JP5972319B2 - Dashi soup production equipment - Google Patents

Description

The present invention relates to equipment for the manufacture of a broth for use such as noodles, about the particular broth production equipment employing a negative pressure circulating extraction method.

  When cooking various foods, including noodles, dashi soup is the decisive factor. In the past, the soup stock was generally made by boiling off shavings that consist mainly of dried seafood, but in recent years, the use of soup stock packs has increased.

Such dashi soup is naturally in demand at restaurants. Moreover, it requires a larger amount of soup stock than ordinary households. Therefore, conventionally, a soup stock producing apparatus capable of efficiently producing soup stock has been developed and widely used in restaurants.
For example, in Patent Document 1, water and a soup pack (bonito pack) are placed in a soup stock extraction tank (first tank (3)) and heated with a heater (heater heater (5)) at a predetermined temperature for a predetermined time. An apparatus for producing broth by boiling is described (see paragraphs 0006 to 0016, etc.).
Since this apparatus boiles the dashi pack and extracts the dashi stock, it can be said that it is a boiled extraction type dashi stock production apparatus.

  On the other hand, soup stock is produced by a drip extraction method, but a juice production apparatus has been proposed.

For example, in Patent Document 2, a filter (53) is provided at the bottom, but a juice extraction tank (extraction vessel (51)) is provided, which is stored in this extraction tank, but hot water is sprayed onto the powder to extract the soup stock. Disclosed is a soup stock production apparatus. In this publication, “hot water heated by the heater (3) is sprayed onto the dough powder contained in the extraction container (51), and the dough powder and hot water are mixed in the extraction container (51) for a certain period of time. The soup is extracted by the filter (53), received by the receiving member (54) provided below the extraction container (51), and then sent to the heat retaining tank (7). " (See paragraph 0037).
The invention described in Patent Document 2 also uses a stirring action when extracting soup stock. In other words, the stirring tank (52) is provided in the extraction tank, and the hot water sprayed on the extraction tank is stirred. Regarding the action of the stirring honey (52), Patent Document 2 states that “the above-described hot water jetting action and the stirring honey stirring action promote the swaying of the soup stock in the hot water in the extraction section, so that it is stable and effective. Extraction can be performed "(see paragraph 0038).
As for dashi powder, “Doshi powder is preferably made into powdered form such as knots and niboshi using a mixer attached to the equipment” (see paragraph 0037). Is clearly stated.

Patent Document 3 also discloses a soup stock production apparatus that employs a drip extraction method.
In this apparatus, the inside of the extraction tank is divided up and down by a filter (108), and the upper part is an upper chamber (102) and the lower part is a lower chamber (103). Then, the shaving node (raw material for seasoning) is stored in the upper chamber (102) and hot water is supplied. At this time, the pressure in the lower chamber (103) is made higher than that in the upper chamber (102) to prevent the stock broth being extracted from dripping into the lower chamber (103) while stirring the stirring blade (104) to obtain the broth. Perform extraction. When the extraction of the soup stock is completed, the pressure in the lower chamber (103) is reduced, and the extraction is promoted to drop the juice into the lower chamber (103) (see paragraphs 0018 to 0052).

Japanese Patent Application Laid-Open No. 08-089205 JP 2006-158221 A JP 2005-040387A

Because the soup production system of the boiled extraction method uses hot water convection to extract the active ingredients of the dashi stock from shaving nodes and dashi packs,
(1) Ash juice comes out (2) Flavor is easy to escape (3) It takes time to extract soup stock (especially when using soup stock pack)
Has the problem.
The reason why it takes time to extract the soup stock when using the dashi pack is that hot water does not circulate sufficiently to the inside of the dashi pack.

On the other hand, the drip extraction type broth manufacturing apparatus is excellent in that the problems (1) and (2) are less likely to occur.
However, in order to extract enough active ingredients from the dashi stock, it is necessary to extract the soup stock by passing hot water once through the dashi stock. It is necessary to reduce the dropping speed and perform extraction slowly over time. For this reason, it can be said that the drip extraction type broth manufacturing apparatus inherently has the problem (3).
In addition to this, it is necessary to extract slowly over time,
(4) There is also a problem that the temperature of the stock after completion is lowered.

  As described above, there is a problem (problem (3) above) that it is difficult to extract a soup stock having a sufficient concentration in a short time, regardless of whether the boiled extraction method or the drip extraction method is adopted.

The present invention has been made in view of the above problems, an object of the present invention to provide a soup production equipment capable of sufficiently extracting the short time the active ingredient from soup ingredients.

The dashi stock production apparatus of the present invention is an extraction tank for storing supplied hot water, and is attached to the extraction tank so as to freely distribute hot water and detachably attach to the inside of the extraction tank so as to extract dashi stock. Yes of a set portion for placing the raw material out, the negative pressure chamber of the tufts (room) shape adjacent to the side surface located on the bottom surface and a lower positive pressure chamber located above the set portion in the extraction tank And a communication path that connects the negative pressure chamber and the positive pressure chamber at the center portion with a portion communicating with the side surface of the negative pressure chamber as an inlet and a portion communicating with the bottom surface of the positive pressure chamber as an outlet. A plurality of discharge ports provided on the outer peripheral portion facing the inlet and the water intake port facing the outlet, the impeller disposed rotatably in the communication path, and disposed outside the extraction tank. To drive the impeller A circulating pump that is rotated by the impeller driven by the motor and sucking hot water from the negative pressure chamber from the water suction port and discharging the hot water from the discharge port. By solving, the above-mentioned problem is solved.

  According to the present invention, hot water passes through and circulates the raw material placed on the set section many times, so that the active ingredient is sufficiently dissolved and the juice can be extracted in a short time.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic diagram which shows the principle of the soup stock manufacturing apparatus and the soup stock manufacturing method of embodiment, (a) is an example by which the temperature control unit for an extraction tank (the heater for an extraction tank and a temperature measuring body) is arrange | positioned in the negative pressure chamber. (B) is a schematic diagram which shows an example in which the temperature control unit for an extraction tank (the heater for an extraction tank and a temperature measuring body) is arrange | positioned in the positive pressure chamber, respectively. The perspective view which shows one Embodiment of a soup stock manufacturing apparatus. The side view which shows a part of internal part virtually. The schematic diagram which shows an example of schematic structure of a soup stock manufacturing apparatus. The front view of an operation panel. The block diagram which shows the electrical connection of each part. The flowchart which shows the flow of a hot water storage process. The flowchart which shows the flow of a soup stock extraction process. The flowchart which shows the flow of a stirring process, a soup stock transfer process, and a white soup pouring process. The flowchart which shows the flow of stock soup heat insulation pouring processing. The schematic diagram which shows an example of the schematic structure as a modification of a soup stock manufacturing apparatus. The schematic diagram which shows an example of the schematic structure as another modification of a soup stock manufacturing apparatus.

Embodiments will be described with reference to the drawings.
First, the principle of the soup stock production method using the soup stock production apparatus of the present embodiment will be described based on FIGS. 1 (a) and 1 (b), and then the embodiment will be described in detail based on FIGS. 11 and 12 show a modification.
The description items are as follows.
1. Principle of soup stock production method Embodiment (1) Appearance configuration (2) Internal configuration
(A) Extraction tank
(B) Hot water storage tank
(C) Thermal insulation tank
(D) Operation unit (first operation panel)
(3) Hardware configuration (4) Program processing
(A) Hot water storage treatment
(B) Dashi stock extraction process, stirring process, dashi stock transfer process, white dashi pouring process
(B-1) Dashi soup extraction process
(B-2) Stir processing and soup stock transfer processing
(B-3) White stock pouring process
(C) Dashi stock warming pouring process (5) Effect (6) Modification
(A) Modification 1
(B) Modification 2
(C) Modification 3
(D) Modification 4
(E) Modification 5

1. Principle of soup stock production method The soup stock production apparatus 1 according to the present embodiment includes an extraction tank 101 for storing the supplied hot water, and extracts the stock soup from the stock material dm of the stock inside the extraction tank 101. As the dashi raw material dm, dashi pack dm1 (see FIGS. 1 (a) and 1 (b), FIG. 3, FIG. 4, FIG. 12) or shaving node dm2 (see FIG. 11) is used.

  The extraction tank 101 includes a set unit 102 on which the raw material dm is placed, and the set unit 102 partitions the inside vertically. The positive pressure chamber 103 is located above the set portion 102 and the negative pressure chamber 104 is located below. The set part 102 is a casing having a depth enough to store the raw material dm so that hot water can freely flow between the positive pressure chamber 103 and the negative pressure chamber 104. The flow member 102a is provided at the bottom. The flow member 102a is formed of a porous material such as a wire mesh or punch metal.

  In the soup stock producing apparatus 1, the positive pressure chamber 103 and the negative pressure chamber 104 are connected by a tubular communication path 105, and a circulation pump P1 (see also FIG. 6) is interposed in the communication path 105. Circulation pump P1 is a centrifugal pump that rotates an impeller and transfers fluid by centrifugal force.

In order to obtain the soup stock under such a configuration, first, the stock material dm is placed on the set part 102.
Next, hot water HW is supplied to the extraction tank 101. Hot water HW flows through the raw material dm of dashi and a flow member 102 a provided at the bottom of the set unit 102, and is filled in the positive pressure chamber 103 and the negative pressure chamber 104.
When the extraction tank 101 is filled with hot water HW, the circulation pump P1 is operated. Then, the hot water HW in the extraction tank 101 is sucked into the suction side of the circulation pump P1 and sucked into the communication path 105, discharged from the discharge side of the circulation pump P1, and returned to the positive pressure chamber 103. At this time, since the negative pressure chamber 104 becomes negative pressure, the hot water HW flows from the positive pressure chamber 103 into the negative pressure chamber 104. Thus, the hot water HW circulates between the negative pressure chamber 104 and the positive pressure chamber 103.

At this time, during the process in which the hot water HW flows from the positive pressure chamber 103 to the negative pressure chamber 104, the active ingredient of the stock dm dissolves in the hot water HW, and the stock is extracted. Then, the hot water HW in which the active ingredient of the soup stock dm is dissolved is returned to the positive pressure chamber 103, and is again circulated through the soup stock dm to the negative pressure chamber 104, whereby the concentration of the stock extracted Will gradually increase.
Therefore, a high-concentrated soup stock in which the active ingredient is sufficiently dissolved is extracted in a short time.

In this way, the present embodiment produces the soup stock according to the operation principle that should be called a circulation system using negative pressure, that is, a “negative pressure circulation extraction system”. The negative pressure circulation extraction method is different from the boiled extraction method, and it is not necessary to boil the stock dm of the dashi stock when extracting the dashi.
by this,
-The effect that a high concentration stock broth can be extracted in a short time is acquired.

This effect is particularly great when using a dashi pack.
This is because the boiled extraction method uses hot water convection to gradually extract dashi while circulating hot water in the dashi stock, so when using a dashi pack it is difficult for hot water to reach the inside. It takes a long time to extract.
On the other hand, in the negative pressure circulation extraction system, hot water HW is drawn from the positive pressure chamber 103 into the negative pressure chamber 104 using the negative pressure generated in the negative pressure chamber 104, so that the dashi pack dm1 is a flow member of the set unit 102. The hot water HW passes through the entire surface of the pack dm1.
For this reason, the hot water HW can be evenly distributed throughout the dashi pack dm1, and the dashi can be extracted in a relatively short time.

In addition, compared to the boiled extraction method, the stock extraction method using the negative pressure circulation extraction method is
・ Suppresses the generation of lye as much as possible ・ No worries about spilled or boiled ・ Excellent in that the flavor is difficult to escape.

The stock extraction method using the negative pressure circulation extraction method is also clearly different from the drip extraction method.
In the drip extraction method, hot water passes through the dashi raw material (corresponding to dashi raw material dm in the present embodiment) only once. For this reason, even if it takes a long time to distribute hot water, there is a tendency that it is difficult to extract a high concentration of soup stock in which the active ingredients are sufficiently dissolved.
On the other hand, the dashi extraction method using the negative pressure circulation extraction method, compared with the drip extraction method,
-Demonstrates the effect of being able to extract a high concentration of soup stock in a short time.

Another problem of the drip extraction method is that the temperature of the stock after production has been lowered because it is necessary to spend a sufficient amount of time to distribute hot water to the raw material of the stock.
On the other hand, according to the stock extraction method based on the negative pressure circulation extraction system, by installing a heater (extraction heater H1) inside the extraction tank 101, the hot water HW being circulated and extracted can be heated. (See also FIG. 6). In addition, if the temperature measuring body (dashi stock temperature sensor TS1) is provided inside the extraction tank 101 to measure the temperature of the hot water HW, and the driving of the extraction heater H1 is intermittently performed according to the measurement result, it is circulated but being extracted. It is also possible to manage the hot water HW at a constant temperature (see also FIG. 6).
1A shows an example in which the extraction heater H1 and the broth temperature sensor TS1 are installed in the negative pressure chamber 104, and FIG. 1B shows an example in which the extraction heater H1 and the broth temperature sensor TS1 are installed in the positive pressure chamber 103, respectively. .
Therefore, according to the stock extraction method using the negative pressure circulation extraction method,
-The effect that the stock broth after manufacture is prevented from being cooled and can be maintained at a high temperature is also obtained.

2. Embodiment (1) Appearance Configuration As shown in FIGS. 2 and 3, the soup stock manufacturing apparatus 1 of the present embodiment houses each part in a sheet metal housing 12 supported by leg portions 11 at four corners. . The housing 12 includes an upper housing 12a and a lower housing 12b, and has a shape in which a rectangular parallelepiped upper housing 12a having a small depth dimension is placed on a substantially regular cubic lower housing 12b. The upper housing 12a is offset on the back side, and forms a space on the upper surface of the lower housing 12b.

The housing 12 stores the extraction tank 101 described above in the upper housing 12a, and stores the hot water storage tank 201 and the heat retaining tank 301 in the lower housing 12b (see FIGS. 3 and 4).
The hot water storage tank 201 is a tank for storing hot water HW. The hot water HW stored here is transferred to the extraction tank 101 for the extraction of the soup stock.
The heat retaining tank 301 is a tank that is manufactured but stores juice. The soup stock stored here is discharged to a bowl D as needed.

  An extraction tank lid 13 is detachably attached to the upper surface of the upper housing 12a. The extraction tank lid 13 covers the upper surface of the extraction tank 101 so that it can be opened and closed, and allows the set unit 102 to be taken in and out.

  2 and 3, what is indicated by reference numeral 102 b is a handle of the set unit 102. The set part 102 can be taken out from the extraction tank 101 by grasping and pulling the handle 102b. The taken-out set unit 102 can be placed on the tray 14 disposed on the upper surface of the upper housing 12a adjacent to the extraction tank lid 13, and in this state, the stock dm1 that is the raw material dm can be replaced. .

  2 and 3, the pipe adjacent to the extraction tank lid 13 is a hot water supply pipe 151 for supplying hot water HW from the hot water storage tank 201 to the extraction tank 101, and a tap faucet 15 for cleaning is provided behind the tray 14. Is prepared.

  A first operation panel 401 as an operation unit is disposed on the right side of the front surface of the upper housing 12a. The first operation panel 401 will be described in detail later based on FIG.

  Above the first operation panel 401 is a stock pouring lever 411. However, the pouring lever 411 is swingably mounted about the horizontal axis and can be pushed down manually. When the hand is released, the pouring lever 411 returns to the upper initial position by the biasing force of a spring (not shown). When the soup pour lever 411 is pushed down, the soup stock stored in the heat retaining tank 301 can be poured out from the pour out pipe 302. However, the pouring pipe 302 is a pipe provided in communication with the heat retaining tank 301, and extends upward from the upper surface of the lower housing 12b. The upper part is bent into a U shape and the outlet faces downward. The upper housing 12 a is provided with a table table 16 below the outlet of the dashi pour tube 302 so that, for example, the dough bowl D placed on the table table 16 can be discharged from the pour tube 302.

  A cover 17 is covered on the upper surface of the lower housing 12b. The cover 17 is a lid that covers the open upper surface of the heat retaining tank 301 so as to be freely opened and closed, and has a double structure. When the cover 17 is removed, the heat retaining tank 301 is exposed, and maintenance thereof is possible.

  A tubular thing arranged at the upper part of the cover 17 is a soup stock transfer pipe 18. The soup stock transfer pipe 18 is disposed at the bottom right of the front of the upper housing 12a, but is fitted and connected to the discharge connector 19, and is inserted into a connection port (not shown) formed in the cover 17 with the stock discharge port 18a at the tip. It is out.

  However, the discharge connector 19 is a structure that is connected to the lower surface of the extraction tank 101 and is stored in the extraction tank 101 but discharges the juice by its own weight. Of course, since the soup stock does not spill from the extraction tank 101, the stock soup valve 19a (see FIGS. 4, 11, and 12) built in the stock discharge connector 19 normally prevents the stock soup from flowing out. The soup stock valve 19a is opened and closed by rotating the stock soup discharge handle 19b left and right. When the stock soup discharge handle 19b is rotated clockwise, the stock soup valve 19a is closed, and when the stock soup discharge handle 19b is rotated counterclockwise, the stock soup valve 19a is opened.

  Since the root portion of the soup stock transfer pipe 18 is connected to the stock discharge connector 19, when the stock stock discharge handle 19b is rotated counterclockwise to open the stock soup valve 19a, the stock stock is discharged from the stock discharge port 18a. However, as described above, the discharge port 18 a is fitted into a connection port (not shown) formed in the cover 17, and this communication port communicates with the heat retaining tank 301. Therefore, when the soup stock discharge handle 19b is rotated counterclockwise and the soup stock valve 19a is opened, the soup produced in the extraction tank 101 is transferred to the heat retaining tank 301 through the soup stock transfer pipe 18.

  However, the soup stock transfer pipe 18 has a flexible structure formed in a bellows shape. For this reason, it is possible to discharge the soup stock anywhere within the movable range of the soup stock transfer pipe 18 by removing the soup stock discharge port 18 a from the communication port formed in the cover 17. Therefore, in the present embodiment, a container base 20 is provided on the front right side of the lower housing 12b so that the soup can be discharged into the container C placed on the container base 20. Therefore, the soup stock transfer pipe 18 is formed in such a length that the discharge port 18 a can be positioned right above the container C placed on the container table 20.

By the way, although it is the container stand 20, this is a foldable type.
That is, the container base 20 includes a base 20a on which the container C is placed and a stopper 20b that supports the base 20a. The base 20a and the stopper 20b are formed on the lower housing 12b so that their upper edges are rotatable about the horizontal axis. Attached to the front panel.
The pedestal 20a and the stopper 20b are in a state where the state along the front panel of the lower housing 12b is folded, and are folded when the container base 20 is not used.
When the pedestal 20a is rotated from this state to the horizontal state and the stopper 20b is rotated by about 45 degrees, the stopper 20b is caught on the pedestal 20a, and the pedestal 20a can be maintained in that state. This state is a use state of the container stand 20.

On the front surface of the lower housing 12b, a second operation panel 421 as an operation unit is disposed at an upper left position. A power switch 422 is disposed on the second operation panel 421 and an operation display unit 423 is provided.
The power switch 422 is a switch for turning on / off the power supply of the whole soup stock production apparatus 1. As long as the power switch 422 is turned on, the necessary minimum power is supplied to the electronic components.
The operation display unit 423 is a part of a temperature control unit 553 (see FIG. 6) described later in the item “(3) Hardware configuration”, and sets the temperature of the soup stock stored in the heat storage tank 301. Or display.

The lower housing 12b is provided with a stock gauge 21 positioned on the left side of the front. The dashi gauge 21 includes a head tube 21a and a gauge 21b, and indicates the amount of soup stock stored in the heat retaining tank 301.
The water head tube 21 a is a transparent tube that is vertically arranged with the height and position from the lower surface to the upper surface of the heat retaining tank 301, and is connected to the inside of the heat retaining tank 301. As a result, the water storage tank 301 and the water head tube 21a have the same water head position, and are stored in the heat storage tank 301, but the water level of the juice is shown in the water head tube 21a.
The gauge 21b is a gauge that displays the head position of the water head tube 21a by replacing it with the remaining amount of soup stock stored in the heat retaining tank 301.
Therefore, by reading the value of the gauge 21b corresponding to the water head position of the water head tube 21a, the remaining amount of the soup stock stored in the heat retaining tank 301 can be known.

A drain operation port 22 is disposed at the lower left position on the front side of the lower housing 12b.
A drain cock 23 is disposed at an internal position of the lower housing 12b where a hand can be reached from the drain operation port 22. The drain cock 23 is provided with a lever (not shown), and the stock is drained from the heat retaining tank 301 by twisting the lever.

(2) Internal Configuration As shown in FIGS. 3 and 4, the soup stock producing apparatus 1 of the present embodiment stores and holds the extraction tank 101 in the upper housing 12a, and the hot water storage tank 201 and the heat retaining tank in the lower housing 12b. 301 is stored and held.

(A) Extraction tank The extraction tank 101 is a tank for extracting dashi as described above. By opening and closing the extraction tank lid 13 provided on the upper surface of the upper housing 12a, the set unit 102 can be taken in and out from the upper part of the extraction tank 101.

  In the present embodiment, dashi pack dm1 is used as dashi raw material dm to be set in setting unit 102. The set part 102 includes a circulation member 102a at the bottom, and stores the three stock packs dm1 stacked on the circulation member 102a. However, how many packs dm1 are used is arbitrary, and one, two, or three of them can be set in the setting unit 102.

  Therefore, the inside of the extraction tank 101 is divided into upper and lower parts by the set part 102 and the discharge pack dm1, and a positive pressure chamber 103 is formed in the upper part and a negative pressure chamber 104 is formed in the lower part. The outer surface of the set portion 102 is fitted into the communication space between the positive pressure chamber 103 and the negative pressure chamber 104 without any gap, and the positive pressure chamber 103 and the negative pressure chamber 104 are divided.

What is important in this case is how much the set portion 102 partitions the positive pressure chamber 103 and the negative pressure chamber 104.
In the present embodiment, the side wall 102c of the set portion 102 is formed of a metal plate-like member so as to prevent the fluid (hot water HW in the present embodiment) from flowing. That is, only the upper and lower surfaces of the set portion 102 are open, and the flow member 102a is disposed on the lower surface that opens.
The distribution member 102a is formed in a size that is completely covered by the stock pack dm1.
Therefore, when the set unit 102 is disposed in the extraction tank 101 with the stock pack dm1 placed on the flow member 102a, the positive pressure chamber 103 and the negative pressure chamber 104 are completely separated. That is, when hot water HW is circulated between the negative pressure chamber 104 and the positive pressure chamber 103, the hot water HW always passes only through the dashi pack dm1. As a result, the dashi can be extracted from the dashi pack dm1 in a short time.

However, the dashi pack dm1 is resistant to the hot water HW that is distributed, and depending on the type of the dashi pack dm1, it is assumed that the resistance given to the hot water HW is too strong. In this case, for example, by making a hole in the side wall 102c of the set part 102 or making the area of the flow member 102a larger than the area of the pack dm1, the hot water HW can be circulated in addition to the portion of the dashi pack dm1. A route may be formed. Alternatively, the number of the set packs dm1 may be adjusted.
The extent to which the set unit 102 divides the positive pressure chamber 103 and the negative pressure chamber 104 is appropriately set in consideration of various factors such as the power of the circulation pump P1 (see FIG. 4 and the like) and the type of the stock pack dm1.

  The positive pressure chamber 103 and the negative pressure chamber 104 thus partitioned by the set unit 102 are in communication with each other through a communication path 105. Although the tubular communication path 105 is illustrated in FIGS. 1A and 1B, the communication path 105 does not necessarily have a tubular shape. As shown in FIG. 4, the communication path 105 of the present embodiment is formed in a tuft shape that connects the bottom surface of the positive pressure chamber 103 and the side surface of the negative pressure chamber 104. The portion that communicates with the side surface of the negative pressure chamber 104 is the inlet 105 a of the communication path 105, and the portion that communicates with the bottom surface of the positive pressure chamber 103 is the outlet 105 b of the communication path 105.

An impeller 106 of the circulation pump P1 is disposed at the inlet 105a of the communication path 105, and a water inlet 106a provided at the central portion thereof faces the inlet 105a. The impeller 106 includes a plurality of discharge ports 106 b on the outer peripheral portion, and these discharge ports 106 b face the outlet 105 b of the communication path 105.
The impeller 106 is rotated by being driven by a motor 107 fixed to the outer surface of the extraction tank 101. By rotating, the hot water HW is drawn into the water inlet 106a from the inlet 105a of the communication path 105 and discharged from the outlet 106b. Therefore, the hot water HW can be transferred from the negative pressure chamber 104 to the positive pressure chamber 103 by operating the circulation pump P1.

1A shows an example in which the extraction heater H1 and the soup stock temperature sensor TS1 are arranged in the negative pressure chamber 104, and in FIG. 1B, those extraction heater H1 and the soup stock temperature sensor TS1 are arranged in the positive pressure chamber 103. Each example is shown.
As shown in FIG. 3, in this Embodiment, the extraction heater H1 is arrange | positioned under the bottom face of the extraction tank 101, and the hot water HW which the extraction tank 101 stores is heated from the outside. In FIG. 4, the extraction heater H <b> 1 is illustrated as being disposed inside the negative pressure chamber 104, but this is schematically illustrated. On the other hand, the soup stock temperature sensor TS1 is disposed inside the negative pressure chamber 104 as in the example shown in FIG.

The extraction tank 101 includes four water level sensors S1 to S4.
The water level sensor S1 is a sensor that reacts when 6 liters of hot water HW is stored in the extraction tank 101 (see FIGS. 3 and 4).
The water level sensor S2 is a sensor that reacts when 12 liters of hot water HW is stored in the extraction tank 101 (see FIGS. 3 and 4).
The water level sensor S3 is a sensor that reacts when 18 liters of hot water HW is stored in the extraction tank 101 (see FIGS. 3 and 4).
The water level sensor S4 is a sensor that reacts when a certain amount of hot water HW is stored in the extraction tank 101. Used for air detection (see FIG. 3).

As described above, the juice produced in the extraction tank 101 is transferred to the heat retaining tank 301 by the soup stock transfer pipe 18 or transferred to the container C. For this reason, it is necessary to transfer the soup stock in the extraction tank 101 to the arrangement position of the discharge connector 19 to which the soup stock transfer pipe 18 is connected. As a structure for this purpose, in the present embodiment, the bottom of the extraction tank 101 and the discharge connector 19 are communicated with each other through a communication pipe 108. Therefore, if the soup stock discharge handle 19b is rotated to open the soup stock valve 19a of the discharge connector 19, the stock is stored in the extraction tank 101, but the juice falls by its own weight, and passes through the connecting pipe 108, the discharge connector 19 and the soup stock transfer pipe 18. It is discharged from the discharge port 18a.
The opening / closing of the soup stock valve 19a at this time is detected by the stock transfer sensor S10 (see FIG. 6). However, various types of transfer sensor S10 can be used. For example, a flow sensor provided inside the discharge connector 19, a rotary switch that detects the open / close state of the soup discharge handle 19b, and the like can be used as the transfer sensor S10.

(B) Hot Water Storage Tank The hot water storage tank 201 is a tank that stores hot water HW supplied to the extraction tank 101.

  The hot water storage tank 201 is supplied with tap water W. As a structure for this purpose, a water supply pipe 202 for supplying water from the water supply to the hot water storage tank 201 is provided, and a water supply electromagnetic valve V1 is provided in the water supply pipe 202. Therefore, if the water supply electromagnetic valve V1 is driven and opened, the tap water W flows into the hot water storage tank 201.

  The hot water storage tank 201 is provided with a heater (water heating heater H2) for heating the supplied tap water W to make the hot water HW, and a temperature measuring body for measuring the temperature of the hot water HW heated by the water heating heater H2 ( A hot water temperature sensor TS2) is attached (see also FIG. 6). As shown in FIGS. 3 and 4, the water heater H <b> 2 is disposed near the inner bottom surface of the hot water storage tank 201. The arrangement position of the hot water temperature sensor TS2 is also inside the hot water storage tank 201.

The hot water storage tank 201 includes four water level sensors S5 to S8.
The water level sensor S5 is a sensor that reacts when 6 liters + α of tap water W is stored in the hot water storage tank 201 (see FIGS. 3 and 4).
The water level sensor S6 is a sensor that reacts when 12 liters + α of tap water W is stored in the hot water storage tank 201 (see FIGS. 3 and 4).
The water level sensor S7 is a sensor that reacts when 18 liters + α of tap water W is stored in the hot water storage tank 201 (see FIGS. 3 and 4).
The water level sensor S8 is a sensor that reacts when a certain amount of tap water W is stored in the hot water storage tank 201. Used for air detection (see FIG. 3).
For example, float switches can be used for these water level sensors S5 to S8.

  In order to transfer the hot water HW springed up and stored in the hot water storage tank 201 to the extraction tank 101, the soup stock production apparatus 1 includes a hot water transfer unit 152. The hot water transfer section 152 is provided with the transfer pump P2 interposed in the hot water supply pipe 151 connected to the bottom of the hot water storage tank 201. The transfer pump P <b> 2 is a centrifugal pump, for example, and sucks up the hot water HW stored in the hot water storage tank 201 by its operation and transfers it to the extraction tank 101 via the hot water supply pipe 151.

  The hot water storage tank 201 further includes an overflow pipe 203. The overflow pipe 203 opens the overflow port 203a at a position higher than the water level to which the water level sensor S7 reacts, and drains the tap water W (hot water HW) reaching the overflow port 203a to the outside.

(C) Thermal insulation tank The thermal insulation tank 301 is a tank which is transferred from the extraction tank 101 but stores the juice so as to be able to keep the temperature.

  The heat retaining tank 301 is provided with a heater (heat retaining heater H3) that heats the stored soup stock and keeps it warm, and a temperature measuring body (heat retaining sensor TS3) that measures the temperature of the stock stock kept by the heat retaining heater H3 is attached. (See also FIG. 6). The heat retaining heater H3 is arranged at the bottom of the bottom surface of the heat retaining tank 301 so as to heat the soup stock stored in the heat retaining tank 301 from the outside. On the other hand, the heat retaining sensor TS3 is disposed inside the heat retaining tank 301.

  As described above, when the stock pour lever 411 is pushed down, the stock stored in the heat retaining tank 301 can be poured out from the pour tube 302. As a mechanism for that purpose, the soup stock producing apparatus 1 is provided with a stock pouring switch 412 and a stock pouring pump P3 (see FIG. 6). The stock pouring switch 412 is a switch that is turned on by depressing the stock pouring lever 411. The pour-out pump P3 is, for example, a centrifugal pump, and a water supply port (not shown) is connected to an opening (not shown) formed on the bottom surface of the heat retaining tank 301, and a discharge port (not shown) is poured out. The tube 302 is connected. Therefore, when the dashi pour lever 411 is pushed down, the pour pour switch 412 is turned on, and the dashi pour pump P3 is actuated accordingly, so that the dashi stock stored in the heat retaining tank 301 is discharged. It is possible to suck out and pour out from the outlet.

  The heat retaining tank 301 includes a water level sensor S9. This water level sensor S9 is disposed at the bottom of the heat retaining tank 301, and is a sensor that reacts when dashi stock is supplied to the heat retaining tank 301. Used for air detection (see FIG. 3).

(D) Operation unit (first operation panel)
As shown in FIG. 5, the first operation panel 401 is divided into three regions. An extraction preparation area 401a, an extraction area 401b, and a discharge area 401c.

  The extraction preparation area 401a is an area that accepts an operation in the stock extraction preparation stage and provides information on that stage.

  In order to accept the operation, the extraction preparation area 401 a is provided with a changeover switch 402. The changeover switch 402 is a rotary switch for switching the amount of broth extracted into three stages of 6 liters, 12 liters, and 18 liters. As visually showing the switching position, a switching display 402 a of “6L”, “12L”, and “18L” is written at the switching position of the changeover switch 402.

In order to provide information, the extraction preparation area 401a prepares three notification lamps 403 (6L lamp 403a, 12L lamp 403b, and 18L lamp 403c) as notification sections.
These notification lamps 403 (6L lamp 403a, 12L lamp 403b, 18L lamp 403c) are arranged corresponding to the positions of “6L”, “12L”, and “18L” in the switching display 402a, respectively, and hot water HW in the hot water storage tank 201 is arranged. The preparation state of is notified. As will be described in detail in the section “(4) Program processing”, the notification lamps 403a, 403b, and 403c indicate that hot water HW is being prepared by blinking, and that the hot water HW is ready by being lit.
Whether it is being prepared or whether it is ready is determined by the amount of hot water HW and the temperature.

  The extraction area 401b is an area that receives operations at the stock extraction stage and the stirring stage and provides information on the stages.

  An extraction area 401b prepared for accepting an operation is a start button 404. The start button 404 is a switch for instructing the start of the stock extraction operation, and for instructing the start of the stirring operation of the manufactured soup and the soup stock.

In order to provide information, the extraction area 401b provides a stock extraction lamp 405 and a stirring lamp 406.
The stock extraction lamp 405 blinks to indicate that the stock extraction operation is being performed after the start button 404 is turned on, and lights to indicate that the stock extraction operation has been completed.
The stirrer lamp 406 blinks to indicate that the start button 404 is turned on and the stirring operation of the soup stock and the soup stock is in progress, and indicates that the stirring operation has been completed by lighting.

The drainage area 401 c is an area that provides information on the stage of discharging the broth from the extraction tank 101. In the discharge area 401c, a handle open / close display lamp 407 is provided together with a notice that “the handle should be closed after draining”.
The handle opening / closing display lamp 407 indicates when the soup stock discharge handle 19b is rotated counterclockwise to open the soup stock valve 19a and the stock soup is discharged from the stock discharge port 18a. When the soup stock discharge handle 19b is rotated clockwise to close the soup stock valve 19a, the handle open / close display lamp 407 is turned off.

(3) Hardware configuration The soup stock production apparatus 1 includes a control unit 501, and each unit is controlled by the control unit 501.
The control unit 501 is configured by connecting a ROM 503, a RAM 504, and an EEPROM 505 to a CPU 502 that executes various arithmetic processes and centrally controls each unit.
The ROM 503 is a storage medium that stores data in a fixed manner, and stores a computer program for producing soup stock.
The RAM 504 is a storage medium that stores data in a rewritable manner, and is used as a work area when the computer program stored in the ROM 503 is executed.
The EEPROM 505 is a storage medium that can store data in a rewritable manner and store the stored contents. For example,
-Extraction operation time of soup stock by the negative pressure circulation system, that is, operation time of the circulation pump P1 (see steps S217 to S218 in the flowchart of FIG. 8)
・ Agitation time of dashi soup and mash soup, that is, operating time of circulation pump P1 (see steps S225 to S226 in the flowchart of FIG. 9)
Etc. are stored in a rewritable manner.
A timer 506 is connected to such a control unit 501.

Circulation pump P1 for circulating hot water HW (dashi soup) stored in extraction tank 101, transfer pump P2 for transferring hot water HW stored in hot water storage tank 201 to extraction tank 101, and stock soup stock stored in heat retaining tank 301 are poured out. The stock pour pump P3 is connected to the control unit 501 via the pump drive circuit 511.
The pump drive circuit 511 is a circuit that drives the circulation pump P1, the transfer pump P2, and the stock pour pump P3 in accordance with the drive signal sent from the CPU 502.

A water supply electromagnetic valve V <b> 1 for supplying tap water W to the hot water storage tank 201 is connected to the control unit 501 via a valve drive circuit 512.
The valve drive circuit 512 is a circuit that drives the water supply electromagnetic valve V <b> 1 in accordance with a drive signal sent from the CPU 502.

The four water level sensors S1 to S4 arranged in the extraction tank 101, the four water level sensors S5 to S8 arranged in the hot water storage tank 201, and the water level sensor S9 arranged in the heat retaining tank 301 are a sensor input circuit 531. It is connected to the control unit 501 via A stock sensor S10 that detects the open / close state of the soup stock valve 19a is also connected to the control unit 501 via the sensor input circuit 531.
The sensor input circuit 531 is a circuit that binarizes analog signals output from the water level sensors S1 to S9 and the stock transfer sensor S10 and inputs them to the input port of the CPU 502.
As described above, the water level sensors S1 to S9 are sensors that react to each water level. The sensor input circuit 531 is configured to output an ON signal when the water level sensors S1 to S9 react to the respective water levels.

However, the push-out switch 412 that detects the depression of the pour-out lever 411 and the first operation panel 401 are connected to the control unit 501 via the input / output circuit 541.
The input / output circuit 541 binarizes the analog signal fetched from the stock pouring switch 412 and the first operation panel 401 and inputs it to the input port of the CPU 502.

  The soup stock producing apparatus 1 includes three temperature control units 551, 552, and 553. They are an extraction temperature control unit 551 for the extraction tank 101, a hot water storage temperature control unit 552 for the hot water storage tank 201, and a thermal insulation temperature control unit 553 for the thermal insulation tank 301.

The extraction temperature control unit 551 includes a temperature controller 551a incorporating a control circuit and an operation device 551b incorporating a drive circuit, and causes the operation device 551b to drive the extraction heater H1 under the control of the temperature controller 551a. The hot water HW (dashi soup) stored in the extraction tank 101 is heated, the temperature is measured by the soup temperature sensor TS1, and the temperature controller 551a turns on and off the extraction heater H1 so that the measured value becomes a predetermined temperature. The unit to control.
The temperature controller 551a includes an EEPROM (not shown), and stores a “predetermined temperature” in an rewritable manner in the EEPROM. Therefore, by operating the temperature controller 551a, the temperature to be adjusted can be freely set in the EEPROM. However, the operation for setting the temperature is not left to the user, but is performed by a service person.

The hot water storage temperature control unit 552 includes a temperature controller 552a incorporating a control circuit and an operation device 552b incorporating a drive circuit, and drives the water heater H2 to the operation device 552b under the control of the temperature controller 552a. Then, the tap water W stored in the hot water storage tank 201 is heated, the temperature is measured by the hot water temperature sensor TS2, and the temperature controller 552a turns the water heater H2 on and off so that the measured value becomes a predetermined temperature. The unit to control.
The temperature controller 552a includes an EEPROM (not shown), and stores a “predetermined temperature” in an rewritable manner in the EEPROM. Therefore, by operating the temperature controller 552a, the temperature to be adjusted can be freely set in the EEPROM. However, the operation for setting the temperature is not left to the user, but is performed by a service person.

The temperature control unit 553 has a temperature controller 553a with a built-in control circuit and an operating device 553b with a built-in drive circuit, and causes the operating device 553b to drive the temperature maintaining heater H3 under the control of the temperature controller 553a. This is a unit that heats the soup stock stored in the heat retaining tank 301, measures the temperature by the heat retaining sensor TS3, and controls the heat retaining heater H3 on and off so that the measured value becomes a predetermined temperature. .
An operation display unit 423 disposed on the second operation panel 421 is connected to the temperature controller 553a. The operation display unit 423 includes a display area, and displays a large temperature for the soup stock in this display area, and displays the current temperature of the soup stock stored in the heat retaining tank 301 small. The operation display unit 423 also has an input button, and the input temperature can be set by using the input button.
The temperature controller 553a includes an EEPROM (not shown), and stores the “predetermined temperature”, that is, the set temperature input by the input button, in an rewritable manner in the EEPROM. Therefore, by operating the input button provided on the operation display unit 423, the temperature to be adjusted can be freely set in the EEPROM. Since this operation is performed using the input button of the operation display unit 423, it is released not only to the service person but also to the user.

(4) Program processing In accordance with a computer program stored in the ROM 503, the control unit 501 performs “hot water storage processing”, “dashi stock extraction processing”, “stirring processing”, “dashi stock transfer processing”, “white stock pour out processing”, “dashi stock warming pour out processing” ”Is executed.
The hot water storage process is a process in which tap water W is supplied to the hot water storage tank 201 and heated to the set temperature of the hot water temperature control unit 552 (see FIG. 7).
The soup stock extraction process is a process for producing soup stock in the extraction tank 101 by a negative pressure circulation system (see FIG. 8).
The agitation process is a process for agitating and mixing the soup stock and the koji soup in the extraction tank 101 (see FIG. 9).
The white dashi pour out process is a process for pour out white dashi (a dashi stock not mixed with the soup) from the extraction tank 101 (see FIG. 9).
The soup stock warming and pouring process is a process for keeping the soup stock warm and pouring in the heat retaining tank 301 (see FIG. 10).
Hereinafter, each process will be described with the work by the operator.

  First, as a premise for executing these processes, or in parallel with these processes, the operator sets the stock pack dm1, which is the raw material dm, in the soup stock production apparatus 1. The extraction tank lid 13 is opened, the handle 102b is grasped, the set unit 102 is pulled up from the extraction tank 101, and a desired number of stock packs dm1 are placed on the flow member 102a of the set unit 102. When the handle 102b is grasped and the setting portion 102 is returned to the extraction tank 101 and the extraction tank lid 13 is closed, the setting work of the pack dm1 is completed.

(A) Hot Water Storage Process As shown in the flowchart of FIG. 7, when the power switch 422 of the soup stock producing apparatus 1 is turned on, the control unit 501 performs initialization and then opens the water supply electromagnetic valve V1 (step S101). As a result, the tap water W is supplied to the hot water storage tank 201.

  At this time, the CPU 502 determines the switching state of the changeover switch 402, that is, how many liters of soup stock production is selected among 6 liters, 12 liters, or 18 liters (steps S102 to S104).

When it is determined that 6 liters is selected (YES in step S102), the CPU 502 gives a signal to the input / output circuit 541, and among the notification lamps 403 provided in the extraction preparation area 401a of the first operation panel 401, the 6L lamp 403a is turned on (step S106).
When it is determined that 12 liters is selected (YES in step S103), the CPU 502 gives a signal to the input / output circuit 541, and among the notification lamps 403 provided in the extraction preparation area 401a of the first operation panel 401, the 12L lamp 403b is turned on (step S107).
When it is determined that 18 liters is selected (YES in step S104), the CPU 502 gives a signal to the input / output circuit 541, and among the notification lamps 403 provided in the extraction preparation area 401a of the first operation panel 401, the 18L lamp 403c is turned on (step S108).
If the changeover state of the changeover switch 402 is not 6 liters, 12 liters, or 18 liters, an error is estimated, and error processing is executed (step S105).

  By blinking the notification lamp 403 in this way, it is possible to indicate to the operator that the hot water HW is being prepared.

  Next, when it is determined that the water level sensor S8 is turned on, that is, there is no concern about emptying (YES in step S109), the CPU 502 gives a temperature control start instruction to the hot water storage temperature control unit 552 (step S109). S110).

  In response to this, the temperature controller 552a of the hot water storage temperature control unit 552 gives a drive command to the operating device 552b to drive the water heater H2. Then, the water heater H2 heats the tap water W stored in the hot water storage tank 201 to make the hot water HW. At this time, the temperature controller 552a measures the temperature of the hot water HW with the hot water temperature sensor TS2, stops the driving of the water heater H2 when the temperature reaches the set temperature of the hot water temperature control unit 552, and heats the water again when the temperature decreases. The process of driving the heater H2 is repeated. That is, the temperature control operation is executed, and the temperature of the hot water HW stored in the hot water storage tank 201 is maintained at a predetermined temperature set in advance.

  While the temperature controller 552a of the temperature control unit 552 for hot water storage is performing the temperature adjustment operation, the CPU 502 again switches the changeover switch 402, that is, how many liters of soup stock out of 6 liters, 12 liters, or 18 liters. It is determined whether or not manufacturing is selected (steps S111 to S113).

If it is determined that 6 liters has been selected (YES in step S111), the CPU 502 determines the state of the water level sensor S5, and if turned on (YES in step S114), the water supply electromagnetic valve V1 is closed. A signal is given to the valve drive circuit 512 (step S114). As a result, 6 liters + α of tap water W is stored in the hot water storage tank 201.
If it is determined that 12 liters has been selected (YES in step S112), the CPU 502 determines the state of the water level sensor S6. If it is turned on (YES in step S115), the water supply electromagnetic valve V1 is closed. A signal is given to the valve drive circuit 512 (step S115). As a result, 12 liters + α of tap water W is stored in the hot water storage tank 201.
If it is determined that 18 liters has been selected (YES in step S113), the CPU 502 determines the state of the water level sensor S7. If it is turned on (YES in step S116), the water supply electromagnetic valve V1 is closed. A signal is given to the valve drive circuit 512 (step S116). As a result, an amount of 18 liters + α of tap water W is stored in the hot water storage tank 201.
If the changeover state of the changeover switch 402 is not 6 liters, 12 liters, or 18 liters, an error is estimated, and the CPU 502 executes error processing (step S105).

While the control unit 501 is executing such a water supply process, the hot water storage temperature adjustment unit 552 is executing the temperature adjustment process.
Therefore, the CPU 502 determines whether or not the tap water W stored in the hot water storage tank 201 has a predetermined temperature (step S118). This process is performed by receiving a signal transmitted from the hot water storage temperature control unit 552 as to whether or not the hot water HW has reached a specified set temperature.

When it is determined that the tap water W stored in the hot water storage tank 201 is at a predetermined temperature (YES in step S118), the hot water HW is ready, so the CPU 502 has The state of the notification lamp 403 that has been blinking is changed from blinking to lighting (step S119). That is, if the 6L lamp 403a is blinking, it is turned on. If the 12L lamp 403b is blinking, it is turned on. If the 18L lamp 403c is blinked, it is turned on. That is why.
Thus, the operator can know that the hot water HW is ready.

  Thereafter, the CPU 502 waits for the determination of the presence or absence of a water supply permission declaration (see step S216 in the flowchart of FIG. 8) (step S120), and when the water supply permission is granted (YES in step S120), the water supply electromagnetic valve V1 is turned on. Open (step S121). This is because the hot water HW stored in the hot water storage tank 201 is transferred to the extraction tank 101 and consumed in a situation where water supply permission is granted, and only a small amount of hot water HW remains in the hot water storage tank 201.

CPU502 which performed the process which opens the water supply electromagnetic valve V1 determines the switching state of the changeover switch 402, ie, how many liters of soup production is selected among 6 liters, 12 liters, or 18 liters S111-S113 Return to processing.
As a result, the hot water storage tank 201 is again supplied with tap water W and heated, and a predetermined amount of hot water HW selected by the changeover switch 402 is stored to prepare for the extraction of soup stock.

(B) Dashi soup extraction process, stirring process, dashi soup transfer process, and white dashi pouring process The operator looks at the state of the notification lamp 403 of the first operation panel 401 to determine whether the hot water HW is ready. You can know at a glance. That is, if the amount of the notification lamp 403 (6L lamp 403a, 12L lamp 403b, or 18L lamp 403c) selected by switching the changeover switch 402 changes from blinking to lighting, the hot water HW is ready. Recognize.
If it is confirmed that the hot water HW is ready, the operator presses the start button 404 on the first operation panel 401.

  The CPU 502 executes “dashi soup extraction process”, “stirring process”, “dashi soup transfer process”, and “white dashi pouring process” shown in FIGS. 8 and 9 by hot water storage processing and multitasking shown in the flowchart of FIG.

(B-1) Dashi Stock Extraction Process As shown in the flowchart of FIG. 8, the CPU 502 is on standby for a determination process for determining whether or not the start button 404 is pressed (step S201).

  The CPU 502 that has determined that the start button 404 has been pressed (YES in step S201) determines whether the operating conditions are satisfied, that is, whether the hot water storage tank 201 is ready for hot water HW (step S202).

Whether or not hot water HW is ready in hot water storage tank 201 is determined when it is determined in step S118 that hot water HW is at the set temperature (YES in step S118).
That is, the control unit 501 temporarily stores the determination result in step S118 in FIG. 7 in the RAM 504, and refers to this in step S202 in FIG.

When the CPU 502 determines that the hot water HW is not ready and the operating conditions are not satisfied (NO in step S202), the CPU 502 treats the pressing of the start button 404 as invalid (step S203), and performs the processing in step S201. Return.
That is, when the start button 404 is pressed even though the hot water storage tank 201 is not ready for the hot water HW, this operation is invalidated and the soup stock extraction operation is not started.

On the other hand, if the CPU 502 determines that the hot water HW is ready and the operating conditions are satisfied (YES in step S202), the CPU 502 flashes the extraction lamp 405 provided in the extraction area 401b of the first operation panel 401. (Step S204), a drive signal is given to the pump drive circuit 511 to drive the transfer pump P2 (Step S205).
As a result, the hot water HW stored in the hot water storage tank 201 is sucked into the transfer pump P <b> 2 and transferred to the extraction tank 101. The soup stock preparation begins.
The start of the stock soup extraction is indicated to the operator by the flashing of the stock extract lamp 405.

  Next, if the CPU 502 determines that the water level sensor S4 is turned on, that is, that there is no concern about airing (YES in step S206), it gives a temperature adjustment start instruction to the extraction temperature adjustment unit 551 (step S206). S207).

  In response to this, the temperature controller 551a of the extraction temperature control unit 551 gives a drive command to the operating device 551b to drive the extraction heater H1. Then, the extraction heater H1 heats the hot water HW stored in the extraction tank 101 and maintains the temperature. At this time, the temperature controller 551a measures the temperature of the hot water HW with the soup temperature sensor TS1, stops the driving of the extraction heater H1 when it reaches the set temperature of the extraction temperature control unit 551, and starts again when the temperature decreases. The process of driving H1 is repeated. That is, the temperature adjustment operation is performed, and the temperature of the hot water HW stored in the extraction tank 101 is maintained at a preset predetermined temperature.

  Even while the temperature controller 551a of the extraction temperature control unit 551 is performing the temperature control operation, the CPU 502 switches the changeover switch 402, that is, how many liters out of 6 liters, 12 liters, or 18 liters is produced. Is selected (steps S208 to S210).

If it is determined that 6 liters is selected (YES in step S208), the CPU 502 determines the state of the water level sensor S1, and if it is turned on (YES in step S212), the drive of the transfer pump P2 is stopped. (Step S215). As a result, a hot water HW having a volume of just 6 liters is stored in the hot water storage tank 201.
If it is determined that 12 liters has been selected (YES in step S209), the CPU 502 determines the state of the water level sensor S2, and if turned on (YES in step S213), stops driving the transfer pump P2. (Step S215). As a result, a hot water HW having a volume of just 12 liters is stored in the hot water storage tank 201.
If it is determined that 18 liters is selected (YES in step S210), the CPU 502 determines the state of the water level sensor S3, and if it is turned on (YES in step S214), the drive of the transfer pump P2 is stopped. (Step S215). As a result, an amount of hot water HW of exactly 18 liters is stored in the hot water storage tank 201.
If the changeover state of the changeover switch 402 is not 6 liters, 12 liters, or 18 liters, an error is estimated, and the CPU 502 executes error processing (step S211).

In step S212, step S213, or step S214, a necessary amount of hot water HW is transferred from the hot water storage tank 201 to the extraction tank 101.
Therefore, the CPU 502 declares water supply permission (step S216).
Then, in the soup stock extraction process (flow charts of FIGS. 8 and 9) and the hot water storage process shown in the flow chart of FIG. 7 executed in multitasking, the CPU 502 determines that there is a water supply permission declaration (in step S120 in the flow chart of FIG. 7). YES), the water supply electromagnetic valve V1 is opened (step S121 in the flowchart of FIG. 7). As a result, water supply to the hot water storage tank 201 is started again, and the hot water HW is ready.

When the necessary amount of hot water HW has been transferred from the hot water storage tank 201 to the extraction tank 101 (see step S215), the CPU 502 outputs a drive signal to the pump drive circuit 511 to drive the circulation pump P1 (step S217).
Then, the hot water HW in the extraction tank 101 is sucked into the suction side of the circulation pump P1 and sucked into the communication path 105, discharged from the discharge side of the circulation pump P1, and returned to the positive pressure chamber 103. At this time, since the negative pressure chamber 104 becomes negative pressure, the hot water HW flows from the positive pressure chamber 103 into the negative pressure chamber 104. Thus, the hot water HW circulates between the negative pressure chamber 104 and the positive pressure chamber 103.

At this time, during the process in which the hot water HW flows from the positive pressure chamber 103 to the negative pressure chamber 104, the active ingredient of the stock dm dissolves in the hot water HW, and the stock is extracted. Then, the hot water HW in which the active ingredient of the soup stock dm is dissolved is returned to the positive pressure chamber 103, and is again circulated through the soup stock dm to the negative pressure chamber 104, whereby the concentration of the stock extracted Will gradually increase.
Therefore, a high-concentrated soup stock in which the active ingredient is sufficiently dissolved is extracted in a short time.

Such a dashi stock extraction operation of the negative pressure circulation system is executed until a predetermined time is up (step S218).
That is, the CPU 502 counts the elapsed time with the timer 506 after the start of the stock soup extraction operation (step S217) by driving the circulation pump P1, and monitors the time-up of a predetermined time set in the EEPROM 505. If it is determined that the time is up (YES in step S218), driving of the circulation pump P1 is stopped (step S219). Thus, the soup stock extraction operation is completed.
Therefore, the CPU 502 changes the state of the extraction lamp 405 blinking in the extraction area 401b of the first operation panel 401 to a lighting state (step S220), and notifies the operator of the completion of the soup extraction operation.
Thus, the soup stock extraction operation is completed, and the soup stock which is set in the setting unit 102 but in which the active ingredient of the pack dm1 is dissolved is extracted. At this time, the soup stock is stored in the extraction tank 101.

  At this stage, the operator is given two options.

  One of the two options is an option of extracting the active ingredient from the dashi pack dm1 and mixing the soup with the soup so that the soup can be used immediately (hereinafter referred to as “option 1”). ).

  When selecting option 1, the worker performs four operations.

The first operation is an operation of taking out the dashi pack dm1 from the extraction tank 101 and putting the soup into the soup stock in the extraction tank 101.
That is, the extraction tank lid 13 is opened, the handle 102 b is grasped, and the set unit 102 is taken out from the extraction tank 101. The set unit 102 taken out is placed on the tray 14, for example. Then, the soup stock is put into the soup stock in the extraction tank 101 and the extraction tank lid 13 is closed.
At this time, when the soup stock extraction operation is continued, the stock pack dm1 may be replaced with a new one while the set portion 102 is placed on the tray 14.

The second operation is to confirm whether or not the discharge port 18a of the soup stock transfer pipe 18 is fitted in a connection port (not shown) formed in the cover 17, and if it is not fitted, it is fitted into the communication port. (See FIGS. 2 and 3).
That is, it is confirmed that the discharge port 18a of the soup stock transfer pipe 18 is in contact with the heat retaining tank 301, and if it is not in contact, it is informed.

  The first work and the second work do not have to be performed first, and any of them may be performed first.

The third operation is an operation for instructing the stirring of the soup stock and the soup stock.
This operation is performed by depressing a start button 404 provided in the extraction area 401b of the first operation panel 401.
This work is performed after the first work and the second work are completed.

The fourth operation is an operation in which the soup is mixed with the koji soup and the soup is transferred from the extraction tank 101 to the heat retaining tank 301.
This operation is performed by rotating the soup stock discharge handle 19b counterclockwise and opening the stock soup valve 19a of the discharge connector 19. Then, the soup stock stored in the extraction tank 101 falls by its own weight through the communication pipe 108, the discharge connector 19 and the soup stock transfer pipe 18, and is transferred to the heat retaining tank 301.
This work is performed after the third work is completed.

The other of the two options is an option of extracting the active ingredient from the dashi pack dm1, but taking out the juice into, for example, the container C and using it as a so-called “white soup” (hereinafter referred to as “option 2”). .
When selecting option 2, the operator prepares the container stand 20, places the container C, and positions the discharge port 18a of the soup stock transfer pipe 18 on the container C (see FIGS. 2 and 3).
Then, the soup discharge handle 19b is rotated counterclockwise to open the soup stock valve 19a of the discharge connector 19.
Then, the soup stock stored in the extraction tank 101 falls by its own weight through the communication pipe 108, the discharge connector 19, and the soup stock transfer pipe 18, and is supplied to the container C as white stock.

As shown in the flowchart of FIG. 9, the CPU 502 waits for a determination process as to whether the soup stock discharge handle 19b has been opened in order to determine which of these two options (option 1 and option 2) is selected. (Step S221).
According to the opening / closing of the soup stock discharge handle 19b, however, the opening / closing of the soup valve 19a is detected by the stock transfer sensor S10. Therefore, the process of step S221 is executed by referring to the signal sent from the stock transfer sensor S10.

(B-2) Stir processing and dashi stock transfer processing The flow of processing when Option 1 is selected is as follows.

As shown in the flowchart of FIG. 9, in step S221, the CPU 502 refers to the output of the transfer sensor S10, determines that the soup discharge handle 19b is not opened (NO in step S221), and then presses the start button 404. Determination is made (YES in step S222).
As a result, the CPU 502 executes “stirring process” and “dashi stock transfer process” which are processes when option 1 is selected.

First, the CPU 502 turns on the extraction area 401b of the first operation panel 401 and turns off the extraction lamp 405 (step S223).
This is because a new stage of stirring processing is entered.

Next, the CPU 502 causes the stirring lamp 406 disposed in the extraction area 401b of the first operation panel 401 to blink (step S224).
This is to inform the worker that the soup stock and the soup stock are being stirred.

Thereafter, the CPU 502 outputs a drive signal to the pump drive circuit 511 to drive the circulation pump P1 (step S225).
Then, the soup stock stored in the extraction tank 101 is introduced, but the soup is sucked into the suction side of the circulation pump P1 and sucked into the communication path 105, discharged from the discharge side of the circulation pump P1, and returned to the positive pressure chamber 103. By repeating this operation, the broth circulates between the negative pressure chamber 104 and the positive pressure chamber 103, and the broth and the mash are stirred and mixed.

Such a stirring operation is executed until a predetermined time is up (step S226). That is, the CPU 502 counts the elapsed time with the timer 506 after the start of the stirring operation (step S225) by driving the circulation pump P1, and monitors the time-up of a predetermined time set in the EEPROM 505. If it is determined that the time is up (YES in step S226), the driving of the circulation pump P1 is stopped (step S227). Thus, the stirring operation is completed.
Therefore, the CPU 502 changes the state of the stirring lamp 406 blinking in the extraction region 401b of the first operation panel 401 to a lighting state (step S228), and notifies the operator of the completion of the stirring operation.

  Here, the operator performs the above-mentioned “fourth operation”, that is, the operation of transferring the juice from the extraction tank 101 to the heat retaining tank 301 while being mixed with the soup stock. The dashi stock discharge handle 19b is rotated counterclockwise to open the dashi stock valve 19a of the discharge connector 19.

The CPU 502 refers to the output of the transfer sensor S10 to monitor whether the soup stock discharge handle 19b has been opened (step S229). If it is determined that the stock soup discharge handle 19b has been opened (YES in step S229), the stirring lamp 406 Is turned off (step S230).
This is because it enters a new stage of soup stock transfer processing.

Next, the CPU 502 blinks the handle opening / closing display lamp 407 disposed in the discharge area 401c of the first operation panel 401 (step S232).
To inform the operator that the soup stock discharge handle 19b is open, more precisely, the stock soup discharge handle 19b rotates counterclockwise and the stock soup valve 19a is open. This is to call attention.

Thereafter, the CPU 502 gives a temperature control stop instruction to the temperature controller 551a of the extraction temperature control unit 551 that controls the temperature control operation of the extraction tank 101 (step S233).
This is because the extraction tank 101 is emptied directly to prevent emptying by the extraction heater H1.

  At this time, the operator opens the extraction tank lid 13 and notices that the inside of the extraction tank 101 is empty, and closes the soup discharge handle 19b. That is, the soup stock discharge handle 19b is rotated clockwise to close the soup stock valve 19a.

  When the CPU 502 confirms that the soup discharge handle 19b is closed (YES in step S234), the handle open / close display lamp 407 is turned off (step S235), and the soup stock transfer process is completed.

(B-3) White stock pouring process The process flow when option 2 is selected is as follows.

As shown in the flowchart of FIG. 9, in step S221, the CPU 502 determines that the soup discharge handle 19b has been opened (YES in step S221).
As a result, the CPU 502 executes a “white soup pouring process” that is a process when the option 2 is selected.

In step S221, when the CPU 502 refers to the output value of the transfer sensor S10 and determines that the soup discharge handle 19b is opened (YES in step S221), the extraction lamp is lit in the extraction area 401b of the first operation panel 401. 405 is turned off (step S221).
This is because it enters a new stage of white dashi pouring.

Next, the CPU 502 blinks the handle opening / closing display lamp 407 disposed in the discharge area 401c of the first operation panel 401 (step S232).
To inform the operator that the soup stock discharge handle 19b is open, more precisely, the stock soup discharge handle 19b rotates counterclockwise and the stock soup valve 19a is open. This is to call attention.

Thereafter, the CPU 502 gives a temperature control stop instruction to the temperature controller 551a of the extraction temperature control unit 551 that controls the temperature control operation of the extraction tank 101 (step S233).
This is because the extraction tank 101 is emptied directly to prevent emptying by the extraction heater H1.

  At this time, the operator opens the extraction tank lid 13 and notices that the inside of the extraction tank 101 is empty, and closes the soup discharge handle 19b. That is, the soup stock discharge handle 19b is rotated clockwise to close the soup stock valve 19a.

  When the CPU 502 confirms that the soup stock discharge handle 19b is closed (YES in step S234), the handle open / close display lamp 407 is turned off (step S235), and the white soup pouring process is completed.

(C) Dashi stock warming and pouring process In the heat retaining tank 301, the soup stock is warmed and poured out.

  As shown in the flowchart of FIG. 10, the CPU 502 refers to the output of the water level sensor S9 when it is arranged at the bottom of the heat retention tank 301, and whether the heat retention tank 301 is empty (the water level sensor S9 is off) or the heat retention tank 301. It is determined whether dashi stock is stored (water level sensor S9 is on) (step S301).

When the water level sensor S9 is off, that is, when the heat retaining tank 301 is empty (NO in step S301), there is a risk of emptying if the temperature maintaining temperature control unit 553 is performing a temperature control operation.
Therefore, when it is determined that the temperature adjustment operation is being performed (YES in step S302), the CPU 502 gives a temperature adjustment stop instruction to the temperature maintaining temperature adjustment unit 553 (step S303), and when it is determined that the temperature adjustment operation is not being performed. In (NO in step S302), the process directly returns to the determination process in step S301.

When the water level sensor S9 is on, that is, when the soup stock is stored in the heat retaining tank 301 (YES in step S301), a temperature control operation by the temperature control unit 553 is required.
Therefore, the CPU 502 determines whether or not the temperature adjustment operation is in progress (step S304). If the temperature adjustment operation is not in progress (NO in step S304), after giving a temperature adjustment start instruction to the temperature-maintaining temperature adjustment unit 553 (step S305). ) If the temperature adjustment operation is in progress, the process proceeds to step S306.

The temperature maintaining temperature control unit 553 is stored in the temperature maintaining tank 301, but the juice is heated by the temperature maintaining heater H3, the temperature is measured by the temperature maintaining sensor TS3, and the temperature of the soup is set by the operation display unit 423 of the second operation panel 421. The temperature controller 553a controls on / off of the heat retaining heater H3 so that the temperature is maintained.
Therefore, when the stock broth is stored in the heat retaining tank 301 (YES in step S301), the temperature of the stock soup is adjusted by the temperature maintaining temperature control unit 553 and maintained at the set temperature input by the operation display unit 423.
Such a temperature control unit 553 starts a temperature control operation in response to a temperature control start instruction from the CPU 502 and stops a temperature control operation in response to a temperature control stop instruction.

The process in step S306 is a process for determining whether the operator intends to pour out the stock.
That is, in step S306, the CPU 502 determines whether the stock pouring lever 411 is pushed down and the stock pouring switch 412 is turned on.

If the CPU 502 determines that the stock pouring switch 412 is on (YES in step S306), it gives a drive signal to the pump drive circuit 511 to drive the stock pouring pump P3. As a result, the soup stock stored in the heat retaining tank 301 is sucked into the stock pour pump P3 and poured out from the stock pour tube 302.
Therefore, if the bowl D is placed on the table 16, the broth can be poured into the bowl D from the broth pipe 302.

However, as described above, the pour-out lever 411 returns to its original position by the urging force of a spring (not shown) when the hand is released from the depressed state. However, if the pouring lever 411 returns to the original position, the pouring pouring switch 412 is turned off.
If the CPU 502 determines that the stock pouring switch 412 is turned off (YES in step S308), the CPU 502 stops driving the stock pouring pump P3 (step S309) and ends the process.

(5) Effect According to the present embodiment, as described above, since hot water passes through the pack dm1 and circulates many times through the pack dm1 and circulates, the active ingredient is extracted from the dashi pack dm1. Dissolves well but juice can be extracted in a short time.
In addition, the soup stock producing apparatus 1 according to the present embodiment has several unique configurations, and exhibits a technical effect by such a configuration. Such configurations and effects are listed below.

According to the present embodiment, the hot water storage tank 201, the water heater H2, the hot water transfer unit 152, the first operation panel 401 (start button 404) as the operation unit, and the control unit 501 are provided.
Then, the control unit 501 operates the transfer pump P2 in accordance with an instruction to start the soup extraction operation by depressing the start button 404 (see step S201 in the flowchart of FIG. 8), so that the hot water storage tank 201 moves to the positive pressure chamber 103 in advance. A hot water transfer process for transferring the determined amount of hot water HW (see step S205 in the flowchart of FIG. 8) and an extraction process for operating the circulation pump P1 after the hot water HW is transferred to extract the soup stock (in the flowchart of FIG. 9). Step S217).
Therefore, the work of introducing the hot water HW into the extraction tank 101 becomes unnecessary, and not only the workability is good but also the safety can be improved.

According to the present embodiment, the water supply electromagnetic valve V1 interposed in the water supply pipe 202 for supplying water from the water supply to the hot water storage tank 201 is provided, and the control unit 501 controls the water supply electromagnetic valve V1 to measure the amount according to the amount of soup stock to be produced. By supplying only the tap water W to the hot water storage tank 201, a predetermined amount of hot water HW is transferred from the hot water storage tank 201 to the positive pressure chamber 103 during the hot water transfer process.
Therefore, the minimum required water is boiled in the hot water storage tank 201, so that energy efficiency can be improved.

According to the present embodiment, the control unit 501 switches the amount of stock soup to be produced in a plurality of stages in accordance with an instruction for designating the amount of stock soup extracted from the first operation panel 401 (changeover switch 402) (flowchart in FIG. 7). Steps S111 to S117 in the middle, steps S208 to S215 in the flowchart of FIG. 8).
Therefore, the optimal amount of broth can be produced from time to time, and waste can be eliminated.

According to the present embodiment, the hot water temperature sensor TS2 that measures the temperature of the hot water HW stored in the hot water storage tank 201 is provided, and the control unit 501 turns the water heater H2 on and off according to the measured value of the hot water temperature sensor TS2. Controlling and maintaining the temperature of the hot water HW stored in the hot water storage tank 201 at a predetermined temperature;
Therefore, hot water having a fixed temperature can be supplied to the extraction tank 101 at all times.

According to the present embodiment, the notification lamp 403 (6L lamp 403a, 12L lamp 403b, 18L lamp 403c) as a notification section for reporting information is provided, and the control section 501 is configured to supply hot water HW stored in the hot water storage tank 201. The notification lamp 403 is notified that the temperature has reached a predetermined temperature.
Therefore, it is possible to notify the operator of the timing for giving the start instruction for the soup stock extraction operation (see step S201 in the flowchart of FIG. 8).

According to the present embodiment, control unit 501 validates the dashi stock extraction operation start instruction on condition that the temperature of hot water stored in hot water storage tank 201 has reached a predetermined temperature.
Therefore, it is possible to prevent the inconvenience that the dashi soup extraction operation is started even though the hot water storage tank 201 is not ready for the hot water HW.

According to the present embodiment, the controller 501 includes the extraction heater H1 that heats the hot water stored in the extraction tank 101, and the soup stock temperature sensor TS1 that measures the temperature of the hot water stored in the extraction tank 101. The on / off state of the extraction heater H1 is controlled to maintain the temperature of hot water stored in the extraction tank 101 at a predetermined temperature.
Therefore, the temperature of the soup stock after manufacture can be maintained at an ideal temperature in the extraction tank 101.

According to the present embodiment, the control unit 501 stops the operation of the circulation pump P1 with the passage of a predetermined time according to the amount of the soup to be produced during the soup stock extraction process.
Therefore, without requiring management of the stock soup extraction time by the operator, that is, without requiring special know-how related to the soup stock production, it is possible to always obtain a homogenous soup stock at the optimum concentration no matter who performs the work. it can.

According to the present embodiment, the control unit 501 operates the circulation pump P1 in response to an instruction to start stirring the soup stock and the soup stock from the first operation panel 401 (start button 404). An agitation process is performed to agitate the kale soup that has been introduced into the extraction tank 101 later.
Therefore, the soup stock and the soup stock can be stirred using the mechanism (circulation pump P1) for the soup stock extraction.

According to the present embodiment, the control unit 501 stops the operation of the circulation pump P1 with the passage of a predetermined time during the stirring process.
Therefore, it is possible to sufficiently mix and mix the soup stock and the soup stock without requiring management of the stirring time by the operator.

(6) Modifications Various modifications and changes can be made during implementation.
Hereinafter, some modified examples will be exemplified.

(A) Modification 1
Based on FIG. 11, the modification of the soup stock manufacturing apparatus 1 of this Embodiment is demonstrated. The same parts as those described with reference to FIGS.

This example is an example in which a shaving node dm2 is used instead of the dashi pack dm1 as the dashi raw material dm.
Therefore, the set member 102 is provided with a flow member 102a that extends not only to the bottom but also to the side. As the flow member 102a, a very fine member is used because it is necessary to keep the cut node dm2 in the set portion 102.

(B) Modification 2
Based on FIG. 12, another modified example of the soup stock producing apparatus 1 of the present embodiment will be described. The same parts as those described with reference to FIGS.

This example is an example in which a water heater 251 is used instead of the hot water storage tank 201.
The water heater 251 is a first-stop type electric water heater, and its drain 252 is connected to the positive pressure chamber 103 of the extraction tank 101.
It is a pipe 161 that connects the hot water outlet 252 of the water heater 251 and the positive pressure chamber 103 of the extraction tank 101. A transfer electromagnetic valve V2 is interposed in the pipe 161 to control the transfer of hot water HW from the water heater 251 to the extraction tank 101. The transfer solenoid valve V2 is connected to a valve drive circuit 512, and the control unit 501 controls the transfer.

As described above, since the water heater 251 is used in this example, the hot water storage tank 201 and its peripheral structure, for example, the water supply pipe 202, the water supply electromagnetic valve V1, the water level sensors S5 to S8, the hot water temperature sensor TS2, the water heater H2, and the transfer pump. P2, the hot water supply pipe 151, etc. are unnecessary.
Moreover, since control with respect to the water heater 251 and its surrounding structures becomes unnecessary, the control part 501 does not perform the process shown in the flowchart of FIG.

  Although FIG. 12 shows an example in which the water heater 251 is housed in the lower housing 12b, the water heater 251 may be disposed anywhere in the implementation. For example, the water heater 251 can be disposed outside the housing 12 of the soup stock production apparatus 1.

With such a structure, the controller 501 drives the transfer solenoid valve V2 to open and close the pipe 161, whereby a desired amount of hot water HW can be supplied to the extraction tank 101.
At this time, the control unit 501 switches the amount of hot water to be transferred from the water heater 251 to the positive pressure chamber 103 in a plurality of stages in accordance with an instruction for designating the amount of extract from the first operation panel 401 (changeover switch 402). (See steps S208 to S215 in the flowchart of FIG. 8). As a result, an optimal amount of broth can be produced from time to time, and waste can be eliminated.

(C) Modification 3
In this embodiment, as the notification by the notification lamp 403, only the 6L lamp 403a, 12L lamp 403b, or 18L lamp 403c corresponding to 6 liter, 12 liter, or 18 liter selected by the switching state of the changeover switch 402 blinks. And an example of lighting is shown.

  On the other hand, the embodiment is not limited to this, and the 6L lamp 403a, 12L lamp 403b, and 18L lamp 403c may be blinked or lit regardless of the switching position of the changeover switch 402. . For example, even when 12 liters is selected by the changeover switch 402, all of the 6L lamp 403a, 12L lamp 403b, and 18L lamp 403c are blinked during preparation of hot water HW, and preparation of 6 liter of hot water HW is performed. If the 6L lamp 403a is changed from blinking to lighting when the lamp is ready, the notification may be made so that the 12L lamp 403b changes state from blinking to lighting when the 12-liter hot water HW is ready. At this time, the 18L lamp 403c may be kept in a blinking state or may be turned off.

  In the present embodiment, the flashing of the notification lamps 403a, 403b, and 403c indicates that the hot water HW is being prepared, and an example that indicates that the hot water HW is ready by lighting is shown. It is not limited to. For example, the notification lamps 403a, 403b, and 403c may be kept off during preparation of the hot water HW.

(D) Modification 4
In step S118 in the flowchart of FIG. 7, the CPU 502 of the control unit 501 receives a signal indicating whether the hot water HW has reached a specified set temperature from the hot water storage temperature adjustment unit 552, and tap water stored in the hot water storage tank 201. The process of determining whether W is a predetermined temperature determined in advance is exemplified.

  On the other hand, in the implementation, it is not limited to this process, and any process for determining whether the tap water W stored in the hot water storage tank 201 has a predetermined temperature can be adopted. It is. For example, an inquiry is sent from the CPU 502 of the control unit 501 to the hot water storage temperature control unit 552, and whether the tap water W stored in the hot water storage tank 201 from the hot water storage temperature control unit 552 is at a predetermined specified temperature. An answer may be obtained. Alternatively, only the temperature data measured by the hot water temperature sensor TS2 is received from the hot water temperature control unit 552, and the control unit 501 determines whether or not the tap water W stored in the hot water storage tank 201 has a predetermined temperature. May be determined by himself.

(E) Modification 5
In this embodiment, as hardware resources for executing various functions and processes, a control unit 501 (CPU 502, ROM 503, RAM 504, EEPROM 505), a timer 506, an extraction temperature adjustment unit 551, a hot water storage temperature adjustment unit 552, and The use of the temperature control unit 553 for heat insulation was illustrated.

  On the other hand, the implementation is not limited to this, and any hardware resource can be used as long as the same or similar functions and processes can be executed.

DESCRIPTION OF SYMBOLS 101 ... Extraction tank 102 ... Set part 103 ... Positive pressure chamber 104 ... Negative pressure chamber 105 ... Communication path 152 ... Hot water transfer part 161 ... Pipe 201 ... Hot water storage tank 202 ... Water supply pipe 401 ... First operation panel (operation unit)
403 ... Notification lamp (notification unit)
403a ... 6L lamp (notification part)
403b ··· 12L lamp (notification unit)
403c ··· 18L lamp (notification unit)
421 ... Second operation panel (operation unit)
501 ... Control unit dm ... Dashi raw material dm1 ... Dashi pack (Dashi raw material)
dm2 ・ ・ Shaving clause (raw material)
HW ... Hot water H1 ... Extraction heater H2 ... Water heater P1 ... Circulation pump P2 ... Transfer pump TS1 ·· Stock broth temperature sensor TS2 · · Hot water temperature sensor V1 · Water supply solenoid valve V2 ... Solenoid valves for transfer

Claims (13)

An extraction tank for storing the supplied hot water;
A set part on which the stock of the stock for extracting the soup stock is placed, detachably attached to the extraction tank with free circulation of hot water, and partitioning the inside of the extraction tank up and down;
Has a negative pressure chamber of the tufts (room) shape adjacent to the side surface located on the bottom surface and a lower positive pressure chamber located above the set portion in the extraction tank, contact a side surface of the negative pressure chamber A connecting path that connects the negative pressure chamber and the positive pressure chamber with the portion that performs as an inlet and the portion that communicates with the bottom surface of the positive pressure chamber as an outlet;
An impeller disposed rotatably in the communication path with a plurality of discharge ports provided in an outer peripheral portion facing a water inlet provided in a central portion facing the inlet, and the extraction tank A motor that is arranged outside and drives and rotates the impeller, and the impeller that is driven and rotated by the motor sucks hot water from the negative pressure chamber from the water suction port and discharges it from the discharge port. A circulation pump for returning to the positive pressure chamber;
An apparatus for producing soup stock. A hot water storage tank for storing water,
A water heater that heats the water stored in the hot water storage tank to form hot water;
A hot water transfer section for transferring hot water stored in the hot water storage tank to the positive pressure chamber by operation of a transfer pump;
An operation unit for giving instructions;
A hot water transfer process for operating the transfer pump according to a start instruction for the soup stock extraction operation of the operation unit to transfer a predetermined amount of hot water from the hot water storage tank to the positive pressure chamber, and the circulation pump after the transfer of hot water And a control unit that performs an extraction process for extracting the soup stock,
The dashi stock production apparatus according to claim 1, comprising: A water supply solenoid valve interposed in a water supply pipe for supplying water from a water supply to the hot water storage tank;
The controller is
A predetermined amount from the hot water storage tank to the positive pressure chamber during the hot water transfer process by controlling the water supply electromagnetic valve and supplying only the amount of tap water corresponding to the amount of broth to be produced to the hot water storage tank Transport hot water,
The apparatus for producing soup stock according to claim 2. The controller is
According to the instruction to specify the stock extract amount of the operation unit, the amount of the soup stock to be manufactured is switched to a plurality of stages.
The apparatus for producing the soup stock according to claim 3. A hot water temperature sensor for measuring the temperature of hot water stored in the hot water storage tank;
The controller is
Controlling the on / off of the water heater according to the measured value of the hot water temperature sensor, and maintaining the temperature of the hot water stored in the hot water storage tank at a predetermined temperature;
The apparatus for producing soup stock according to any one of claims 2 to 4. An informing unit for informing information,
The controller is
Informing the notification unit that the temperature of hot water stored in the hot water storage tank has reached a predetermined temperature;
The dashi stock production apparatus according to claim 5. The controller is
Enabling the start instruction of the soup stock extraction operation of the operation unit, provided that the temperature of the hot water stored in the hot water storage tank has reached a predetermined temperature,
The apparatus for producing soup stock according to claim 5 or 6. Piping for connecting the hot water outlet to the positive pressure chamber;
A transfer solenoid valve interposed in the pipe;
An operation unit for giving instructions;
In accordance with a start instruction for the soup stock extraction operation of the operation unit, the transfer solenoid valve is opened, a hot water transfer process for transferring a predetermined amount of hot water from the water heater to the positive pressure chamber, and the circulation after the transfer of hot water. A control unit for operating the pump and performing an extraction process for extracting the soup stock;
The dashi stock production apparatus according to claim 1, comprising: The controller is
Switching the amount of hot water to be transferred from the water heater to the positive pressure chamber in a plurality of stages in accordance with an instruction to specify the amount of broth extracted from the operation unit;
The apparatus for producing soup stock according to claim 8. An extraction heater for heating the hot water stored in the extraction tank;
A soup temperature sensor that measures the temperature of hot water stored in the extraction tank;
With
The controller is
Controlling the on / off of the extraction heater according to the measured value of the soup stock temperature sensor, and maintaining the temperature of hot water stored in the extraction tank at a predetermined temperature;
The apparatus for producing soup stock according to any one of claims 2 to 9. The controller is
During the extraction process, the operation of the circulation pump is stopped with the passage of a predetermined time according to the amount of the soup stock to be produced.
The apparatus for producing soup stock according to any one of claims 2 to 10. The controller is
The circulating pump is operated in accordance with an instruction to start the stirring operation of the soup stock and the soup stock in the operation unit, and a stirring process is performed to stir the manufactured stock and the back soup stock introduced into the extraction tank. ,
The apparatus for producing soup stock according to any one of claims 2 to 11. The controller is
During the stirring process, the operation of the circulation pump is stopped with the passage of a predetermined time.
The apparatus for producing soup stock according to claim 12.

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