JP2009092266A - Gas cooker - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gas cooker capable of judging an abnormal state when a temperature sensor for detecting a cooking container temperature is not normally mounted or is in out of order. <P>SOLUTION: A CPU monitors a detection temperature Tp by a thermistor during a prescribed time from the ignition (START) of a standard burner (S5). Whether a value of change of the detection temperature by the thermistor is within a prescribed range or not is judged (S6), and it is judged that the thermistor is operated in a normal state, when the value of change of the detection temperature by the thermistor is over the prescribed range (S6:NO). On the other hand, when the value of change of the detection temperature by the thermistor is kept within the prescribed range continuously for a prescribed time (S6:YES), it is judged that the thermistor is in an abnormal state (S8). Thus the abnormal state can be properly judged when the gas cooker is used in a state that the thermistor is not normally mounted, or gets out of order. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a gas cooker, and more particularly to a gas cooker including a temperature sensor that detects the temperature of the bottom surface of a cooking container.

  Conventionally, gas cookers having a safety function for preventing a tempura fire or the like are known. In such a gas cooker, a temperature sensor with a built-in thermistor is brought into contact with the bottom surface of a cooking container placed on Gotoku. Then, the temperature detected by the thermistor is monitored, and when the detected temperature reaches the set temperature, it is determined that the temperature is overheated, and the electromagnetic valve provided in the gas supply path to the burner is forcibly closed to automatically digest. It has become. Such a gas cooker, of course, does not activate the safety function when used with the temperature sensor broken or removed. In this case, even if the cooking container is in an overheated state, the gas continues to be supplied to the burner and continues to burn, so that it becomes a dangerous state.

Therefore, in order to detect a failure of the temperature sensor, a gas cooker in which a current fuse is connected in series with a thermistor in the temperature sensor has been proposed (see, for example, Patent Document 1). According to this gas cooker, when the thermistor is short-circuited, the current fuse is blown to detect a failure. A gas cooker has also been proposed that detects a disconnection failure when the electrical resistance of the thermistor exceeds a predetermined value (see, for example, Patent Document 2).
JP-A-9-33047 JP-A-9-210808

  However, in such a conventional gas cooker, the abnormality of the temperature sensor can only be detected by detecting the thermistor short-circuit failure and disconnection failure. Therefore, when the abnormality of the temperature sensor is not the case of the short circuit failure and the disconnection failure of the thermistor, there is a concern that the cooking container is not extinguished even though the cooking container is actually overheated.

  Even if the temperature sensor is not malfunctioning, if the temperature sensor is not properly installed at the time of manufacture, or if the temperature sensor is improperly removed by the user, for example, The sensor cannot detect the temperature of the cooking container. In this case, even if the cooking container is in an overheated state, the gas continues to be supplied to the burner and continues to burn, which may lead to a dangerous state. Until now, a gas cooker for detecting whether or not a temperature sensor is normally mounted has not been proposed.

  The present invention has been made to solve the above-described problems, and provides a gas cooker that ensures safety by determining an abnormal state when a temperature sensor is not properly mounted or in a failure state. The purpose is to do.

  In order to achieve the above object, a gas cooker according to the first aspect of the present invention comprises a gas burner for heating a cooking vessel placed on a virtues, and a heating start judgment for judging whether heating has been started by the gas burner. And a gas cooker that forcibly extinguishes the gas burner when the temperature detected by the temperature sensor is equal to or higher than a set temperature. The heating time measuring means for measuring the time from the ignition operation to the gas burner or the heating start determination time by the heating start determining means, and until the time measured by the heating time measuring means passes a predetermined time, When the change value of the temperature detected by the temperature sensor remains within a set range, it is determined that the temperature sensor is in an abnormal state that is not operating in a normal state. Characterized in that it comprises a abnormal state determining means.

  Moreover, the gas cooker of the invention which concerns on Claim 2 is provided with the alerting | reporting means which alert | reports in addition to the structure of the invention of Claim 1, when it judges that it is an abnormal state by the said abnormal condition determination means. It is characterized by that.

  In addition to the configuration of the invention described in claim 1 or 2, the gas cooker of the invention according to claim 3 can be applied to the gas burner after that when the abnormal state is determined by the abnormal state determination means. An ignition operation invalidating unit that does not accept the ignition operation even when the ignition operation is performed is provided.

  In addition to the configuration of the invention according to any one of claims 1 to 3, the gas cooker according to a fourth aspect of the present invention includes the gas burner when the abnormal state determination means determines that the gas burner is in an abnormal state. Gas supply prohibiting means for prohibiting the gas supply to is provided.

  In addition to the configuration of the invention according to any one of claims 1 to 4, the gas cooker of the invention according to claim 5 is an initial stage in which a temperature detected by the temperature sensor is preset in an ignition operation for the gas burner. When the temperature is within the temperature range, the abnormal state determination means determines whether or not the temperature sensor is in an abnormal state.

  In the gas cooker according to the first aspect of the present invention, the heating time measuring means measures the time from the ignition operation to the gas burner or from the start of heating, and the abnormal state judging means measures the time measured by the heating time measuring means. Whether or not the change value of the temperature detected by the temperature sensor keeps within the set range is confirmed until a predetermined time elapses. In the case of a normally mounted temperature sensor, the detected temperature exceeds the set range before a predetermined time elapses from ignition. For this reason, when the temperature detected by the temperature sensor remains within a predetermined range until a predetermined time elapses from ignition, it is determined that the temperature sensor is in an abnormal state that is not operating in a normal state. Thereby, when it is used in a state where the temperature sensor is not normally attached, it can be accurately determined that the temperature sensor is in an abnormal state. Even if the temperature sensor failure is not an extreme case such as a short circuit failure or a disconnection failure, an abnormal state can be detected accurately.

  In addition, in the gas cooker of the invention according to claim 2, in addition to the effect of the invention according to claim 1, notification is performed when the notification means is determined to be abnormal by the abnormal state determination means. Thereby, the user can know that the temperature sensor is in an abnormal state, and the user can avoid cooking without being aware of the abnormal state of the temperature sensor. Therefore, a highly safe gas appliance can be provided.

  Further, in the gas cooker of the invention according to claim 3, in addition to the effect of the invention of claim 1 or 2, when the ignition operation invalidating means is determined to be abnormal by the abnormal state determining means, Even if the ignition operation for the gas burner is performed thereafter, the ignition operation is not accepted. Thereby, even when the user performs an ignition operation without noticing that the temperature sensor is in an abnormal state, the gas device is not ignited in the abnormal state, and a safer gas appliance can be provided.

  In addition, in the gas cooker of the invention according to claim 4, in addition to the effects of the invention according to any one of claims 1 to 3, when the gas supply prohibiting means is determined to be abnormal by the abnormal state determining means In this case, the gas supply to the gas burner is prohibited. Therefore, when there is an abnormality in the temperature sensor, heating of the cooking container is forcibly interrupted. Thereby, the fire by overheating of a to-be-cooked object can be prevented reliably, and a safer gas appliance can be provided.

  In addition, in the gas cooker of the invention according to claim 5, in addition to the effect of the invention according to any one of claims 1 to 4, the abnormal state determination means is preset with the temperature detected by the temperature sensor during the ignition operation. Only when the temperature is within the initial temperature range, it is determined whether or not the temperature sensor is in an abnormal state. During the ignition operation, even if the cooking container already in a high temperature state is further heated, the temperature of the cooking container hardly changes. Also, when the cooking container cooled during the ignition operation is heated, or when the room temperature is low, the cooking container temperature rises slowly. In other words, when the temperature detected by the temperature sensor that detects the temperature of the cooking container is outside the predetermined range during the ignition operation, even if the temperature sensor in the normal state is used, the detected temperature from the ignition operation The change value of is small. In the present invention, the temperature sensor is in a normal state by determining whether or not the temperature sensor is in an abnormal state only when the temperature detected by the temperature sensor during the ignition operation is within a preset initial temperature range. Nevertheless, misjudgment that determines that the state is abnormal is prevented. Thereby, the gas cooker which improved safety | security without impairing usability can be provided.

  Hereinafter, a stove 1 according to an embodiment of the present invention will be described with reference to the drawings. 1 is a plan view of the stove 1, FIG. 2 is a front view of the stove 1, and FIG. 3 is a block diagram showing an electrical configuration of the stove 1. As shown in FIG. FIG. 4 is a diagram showing an example in which the detected temperature of the first thermistor 7 operating in the normal state is compared with the detected temperature of the first thermistor 7 operating in the abnormal state. 5 is a flowchart showing a thermistor abnormality detection process by the microcomputer control circuit 40.

  The stove 1 according to the present embodiment monitors the detected temperature of the thermistors 7 and 8 provided in the burners 5 and 6 for one minute from the ignition operation. If the change value of the detected temperature is within a certain temperature range for 1 minute from the ignition operation, it is determined that the thermistors 7 and 8 are not operating in a normal state.

  First, a schematic configuration of the stove 1 will be described. As shown in FIGS. 1 and 2, a top plate 2 having a substantially rectangular plate shape is provided on the top surface of the stove 1, and a circular opening 3 is formed in a right half portion of the top plate 2. A circular opening 4 is formed in the left half portion. A standard burner 5 is provided inside the opening 4, and a strong heating power burner 6 is provided inside the opening 3. The openings 3 and 4 are provided with virtues 11 and 12 so as to cover the outer peripheries of the standard burner 5 and the high thermal power burner 6, and cooking pots (not shown) are placed on the upper portions of the virtues 11 and 12. Placed.

  In addition, thermocouples 19 and 20 are provided in the vicinity of the standard burner 5 and the high thermal power burner 6 to detect that the burners 5 and 6 are in a combustion state by generating an electromotive force by heating the combustion flame. To do. A first thermistor 7 is provided at the center of the standard burner 5, and a second thermistor 8 is provided at the center of the high thermal power burner 6. These thermistors 7 and 8 detect the bottom temperature of the pot by abutting against the bottom of the cooking pot placed on the virtues 11 and 12. That is, since the temperature of the cooking object in the cooking pan cannot be directly detected, the temperature of the cooking object in the cooking pan is estimated by detecting the pan bottom temperature. In addition, a grill 15 is provided in the center of the inside of the stove 1, and a grill burner (not shown) for heating an object to be cooked is provided in a grill box (not shown) of the grill 15.

  Further, an exhaust port (not shown) of the grill 15 is provided behind the top plate 2, and exhaust port covers 13 and 14 are detachably provided on the grill exhaust port. The exhaust port covers 13 and 14 are provided with a plurality of exhaust holes 13a and 14a, respectively.

  As shown in FIG. 2, an ignition switch 21 for igniting the standard burner 5 is provided at the lower part on the left side of the front surface facing the user of the stove 1. Further, an ignition switch 22 for igniting the high-burning power burner 6 and an ignition switch 23 for igniting the grill burner (not shown) are provided side by side on the lower right side across the grill 15. Further, a heating power adjustment lever 25 capable of manually adjusting the heating power of the standard burner 5 is provided above the ignition switch 21, and a heating power adjustment lever capable of manually adjusting the heating power of the strong heating power burner 6 is provided above the ignition switch 22. 26 is provided, and on the upper side of the ignition switch 23, a heating power adjusting lever 27 capable of manually adjusting the heating power of the grill burner (not shown) is provided. In addition, a battery box 29 in which a dry battery is installed and a speaker 50 (see FIG. 3) for sounding a buzzer are provided at the left end of the front surface of the stove 1.

  Further, the standard burner 5, the strong burner 6, and the grill burner of the stove 1 are each provided with an igniter 35 (see FIG. 3) for igniting each burner. Further, the stove 1 is provided with a safety valve 38 (see FIG. 3), which is an electromagnetic valve for shutting off the gas supply when an abnormality of the thermistors 7 and 8 is detected. The standard burner 5 and the high thermal power burner 6 shown in FIGS. 1 and 2 correspond to the “gas burner” of the present invention, and the first thermistor 7 and the second thermistor 8 correspond to the “temperature sensor”.

  Next, the electrical configuration of the stove 1 will be described. As shown in FIG. 3, the stove 1 includes a microcomputer control circuit 40 that performs thermal power control of various burners. The microcomputer control circuit 40 includes a CPU 40a, a ROM 40b, a RAM 40c, an I / O interface (not shown), and the like. The microcomputer control circuit 40 includes a power supply circuit 41 that supplies power to various circuits using a dry battery mounted in a battery box 29 (see FIG. 2), and switches that detect pressing of the ignition switches 21, 22, and 23, respectively. An input circuit 42, a thermistor input circuit 43 for inputting detection signals output from the thermistors 7 and 8, an igniter circuit 45 for driving the igniters 35 of various burners, and a safety valve for controlling the opening and closing of each safety valve 38 A circuit 46, a thermocouple circuit 51 for detecting the electromotive force of the thermocouples 19 and 20, a voltage monitoring circuit 47 for monitoring the voltage of the power supplied from the power supply circuit 41, and a buzzer for outputting a buzzer from the speaker 50. Non-volatile memory circuit 4 which is a semiconductor memory capable of retaining stored contents even when power from output circuit 48 and power supply circuit 41 is cut off If, like are respectively connected. The power supply circuit 41 includes a microcomputer control circuit 40, a switch input circuit 42, a thermistor input circuit 43, an igniter circuit 45, a safety valve circuit 46, a thermocouple circuit 51, a voltage monitoring circuit 47, a buzzer output circuit 48, and a nonvolatile memory circuit 49. Are connected to each other to supply power to each circuit.

  Next, an abnormality detection method for the thermistors 7 and 8 in the stove 1 will be described. In the present embodiment, since the same abnormality detection method is applied to the two thermistors 7 and 8, the abnormality detection method for the first thermistor 7 will be described below. In the example shown in FIG. 4, the time-dependent change (a, b, d) of the detected temperature of the first thermistor 7 operating in the normal state and the time-dependent change of the detected temperature of the first thermistor 7 operating in the abnormal state. An example is compared with (c). The “abnormal state” in this example refers to a “state that is not normally attached”.

  A curve a is a change with time in temperature detected by the first thermistor 7 operating in a normal state when an object to be cooked such as water is put in a cooking container and heated. Curve b is a change over time in temperature detected by the first thermistor 7 operating in a normal state when a low-temperature food item is placed in a cooking container and heated, such as when thawing frozen food. Curve c is a change with time of the temperature detected by the first thermistor 7 when the cooking container is heated in a state where the first thermistor 7 is not correctly mounted. A curve d is a change with time in temperature detected by the first thermistor 7 operating in a normal state when the cooking container heated to a predetermined temperature or higher is further heated.

First, the curve a will be described. A curve a shown in FIG. 4 is a change with time in temperature detected by the first thermistor 7 operating in a normal state when a cooking container containing a material to be cooked that is close to room temperature such as water is heated. As described above, the first thermistor 7 detects the temperature of the bottom of the cooking container. However, since the cooking object close to room temperature is contained in the cooking container, the standard burner 5 is ignited. detection temperature Tr of the first thermistor 7 of (time "0") is about room temperature equally, from T _L in the range of T _H. As will be described later, the stove 1 of the present embodiment determines whether or not the thermistors 7 and 8 are abnormal only when the detected temperature Tr of the thermistors 7 and 8 during the ignition operation is within a preset initial temperature range. Make a decision. T _L and T _H are the initial temperature range, respectively lower and upper limit values.

  The detected temperature of the first thermistor 7 rises as time elapses, the cooking container is heated, and rises at least Δβ from the detected temperature Tr at the time of ignition until at least 1 minute has passed since ignition ( A point). As will be described later, the stove 1 according to the present embodiment indicates that the thermistors 7 and 8 are abnormal when the change value ΔT of the detected temperature Tr of the thermistors 7 and 8 remains within a certain range for one minute from the ignition operation. to decide. Δβ is a threshold value of a change value to the high temperature side when the abnormality determination is performed.

Next, the curve b will be described. A curve b shown in FIG. 4 is a change with time in temperature detected by the first thermistor 7 operating in a normal state when a cooking container containing a low-temperature food item such as frozen food is heated. When cooking frozen foods, in most cases, cooking is started immediately after the frozen foods are put into a cooking container. In addition, since the frozen food is almost solid, air enters between the food and the cooking container, thereby inhibiting heat transfer from the food to the cooking container. Therefore, when the standard burner 5 is ignited (time “0”), the temperature of the low-temperature food is not transferred to the bottom of the cooking container. Accordingly, the detected temperature Tr of the first thermistor 7 of ignition is approximated to the temperature of the cooking vessel before turning the food, it is in the range of T _H from T _L close to room temperature. The detected temperature of the first thermistor 7 is detected at the time of elapse of time, the temperature of the frozen food is transferred to the cooking container and once falls, and at least 1 minute has elapsed since ignition. Shows a drop of Δα or more from the temperature Tr (point B). Then, the detected temperature of the first thermistor 7 increases with the heating of the cooking container by the standard burner 5. Note that Δα is a threshold value of a change value to the low temperature side when the abnormality determination is performed.

This, in this embodiment, the temperature detected by the first thermistor 7, there from T _L during ignition of the standard burner 5 in the range of T _H, and showed an increase of more than Δβ within 1 minute from the ignition In the case (a curve), or when it shows a drop of Δα or more (b curve), it is determined that the first thermistor 7 is operating in a normal state.

Next, the curve c will be described. A curve c shown in FIG. 4 is a change with time of the temperature detected by the first thermistor 7 when the cooking container is heated in a state where the first thermistor 7 is not properly attached. The first thermistor 7, the time of standard burner 5 was ignited (time "0"), similarly to the first thermistor 7 which is operating in a normal state, to detect a range of T _H from T _L. However, after that, even if the cooking container is heated by the standard burner 5, it continues to detect a substantially constant temperature. This is because the first thermistor 7 is not normally mounted and is not in contact with the cooking container, and therefore the room temperature is detected without detecting the temperature of the cooking container. In this case, the detected temperature of the first thermistor 7 does not rise above Δβ or fall below Δα within one minute from ignition.

This, in this embodiment, the temperature detected by the first thermistor 7, there from T _L during ignition of the standard burner 5 in the range of T _H, and also rise more than Δβ within one minute from the ignition, [Delta] [alpha] If the lowering is not shown, it is determined that the first thermistor 7 is operating in an abnormal state.

Note that T _L , T _H , Δα, and Δβ have different optimum values depending on the type of cooking object and cooking container in addition to the room temperature, and can be set as appropriate depending on the region of use, usage, and the like. T _L ° C is (7 ± 2) ° C, T _H ° C is (40 ± 2) ° C, Δα ° C is Δ (2 ± 2) ° C, and Δβ ° C is Δ (8 ± 2) ° C.

Next, the curve d will be described. A curve d shown in FIG. 4 is a change with time of the temperature detected by the first thermistor 7 operating in a normal state when the cooking container heated in advance to _TH or higher is further heated. Because the cooking vessel is heated above a pre T _H, the detected temperature Tc of the first thermistor 7 when the standard burner 5 in this case has been ignited (time "0") is T _H or more. The detected temperature of the first thermistor 7 rises as time passes and the cooking container is further heated, but the cooking container has already been heated, so the rate of rise is slow. Therefore, even after 1 minute has elapsed since ignition, the detected temperature does not increase by more than Δβ and does not decrease by more than Δα.

Thus, in the case of further heating the cooking container that has been heated to _TH or higher in advance, even if the first thermistor 7 operating in a normal state is used, the detection is performed within 1 minute from the ignition. In some cases, the temperature does not increase by more than Δβ and does not decrease by more than Δα. Therefore, the temperature detected by the first thermistor 7 at ignition of the standard burner 5 as the case when more than T _H, it is assumed that the first thermistor 7 does not perform the judgment of whether the abnormal state .

In addition, when heating the cooking container cooled beforehand or when room temperature is low, it takes time until the cooking container is heated after the standard burner 5 is ignited. That is, even when the first thermistor 7 operating in the normal state is used, the detected temperature may not increase by Δβ or more within one minute after ignition. Therefore, even when the detected temperature Tr is less than T _L of the first thermistor 7 at ignition of the standard burner 5, similarly to the case where the detected temperature Tr of the first thermistor 7 at ignition of the standard burner 5 is not less than T _H, Whether or not the thermistors 7 and 8 are in an abnormal state is not determined.

  Next, the thermistor abnormality detection processing will be described with reference to the block diagram shown in FIG. 3 and the flowchart shown in FIG. In the present embodiment, since the same abnormality detection process is executed for the two thermistors 7, 8, the process for the first thermistor 7 will be described below.

  When the ignition switch 21 is operated and the power supply circuit 41 starts to supply power to the microcomputer control circuit 40, the thermistor abnormality detection process by the CPU 40a of the microcomputer control circuit 40 is started as shown in FIG. In this thermistor abnormality detection process, first, the detected temperature Tr of the first thermistor 7 at the time of input of the ignition switch 21 is stored in the RAM 40c of the microcomputer control circuit 40 (S1).

Then, the detected temperature Tr of the first thermistor 7 at the operation of the ignition switch 21 is whether the judgment is in the range of T _L of T _H is performed (S2). Here, if the detected temperature Tr is determined not in the range of T _H from T _L: the (S2 NO), the following process is not performed, and terminates the thermistor abnormality detection processing.

On the other hand, the detected temperature is when it is determined that the range of T _L of T _H: The (S2 YES), the standard burner 5 actually determines whether a spark state is performed (S3). This determination is made by measuring the electromotive force of the thermocouple 19 by the thermocouple circuit 51 and determining whether an electromotive force of a certain level or more is measured, that is, whether a flame is detected. When an electromotive force of a certain level or more is not measured, it is determined that the heating state is not yet substantial, that is, it is not in an ignition state (S3: NO), and the process of S3 is performed again.

  When an electromotive force of a certain level or more is measured by the thermocouple 19 and it is determined that the standard burner 5 is actually in an ignition state (S3: YES), processing for starting measurement for one minute by a timer is performed ( S4). Then, the detected temperature Tp of the first thermistor 7 at that time is stored in the RAM 40c of the microcomputer control circuit 40 (S5).

  Thereafter, a value obtained by subtracting the detected temperature Tr of the first thermistor 7 at the time of input of the ignition switch 21 from the detected temperature Tp of the first thermistor 7 at that time is calculated, and this value is in the range of -Δα to Δβ. Is determined (S6). Here, when the subtracted value is outside the range of -Δα to Δβ (S6: NO), it is determined that the first thermistor 7 is normally detecting the temperature of the cooking container, and the thermistor abnormality is detected as it is. The detection process ends. On the other hand, when the subtracted value is within the range of -Δα to Δβ (S6: YES), it is further determined whether or not the one-minute measurement by the timer has ended (S7). If it is determined that the one-minute measurement by the timer has not ended (S7: NO), the process returns to S5, and the processes of S5 to S7 are repeated until the one-minute measurement by the timer is completed. .

  On the other hand, when it is determined that the one-minute measurement by the timer has been completed (S7: YES), the nonvolatile memory circuit 49 stores that the first thermistor 7 is in an abnormal state (S8). Next, by generating a buzzer from the speaker 50, it is informed that the first thermistor 7 is in an abnormal state (S9), and the process of closing the safety valve 38 is performed to cut off the gas supply to the standard burner 5. (S10). Then, even if the user subsequently presses the ignition switch 21, in order to invalidate the ignition operation, processing for prohibiting driving of the igniter 35 for igniting the standard burner 5 is performed (S11).

  In S2 of the flowchart shown in FIG. 5, the CPU 40a of the microcomputer control circuit 40 that determines whether or not the heating by the standard burner 5 is performed based on the electromotive force measured by the thermocouple 19 is “ The CPU 40a that functions as “heating start determination means” and determines whether or not the timer set in S4 has expired in S7 functions as “heating time measurement means”. In S6, the CPU 40a that detects the abnormality of the first thermistor 7 functions as "abnormal state determination means" by determining whether or not the temperature that has risen within the predetermined time is within a predetermined range. In S9, the CPU 40a that performs processing for generating a buzzer from the speaker 50 functions as the “notification means” of the present invention. In S10, the safety valve 38 is closed to shut off the supply of gas to the standard burner 5. The CPU 40a that performs the processing corresponds to the “gas supply prohibiting means” of the present invention. And CPU40a which performs the process which prohibits the drive of the igniter 35 for igniting the standard burner 5 by S11 is equivalent to the "ignition operation invalid means" of this invention.

  As described above, in the stove 1 of the present embodiment, the temperature detected by the thermistors 7 and 8 is monitored for one minute after the burners 5 and 6 are ignited. In the case of the thermistors 7 and 8 that are normally mounted, the detected temperature of the thermistors 7 and 8 rises by more than Δβ or falls by more than Δα by the time one minute has passed since ignition. In the present embodiment, a value obtained by subtracting the detected temperature Tr of the first thermistor 7 at the time of input of the ignition switch 21 is calculated, and it is determined whether or not this value is in the range of −Δα to Δβ. When the subtracted value continues for one minute and stays within the range of -Δα to Δβ, it is determined that the thermistors 7 and 8 are in an abnormal state where they are not operating in a normal state. Thereby, when the thermistors 7 and 8 are used in a state where they are not normally attached, it can be accurately determined that the thermistors 7 and 8 are abnormal. Further, even if the thermistors 7 and 8 are not extreme cases such as a short circuit failure and a disconnection failure, an abnormal state can be detected accurately.

  When it is detected that the first thermistor 7 is in an abnormal state, a buzzer is generated from the speaker 50 to let the user know that the first thermistor 7 is in an abnormal state. Thereby, it can avoid that a user cooks without noticing the abnormal state of the 1st thermistor 7, and can improve safety | security.

  Furthermore, when it is detected that the first thermistor 7 is in an abnormal state, the igniter 35 is not driven even if the user performs an ignition operation on the standard burner 5 thereafter. As a result, even when the user performs an ignition operation without noticing that the first thermistor 7 is in an abnormal state, the first thermistor 7 is not ignited in the abnormal state, and safety can be further improved.

  Further, when it is detected that the first thermistor 7 is in an abnormal state, a process for closing the safety valve 38 is performed even during cooking. Thereby, when there is an abnormality in the first thermistor 7, heating of the cooking container is forcibly interrupted. Therefore, a fire due to overheating of the object to be cooked can be reliably prevented, and safety can be further improved.

Moreover, the stove 1 of the present embodiment, only when the detected temperature Tr by the thermistor 7 and 8 at the time when the burner 5 and 6 is ignited is in the range of T _L of T _H, followed by the thermistor 7 and 8 It is determined whether or not is in an abnormal state. During the ignition operation, even if the cooking container already in a high temperature state is further heated, the temperature of the cooking container hardly changes. In addition, when the cooking container that has been cooled is heated or the room temperature is low during the ignition operation, the rate of increase in the cooking container temperature is moderate. That is, when the detected temperature of the thermistors 7 and 8 for detecting the temperature of the cooking container is outside the predetermined range during the ignition operation, even when the thermistors 7 and 8 in the normal state are used, The change in the detected temperature from is small. In this embodiment, only when the detected temperature Tr of the thermistor 7 and 8 at the time of ignition operation is in the range of T _L of T _H, followed by the determination of whether the thermistor 7 and 8 is in an abnormal state By doing the above, it is possible to prevent an erroneous determination that the abnormal state is determined despite the normal state. Thereby, the gas cooker which improved safety | security without impairing usability can be provided.

  In addition, the gas cooker of this invention is not limited to the stove 1 of the said embodiment, A various change is possible. First, in the present embodiment, the time measurement by the timer (S4) starts after it is determined that the ignition state is actually in effect (S3: YES), but the ignition switch 21 is input (START). You may start after. If the time measurement by the timer is performed after the ignition switch 21 is input (START), the determination as to whether or not the ignition state is present (S3) may be performed between S1 and S7. .

In the present embodiment, T _L ° C. is (7 ± 2) ° C., T _H ° C. is (40 ± 2) ° C., and the detected temperature Tr of the first thermistor 7 is T only if the _L of T _H, is carried out subsequent thermistor abnormality detection processing. However, this initial temperature can be adjusted as appropriate. For example, at the time of assembly in a factory, T _L and T _H may be set according to the area of use.

  In the present embodiment, Δα ° C. is Δ (2 ± 2) ° C., Δβ ° C. is Δ (8 ± 2) ° C., and the temperature detected by the first thermistor 7 is 1 minute after the ignition operation. Does not show an increase over Δβ and does not show a decrease over Δα, it is determined that the first thermistor 7 is in an abnormal state. However, the range of the change value that is the criterion for determining the failure can also be adjusted as appropriate. For example, different ranges of change values may be set for the first thermistor 7 provided in the standard burner 5 and for the second thermistor 8 provided in the high-burning power burner 6, or the heating power adjusting lever 25 may be set. , 26, etc., it may be configured to be set each time according to the strength of the thermal power detected. Moreover, what is necessary is just to set suitably also about the length of the time measured by a timer.

  Further, in this embodiment, in order to prohibit the subsequent ignition operation, a process for prohibiting the driving of the igniter 35 is performed in S11. As a process for prohibiting the ignition operation, the driving of the igniter 35 is prohibited. It is not limited to. For example, even when the user presses the ignition switch 21, it is possible to make a setting so that power is not supplied to the microcomputer control circuit 40, or a setting so that the safety valve 38 is not opened.

  The gas cooker of this invention can be utilized for the gas cooker provided with the thermistor which can measure the heating temperature of to-be-cooked material.

1 is a plan view of a stove 1. FIG. 1 is a front view of a stove 1. FIG. It is a block diagram which shows the electric constitution of the stove. It is a figure which shows an example which compared the detected temperature of the 1st thermistor 7 which operate | moves in a normal state, and the detected temperature of the 1st thermistor 7 which operate | moves in an abnormal state. 4 is a flowchart showing a thermistor abnormality detection process by a microcomputer control circuit 40.

Explanation of symbols

1 Stove 5 Standard Burner 6 High Power Burner 7 First Thermistor 8 Second Thermistor 19, 20 Thermocouple 21, 22 Ignition Switch 40 Microcomputer Control Circuit 40a CPU
50 speakers

Claims (5)

A gas burner for heating the cooking container placed on the five virtues, a heating start determining means for determining whether heating has been started by the gas burner, and a temperature sensor for detecting the temperature of the cooking container in contact with the cooking container And
In the gas cooker that forcibly extinguishes the gas burner when the temperature detected by the temperature sensor is equal to or higher than a set temperature,
A heating time measuring means for measuring a time from an ignition operation to the gas burner or a heating start judgment by the heating start judgment means;
Abnormal state where the temperature sensor is not operating in a normal state when the change value of the temperature detected by the temperature sensor remains within a set range until the time measured by the heating time measuring means elapses a predetermined time. A gas cooker comprising: an abnormal state judging means for judging that   The gas cooker according to claim 1, further comprising an informing unit for informing when an abnormal state is determined by the abnormal state determining unit.   An ignition operation invalidating unit that does not accept the ignition operation even when an ignition operation is performed on the gas burner after that when the abnormal state determination unit determines that the abnormal state has occurred. The gas cooker according to 1 or 2.   The gas according to any one of claims 1 to 3, further comprising gas supply prohibiting means for prohibiting gas supply to the gas burner when the abnormal state determining means determines that the gas is in an abnormal state. Cooking device.   When the temperature detected by the temperature sensor is within a preset initial temperature range during the ignition operation for the gas burner, the abnormal state determination means determines whether or not the temperature sensor is in an abnormal state. The gas cooker according to any one of claims 1 to 4, wherein the gas cooker is characterized by the following.

Images