JP2009041854A - Cooker - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cooker equipped with a heating means capable of executing optimum cooking according to the charge amount and convenient for a user. <P>SOLUTION: The cooker includes a heating chamber 4 for storing a heating object, heaters 17, 18, 23a, 23b and a magnetron 11 for heating the heating object, a secondary battery 34 charged by a commercial power source 35 and supplying power to the heaters, a storage means 37 for storing a secondary battery cooking menu for heating by the heaters when power is supplied from the secondary battery 34, and a control part 37 for executing and controlling the secondary battery cooking menu. The storage means 37 stores a plurality of secondary battery cooking menus according to the charge amount of the secondary battery 34. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a cooking device including a secondary battery.

Conventionally, a heating cooker such as an electronic microwave oven has a plurality of heating means such as a magnetron and a heater. While heating the inside of the food with a magnetron, the food surface is baked fragrantly with the heater, and the degree of heating and scorching Cooking is done in a balanced manner. In this case, since power consumption is limited, heating is performed within the power consumption.
For example, if the voltage of the commercial AC power supply is 100 V, the output of the plurality of heating means is controlled so that the current consumption is 15 A or less, which is a standard outlet capacity of a general household, that is, the power consumption is 1500 W or less. Or heating was performed at intervals of operating time. For this reason, there existed a fault that the time which heat cooking requires must be prolonged.

As a technique for solving the above problems, Patent Document 1 discloses a microwave oven configured to supply power from an external power source to either a power converter or a heater unit and to supply power from a storage battery to the other. It is disclosed (see Patent Document 1).
Further, in Patent Document 2, in cooking using a storage battery, the storage battery can always supply the maximum power until the next heating operation by operating the charging circuit when the heating operation is stopped to charge the storage battery. Is provided (see Patent Document 2).
JP-A-6-20773 Japanese Patent Laid-Open No. 4-292892

However, although the technique disclosed in Patent Document 1 employs a storage battery in a microwave oven and performs high-frequency heating, there is no disclosure about how the storage battery is employed for cooking.
In the technique disclosed in Patent Document 2, charging is performed after the heating operation until the maximum power can be supplied to the heating means. According to this, when the user desires cooking using the storage battery again after using the charging capacity of the storage battery, the user has to wait until the battery is charged to the maximum capacity, which is inconvenient. there were.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a highly convenient cooking device that can be performed without waiting for a desired cooking charging time in a cooking device provided with heating means. Is to provide.

  In order to achieve the above object, a heating cooker according to the present invention includes a heating chamber that accommodates an object to be heated, a heating unit that heats the object to be heated, and a commercial power source that supplies power to the heating unit. And a storage means for storing a cooking menu (hereinafter referred to as a secondary battery cooking menu) for heating by a heating means supplied with power from the secondary battery, and executing the secondary battery cooking menu Control means for controlling, and the storage means mainly stores a plurality of secondary battery cooking menus according to the charge amount of the secondary battery.

  According to the heating cooker of the present invention, since it has a plurality of secondary battery cooking menus according to the charging capacity of the secondary battery, optimal cooking can be executed according to the amount of charge, and the maximum capacity Therefore, the user can perform desired cooking without waiting for the charging time in the usage state of the secondary battery.

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a block diagram schematically showing the configuration of the control system of the microwave oven 1, and FIGS. 2 to 4 are diagrams showing the configuration of the microwave oven 1 with an oven function. FIG. FIG. 5 is a diagram showing the charging characteristics of the secondary battery, and FIG. 6 is a diagram showing the discharge rate of the secondary battery. FIG. 7 is a diagram of a display unit showing a charging state of the secondary battery. FIG. 8 is a detailed view of the connection switch. FIG. 9 is a detailed view of the inverter. FIG. 10 is a current operation diagram of the inverter. FIG. 11 is a detailed view of the operation unit, and FIG. 12 is a relative view of the cooking menu and the charge capacity of the secondary battery. FIG. 13 is a diagram showing a display state of each cooking menu. FIG. 14 is a flowchart of a display method. FIG. 15 is an operation diagram of the secondary battery cooking menu.

The main body of the microwave oven 1 is configured by fixing a rectangular inner box 3 in a rectangular outer box 2 having an open front as shown in FIG. The inside of the inner box 3 is a heating chamber 4.
The front opening of the heating chamber 4 is opened and closed by a door 5 that rotates up and down. On the front surface of the door 5, a handle portion 6 is provided at the upper portion, and an operation panel 9 having a plurality of operation portions 7 and a display portion 8 (corresponding to display means) is provided at the lower portion. The operation unit 7 is for setting a cooking menu, cooking time, cooking temperature, cooking chamber temperature (setting temperature), etc. for cooking, and the display unit 8 displays the selected cooking menu, cooking time, and the like. It is for display. In these cooking menus, “gratin”, “pizza”, and the like can be selected, and a cooking method suitable for each food is stored in advance in the control unit 37 (corresponding to storage means).

A machine room 10 located between the outer box 2 and the inner box 3 is formed in the back part of the main body of the microwave oven 1. A magnetron 11, which is a microwave heating means, is formed in the lower part of the machine room 10. In addition, although not shown, a power supply device for the magnetron 11 and a cooling fan device for cooling the magnetron 11 and the power supply device are disposed. The magnetron 11 generates high frequency, and the generated high frequency is supplied into the heating chamber 4 from the excitation port 13 formed at the bottom of the inner box 3 through the waveguide 12 disposed on the lower surface of the inner box 3. It has come to be.
A step portion 14 is formed inside the bottom portion of the inner box 3, and a bottom plate 15 formed of a glass plate or a ceramic plate is placed on the step portion 14. The bottom plate 15 substantially constitutes the bottom surface of the heating chamber 4, and a rotary antenna 16 for reflecting and stirring the high frequency supplied from the excitation port 13 is disposed in a space below the bottom plate 15. ing. In addition, a lower heater 17 (corresponding to a heating means) such as a sheath heater is disposed in a space below the bottom plate 15 so as to surround the rotating antenna 16, and a planar shape is provided above the inner box 3. An upper heater 18 (corresponding to a heating means) such as a heater is disposed. These upper and lower heaters 17 and 18 function as oven cooking heaters which are one of cooking functions.
The lower heater 17 and the upper heater 18 are configured with different rated outputs. The lower heater 17 is set to 1000 W, and the upper heater 18 is set to 1100 W.

On the other hand, a casing 20 of a hot air generator 19 is fixed to the back surface of the inner box 3, and a centrifugal fan 22 driven by a fan motor 21 and a hot air heater 23 (heating means) are installed in the casing 20. Is equivalent).
The hot air heater 23 is configured so that two heaters are provided around the fan 22, and an inner peripheral heater 23 a (heating means) and an outer peripheral heater 23 b (heating) are located at different locations on the inner peripheral side and the outer peripheral side. Means). The two heaters for hot air have different rated outputs. The inner heater 23a is 1300W and the outer heater 23b is 1400W. These inner peripheral heater 23a and outer peripheral heater 23b function as heaters for hot air circulation cooking, which is one of cooking functions.
The rear wall of the inner box 3, which is the rear surface of the heating chamber 4, is formed with an intake port 24 made up of a number of small holes corresponding to the center side of the fan 22, and both the upper and lower sides of the intake port 24. Exhaust ports 25 that are also located in the portion and are similarly formed of a number of small holes are formed.

  In the hot air generator 19, when the fan 22 rotates, the air in the heating chamber 4 is sucked into the casing 20 from the intake port 24, and heated by the hot air heater 23 to be heated from the upper and lower exhaust ports 25 to the heating chamber 4. It is discharged inside. The inside of the heating chamber 4 is heated by such circulation of hot air so that oven cooking is performed. In oven cooking, oven cooking dishes (not shown) can be arranged in two stages in the heating chamber 4, but the same amount of hot air is supplied from the upper and lower vents 25 as described above. By doing so, the food on the oven-cooked dishes placed one above the other can be cooked well together.

The inner box 3 is made of a metal plate such as an iron plate, and includes a rectangular flange plate 26, an upper surface plate 27, a rear surface plate 28, a left side plate 29, a right side plate 30, and a bottom surface plate 31 on the front side. Among them, the upper plate 27 and the rear plate 28 are formed by bending a single plate material into an approximately L shape.
These plates 26 to 31 are joined to each other by welding or the like, and the front flange plate 26 is joined to the outer box 2 by welding or the like.
Of the ridge corners of the upper part of the inner box 3, the ridge corner on the upper rear side, that is, the boundary between the upper plate 27 and the rear plate 28 formed from a single plate is an inclined surface 32 that descends toward the rear side. Is formed. An infrared detection window (not shown) is formed at the center of the inclined surface 32 in the horizontal (left / right) direction, and an infrared sensor (temperature detection means) 33 is disposed as desired in the window.

As shown in FIG. 2, the machine room 10 is charged with a secondary battery 34 made of a lithium ion battery, and the secondary battery 34 is charged from a 100 V commercial (alternating current) power source 35 (see FIG. 1). A charging circuit 36 for performing is arranged. A charging relay 55 is interposed between the commercial power source 35 and the charging circuit 36. When the charging relay 55 is turned on / off by a command from the control unit 37, the supply of the commercial power source 35 to the charging circuit 36 is turned on / off. Is controlled (see FIG. 1).
The secondary battery 34 has a terminal voltage set to about 33 V, for example, and can be fully charged in about 12 minutes as shown in FIG. 5, and 5 C (mA) as shown in FIG. ) Even when discharged, the discharge capacity is not greatly reduced (see, for example, Japanese Patent Application Laid-Open No. 2004-296255).
If a discharge capacity of 1600 mAh is discharged at 20 C, a power supply of 32 A × 33 V = 1056 W can be supplied for 3 minutes.

Here, the configuration of the control system in the microwave oven 1 will be described with reference to FIG.
The control part 37 is comprised with the microcomputer, and the sensor signal output by the infrared sensor 33 and the internal temperature sensor 38 (temperature detection means) (refer FIG. 1) is input, and the opening / closing of the door 5 is detected. A signal from the door opening / closing detection means 90 is input. The control unit 37 is configured such that when the main power supply 83 is turned on by the operation unit 7, the main power switch 56 is turned on and power is supplied to the control unit 37. The display unit 8 is controlled so that the drive of the magnetron 11 and the heaters 17, 18, 23 a, 23 b is controlled based on a plurality of cooking menu programs stored in the internal memory. Yes.

The charge amount detection circuit 39 detects the charging state of the secondary battery 34 performed via the charging circuit 36 from, for example, the terminal voltage of the secondary battery 34 and outputs the detection result to the control unit 37. It has become. And the control part 37 displays the charge condition of the secondary battery 34 on the display part 8 as shown, for example to Fig.7 (a). FIG. 7B shows a change in display state when the remaining capacity of the secondary battery 34 in the charge capacity display portion 8b gradually decreases.
The remaining capacity of the secondary battery 34 of the display unit 8 is displayed on the charge capacity display unit 8b. For example, when the maximum charge capacity is 400 Wh, when only one scale is displayed, it indicates that 80 Wh of charge capacity (20% of the maximum charge capacity) is being charged, and five scales are displayed. When it is, it indicates that the secondary battery 34 is fully charged.
And to the right of the remaining capacity of the secondary battery 34, there is a cooking name display section 8 a that displays the name of the cooking menu that can be cooked according to the remaining capacity of the secondary battery 34 (corresponding to the item of the cooking menu). Above and below, the time required for the cooking menu (end time) and the set temperature in the heating chamber 4 according to the cooking menu are displayed.

Next, the power supply method with each heating means with a secondary battery is demonstrated.
The upper and lower heaters 17 and 18 and the hot air heaters 23a and 23b, which are the heating means, are configured to be connected to the connection switches 51 to 54 as the switching means shown in FIG. 1, and as shown in FIG. By switching the terminals connected to the contacts a, b, and c, different power sources for the commercial power supply 35 (when connected to the contact b) and the secondary battery 34 (when connected to the contact d) are selected. Each heater can select a power supply destination. That is, each heater is configured such that power is supplied from one of different power sources.

Further, an inverter 50 is connected to the magnetron 11, and this inverter 50 is configured as shown in FIG. 9, unlike the connection switches 51 to 54.
The inverter 50 includes a rectifying unit 60, a semiconductor switch 61, an inverter switch 62, a high-frequency transformer 63, and the like. A commercial power source 35 is connected to the rectifying unit 60, and the secondary battery 34 is connected to the inverter switch 62. It is connected.

The inverter 50 configured as described above operates as shown in FIG. 10 when the commercial power source 35 and the secondary battery 34 are used simultaneously.
First, the electric power supplied from the commercial power source 35 is rectified by the rectification unit 60 and controlled by the semiconductor switch 61. At this time, the alternating current supplied from the commercial power source 35 becomes a pulsating flow as shown in FIG.
Subsequently, the electric power supplied from the charged secondary battery 34 is converted into a direct current and supplied to the connection point A from the commercial power source 35 via the inverter switch 62 (see FIG. 10B).
Then, at the connection point A, the power of FIG. 10B is added to the pulsating flow of FIG. 10A, and the power whose output is increased is supplied to the high-frequency transformer 63. Then, the rectified electric power is supplied to the magnetron 11 via the high-frequency transformer 63.
Therefore, this inverter 50 can supply the total power of the commercial power source 35 and the secondary battery 34 to the magnetron 11, unlike the configuration in which any one of the power sources such as the connection switches 51 to 54 is selected.

Here, a display method of the charge amount and cooking menu name on the display unit 8 and an operation method based on the displayed contents will be described.
FIG. 11 is a detailed view of the operation unit 7. The operation unit 7 includes a main power supply 83 for turning on the microwave 1, an automatic cooking menu selection key 82 for selecting a cooking menu displayed on the display unit 8, and an automatic cooking menu selection key 82 for selection. A start key 84 for starting execution of the prepared cooking menu is provided. A manual cooking menu selection key 85 for manually selecting a cooking menu is also provided. A charging key 86 is also provided. By selecting this key, the charging relay 55 is turned on, and the secondary battery 34 is charged from the commercial power source 35 through the charging circuit 36.

A plurality of cooking menus that can be selected from the selection keys 84 and 85 are stored in the control unit 37, and as shown in FIG. Battery cooking menu) and a normal cooking menu “warming” in which power is supplied only from the commercial power source 35 that does not use the secondary battery 34.
The secondary battery cooking menu stores “rapid warm cooking”, “gratin cooking”, “shoe cooking”, “cookie cooking”, “apple pie cooking”, “hamburg cooking”, “pizza cooking”, and the like.
These secondary battery cooking menus are set so that the heating conditions are different, and heating means (magnetron 11, lower heater 17, upper heater 18, hot air heater 23, inner peripheral heater 23a, outer peripheral heater 23b for execution are executed. At least one of the selection time, the usage time of the heating means, or the used electric energy supplied from the secondary battery 34 to the heating means is set to be different.

The heating conditions of the secondary battery cooking menu will be described.
First, “gratin cooking” will be described.
This cooking uses the secondary battery 34 at the time of execution as described above. The necessary amount of electric power (the amount of electric power used) when using the secondary battery 34 is 160 Wh, and the upper heater 1 and 1 kW are controlled to be heated for about 8 minutes.
Subsequently, “puff cooking” is a cooking method of cooking a cream puffed dough, and the secondary battery 34 is used when the cooking is performed. The necessary amount of electric power (the amount of electric power used) when using the secondary battery 34 is 240 Wh, and the lower heater 1 kW is controlled to be heated for about 14 minutes.

  “Pizza cooking” similarly uses the secondary battery 34. The necessary power amount (usage power amount) when using the secondary battery 34 is 400 Wh, and the upper heater 1, 1 kW and the lower heater 1 kW are controlled to be heated for about 11 minutes.

As described above, the secondary battery cooking menu is set such that the heating means to be used, the usage time of the heating means, and the amount of electric power supplied from the secondary battery 34 to the heating means are different.
That is, in the secondary battery cooking menu, the amount of power used for cooking is determined, and when the secondary battery 34 is used, the above-described amount of power (the amount of power used) is the secondary battery 34. If it is not charged, cooking cannot be performed.

Here, in the table of FIG. 12, “○” and “×” are marked for the charge amount of the secondary battery 34 that can be cooked, and the scale of the charge amount of the secondary battery 34 is not less than a predetermined amount. For example, “○” is marked as being ready for cooking.
Based on the table of FIG. 12, the name of the cooking menu corresponding to the “◯” mark in the above table is displayed on the display unit 8 indicating the state of charge as shown in FIG.

  As shown in FIG. 14, the control unit 37 displays the contents displayed on the display unit 8 when the charge detection unit 39 detects the charge capacity of the secondary battery 34 when the power source of the microwave oven 1 is turned on. Deciding.

  That is, when it is detected that the charging capacity is 5 scales as in step S1, the names of the six cooking menus are displayed as in step S1a. The smaller the charge capacity, the fewer names of cooking menus that are displayed.

A specific explanation will be given below.
First, when the state of charge is 2 scales (40%), the display unit 8 displays “gratin” which is a cooking menu that can be executed with the charge capacity of 2 scales (see FIG. 13A).
FIG. 13A is a display screen for this “gratin” cooking. If there is a charge capacity of 2 scales, the interior is set to 300 ° C. and heated, and can be completed in 20 minutes. Indicates that it is feasible.
When the “gratin” cooking is displayed, the “gratin” cooking menu is executed by pressing the start key 84.
In this case, the cooking name display unit 8a displays "Gratin", but when the automatic cooking menu selection key 82 of the operation unit 7 is pressed, the cooking name display unit 8a is charged with two scales. If there is capacity, the cooking menu that can be executed is sequentially displayed.
That is, when the cooking mode “hot” and “rapid hot” are sequentially displayed in the column of the scale 2 in FIG. 12 and the corresponding mode is displayed, the start key 84 is set. By pressing, the cooking menu is executed.

Further, as shown in FIG. 13B, in the case of a charging capacity with a scale of 3 (60% of the maximum capacity), “shoe” cooking corresponding to the charging capacity is displayed.
At this time as well, the display unit 8 shows that the current charge capacity scale is 3, the inside is set to 220 ° C. and heated, and cooking is completed in 28 minutes. It has been shown that “shoe” cooking is feasible.
Then, “cookies” that require the same charging capacity to perform cooking are subsequently displayed. Then, a cooking menu, “gratin”, “rapid warming”, and “hot warming” that can be executed at the scale 3 or lower are displayed in order.

  When the desired cooking menu is displayed as in the case of the charge capacity of the scale 2, the cooking menu is executed by pressing the start key 84.

Similarly, as shown in FIG. 13C, when the scale is 5 and the maximum charging capacity of the secondary battery 34 is charged (charging capacity 400 Wh, 100%), all cooking menus can be executed. It is displayed on the display unit 8.
First, “pizza” cooking that requires 5 charging capacities is displayed.
This display screen shows that the current charge capacity scale is 5, the charge amount is maximum, the interior is set to 300 degrees C and heated, and cooking is finished in 15 minutes. And "pizza" cooking is shown to be feasible.
After this display, “Apple pie”, “hamburger”, “shoe”, “cookie”, “gratin”, “rapid warm”, “warm” are displayed in order, and the user displays the desired cooking menu By pressing the start key 84, the cooking can be executed.

  Thus, one of a plurality of cooking menus is displayed on the display unit 8, and the user presses the automatic cooking menu selection key 82 to display another executable cooking menu, and the desired cooking menu is displayed. Is displayed on the display unit 8, the cooking menu can be executed by pressing the start key 84.

Here, the operation of the secondary battery cooking menu will be described with reference to FIG.
First, the “gratin” cooking operation corresponding to FIG. 13A will be described with reference to FIG.
FIG. 15A is a timing chart showing the internal temperature change when the “gratin” cooking menu is selected.
First, when the “gratin” is displayed on the display unit 8 and the start button is pressed, the “gratin cooking menu” stored in the control unit 37 is started.
When the user starts cooking, as shown in FIG. 15 (a), the control unit 37 selects the inner peripheral heater 23b on the back surface from among the plurality of heating means from the start of heating cooking, and commercial power Power is supplied from 35.
When the internal temperature reaches the cooking set temperature (300 degrees C), the inner peripheral heater 23a (1300W) connected to the commercial power source 35 is intermittently maintained to maintain the set temperature.

And 12 minutes after cooking is started (8 minutes before cooking is finished), the connection switch 51 of the upper heater 18 is switched from the contact a to the contact c. Then, the upper heater 18 is connected to the secondary battery 34, and power is supplied to the upper heater 18 from the secondary battery 34.
And cooking is complete | finished after heating above preset temperature only for predetermined time (8 minutes). In this case, the commercial power supply 35 is intermittently supplied to the inner peripheral heater, and the power supply from the commercial power supply 35 and the secondary battery 34 is simultaneously performed.
For example, when cooking a gratin or the like, it is preferable to finish so that the surface portion of the dish is slightly burnt. Therefore, if it controls like this gratin cooking, a heating output can be temporarily raised immediately before completion | finish of cooking, and the surface part of foodstuffs can be burnt.
Thus, during heating, the upper heater 18 (rated output 1100 W), which is located at a different location from the inner heater 23 a (rated output 1300 W) and has a different rated output, is switched by the connection switch and connected to the secondary battery 34. Thus, the inner heater 23a and the upper heater 18 can be used at the same time using power consumption of 1500 W or more, and cooking suitable for the cooking menu of the “gratin” menu can be performed.

  Therefore, in this way, according to each cooking menu, such as an operation of making the heating means of the place (upper heater 18) suitable for the cooked food with high output by the secondary battery 34 and coloring the “gratin menu”, By determining the heating means connected to the commercial power source 35 or the secondary battery 34, cooking suitable for cooking menus (cooking items) using a heating output exceeding the rated power consumption of the microwave oven 1 can be performed. it can.

FIG. 13B is a timing chart showing a change in the internal temperature when the “shoe” cooking menu is selected.
When the user starts cooking, the control unit 37 preheats the heating chamber 4 by connecting the inner heater 23a to the commercial power source 35 and energizing it. When the internal temperature reaches the set temperature of “shoe” cooking 220 ° C., the control unit 37 displays on the display unit 8 that the preheating process has been completed.

Then, the user opens the door 5 to store the cream dough in the heating chamber 4 and closes the door 5 again to start cooking. At this time, the inside temperature rapidly decreases. Therefore, in this shoe cooking, when the door opening / closing detection means 90 detects that the door 5 is closed, the lower heater 23 (1 kW) is also energized at the same time so as to receive power supply from the secondary battery 34, and the lowered interior Raise temperature.
In this case, even if the rated power consumption of the microwave oven 1 is 1500 W, for example, the secondary battery 34 can be used together to perform heating with a higher output. Then, the lower heater 17 is energized for 14 minutes until the internal temperature reaches the set temperature again, and then the inner peripheral heater 23a is energized intermittently to perform cooking by maintaining the internal temperature constant.
In this way, the shoe dough is accommodated, and the secondary battery 34 is energized to the lower heater 17 at a lower temperature in the initial stage where the dough is heated and swells. Moisture evaporation is promoted, and the swelling of the dough due to the water vapor can be improved.

FIG. 15C is a timing chart showing a change in the internal temperature when the “pizza” cooking menu is selected.
In this case, the cooking is started from a state in which the internal temperature is substantially the same as the room temperature, and food is stored in the heating chamber 4 and the heat capacity is large. Therefore, as shown in FIG. 15C, the control unit 37 connects the inner heater 23 to the commercial power source 35 from the start of cooking, and the upper heater 17 (1.1 kW) and the lower heater 18 (1 kW). Are connected to a secondary power source and simultaneously energized for heating operation.
When the internal temperature reaches the pizza set temperature (300 ° C.), the internal temperature is maintained constant by energizing the hot air heater 23 and the upper and lower heaters 17 and 18 intermittently. .

When cooking pizza in this way, the upper and lower heaters 17 and 18 are connected by supplying power from the secondary power source, and the pizza can be cooked from the top and bottom at the same time. Can do.
Moreover, since the hot air heater 23 that receives power supply from the secondary battery 34 is operated simultaneously with the upper and lower heaters 17 and 18 from the start of cooking, the cooking time is shortened and the surface portion of the food is prevented from drying, The finished state of cooking can be improved.
In this case, power is simultaneously supplied to the upper and lower heaters 17 and 18 from the secondary power source, and the secondary battery capacity ends when the power supply time has elapsed for 11 minutes.

  Thus, according to the present embodiment, the heating chamber 4 that accommodates the object to be heated, each heater or magnetron 11 that heats the object to be heated, and the commercial power supply 35 are charged, and the electric power is supplied to the heater and the like. A secondary battery 34 to be supplied, a control unit 37 that stores a cooking menu, and a control unit 37 that executes and controls the cooking menu are provided. The control unit 37 has a plurality of charge levels according to the charge amount of the secondary battery 34. Since the secondary battery cooking menu is stored, the user can execute an optimum cooking menu according to the amount of charge of the secondary battery 34.

For example, since the cooking menu suitable for the low charge state can be executed even when the charge amount of the secondary battery is not 100% and lower than that, the user does not need to be heated based on a large amount of charge. As for an object, desired cooking can be performed on the object to be heated without waiting for the secondary battery 34 to be fully charged.
That is, since cooking can be performed without requiring the maximum capacity, the user can perform desired cooking without waiting for the charging time of the secondary battery 34 in the usage state of the secondary battery 34. it can.

  In addition, the display unit 8 that displays the name of the cooking menu that is an item of the secondary battery cooking menu is provided, and the amount of charge of the secondary battery 34 is larger than the predetermined amount of charge necessary for executing the secondary battery cooking menu. In addition, since the secondary battery cooking menu item is displayed on the display means, the user can grasp the cooking that can be used at present at a glance, which is highly convenient for the user. .

  In addition, the control unit 37 selects a heating unit (heater) for heating, uses the heating unit (energization time), or secondary so that the heating condition varies depending on the charge amount of the secondary battery 34. A plurality of secondary battery cooking menus are stored in such a manner that at least one of the amounts of power used supplied from the battery 34 to the heating means is different, and a heater in a place suitable for the cooking is used, or the cooking By preparing a cooking menu suitable for various purposes by changing the time to color the grill and changing the timing, the user can select more suitable cooking.

(Second embodiment)
Next, a second embodiment of the cooking device according to the present invention will be described with reference to FIGS.

FIG. 16 is a flow chart of the simulated secondary battery cooking menu when the manual cooking selection key is pressed. FIG. 17 is an operation diagram of the simulated secondary battery cooking menu.
The same parts as those of the first embodiment are denoted by the same reference numerals, description thereof is omitted, and different points will be described below.
That is, the difference from the first embodiment is the control method of the secondary battery cooking menu, which is applicable even when the charge amount necessary for executing the secondary battery cooking menu is not satisfied. It is the point which enables it to perform the heating cooking according to a secondary battery cooking menu.

The operation unit 7 has a manual cooking menu selection key 85, and the user selects the manual cooking menu selection key 85, thereby cooking with high thermal power using the secondary battery 34. The menu can be executed.
When the user presses the manual cooking menu selection key 85, the name of the cooking menu stored in the control unit 37 is displayed on the display unit 8.
That is, “rapid warming”, “gratin”, “shoe”, “apple pie”, “pizza” and the like shown in FIG. 12 are displayed at any time by pressing the manual cooking menu selection key 85.

In this operation, unlike the first embodiment, the secondary battery cooking menu is displayed even if the battery capacity of the secondary battery 34 does not have the amount of charge required for the secondary battery cooking menu.
When the manual cooking menu selection key 85 is selected and the start key 84 is pressed, the displayed cooking is executed.
Although details will be described later, in this operation, if the cooking of the selected display item has a charging capacity necessary for the secondary battery cooking menu, the heating control of the secondary battery cooking menu is performed. On the other hand, if the cooking menu of the selected display item does not have the charge capacity necessary for the secondary battery cooking menu, the heating method is adjusted so that the finish is equivalent to the secondary battery cooking menu. The changed heating control is performed (hereinafter referred to as a simulated secondary battery cooking menu).

Here, an example of the simulated secondary battery cooking menu will be described with reference to FIGS.
FIG. 16 is a flowchart when the user performs cooking when the item “pizza” is displayed. FIG. 17 is a timing chart showing a change in the internal temperature of “pizza” cooking in the simulated secondary battery cooking menu.
First, the user presses the manual cooking menu selection key 85, and when the “pizza” item is displayed, the user presses the start key 84 to select “pizza” cooking in the simulated secondary battery cooking menu (T1, T2). T2).
At this time, the charge amount detection circuit 39 of the control unit 37 detects the capacity of the secondary battery 34 and determines whether it has the charge amount (100%) necessary for “pizza” cooking in the secondary battery cooking menu. To do.

When the secondary battery capacity is 100% (yes in T4), the secondary battery cooking menu shown in FIG. 15C of the first embodiment, which is “pizza” cooking of the secondary battery cooking menu, is displayed. The heating control for “pizza” cooking is performed (T5).
In this heating control, the energization time, which is the time for supplying power from the commercial power source 35 to the inner peripheral heater 23b, is set in advance as 11 minutes, and after the internal temperature reaches the set temperature, the inner peripheral heater is interrupted intermittently. It is programmed to energize 23b.
In addition, the power supply time from the secondary battery 34 to the upper and lower heaters 17 and 18 is set in advance to energize for a total of 11 minutes from the start of cooking to the end of cooking, and after the internal temperature reaches the set temperature, It is programmed to intermittently energize the inner peripheral heater 23b.
At this time, the scale of the charge capacity is displayed as 5 on the display unit 8, and the cooking end time is displayed as 15 minutes (see FIG. 3C).

On the other hand, for example, when the secondary battery capacity detected by the charge amount detection circuit 39 is 40% and the charge capacity scale 2 is displayed on the display unit 8, the secondary battery capacity is less than 100%. Therefore, since the secondary battery cooking menu of “pizza” cannot be executed, the user is notified on the display section 8 “Do you want to charge?” (T6).
At this time, when the user operates the charging key 86 of the operation unit 7 (T9), charging starts (T8). After the charging, when the charging capacity exceeds 100%, the charging detecting means detects it and the “pizza” secondary battery cooking menu is started (T4yes, T5).

If the user does not operate the charging key 86 within a predetermined time, the control unit 37 is different from the heating method of the “pizza” secondary battery cooking menu, but changes to the heating condition according to the heating method and simulates it. A secondary battery cooking menu (referred to as a simulated secondary battery cooking menu) is performed (T10).
At this time, the cooking end time is displayed as 20 minutes on the display unit 8, indicating that the cooking time is longer than the time of “pizza” cooking (15 minutes) in the secondary battery cooking menu, and the cooking name “Pseudo pizza” is displayed on the display unit 8a, and the user is informed so that the user can recognize that cooking is different from “pizza” cooking, which is a normal secondary battery cooking menu, and the cooking time is long. .

Next, a simulated secondary battery cooking menu operation of “pizza” cooking in the high-heat cooking menu will be described with reference to FIG.
In this case, the cooking is started from a state in which the internal temperature is substantially the same as the room temperature, and food is stored in the heating chamber 4 and the heat capacity is large. Therefore, the controller 37 connects the hot-air heater 23 to the commercial power source 35 and connects the upper and lower heaters 17 and 18 to the secondary battery 34 from the start of cooking, thereby energizing and heating them simultaneously.
At this time, the capacity of the secondary battery 34 is all used immediately after the start, which is a process of rapidly increasing the internal temperature.

Then, before the internal temperature reaches the pizza set temperature (300 ° C.), when the upper and lower heaters are powered for 4.4 minutes, the capacity of the secondary battery 34 is lost, and thereafter, the inner peripheral heater 23a using the commercial power source 35 is used. Use to increase the internal temperature.
Therefore, the time for detecting that the internal temperature sensor 38 reaches the set temperature is longer than the pizza cooking (see FIG. 15C) of the secondary battery cooking menu.
When the internal temperature reaches the set temperature of the pizza (300 degrees C), only the hot air heater 23 is energized intermittently to maintain the internal temperature to be constant and energize for a total of 15 minutes. Cooking ends.

The heating control for cooking the “simulated pizza” is preset so that the power supply time from the secondary battery 34 to the upper and lower heaters 17 and 18 in the “pizza” cooking is energized for a total of 11 minutes from the start of cooking to the end of cooking. In contrast to this, the energization time, which is the charge capacity of the secondary battery 34, is changed to 4.4 minutes to shorten the energization time compared to “pizza” cooking.
Then, in the “pizza” cooking, the energization time, which is the time for supplying the electric power from the commercial power source 35 to the inner peripheral heater 23b, is set to 11 minutes, and is changed to 15 minutes, compared with “pizza” cooking. Energizing time is extended. Further, after reaching the set temperature, energization is performed intermittently in order to keep the temperature of the heating chamber 4 constant.
Therefore, since “simulated pizza” cooking as described above changes the heating operation so as to approach the finish of “pizza” cooking, the cooking end time (20 minutes) of “simulated pizza” is “pizza” cooking (15 minutes). ) Longer than

  As described above, according to the cooking method of “simulated pizza” in FIG. 17, the end time is longer than that in the secondary battery cooking menu, but the user does not wait for the time for the secondary battery 34 to be charged. Because it is possible to obtain the effect of using the secondary battery 34 that simultaneously heats the pizza from the top and bottom of the pizza at the beginning of cooking to make both the front and back fragrant, a finished pizza equivalent to “pizza” cooking is provided and used Convenient for the user.

  When the battery capacity at the start of cooking is further small (for example, 20%), the energizable time of the upper and lower heaters 17 and 18 is further shortened, so the power supply time from the secondary battery 34 to the upper and lower heaters 17 and 18 is shortened. Then, the power supply time from the commercial power source 35 to the hot air heater is set to be longer.

Thus, the inner peripheral heater 23a (corresponding to the first heating means) supplied with power from the commercial power source 35 and the upper and lower heaters (corresponding to the second heating means) supplied with power from the secondary battery 34 are provided. Regarding the secondary battery cooking menu to be heated in combination, the power supply time (11 minutes) from the commercial power source 35 to the hot air heater and the power supply time (11 minutes) from the secondary battery 34 to the upper and lower heaters are preliminarily set. The microwave oven 1 is configured so that the set “pizza” cooking (corresponding to the secondary battery cooking menu) can be executed, and the control unit 37 sets the secondary battery capacity to “pizza” cooking in the secondary battery cooking menu. When the required capacity is not satisfied, it is detected and the power supply time from the secondary battery 34 to the upper and lower heaters is shortened to 4.4 minutes, and the first heating means from the commercial power source 35 is supplied. Extends the power supply time to 15 minutes Was to be able to perform a simulated secondary battery cooking menu was changed to so that.
Accordingly, since the high-capacity cooking can be performed using the current charging capacity, the user can execute a desired cooking menu without waiting for the charging time of the secondary battery 34 to increase. It is convenient and convenient.
Also, other cooking display items (for example, gratin) can be cooked using the secondary battery 34 as long as the secondary battery capacity is small.

(Third embodiment)
Next, a third embodiment of the heating cooker according to the present invention will be described with reference to FIG.
FIG. 18 is a timing chart showing the internal temperature change of “pizza” cooking in the simulated secondary battery cooking menu, and is equivalent to FIG.
The difference from the second embodiment is a control method of “pizza” cooking in the simulated secondary battery cooking menu.

First, when a simulated secondary battery cooking menu is selected (T10), the control unit 37 displays a cooking end time of 20 minutes on the display unit 8, and the “pizza” cooking menu of the secondary battery cooking menu is displayed. It indicates that the cooking time is longer than the time (15 minutes) and notifies the user (see FIG. 16).
Then, “simulated pizza” cooking is started.
First, from the start of cooking, the control unit 37 connects the hot air heater 23 to the commercial power source 35 and connects the upper and lower heaters 17 and 18 to the secondary battery 34 to simultaneously energize and perform the heating operation.
The capacity charged in the secondary battery 34 is consumed by continuously energizing for 4.4 minutes, and then the hot air heater 23 is continuously energized to raise the internal temperature.

When the internal temperature reaches the pizza set temperature (300 ° C.), the control unit 37 is energized from the commercial power source 35 to the upper heater 17 which is a heating means to which power has been supplied from the secondary battery 34 until then. Thus, the connection is switched on by the connection switch 51. At this time, the hot air heater 23 exceeds the power consumption of 1500 W, and is thus disconnected from the commercial power source 35 by the connection switch 54.
Subsequently, the upper heater 17 is disconnected and the lower heater 18 is energized so that the lower heater 18, which is a heating unit supplied with power from the secondary power source 34, is energized from the commercial power source 35. Switch.
Then, after energizing the upper and lower heaters 17, 18, the connection to the hot air heater 23 is returned to energize.
Thus, the heaters 17, 18, and 23 a connected to the commercial power source 35 are switched every predetermined time and controlled to repeat, and cooking ends when 20 minutes have elapsed after the start of heating.

Accordingly, the upper and lower heaters 17 and 18 are controlled so that the power supply destination is switched so that the secondary battery 34 is energized for 4.4 minutes immediately after the start, and then the commercial power source 35 is intermittently energized.
The power supply time from the commercial power supply 35 to the upper and lower heaters 17 and 18 is 3.6 minutes. By controlling the power supply time to be changed, the upper and lower heaters 17 and 18 are energized during cooking. The time required for the charging is changed so that the total supply time from the secondary battery 34 and the commercial power source 35 is energized for 8 minutes.
Therefore, in the “simulated pizza” cooking in the third embodiment as described above, the heating operation is changed in order to approximate the finish of “pizza” cooking, so the cooking end time (20 minutes) of “simulated pizza” is “ It will be longer than “pizza” cooking (15 minutes).

As described above, according to the cooking method of “simulated pizza” in FIG. 18, the end time is longer than that in the secondary battery cooking menu, but the user does not wait for the time for the secondary battery 34 to be charged. A finished pizza according to “pizza” cooking is provided, which is convenient for the user.
In particular, unlike the second embodiment, the operation necessary for pizza cooking in which the front and back surfaces of the pizza are scented by heating from above and below is controlled not only at the beginning but also after reaching the set temperature. Therefore, a finished pizza that is closer to “pizza” cooking can be provided.

That is, the heating means energized from the secondary battery 34 set in advance as part of the cooking menu operation is necessary for finishing the object to be heated as the cooking menu operation. In the case where there is little, the control is made different as a simulated secondary battery cooking menu so that the commercial power source 35 is connected and can be energized as an alternative means.
According to this, although the control method is different depending on the object to be heated by the secondary battery cooking menu, such as heating from the top and bottom directions or heating by microwaves, the charging capacity is small. Even if it cannot heat based on the secondary battery 34, since the said heating means can be energized with the commercial power source 35, the simulation secondary battery cooking menu more suitable for a to-be-heated material can be performed.

  As described above, according to the third embodiment, the inner heater 23a (first heating means) and the upper and lower heaters 17 and 18 (second heating means) are connected to either the commercial power source 35 or the secondary battery 34. The controller 37 is configured to be connectable, and when the control unit 37 selects the simulated secondary battery cooking menu, the power supply time from the secondary battery 34 to the upper and lower heaters 17 and 18 is shortened from 11 minutes to 4.4 minutes, In the time zone when the secondary battery 34 is not energized to the upper and lower heaters 17 and 18, the connection of the commercial power source 35 is switched from the inner peripheral heater 23 a to either the upper or lower heater 17 or 18 to supply power. The user can provide a finished pizza according to the “pizza” cooking without waiting for the secondary battery 34 to be charged.

  In the above embodiment, the secondary battery cooking menu in which the executable charge capacity is charged in the secondary battery 34 is sequentially displayed on the display unit 8, but this is not displayed in order. Alternatively, a configuration may be adopted in which all corresponding secondary battery cooking menus are displayed and one item can be selected.

  Moreover, the item of a secondary battery cooking menu should just be the content which points out the secondary battery cooking menu, such as the name of a secondary battery cooking menu, the abbreviated name.

  In the present embodiment, the power supply time of the commercial power supply 35 designates the time during which the heating means is energized from the start of heating to the end of heating in the present embodiment. For example, FIG. In cooking such as (c), the power supply time of the commercial power source 35 may be designated as the time when the commercial power source 35 is energized after the temperature of the heating chamber 4 reaches the set temperature.

  In this embodiment, the voltage of the commercial AC power supply is 100 V, the standard outlet capacity is 15 A, and the secondary power is output in an environment where the output must be controlled so that the power consumption is 1500 W or less (maximum power). Although the operation method of the battery has been described, even in an area where the voltage is 100 V or more (for example, 150 V) or the like, electric power that is greater than the maximum power in the area can be supplied by the secondary battery.

  The present invention is not limited to the embodiments described above and shown in the drawings, but can be modified or expanded.

The block diagram which is 1st Example of this invention and shows schematically the structure of the control system of a microwave oven Longitudinal side view of microwave oven Front view with the door open Front view with the door closed Diagram showing charging characteristics of secondary battery Diagram showing discharge rate of secondary battery (A) is the state which displayed the charge condition of the secondary battery on the display part, (b) is a figure which shows the change of a display state corresponding to the case where the remaining capacity of a secondary battery reduces gradually. Detailed view of the connection switch. Detailed view of the inverter. The current operation figure of an inverter. Detailed view of the operation unit. The relative figure of a cooking menu and the required charging capacity of a secondary battery. The figure which shows the display state of each cooking menu. The flowchart of each cooking menu display method. (A) (b) (c) Operation | movement figure of each secondary battery cooking menu. The flowchart of the simulation secondary battery cooking menu which is 2nd Example of this invention. The timing chart which shows the internal temperature change of "simulated pizza" cooking. FIG. 17 is a diagram corresponding to FIG. 17 of the third embodiment.

Explanation of symbols

  In the drawings, 1 is a microwave oven, 2 is an outer box, 3 is an inner box, 4 is a heating chamber, 5 is a door, 6 is a handle portion, 7 is an operation portion, 8 is a display portion (display means), and 8a is a cooking name. Display unit, 8b is a charge capacity display unit, 9 is an operation panel, 10 is a machine room, 11 is a magnetron (heating means), 12 is a waveguide, 13 is an excitation port, 14 is a step, 15 is a bottom plate, 16 is Rotating antenna, 17 is a lower heater (heating means), 18 is an upper heater (heating means), 19 is a hot air generator, 20 is a casing, 21 is a fan motor, 22 is a fan, 23 is a heater for hot air (heating means), 23a is an inner peripheral heater (heating means), 23b is an outer peripheral heater (heating means), 24 is an air inlet, 25 is an air outlet, 26 is a flange plate, 27 is an upper surface plate, 28 is a rear surface plate, 29 is a left side plate, 30 Is a right side plate, 31 is a bottom plate, 32 is an inclined surface, 33 is an infrared sensor ( Degree detection means), 34 is a secondary battery, 35 is a commercial power supply, 36 is a charging circuit, 37 is a control unit (storage means, control means), 38 is an internal temperature sensor (temperature detection means), and 39 is a charge amount detection. Circuit, 50 is an inverter, 51 to 54 are connection switches, 55 is a charging relay, 56 is a main power switch, 60 is a rectifier unit, 61 is a semiconductor switch, 62 is an inverter switch, 63 is a high frequency transformer, 82 is an automatic cooking menu selection 83, a main power source, 84, a start key, 85, a manual cooking menu selection key, 86, a charge key, and 90, a door open / close detection means.

Claims (7)

A heating chamber for storing an object to be heated;
Heating means for heating an object to be heated;
A secondary battery that is charged by a commercial power source and supplies power to the heating means;
Storage means for storing a cooking menu (hereinafter referred to as a secondary battery cooking menu) for heating by heating means to which power is supplied from the secondary battery;
Control means for controlling execution of the secondary battery cooking menu,
The storage device stores a plurality of secondary battery cooking menus according to the amount of charge of the secondary battery. Charge amount detection means for detecting the state of charge amount of the secondary battery;
Display means for displaying items of the secondary battery cooking menu,
The control means displays the item of the secondary battery cooking menu when the charge quantity detected by the charge quantity detection means is larger than a predetermined charge quantity required for executing the secondary battery cooking menu. The cooking device according to claim 1, wherein the cooking device is displayed on the means.   The cooking device according to claim 1 or 2, wherein the storage means has a secondary battery cooking menu with different heating conditions according to the charge amount of the secondary battery.   The storage means has a secondary battery cooking menu in which at least one of the selection of the heating means for heating, the usage time of the heating means, or the amount of electric power supplied from the secondary battery to the heating means is different. The cooking device according to any one of claims 1 to 3, characterized in that: Charge amount detection means for detecting the state of charge amount of the secondary battery;
Selecting means for selecting a secondary battery cooking menu,
The storage unit performs a heating operation using a first heating unit to which power is supplied from a commercial power source and a second heating unit to which power is supplied from a secondary battery. The power supply time to the heating means, and the power supply time from the secondary battery to the second heating means has a commercial power combined secondary battery cooking menu,
The control means
The selection means selects the commercial battery combined use secondary battery cooking menu,
When the charge amount of the secondary battery detected by the charge detection means is less than the amount necessary for executing the commercial battery combined use secondary battery cooking menu,
The cooking device according to claim 1, wherein the power supply time from the secondary battery to the second heating unit is shortened and the power supply time from the commercial power source to the heating unit is changed. The control means
The selection means selects the commercial battery combined use secondary battery cooking menu,
When the charge amount of the secondary battery detected by the charge detection means is less than the amount necessary for executing the commercial battery combined use secondary battery cooking menu,
6. The cooking device according to claim 5, wherein the time for supplying power from the secondary battery to the second heating means is shortened, and the time for supplying power from the commercial power source to the first heating means is extended. The first heating means and the second heating means are configured to be connectable to either a commercial power source or a secondary battery,
The control means
The selection means selects the commercial battery combined use secondary battery cooking menu,
When the charge amount of the secondary battery detected by the charge detection means is less than the amount necessary for executing the commercial battery combined use secondary battery cooking menu,
Reducing the power supply time from the secondary battery to the second heating means;
The cooking device according to claim 5, wherein when the electric power is not supplied from the secondary battery to the second heating unit, electric power is supplied from the commercial power source to the second heating unit.