KR20030081125A - Extractor - Google Patents

Abstract

An object of the present invention is to provide an extraction device with good user convenience.

When the setting switch SW is turned on (the extraction device is set to supply water to the reservoir tank manually) (No at S1), the water supply solenoid valve is opened at S2 and the water level detection SW is turned on at S3. If yes (YES in S3), the solenoid valve for water supply is closed 15 seconds after the ON of the water level detection SW (S5 to S6), and the heating operation of the hot water in the storage tank after S7 is performed. On the other hand, when the setting SW is turned off (it is set to be automatically supplied to the water storage tank), when the water level detection SW is turned on (YES in S3 and S4), the heating of the hot water in the storage tank after S7 is in that state. The operation is performed.

Description

Extraction unit {EXTRACTOR}

The present invention relates to an extraction apparatus, and more particularly, to an extraction apparatus for obtaining an extract by supplying hot water to a container containing a powder raw material and a filter.

Conventionally, there has been an apparatus for automatically supplying hot water to a container 600 including a powder raw material and a filter such as a vending machine for coffee beverages to obtain an extract. 26 shows a schematic hot water supply mechanism in such an apparatus.

In the apparatus shown in FIG. 26, the water supplied to the water storage tank 503 is transferred to the water storage tank 505, and is heated by the heater 550 in the water storage tank 505 to become hot water, and thus the capacity of the measuring cup having a predetermined capacity ( 507). Then, the hot water in the measuring cup 507 is transferred to the container 600 including the powder raw material and the filter by the air transferred from the pump 506 on the condition that the temperature is detected by the temperature sensor 554 to reach a predetermined temperature. Transferred. In addition, the extract obtained from the vessel 600 is supplied to the cup 400.

In addition, the steam of the storage tank 505 was sent to the storage tank 503 via the steam pipe 559. In addition, when the exhaustion of water was detected by the water level sensor 530 attached below in the water storage tank 503, the extraction apparatus notified the user, and stopped operation | movement. Then, the user supplied water to the water storage tank 503 based on the above notification, so that the water depletion detection was released by the water level sensor 530, and the extraction apparatus resumed operation.

If the apparatus shown in Fig. 26 is to be configured to automatically supply water to the reservoir tank 503, a design change is necessary. This is because the purpose of detecting the water level sensor 530 in the apparatus is different from the supply of water to the water storage tank 503 manually or automatically.

Specifically, when water is supplied manually, the water level sensor 530 is at a level to prevent co-heating, and the extraction apparatus detects water depletion when the water level in the water storage tank 503 becomes relatively small. It was designed.

On the other hand, when water is automatically supplied, the water level sensor is designed to stop the water supply to the water storage tank 503, that is, to perform the water depletion detection while the water storage tank 503 is near full water.

In addition, when a device designed to supply water manually is used in a situation in which water is automatically supplied, the water in the reservoir tank 503 is always in an amount such that water depletion detection of the water level sensor 530 is performed. That is, it is maintained in a relatively small state as described above. Such a situation is dangerous in the water storage tank 503 because there is always no room for water, and when water is used, the water is immediately supplied, and opening / closing of a valve for switching on / off of water supply. It is not desirable to increase the number of times.

On the other hand, when a device designed to automatically supply water is used in a situation in which water is supplied manually, the water level sensor 530 detects water depletion even in a state where relatively large amount of water remains in the reservoir tank 503. Therefore, the user is required to diligently supply water, and the situation which is considered unpleasant is considered. That is, an apparatus designed to be suitable for automatically supplying water is not preferably used in the situation of supplying water manually.

As described above, the conventional extraction device is designed to be suitable for automatically supplying water, and is designed to be suitable for manually supplying water.

In the apparatus shown in Fig. 26, when the hot water in the water storage tank 505 enters the steam pipe 559, the amount of the hot water enters, or the connection portion of the steam pipe 559 in the water storage tank 503. When water enters the vicinity, the situation where water circulation occurs between the water storage tank 503 and the water storage tank 505 is considered. When such a circulation occurs, the heater 550 must heat the water in the reservoir tank 505 and the measuring cup 507 as well as the water in the reservoir tank 503. For this reason, unnecessary heating is performed to the heater 550 to increase the running cost, and further, the time until the water in the measuring cup 507 reaches the predetermined temperature after the water is supplied to the water storage tank 503. It was difficult to say that the user's ease of use was good for the user because it took a long time unnecessarily.

The present invention has been devised in view of the above situation, and an object thereof is to provide an extraction device with good user convenience.

1 is a perspective view of an extraction device according to one embodiment of the present invention;

2 is a front view of the extraction device of FIG. 1;

3 is a right side view of the extraction apparatus of FIG.

4 is a partial perspective view of the extraction device of FIG.

FIG. 5 is a diagram schematically showing the internal structure of the extraction device of FIG. 1; FIG.

Fig. 6 is a front view in a state where the front part of the exterior part of the extracting apparatus of Fig. 1 is removed;

7 is a plan view in a state where the outer surface upper part of the extracting apparatus of FIG. 1 is removed;

Fig. 8 is a right side view in a state in which the outer surface right side portion of the extracting apparatus of Fig. 1 is removed;

FIG. 9 is a view showing the vicinity of a drawer in the extraction apparatus of FIG. 1 with the drawer taken out; FIG.

10 is a view for explaining a change in height of the fixing member in accordance with the rotation of the gear in the extraction device of FIG.

11 is a view for explaining a change in height of the fixing member in accordance with the rotation of the gear in the extraction device of FIG.

FIG. 12 is a view for explaining a state in which the fixing member drawer partially contacts in the extraction device of FIG. 1; FIG.

FIG. 13 is a view showing the positional relationship of a partition plate, a pump case, and a circuit board in the extraction device of FIG.

FIG. 14 shows the internal structure of the pump case of FIG.

FIG. 15 is a view for explaining a structure near the bottom of the water storage tank of FIG. 6; FIG.

Figure 16 is a plan view of the nut of Figure 15;

FIG. 17 is an enlarged view of a connection portion between the steam pipe and the reservoir tank of the extraction device of FIG. 1; FIG.

FIG. 18 is an enlarged view of the vicinity of an outflow path provided in the upper portion of the water storage tank of the extraction device of FIG. 1; FIG.

FIG. 19 is a flowchart of a control process of a general operation executed by a CPU included in the extracting apparatus of FIG. 1; FIG.

20 is a flowchart of a control process of a general operation executed by a CPU included in the extraction device of FIG.

21 is a flowchart of a subroutine of the extraction operation processing of FIG.

Fig. 22 is a circuit diagram of a part of the circuit provided on the circuit board of the extraction device of Fig. 1 relating to the drive of the gear motor.

FIG. 23 is a circuit diagram of a portion of the circuit provided on the circuit board of the extraction device of FIG. 1 for setting the introduction amount of a bath.

24 is a time chart in an extraction operation process of the extraction device of FIG.

25 is a time chart in the extraction operation process of the extraction device of FIG.

Fig. 26 is a view schematically showing a hot water supply mechanism in a conventional extraction device. <Description of reference numerals for major parts in the drawings>

1: extraction device

2: exterior

3: reservoir tank

5: water storage tank

6: gear pump

11 to 17: resistance

20: operation panel

21, 22: Start button

23: windows

29: drawer

30: water level sensor

31: cup holder

32: coasters

50: heater

51, 53, 62, 63: tube

52: runoff

52A: commutation member

58: nuts

59: steam pipe

60: 3-way solenoid valve

64: fixed member

64A: pin

65: introduction needle

66: circuit board

70: extraction chamber

73: gear motor

74: gear

75: tooth plate

76 convex part

77, 78, 91 to 97, 171, 172: switch

81: motor

100: extraction cup

177, 178: discharge resistance

An extraction device according to an aspect of the present invention is an extraction device for obtaining an extraction liquid through the filter out of the extraction container by supplying a hot water to an inside of the extraction container, which is a container including a powder raw material and a filter, and storing the water. A mud tank for heating, a heater provided in the mud tank, a reservoir for storing water for supply to the mud tank, a sensor for detecting whether a specific amount of water is stored in the reservoir tank, An introduction signal output section for outputting a water introduction signal, which is a signal for introducing water into the reservoir tank, a water introduction setting section for setting whether or not to output the water introduction signal to the introduction signal output section, and It characterized in that it comprises a heater control unit for controlling the operation. If the water introduction setting unit is set to output the water introduction signal, the introduction signal output unit has a predetermined time after the sensor detects that the water in the reservoir tank has reached the specific amount. After outputting the water introduction signal until the elapsed time, the output of the water introduction signal is stopped, and the heater control unit starts heating with the heater after the output of the water introduction signal is stopped, the water introduction setting In the case where the unit is set not to output the water introduction signal, the heater control unit starts heating with the heater as the sensor detects that the water in the reservoir tank has reached the specific amount.

According to a certain aspect of the present invention, the extraction apparatus starts the heating by the heater after automatically supplying water for a predetermined time after the water depletion detection in the sensor is released according to the setting in the water introduction setting unit. As the water depletion detection in the sensor is released, the heating is started by the heater, or the operation can be performed by either of these two methods.

Thereby, the extraction device is used even in a situation where the water is automatically supplied to the reservoir tank when the specific amount detected by the sensor is relatively small, that is, when the extraction device is designed to be suitable for supplying water manually. The water in the reservoir tank can be maintained in an amount larger than the amount of the sensor detecting water depletion. Therefore, the extraction device is used safely and comfortably even if water is automatically or manually supplied to the reservoir tank without any design change.

Moreover, in the extraction apparatus of this invention, it is preferable that the heat generating part of the said heater is provided with the part which has a spiral shape.

Thereby, the heating of the hot water in a boiling point tank is performed efficiently.

An extraction device according to another aspect of the present invention is an extraction device for obtaining an extract through the filter out of the extraction container by supplying a hot water into the extraction container which is a container including a powder raw material and a filter, A storage tank for storing water, a storage tank for storing water for supply to the storage tank, and a pipe connected to the storage tank from the storage tank, for introducing steam in the storage tank into the storage tank. And a steam pipe, wherein the steam pipe is partially smaller in the water storage tank side than in the water tank.

According to another aspect of the present invention, even when a hot water tank enters the steam pipe, the hot water inhibits entry into the water storage tank in a portion where the inner diameter of the water storage tank side is smaller than that of the water spray tank side.

As a result, the inside of the steam pipe is filled with the hot water, thereby avoiding a situation in which water circulation occurs between the hot water tank and the water storage tank, and an inefficient heating that is heated to the water of the water storage tank can be avoided. . Therefore, the extraction apparatus is good in the ease of use which can avoid the fall of heating efficiency.

In the extraction apparatus of the present invention, the steam pipe preferably has a smaller inner diameter at the water storage tank side than at the water tank at the connection portion to the water storage tank.

As a result, it is possible to avoid the hot water of the boiling water tank from entering the storage tank while effectively separating the water and the air in the steam in the steam pipe.

Moreover, in the extraction apparatus of this invention, it is preferable that the said water storage tank is comprised so that the quantity of water in the said storage tank can visually confirm at least one part from the exterior of the said extraction apparatus.

Thereby, the quantity of water in a water storage tank can be detected easily and at low cost, without using another member.

An extraction device according to another aspect of the present invention is an extraction device for obtaining an extract through the filter out of the extraction container by supplying a hot water to the interior of the extraction container which is a container containing a powder raw material and a filter, And a heater for storage, and a heater provided in the tank, wherein the heat generating portion of the heater has a portion having a spiral shape.

According to the present invention, the hot water in the boiling water tank can be heated faster than when the linear heater is provided.

As a result, the extraction liquid can be provided quickly after the heating of the hot water in the boiling water tank is started, so that the extraction device has good user convenience.

In the extraction apparatus of the present invention, the molten metal tank is provided with an outlet for letting out the stored hot water for supplying the hot water to the extraction container, and the heating portion of the heater is located near the outlet of the molten metal tank. It is preferable to provide the part which has a spiral shape.

As a result, the hot water in the position used for extraction can be efficiently heated among the hot water in the hot water tank, so that the extraction liquid can be provided more quickly after the heating of the hot water in the water tank is started.

An extraction device according to another aspect of the present invention is an extraction device for obtaining an extract through the filter out of the extraction container by supplying a hot water to the inside of the extraction container which is a container including a powder raw material and a filter, the reservoir is stored A tanbi tank for heating, a heater provided in the tanbi tank, a pump for sucking the hot water in the tanbi tank to the extraction container, a suction tube for flowing hot water from the tanbi tank to the pump, and the suction tube It is characterized by including the rectifying member which is a member opposing a direction perpendicular | vertical to a water tank tank side opening.

According to the present invention, bubbles generated by the heating of water in the boiling water tank by the heater are blocked by the rectifying member so that they cannot penetrate into the suction pipe.

As a result, it is possible to avoid the mixing of air bubbles into the hot water sucked by the pump, so that the change in the amount of hot water supplied to the extraction container is suppressed. Therefore, the concentration of the extract liquid is constant and the extraction device has good convenience for the user. do.

In addition, the extraction apparatus of the present invention further includes an opening and closing portion for opening and closing the mute tank to switch whether or not to discharge the hot water in the mute tank connected to the mute tank, the mute tank is connected to the opening portion It is preferable that a discharge hole is formed in the part, and the nut for connecting with the said opening-and-closing part is provided, and the said nut is formed in the said water tank to cut out part connected to the said discharge hole from the outer peripheral part of the said nut.

As a result, when the hot water in the molten metal tank is discharged, since the hot water near the nut flows from the nut outer peripheral part to the discharge hole along the cutout portion, it is possible to avoid remaining near the nut.

EMBODIMENT OF THE INVENTION Below, the extraction apparatus which is one Embodiment of this invention is demonstrated, referring drawings. 1 is a perspective view of an extraction apparatus according to an embodiment of the present invention, FIG. 2 is a front view of the extraction apparatus, and FIG. 3 is a right side view of the extraction apparatus. 4 is a perspective view of the lower part of the extraction apparatus.

The extraction apparatus 1 covers the outer part with the exterior part 2, has an operation panel 20 on the upper left side of the front face, a drawer 29 on the upper right side of the front face, The tray 4 is attached to the lower part of the direction. The extraction apparatus 1 is equipped with an extraction container (the extraction cup 100 to be described later), which is a container containing a powder raw material and a filter in the drawer 29, thereby supplying hot water to the extraction container and supplying the extraction container. The extract of the powder raw material in the inside is supplied. In the state shown in FIG. 1, the cup support 40 is again attached on the tray 4, and the cup 400 is mounted on the cup support 40. As shown in FIG. In this state, the cup 400 is located below the drawer 29. In addition, the extraction apparatus 1 may supply the extract liquid to the cup 400.

The operation panel 20 is provided with start buttons 21, 22, windows 23, and lamps 24 to 27. The start button 21 is a key for executing the extraction operation of the powder raw material in order for the user to drink the extract in a hot state. Hereinafter, the extract liquid for drinking in a hot state is called "hot extract liquid." The start button 22 is a key for executing the above-described extraction operation of the powder raw material (hereinafter simply referred to as the extraction operation) for the user to add ice to the extraction liquid for drinking in a cold state. Hereinafter, the extract liquid for drinking in a cold state is called "ice extract liquid." In addition, the extract for ice by one extraction operation is less in quantity than the extract for hot. This is intended to be the same amount as the hot extract by mixing with ice.

The extraction apparatus 1 accommodates the tank (storage tank 3 mentioned later) inside the exterior part 2. The reservoir tank 3 is covered by the tank lid 41, and a part thereof can be visually confirmed from the outside of the extraction apparatus via the window 23. In addition, since the tank is made of a transparent or translucent material, the user can visually check the remaining amount of water in the tank via the window 23. In addition, when the tank lid 41 is opened, the water storage tank 3 is supplied with water from the outside without being taken out of the exterior part 2.

The dust cover 28 is attached to the lower part of the front surface of the extraction apparatus 1. The dust box 42 is accommodated inside the exterior part 2 and inside the dust cover 28 as shown in FIG. The extraction cup 100 is exchanged every one extraction operation, and the dust box 42 is provided in the exterior portion 2 to accommodate the extraction cup 100 after being used in the extraction operation. The dust cover 28 has its upper end fixed to the front face of the exterior part 2. As the dust cover 28 is rotated about the upper end portion thereof, the dust box 42 can be taken out of the exterior portion 2 as shown in Fig. 3 or 4.

The lamp 24 is turned on when the extraction device 1 is in the ready state for the extraction operation. The lamp 25 is turned on when the extraction device 1 is in a state capable of performing the extraction operation. The lamp 26 lights when the water supply to the water storage tank 3 is needed (when the exhaustion of water is detected by the water level sensor 30 described later). The lamp 27 lights up when it is detected by the predetermined sensor that the dust box 42 is full.

5 schematically shows the internal structure of the extraction apparatus 1.

In the extraction device 1, the water supplied to the water storage tank 3 is introduced into the water storage tank 5 via the pipe 51. Water introduced into the water storage tank 5 is heated by the heater 50. The temperature of the bath located in the upper part of the water storage tank 5 is detected by the temperature sensor 54. When the detection temperature of the temperature sensor 54 reaches a predetermined temperature and the start button 21 or 22 is pressed, the gear pump 6 is driven so that the hot water in the water storage tank 5 flows out of the flow path 52. ), The pipe 53 and the three-way solenoid valve 60 are guided to the gear pump 6 and supplied to the extraction cup 100 via the pipe 63 and the introduction needle 65. In addition, the steam in the storage tank 5 is sent to the storage tank 3 via the steam pipe 59.

Introduction needle 65 is a hollow needle. The extraction cup 100 is fixed by inserting it into the cup holder 32 in the cup holder 31. The cup holder 31 is detachably fixed in the drawer 29. The fixing member 64 is attached to the introduction needle 65. The cup holder 31 has pins 31A and 31B formed at both left and right ends thereof, and the pins 31A and 31B are fastened or inserted into the holes appropriately provided in the drawer 29 to pin the drawers 29. It can rotate with the axis 31A, 31B as an axis. As the cup holder 31 is rotated in this manner with respect to the drawer 29, the extraction cup 100 is put into the dust box 42.

The supply of hot water to the extraction cup 100 described above is such that the introduction needle 65 and the fixing member 64 are close to the extraction cup 100 fixed to the cup holder 31 by a predetermined mechanism. Then, the extraction operation is performed in the state where the introduction needle 65 is inserted into the extraction cup 100.

The three-way solenoid valve 60 connects the pipe 62 and the pipe 53 or the intake hole 61. When the pipe 62 is connected with the pipe 53, the hot water of the storage tank 5 can flow from the pipe 62 to the pipe 53 as mentioned above. On the other hand, when the pipe 62 is connected to the intake hole 61, air is sucked into the extraction cup 100 via the gear pump 6, the pipe 63, and the introduction needle 65. Since the three-way solenoid valve 60 is located upstream with respect to the flow in which hot water or air is sent to the extraction cup 100 rather than the gear pump 6, both the hot water and the air are extracted from the gear pump 6. I can send it in (100).

The drain cock 57 and the drain pipe 56 are connected to the bottom part of the water storage tank 5. The drain cock 57 is attached to the bottom of the water storage tank 5 by the nut 58. The drain cock 57 has a function of a valve, and the valve is opened and closed by the operation lever 55. That is, by operating the operation lever 55, the drain cock 57 is opened, and the hot water (or water) in the water storage tank 5 is discharged through the drain pipe 56 via the drain cock 57.

Hereinafter, the internal structure of the extraction apparatus 1 is demonstrated. FIG. 6 is a front view in a state where the front part of the exterior part 2 of the extraction apparatus 1 is removed, and FIG. 7 is a plan view in a state where the top surface part of the exterior part 2 of the extraction apparatus 1 is removed. to be. 8 is a right side view in a state in which the right side surface portion of the exterior part 2 of the extraction apparatus 1 is removed. In addition, in FIG. 6, the longitudinal cross section is shown in order to partially break the member which is ahead of the water storage tank 5, and to explain the inside of the water storage tank 5 in detail. In addition, in FIG. 8, the extraction chamber 70 is partially broken to show the internal structure of the extraction chamber 70, and the drawer 29 is also partially broken.

6-8, the reservoir tank 3 is arrange | positioned at the upper left side in the inside of the extraction apparatus 1, and the extraction chamber 70 is arrange | positioned in front of the upper right side. In addition, a partition plate 85 is provided between the dust box 42 and the extraction chamber 70. Further, a storage tank 5 is provided at the rear lower portion of the extraction apparatus 1, and a steam pipe 59 extending from the storage tank 5 is connected to the rear end of the storage tank 3. In addition, a three-way solenoid valve 60 is provided behind the water storage tank 3. In addition, the upper part of the water storage tank 3 is provided with a filter 43 to be covered by the tank lid 41. The user opens the tank cover 41 to replenish the water in the reservoir tank 3 via the filter 43.

Extraction chamber 70 is a housing having a top, rear and left and right sides. Slide rails 71 and 72 are attached to the left and right side surfaces of the extraction chamber 70, respectively. Arms 29A and 29B are attached to the drawers 29 at left and right sides, and arms 29A and 29B are attached to slide rails 71 and 72, respectively. The slide rails 71 and 72 are configured to be elastic, and the slide rails 71 and 72 are extended by the drawer 29 being pulled forward. In this way, the drawer 29 moves in the front-rear direction of the extraction device 1. The state in which the drawer 29 is drawn out will be described in more detail with reference to FIG. 9 is a diagram showing the vicinity of the drawer 29 in the extraction apparatus 1 in the state where the drawer 29 is drawn out.

The pins 31A and 31B of the cup holder 31 are fitted into the arms 29A and 29B. As a result, the cup holder 31 is detachably fixed between the arm 29A and the arm 29B. The slide rails 71 and 72 are configured to be extensible, and in the state shown in Fig. 9, they extend in a state where the arms 29A and 29B are fitted, and in the state shown in Fig. 7 and the like, they are in a contracted state.

The funnel 33 is provided in the lower part of the extraction chamber 70 so that the partition plate 85 may penetrate. When the slide rails 71 and 72 are reduced, and the cup holder 31 is accommodated in the exterior part 2 and the extraction operation is performed, the funnel 33 is located below the extraction cup set in the cup holder 31. Located. When the hot water is supplied into the extraction cup 100, the extraction liquid flowing from the extraction cup 100 is provided to a container such as the cup 400 via the funnel 33. In detail, the funnel 33 is provided with the extraction port 33A below, and the extract liquid is provided to the container, such as the cup 400, via the said extraction port 33A.

The rail 69 is attached to the center part of the ceiling surface in the extraction chamber 70 so that it may run in the front-back direction. In addition, the tooth plate 75 is formed with an indentation on the upper surface, and the lower side is fitted into the rail 69. In addition, the upper surface with the notch in the tooth plate 75 is located above the extraction chamber 70, and the lower side surface which fits in the rail 69 is located in the extraction chamber 70. One end of the arm 79 is attached to the rear end of the tooth plate 75 inside the extraction chamber 70. The other end of the arm 79 is attached to the fixing member 64.

Rails 68 and 67 extending in the longitudinal direction are attached to the left and right side surfaces of the extraction chamber 70. Then, the members properly attached to the left and right sides of the fixing member 64 are fitted to the rails 68 and 67, so that the fixing member 64 is movable in the vertical direction along the rails 68 and 67. It is.

The gear motor 73 and the gear 74 connected to the gear motor 73 are attached to the upper part of the extraction chamber 70. The gear 74 rotates by driving the gear motor 73. The gear 74 is engaged with the top notch of the tooth plate 75. As the gear 74 rotates, the tooth plate 75 slides forward or backward with respect to the gear 74 in accordance with the rotational direction of the gear 74. The angle at which the arm 79 extends changes as the tooth plate 75 moves forward or backward. The height of the fixing member 64 changes as the angle at which the arm 79 extends changes.

10 and 11, the height change of the fixing member 64 in accordance with the rotation of the gear 74 will be described. 10 shows a state in which the fixing member 64 is in the standby position in the extraction apparatus 1, and FIG. 11 shows a state in which the fixing member 64 is in the position at the time of the extraction operation.

The other end of the arm 79 is attached to the fixing member 64, and one end of the tube 63 is attached. In addition, an introduction needle 65 is attached to one end of the tube 63. The extraction cup 100 is set in the cup holder 32 of the cup holder 31. In the state shown in FIG. 10, the front end of the tooth plate 75 is fitted with the gear 74. Then, the gear motor 73 rotates in a constant direction (the direction of rotating the gear 74 in the counterclockwise direction in FIG. 10), so that the tooth plate 75 is in the right direction in the FIG. 10 (in the extraction apparatus 1). Forward direction]. As the tooth plate 75 proceeds in the right direction in FIG. 10, one end of the arm 79 (the end attached to the tooth plate 75) also does not change its height in the right direction in FIG. 10. Proceeding, the other end of the arm 79 moves the fixing member 64 downward along the rails 68 and 67.

When the rotation of the gear 74 is performed until the rear end of the tooth plate 75 (left end in FIG. 10) reaches the position where the gear 74 fits with the gear 74, the fixing member as shown in FIG. 11. 64 contacts the upper surface of the cup 100 for extraction and presses the said cup 100 for downward. In addition, in the state shown in FIG. 11, the introduction needle 65 is inserted inside from the upper surface of the cup 100 for extraction.

The bottom part of the cup holder 31 is provided with the hollow extraction needle 31C and the extraction path 31D connected to the extraction needle 31. In the state shown in FIG. 10, the extraction cup 100 is set in the state which floated from the extraction needle 31C. In the state shown in FIG. 11, the extraction cup 100 is pressed downward by the cup holder 31 together with the cup support 32. As a result, the extraction needle 31 is inserted into the bottom of the extraction cup 100. Then, when hot water is introduced into the extraction cup 100 from the tube 63 via the introduction needle 65 in the state shown in Fig. 11, the extraction liquid generated in the extraction cup 100 is extracted needle 31C and It flows into the funnel 33 via the extraction path 31D, and is provided to containers, such as the cup 400, via the extraction opening 33A.

As described above, when the extraction operation is performed, the gear motor 73 rotates so that the fixing member 64 moves downward, the introduction needle 65 is inserted into the extraction cup 100, and the extraction is performed. The needle 31C is inserted into the bottom of the extraction cup 100. In addition, when the extraction operation is completed, the gear motor 73 is rotated in the reverse direction to the above-described constant direction to return to the state shown in FIGS. 11 to 10. As a result, the introduction needle 65 and the extraction needle 31C are separated from the extraction cup 100.

In addition, the switch 86 is fixed to the fixing member 64. The switch 86 is provided with a lever 86A, and is configured such that the opening and closing of the circuit is switched by pressing the lever 86A upward. In the state shown in Fig. 10, the lever 86A is not pressed. In the state shown in Fig. 11, the lever 86A is pushed upward by the extraction cup 100 and the main body of the switch 86. Is housed inside. Thereby, if the extraction cup 100 is set in the cup support 32, when the fixing member 64 is moved downward as shown in FIG. 11, the extraction cup 100 will switch 86 The switching of the circuit is switched.

In addition, although illustration is abbreviate | omitted in FIG.10 and FIG.11, the fixing member 64 is equipped with the part which contacts the arm 29A of the drawer 29. As shown in FIG. Fig. 12 is a diagram showing a state where the fixing member 64 and the drawer 29 partially contact when the extraction operation is performed. 10 and 11 are views of the inside of the extraction chamber 70 viewed from the left side, and the arm 29A is omitted to show the interior of the extraction cup 100. FIG. The inside of 70 is the figure seen from the left side, and the state seen from the left side more than the arm 29A is shown. In addition, in the state shown in FIG. 12, the fixing member 64 is in the position when the extraction operation | movement is performed like the state shown in FIG.

The fixing member 64 is provided with the pin 64A extended downward in the left end part. Moreover, the drawer 29 is provided with the convex part 290 in the left side surface of the arm 29A. And when the drawer 29 is accommodated in the extraction chamber 70, and the extraction cup 100 will be in the position suitable for an extraction operation | movement, the convex part 290 will be rear behind the pin 64A (FIG. 12). On the left). In this state, even when the drawer 29 is to be pulled forward (right side in Fig. 12), the convex portion 290 is caught by the pin 64A, and withdrawal is prevented. That is, in the extraction apparatus 1, when the extraction operation is being performed, pulling out the drawer 29 is prevented. As a result, the boiling water introduced from the introduction needle 65 is scattered.

In addition, although illustration is abbreviate | omitted in FIGS. 10-12, the extraction apparatus 1 is equipped with the switch (door switch mentioned later) which detects that the drawer 29 is in the position suitable for an extraction operation. By the detection output of the switch, the drawer 29 has a suitable position for the extraction operation (the extraction cup 100 set in the cup support 32 is introduced into the needle 65 and the extraction needle as shown in FIG. 11). Position at which the 31C is inserted] can be detected.

6 to 8, the partition plate 82, which is inside the exterior part 2 and behind the dust box 42 and the partition plate 85, is provided with a water repellent member such as plastic. Above the plate 82, a pump case 80 is provided. The gear pump 6 is accommodated in the pump case 80. In addition, a circuit board 66 is attached to the lower surface of the partition plate 82. The positional relationship of the partition plate 82, the pump case 80, and the circuit board 66 is shown in FIG.

Referring back to FIG. 13, a partition plate 83 is provided between the circuit board 66 and the water storage tank 5. In addition, a partition plate 84 is provided in front of the storage tank 5. Various circuit components, such as a circuit for driving the gear pump 6 in the extraction apparatus 1, are mounted in the circuit board 66. As shown in FIG. In the inside of the exterior part 2 of the extraction apparatus 1, the pipe | tube through which hot water, such as the pipe | tube 62 and 63, passes is arrange | positioned at the upper part, and the circuit board 66 is arrange | positioned under it. Thereby, even if heat | fever leaks from the pipes 62 and 63, it can avoid that the heat | fever transfers to the circuit board 66. In addition, the upper part of the circuit board 66 is covered by the partition plate 82. As a result, even in the case of condensation on the outer surfaces of the tubes 62 and 63 or in the case of cracks in the tubes 62 and 63, the water droplets based on the condensation can be prevented from directly adhering to the circuit board 66. Can be. In addition, by providing the partition plates 83 and 84, the diffusion of steam generated in the vicinity of the water storage tank 5 into the exterior part 2 is suppressed.

The gear case 6 is accommodated in the pump case 80, and the motor 81 which drives the gear pump 6 is attached to the gear pump 6, but most of it protrudes out of the case 80. . FIG. 14 shows the internal structure of the pump case 80 shown in FIG. 14 shows a state in which the cross section of the pump case 80 is viewed from above.

Referring to Fig. 14 again, the pipes 62 and 63 penetrate the pump casing 80 to connect to the gear pump 6 in the pump casing 80. On the inner wall of the pump case 80, there is attached a sound absorbing member 80A for absorbing the sound generated when the gear pump 6 sends hot water. Thereby, the noise at the time of extraction operation in the extraction apparatus 1 is suppressed. In addition, since at least a part of the motor 81 is exposed to the outside of the pump case 80, even when the motor 81 is driven, heat dissipation of the motor 81 is sufficiently performed.

6 to 8, the heater 50 is provided in the water storage tank 5. A part of the heater 50 has a spiral structure. Thus, since the heater 50 has a spiral structure, the hot water in the bottom tank 5 can be heated more powerfully and faster than the heater is comprised only by a linear structure, and the preparation time for extraction can be shortened. In addition, the spiral structure is located in the upper half of the water storage tank 5, for example, the area of the upper half of the water storage tank 5. In this manner, by bringing the spiral portion close to the outflow passage 52, hot water having a high temperature can be efficiently supplied to the cup 100 for extraction.

Next, the structure near the bottom of the water storage tank 5 will be described with reference to FIG. 15 shows a longitudinal section of the storage tank 5 and the nut 58 attached to the bottom of the storage tank 5 and the side surface of the drain cock 57 and the operation lever 55. The drain cock 57 is connected with a drain pipe 56 to the connection cylinder 57A.

The nut 58 is provided with the cylinder part 58B extended in the vertical direction with the horizontal surface 58A. The horizontal surface 58A has a shape in which a disk has a cutout portion 58X partially formed inwardly from its outer peripheral portion. 16 shows a plan view of the nut 58. The cutout part 58X which is connected to the cavity part in the cylinder part 58B is formed in the horizontal surface 58A, and the nut 58 has the hole which penetrated in the vertical direction. Moreover, the wall surface of the lower part of the water storage tank 5 has inclination. When the operation lever 55 is opened and the hot water is discharged from the water storage tank 5 via the drain cock 57 to the drain pipe 56, the water is discharged from the bottom wall of the water storage tank 5 by the inclination of the lower wall surface. Are gathered. The hot water collected at the bottom center and near the nut 58 is led from the cutout portion 58X to the drain cock 57 from the cavity in the tube portion 58B. As a result, when the operation lever 55 is opened, the hot water in the water storage tank 5 is led to the drain pipe 56 via the drain cock 57 without remaining.

17 shows an enlarged view of the connection portion between the steam pipe 59 and the water storage tank 3. As for the steam pipe 59, the inside diameter of the part 59A which connects with the water storage tank 3 is small in the water storage tank 3 side. Thereby, even if the hot water in the storage tank 5 invades the steam pipe 59, it can avoid that the hot water flows into the water storage tank 3. As shown in FIG. Therefore, even if a large amount of hot water is mixed into the steam pipe 5 even temporarily, the steam pipe 5 may be a circulation path of the hot water, or the water may enter the vicinity of the connection portion with the steam pipe 5 in the reservoir tank 3. Even if it is, the situation where a hot water (or water) circulates between the water storage tank 3 and the water storage tank 5 can be avoided. Thereby, water circulates between the water storage tank 3 and the water storage tank 5, and the heater 50 of the water storage tank 5 is the same temperature as the water in the water storage tank 5 even the water in the water storage tank 3 is carried out. If it does not heat up to this point, the situation which extraction will not start can be avoided. In order to guide much of the steam in the steam pipe 59 to the water storage tank 3, the position in which the inner diameter changes like the portion 59A in the steam pipe 59 is preferably a position close to the water storage tank 3, The position where (3) and the steam pipe 59 connect is more preferable.

18 shows an enlarged view of the vicinity of the outflow passage 52 provided in the upper portion of the storage tank 5. The outflow path 52 is connected with the pipe 53. In the vicinity of the outflow passage 52, a sensor hole 54A in which the temperature sensor 54 is set is formed. 18, illustration of the temperature sensor 54 is omitted.

When the outflow path 52 is connected with the pipe 53, the lower end part of the outflow path 52 becomes an opening of the water storage tank 5 side of the pipe which flows hot water to the gear pump 6. As shown in FIG. A rectifying member 52A is attached to the lower portion of the outlet passage 52 so as to face the vertical direction at a distance from the opening to the lower end opening of the outlet passage 52. By attaching the rectifying member 52A, the hot water is introduced into the outflow path 52 from the vertical direction (the arrow P direction in FIG. 18) when the hot water in the water storage tank 5 is sucked from the lower end of the outflow path 52. Will not be. Specifically, the hot water is mainly introduced into the outflow path 52 from the direction (arrow Q direction in FIG. 18) along the inner wall of the rectifying member 52A. Thereby, even if bubbles generate | occur | produce when a hot water is heated in the boiling water tank 5, it is possible to avoid that the bubbles are sucked into the gear pump 6 via the outflow path 52 and the pipe 53. In the extraction apparatus 1, the gear pump 6 is used to introduce a predetermined amount of hot water into the extraction cup 100. And the extraction apparatus 1 is equipped with the rectifying member 52A, and it is avoided that air is sent to the gear pump 6, and can introduce a predetermined amount of hot water into the extraction cup 100 accurately by this. .

Next, the control content of the overall operation performed in the extraction apparatus 1 will be described. 19 and 20 show flowcharts of a control process of a general operation executed by a central processing unit (CPU) included in the extraction device 1. In addition, the CPU can electrically control the operation of all members in the extraction apparatus 1.

In the following description of the control process, the setting switch (setting SW) corresponds to whether the water supply to the water storage tank 3 is manually corresponded by the user in the extraction apparatus 1 or automatically corresponding to a predetermined water supply apparatus. It is a switch for setting, and is a switch provided on the circuit board 66.

The water level detection switch (water level detection SW) is a switch which is turned on when the water level sensor 30 detects water, and the detection output is a switch output to a predetermined circuit on the circuit board 66. By the detection output of the water level detection switch, it is possible to detect whether or not the water level in the water storage tank 3 is up to the height at which the water level sensor 30 is provided. In addition, the water level sensor 30 is installed in the water storage tank 3 relatively lower in this embodiment.

Further, the door switch (door SW) is a switch for detecting that the drawer 29 described above is in a position suitable for the extraction operation, and is turned on when the drawer 29 is accommodated in the extraction chamber 70 and is in a position suitable for the extraction operation. And the drawer 29 is turned off by withdrawing from said suitable position.

Further, the front switch (front SW) is a switch 78, and the rear switch (rear SW) is a switch 77. Here, the operation of the switches 77 and 78 will be described in detail with reference to FIG. 7 again in connection with the moving aspect of the tooth plate 75. The switch 78 is switched on and off by pressing the plate member 78A in the direction of the arrow RB. The switch 77 is switched on and off by pressing the plate member 77A in the direction of the arrow RA. The tooth plate 75 is provided with a convex portion 76 on the side surfaces of the switches 77 and 78.

The start switch (start SW) is a switch that is turned on by the start button 21 or the start button 22 being pressed.

When the gear motor 73 rotates in a predetermined direction and the tooth plate 75 moves in the direction of the arrow RB, when the front end of the convex portion 76 pushes the plate member 78A in the direction of the arrow RB, the switch 78 Is on. Thereby, the electricity supply to the gear motor 73 is stopped. In addition, when the tooth plate 75 moves in the arrow RA direction from this state, and the press of the board member 78A is released by the convex part 76, the switch 78 will turn off.

On the other hand, when the gear motor 73 rotates in the direction opposite to the predetermined direction and the tooth plate 75 moves in the direction of the arrow RA, the rear end of the convex portion 76 moves the plate member 77A in the direction of the arrow RA. When pressed (state shown in Fig. 7), the switch 77 is turned on. Thereby, the electricity supply to the gear motor 73 is stopped. In addition, when the tooth plate 75 moves in the arrow RB direction from this state, and the press of the plate member 77A is canceled by the convex part 76, the switch 77 will turn off.

That is, the tooth plate 75 is moved by the rotation of the gear motor 73, so that the switches 77 and 78 are switched on and off. In addition, the tooth plate 75 is moved in the range from the position where the convex part 76 presses the plate member 77A to the position which presses the plate member 78A.

The cup detection switch (cup detection SW) is a switch which is turned on by the lever 86A being accommodated in the main body of the switch 86. That is, it is a switch for detecting the presence or absence of the extraction cup 100 and whether the extraction cup 100 is in a position suitable for an extraction operation.

Referring again to FIG. 19, when electric power is supplied to the extraction apparatus 1 from the outside, the CPU first detects on / off of the setting SW in step S1 (hereinafter, the step is omitted). In addition, whether or not electric power is supplied from the outside to the extraction device 1 is switched by operating the power switch 99 (see FIG. 3 and the like) attached to the rear part of the extraction device 1. Then, when the setting SW is turned on (the extraction device 1 is set to be manually supplied to the water storage tank 3), the process proceeds to S3. On the other hand, when the setting SW is turned off (the extraction device 1 is set to be automatically supplied to the water storage tank 3), the processing proceeds to step S2.

In step S2, the CPU outputs a signal to open the water supply solenoid valve and advances the process to step S3. The solenoid valve for water supply is a valve connected to the water storage tank 3, and water is introduced into the water storage tank 3 by opening and closing, and the introduction of water into the water storage tank 3 is stopped.

In step S3, the CPU turns on the water replenishment LED (lamp 26) in step S4 until the detection output of the water level detection SW is turned on, that is, until water is detected at the position of the water level sensor 30. It lights up and a process progresses to step S5.

In step S5, on / off of the setting SW is detected in the same manner as in step S1, and the process advances to step S8 when it is on, and to S6 when it is off. In addition, in FIG. 19, the case where setting SW is ON is described as the case where the CPU judged yes.

In step S6, by waiting for 15 seconds to elapse after the process of step S5 by referring to a predetermined timer. After 15 seconds have elapsed, the signal for closing the water supply solenoid valve is output in step S7, and the process proceeds to step S8.

In step S8, the CPU judges whether or not the water temperature detected by the temperature sensor 54 exceeds 97 ° C. If the water temperature is 97 ° C or less, the heater 50 is turned on in step S9 to start heating, and in step S10. The LED (lamp 24) lights up during preparation. Heating in step S9 is continued until it is determined in step S11 that the water temperature has reached 97 ° C. When it is determined in step S11 that the water temperature has reached 97 ° C, the CPU turns off the heater 50 in step S12 and proceeds to step S13.

From the above, in the extraction apparatus 1, in the process of S1-S12, control content changes according to the setting content of the water supply aspect to the water storage tank 3 in setting SW. That is, when setting SW is set to ON, heating is started as it is detected that water exists in the position where the water level sensor 30 is installed. On the other hand, when the setting SW is set to OFF, the water supply solenoid valve is opened for 15 seconds after it is detected that there is water in the position where the water level sensor 30 is installed. The valve is closed and heating is started. From this, in this embodiment, the introduction signal output part is comprised by CPU, and the water introduction setting part is comprised by setting SW. The case where the setting SW is set to off corresponds to the case where the water introduction setting section outputs a water introduction signal.

Then, the CPU turns on the lamp 25 in step S13, and detects whether the door SW is off in step S14. If it is off, the process advances to S15, and if it is not detected that it has been off once since the previous extraction operation, the process returns to step S8.

In step S15, the CPU waits for the door SW to be turned on and advances the processing to step S16. In step S16, the CPU flashes the lamp 25 to advance the processing to step S17. In step S17, the CPU detects whether or not the start SW is turned on. Further, the CPU repeats the processing of steps S16 to S17 until it detects that the start SW is on, and advances the process to step S18 when detecting that the start SW is on.

In step S18, the gear motor 73 is driven in the forward rotation direction. In addition, the forward rotation refers to the rotation in the direction to move the tooth plate 75 forward. Thereby, the tooth plate 75 changes from the state shown in FIG. 10 to the state shown in FIG.

When the CPU detects that the front SW is turned on in step S19, the CPU stops the rotation of the gear motor 73 in step S20 to advance the processing to step S21.

In step S21, the CPU judges whether or not the cup detection SW is on, and if it is on, executes the extraction operation in step S22 and then advances the process to step S24. Details of the processing contents of the extraction operation of step S22 will be described later with reference to FIG. On the other hand, when the cup detection SW is not turned on, the CPU issues an error notification by a buzzer or the like in step S23 to advance the processing to step S24.

In step S24, the CPU drives the gear motor 73 in the reverse direction until the rear SW is turned on (YES in step S25), and stops the rotation of the gear motor 73 in step S26 to step S27. Proceed with processing.

In step S27, it is judged whether or not the water level detection SW is on, and the process advances to step S8 if it is on, and to step S1 if not.

In the process described above, the drive of the gear motor 73 is stopped by turning on the front SW or the rear SW. In addition, in this embodiment, the drive stop of the gear motor 73 is performed in two steps. The driving stop of the gear motor 73 will be described with reference to FIG. 22 is a circuit diagram of a portion of the circuit provided on the circuit board 66 related to the drive of the gear motor 73.

In the circuit diagram shown in Fig. 22, a gear motor 73, switches 77 and 78, discharge resistors 177 and 178, a relay 170 and an integrated circuit (IC) 175 are connected. The switches 77 and 78 are configured to close the circuit by pressing the plate members 77A and 78A to the convex portion 76, respectively, and to open the circuit when the pressing is released. The relay 170 includes switches 171 and 172 for switching the rotation direction of the gear motor 73. The switches 171 and 172 are provided with three contacts 171A to 171C and 172A to 172C, respectively. IC 175 controls the drive on / off of gear motor 73. In addition, the rotation direction of the gear motor 73 is controlled by controlling the opening and closing of the circuit by the switches 171 and 172 in accordance with a control signal from a circuit (not shown).

When driving the gear motor 73 in the forward rotation direction, the contact 171A and the contact 171B are connected at the switch 171, and the contact 172A and the contact 172B are connected at the switch 172. On the other hand, when driving the gear motor 73 in the reverse rotation direction, the contact 171B and the contact 171C are connected at the switch 171, and the contact 172B and the contact 172C are connected at the switch 172. do. The contacts P1 and P2 in the circuit shown in FIG. 22 are connected to a circuit capable of supplying direct current power. That is, the drive direction of the gear motor 73 is reversed by reversing the direction of the electric current which flows into the gear motor 73.

When the drive of the gear motor 73 is stopped, the output from the IC 175 is turned off. In addition, in this embodiment, the switching of the circuit by the switches 77 and 78 is also switched.

Specifically, when the drive of the gear motor 73 is stopped in the forward rotation direction, the convex portion 76 presses the plate member 78A so that the switch 78 closes the circuit. As a result, the gear motor 73 is stopped from the supply of electric power by the IC 175, and the current remaining in the vicinity thereof is consumed by the discharge resistor 178. In the circuit shown in Fig. 22, when the gear motor 73 is driven in the forward rotation direction, current flows in the direction of the arrow L2 in the figure. Thus, when the switch 78 closes the circuit, the current remaining around the gear motor 73 by the diode 178A is efficiently consumed by the discharge resistor 178 and flows into the gear motor 73. You can stop being.

On the other hand, when the drive of the gear motor 73 is stopped in the reverse rotation direction, the convex portion 76 presses the plate member 77A so that the switch 77 closes the circuit. As a result, the gear motor 73 is stopped from the supply of electric power by the IC 175, and the current remaining in the vicinity thereof is consumed by the discharge resistor 177. In the circuit shown in Fig. 22, when the gear motor 73 is driven in the reverse rotation direction, current flows in the direction of the arrow L1 in the figure. Thus, when the switch 77 closes the circuit, current remaining around the gear motor 73 by the diode 177A is efficiently consumed by the discharge resistor 177 and flows into the gear motor 73. You can stop being.

As described above, in the present embodiment, the driving stop of the gear motor 73 is performed in two stages using the IC 175 and those using the switches 77 and 78. As a result, the gear motor 73 can be reliably stopped when the gear motor 73 is to be stopped. Therefore, the fixing member 64 is reliably stopped at the standby position shown in FIG. 10 or FIG.

21 is a flowchart of a subroutine of the extraction operation processing of step S22. Hereinafter, the contents of the extraction operation processing will be described in detail.

In the extraction operation process, the CPU judges whether the start SW turned on in step S221 is caused by the pressing of the start button 21 corresponding to hot, and if so, the process proceeds to step S222. On the other hand, processing proceeds to step S224.

In step S222, the CPU introduces a predetermined amount of hot water for 20 seconds by sending hot water into the gear pump 6 in the extraction cup 100, and then in step S223, the valve of the three-way solenoid valve 60 is removed. By switching, the introduction needle 65 and the intake hole 61 are connected, and air is sent to the gear pump 6 to the extraction cup 100 for 10 second, and it returns.

On the other hand, in step S224, the CPU determines whether the start SW is turned on because the start button 22 corresponding to the ice is pressed. Then, the process advances to step S225. In addition, when it cannot be determined that it is due to the press of the start button 22 in step S224, the CPU returns the processing to step S221 again.

In step S225, a part of the predetermined amount of water is introduced over 6 seconds by sending the water to the gear pump 6 in the cup 100 for extraction, and then waits for 2 seconds in step S226. Then, the remaining amount of the predetermined amount of water is introduced into the cup 100 for brewing for 12 seconds, and then the introduction needle 65 and the intake hole 61 are connected by switching the valve of the three-way solenoid valve 60. The air is returned to the gear pump 6 by the cup 100 for extraction for 10 seconds.

The extraction device 1 may be set to introduce different amounts of hot water into the extraction cup 100 for each of hot and ice. 23 shows a circuit diagram of a portion of the circuit provided on the circuit board 66 for setting the introduction amount of the hot water.

The circuit shown in Fig. 23 includes a motor 81, an IC 10, transistors 90 and 98, switches 91 to 97, resistors 11 to 17, and a resistor 18 for driving a gear pump 6; , 19). The transistors 90 and 98 are connected to a circuit for controlling the ice extraction operation (ICE control circuit) and a circuit for controlling the hot extraction operation (HOT control circuit), respectively. The IC 10 is connected to a circuit (extraction control circuit) for controlling the entire extraction operation.

Switches 91 to 93 and resistors 11 to 13 are connected in series to the transistor 90. The switches 98 to 97 and the resistors 14 to 17 are connected in series to the transistor 98. The resistors 11 to 17 are connected in parallel with the resistor 18 and in series with the resistor 19.

In the extraction apparatus 1, when the extraction operation for ice is performed, the transistor 90 is turned on. At this time, the voltage supplied to the motor 81 is determined by dividing the combined resistance between any one of the resistors 11 to 13 and the resistor 18 and the resistor 19. Since the voltage value supplied to the motor 81 drives the gear motor 6, it corresponds to the amount of hot water introduced into the extraction cup 100. That is, when the ice extraction operation is performed, the extraction amount in the ice extraction operation is set by closing the circuit with any of the switches 91 to 93. In the extraction device 1, the transistor 98 is turned on when the hot extraction operation is performed. The extraction amount in the hot extraction operation is set by closing the circuit with any of the switches 94 to 97 as in the ice extraction operation. In addition, the extraction amount in each case is determined by appropriately adjusting the resistance values of the resistors 11 to 17.

That is, the hot water amount designation part which designates the quantity of hot water sent to the gear pump 6 by one time of hot water supply operation by the switches 91-97 is comprised. Moreover, it is preferable that it is comprised so that a user can set whether the circuit is closed by any of the switches 91-97.

24 and 25 show timing charts in the extraction operation processing shown in FIG. 24 corresponds to the hot extraction operation, and FIG. 25 corresponds to the ice extraction operation. 24 and 25 show a driving mode of the gear motor 73, a driving mode of the three-way solenoid valve 60, and a driving voltage of the gear pump 6.

Referring to Fig. 24, when the hot extraction operation process is started, the gear motor 73 is driven for about 1 second in the forward rotation direction. As a result, the fixing member 64 descends to a position suitable for the extraction operation. Thereafter, the three-way solenoid valve 60 connects the tube 63 with the tube 53, and the gear pump 6 is driven for 20 seconds at a driving voltage of 18V. As a result, hot water is supplied to the cup 100 for extraction as described in step S222 for 20 seconds.

Thereafter, the three-way solenoid valve 60 connects the tube 63 with the intake hole 61, and the gear pump 6 is driven for 10 seconds at a driving voltage of 22V. As a result, as described in step S223, air is sent into the extraction cup 100 for 10 seconds. Thereafter, the gear motor 73 is driven in the reverse direction for about 1 second, so that the fixing member 64 is raised to the standby position.

Referring to Fig. 25, when the extraction operation for ice is started, the gear motor 73 is driven for about 1 second in the forward rotation direction. As a result, the fixing member 64 descends to a position suitable for the extraction operation. Thereafter, the three-way solenoid valve 60 connects the tube 63 with the tube 53, and the gear pump 6 is driven for 6 seconds at a driving voltage of 12V. Thereby, hot water supply to the extraction cup 100 is performed for 6 second as demonstrated in step S225. Thereafter, the drive of the gear pump 6 is stopped for 2 seconds to correspond to the process of step S226, and is driven again to the drive voltage of 12 V for 12 seconds to correspond to the process of step S227.

Thereafter, the three-way solenoid valve 60 connects the tube 63 with the intake hole 61, and the gear pump 6 is driven for 10 seconds at a driving voltage of 22V. As a result, as described in step S223, air is sent into the extraction cup 100 for 10 seconds. Thereafter, the gear motor 73 is driven in the reverse direction for about 1 second, so that the fixing member 64 is raised to the standby position.

In the hot or ice extraction operation described above, the extraction operation is performed for 30 seconds after the fixing member 64 is lowered to a position suitable for the extraction operation, and air is sent to the extraction cup 100 for the last 10 seconds. Moreover, the drive voltage of the gear pump 6 at the time of sending air to the extraction cup 100 in the last 10 second is higher than the drive voltage at the time of sending hot water. As a result, air is strongly transferred to the extraction cup 100. Therefore, more extract liquid remaining in the extraction cup 100 can be supplied to the cup 400 or the like.

In addition, in hot and ice use, the extraction amount is changed by changing the voltage value for driving the gear pump 6 when supplying hot water in the same time. Also, the drive voltage of the gear pump 6 is changed as described with reference to FIG. As described above, in the present embodiment, the extraction operation is performed within the same time even for hot or ice or even when the extraction amount is changed.

In the ice extraction operation shown in Fig. 25, the supply of the hot water is stopped by stopping the drive of the gear pump 6 for two seconds in the middle of the extraction operation. As a result, for example, in the case of obtaining an extract of coffee, the coffee beans in the extraction cup 100 can be distilled for 2 seconds to improve the flavor of the extract obtained.

In the present embodiment described above, a gear pump is used as a pump for sending hot water to the cup 100 for extraction. However, any pump of another type may be used as long as the pump sends a specified amount of hot water.

It should be thought that embodiment disclosed this time is an illustration and restrictive at no points. The scope of the present invention is disclosed by the claims rather than the foregoing description, and is intended to include any modifications within the scope and meaning equivalent to the claims.

With the above configuration, it is possible to provide an extraction device with good user convenience.

Claims (9)

It is an extraction apparatus for obtaining an extraction liquid through the said filter out of the said extraction container by supplying hot water into the extraction container which is a container containing a powder raw material and a filter, A tanbi tank for storing the hot water, A heater provided in the water tank; A reservoir tank for storing water for supplying the water tank; A sensor for detecting whether a specific amount of water is stored in the reservoir tank; An introduction signal output unit for outputting a water introduction signal, which is a signal for introducing water into the water storage tank; A water introduction setting unit for setting whether to output a water introduction signal to the introduction signal output unit; A heater control unit for controlling the operation of the heater, When the water introduction setting unit is set to output the water introduction signal, the introduction signal output unit has a predetermined time elapsed after the sensor detects that the water in the reservoir tank has reached the specific amount. After outputting the water introduction signal until the output of the water introduction signal is stopped, the heater control unit starts the heating by the heater after the output of the water introduction signal is stopped, When the water introduction setting section is set not to output the water introduction signal, the heater control unit starts heating with the heater as the sensor detects that the water in the reservoir tank has reached the specific amount. Extraction apparatus, characterized in that. The extracting apparatus according to claim 1, wherein the heat generating portion of the heater includes a portion having a spiral shape. It is an extraction apparatus for obtaining an extraction liquid through the said filter out of the said extraction container by supplying hot water into the extraction container which is a container containing a powder raw material and a filter, A tanbi tank for storing the hot water, A reservoir tank for storing water for supplying the water tank; A steam pipe configured to connect the water storage tank to the water storage tank, the steam pipe for introducing steam in the water storage tank into the water storage tank, The said steam pipe is an extraction apparatus characterized by the inner diameter of the said water storage tank side being smaller than the said water tank tank side partially. The extraction apparatus according to claim 3, wherein the steam pipe has a smaller inner diameter at the water storage tank side than at the water tank at the connection portion to the water storage tank. The extraction apparatus according to claim 1, wherein the water storage tank is configured so that at least a part of the water storage tank can determine the quantity of water in the storage tank from the outside of the extraction apparatus. It is an extraction apparatus for obtaining an extraction liquid through the said filter out of the said extraction container by supplying hot water into the extraction container which is a container containing a powder raw material and a filter, A tanbi tank for storing the hot water, It includes a heater provided in the water tank, Extraction apparatus characterized in that the heat generating portion of the heater comprises a portion having a spiral shape. According to claim 6, wherein the tank tank is provided with an outlet for outflow of the stored reservoir for supplying the hot water to the extraction container, The heating part of the said heater is provided with the part which has the said spiral shape in the vicinity of the said outlet of the said water tank. It is an extraction apparatus for obtaining an extraction liquid through the said filter out of the said extraction container by supplying hot water into the extraction container which is a container containing a powder raw material and a filter, A tanbi tank for storing the hot water, A heater provided in the water tank; A pump for sucking in the hot water in the hot water tank and sending it to the extraction container; A suction pipe through which the hot water flows from the hot water tank to the pump; And a rectifying member, which is a member opposed to a direction perpendicular to the opening of the sludge tank side of the suction pipe. The apparatus of claim 1, further comprising: an opening / closing portion connected to the tangy tank for opening or closing the tangy tank to switch whether or not to discharge the hot water in the tangy tank, The water tank is provided with a discharge hole in a portion connected to the opening and closing portion, and further provided with a nut for connecting with the opening and closing portion, An extraction device according to claim 1, wherein the nut has a cutout portion connected to the discharge hole from an outer circumferential portion of the nut.