JP2020186895A - Stove with grill - Google Patents

Abstract

To provide a technology capable of performing proper ventilation during remaining heat step, in a stove with a grill capable of executing the remaining heat step.SOLUTION: When all gas burners 51, 52, 53, 54 are in a fire extinguishing state by switching the gas burner 54 from an ignition state to a fire extinguishing state in a normal mode, a control circuit 10 and a communication unit 92 of a stove 1 wirelessly transmit a stop signal to a discharge device 100 in response to the switching of the gas burner 54 to the fire extinguishing state. When all the gas burners 51, 52, 53, 54 are in the fire extinguishing state due to the completion of a combustion step in an automatic cooking mode, the control circuit 10 and the communication unit 92 wirelessly transmit the stop signal in response to the completion of a remaining heat step.SELECTED DRAWING: Figure 7

Description

The present invention relates to a stove with a grill.

The gas stove of Patent Document 1 is a drop-in type gas stove installed on the countertop of a kitchen cabinet in a drop-in manner. Above this gas stove, a range hood as a ventilation device is installed. The gas stove is provided with an infrared transmitter that emits an infrared signal that starts or stops the operation of the range hood in conjunction with the start or stop of heating. The range hood is provided with an infrared receiver that receives an infrared signal.

In this type of gas stove, when the combustion of any gas burner starts, the gas stove sends a start signal (infrared signal) instructing the range hood to start operation, and the range hood responds to receiving the start signal. And perform ventilation operation. Then, when the combustion of all the gas burners is stopped, a stop signal (infrared signal) instructing the range hood to stop the operation is transmitted from the gas stove, and the range hood stops the ventilation operation in response to receiving the stop signal. Let me.

Japanese Unexamined Patent Publication No. 2006-78144

However, if such an interlocking method is uniformly adopted, a situation may occur in which ventilation is not performed at the time when ventilation should be performed.

For example, in recent gas stoves, after the step of burning and heating the grill burner (heating step) is performed until the combustion stop condition is satisfied, the combustion of the grill burner is stopped and cooking is performed with residual heat until the predetermined end condition is satisfied. Some have adopted an "automatic cooking mode" that performs a process (remaining heat process). If the above-mentioned interlocking method (a method of stopping the ventilation operation of the range hood according to the extinguishing of all gas burners) is adopted for this type of gas stove, the ventilation operation of the range hood will stop when the combustion of the grill burner stops. Therefore, there is a risk that odors, smoke, steam, etc. will not be properly discharged from the vicinity of the gas stove during the execution of the residual heat process.

The present invention has been made to solve at least one of the above-mentioned problems, and to provide a technique capable of appropriately ventilating during a preheating process in a stove with a grill capable of performing a preheating process. It is the purpose.

The stove with grill of the present invention
With multiple gas burners
A grill with a grill burner and a grill
A grill switch used for ignition operation and fire extinguishing operation of the grill burner,
An adjustment operation unit used for the operation of adjusting the thermal power of the grill burner,
A thermal power adjustment unit that adjusts the thermal power of the grill burner,
A switching unit that switches the operation mode of the grill burner between the first mode and the second mode,
A control unit that controls the thermal power adjustment unit and
A wireless communication unit that transmits a wireless signal to an exhaust device that discharges exhaust gas,
Have,
The control unit
When the switching unit switches to the first mode, the heating power adjusting unit is controlled so that the heating power of the grill burner is set to the heating power according to the operating state of the adjusting operation unit.
When the mode is switched to the second mode by the switching unit, a combustion step of burning the grill burner by a predetermined method and a residual heat step of stopping the combustion of the grill burner after the combustion step and cooking with residual heat. And
The wireless communication unit
When all of the plurality of gas burners and the grill burners are in the fire extinguishing state by switching the grill burner from the ignition state to the fire extinguishing state in the first mode, the grill burner is switched to the fire extinguishing state. Wirelessly transmit a stop signal to the discharge device
When all of the plurality of gas burners and the grill burners are in a fire extinguishing state due to the completion of the combustion step in the second mode, a predetermined condition is set according to the completion of the preheating step or during the preheating step. The stop signal is wirelessly transmitted according to the establishment.

According to the present invention, in a stove with a grill capable of performing a preheating step, ventilation can be appropriately performed during the preheating step.

It is a perspective view which schematically illustrates the gas stove of 1st Embodiment. It is explanatory drawing which conceptually shows the gas supply path and the like to each gas burner of the gas stove of 1st Embodiment. It is a block diagram which schematically illustrates the electric structure of the gas stove of 1st Embodiment. It is explanatory drawing which illustrates the structure of the operation panel of 1st Embodiment. It is explanatory drawing which schematically illustrates the cooking system which combined the gas stove and the discharge device of 1st Embodiment. It is a flowchart which illustrates the flow of control in the normal mode (first mode) of the gas stove of 1st Embodiment. It is a flowchart which illustrates the flow of control in the automatic cooking mode (second mode) of the gas stove of 1st Embodiment.

Hereinafter, a desirable example of the present invention is shown. However, the present invention is not limited to the following examples.

A stove with a grill, which is one of the present inventions, is used for a plurality of gas burners, a grill storage equipped with grill burners, a grill switch used for ignition operation and fire extinguishing operation of the grill burner, and an operation for adjusting the thermal power of the grill burner. The adjustment operation unit, the thermal power adjustment unit that adjusts the thermal power of the grill burner, the switching unit that switches the operation mode of the grill burner between the first mode and the second mode, the control unit that controls the thermal power adjustment unit, and the exhaust gas are discharged. It is possible to have a wireless communication unit that transmits a wireless signal to the discharging device. Then, when the control unit is switched to the first mode by the switching unit, the control unit controls the heating power adjusting unit so that the heating power of the grill burner is set to the heating power according to the operating state of the adjusting operation unit, and the switching unit switches to the second mode. When switched, the combustion step of burning the grill burner by a predetermined method and the residual heat step of stopping the combustion of the grill burner after the combustion step and cooking with residual heat may be performed.
With such a configuration, the stove with a grill can control the heating power adjusting unit so that the heating power of the grill burner becomes the heating power according to the operating state of the adjusting operation unit in the first mode, and the second mode At this time, it is possible to operate so as to perform a combustion step of burning the grill burner by a predetermined method and a residual heat step of stopping the combustion of the grill burner after the combustion step and cooking with residual heat.
Further, the wireless communication unit responds to the switching of the grill burner to the fire extinguishing state when all of the plurality of gas burners and the grill burner are in the fire extinguishing state by switching the grill burner from the ignition state to the fire extinguishing state in the first mode. When a stop signal is wirelessly transmitted to the discharge device and all of the multiple gas burners and grill burners are extinguished by the end of the combustion process in the second mode, or in response to the end of the residual heat process. It is possible to operate so as to wirelessly transmit the stop signal when a predetermined condition is satisfied during the preheating step.
With such a configuration, in the first mode, the stove with a grill stops promptly when all of the plurality of gas burners and the grill burner are in the fire extinguishing state by switching the grill burner from the ignition state to the fire extinguishing state. The signal can be transmitted wirelessly to stop the discharge device. Therefore, it is possible to prevent the discharge device from continuing to operate too much after all of the plurality of gas burners and grill burners are in the fire extinguishing state, and it is possible to save power.

On the other hand, the stove with a grill has residual heat at least until the stop signal is wirelessly transmitted when all of the plurality of gas burners and the grill burner are in a fire extinguishing state due to the completion of the combustion process in the second mode. The discharge device can be operated during the process. Therefore, the area around the stove with a grill will be properly ventilated even during the preheating process.

The stove with a grill may have a notification unit that notifies the outside. Then, the control unit may notify the notification unit when the preheating process is completed in the second mode. Then, when all of the plurality of gas burners and grill burners are in the fire extinguishing state due to the completion of the combustion process in the second mode, the wireless communication unit wirelessly transmits a stop signal in response to the notification by the notification unit. May work on.
With such a configuration, the stove with a grill is notified by a notification unit when all of the plurality of gas burners and the grill burner are in a fire extinguishing state due to the completion of the combustion process at least in the second mode. It can be notified. Therefore, the user can know that such a fire extinguishing state has occurred. Then, since the wireless communication unit wirelessly transmits the stop signal in response to such notification, the discharging device can be operated even during the preheating process at least until the notification is given by the notification unit.

The stove with a grill may have a residual heat time operation unit used for an operation of adjusting the time for performing the residual heat step. When the control unit is switched to the second mode by the switching unit, the control unit is adjusted by the combustion step of burning the grill burner by a predetermined method and the residual heat time operation unit by stopping the combustion of the grill burner after the combustion step. It may operate so as to perform a preheating step of cooking with residual heat until the elapsed time elapses.
With such a configuration, the user can adjust the time for performing the preheating process to a desired length by operating the preheating time operation unit. Then, the stove with a grill can wirelessly transmit a stop signal according to the completion of the preheating process or when a predetermined condition is satisfied during the preheating process while performing the preheating process with the preheating time adjusted by the user. ..

<First Embodiment>
Hereinafter, the first embodiment will be described with reference to the drawings.
The stove with a grill 1 shown in FIG. 1 (hereinafter, also referred to as a stove 1) is configured as a built-in stove capable of heating cooking utensils such as a cooking pot. The stove 1 is used, for example, in a cooking system as shown in FIG. The cooking system shown in FIG. 5 includes a stove 1 and a discharge device 100, and can transmit information by wireless communication between the stove 1 and the discharge device 100.

The stove 1 is provided with a right stove portion 4A and a left stove portion 4B so as to be exposed from a top plate 2 (top plate) constituting the upper surface of the stove body 1A, and the left and right stove portions 4A, respectively. A small stove portion 4C is provided between the 4Bs toward the rear. A grill storage 3 is provided below the top plate 2 near the center of the inside of the stove body 1A. The grill storage 3 is a portion that accommodates an object to be cooked and is cooked by a grill burner (gas burner 54: FIG. 2). The grill storage 3 can be opened and closed by a grill door 3B provided on the front surface of the stove body 1A.

As shown in FIG. 1, the gas burners 51, 52, 53, and 54 shown in FIG. 2 are provided in the right corner portion 4A, the left corner portion 4B, the small corner portion 4C, and the grill storage 3, respectively. As shown in FIG. 2, a plurality of branch supply paths 61, 62, 63, 64 are connected to the plurality of gas burners 51, 52, 53, 54, respectively, and these branch supply paths 61, 62, 63, 64 are common. It is configured to branch from the supply path 60. The common supply path 60 is a common gas path to the gas burners 51, 52, 53, 54, and the plurality of branch supply paths 61, 62, 63, 64 branch from the common supply path 60 and each gas burner 51, 52. , 53, 54 are supply paths arranged to guide the gas. The common supply path 60 is provided with a main solenoid valve N1 that opens and closes the common supply path 60. The branch supply path 61 that branches from the common supply path 60 and continues to the gas burner 51 includes a solenoid valve (safety valve) 51G that can open and close the branch supply path 61, a shutoff valve 51F that can open and close the branch supply path 61, and a gas burner 51. A thermal power control valve 51E that can adjust the amount of gas supplied to the vehicle is provided. The branch supply path 62 that branches from the common supply path 60 and continues to the gas burner 52 includes a solenoid valve (safety valve) 52G that can open and close the branch supply path 62, a shutoff valve 52F that can open and close the branch supply path 62, and a gas burner 52. A thermal power control valve 52E that can adjust the amount of gas supplied to the vehicle is provided. The branch supply path 63 that branches from the common supply path 60 and continues to the gas burner 53 includes a solenoid valve (safety valve) 53G that can open and close the branch supply path 63, a shutoff valve 53F that can open and close the branch supply path 63, and a gas burner 53. A thermal power control valve 53E that can adjust the amount of gas supplied to the vehicle is provided.

The gas burner 54 (grill burner) of the grill storage 3 is a gas burner that heats the cooking object housed in the grill storage 3, and has an upper burner 54A arranged on the upper side in the grill storage 3 and an upper burner 54A in the grill storage 3. It is provided with a lower burner 54B arranged below the burner 54A. The branch supply path 64 that branches from the common supply path 60 and guides the gas to the gas burner 54 further includes a first supply path 65A that branches from the branch supply path 64 and guides the gas to the upper burner 54A, and a branch supply path 64. A second supply path 65B that branches and guides gas to the lower burner 54B is connected. The branch supply path 64 is provided with an electromagnetic valve (safety valve) 54G capable of opening and closing the branch supply path 64 and a closing valve 54F, and the first supply path 65A is provided with a plurality of solenoid valves 54H and 54J. A solenoid valve 54K is provided in the supply path 65B. The solenoid valves 54H, 54J, 54K correspond to an example of the thermal power adjusting unit, and are used for the operation of adjusting the thermal power of the gas burner 54.

As shown in FIG. 1, four rotation operation units 6A, 6B, 6C, and 6D are provided so as to correspond to the right side portion 4A, the left side portion 4B, the small portion 4C, and the grill storage 3, respectively. There is. In the example of FIG. 1, all of the rotation operation units 6A, 6B, 6C, and 6D are switched between the retracted position and the protruding position each time the user pushes them. The rotation operation unit 6D corresponds to an example of a grill switch, and is used for ignition operation and fire extinguishing operation of the gas burner 54 (grill burner). The rotation operation unit 6D corresponds to an example of the adjustment operation unit, and is used for an operation of adjusting the thermal power of the gas burner 54. As shown in the electrical configuration of FIG. 3, switches 30A, 30B, 30C, and 30D are provided so as to correspond to the rotation operation units 6A, 6B, 6C, and 6D, respectively, and switches 30A, 30B, 30C, and 30D are provided, respectively. Ignition signal input circuits 40A, 40B, 40C, and 40D are provided so as to correspond to each other. Further, displacement detection units 32A, 32B, 32C and 32D are provided so as to correspond to the rotation operation units 6A, 6B, 6C and 6D, respectively, and thermal power is provided so as to correspond to the displacement detection units 32A, 32B, 32C and 32D, respectively. The signal input circuits 42A, 42B, 42C, and 42D are provided, respectively. In any of the rotation operation units 6A, 6B, 6C, and 6D, the displacement detection unit corresponds to the displacement (rotation position) of the rotation operation unit, and the displacement detection unit detects the displacement (rotation position) of the rotation operation unit from the thermal signal input circuit corresponding to the displacement detection unit. A signal corresponding to the detected displacement (rotational position) is given to the control circuit 10.

As shown in FIG. 2, a first supply path 65A is configured as a main path for guiding gas to the upper burner 54A, and the path of the solenoid valve 54J and the path of the solenoid valve 54J are bypassed so as to bypass the solenoid valve 54J provided in the first supply path 65A. A bypass path 66A, which is a parallel path, is provided. When the solenoid valve 54J is closed with the solenoid valve 54H open, the gas guided by the branch supply path 64 is supplied to the upper burner 54A through the bypass path 66A. When both the solenoid valves 54H and 54J are open, the gas guided by the branch supply path 64 is supplied to the upper burner 54A through the first supply path 65A or the bypass path 66A. Further, a second supply path 65B is configured as a main path for guiding gas to the lower burner 54B, and a path parallel to the path of the solenoid valve 54K is used so as to bypass the solenoid valve 54K provided in the second supply path 65B. A bypass path 66B is provided. When the solenoid valve 54K is closed, the gas guided by the branch supply path 64 is supplied to the lower burner 54B through the bypass path 66B. When the solenoid valve 54K is open, the gas guided by the branch supply path 64 is supplied to the lower burner 54B through the second supply path 65B or the bypass path 66B. Further, as shown in FIGS. 2 and 3, thermocouples 51C, 52C, 53C, 54C, 54D are provided adjacent to the burners 51, 52, 53, 54A, 54B, respectively, and thermocouples 51C, 52C, respectively. Temperature signal input circuits 44A, 44B, 44C, 44D, 44E are provided corresponding to each of 53C, 54C, and 54D, respectively. The temperature signal input circuits 44A, 44B, 44C, 44D, and 44E all input signals to the control circuit 10 according to the electromotive force generated by the corresponding thermocouple. Igniters 26A, 26B, 26C, 26D are provided adjacent to each of the gas burners 51, 52, 53, 54, respectively, and igniter circuits 46A, 46B, 46C, corresponding to the igniters 26A, 26B, 26C, 26D, respectively. Each of the 46Ds is provided. For example, an igniter 26D is provided corresponding to the gas burner 54, and the igniter circuit 46D drives the igniter 26D in response to an external ignition operation (ignition operation of the switch 30D) with respect to the rotation operation unit 6D, and sparks are generated by the igniter 26D. It is discharged and the gas burner 54 is ignited.

As shown in FIG. 4, the operation panel 18 includes a plurality of buttons 18A, 18B, and 18C, and is a portion capable of performing an operation for instructing the start of cooking in the automatic cooking mode in the grill storage 3. The button 18A is a mode selection switch, and when pressed while the power is on, the mode setting state is switched. Buttons 18B and 18C are buttons for adjusting the heating temperature and the heating time. Further, the buttons 18B and 18C correspond to an example of the residual heat time operation unit, and are used for the operation of adjusting the time for performing the residual heat step.

The communication unit 92 and the control circuit 10 described later correspond to an example of the wireless communication unit, and transmit a wireless signal to the exhaust device 100 that discharges the exhaust gas. The communication unit 92 has a known light emitting element such as an infrared LED capable of generating infrared light and a drive circuit, and has a configuration capable of transmitting an infrared signal by turning on / off the light emitting element. The drive circuit is a circuit that drives a light emitting element based on a command from the control circuit 10. The light emitting element can be provided, for example, in the transmitting units 41 and 42 shown in FIGS. 1 and 5. In infrared communication, as shown in FIG. 5, infrared light emitted from a light emitting element incorporated in the transmitting units 41 and 42 is applied to the user P, and the light reflected from the user P is emitted from the receiving unit 102 of the discharging device (exhausting device) 100. (Infrared light receiving unit) may be used, and the infrared light emitted from the light emitting element hits the floor or the like, and the receiving unit 102 of the discharging device 100 receives the light reflected from the floor or the like. You may.

The exhaust device 100, which is a communication partner, is configured as a known range hood having a ventilation fan, and exhaust gas generated by the heating operation of the right microwave oven portion 4A, the left microwave oven portion 4B, the small microwave oven portion 4C, and the grill storage 3. Has the function of discharging. As shown in FIG. 3, the discharge device 100 includes a receiving unit 102 that receives an infrared signal, a control device 104 that analyzes the infrared signal received by the receiving unit 102, and a drive load 106 (ventilation fan) driven by the control device 104. The drive load 106 is driven by the control of the control device 104.

The control circuit 10 is configured as a microcomputer, for example, and includes a CPU 10A, a ROM 10B, a RAM 10C, and the like, as shown in FIG. 3, and further includes a timer, an I / O interface, and the like (not shown). Further, although not shown, a non-volatile memory may be provided inside or outside the control circuit 10. The control circuit 10 corresponds to an example of a switching unit, and switches the operation mode of the gas burner 54 between a normal mode (first mode) and an automatic cooking mode (second mode). Further, the control circuit 10 corresponds to an example of the control unit, and controls the solenoid valves 54H, 54J, 54K. The control circuit 10 can control each of the above-mentioned solenoid valves (not shown in FIG. 3), igniters 26A, 26B, 26C, 26D, a plurality of display devices 21, 22, 23, 24, a voice device 14, and the like. As shown in FIG. 1, each of the display devices 21, 22, 23, and 24 is provided corresponding to each of the rotation operation units 6A, 6B, 6C, and 6D. The voice device 14 corresponds to an example of a notification unit, and is a device that emits voices such as a melody and a message. The voice device 14 includes, for example, a speaker or a drive circuit that gives a voice signal to the speaker, and operates so as to emit voice corresponding to an instruction from the control circuit 10. Further, a power supply circuit 48 is provided so as to supply electric power to various electric components including the above-mentioned electric components. The power supply circuit 48 has a function of receiving power from two dry batteries 49 housed in a battery box and generating a predetermined power supply voltage, and the power supply voltage generated by the power supply circuit 48 follows a path (not shown). It is supplied to various electric parts via.

Next, the cooking mode of the stove 1 will be described.
In the stove 1, a plurality of types of cooking modes can be set in the grill storage 3. The plurality of types of cooking modes include at least "normal mode" and "automatic cooking mode (auto mode)", and "automatic cooking mode" includes, for example, "toast mode" and "dried fish mode". "Filling mode", "figure-baking mode", etc. are included. The "normal mode" corresponds to an example of the first mode. The "automatic cooking mode" corresponds to an example of the second mode. The normal mode is a mode in which such an automatic cooking mode (“toast mode”, “dried fish mode”, “fillet mode”, “figure burning mode”, etc.) is not performed.

In the stove 1, the mode can be switched by operating the operation panel 18 shown in FIG. 4 when the power of the stove 1 is on. The mode setting information that can identify which mode is set is stored in a memory or the like.

(Normal mode control)
The flow shown in FIG. 6 is the control when the stove 1 is set to the “normal mode”. The control of FIG. 6 is started when the control circuit 10 detects an ignition operation (S11). Following S11, the control circuit 10 transmits a ventilation start instruction (S12). That is, the control circuit 10 transmits a radio signal including an exhaust start instruction to the exhaust device 100 via the communication unit 92. Upon receiving the ventilation start instruction, the exhaust device 100 starts the exhaust control.

When a fire extinguishing operation (an operation of pressing the rotation operation unit 6D) is performed after S12, the control circuit 10 detects the fire extinguishing operation (S13). Following S13, the control circuit 10 determines whether or not all the gas burners 51, 52, 53, 54 are in the fire extinguishing state (S14). For example, the control circuit 10 determines whether or not all the shutoff valves 51F, 52F, 53F, and 54F connected to the gas burners 51, 52, 53, and 54 are in the closed state. When the control circuit 10 determines that all the gas burners 51, 52, 53, 54 are not in the fire extinguishing state (at least one gas burner is in the ignition state) (No in S14), all the gas burners 51, 52, The process of S14 is repeated until it is determined that 53 and 54 are in the fire extinguishing state.

On the other hand, when it is determined that all the gas burners 51, 52, 53, 54 are in the fire extinguishing state (Yes in S14), the control circuit 10 transmits a ventilation stop instruction (stop signal) (S15). That is, the control circuit 10 transmits a radio signal including an exhaust stop instruction to the exhaust device 100 via the communication unit 92. Upon receiving the ventilation stop instruction, the exhaust device 100 ends the exhaust control.

In the normal mode, when focusing on the gas burner 54 (grill burner), the operation is as follows. In this case, the control circuit 10 controls the solenoid valves 54H, 54J, 54K so that when the mode is switched to the first mode, the thermal power of the grill burner 54 is set to the thermal power according to the operation state of the rotation operation unit 6D. Specifically, the opening / closing pattern of the solenoid valves 54H, 54J, 54K is determined according to the rotation angle of the rotation operation unit 6D. When the rotation operation unit 6D is in the first operation state (first rotation angle range), the solenoid valves 54H, 54J, 54K are all closed, and the thermal power of the lower burner 54B is reduced. When the rotation operation unit 6D is in the second operation state (second rotation angle range), the solenoid valve 54H is opened, the solenoid valves 54J and 54K are closed, and the thermal power of the upper burner 54A and the lower burner 54B is reduced. When the rotation operation unit 6D is in the third operating state (third rotation angle range), the solenoid valves 54H and 54K are opened, the solenoid valves 54J are closed, the thermal power of the upper burner 54A is reduced, and the thermal power of the lower burner 54B is reduced. Becomes larger. When the rotation operation unit 6D is in the fourth operation state (fourth rotation angle range), the solenoid valves 54H, 54J, 54K are opened, and the thermal power of the upper burner 54A and the lower burner 54B is increased.

When the control circuit 11 switches the grill burner 54 from the ignition state to the fire extinguishing state in the normal mode (first mode), all of the plurality of gas burners 51, 52, 53 and the grill burner 54 are in the fire extinguishing state. A stop signal is wirelessly transmitted to the discharge device 100 in response to the switching of the grill burner 54 to the fire extinguishing state. When all the burners 51, 52, 53, and 54 are in the fire extinguishing state in the normal mode (first mode) (when Yes in step S14), the grill burner 54 is switched to the fire extinguishing state. , A ventilation stop signal (stop signal) is wirelessly transmitted to the discharge device 100 in step S15. When it is determined Yes in S14, the stop signal may be transmitted immediately or after a predetermined short time has elapsed.

(Control of automatic cooking mode)
In the stove 1 shown in FIG. 1 and the like, when the power of the stove 1 is on (when the operating power is supplied to each component from the power supply circuit) and a predetermined start condition is satisfied, the control circuit The automatic cooking control shown in FIG. 7 is executed by 10. The predetermined start condition is, for example, a condition that an ignition instruction operation is performed on the rotation operation unit 6D when any of "toast mode", "dried fish mode", "fillet mode", and "figure burning mode" is set. Is.

The control of FIG. 7 is started when the control circuit 10 first detects the automatic cooking start operation (step S21) and a predetermined start condition is satisfied. Following S21, the control circuit 10 starts a combustion process (S22). Specifically, the control circuit 10 burns the gas burner 54 in a predetermined manner. Here, combustion performed by a predetermined method is combustion in a state in which one or a plurality of combustion processes are predetermined, and the thermal power state in each combustion process and the end condition of each combustion process are defined. is there. The end condition is that a certain condition has passed from the start, or that the temperature at a predetermined position exceeds a certain value. Specifically, one combustion step is defined as the first automatic cooking mode, and this combustion step is a step of performing the grill burner 54 with a predetermined heating power until a predetermined end condition is satisfied.

Following S22, the control circuit 10 transmits a ventilation start instruction (S23). That is, the control circuit 10 transmits a radio signal including an exhaust start instruction to the exhaust device 100 via the communication unit 92. Upon receiving the ventilation start instruction, the exhaust device 100 starts the exhaust control.

Following S23, the control circuit 10 performs a combustion process termination process (S24). That is, the control circuit 10 extinguishes the gas burner 54 after the combustion time corresponding to the set automatic cooking mode elapses. The stove 1 may be configured to measure the temperature of the grill storage 3, and the control circuit 10 may be configured to extinguish the fire of the gas burner 54 when the temperature of the grill storage 3 reaches a predetermined cutoff temperature. .. The predetermined cutoff temperature is determined, for example, based on a predetermined calculation formula.

Following S24, the control circuit 10 performs a preheating process start process (S25). Specifically, the control circuit 10 operates a timer (a timer that measures the elapsed time from the start of ignition of the gas burner 54).

Following S25, the control circuit 10 performs a preheating process termination process (S26). Specifically, when the timer measurement time reaches a predetermined set time (for example, the time set for each automatic cooking mode), the control circuit 10 stops the timer measurement and performs a residual heat step. Is completed, and the subsequent processing of S27 is performed. The control circuit 10 can adjust the time for performing the preheating process to a desired length by operating the buttons 18B and 18C on the operation panel 18. The end condition of the preheating step (execution condition of S26) is not limited to the above example, and for example, the temperature inside the grill 3 may be equal to or less than the threshold value.

In S27, the control circuit 10 notifies the end of automatic cooking. For example, the control circuit 10 is controlled by the voice device 14 so as to emit a voice such as a melody or a message indicating that the automatic cooking is completed.

Following S27, the control circuit 10 determines whether or not all the gas burners 51, 52, 53, 54 are in the fire extinguishing state (S28). For example, the control circuit 10 determines whether or not all the shutoff valves 51F, 52F, 53F, and 54F connected to the gas burners 51, 52, 53, and 54 are in the closed state. When the control circuit 10 determines that all the gas burners 51, 52, 53, 54 are not in the fire extinguishing state (at least one gas burner is in the ignition state) (No in S28), all the gas burners 51, 52, The process of S28 is repeated until it is determined that 53 and 54 are in the fire extinguishing state.

On the other hand, when the control circuit 10 determines that all the gas burners 51, 52, 53, 54 are in the fire extinguishing state (Yes in S28), the control circuit 10 transmits a ventilation stop instruction (S29). That is, the control circuit 10 transmits a radio signal including an exhaust stop instruction to the exhaust device 100 via the communication unit 92. Upon receiving the ventilation stop instruction, the exhaust device 100 ends the exhaust control. When the combustion process is completed in the automatic cooking mode (second mode) and all of the plurality of gas burners 51, 52, 53 and the grill burner 54 are in the fire extinguishing state, the control circuit 10 ends the residual heat process. The stop signal is transmitted wirelessly accordingly. In this example, when all the burners 51, 52, 53, 54 are in the fire extinguishing state at the end of the combustion process, that is, when the grill burner 54 is switched to the fire extinguishing state, the discharge device 100 is subjected to in step S29. The ventilation stop signal (stop signal) is transmitted wirelessly.

Here, the effect of this configuration will be illustrated.
The stove 1 with a grill is used for ignition operation and fire extinguishing operation of a plurality of gas burners 51, 52, 53, a grill storage 3 having a grill burner 54, and a grill burner 54, and is used for an operation of adjusting the thermal power of the grill burner 54. Control to control the solenoid valves 54H, 54J, 54K, which switches the operation mode of the operation unit 6D, the solenoid valves 54H, 54J, 54K for adjusting the thermal power of the grill burner 54, and the grill burner 54 between the first mode and the second mode. It has a circuit 10 and a communication unit 92 that transmits a radio signal to a discharge device 100 that discharges exhaust gas. Then, when the control circuit 10 is switched to the first mode, the control circuit 10 controls the solenoid valves 54H, 54J, 54K so that the thermal power of the grill burner 54 becomes the thermal power according to the operation state of the rotation operation unit 6D, and switches to the second mode. When switched, it operates so as to perform a combustion step of burning the grill burner 54 by a predetermined method and a residual heat step of stopping the combustion of the grill burner 54 after the combustion step and cooking with residual heat.
In such a configuration, the stove 1 with a grill can control the electromagnetic valves 54H, 54J, 54K so that the thermal power of the grill burner 54 becomes the thermal power according to the operation state of the rotation operation unit 6D in the first mode. In the second mode, the combustion step of burning the grill burner 54 by a predetermined method and the residual heat step of stopping the combustion of the grill burner 54 after the combustion step and cooking with residual heat are performed. Can be done.
Further, in the communication unit 92 and the control circuit 10, when the grill burner 54 is switched from the ignition state to the fire extinguishing state in the first mode, all of the plurality of gas burners 51, 52, 53 and the grill burner 54 are in the fire extinguishing state. In response to the switching of the grill burner 54 to the fire extinguishing state, a stop signal is wirelessly transmitted to the discharge device 100, and the combustion process is completed in the second mode, so that the plurality of 51, 52, 53 and the grill burner 54 When all of them are in a fire extinguishing state, it is possible to operate so as to wirelessly transmit a stop signal according to the completion of the preheating process or when a predetermined condition is satisfied during the preheating process.
In such a configuration, in the first mode, when the grill burner 54 is switched from the ignition state to the fire extinguishing state, the plurality of 51, 52, 53 and the grill burner 54 are all in the fire extinguishing state. The stop signal can be quickly transmitted wirelessly to stop the discharge device. Therefore, it is possible to prevent the discharge device 100 from continuing to operate too much after all of the plurality of gas burners 51, 52, 53 and the grill burner 54 are in the fire extinguishing state, and it is possible to save power.

On the other hand, in the stove 1 with a grill, at least a stop signal is wirelessly transmitted when all of the plurality of gas burners 51, 52, 53 and the grill burner 54 are in a fire extinguishing state due to the completion of the combustion process in the second mode. Until this is done, the discharge device 100 can be operated even during the preheating process. Therefore, in the vicinity of the stove 1 with a grill, proper ventilation is performed even during the preheating process.

The stove 1 with a grill has a voice device 14 that notifies the outside. Then, the control circuit 10 causes the voice device 14 to notify when the preheating process is completed in the second mode. Then, when the communication unit 92 and the control circuit 10 all of the plurality of 51, 52, 53 and the grill burner 54 are in the fire extinguishing state due to the completion of the combustion process in the second mode, the voice device 14 notifies the communication unit 92 and the control circuit 10. It operates to wirelessly transmit a stop signal according to the above.
In such a configuration, the grilled stove 1 can be used when all of the plurality of gas burners 51, 52, 53 and the grill burner 54 are extinguished by the completion of the combustion step at least in the second mode. The fact can be notified by the voice device 14. Therefore, the user can know that such a fire extinguishing state has occurred. Then, since the communication unit 92 and the control circuit 10 wirelessly transmit the stop signal in response to such notification, the discharge device 100 is operated even during the residual heat step at least until the notification is given by the voice device 14. Can be done.

The stove 1 with a grill has buttons 18B and 18C used for an operation of adjusting the time for performing the preheating process. Then, when the control circuit 10 is switched to the second mode, the combustion step of burning the grill burner 54 by a predetermined method and the combustion of the grill burner 54 after the combustion step are stopped and adjusted by the buttons 18B and 18C. It operates to perform a preheating process in which cooking is performed with residual heat until the time elapses.
In such a configuration, the user can adjust the time for performing the preheating step to a desired length by operating the buttons 18B and 18C. Then, the stove 1 with a grill can wirelessly transmit a stop signal according to the completion of the preheating process or when a predetermined condition is satisfied during the preheating process while performing the preheating process with the preheating time adjusted by the user. it can.

<Other embodiments>
The present invention is not limited to the embodiments described in the above description and drawings, and for example, the following examples are also included in the technical scope of the present invention.

In the first embodiment, the stove 1 transmits a ventilation stop instruction according to the end of the preheating process (S29 in FIG. 7), but the stove 1 ventilates according to the fact that a predetermined condition is satisfied during the preheating process. A stop instruction may be sent. For example, when the preheating process ends at time X from the start of the preheating process, a stop signal may be transmitted after the end of the combustion process and before a predetermined time (for example, 30 seconds) from the time point X.

In the first embodiment, after notifying the end of automatic cooking (after S27), the stove 1 continuously stops ventilation when all the gas burners 51, 52, 53, 54 are in the fire extinguishing state (Yes in S28). The instruction was transmitted (S29). However, after notifying the end of automatic cooking, even if Yes in S28, a ventilation stop instruction may be transmitted after a predetermined time (for example, 30 seconds) has elapsed (S29).

In the first embodiment, the stove 1 notifies the end of automatic cooking by the generation of voice by the voice device 14 (S27), but the generation of sound by the buzzer, the irradiation of light by the lamp, the operation panel 18, etc. It may be performed by the display by the display unit (7-segment display or the like) provided in.

In the first embodiment, the stove 1 may transmit a ventilation stop instruction when the power is switched to the off state during the execution of automatic cooking.

It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is not limited to the embodiments disclosed here, but may be indicated by the scope of claims and include all modifications within the meaning and scope equivalent to the scope of claims. Intended.

1 ... Gas stove (stove with grill)
3 ... Grill storage 6D ... Rotation operation unit (grill switch, adjustment operation unit)
10 ... Control circuit (switching unit, control unit, wireless communication unit)
14 ... Voice device (notification unit)
18B, 18C ... Button (remaining heat time operation unit)
51, 52, 53 ... Gas burner 54 ... Gas burner (grill burner)
54H, 54J, 54K ... Solenoid valve (thermal power adjustment unit)
92 ... Communication unit (wireless communication unit)
100 ... Discharge device

Claims (3)

With multiple gas burners
A grill with a grill burner and a grill
A grill switch used for ignition operation and fire extinguishing operation of the grill burner,
An adjustment operation unit used for the operation of adjusting the thermal power of the grill burner,
A thermal power adjustment unit that adjusts the thermal power of the grill burner,
A switching unit that switches the operation mode of the grill burner between the first mode and the second mode,
A control unit that controls the thermal power adjustment unit and
A wireless communication unit that transmits a wireless signal to an exhaust device that discharges exhaust gas,
Have,
The control unit
When the switching unit switches to the first mode, the heating power adjusting unit is controlled so that the heating power of the grill burner is set to the heating power according to the operating state of the adjusting operation unit.
When the mode is switched to the second mode by the switching unit, a combustion step of burning the grill burner by a predetermined method and a residual heat step of stopping the combustion of the grill burner after the combustion step and cooking with residual heat. And
The wireless communication unit
When all of the plurality of gas burners and the grill burners are in the fire extinguishing state by switching the grill burner from the ignition state to the fire extinguishing state in the first mode, the grill burner is switched to the fire extinguishing state. Wirelessly transmit a stop signal to the discharge device
When all of the plurality of gas burners and the grill burner are in a fire extinguishing state due to the completion of the combustion step in the second mode, a predetermined condition is set according to the completion of the preheating step or during the preheating step. A stove with a grill that wirelessly transmits the stop signal according to the establishment. It has a notification unit that notifies the outside
The control unit causes the notification unit to notify when the preheating step is completed in the second mode.
When all of the plurality of gas burners and the grill burner are in a fire extinguishing state due to the completion of the combustion step in the second mode, the wireless communication unit responds to the notification by the notification unit and causes the stop signal. The stove with a grill according to claim 1. It has a residual heat time operation unit used for the operation of adjusting the time for performing the residual heat step.
When the control unit is switched to the second mode by the switching unit, the control unit has a combustion step of burning the grill burner by a predetermined method and a combustion step of stopping the combustion of the grill burner after the combustion step to obtain the residual heat time. The stove with a grill according to claim 1 or 2, wherein the preheating step of cooking with residual heat is performed until the time adjusted by the operation unit elapses.