the cleaning liquid supply pipe 64 to the first connection part 26, the liquid supply pipe 27, the mixing part 50, the beverage delivery pipe 51, the forming part 52, the beverage outlet passage and the nozzle. Pass through part 54.

  When the set time has elapsed (step S208b: Yes), the control unit 100 sends a drive stop command to the cleaning liquid supply pump (step S208c), starts measuring time through the clock unit, and sets a preset drive stop time. (Step S208d).

  According to this, it is possible to perform an intermittent drive in which the cleaning liquid supply pump is driven for the set time and the cleaning liquid supply pump is stopped during the drive stop time.

  When the drive stop time has elapsed (step S208d: Yes), the control unit 100 sends an open command to the second steam supply valve 23a (step S208e), starts time measurement through the clock unit, and is set in advance. It waits for the elapsed open time (step S208f).

  When the opening time has elapsed (step S208f: Yes), the control unit 100 sends a close command to the second steam supply valve 23a (step S208g), and the cleaning liquid pump 64a is driven a predetermined number of times in advance. It is confirmed whether or not n times have been reached (step S208h).

  When the number of driving times of the cleaning liquid pump 64a has not reached n times (step S208h: No), the control unit 100 repeats the processes of steps S208a to S208g described above.

  On the other hand, when the number of times of driving the cleaning liquid pump 64a has reached n (step S208h: Yes), the control unit 100 sends a driving command to the cleaning liquid pump 64a (step S208i), and then returns the procedure. This alkaline cleaning liquid supply process is terminated.

  The controller 100 that has performed the alkali cleaning liquid supply process in this way, when the time measured through the clock unit after performing Step S208i has passed a preset driving time (Step S209: Yes), the mixing container 61 Assuming that all of the alkaline cleaning liquid inside is supplied, a drive stop command is sent to the cleaning liquid pump 64a (step S210).

  Then, the control unit 100 gives an opening command to the second steam supply valve 23a (step S211), starts time measurement through the clock unit, and waits for elapse of a preset opening time (step S212). Thereby, the alkali cleaning liquid supplied in the above procedure can be blown.

  When the opening time has elapsed (step S212: Yes), the control unit 100 sends a close command to the second steam supply valve 23a (step S213), and then returns the procedure to end the current alkali cleaning process. .

  The control unit 100 that has performed the alkali cleaning process in this manner performs an alkali cleaning rinse process (step S300).

  FIG. 11 is a flowchart showing the processing contents of the alkaline cleaning rinsing processing shown in FIG. In this alkaline cleaning rinsing process, the control unit 100 sends a drive command to the hot water pump 65a (step S301), starts measuring time through the clock unit, and waits for elapse of a preset driving time (step S302). ).

  As a result, hot water is supplied from the hot water tank 25 to the mixing container 61 through the cleaning hot water supply pipe 65 as cleaning hot water. As described above, since the other end side of the cleaning water supply pipe 65 is branched into two, a part of the hot water is discharged upward from the discharge port 611. In addition, as described above, the washing hot water supply pipe 65 communicating with the upper hot water supply port 612 extends in the substantially tangential direction of the side portion 61a of the mixing container 61 at the upper hot water supply port 612. It is discharged from the upper hot water supply port 612 and passes spirally downward along the inner wall surface of the side portion 61 a of the mixing container 61.

  When the drive time has elapsed (step S302: Yes), the control unit 100 sends a drive stop command to the hot water pump 65a (step S303), starts measuring the time through the clock unit, and sets a preset standby time. (Step S304). Here, the waiting time is a time provided for the hot water sent out by the washing water pump 65a to reach the mixing container 61 with certainty.

  When the standby time has elapsed (step S304: Yes), the control unit 100 sends a driving command to the cleaning liquid pump 64a (step S305), starts measuring time through the clock unit, and elapses of a preset driving time. Waiting (step S306). Thereby, the hot water in the mixing container 61 is used as washing hot water, the first connection part 26, the liquid supply pipe 27, the mixing part 50, the beverage delivery pipe 51, the forming part 52, and the beverage derivation constituting the beverage supply path from the cleaning liquid supply pipe 64. It passes through the passage and nozzle part 54.

  When the drive time has elapsed (step S306: Yes), the control unit 100 sends a drive stop command to the cleaning liquid supply pump and gives an open command to the second steam supply valve 23a (steps S307 and S308). Thus, the control part 100 which gave the opening command to the 2nd steam supply valve 23a starts measurement of time through a timepiece part, and waits for progress of the preset opening time (step S309).

  Accordingly, the second steam supply valve 23a is opened until the opening time elapses, so that the pressurized steam that has passed through the second steam supply pipe 23 is converted into the first connection part 26, the liquid supply pipe 27, the mixing part 50, The hot water supplied in step S305 can be blown through the beverage delivery pipe 51, the forming portion 52, the beverage outlet passage and the nozzle portion 54.

  When the opening time has elapsed (step S309: Yes), the control unit 100 sends a close command to the second steam supply valve 23a (step S310), and then returns the procedure to complete the current alkaline cleaning rinse process. To do.

  Thus, the control part 100 which implemented the alkali washing rinse process implements an acid washing process (step S400).

  FIG. 12 is a flowchart showing the contents of the acid cleaning process shown in FIG. In this acid cleaning process, the control unit 100 sends a drive command to the second cleaning stock solution supply pump 63a (step S401), starts time measurement through the clock unit, and waits for elapse of a preset drive time ( Step S402).

  When the drive time has elapsed (step S402: Yes), the control unit 100 sends a drive stop command to the second cleaning stock solution supply pump 63a (step S403).

  Accordingly, the second cleaning stock solution supply pump 63a is driven for the above driving time, and the acidic cleaning stock solution stored in the second cleaning stock solution storage unit 67 is supplied to the mixing container 61 by a predetermined amount. The acidic cleaning stock solution supplied to the mixing container 61 is stored in the lower part of the mixing container 61.

  Then, the control unit 100 sends a drive command to the hot water pump 65a (step S404), starts measuring time through the clock unit, and waits for a preset drive time (step S405).

  As a result, hot water is supplied from the hot water tank 25 to the mixing container 61 through the cleaning hot water supply pipe 65 as cleaning hot water. As described above, the other end of the cleaning water supply pipe 65 is branched into two, a part of the hot water is discharged upward from the discharge port 611, and the remaining hot water is mixed from the upper hot water supply port 612. Since it passes spirally downward along the inner wall surface of the side portion 61a of the container 61, the already stored alkaline cleaning stock solution and hot water (cleaning hot water) can be satisfactorily stirred. A cleaning liquid can be generated.

  When the drive time has elapsed (step S405: Yes), the control unit 100 sends a drive stop command to the hot water pump 65a (step S406), starts measuring time through the clock unit, and sets a standby time that is set in advance. (Step S407). This standby time is a time provided for the hot water sent out by the washing hot water pump 65a to reach the mixing container 61 reliably, as in the pre-rinsing process described above.

  When the standby time has elapsed (step S407: Yes), the control unit 100 performs an acid cleaning liquid supply process (step S408).

  FIG. 13 is a flowchart showing the contents of the acid cleaning liquid supply process shown in FIG. In this acid cleaning liquid supply process, the control unit 100 sends a drive command to the cleaning liquid pump 64a (step S408a), starts measuring time through the clock unit, and waits for elapse of a preset set time (step S408b). . As a result, the acid cleaning liquid in the mixing container 61 is supplied from the cleaning liquid supply pipe 64 to the first connection part 26, the liquid supply pipe 27, the mixing part 50, the beverage delivery pipe 51, the forming part 52, the beverage outlet passage and the nozzle. Pass through part 54.

  When the set time has elapsed (step S408b: Yes), the control unit 100 sends a drive stop command to the cleaning liquid supply pump (step S408c), starts measuring time through the clock unit, and sets a preset drive stop time. (Step S408d).

  According to this, it is possible to perform an intermittent drive in which the cleaning liquid supply pump is driven for the set time and the cleaning liquid supply pump is stopped during the drive stop time.

  When the drive stop time has elapsed (step S408d: Yes), the control unit 100 sends an open command to the second steam supply valve 23a (step S408e), starts time measurement through the clock unit, and is set in advance. It waits for the elapsed open time (step S408f).

  When the opening time has elapsed (step S408f: Yes), the control unit 100 sends a close command to the second steam supply valve 23a (step S408g), and the cleaning liquid pump 64a is driven a predetermined number of times in advance. It is confirmed whether or not n times have been reached (step S408h).

  When the number of driving times of the cleaning liquid pump 64a has not reached n times (step S408h: No), the control unit 100 repeats the processes of steps S408a to S408g described above. On the other hand, when the number of driving times of the cleaning liquid pump 64a has reached n times (step S408h: Yes), the control unit 100 sends a driving command to the cleaning liquid pump 64a (step S408i), and then returns the procedure. This acid cleaning liquid supply process is terminated.

  The control unit 100 that has performed the acid cleaning liquid supply processing in this way, when the time measured through the clock unit after performing Step S408i has passed a preset driving time (Step S409: Yes), the mixing container 61 Assuming that all of the acid cleaning liquid inside has been supplied, a drive stop command is sent to the cleaning liquid pump 64a (step S410).

  Then, the control unit 100 gives an opening command to the second steam supply valve 23a (step S411), starts time measurement through the clock unit, and waits for the elapse of a preset opening time (step S412). Thereby, the acid cleaning liquid supplied in the above procedure can be blown.

  When the opening time has elapsed (step S412: Yes), the control unit 100 sends a close command to the second steam supply valve 23a (step S413), and then returns the procedure to end the current acid cleaning process. .

  Thus, the control part 100 which implemented the acid cleaning process implements an acid cleaning rinse process (step S500).

  FIG. 14 is a flowchart showing the contents of the acid cleaning rinsing process shown in FIG. In this acid cleaning rinsing process, the control unit 100 sends a drive command to the hot water pump 65a (step S501), starts measuring time through the clock unit, and waits for elapse of a preset driving time (step S502). ). As a result, hot water is supplied from the hot water tank 25 to the mixing container 61 through the cleaning hot water supply pipe 65 as cleaning hot water. As described above, since the other end side of the cleaning water supply pipe 65 is branched into two, a part of the hot water is discharged upward from the discharge port 611. In addition, as described above, the washing hot water supply pipe 65 communicating with the upper hot water supply port 612 extends in the substantially tangential direction of the side portion 61a of the mixing container 61 at the upper hot water supply port 612. It is discharged from the upper hot water supply port 612 and passes spirally downward along the inner wall surface of the side portion 61 a of the mixing container 61.

  When the drive time has elapsed (step S502: Yes), the control unit 100 sends a drive stop command to the hot water pump 65a (step S503), starts measuring time through the clock unit, and sets a standby time that is set in advance. (Step S504). Here, the waiting time is a time provided for the hot water sent out by the washing water pump 65a to reach the mixing container 61 with certainty.

  When the standby time has elapsed (step S504: Yes), the control unit 100 sends a drive command to the cleaning liquid pump 64a (step S505), starts measuring time through the clock unit, and elapses of a preset drive time. The process waits (step S506). Thereby, the hot water in the mixing container 61 is used as washing hot water, the first connection part 26, the liquid supply pipe 27, the mixing part 50, the beverage delivery pipe 51, the forming part 52, and the beverage derivation constituting the beverage supply path from the cleaning liquid supply pipe 64. It passes through the passage and nozzle part 54.

  When the drive time has elapsed (step S506: Yes), the control unit 100 sends a drive stop command to the cleaning liquid supply pump and gives an open command to the second steam supply valve 23a (steps S507 and S508). Thus, the control part 100 which gave the opening command to the 2nd steam supply valve 23a starts measurement of time through a timepiece part, and waits for progress of the preset opening time (step S509).

  Accordingly, the second steam supply valve 23a is opened until the opening time elapses, so that the pressurized steam that has passed through the second steam supply pipe 23 is converted into the first connection part 26, the liquid supply pipe 27, the mixing part 50, The hot water supplied in step S505 can be blown through the beverage delivery pipe 51, the forming portion 52, the beverage outlet passage and the nozzle portion 54.

  When the opening time has elapsed (step S509: Yes), the control unit 100 sends a close command to the second steam supply valve 23a (step S510), and then returns the procedure to end the current acid cleaning rinse process. To do.

  The control unit 100 that has performed the acid cleaning rinsing process in this way performs a finish rinsing process (step S600).

  FIG. 15 is a flowchart showing the processing contents of the finishing rinse process shown in FIG. In this finishing rinsing process, the control unit 100 sends a drive command to the hot water pump 65a (step S601), starts measuring time through the clock unit, and waits for elapse of a preset drive time (step S602). .

  As a result, hot water is supplied from the hot water tank 25 to the mixing container 61 through the cleaning hot water supply pipe 65 as cleaning hot water. As described above, since the other end side of the cleaning water supply pipe 65 is branched into two, a part of the hot water is discharged upward from the discharge port 611. In addition, as described above, the washing hot water supply pipe 65 communicating with the upper hot water supply port 612 extends in the substantially tangential direction of the side portion 61a of the mixing container 61 at the upper hot water supply port 612. It is discharged from the upper hot water supply port 612 and passes spirally downward along the inner wall surface of the side portion 61 a of the mixing container 61.

  When the drive time has elapsed (step S602: Yes), the control unit 100 sends a drive stop command to the hot water pump 65a (step S603), starts measuring time through the clock unit, and sets a standby time that is set in advance. (Step S604). Here, the waiting time is a time provided for the hot water sent out by the washing water pump 65a to reach the mixing container 61 with certainty.

  When the standby time has elapsed (step S604: Yes), the control unit 100 sends a driving command to the cleaning liquid pump 64a (step S605), starts measuring time through the clock unit, and elapses of a preset driving time. The process waits (step S606). Thereby, the hot water in the mixing container 61 is used as washing hot water, the first connection part 26, the liquid supply pipe 27, the mixing part 50, the beverage delivery pipe 51, the forming part 52, and the beverage derivation constituting the beverage supply path from the cleaning liquid supply pipe 64. It passes through the passage and nozzle part 54.

  When the drive time has elapsed (step S606: Yes), the control unit 100 sends a drive stop command to the cleaning liquid supply pump and gives an open command to the second steam supply valve 23a (steps S607 and S608). Thus, the control part 100 which gave the opening command to the 2nd steam supply valve 23a starts measurement of time through a timepiece part, and waits for progress of the preset opening time (step S609).

  Accordingly, the second steam supply valve 23a is opened until the opening time elapses, so that the pressurized steam that has passed through the second steam supply pipe 23 is converted into the first connection part 26, the liquid supply pipe 27, the mixing part 50, Hot water supplied in step S605 can be blown through the beverage delivery pipe 51, the forming portion 52, the beverage outlet passage and the nozzle portion 54.

  When the opening time has elapsed (step S609: Yes), the control unit 100 sends a close command to the second steam supply valve 23a (step S610), and the number of times the cleaning water pump 65a and the cleaning liquid pump 64a are driven is preset. It is confirmed whether or not the predetermined number m has been reached (step S611).

  When the number of driving times of the cleaning water pump 65a and the cleaning liquid pump 64a has not reached m times (step S611: No), the control unit 100 repeats the processes of steps S601 to S610 described above. On the other hand, when the number of driving times of the cleaning water pump 65a and the cleaning liquid pump 64a has reached m times (step S611: Yes), the control unit 100 sends a cleaning completion signal to the host device or the display unit (step S612). ), And then the procedure is returned to finish the final rinsing process. By performing the finish rinsing process in this way, the process procedure of the cleaning control process is returned, and the current cleaning control process is terminated.

  As described above, according to the beverage supply apparatus according to the embodiment of the present invention, when the cleaning unit 60 is given a cleaning command, the cleaning stock solution supplied from the cleaning stock solution storage units 66 and 67 and the hot water tank The hot water supplied from the hot water 25 (cleaning hot water) is mixed to produce a cleaning liquid, the cleaning liquid is supplied to the beverage supply path that is in a communicating state, and then the hot water supplied from the hot water tank 25 is used as the rinse water. Since it is supplied to the supply path, it is not necessary to connect and disconnect the cleaning liquid storage section and to connect and disconnect the rinse water storage section as in the prior art, and the beverage supply path can be cleaned simply by giving a cleaning command. it can. Therefore, the beverage supply path can be easily cleaned.

  In particular, since the cleaning liquid is supplied intermittently by the cleaning unit 60, the beverage supply path can be more effectively cleaned.

  In the mixing container 61 of the cleaning unit 60, cleaning hot water is supplied upward from the discharge port 611 and spiraled downward from the upper hot water supply port 612 along the inner wall surface of the side portion 61a while storing the cleaning stock solution. Therefore, it is possible to satisfactorily stir the washing stock solution and the washing water, thereby producing a well diluted washing solution.

  The preferred embodiment of the present invention has been described above, but the present invention is not limited to this, and various modifications can be made.

  In the embodiment described above, milk is used as an example of a milk beverage. However, in the present invention, a milk beverage such as soy milk may be used.

  In the above-described embodiment, the beverage connection path is cleaned after the first connection portion 26 and the second connection portion 33 are disconnected and the third connection portion 68 is connected to the first connection portion 26. In the present invention, the beverage supply path may be washed in a state where the first connection portion 26, the second connection portion 33, and the third connection portion 68 are connected to each other. According to this, it is not necessary to disconnect the 2nd connection part 33 from the 1st connection part 26, and to connect the 3rd connection part 68 to the 1st connection part 26, and it can wash | clean a drink supply path more easily. .

DESCRIPTION OF SYMBOLS 1 Beverage dispenser 10 Beverage supply apparatus 20 Steam supply part 25 Hot water tank 30 Stock solution supply part 40 Air supply part 50 Mixing part 52 Forming part 54 Nozzle part 60 Cleaning part 61 Mixing container 61a Side part 61b Bottom part 611 Discharge port 612 Upper hot water supply port 62 1st washing | cleaning stock solution supply pipe 63 2nd washing | cleaning stock solution supply pipe 64 Cleaning liquid supply pipe 65 Washing water supply pipe 100 Control part C Cup

Claims (3)

In a beverage supply apparatus that is applied to a beverage dispenser that provides a beverage to a beverage container and has a beverage supply path that supplies milk beverage to the beverage container,
When a cleaning instruction is given, the cleaning stock solution supplied from the cleaning stock solution storage unit that stores the cleaning stock solution and the hot water supplied from the hot water storage unit that stores the hot water that generates the pressurized steam constituting the milk beverage Mixing with certain hot water to generate a cleaning liquid, supplying the cleaning liquid to the beverage supply path that is in communication, and then supplying the hot water supplied from the hot water storage section as rinse water to the beverage supply path A beverage supply device comprising a cleaning unit that performs the cleaning.   The cleaning unit mixes the alkaline cleaning stock solution supplied from the cleaning stock solution storage unit with the cleaning hot water to generate an alkaline cleaning solution, and supplies the alkaline cleaning solution to the beverage supply path that is in a communicating state. Then, the rinsing hot water is supplied, and then the acidic cleaning stock solution supplied from the cleaning stock solution storage unit and the cleaning hot water are mixed to produce an acidic cleaning liquid, which is acidic with respect to the beverage supply path. The beverage supply apparatus according to claim 1, wherein the rinse water is supplied after the cleaning liquid is supplied.   The beverage supply device according to claim 1, wherein the cleaning unit intermittently supplies the cleaning liquid to the beverage supply path.

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