JP2015019827A - Heating cooking device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heating cooking device capable of excellently heating a cooked object inside a cooking container.SOLUTION: A heating cooking device can perform DO (Dutch Oven) cooking using a Dutch Oven in a grill chamber 20. In addition to heat quantity required for heating of a cooked object, heat quantity required to heat a deep pot 101 itself influences the DO cooking. Therefore, in the grill chamber 20, initial heating making a lower fire burner and an upper fire burner burn for a time T1 required for the heating of the deep pot 101 itself is performed after igniting both the burners and starting combustion. Thus, even if a heat capacity of the deep pot 101 is large, the heating cooking device can sufficiently heat the deep pot 101 itself. After the initial heating, each of the combustion operations of the lower fire burner and the upper fire burner is controlled in a combustion mode corresponding to a set time P set in an operation panel for grilling. Consequently, the cooked object inside the deep pot 101 can be sufficiently heated without becoming underdone.

Description

  The present invention relates to a cooking device.

  2. Description of the Related Art Conventionally, there is known a cooking device that can perform cooking in a grill using a cooking container such as a Dutch oven. When performing cooking by heating, a cooking container containing an object to be cooked is stored in a grill, and the upper and lower burners are ignited and burned. Then, the cooking in the cooking container proceeds by being heated from above and below by the upper fire burner and the lower fire burner. However, when the upper fire burner and the lower fire burner continue to burn, the upper temperature in the heating chamber rises higher than the lower temperature. As a result, the temperature becomes uneven at the upper and lower parts of the cooking container, and when the food to be cooked accommodated in the cooking container is a baked product such as bread or cake, the baked product cannot be baked well. There was a point.

  Therefore, an initial heating time shorter than the cooking time is calculated based on the cooking time set manually, and after the initial heating time has elapsed after the ignition means is activated and the upper and lower burners burn, There has been proposed a gas cooker that extinguishes only the fire burner and then burns only the lower fire burner with low heating power until the timer counts the input cooking time (for example, see Patent Document 1).

JP 2009-142314 A

  However, in the gas cooker described in Patent Document 1, a time corresponding to a predetermined ratio (for example, 50%) of the cooking time set by the user is calculated, and the time is simply used as the initial heating time as it is. Depending on the length of cooking time, the initial heating time may be shortened. Thereby, the upper fire burner may be extinguished while the cooking container is not sufficiently heated, and there is a problem that bread, pancakes and the like cannot be burned well.

  The objective of this invention is providing the heating cooker which can heat the to-be-cooked item in a cooking container favorably.

  A heating cooker according to a first aspect of the present invention includes a heating chamber capable of storing a cooking container for storing an object to be cooked, an upper fire burner provided on the upper side of the heating chamber, and a bottom of the heating chamber. The setting which sets the heating time which heats the said cooking container accommodated in the said heating chamber and cooks the said to-be-cooked food using the lower-fire burner provided in the side, the said upper-fire burner, and the said lower-fire burner Means for determining the combustion mode of the upper fire burner and the lower fire burner based on the heating time set by the setting means, and ignition for igniting the upper fire burner and the lower fire burner Means, initial heating means for burning the upper fire burner and the lower fire burner ignited by the ignition means for a time required for heating the cooking vessel itself, and the upper fire burner and the lower fire burner by the initial heating means. fire And a combustion control means for controlling the combustion operation of the upper fire burner and the lower fire burner based on the combustion mode determined by the combustion mode determination unit after the burner is burned. .

  In addition, in the cooking device of the invention according to claim 2, in addition to the configuration of the invention of claim 1, according to a plurality of patterns of the heating time set by the setting means, the upper fire burner and the Storage means for storing combustion control information, which is information in which the respective heating power and combustion time of the lower fire burner are associated, and the combustion mode determination means is based on the combustion control information stored in the storage means, The heating power and the combustion time of each of the upper fire burner and the lower fire burner corresponding to the heating time set by the setting means are determined, and the combustion control means is determined by the combustion mode determining means The combustion operation of the upper fire burner and the lower fire burner is controlled based on the heating power and the combustion time.

  Moreover, in the heating cooker of the invention which concerns on Claim 3, in addition to the structure of the invention of Claim 2, the said combustion control information is based on the said several pattern of the said heating time, and the said upper-fire burner and the said A first both-fire combustion time for burning both the lower-burner burner with a strong heating power and a second both-fire burning time for burning both the upper-burner burner and the lower-burning burner with a weak heating power, and the combustion mode determining means includes And determining the first both-fire combustion time and the second both-fire combustion time corresponding to the heating time set by the setting means based on the combustion control information, and the combustion control means The upper fire burner and the lower fire burner are both burned with high heating power during the first both-fire combustion time determined by the determining means, and then the second both-fire combustion determined by the combustion mode determining means. For hours Serial on flame burners and both the burning down burner, characterized in that burning over low heat power.

  Moreover, in the heating cooker of the invention which concerns on Claim 4, in addition to the structure of the invention of Claim 3, the said combustion control information extinguishes the said upper fire burner according to the said several pattern of the said heating time. The combustion mode determining means further includes a single-flame combustion time for burning only the lower flame burner, and the combustion mode determining means is based on the combustion control information and corresponds to the first double fire corresponding to the heating time set by the setting means. A combustion time, the second double-fire combustion time, and the one-fire combustion time are determined, and the combustion control means is configured to perform the upper fire burner during the first double-fire combustion time determined by the combustion mode determination means. And both the lower fire burner and the lower fire burner are both burned with low thermal power during the second both-fire combustion time determined by the combustion mode determining means. And even that And extinguishing the on flame burners, between the pieces fire burning time determined by the combustion mode determining means, characterized in that the combustion of only the burning down burner on low heat power.

  Moreover, in the heating cooker of the invention which concerns on Claim 5, in addition to the structure of the invention in any one of Claim 2 to 4, the said memory | storage means respond | corresponds to the kind of the said cooking container accommodated in the said heating chamber. A plurality of the combustion control information is stored, and the combustion mode determining means is configured to determine the heating power and the combustion of the upper fire burner and the lower fire burner based on the combustion control information corresponding to the type of the cooking container. It is characterized by determining time.

  In the cooking device according to the first aspect of the present invention, the cooking by the cooking container is affected by the amount of heat required to heat the cooking container itself in addition to the amount of heat required for heating the cooking object. In the present invention, since the initial heating is performed after ignition and the start of combustion, the cooking container itself can be sufficiently heated even when the heat capacity of the cooking container is large. And after initial heating, since each combustion operation of an upper fire burner and a lower fire burner is controlled by the combustion mode corresponding to the setting time set up by the setting means, the to-be-cooked object in a cooking vessel becomes raw-burned It is possible to heat sufficiently.

  In addition, in the cooking device of the invention according to claim 2, in addition to the effect of the invention of claim 1, in accordance with the heating time set by the setting means, the heating power and the combustion time of the upper fire burner and the lower fire burner Therefore, cooking can be performed with heating power and combustion time appropriate for the heating time. In addition, with respect to the combustion control information stored in the storage means, specific cooking power and combustion time are associated with each other according to a plurality of patterns of heating time, thereby appropriately performing cooking corresponding to actual cooking. Can do.

  Moreover, in the heating cooker of the invention which concerns on Claim 3, in addition to the effect of the invention of Claim 2, according to the several pattern of heating time, 1st both-flame combustion time and 2nd both-fire combustion time are set. Since the combustion control information is set in advance, the upper fire burner and the lower fire burner can be burned in a combustion mode suitable for the heating time set by the setting means. In addition, after the initial heating, both the upper and lower fire burners can be burned with high heating power to efficiently heat the food to be cooked in a short time, and then both burners should be set to low heating power. Thus, it is possible to prevent the object to be cooked in the cooking container from being overheated and scorching.

  In addition, in the cooking device of the invention according to claim 4, in addition to the effect of the invention according to claim 3, the combustion control means burns the upper fire burner and the lower fire burner with both fires, so that the high-temperature air Moves to the upper side in the heating chamber. Then, the temperature in the heating chamber is made uniform by extinguishing the upper fire burner and burning only the lower fire burner. Therefore, the cooking device can heat the cooking object in the cooking container satisfactorily and uniformly. Also, when the upper fire burner and lower fire burner are burned and the temperature in the heating chamber rises to a temperature suitable for cooking, the upper fire burner is extinguished and heated only by the lower fire burner. Consumption can be saved.

  In addition, in the cooking device of the invention according to claim 5, in addition to the effect of the invention according to any one of claims 2 to 4, each of the combustion control information corresponds to the type of cooking container accommodated in the heating cabinet. Since it is correspondingly stored in the storage means, the initial heating time can be appropriately determined regardless of the type of cooking container.

1 is a perspective view of a stove 1. FIG. It is a perspective view of grill warehouse 20 (household deep pan 101) which removed the upper cover. It is a cross-sectional view of the grill cabinet 20 containing the deep pot 101. It is a cross-sectional view of the grill warehouse 20 which accommodated the shallow pot 102. 3 is a schematic view of a gas supply structure of a lower fire burner 25 and an upper fire burner 26. FIG. It is a block diagram which shows the electric constitution of the stove. It is a conceptual diagram of DO cooking table 741. It is a graph which shows the experimental result for time T1 determination. It is a flowchart of DO cooking processing. 10 is a flowchart showing a continuation of FIG. 9.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In FIG. 1, diagonally downward left, diagonally upward right, diagonally downward right, and diagonally upward left are defined as the front, rear, right, and left of the stove 1, respectively. In FIG. 2, left diagonally downward, right diagonally upward, right diagonally downward and left diagonally upward are defined as the front, rear, right and left sides of the grill cabinet 20, respectively. A stove 1 shown in FIG. 1 is a built-in stove that is installed by being dropped into an opening provided in a countertop of a kitchen (not shown).

  The overall structure of the stove 1 will be described with reference to FIG. The stove 1 includes a substantially rectangular parallelepiped instrument body 2. A grill cabinet 20 (see FIGS. 2 and 3) is attached to the center in the width direction inside the appliance body 2. A top plate 3 having a rectangular shape in plan view is attached to the upper part of the instrument body 2. A right burner 4 is provided on the right front side of the top plate 3, a left burner 5 is provided on the left front side, and a back burner 6 is provided on the center rear side. An exhaust port 7 that communicates with the inside of the grill cabinet 20 is provided behind the back burner 6. Although not described in detail, an igniter for ignition and a thermocouple for detecting misfire are attached to the various burners 4 to 6.

  A grill door 8 having a rectangular shape in front view is provided in the center of the front surface of the appliance body 2. The grill door 8 is provided so as to be slidable in the front-rear direction by a rail unit 30 (see FIG. 2), which will be described later, provided in the grill cabinet 20, and opens and closes a grill opening (not shown) on the front surface of the grill cabinet 20. The lower part on the back side of the grill door 8 is fixed to a connecting member 35 provided at the front part of the rail unit 30 shown in FIG. 2 with screws (not shown). As shown in FIG. 2, the tray 50 and the grill net support frame 41 are attached on the rail unit 30, respectively. The grill net support frame 41 supports a grill net (not shown) above the tray 50.

  As shown in FIG. 1, a handle 9 is provided on the front upper portion of the grill door 8 so as to be inclined forward and obliquely downward. When the user puts his finger on the handle 9 from the lower side and pulls out the grill door 8 toward the front side, the user can take out the grill net and the saucer 50 from the grill cabinet 20 to the outside by the extension operation of the rail unit 30.

  By the way, a power switch 10 for turning on / off the stove 1 is provided at the upper right corner of the front surface of the instrument body 2. Below the power switch 10, ignition buttons 11 to 13 having a circular shape in front view are provided in a horizontal row in order from the right side to the left side. Further, an ignition button 14 having a circular shape in front view is provided on the left side of the grill door 8 at the same height as the ignition buttons 11 to 13. The ignition button 11 is the right burner 4, the ignition button 12 is the left burner 5, the ignition button 13 is the back burner 6, and the ignition button 14 is a lower fire burner 25 and an upper fire burner 26 (described later) in the grill 20 (FIGS. 3 and 5). (See below) to ignite / extinguish each. When the ignition buttons 11 to 14 are pressed for ignition, they are projected forward from the front surface of the instrument body 2 in a cylindrical shape by a known push-on / push-off mechanism (not shown), and are rotated in the projected state. Is possible. The user can adjust the heating power of the various burners 4 to 6, 25 and 26 by rotating the ignition buttons 11 to 14, respectively.

  Further, on the front surface of the instrument body 2, a panel 16 is provided below the ignition buttons 11 to 13, and a panel 17 is provided below the ignition button 14. When the panel 16 is pushed in with a finger, a plate-like stove control panel 18 (see FIG. 6, not shown in FIG. 1) fixed to the back of the panel 16 by a known push-on / push-off mechanism (not shown). Can be pulled forward. When the panel 17 is pushed in with a finger, the plate-like grill operation panel 19 (see FIG. 6, not shown in FIG. 1) fixed to the back surface of the panel 17 can be pulled forward by the same mechanism. Then, by pressing the panels 16 and 17 again, the stove operation panel 18 and the grill operation panel 19 are accommodated inside the instrument body 2, and the panels 16 and 17 are flush with the front surface of the instrument body 2. .

  With reference to FIGS. 2 and 3, the internal structure of the grill cabinet 20 will be described. The grill cabinet 20 includes a lower case 21 and an upper case 22 (see FIG. 3). The lower case 21 is a substantially rectangular parallelepiped housing whose upper surface and front surface are open. The upper case 22 is a substantially rectangular parallelepiped housing whose lower surface and front surface are open. The upper case 22 is placed on the upper part of the lower case 21 and fixed with screws (not shown), whereby a substantially rectangular parallelepiped grill box 20 is configured.

  As shown in FIG. 2, a rail unit 30 is provided in the lower part inside the lower case 21. The rail unit 30 includes a pair of rail structures 31 and 32 and connecting members 35 and 36. The rail structures 31 and 32 are fixed to the left and right sides of the bottom surface of the lower case 21, respectively. Although not described in detail, each of the rail structures 31 and 32 includes a fixed rail and a movable rail that is slidable along the fixed rail, and can extend and contract in the front-rear direction of the grill cabinet 20. The front ends of the movable rails of the rail structures 31 and 32 are connected by a connecting member 35, and the rear ends are connected by a connecting member 36, thereby forming one rail unit 30. The connecting member 35 is formed in an L-shaped cross section, and the back surface of the grill door 8 shown in FIG. 1 is detachably fixed to a portion bent substantially perpendicular to the horizontal plane.

  As shown in FIG. 3, a lower fire burner 25 </ b> A, a lower fire burner 25 </ b> B, and an upper fire burner 26 are provided inside the grill cabinet 20. The lower fire burner 25 </ b> A is provided on the left side surface of the lower case 21, and the lower fire burner 25 </ b> B is provided on the right side surface of the lower case 21. Each of the lower fire burner 25 </ b> A and the lower fire burner 25 </ b> B heats the lower side in the grill cabinet 20 with the flame port (not shown) directed toward the center of the grill cabinet 20. In the following description, the lower fire burners 25A and 25B are collectively referred to as “lower fire burner 25”. The upper fire burner 26 is provided substantially at the center of the upper surface of the upper case 22. The upper fire burner 26 forms a rectangular combustion surface and has a plurality of flame outlets (not shown) facing downward. The upper fire burner 26 heats the upper side in the grill cabinet 20. Thereby, the to-be-cooked object accommodated in the grill warehouse 20 or the whole Dutch oven is heated.

  With reference to FIG. 3 and FIG. 4, cooking using a Dutch oven will be described. In this embodiment, DO cooking using a Dutch oven (hereinafter simply referred to as DO) is possible. DO is a pan with a metal lid, and is generally made of cast iron. For example, an aluminum alloy, steel plate, or stainless steel can also be used. DO cooking has the advantage that the pan is thick, so there is little temperature change and the entire pan is kept at a uniform temperature, and the cooked item is thoroughly ignited. Moreover, the water vapor | steam from the to-be-cooked object fills the clearance gap between a lid and a pan, and also becomes a sealed state with the weight of a lid. If it continues to be heated in this state, the internal atmospheric pressure rises and it can be in the same state as the pressure cooker. And since water | moisture content does not escape as a vapor | steam, there also exists an advantage that the anhydrous cooking using the water | moisture content of a to-be-cooked object is easy.

  In the stove 1 of the present embodiment, a deep pan 101 (see FIG. 3) and a shallow pan 102 (see FIG. 4) as examples of DO can be used. The deep pan 101 has a deep bottom, and is a pan having a capacity of 800 ml as an example. The shallow pan 102 is shallower than the deep pan 101. These may be properly selected and used by the user according to the cooking method and the type and amount of food to be cooked. When using the deep pan 101, as shown in FIG. 3, the deep pan 101 is directly placed on and supported by the upper surface of the tray 50. When using the shallow pan 102, as shown in FIG. 4, a pan support frame 42 is further attached to the net support frame 41 from above, and the shallow pan 102 is supported by the pan support frame 42. Thereby, the pans with different sizes can be supported horizontally and stably at the approximate center in the grill cabinet 20.

  With reference to FIG. 5, a mechanism for supplying gas to the lower fire burner 25 and the upper fire burner 26 in the grill cabinet 20 and adjusting the thermal power will be described. The appliance body 2 is provided with a gas supply pipe 61 that extends toward the grill cabinet 20. A cock switch (not shown) is provided upstream of the gas supply pipe 61 in the gas flow direction. The gas supply pipe 61 is branched into a first supply pipe 62 and a second supply pipe 63 at the branch portion 67, respectively. The first supply pipe 62 is directed to the lower fire burner 25, and the second supply pipe 63 is directed to the upper fire burner 26. It is extended. A gas nozzle 62 </ b> A is connected to the downstream end of the first supply pipe 62 in the gas flow direction. The gas nozzle 62 </ b> A ejects gas toward the gas inlet 25 </ b> C of the lower fire burner 25. The gas is equally supplied to the lower fire burners 25A and 25B. A gas nozzle 63 </ b> A is connected to the downstream end of the second supply pipe 63 in the gas flow direction. The gas nozzle 63 </ b> A ejects gas toward the gas inlet 26 </ b> A of the upper fire burner 26.

  An original electromagnetic valve 91 is provided upstream of the branching portion 67 in the gas supply pipe 61, and a safety valve 92 is provided between the original electromagnetic valve 91 and the branching portion 67. The original solenoid valve 91 and the safety valve 92 open and close the flow path of the gas supply pipe 61 in response to a control command from a CPU 71 of a control circuit 70 described later.

  The first supply pipe 62 is provided with a bypass pipe 64. One end of the bypass pipe 64 on the upstream side in the gas flow direction is connected to a branch part 76 provided in the middle of the first supply pipe 62, and the other end is downstream of the branch part 76 of the first supply pipe 62. It is connected to a merging portion 77 provided on the side. A thermal power switching valve 93 is provided in the bypass pipe 64. The thermal power switching valve 93 is a keep solenoid valve that opens and closes the flow path of the bypass pipe 64. In the lower fire burner 25, the amount of gas flowing through the lower fire burner 25 can be adjusted in two stages by opening and closing the heating power switching valve 93. When the thermal power switching valve 93 is closed, the lower fire burner 25 burns with low thermal power, and when the thermal power switching valve 93 is opened, the lower fire burner 25 burns with strong thermal power. Thereby, the thermal power of the lower-fired burner 25 can be controlled in two stages, a low thermal power and a high thermal power.

  A bypass pipe 65 is provided in the second supply pipe 63. One end of the bypass pipe 65 on the upstream side in the gas flow direction is connected to a branch part 78 provided in the middle of the second supply pipe 63, and the other end is downstream of the branch part 78 of the second supply pipe 63. It is connected to a merging portion 79 provided on the side. A thermal power switching valve 94 is provided in the bypass pipe 65. The thermal power switching valve 94 is a keep solenoid valve that opens and closes the flow path of the bypass pipe 65. Further, an upper fire cutoff valve 95 is provided on the downstream side of the junction 79 in the second supply pipe 63. The upper fire cutoff valve 95 is a keep solenoid valve that opens and closes the flow path of the second supply pipe 63.

  In the upper fire burner 26, the amount of gas flowing through the upper fire burner 26 can be adjusted in two steps by opening and closing the heating power switching valve 94. When the thermal power switching valve 94 is closed, the upper fire burner 26 burns with low thermal power, and when the thermal power switching valve 94 is opened, the upper fire burner 26 burns with high thermal power. As a result, the heating power of the upper fire burner 26 can be controlled in two stages, a weak heating power and a strong heating power. As described above, in the stove 1, the thermal powers of the lower fire burner 25 and the upper fire burner 26 can be adjusted independently in two stages of strong fire power and weak fire power.

  Further, as shown in FIG. 5, the lower fire burner 25A is provided with an igniter 51 and a thermocouple 45, and the lower fire burner 25B is provided with an igniter 52 and a thermocouple 46, respectively. With the gas supplied to the lower fire burners 25A and 25B, the igniters 51 and 52 spark (spark discharge) to ignite the lower fire burners 25A and 25B. The thermocouples 45 and 46 detect misfires of the lower fire burners 25A and 25B, respectively. The upper fire burner 26 is provided with an igniter 53 and a thermocouple 47. With the gas supplied to the upper fire burner 26, the igniter 53 sparks to ignite the upper fire burner 26. The thermocouple 47 detects the misfire of the upper fire burner 26.

  Further, a grill thermistor 55 is provided in the grill cabinet 20. The grill thermistor 55 detects the temperature in the grill cabinet 20 and outputs the detection signal to the CPU 71 of the control circuit 70. The CPU 71 can control each heating power of the lower fire burner 25 and the upper fire burner 26 in the grill cabinet 20 based on the temperature detected by the grill thermistor 55.

  The electrical configuration of the stove 1 will be described with reference to FIG. In the present embodiment, for convenience of explanation, description will be made focusing on electrical connection between various devices related to the grill and a control circuit 70 described later. Therefore, description of electrical connection with various devices related to the burners 4 to 6 is omitted. In FIG. 6, various devices related to the burners 4 to 6 are not illustrated.

  The stove 1 includes a control circuit 70. The control circuit 70 includes a CPU 71, a ROM 72, a RAM 73, a flash memory 74, a timer 75, and the like. The timer 75 is operated by a program. The CPU 71 performs overall control of various operations of the stove 1. The ROM 72 stores a “DO cooking program” in addition to the various control programs of the stove 1. The DO cooking program is a control program for executing a DO cooking process (see FIGS. 9 and 10) described later. The RAM 73 stores various types of information on the stove 1. The flash memory 74 stores a DO cooking table 741 (see FIG. 7), which will be described later, and the like. The control circuit 70 includes a power supply circuit 81, a switch input circuit 82, an operation panel circuit 83, an ignition button operation circuit 84, an igniter circuit 85, a thermocouple circuit 86, a thermistor circuit 87, a safety valve circuit 88, an electromagnetic valve circuit 90, etc. It is connected.

  The power supply circuit 81 supplies power to various circuits with two dry batteries mounted in a battery box (not shown). The power supply circuit 81 includes a transistor switch (not shown). The switch input circuit 82 detects pressing of the power switch 10. The power switch 10 is connected in parallel to the switch input circuit 82 and the positive side of the dry battery stored in the battery box. The negative side of the dry battery is connected to the power supply circuit 81, and the switch input circuit 82 is also connected to the power supply circuit 81. When the power switch 10 is turned on by the user, the power of the dry battery is supplied to the power circuit 81 via the switch input circuit 82, and the transistor switch of the power circuit 81 is turned on. Thereby, current flows from the power supply circuit 81 to various circuits, and the power supply of the stove 1 is turned on. In the stove 1, the power source of the main body is automatically turned off when there is no operation for 3 minutes or more after the power switch 10 is turned on. Thereby, consumption of battery power can be prevented.

  The operation panel circuit 83 detects various operations of the stove operation panel 18 and the grill operation panel 19 and inputs them to the control circuit 70. The ignition button operation circuit 84 detects pressing and rotation operations of the ignition buttons 11 to 14 and inputs them to the control circuit 70. The igniter circuit 85 receives a command from the control circuit 70 and drives the igniters 51 to 53, respectively. The thermocouple circuit 86 inputs the output from the thermocouples 45 to 47 to the control circuit 70. The thermistor circuit 87 inputs the detection signal from the grill thermistor 55 to the control circuit 70. The safety valve circuit 88 receives a command from the control circuit 70, and opens and closes the original solenoid valve 91 and the safety valve 92, respectively. The electromagnetic valve circuit 90 receives a command from the control circuit 70, and opens and closes the heating power switching valves 93 and 94 and the upper fire cutoff valve 95, respectively.

  The DO cooking table 741 will be described with reference to FIG. The DO cooking table 741 has an initial heating time T1, a double-fire high-heat power heating time T2, a double-fire low-heat power heating time T3, and a single-fire low-heat power heating time T4 with respect to a plurality of patterns of the DO cooking set time P, respectively. Store it in association. The set time P corresponds to the “heating time” of the present invention.

  The set time P is a heating time when cooking the food to be cooked using the deep pan 101 or the shallow pan 102, and is a time that can be set manually by the user using the grill operation panel 19. In the grill operation panel 19, the set time P can be set in units of “minutes” in consideration of ease of setting by the user.

  The initial heating time T1 is a time required for the initial heating in which the lower-burner burner 25 and the upper-burner burner 26 are first burned with high heat and the deep pot 101 or the shallow pot 102 itself is heated. Regardless of the time, the same fixed time is assumed. The method for determining the initial heating time T1 will be described later. In this embodiment, it is set to 180 seconds. The both-fire high-heat power heating time T2 is a time during which the lower fire burner 25 and the upper fire burner 26 are both burned with strong heat after the initial heating, and differs depending on the set time P. The both-fire low-heating power heating time T3 is a time for both the lower-burner burner 25 and the upper-burner burner 26 to be switched to the lower heating power after both the two-fire high heating power heating, and varies depending on the set time P. The one-flame low heating power heating time T4 is a time for extinguishing the upper fire burner 26 and burning only the lower fire burner 25 with a low heating power after the two fire weak heating power heating, and differs depending on the set time P. In the following description, the initial heating time T1, the two-fire high heating power heating time T2, the both-fire low heating power heating time T3, and the one-fire low heating power heating time T4 are referred to as times T1, T2, T3, and T4, respectively. To do.

  Next, distribution of various times in the DO cooking table 741 will be described. As shown in FIG. 7, the DO cooking table 741 is divided into a first data area 741A and a second data area 741B according to the set time P. The first data area 741A is a data area for the set time P = 1 to 10 minutes, and the second data area 741B is a data area for the set time P = 11 to 30 minutes. The first data area 741A and the second data area 741B have different allocation methods for the times T1 to T4.

  First, a method for distributing the times T1 to T4 in the first data area 741A will be described. In the first data area 741A, in principle, the remaining time obtained by subtracting the time T1 (180 seconds in the present embodiment) from ½ hour of the set time P is defined as time T2, and ½ hour of the other set time P. To time T3. For example, when the set time P is 10 minutes, the half time of the set time P is 300 seconds, so the remaining 120 seconds obtained by subtracting 180 seconds, which is the time T1, from 300 seconds is the time T2, and the time T3 is It becomes 300 seconds as it is.

  However, when ½ time of the set time P does not reach the time T1, the following processing is performed. When the set time P is 5 minutes, the half time of the set time P is 150 seconds, and therefore does not reach the time T1, which is 180 seconds. In this case, the time T2 is set to 0 seconds, and the remaining time of -30 seconds obtained by subtracting 180 seconds, which is the time T1, from 150 seconds is added to the other 150 seconds, which is 1/2 of the set time P. As a result, the obtained 120 seconds is defined as time T3.

  In the present embodiment, in consideration of the convenience of the user, the set time P can be set to 3 minutes or less in the first data area 741A. In this case, the time T1 is set to the same time as the set time P, but when the time T1 elapses after ignition, the timer is increased as it is, so that the time T2 to T4 is necessarily set to 0.

Next, a method for distributing the times T1 to T4 in the second data area 741B will be described. In the second data area 741B, in principle, the remaining time obtained by subtracting the time T1 from the set time P is divided into three equal parts and assigned to the times T2 to T4, respectively. When the remaining time cannot be divided into three equal parts, the remaining time is distributed according to the following method.
When the set time P = 21 minutes, it is assigned to 3 + 6 + 6 + 6, and time T1 = 3 minutes, time T2 = 6 minutes, time T3 = 6 minutes, and time T4 = 6 minutes.
When the set time P = 22 minutes, it is assigned to 3 + 6 + 6 + 7, and the time T1 = 3 minutes, the time T2 = 6 minutes, the time T3 = 6 minutes, and the time T4 = 7 minutes.
When the set time P = 23 minutes, it is assigned to 3 + 6 + 7 + 7, and time T1 = 3 minutes, time T2 = 6 minutes, time T3 = 7 minutes, and time T4 = 7 minutes.
When the set time P = 24 minutes, it is assigned to 3 + 7 + 7 + 7, and the time T1 = 3 minutes, the time T2 = 7 minutes, the time T3 = 7 minutes, and the time T4 = 7 minutes.

  In the above example, the remaining time is divided into three equal parts, and the time that cannot be divided is distributed in the order of time T4 and time T3. The method of distributing the time that cannot be divided is not limited to the above example, but by distributing as in the above example, the thermal power is shifted to the low thermal power side, so that the gas consumption in the stove 1 can be saved.

  And in this embodiment, the set time P which the stove 1 recommends is predetermined according to the kind of pan used for DO cooking. The deep pan 101 is used for, for example, a thing with much moisture such as a stew, a bread, a cake, or the like, so that it is estimated that the heating time is relatively long. On the other hand, the shallow pan 102 is used for grilling vegetables, cooking pizza, fried foods, finishing of grilled foods, etc., so it is estimated that the heating time is relatively short. Therefore, when using the shallow pan 102, setting within the range of the set time P = 1 to 10 minutes is recommended, and when cooking using the deep pan 101, the set time P is within the range of 11 to 30 minutes. Setting in is recommended. These recommended times can be notified to the user, for example, in the manual or instruction manual of the stove 1. Therefore, the user decides and sets the set time P within the range of the recommended set time P according to the type of pot used for DO cooking. Cooking can be done.

  Next, a method for determining the time T1 will be described. DO cooking is an indirect dish in which an object to be cooked is cooked using the deep pan 101 or the shallow pan 102. When performing indirect cooking, since the heat capacity of the pan is large, the influence of the amount of heat required to heat the pan itself in addition to the amount of heat required to heat the cooking object cannot be ignored. When the amount of heat for heating the pan itself is not sufficient, heat is not sufficiently transmitted to the cooking object in the pan, and the cooking object is likely to be burnt. Therefore, it is necessary to sufficiently consider the time required for heating the pan itself as the time T1. Therefore, the time T1 is determined by performing the following experiment in the present embodiment.

  First, the experimental method will be described. Using a pan 101 having a capacity of 800 ml, a plurality of pans with different amounts of water were prepared, and for each of these pans, the lower fire burner 25 and the upper fire burner 26 were both burned with strong heat in the grill cabinet 20. The rise in water temperature when heated in a state was measured with a temperature sensor (thermocouple), and the time to reach 100 ° C. was measured. The measurement position is the center of the space in the pan. And the temperature data of five typical pots were extracted from the temperature data measured with each pot, and were put together in the graph shown in FIG.

  The experimental results will be described. As shown in FIG. 8, the boiling time of each pan is about 13 minutes for 800 ml of water, about 8 minutes for 400 ml of water, about 5.5 minutes for 200 ml of water, and about 5 minutes for 100 ml of water. In the case of 4.3 minutes and 50 ml of water, it was about 3.6 minutes. From these results, as the amount of water in the pot decreases by half, the interval of boiling required time is also shortened by about half, so it can be estimated that the time required to reach 100 ° C in the pot without water is about 3 minutes. . And these 3 minutes can be considered as the heat capacity inherent to the pan as it is. Accordingly, the time T1 is determined to be 3 minutes (180 seconds) when the set time P recommended when using the deep pan 101 is in the range of 11 to 30 minutes.

  Further, as described above, cooking with a relatively short heating time is assumed for the shallow pan 102, and therefore, in this embodiment, the set time P is set to a maximum of 10 minutes. Therefore, even if the capacity of the shallow pan 102 is small and heat is easily transmitted, it is considered that the cooking object is not easily burned due to residual heat. Therefore, even when the set time P is in the range of 1 to 10 minutes, the time T1. The same 3 minutes as the deep pot 101. In addition, about time T1 of the shallow pot 102, you may determine time T1 intrinsic | native to the shallow pot 102 by performing said experiment similarly to the deep pot 101. FIG.

  The DO cooking process executed by the CPU 71 will be described with reference to the flowcharts of FIGS. 9 and 10. When the user turns on the power switch 10, the CPU 71 periodically reads out the “DO cooking program” from the ROM 72 and executes this processing.

  First, the CPU 71 determines whether or not the set time P has been set (S1). The user inputs the set time P using the grill operation panel 19 and finally presses a DO cooking start button (not shown). The CPU 71 stores the input set time P in the RAM 73 and completes the setting of the set time P. If the set time P is not set (S1: NO), this process is terminated.

  When a user intends to cook DO using the shallow pan 102, the set time P suitable for the cooking object to be cooked from the set time P = 1 to 10 minutes recommended for the shallow pan 102. Enter to set. If you are going to cook DO using the pan 101, enter the set time P that is appropriate for the food to be cooked from the set time P = 11 to 30 minutes recommended for the pan 101. Set.

  When the set time P is set (S1: YES), the CPU 71 refers to the DO cooking table 741 (see FIG. 7) stored in the flash memory 74, and time T1, time T2 corresponding to the set time P. , Time T3 and time T4 are read (S2). Various read data are written in the RAM 73.

  For example, in the case of DO cooking using the shallow pan 102, when the set time P = 5 minutes is set, the time T1 = 180 seconds, the time T2 = 0 seconds, the time T3 = 120 seconds, and the time T4 = 0 seconds are read. , Written in the RAM 73. When the set time P = 10 minutes is set, the time T1 = 180 seconds, the time T2 = 120 seconds, the time T3 = 300 seconds, and the time T4 = 0 seconds are read and written to the RAM 73, respectively. In addition, when the set time P = 20 minutes is set for DO cooking using the deep pan 101, time T1 = 180 seconds, time T2 = 300 seconds, time T3 = 360 seconds, and time T4 = 360 seconds are read. Then, the data is written in the RAM 73.

  Next, it is determined whether or not an ignition operation has been performed (S3). The user installs the shallow pan 102 or the deep pan 101 containing the food to be cooked in the grill cabinet 20, closes the grill door 8, and then presses the ignition button 14 to perform the ignition operation. Until there is an ignition operation (S3: NO), the process returns to S3 and enters a standby state.

  When the ignition operation is performed (S3: YES), as shown in FIG. 5, the igniters 51 to 51 are opened after the original solenoid valve 91, the safety valve 92, the thermal power switching valves 93 and 94, and the upper fire cutoff valve 95 are opened. The lower fire burner 25 and the upper fire burner 26 are ignited by driving 53 (S4). After ignition, both the lower fire burner 25 and the upper fire burner 26 are in a combustion state with both fires and strong heat that burns with strong heat, and DO cooking starts. In addition, this process is complete | finished when the misfire of the lower fire burner 25 and the upper fire burner 26 is detected by the thermocouples 45-47.

  Next, the CPU 71 starts another program and starts counting the cooking time t using the output from the timer 75 (see FIG. 3) (S5). The count value is stored in the RAM 73. The count value is reset when the program is started.

  Next, it is determined whether or not the set time P is 3 minutes or longer (S7). When the set time P is less than 3 minutes (S7: NO), it is determined whether or not the cooking time t has reached the time T1 in the combustion state of both fires and strong heating power (S11). For example, when the set time P is 2 minutes, since the time T1 is 120 seconds (see FIG. 7), it is determined whether or not the cooking time t has reached 120 seconds. Until the cooking time t reaches the time T1 (S11: NO), the process returns to S11 and the combustion state of the two fires is continued. Then, when the cooking time t reaches time T1 (S11: YES), the lower solenoid burner 25 and the upper flame burner 26 are extinguished together as shown in FIG. 10 by closing the original solenoid valve 91 and the safety valve 92. (S19), this process is terminated.

  On the other hand, returning to FIG. 9, when the set time P is 3 minutes or more (S7: YES), it is determined whether the cooking time t has reached the time T1 (S8). Until the cooking time t reaches time T1 (S8: NO), the combustion state of both fires is continued, and the process returns to S8 and enters a standby state. During this time, the deep pan 101 or the shallow pan 102 is heated, and the temperature of the whole pan rises. When the cooking time t reaches time T1 (S8: YES), it is determined whether or not the time T2 is 0 with reference to the time T2 stored in the RAM 73 (S9). For example, when the set time P is 5 minutes, the time T2 is 0, and when the set time P is 20 minutes, the time T2 is 300 seconds.

  When the time T2 is 0 (S9: YES), the process proceeds to S12 shown in FIG. When the time T2 is not 0 (S9: NO), it is determined whether the cooking time t has reached the sum of the time T1 and the time T2 (S10). For example, when the set time P is 20 minutes, referring to the times T1 and T2 stored in the RAM 73, since the time T1 is 180 seconds and the time T2 is 300 seconds, has the cooking time t reached 180 + 300 = 480 seconds? Judge whether or not. Until the cooking time t reaches the sum of the time T1 and the time T2 (S10: NO), the process returns to S10, and the combustion state of both fires is continued.

  When the cooking time t reaches the total of time T1 + time T2 (S10: YES), as shown in FIG. 10, the time T3 stored in the RAM 73 is referenced to determine whether the time T3 is 0 (S12). ). When the time T3 is 0 (S12: YES), the original solenoid valve 91 and the safety valve 92 are closed, the lower fire burner 25 and the upper fire burner 26 are extinguished together (S19), and this process is terminated.

  On the other hand, when the time T3 is not 0 (S12: NO), the lower power burner 25 and the upper fire burner 26 are switched from the strong heat power to the low heat power by closing the heat power switching valves 93 and 94 shown in FIG. It is set as the combustion state of a low heat power (S13). And it is judged whether the cooking time t reached the sum total of time T1 + time T2 + time T3 in the combustion state of both fire weak thermal powers (S14). For example, when the set time P is 20 minutes, referring to the times T1, T2, and T3 stored in the RAM 73, the time T1 is 180 seconds, the time T2 is 300 seconds, and the time T3 is 360 seconds. It is determined whether or not 180 + 300 + 360 = 840 seconds. Until the cooking time t reaches the sum of time T1 + time T2 + time T3 (S14: NO), the process returns to S14 to continue the combustion state of both fires and low heat.

  When the cooking time t reaches the sum of time T1 + time T2 + time T3 (S14: YES), the time T4 stored in the RAM 73 is referenced to determine whether the time T4 is 0 (S15). In the present embodiment, as shown in FIG. 7, when the set time P is within the range of 1 to 10 minutes (first data area 741A), all the times T4 are set to 0. When the time T4 is 0 (S15: YES), the original solenoid valve 91 and the safety valve 92 are closed, the lower fire burner 25 and the upper fire burner 26 are extinguished together (S19), and this process is terminated.

  On the other hand, when the time T4 is not 0 (S15: NO), the upper fire burner 26 is extinguished by closing the upper fire cutoff valve 95 shown in FIG. 5 (S16), and only the lower fire burner 25 is weakly heated. Set the combustion state to a one-fire low heat power to burn. In the present embodiment, only the set time P is within the range of 11 to 30 minutes (second data area 741B), and the time T4 is set to 180 to 540 seconds. Therefore, in the DO cooking using the deep pan 101, in principle, it is possible to set the combustion state to one-sided low heat power in the second half of cooking. Thus, when the whole inside of the grill cabinet 20 is heated to a temperature suitable for cooking, the upper fire burner 26 is extinguished and the lower fire burner 25 is maintained with a low heating power, so that the lower portion of the deep pan 101 is overheated. Can be suppressed. Therefore, since the baking unevenness of the upper and lower parts of the cooking object in the deep pan 101 is reduced, a high-quality cake or bread can be baked. Furthermore, since the upper fire burner 26 is extinguished and heated only by the lower fire burner 25 when the entire inside of the grill cabinet 20 is heated to a temperature suitable for cooking, the gas consumption of the stove 1 can be saved.

  Next, it is determined whether or not the cooking time t has reached the sum of time T1 + time T2 + time T3 + time T4 in the combustion state of one-sided low heat power (S17). For example, when the set time P is 20 minutes, referring to the times T1, T2, T3, and T4 stored in the RAM 73, the time T1 is 180 seconds, the time T2 is 300 seconds, the time T3 is 360 seconds, and the time T4 is 360 seconds. Therefore, it is determined whether the cooking time t has reached 180 + 300 + 360 + 360 = 1200 seconds. Until the cooking time t reaches the sum of time T1 + time T2 + time T3 + time T4 (S17: NO), the process returns to S17 to continue the combustion state of one-sided low heat power.

  When the cooking time t reaches the sum of time T1 + time T2 + time T3 + time T4 (S17: YES), the lower solenoid burner 25 that has been burned with low heat until now is closed by closing the original solenoid valve 91 and the safety valve 92. Is extinguished (S19), and this process is terminated.

  As described above, DO cooking using the grill cabinet 20 is possible with the stove 1 of the present embodiment. DO cooking is cooking which heats the to-be-cooked material in a pan by heating the pan (for example, the deep pan 101 or the shallow pan 102) which put the to-be-cooked object in the grill cabinet 20. FIG. In DO cooking, in addition to the amount of heat required for heating the cooking object, the amount of heat required to heat the pan itself is affected. Therefore, in the present embodiment, after ignition and combustion start, initial heating is performed in which the upper fire burner 26 and the lower fire burner 25 are burned for a time T1 required for heating the pan itself. Thereby, even if the heat capacity of the pan is large, the pan itself can be heated sufficiently. Then, after the initial heating, each combustion operation of the upper fire burner 26 and the lower fire burner 25 is controlled in a combustion mode corresponding to the set time P set on the grill operation panel 19. Thereby, it can fully heat, without the to-be-cooked thing in a pan becoming raw-burning.

  In the present embodiment, the DO cooking table 741 is stored in the flash memory 74. The DO cooking table 741 is table information in which the heating power and the combustion time of each of the upper fire burner 26 and the lower fire burner 25 are associated with each other according to a plurality of patterns of the set time P set on the grill operation panel 19. is there. Based on the DO cooking table 741, the CPU 71 of the stove 1 determines the respective heating power and combustion time of the upper fire burner 26 and the lower fire burner 25 corresponding to the set time P set on the grill operation panel 19. Each combustion operation of the burner 26 and the lower fire burner 25 is controlled. Thereby, heat cooking can be performed with the heating power and combustion time appropriate for the set time P. In addition, regarding the DO cooking table 741, specific cooking power and combustion time are associated with each other in accordance with a plurality of patterns of the set time P, so that cooking suitable for actual cooking can be appropriately performed.

  Further, in the present embodiment, the DO cooking table 741 stores an initial heating time T1, a double-fire high-heat power heating time T2, and a double-fire low-heat power heating time T3 respectively associated with a plurality of patterns of the set time P. Both-fire high-heat power heating time T2 is a time for burning both the upper fire burner 26 and the lower fire burner 25 with strong heat. Both fires low heating power heating time T3 is a time for burning both the upper fire burner 26 and the lower fire burner 25 with low heat power. Accordingly, the CPU 71 determines the times T1 to T3 based on the DO cooking table 741, so that the upper fire burner 26 and the lower fire burner 25 are set in the combustion mode suitable for the set time P set on the operation panel 19 for grill. Can be burned. In addition, after the initial heating, both the upper fire burner 26 and the lower fire burner 25 are burned with a strong heating power, so that the cooking object can be efficiently heated in a short time. By using a low heating power for both, the food in the pan can be prevented from being burned by overheating.

  Moreover, in this embodiment, DO cooking table 741 memorize | stores the one-flame low heat power heating time T4 in addition to time T1-T3. Time T4 is a time for extinguishing the upper fire burner 26 and burning only the lower fire burner 25 with low heat power. The CPU 71 determines times T1 to T4 corresponding to the set time P set on the grill operation panel 19 based on the DO cooking table 741. By burning the upper fire burner 26 and the lower fire burner 25 with both fires at time T <b> 1 to T <b> 3, hot air moves to the upper side in the grill cabinet 20. Then, after burning the upper fire burner 26 and the lower fire burner 25, at time T4, the upper fire burner 26 is extinguished and only the lower fire burner 25 is burned, so that the temperature in the grill box 20 is made uniform. The Therefore, the stove 1 can heat the cooking object in the pan satisfactorily and uniformly.

  In the present embodiment, the DO cooking table 741 includes a first data area 741A corresponding to DO cooking using the shallow pot 102 and a second data area 741B corresponding to DO cooking using the deep pot 101. . The recommended range of the set time P is determined according to the type of pan used for DO cooking. The user sets the set time P on the grill operation panel 19 in accordance with the type of pan used for DO cooking. Since CPU71 determines time T1-T4 corresponding to set time P based on DO cooking table 741, it can heat a pan in the combustion mode according to the kind of pan used for DO cooking.

  In the above description, the deep pan 101 and the shallow pan 102 which are DO correspond to the “cooking container” of the present invention, the grill cabinet 20 corresponds to the “heating chamber” of the present invention, and the grill operation panel 19 corresponds to the present invention. The CPU 71 that corresponds to “setting means” and executes the process of S2 corresponds to “combustion mode determining means” of the present invention, and the igniters 51 to 53 correspond to “ignition means” of the present invention, and the processes of S5 and S8. The CPU 71 that executes the process corresponds to the “initial heating means” of the present invention, the CPU 71 that executes the processes of S10, S12 to S18, and S19 corresponds to the “combustion control means” of the present invention, and the DO cooking table 741 The flash memory 74 corresponds to the “storage means” of the present invention, the time T2 corresponds to the “first both-fire combustion time” of the present invention, and the time T3 corresponds to the “combustion control information” of the present invention. Phase 2 And, time T4 corresponds to a "single fire burning time" in the present invention.

  In addition, this invention is not limited to the said embodiment, A various change is possible. For example, in the DO cooking table 741 shown in FIG. 7, the times T2 to T4 are allocated to a plurality of patterns of the set time P based on the above-described predetermined rules, but can be freely set according to the set time P. It is also possible to allocate to. Since the times T2 to T4 of the DO cooking table 741 can be rewritten freely, it is possible to distribute the time corresponding to the actual cooking.

  Moreover, in the said embodiment, although 180 second is derived | led-out by the experimental result about the initial heating time T1, 180 second is an example, Comprising: Time required for the heating of the pan itself which is DO used with the grill warehouse 20 at least If it is. Further, the time T1 may be different between the first data area 741A and the second data area 741B. In this case, at least the time T1 of the second data area 741B is longer than the time T1 of the first data area 741A.

  In the above embodiment, the DO cooking table 741 is used, the time T1 is fixed at 180 seconds, and the times T2 to T4 are determined according to the set time P. However, if the time T1 can be secured, the time T2 is set. T4 may be obtained by a calculation formula.

  Moreover, in the said embodiment, although the DO cooking table 741 is provided with 1st data area 741A and 2nd data area 741B which are mutually different according to the size (capacity) of a pan, not only a size but a material and shape A plurality of different data areas may be provided depending on the difference.

  Moreover, in the said embodiment, the stove 1 automatically detects the size of the pan installed in the grill warehouse 20 with a sensor or the like, and the first data of the DO cooking table 741 according to the automatically detected pan size. The area 741A or the second data area 741B may be referred to. Separately from this, the size of the pan is selected on the grill operation panel 19, and the first data area 741A or the second data area 741B of the DO cooking table 741 is referred to according to the selected size. Good.

  Moreover, although the stove 1 provided with the grill warehouse 20 was demonstrated as an example of this invention in the said embodiment, for example, the table stove provided with the grill warehouse may be sufficient, and also the grill cooker provided only with the grill warehouse. Applicable.

DESCRIPTION OF SYMBOLS 1 Stove 2 Instrument body 3 Top plate 10 Power switch 14 Ignition button 19 Grill operation panel 20 Grill box 25 Lower fire burners 51-53 Igniter 70 Control circuit 71 CPU
74 Flash memory 101 Deep pan 102 Shallow pan 741 DO cooking table 741A 1st data area 741B 2nd data area T1 Initial heating time T2 Double fire high heat heating time T3 Double fire low heat heating time T4 Single fire low heat heating time

Claims (5)

A heating chamber capable of storing a cooking container for storing an object to be cooked;
An upper fire burner provided on the upper side of the heating chamber;
A lower fire burner provided under the heating chamber;
Using the upper fire burner and the lower fire burner, setting means for setting the heating time for cooking the cooking object by heating the cooking container accommodated in the heating chamber;
Combustion mode determining means for determining the combustion mode of the upper fire burner and the lower fire burner based on the heating time set by the setting means;
Ignition means for igniting the upper fire burner and the lower fire burner;
Initial heating means for burning the upper fire burner and the lower fire burner ignited by the ignition means for a time required for heating the cooking vessel itself;
After the initial heating means burns the upper fire burner and the lower fire burner, the combustion operation of the upper fire burner and the lower fire burner is controlled based on the combustion manner determined by the combustion manner determining means. A cooking device comprising a combustion control means. Storage means for storing combustion control information, which is information associated with the respective heating power and combustion time of the upper fire burner and the lower fire burner, in accordance with a plurality of patterns of the heating time set by the setting means With
The combustion mode determining means, based on the combustion control information stored in the storage means, the heating power of each of the upper fire burner and the lower fire burner corresponding to the heating time set by the setting means, and the Determine the burning time,
The said combustion control means controls the said combustion operation | movement of the said upper fire burner and the said lower fire burner based on the said thermal power and the said combustion time determined by the said combustion mode determination means. Cooking device. The combustion control information includes a first double-fire combustion time in which the upper fire burner and the lower fire burner are both burned with high heating power according to the plurality of patterns of the heating time, and the upper fire burner and the lower fire. Including a second both-fire combustion time in which the burners are both burned with low heat,
The combustion mode determining means includes
Based on the combustion control information, determine the first both-fire combustion time and the second both-fire combustion time corresponding to the heating time set by the setting means,
The combustion control means includes
During the first both-fire combustion time determined by the combustion mode determining means, both the upper fire burner and the lower fire burner are burned with strong heating power, and then the second fire time determined by the combustion mode determining means is determined. The cooking device according to claim 2, wherein both the upper fire burner and the lower fire burner are burned with a low heating power during both fire combustion times. The combustion control information further includes a one-flame combustion time for extinguishing the upper fire burner and burning only the lower fire burner according to the plurality of patterns of the heating time,
The combustion mode determining means determines the first double-fire combustion time, the second double-fire combustion time, and the one-fire combustion time corresponding to the heating time set by the setting means based on the combustion control information. Decide
The combustion control means burns both the upper fire burner and the lower fire burner with a strong heating power during the first both-fire combustion time determined by the combustion mode determining means, and then the combustion mode determining means The upper fire burner and the lower fire burner are both burned with a low heating power during the determined second both-fire combustion time, and then the upper fire burner is extinguished and determined by the combustion mode determining means. The cooking device according to claim 3, wherein only the lower-burner burner is burned with low heating power during the one-flame combustion time. The storage means stores a plurality of the combustion control information corresponding to the types of the cooking containers accommodated in the heating chamber,
The combustion mode determining means determines the heating power and the combustion time of the upper fire burner and the lower fire burner based on the combustion control information corresponding to the type of the cooking container. The cooking device according to any one of 4 to 4.

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