JP2020025482A - Storage chamber - Google Patents

Abstract

To alleviate trouble of a user when setting the same operation condition on each storage room, while also allowing the user to set the operation condition individually for each storage room.SOLUTION: A dough conditioner 10 includes: a plurality of storage rooms 14 which stores bread dough, and in which each of the plurality of storage rooms 14 includes a function part (cooling device 20, heating device 21, humidifying device 22) for performing at least one of cooling, heating and humidifying inside each storage room 14; an operation panel 26(upper room operation panel 26A, lower room operation panel 26B) provided at each storage room 14, and for receiving the setting of an operation condition of the storage room 14; a control device 24 for operating each storage room 14 based on the operation condition of each storage room 14; and a setting copy button 89 for receiving the copy instruction for copying the operation condition. When the control device 24 has received a copy instruction by the setting copy button 89, it copies the operation condition of one storage room 14 as the operation condition of the other storage room 14.SELECTED DRAWING: Figure 10

Description

  The technology disclosed herein relates to a storage.

2. Description of the Related Art Conventionally, a storage including a plurality of storage rooms that store storage objects, and a plurality of storage rooms each having a functional unit that performs at least one of cooling, heating, and humidification in the storage room is known (for example, Patent Document 1).
Specifically, the temperature and humidity control cabinet for bread making described in Patent Literature 1 has two storage chambers for storing trays on which bread dough is placed in a multi-stage configuration, and the storage chambers are arranged vertically. Temperature control means and humidity control means are provided. In the temperature and humidity control cabinet for bread making, the temperature and humidity of the storage room are independently adjusted by the temperature control means and the humidity control means provided in each storage room, and the bakery dough is matured and fermented.

JP 2000-300555 A

  When a plurality of storage rooms are provided as in the bread-making temperature and humidity control cabinet described in Patent Document 1, different types of bread dough can be aged and fermented for each storage room. Usually, different types of bread dough have different temperatures and humidity suitable for aging and fermentation. Therefore, in general, a storage provided with a plurality of storage rooms is set at a set temperature and a set humidity for each storage room. In the following description, the set temperature and the set humidity are referred to as operating conditions of the storage room.

  By the way, the same kind of bread is sometimes produced in large quantities. In that case, the same type of dough is stored in a plurality of storage rooms, and the same operating conditions are set in each storage room. In this case, in the conventional storage, the user performs the same setting operation for each storage room, which is troublesome for the user.

  The present specification discloses a technique for reducing the user's labor when setting the same operating conditions in each storage room while enabling the operating conditions to be set individually for each storage room.

  The storage disclosed in the present specification is a plurality of storage rooms for storing storage items, each of which has a function unit for performing at least one of cooling, heating, and humidification in the storage room; A setting unit that is provided for each room and receives a setting of an operation condition of the storage room, a control unit that operates each of the storage rooms based on the operation condition of the storage room, and copies the operation condition. A receiving unit that receives a copy instruction; and when the receiving unit receives the copy instruction, the control unit copies the operating condition of one storage room as the operating condition of another storage room.

  According to the above-mentioned storage, since the setting unit is provided for each storage room, the operating conditions can be individually set for each storage room. Further, according to the storage, the operating condition of one storage room can be copied as the operating condition of another storage room, so that the user's labor when setting the same operating condition in each storage room can be reduced. Therefore, according to the storage, it is possible to set the operating conditions individually for each storage room and to reduce the user's labor when setting the same operating conditions in each storage room.

  The setting unit is capable of receiving a plurality of operating condition settings, and the storage unit is a selecting unit that receives selection of the operating condition to be copied from among the plurality of operating conditions set in one storage room. And the control unit may copy the operating condition selected by the selection unit when receiving the copy instruction.

  According to the storage, the operating conditions to be copied can be selected, so that only necessary operating conditions can be copied from a plurality of operating conditions.

  The setting unit is capable of receiving a plurality of settings of the operating conditions, and the control unit, when receiving the copy instruction, collectively copies all the operating conditions set in one storage room. You may.

  According to the storage, all the set operating conditions can be copied by a single copy instruction, so that the user's labor when copying all the set operating conditions can be reduced.

  A storage disclosed in the present specification is a plurality of storage rooms for storing storage items, each of which has a function unit for performing at least one of cooling, heating, and humidification in the storage room; A setting unit that is provided for each room and receives a setting of an operation condition of the storage room; a component that is commonly used for the operation of each storage room and that can be set to operate; A control unit that operates on the basis of the operating conditions of the storage room, and includes a control unit that operates the storage room using the component, and any one of the plurality of setting units. The operation setting of the component can be set only by the setting unit.

  When there is a part commonly used for the operation of a plurality of storage rooms, if the operation of the part can be set in each setting unit, the user misunderstands that the operation of the part can be set separately for each storage room. There is a fear. According to the above-mentioned storage, since the setting of the component can be performed only in any one of the plurality of setting units, the user may misunderstand that the operation of the component can be separately set for each storage room. Performance can be reduced.

  The component may be a clock unit, and the operation setting may be a time setting of the clock unit.

  According to the above storage, the time can be set only in any one of the plurality of setting units, so that the possibility of the user misunderstanding that the time can be set separately for each storage room is reduced. it can.

  The component may be a sound generator, and the operation setting may be a volume setting of the sound generator.

  According to the above-mentioned storage, since the volume can be set only in one of the plurality of setting units, it is possible to reduce the possibility that the user mistakenly thinks that the volume can be set separately for each storage room. it can.

The front view of the deconditioner which is the storage of the embodiment of the present invention. Front view showing a state where the opening / closing door of the deconditioner is removed. Side view of the deconditioner Top view of deconditioner Rear view of deconditioner Side view schematically showing the inside of one space of the deconditioner It is the figure which showed roughly the functional part with respect to one space of the deconditioner, and which shows the flow of the air which flows into a storage. Block diagram showing the electrical configuration of the deconditioner Enlarged view of the upper room operation panel Enlarged view of lower room operation panel Schematic diagram for explaining settings on the upper room operation panel Schematic diagram for explaining the settings on the lower room operation panel

<First embodiment>
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings as embodiments for carrying out the present invention. It should be noted that the present invention is not limited to the following examples, and can be implemented in various modes with various changes and improvements based on the knowledge of those skilled in the art.

(1) Configuration of Deconditioner A deconditioner 10 as a storage according to the first embodiment will be described with reference to FIGS. 1 to 5. The deconditioner 10 manages from the freezing to the fermentation of the formed dough. Specifically, the deconditioner 10 sequentially performs a freeze (freezing) step, a retard (refrigeration) step, a preheating step, and a proofing (fermentation) step on the formed dough before entering the bread baking step. It can be executed automatically, or any of the steps can be executed alone. The deconditioner 10 controls the temperature in accordance with each of these steps, and also controls the humidity in addition to the temperature control in the preheating step and the heating step.

  In the following description, automatically executing the freeze step, the retard step, the preheating step, and the proofing step in order is referred to as a program operation, and executing any of the steps independently is referred to as an independent operation.

  As shown in FIGS. 1 to 3, the deconditioner 10 is mainly configured by a housing 11 as a storage body, which is a box-shaped housing that opens forward. The housing 11 has two vertically arranged spaces 12A and 12B, and storage spaces 14A and 14B for storing dough (storage material) are provided in each of the spaces. The two storage chambers 14A and 14B are open on the front side, and the housing 11 is provided with two doors 15A and 15B that open and close the storage chambers 14A and 14B. In the following description, the storage room 14A is also called an upper room, and the storage room 14B is also called a lower room.

  In each of the storage chambers 14A and 14B, a pair of left and right tray guides (shelf support members) 16 are detachably provided on each of the left and right side walls, and each of the plural pairs of tray guides 16 is provided. , A tray (shelf) on which a large number of doughs are placed can be placed.

  The deconditioner 10 includes a cooling device 20 and a heating device 21 for performing temperature control, a humidifying device 22 for performing humidity control, and a control for controlling the cooling device 20, the heating device 21, the humidifying device 22, and the like. Device 24 (an example of a control unit).

As shown in FIG. 2, a machine room 25 having an open top is provided above the housing 11, and a part of the cooling device 20 and the humidifying device 22 and a control device 24 are provided in the machine room 25. Etc. are accommodated.
Also, as shown in FIG. 1, an upper room operation panel 26A (an example of a setting unit) for performing settings and operations related to the upper storage room 14A, and a lower storage room are provided on the front surface of the machine room 25. A lower room operation panel 26B (an example of a setting unit) for performing settings, operations, and the like relating to 14B is provided. The operation panel 26 will be described later.

As shown in FIG. 3, in each of the spaces 12A and 12B of the housing 11, on the back side (rear side) of each of the storage rooms 14A and 14B, a function unit 19 for adjusting the temperature and humidity of the storage rooms 14A and 14B. Functional unit chambers 30A and 30B that house a part of the cooling device 20, the heating device 21, and the humidifying device 22 (see FIG. 8) are formed. The storage chambers 14A and 14B and the functional unit chambers 30A and 30B are partitioned by a rear panel 32 as a partition member that is a generally plate-shaped member.
As shown in FIG. 5, in the cooling device 20 and the humidifying device 22, the components provided in the machine room 25 and the components provided in the functional unit chambers 30 </ b> A and 30 </ b> B Connected by

  Hereinafter, the internal configuration of each of the spaces 12A and 12B of the housing 11 will be described in detail. Since the configurations in the spaces 12A and 12B are almost the same, the description of the interior of the space 12 will be described on behalf of the upper space 12A with reference to FIG. Further, in the following description, when it is necessary to distinguish between the upper space 12A and the lower space 12B, the reference numerals are denoted by A and B, respectively. And

  As shown in FIG. 6, in the space 12, in addition to the back panel 32 described above, a top panel 33 and a bottom panel 34, which are generally plate-shaped members, are respectively provided on the top surface and the bottom surface. Is arranged. Each of the top panel 33 and the bottom panel 34 connects the storage room 14 and the functional unit room 30 between the top surface of the space 12 and the bottom surface of the space 12, respectively. A circulation path (duct) for circulation is formed. That is, the top panel 33 functions as a top duct member, and the bottom panel 34 functions as a bottom duct member.

  A circulating fan 36 is accommodated in the functional unit room 30, and the circulating fan 36 sends air from above to below in the functional unit room 30. In other words, a circulation path formed by the top panel 33 and the top surface of the space 12 by the circulation fan 36 functions as an intake path 37 that sucks air from the storage room 14 into the functional unit room 30, and The circulation path formed by the bottom surface of the space 12 functions as a discharge path 38 for discharging air from the functional section chamber 30 to the storage chamber 14. That is, when the circulation fan 36 operates, the air in the storage room 14 is sucked into the functional unit room 30 via the intake path 37, passes through the function unit room 30, and is discharged into the storage room 14 via the discharge path 38.

  Further, in the deconditioner 10, the temperature and humidity of the air sent from above to below by the circulation fan 36 (in other words, the air passing through the functional unit chamber 30) are adjusted, and the temperature and humidity are adjusted. Is sent to the storage room 14. Specifically, first, as shown in the schematic diagram of FIG. 7, an evaporator (evaporator) 40 constituting the cooling device 20 is housed in the functional unit chamber 30. The cooling device 20 lowers the temperature of the storage room 14 by cooling the air sent from the circulation fan 36 by the evaporator 40.

  The cooling device 20 uses a well-known cooling circuit, and includes a compressor 41, a condenser 42, expansion means 43, and the evaporator 40 described above. In brief, the refrigerant gas compressed by the compressor 41 is cooled by the condenser 42 to become a liquefied refrigerant, and the liquefied refrigerant is decompressed by the expansion means 43 to become a low-pressure gas-liquid mixed refrigerant, Sent to 40. Then, in the evaporator 40, the refrigerant evaporates and cools the air with the heat of evaporation.

  Note that components other than the evaporator 40 in the cooling device 20 are housed in a machine room 25 as shown in FIGS. As shown in FIG. 5, the compressor 41 and the expansion means 43 are connected to the evaporator 40 by refrigerant pipes 44A and 44B.

  The heating unit 21 is housed in the functional unit room 30. The heating device 21 is mainly composed of three glass tube heaters 46, and raises the temperature of the storage room 14 by heating the air sent from the circulation fan 36 by the heaters 46.

  As shown in FIG. 3, the three heaters 46 extend in the left-right direction and are held in a state of being arranged in the front-rear direction by a heater bracket 47, and are attached to the lower side of the evaporator 40. That is, the heating device 21 efficiently heats the air by the radiant heat and also functions as a defrost heater of the evaporator 40 arranged on the upper side.

  Further, a part of the humidifier 22 is accommodated in the functional section room 30. The humidifier 22 includes a spray nozzle 50 that is a two-fluid nozzle that sprays water in a mist state, a water supply pipe 51 that supplies water to the spray nozzle 50 from a water supply source, and an air supply pipe 52 that supplies air to the spray nozzle 50. And an air pump 53 that sends air in a pressurized state to the spray nozzle 50 through the air supply pipe 52.

  The water supply pipe 51 is provided with a water supply valve 51a, and a drain pipe 54 is connected to the spray nozzle 50 side from the water supply valve 51a, and the drain pipe 54 is provided with a drain valve 54a. The air pump 53 is configured to supply the air sucked from the inside of the functional section chamber 30 to the spray nozzle 50.

  Although the detailed illustration and description of the spray nozzle 50 are omitted, the spray nozzle 50 has a double cylinder arrangement, a water outlet is provided at the tip of the inner cylinder, and the outer cylinder has An air outlet is provided at the tip. The air outlet is located at a position behind the water outlet, and the air is sprayed from behind the jetted water, so that the water is atomized in front of the spray nozzle 50. I do.

  As shown in FIG. 3, the tip of the spray nozzle 50 is attached to the lower side of the heating device 21 so as to face the inside of the functional unit chamber 30 from the side surface.

  Then, the humidifier 22 opens the water supply valve 51 a and operates the air pump 53 to spray mist of water from the spray nozzle 50. Thereby, the air sent from the circulation fan 36 is humidified, and the humidity of the storage room 14 is increased. When the water is not sprayed from the spray nozzle 50, the humidifier 22 opens the drain valve 54a and discharges the water from the drain pipe 54 so that the water does not remain in the water supply pipe 51. .

  Further, a temperature sensor 60 and a humidity sensor 61 (see FIG. 7) are accommodated in the functional section room 30.

(2) Electrical Configuration of Deconditioner The electrical configuration of the deconditioner 10 will be described with reference to FIG. The control device 24 is a substrate on which a microcomputer 56 having a CPU, ROM, RAM and the like integrated into one chip, a clock unit 62 and the like are mounted.
The control device 24 includes a circulation fan 36, a functional unit 19 (cooling device 20, heating device 21, and humidifying device 22), a temperature sensor 60, a humidity sensor 61, an upper operation panel 26A, a lower operation panel 26B, and a buzzer 63 (sound generation). Section) is connected. The deconditioner 10 includes a circulation fan 36, a function unit 19, a temperature sensor 60, and a humidity sensor 61 for each storage room 14, but only one is shown here.

  The clock unit 62 is a real-time clock for the microcomputer 56 to obtain the current time. The buzzer 63 emits a buzzer sound when the program operation is completed (in other words, when a completion time described later has arrived) and notifies the user of the buzzer sound. The clock 62 and the buzzer 63 are components commonly used for the operation of the two storage rooms 14, and are components whose operation can be set.

  As will be described in detail later, an operation menu (an example of operation conditions) is individually set in each storage room 14. The control device 24 controls the circulation fan 36 and the functional unit 19 of each storage room 14 based on the operation menu, thereby adjusting the temperature and the humidity independently for each storage room 14. Specifically, a set temperature, a set humidity, and the like are set in the operation menu. The control device 24 detects the temperature and the humidity of the storage room 14 with the temperature sensor 60 and the humidity sensor 61 and controls the circulation fan 36 and the function unit 19 so that the temperature and the humidity of the storage room 14 become the set temperature and the set humidity. . Controlling the circulation fan 36 and the functional unit 19 is an example of operation of the storage room.

(2) Upper Room Operation Panel and Lower Room Operation Panel First, the upper room operation panel 26A will be described with reference to FIG. The upper room operation panel 26A is arranged on a temperature display section 71, a humidity display section 72, a time / time display section 73, an independent operation menu / holiday display section 74, an operation button 75, a program button 76, and a program button 76. Three menu number lamps 77, a start / stop button 78, a process button 79 (a freeze button 79A, a retard button 79B, a preheat button 79C, and a wheel button 79D), and four process lamps 80 arranged above each process button 79. , A temperature button 81, a humidity button 82, a clock button 83, an oven button 84, a setting / registration button 85, an upper button 86, a lower button 87, a time display switching button 88, and the like. The upper room operation panel 26A also has buttons other than these, but the description is omitted here.

  The temperature display section 71 displays the current temperature or the set temperature for 7 segments. The humidity display section 72 displays the current humidity or the set humidity for 7 segments. The time / time display unit 73 displays various times and times (current time, completion time, which is the time when the program operation is completed, process time, which is the time for executing the process, remaining time of the process time, etc.) in seven segments. It is. The islanding operation menu / holiday display section 74 displays the islanding operation menu or the number of holiday days in seven segments.

  The operation button 75 is a button for turning on / off the power of the deconditioner 10. The program button 76 is a button for selecting an operation menu of a program operation described later. The menu number lamp 77 is for displaying the selected operation menu, and is composed of three LEDs numbered 1 to 3. The program button 76 and the menu number lamp 77 are examples of a selection unit.

  The start / stop button 78 is a button for starting and stopping the program operation. The freeze button 79A, the retard button 79B, the preheat button 79C, and the wheel button 79D are buttons for independently operating each process. The temperature button 81 is a button for setting a set temperature. The humidity button 82 is a button for setting a set humidity.

The clock button 83 is a button for setting various times and times when setting the operation menu. The oven button 84 is a button for setting how many minutes before the completion time a signal instructing start of preheating of the oven is output to the oven at the time of setting. The setting / registration button 85 is a button for setting an operation menu for the program operation and the individual operation of each process. The upper button 86 and the lower button 87 are buttons for changing the temperature, temperature, time, and the like at the time of setting. The time display switching button 88 is a button used to switch setting items at the time of setting.
Note that the clock button 83, the oven button 84, the time display switching button 88, and the like are used for other purposes while the deconditioner 10 is stopped or operating, but the description is omitted here.

  Next, the lower room operation panel 26B will be described with reference to FIG. The configuration of the lower room operation panel 26B is almost the same as that of the upper room operation panel 26A, except that the lower room operation panel 26B is provided with a setting copy button 89 (an example of a receiving unit) instead of the operation button 75. The setting copy button 89 will be described later.

(4) Operation Menu Setting and Operation Procedure The operation menu setting and operation procedure will be described with reference to FIG. As described above, the deconditioner 10 can perform a program operation in which four steps are automatically executed in order and a single operation in which any one of the steps is executed alone. Three operation menus can be set for the program operation and each individual operation. That is, a total of 15 operation menus can be set in the deconditioner 10.
Here, the operation procedure of the deconditioner 10 will be described first, and then the setting of the operation menu will be described.

(4-1) Operation Procedure (4-1-1) Operation Procedure of Program Operation When performing the program operation, the user presses the program button 76 to select an operation menu. Specifically, when the user presses the program button 76, the first menu number lamp 77 is turned on, and the menu number lamp 77 that is turned on every time the user presses the program button 76 is switched in order. Thereby, the operation menu can be selected.

  When the user presses the start / stop button 78 in a state where the operation menu is selected, the program operation is started, and the circulation fan 36 and the functional unit 19 in the upper room are operated according to the selected operation menu. After the start of the operation, when a later-described completion time comes, the program operation ends. When the program operation is completed, a buzzer sound is emitted by the buzzer 63, and the user is notified that the program operation has been completed. Note that the program operation can be terminated by pressing the start / stop button 78 after the operation is started.

(4-1-2) Operation procedure of independent operation When performing individual operation of each process, the user presses the process button 79 of the process to be operated. When the user presses the process button 79, the process lamp 80 corresponding to the process button 79 is turned on, and the single operation of the process is started.
When the user presses the process button 79, 1 is initially displayed as a menu number on the single operation menu / holiday display section 74, and the menu number displayed each time the process button 79 is pressed is sequentially switched. Thereby, the operation menu can be selected. The islanding operation is continued until the user presses and holds the process button 79, and ends when the user presses and holds the process button 79.

(4-2) Procedure for setting the operation menu (4-2-1) Procedure for setting the operation menu for the program operation The operation menu for the program operation can be set only while the operation is stopped. In the setting of the operation menu of the program operation, the completion time for completing the program operation, the set temperature of each process, and the process time of each process are set. Further, in the case of the preheating step and the heating step, the set humidity is further set. Hereinafter, a specific description will be given.

(A) Selection of operation menu While the operation is stopped, the user presses the program button 76 to select a menu number of the operation menu.

(B) Completion time setting When the user presses the setting / registration button 85, the menu number lamp 77 of the selected operation menu switches to blinking. When the user presses the clock button 83 in this state, the "hour" of the time / time display section 73 blinks. In this state, the user presses the up button 86 / down button 87 to set "hour". When the user presses the clock button 83 while "hour" is blinking, "minute" blinks. The user presses the up button 86 / down button 87 in this state to set “minute”.

  After that, when the user presses the setting / registration button 85, the setting is reflected, and the completion time changes to lighting. When the user presses the setting / registration button 85 for a long time, the menu number lamp 77 returns to lighting.

(C) Setting of the freeze process When the user presses the setting / registration button 85, the menu number lamp 77 of the selected operation menu switches to blinking. When the user presses the freeze button 79A in this state, the process lamp 80 of the freeze button 79A is turned on, and the current set temperature is displayed on the temperature display section 71, and the current process time is displayed on the time / time display section 73.

  When the user presses the temperature button 81, the set temperature flashes. The user changes the set temperature by pressing the up button 86 / down button 87 in that state. When the user presses the setting / registration button 85, the change is reflected and the set temperature changes to lighting.

When the user presses the clock button 83, the process time (minute) on the time / time display section 73 blinks. The user presses the up button 86 / down button 87 in that state to change the process time. When the user presses the setting / registration button 85, the change is reflected, and the process time changes to lighting.
When the user presses the setting / registration button 85 for a long time, the menu number lamp 77 returns to lighting.

(C) Setting of the retarding step The setting of the retarding step is substantially the same as that of the freeze step, and therefore, the description is omitted.

(D) Setting of the preheating step The setting of the preheating step is substantially the same as that of the freeze step except that the set humidity is further set, so that the description is omitted.

(E) Setting of the wheeling step The setting of the wheeling step is substantially the same as that of the freeze step except that the set humidity is further set, so that the description is omitted.

(4-2-2) Procedure for setting the operation menu of the independent operation The setting of the operation menu of the independent operation can be performed only during the operation. In the setting of the operation menu of the single operation, the set temperature of the process during the operation is set. Further, in the case of the preheating step and the heating step, the set humidity is further set. Hereinafter, a specific description will be given.

(A) Start of Single Operation The user presses the process button 79 of the operation process to start single operation.

(B) Setting of temperature and humidity When the user presses the temperature button 81 during the single operation, the current set temperature blinks. The user changes the set temperature by pressing the up button 86 / down button 87 in that state. After that, when the user presses the setting / registration button 85, the change is reflected, and the lighting is replaced with the lighting of the current internal temperature.

  In the case of the preheating step and the heating step, the set humidity can be further set. When the user presses the humidity button 82 during the independent operation of the preheating process or the heating process, the current set humidity flashes. The user changes the set humidity by pressing the upper button 86 / the lower button 87 in that state. After that, when the user presses the setting / registration button 85, the change is reflected, and the current chamber humidity is replaced with lighting.

(5) Copy of operation menu When mass-producing the same type of bread, the user stores the same type of bread dough in the upper and lower rooms, and sets the same operation menu in the upper and lower rooms. However, as described above, many button operations are required to set the driving menu, and it is troublesome for the user to perform the same setting operation for the lower room after performing the upper room setting operation. Therefore, the operation condition of the upper room can be copied to the lower room in the deconditioner 10. Hereinafter, a specific description will be given.

(5-1) Procedure for Copying the Operation Menu for Program Operation The operation menu for program operation can be copied only when both the upper and lower rooms are in operation stop.

  First, the user presses the program button 76 on the upper room operation panel 26A to select an operation menu as a copy source. Next, the user presses the program button 76 on the lower room operation panel 26B to select an operation menu as a copy destination. Next, the user presses a setting copy button 89 on the lower room operation panel 26B. Thereby, the operation menu selected in the upper room is copied to the operation menu selected in the lower room.

  Here, the case where the operation menu can be selected independently in the upper room and the lower room has been described as an example, but the operation menu selected in the upper room may be copied to the operation menu of the same menu number in the lower room. Good. In that case, the operation menu selection on the lower room operation panel 26B becomes unnecessary, so that the user's labor is further reduced.

(5-2) Procedure for copying the operation menu of the independent operation The copy of the operation menu of the independent operation can be performed only during the operation.
First, the user presses the process button 79 of the process serving as a copy source on the upper room operation panel 26A to start the independent operation. Next, the user presses the process button 79 to display the operation menu number as the copy source on the single operation menu / holiday display section 74.

  Next, the user presses the process button 79 of the same process on the lower room operation panel 26B to start the independent operation. Next, the user presses the process button 79 to display the number of the operation menu to be copied on the single operation menu / holiday display section 74. Next, the user presses a setting copy button 89 on the lower room operation panel 26B. As a result, the selected operation menu is copied.

  Here, the case where the operation menu can be selected independently in the upper room and the lower room has been described as an example, but the operation menu selected in the upper room may be copied to the operation menu of the same menu number in the lower room. . In that case, the operation menu selection on the lower room operation panel 26B becomes unnecessary, so that the user's labor is further reduced. Further, the operation menu may be copied for the lower room without starting the independent operation.

(6) Effects of Embodiment According to the deconditioner 10 according to the first embodiment, since the operation panel 26 is provided for each storage room 14, an operation menu can be set individually for each storage room 14. In addition, according to the deconditioner 10, since the operation menu of one storage room 14 can be copied as the operation menu of another storage room 14, the user's labor when setting the same operation menu in each storage room 14 can be reduced. . Therefore, according to the deconditioner 10, the operation menu can be set individually for each storage room 14, and the user's labor when setting the same operation menu in each storage room 14 can be reduced.

  According to the deconditioner 10, since the operation menu to be copied can be selected, only a necessary operation menu can be copied from a plurality of operation menus.

<Embodiment 2>
Next, a second embodiment will be described with reference to FIGS.
As described above, the clock 62 and the buzzer 63 are parts commonly used for operating the two storage rooms 14. On the operation panel 26 according to the second embodiment, the operation setting of these components (time setting in the case of the clock unit 62, volume setting in the case of the buzzer 63) can be performed.

  However, when the operation of the components commonly used for the operation of the two storage rooms 14 is set, if the operation can be set on either the upper operation panel 26A or the lower operation panel 26B, the user can set the components for each storage room 14 The user may be confused that the operations can be separately set, and the user may be confused. Therefore, in the deconditioner 10 according to the second embodiment, the operation of these components can be set only on the upper room operation panel 26A.

(1) Setting Operation of Upper Room Operation Panel With reference to FIG. 11, setting operation of the time and the buzzer sound volume on the upper room operation panel 26A will be described.

(A) Setting standby display When the user presses the setting / registration button 85 for a long time while the operation of the deconditioner 10 is stopped, the time / time display 73 is turned off, and “−” flashes in the single operation menu / holiday display 74. I do. Here, this state is called a setting standby display.

(B) Time setting When the user presses the clock button 83 in the setting standby display, the mode shifts to time setting. When a transition is made to the time setting, the current time is displayed on the time / time display section 73, and “hour” flashes. In this state, the user presses the up button 86 / down button 87 to set "hour". When the user presses the clock button 83 while "hour" is flashing, the display switches to "minute". The user presses the up button 86 / down button 87 in this state to set “minute”. After that, when the user presses the setting / registration button 85, the setting is reflected, and the display returns to the setting standby display. When the display returns to the setting standby display, the current time changes to lighting.

(C) Buzzer volume setting When the user presses the time display switching button 88 in the setting standby display, the state transits to the buzzer volume setting. When transitioning to the buzzer volume setting, “bL” is displayed on the temperature display section 71, and the buzzer volume is displayed on the humidity display section 72. In this state, the user presses the up button 86 / down button 87 to change the buzzer volume. Pressing the up button 86 / down button 87 causes the buzzer volume to flash. After that, when the user presses the setting / registration button 85, the setting is reflected, and the display returns to the setting standby display. When the display returns to the setting standby display, the buzzer volume changes to lighting.

(D) Time Adjustment Step Selection The time adjustment step selection is to select whether the time adjustment is performed in the freeze step or the retard step so that the wheel step is completed at the completion time in the case of the program operation.
When the user presses the time display switching button 88 in the buzzer sound volume setting, the process shifts to time adjustment process selection. Upon transition to the time adjustment step selection, “Aj” is displayed on the temperature display section 71, and “F” or “r” is displayed on the humidity display section 72 as the time adjustment step. “F” stands for a freeze step, and “r” stands for a retard step. The initial setting is “r”. The user presses the up button 86 / down button 87 in that state to change the time adjustment process. Pressing the up button 86 / down button 87 causes the time adjustment process to flash. After that, when the user presses the setting / registration button 85, the setting is reflected and returns to the buzzer sound volume setting.

(E) Other Settings When the user presses the temperature button 81 in the setting standby display, the mode transits to the humidification start temperature setting, and the humidification start temperature which is the temperature at which humidification starts can be set. When the oven button 84 is pressed in the setting standby display, the process transits to oven preheating time setting, and it is possible to set how many minutes before the completion time a signal instructing the start of oven preheating is output to the oven.

(F) End of setting standby display When the user presses and holds the setting / registration button 85 in the setting standby display, the setting standby display ends. When the setting standby display is completed, the current time is displayed on the time / time display section 73, and the temperature display section 71, the humidity display section 72, and the single operation menu / holiday display section 74 are turned off.

(2) Setting Operation of Lower Room Operation Panel Next, a setting operation of the lower room operation panel 26B will be described with reference to FIG. The setting operation of the lower room operation panel 26B is basically the same. When the user presses and holds the setting / registration button 85 while the operation is stopped, the setting standby display is displayed.

  However, time setting and buzzer sound volume setting cannot be performed on the lower room operation panel 26B. Specifically, in the lower room operation panel 26B, even if the clock button 83 is pressed in the setting standby display, the state does not transition to the time setting. Further, in the lower room operation panel 26B, even if the time display switching button 88 is pressed in the setting standby display, the state does not transition to the buzzer volume setting. In the case of the lower room operation panel 26B, when the time display switching button 88 is pressed in the setting standby display, the process transits to the time adjustment process selection.

(3) Effects of the Embodiment According to the deconditioner 10 according to the second embodiment, the operation setting of the parts commonly used for the operation of the two storage rooms 14 can be performed only on the upper room operation panel 26A. The possibility of misunderstanding that the operation of the component can be set separately for each storage room 14 can be reduced.

  According to the deconditioner 10, since the time of the clock unit 62 can be set only by the upper room operation panel 26A, the possibility that the user misunderstands that the time can be set separately for each storage room 14 can be reduced.

  According to the deconditioner 10, since the buzzer sound volume of the buzzer 63 can be set only by the upper room operation panel 26A, it is possible to reduce the possibility that the user misunderstands that the buzzer sound volume can be set separately for each storage room 14. .

<Other embodiments>
The technology disclosed in the present specification is not limited to the embodiments described in the above description and the drawings. For example, the following embodiments are also included in the technical scope disclosed in the present specification.

  (1) In the above-described embodiment, an example has been described in which the user selects an operation menu to be copied from a plurality of operation menus that have been set. On the other hand, when the setting copy button 89 is pressed, all the set operation menus may be copied at a time. In this way, the user's trouble in copying all the set operation menus can be reduced.

  (2) In the above embodiment, the case where the operation menu of the upper storage room 14 is copied as the operation menu of the lower storage room 14 has been described as an example. Conversely, the operation menu of the lower storage room 14 may be copied as the operation menu of the upper storage room 14. Alternatively, the operation menu may be bidirectionally copied between the upper storage room 14 and the lower storage room 14.

  (3) In the above embodiment, the time and buzzer sound volume can be set only with the upper room operation panel 26A, but may be set only with the lower room operation panel 26B. If there is another commonly used component, the setting of that component may be similarly settable only on the upper or lower operation panel 26.

  (4) In the above embodiment, the deconditioner 10 has been described as an example of the storage. However, the storage is not limited to the deconditioner 10 and has a function unit that performs at least one of cooling, heating, and humidification in the storage room. Any storage may be used. For example, the storage may be a refrigerator with two or more refrigerator compartments. In that case, a cooling device that cools the refrigerator compartment corresponds to the functional unit. In this case, the storage is not limited to bread dough, and any storage can be stored as needed.

  (5) In the above embodiment, the case where three operation menus can be set for each of the program operation and each individual operation has been described as an example, but only one operation menu may be set for each.

  (6) In the above-described embodiment, an example has been described in which the setting of the operation menu of the isolated operation can be performed only during the operation. On the other hand, if the control is performed such that the operation is started by selecting the operation menu and pressing the start / stop button 78 in the same manner as in the program operation, the operation menu of the independent operation can be set while the operation is stopped. Can be With such control, it is also possible to copy the operation menu of the isolated operation while the operation is stopped.

DESCRIPTION OF SYMBOLS 10 ... Deconditioner (an example of a storage), 14 ... Storage room, 19 ... Functional part, 20 ... Cooling device (part of a functional part), 21 ... Heating device (part of a functional part), 22 ... Humidifier (function) , 24 ... Control device (an example of a control unit), 26A ... Upper room operation panel (an example of a setting unit), 26B ... Lower room operation panel (an example of a setting unit), 62 ... Clock unit (of parts) 63) Buzzer (example of parts), 76: Program button (example of selection unit), 77: Menu number lamp (example of selection unit), 89: Copy setting button (example of reception unit)

Claims (6)

A plurality of storage rooms for storing storage, each having a functional unit that performs at least one of cooling, heating and humidification of the storage room,
A setting unit that is provided for each of the storage rooms and receives a setting of an operation condition of the storage room;
A control unit that operates each of the storage rooms based on the operation conditions of the storage room,
A receiving unit that receives a copy instruction to copy the operating conditions,
With
A storage unit that, when the receiving unit receives the copy instruction, copies the operating condition of one storage room as the operating condition of another storage room; The storage according to claim 1,
The setting unit is capable of receiving a plurality of settings of the operating conditions,
The storage includes a selection unit that receives a selection of the operating condition to be copied from among the plurality of operating conditions set in one storage room,
The control unit, when receiving the copy instruction, copies the operating condition selected by the selecting unit. The storage according to claim 1,
The setting unit is capable of receiving a plurality of settings of the operating conditions,
The storage, wherein the control unit, upon receiving the copy instruction, collectively copies all the operating conditions set in one storage room. A plurality of storage rooms for storing storage, each having a functional unit that performs at least one of cooling, heating and humidification of the storage room,
A setting unit that is provided for each of the storage rooms and receives a setting of an operation condition of the storage room;
A component commonly used for the operation of each of the storage rooms, and a component whose operation can be set;
A control unit that operates each of the storage rooms based on the operating conditions of the storage room, and a control unit that operates the storage room using the components.
With
A storage, wherein the operation setting of the component can be set only in one of the plurality of setting units. 5. The storage of claim 4, wherein:
The part is a clock section,
A storage, wherein the operation setting is a time setting of the clock unit. A storage according to claim 4 or claim 5,
The component is a sound generator,
The storage, wherein the operation setting is a sound volume setting of the sound generator.

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