JP4371740B2 - Combustion device - Google Patents

Description

The present invention provides a gas combustion type burner, ignition means for performing an ignition operation on the burner, fuel supply state adjusting means capable of changing and adjusting a fuel supply state to the burner, and commanding ignition and extinguishing of the burner. Point extinguishing command means, ignition state detection means for detecting whether or not the burner is ignited, and control means for controlling the operation of the ignition means and the fuel supply state adjustment means,
The control means is
When ignition is commanded by the point fire extinguishing command means, fuel is supplied to the burner, and the ignition operation is performed until the ignition status detecting means detects that the ignition status is detected. And an ignition process for controlling the operation of the ignition means and the fuel supply state adjusting means, and
When fire extinguishing is instructed by the point fire extinguishing command means, the fuel supply to the burner is stopped both during the execution of the ignition process and during the subsequent combustion, and the ignition operation is performed during the execution of the ignition process. It is related with the combustion apparatus comprised so that the stop process which controls the action | operation of the said ignition means and the said fuel supply state adjustment means may be performed so that it may stop.

As a first conventional example of the combustion apparatus, a hot water supply apparatus which is an example of a combustion apparatus has been conventionally configured as follows.
In other words, if ignition is commanded by operating the ignition switch as the point fire extinguishing command means, the ignition process as described above is executed. At that time, an error due to non-ignition occurs when the previous ignition switch is operated. When the burner could not be ignited, the ignition process was started after a delay of a set time from the time of the current operation of the ignition switch (for example, see Patent Document 1). .) Explaining the error due to non-ignition, if ignition is not detected even after the set time has elapsed since ignition was commanded by the ignition switch and the ignition process was started, there is a risk of malfunction of the device such as ignition means. Therefore, at that time, the control means executes the stop process.

Further, as a second conventional example, a gas stove as another example of a combustion apparatus has been conventionally configured as follows.
In other words, when the ignition process is performed by operating the point fire switch as the point fire extinguishing command means and executing the ignition process, the ignition state detecting means does not detect that the ignition state is detected. When the time has elapsed, the ignition process is stopped because it is a non-ignition error. Then, after such a non-ignition error is detected, the ignition process can be performed by operating the ignition switch and commanding ignition again (for example, Patent Document 2). reference.). In the gas stove described in Patent Document 2, as a fuel supply state adjusting means, a motor-driven fuel supply in which the valve opening for fuel supply is changed and adjusted by a screw feed type operation mechanism driven by an electric motor. The gas valve is used, and it takes a little time until the ignition fuel supply amount is reached after the ignition is commanded by operating the point fire switch. The non-ignition error is the same as in the first conventional example.

JP 2002-130662 A JP 2000-179860 A

  In the first conventional example, when an ignition error as described above occurs, fuel gas in an unburned state stays in or around the burner, and then the fire extinguishing command means is operated. If the ignition process is started immediately after the ignition is commanded, the remaining fuel gas may explode, causing explosive ignition. By starting the treatment, the fuel gas staying inside or around the burner diffuses into the air or is partially discharged outside, so that the amount of staying fuel gas is reduced By starting the ignition process, explosion ignition is avoided.

  In such a configuration of the first conventional example, when it is determined that the non-ignition error is as described above, the start of the ignition process is delayed at the time of the next ignition command, so that the explosion ignition is performed. However, when the ignition is instructed by the point extinguishing command means and the stop process is executed in a state where the ignition state detecting means has not detected the ignition before the non-ignition error is determined. Is not determined as a non-ignition error, and thereafter, when ignition is commanded again by the point fire extinguishing command means, the ignition process is immediately executed without delay.

  However, even before the non-ignition error is determined, if the fire is commanded to stop and the stop process is executed when the ignition state detection means has not detected ignition, the burner is not Since the fuel gas in the combustion state is supplied, immediately after the stop process is performed, there is a possibility that the high-concentration fuel gas may stay in or around the burner. At that time, if ignition is commanded again by the point fire extinguishing command means immediately after the stop processing is executed, there is a risk of causing explosion ignition that is ignited explosively. In particular, the ignition process and the stop process are repeated a plurality of times by repeatedly performing a fire extinguishing command by the point fire extinguishing command means and a subsequent ignition command in a state where ignition is not detected by the ignition status detecting means. In such a case, there is a disadvantage that the risk of explosion ignition is great.

  In the configuration described in the second conventional example, even if fire extinguishing is commanded in a state where ignition is not detected by the ignition state detecting means before the non-ignition error is determined, Immediately after operating the point extinguishing switch, when the ignition is commanded again, the ignition process can be performed, so that there is a possibility of causing the above-described explosion ignition. In particular, in the case of a gas stove, such an explosion ignition may occur when a grill burner provided in a grill surrounded by a wall is ignited except for an exhaust passage for exhausting combustion gas. It was big.

  And when it is set as the structure which uses the above-mentioned motor drive type fuel supply gas valve as a fuel supply state adjustment means like the above-mentioned composition, when operating a point fire extinguishing command means and commanding ignition, It may take some time (1 second to several seconds) until the amount of fuel supplied by the gas valve for fuel supply becomes the amount of fuel supplied for ignition. In order to reduce power consumption, the ignition means is ignited after the fuel supply amount reaches the ignition fuel supply amount, and the user immediately executes the ignition operation despite the command of ignition. Therefore, it may be considered that the operation is abnormal, and there is a case where an operation of instructing extinguishing and instructing ignition again is repeatedly performed in a state where ignition is not detected by the ignition state detecting means. When such ignition and extinguishing commands are repeatedly performed, there is a high risk of causing the above-described explosion ignition.

  Even if the purpose of the present invention is to start ignition processing by instructing ignition and instructing fire extinguishing in a state where ignition is not detected, stop processing is executed again after that. The object of the present invention is to provide a combustion apparatus capable of improving the safety in use by preventing the burner from exploding and igniting when ignition is commanded.

A combustion apparatus according to the present invention includes a gas combustion burner, ignition means for performing an ignition operation on the burner, fuel supply state adjusting means capable of changing and adjusting a fuel supply state to the burner, and ignition and extinguishing of the burner. A fire extinguishing command means for instructing the ignition, an ignition state detecting means for detecting whether or not the burner is in an ignited state, and a control means for controlling the operation of the ignition means and the fuel supply state adjusting means. And
The control means is
When ignition is commanded by the point fire extinguishing command means, fuel is supplied to the burner, and the ignition operation is performed until the ignition status detection means detects that the ignition status is detected. An ignition process for controlling the operation of the ignition means and the fuel supply state adjustment means is executed, and
When fire extinguishing is instructed by the point fire extinguishing command means, the fuel supply to the burner is stopped both during the execution of the ignition process and during the subsequent combustion, and the ignition operation is performed during the execution of the ignition process. Is configured to execute a stop process for controlling the operation of the ignition means and the fuel supply state adjusting means, and the first characteristic configuration is as follows:
The control means is
When the ignition is instructed by the point fire extinguishing command means and the ignition process is being executed, if the non-ignition determination time elapses without the ignition state detecting means being detected as being in the ignition state, Configured to perform stop processing, and
After the ignition is commanded by the point fire extinguishing command means and fuel supply to the burner is started, the fire extinguishing command means extinguishes the fire in a state where the ignition state detecting means does not detect the ignition state. When the fuel supply to the burner is stopped , the fuel supply amount or the supply elapsed time obtained by integrating the fuel supply amount or the supply elapsed time while the fuel supply is being performed to the burner When the ignition is instructed by the point fire extinguishing command means and fuel is supplied to the burner, it remains unignited, and the fire extinguishing is instructed by the point extinguishing command means and the fuel supply to the burner is stopped. stop time elapsed between maintained in the stop state of the fuel supply based on the stop elapsed time obtained by integrating from the said fuel supply amount or the supply time elapsed The relationship between the stop elapsed time, Until the elapse of the check for configuration elapsed time to determine whether or not the ignition restraint condition to be restraining the ignition for the burner, when determining that the a spark restraining state Until the set elapsed time for checking elapses, the ignition checking process is executed so that the ignition process is not executed regardless of the ignition command from the point-extinguishing command means.

  That is, the fuel supply amount or the supply elapsed time during which fuel was supplied to the burner as described above means that the greater the fuel supply amount or the longer the supply elapsed time, This means that there is a large amount of fuel gas remaining in an unburned state in the surroundings, and the stop elapsed time from when the fuel supply to the burner is stopped until the fuel supply is stopped. Means that the longer the stop elapsed time, the smaller the amount of fuel gas that stays in and around the burner because the fuel gas diffuses into the air or is partially discharged outside. is doing.

  Further, the ignition process and the stop process were repeated a plurality of times by repeatedly performing the fire extinguishing command by the point fire extinguishing command means and the subsequent ignition command in a state where ignition was not detected by the ignition status detecting means. In such a case, the fuel supply amount or the supply elapsed time in each of the ignition processes performed a plurality of times is combined with the fuel supply amount or supply during the fuel supply to the burner. It corresponds to the elapsed time, and the sum of the elapsed stop times for each time in the stop processing performed a plurality of times corresponds to the elapsed stop time.

  The control means, for example, determines whether or not the ignition check state is in accordance with whether or not a difference in length between the supply elapsed time and the stop elapsed time is a set value or more, or the supply elapsed time Or whether the ignition stop state is determined based on whether the ratio between the stop elapsed time and the stop elapsed time is equal to or greater than a set value, or a value corresponding to the fuel supply amount and a value corresponding to the stop elapsed time Whether or not it is an ignition check state in which the ignition to the burner is to be checked based on the fuel supply amount or supply elapsed time and the stop elapsed time by various processes such as It is possible to determine whether or not there is a risk of explosion ignition.

  Further, when the control means determines that it is in the ignition check state, it performs an ignition check process that does not execute the ignition process regardless of the ignition command by the point fire extinguishing command means, and performs this ignition check process. In the meantime, even if the ignition is commanded by the point fire extinguishing command means, the ignition process is not performed, so the burner explodes and ignites by performing the ignition process in a state where a large amount of fuel gas stays in or around the burner. It is possible to avoid such inconvenience.

  Therefore, even if the ignition is instructed and the ignition process is started, even if the extinction is instructed and the stop process is executed in a state where the ignition is not detected, the ignition is instructed again thereafter. Thus, it has been possible to provide a combustion apparatus that can prevent the burner from being ignited by explosion and improve safety in use.

A combustion apparatus according to a second aspect of the present invention includes a gas combustion burner, ignition means for performing an ignition operation on the burner, fuel supply state adjusting means capable of changing and adjusting a fuel supply state to the burner, and the burner. Controls the operation of a point fire extinguishing command means for commanding ignition and extinguishing, an ignition state detecting means for detecting whether or not the burner is in an ignited ignition state, and the ignition means and the fuel supply state adjusting means. Control means,
The control means is
When ignition is commanded by the point fire extinguishing command means, fuel is supplied to the burner, and the ignition operation is performed until the ignition status detecting means detects that the ignition status is detected. And an ignition process for controlling the operation of the ignition means and the fuel supply state adjusting means, and
When fire extinguishing is instructed by the point fire extinguishing command means, the fuel supply to the burner is stopped both during the execution of the ignition process and during the subsequent combustion, and the ignition operation is performed during the execution of the ignition process. A combustion apparatus configured to execute a stop process for controlling the operation of the ignition means and the fuel supply state adjusting means,
The control means is
When the ignition is instructed by the point fire extinguishing command means and the ignition process is being executed, if the non-ignition determination time elapses without the ignition state detecting means being detected as being in the ignition state, Configured to perform stop processing, and
After the ignition is commanded by the point fire extinguishing command means and fuel supply to the burner is started, the fire extinguishing command means extinguishes the fire in a state where the ignition state detecting means does not detect the ignition state. When the fuel supply to the burner is stopped, the fuel supply amount or the supply elapsed time obtained by integrating the fuel supply amount or the supply elapsed time while the fuel supply is being performed to the burner When the ignition is instructed by the point fire extinguishing command means and fuel is supplied to the burner, it remains unignited, and the fire extinguishing is instructed by the point extinguishing command means and the fuel supply to the burner is stopped. stop time elapsed between maintained in the stop state of the fuel supply based on the stop elapsed time obtained by integrating from, than the supply elapsed time is the stop lapse time If longer than another setting period, its until the waiting time has elapsed for supervision from the time to determine that the ignition restraint condition to be restraining the ignition for the burner, when determining that the a spark restraining state, Until the set elapsed time for checking elapses, the ignition checking process is performed in which the ignition process is not executed regardless of the ignition command from the point-extinguishing command means .

That is, the fuel supply amount or the supply elapsed time during which fuel was supplied to the burner as described above means that the greater the fuel supply amount or the longer the supply elapsed time, This means that there is a large amount of fuel gas remaining in an unburned state in the surroundings, and the stop elapsed time from when the fuel supply to the burner is stopped until the fuel supply is stopped. Means that the longer the stop elapsed time, the smaller the amount of fuel gas that stays in and around the burner because the fuel gas diffuses into the air or is partially discharged outside. is doing.
Further, the ignition process and the stop process were repeated a plurality of times by repeatedly performing the fire extinguishing command by the point fire extinguishing command means and the subsequent ignition command in a state where ignition was not detected by the ignition status detecting means. In such a case, the fuel supply amount or the supply elapsed time in each of the ignition processes performed a plurality of times is combined with the fuel supply amount or supply during the fuel supply to the burner. It corresponds to the elapsed time, and the sum of the elapsed stop times for each time in the stop processing performed a plurality of times corresponds to the elapsed stop time.
When the pre-Symbol supply elapsed time becomes longer discrimination set time or more than the stop time elapsed, the time the fuel supply has been made to the burner in a state in which said an ignition state has not been detected is longer On the other hand, since the elapsed stop time while the fuel supply is stopped is short, the amount of fuel gas staying in or around the burner may be increased. Therefore, by setting the ignition check state, an ignition check process that does not execute the ignition process regardless of the ignition command by the point fire extinguishing command means is performed, and the burner can be prevented from exploding and igniting.

  Further, at this time, since the ignition check state is configured until the check standby time elapses, the ignition check state is maintained until the check standby time elapses, so that the inside of the burner By performing the ignition check process until a sufficient amount of time has passed for the fuel gas that has accumulated in the surrounding area to diffuse or be exhausted to the outside, it is possible to accurately prevent the burner from igniting explosively. , Can increase the safety in use.

Third characterizing feature of the combustion apparatus of the present invention, in addition to the first characterizing feature and the second feature structure, said control means, when executing the stop processing in accordance with the elapsed previous SL misfire determination time Is that the non-ignition determination time is set as the supply elapsed time.

  That is, the control means executes the stop process when the non-ignition determination time elapses in a state where it is not detected that the ignition state is detected. Therefore, the ignition is instructed by the point extinguishing command means and the ignition process is performed. Even if it is controlled to execute, even if it is in a state where it does not ignite due to some factor, it is possible to avoid the disadvantage that fuel gas is continuously supplied to the burner without being burned . When the stop process is executed as the misfire determination time elapses in this way, the misfire determination time is set as the supply elapsed time. Even in the case where the stop process is executed after the non-ignition determination time elapses, it is possible to determine whether or not the burner may cause explosion ignition.

  According to a fourth feature configuration of the present invention, in addition to any one of the first feature configuration to the third feature configuration, the control means instructs the ignition by the point extinguishing command means in a state where the ignition check state is not determined. When the ignition process is being executed, if the ignition check state is determined, the stop process is executed.

  That is, even when ignition is commanded by the fire extinguishing command means in a state where the ignition check state is not determined, the ignition process is executed once and the ignition process is executed. If it is determined that the ignition check state is detected, the stop process is executed. Therefore, the ignition process is continued and the fuel gas is supplied to the burner even though the burner is in a state where there is a risk of explosion ignition. Therefore, the disadvantage of continuing to be supplied can be avoided and the safety in use can be improved.

  According to a fifth feature configuration of the present invention, in addition to any one of the second to fourth feature configurations, when the control means is performing the ignition check process, the check standby time elapses. The remaining time until the end of the ignition check process is obtained, and the remaining time is displayed on the time display unit.

  That is, when the ignition check process is being performed, the remaining time until the ignition check process ends after the check standby time has elapsed is displayed on the time display unit. Since it is possible to visually confirm how much time has passed before the ignition process can be executed, it is easy to use.

A sixth characteristic configuration of the present invention is a gas combustion type burner, ignition means for performing an ignition operation for the burner, fuel supply state adjusting means capable of changing and adjusting a fuel supply state to the burner, and ignition to the burner And point extinguishing command means for commanding extinguishing, ignition state detecting means for detecting whether or not the burner is in an ignited state, control means for controlling the operation of the ignition means and the fuel supply state adjusting means, Is provided,
The control means is
When ignition is commanded by the point fire extinguishing command means, fuel is supplied to the burner, and the ignition operation is performed until the ignition state detecting means detects that the ignition status is detected. And an ignition process for controlling the operation of the fuel supply state adjusting means, and
When fire extinguishing is instructed by the point fire extinguishing command means, the fuel supply to the burner is stopped both during the execution of the ignition process and during the subsequent combustion, and the ignition operation is performed during the execution of the ignition process. Is configured to execute a stop process for controlling the operation of the ignition means and the fuel supply state adjusting means so as to stop,
The control means is
When the ignition is instructed by the point fire extinguishing command means and the ignition process is being executed, if the non-ignition determination time elapses without the ignition state detecting means being detected as being in the ignition state, Configured to perform stop processing, and
The number of times that the fire extinguishing is commanded by the point fire extinguishing command means during the ignition process and the stop process is performed, and the number of times that the non-ignition determination time elapses and the stop process is performed during the ignition process. If the total number is the set count and until the elapse of the check for the waiting time after the fuel supply is stopped for the burner by the last of the stop process, be ignited commanded by the point extinguishing command means the The ignition check process is performed without executing the ignition process.

That is, when the number of times that the stop process is performed during the execution of the ignition process reaches the set number, the control means stops the fuel supply to the burner by the last stop process until the check waiting time elapses. During this period, even if ignition is commanded by the point fire extinguishing command means, an ignition check process that does not execute the ignition process is performed.

That is, during execution of the ignition process, the fuel gas is supplied to the burner in a state in which ignition is not detected by the ignition state detection means, so that the fuel in the unburned state is not present in or around the burner. If the ignition process is started immediately when the ignition is instructed by operating the point-extinguishing command means and then the ignition is instructed, the staying fuel gas may cause explosion ignition. Wherein, when the number of times that the stopping process during execution of the pre-Symbol ignition process is set number, until the elapse of the check for the waiting time after the fuel supply is stopped for the burner by the last of the stop process is By performing the ignition check process, it is possible to avoid the possibility of causing explosion ignition.

If the ignition check process is performed when the number of times that the stop process has been performed during the ignition process is a set number, an explosion occurs if the set number is set to an appropriate number according to the configuration of the combustion device. Although it is possible to avoid the possibility of causing ignition, there is no troublesome process of performing the ignition check process every time the stop process is performed, and the control configuration can be simplified.

  Therefore, even if the ignition is instructed and the ignition process is started, even if the extinction is instructed and the stop process is executed in a state where the ignition is not detected, the ignition is instructed again thereafter. Thus, it has been possible to provide a combustion apparatus that can prevent the burner from being ignited by explosion and improve safety in use.

  In addition to any of the first to fifth feature configurations, the seventh feature configuration of the invention of the present application is notified when the control means determines that it is in an ignition restraint state in which ignition to the burner is to be restrained. In the point which is comprised so that the alerting | reporting process which alert | reports a means may be performed.

  That is, when the control means determines that it is in the ignition check state, the notification means is activated so that the user recognizes that the ignition check state in which the ignition to the burner is to be checked is made by the notification processing by the notification means. can do. Accordingly, it is possible to avoid the inconvenience of inadvertently instructing ignition when in the ignition check state, so that it is easy to use.

  According to an eighth feature of the present invention, in addition to any of the first to seventh features described above, the control means executes the ignition process according to the command of the point fire extinguishing command means by the ignition check process. It is in the point comprised so that the alerting | reporting process which alert | reports an alerting | reporting means may be performed when not doing.

  That is, when the control means does not execute the ignition process according to the command of the point fire extinguishing command means by the ignition check process, the notifying means is activated, so that the user does not execute the ignition process by the ignition check process. It can be recognized by the notification process by the notification means. Therefore, it is possible to avoid unnecessary repetition of instructing ignition by the point fire extinguishing command means, and the usability is improved.

[First Embodiment]
Hereinafter, the case where 1st Embodiment of the combustion apparatus which concerns on this invention is applied to a gas stove is described based on drawing.

  As shown in FIG. 1, the gas stove is constituted by a built-in type gas stove including three stove burners 1 a, 1 b, 1 c and a grill portion 3 having a grill burner 2. The three stove burners 1a, 1b, and 1c are constituted by a standard burner 1a, a small burner 1b, and a high thermal power burner 1c. Each of the stove burners 1a, 1b, 1c and the grill burner 2 correspond to a gas combustion type burner. And the grill exhaust port 4 for exhausting the combustion exhaust gas of the grill part 3 is formed, and the top surface of the gas stove is covered with the top plate 5, and each of the stove burners 1a, 1b, 1c is formed on the top plate 5. Five virtues 6 for receiving and supporting an object to be heated (such as a pan) are placed and supported. Further, on the front side of the gas stove, a manual operation unit S for instructing ignition and extinguishing of each of the stove burners 1a, 1b, 1c and the grill burner 2 and adjustment of thermal power is provided, and a microcomputer is provided to execute various controls. The configured control unit H is configured to control the stove burners 1a, 1b, 1c and the grill burner 2 based on the operation state commanded by the manual operation unit S. A push-operated power switch 40 is also provided on the front side of the gas stove.

  As shown in FIG. 2, each of the three burners 1a, 1b, and 1c is provided with an igniter 7 as an ignition means and a thermocouple 8 as an ignition state detection means for detecting an ignition state. 2 is composed of a double-sided burner comprising an upper surface burner 2a and a pair of left and right lower surface burners 2b, 2c, and an igniter 7 as an igniter means for each of the upper surface burner 2a and the pair of left and right lower surface burners 2b, 2c; A thermocouple 8 is provided as an ignition state detection means for detecting the ignition state. In addition, the standard burner 1a located on the left side is provided with a temperature sensor 10 that detects the temperature of the heated object in contact with the bottom surface of the heated object placed and supported by Gotoku 6.

  The gas supply configuration to the three burner burners 1a, 1b, 1c and the grill burner 2 will be described. The original gas supply passage 11 is provided with an original electromagnetic valve 12, and the original gas supply passage 11 and the standard burner branch passage 13a. , A branch path 13b for small burners, a branch path 13c for high-power burners, and a branch path 13d for grill burners, and the branch path 13d for grill burner to the grill burner 2 further includes a branch path for the upper surface burner. A branch path for the lower surface burner is branched, and each of the branch paths is provided with a flow path 15 with an orifice of and a bypass path 17 provided with an open / close solenoid valve 16. Each of the standard burner branch 13a, the small burner branch 13b, the high thermal burner branch 13c, and the grill burner branch 13d is heated by adjusting the flow rate of the fuel gas by driving the stepping motor. A flow control valve 18 for adjusting the amount is provided. This flow control valve 18 corresponds to a fuel supply state adjusting means for each of the burners 1a, 1b, 1c, and 2.

  As shown in FIG. 3, the flow rate control valve 18 includes a stepping motor 19 as a drive source, a screw feed type moving operation mechanism 20 that changes the rotational operation force of the stepping motor 19 to a sliding movement force, and a gas passage. And a flow rate adjusting plate 24 having a plurality of gas passage adjusting holes 23, and the like. The slide closing member 22 and the flow rate adjusting plate 24 constitute a flow rate adjusting unit 25 that can change the gas flow rate. That is, as shown in FIG. 3, the slide closing member 22 and the flow rate adjusting plate 24 are relatively slidably provided in a state of being pressed by the spring 26 in a state of shielding the gas flow path, and the stepping motor 19 is driven. As shown in FIG. 4, the number of adjustment holes 23 of the flow rate adjustment plate 24 in which the insertion holes 21 formed in the slide closure 22 are overlapped and adjusted while the slide closure 22 is slid. Even if the number of the holes 23 is the same, the gas supply amount can be changed and adjusted by changing the opening area. The slide movement amount of the slide closing member 22 is detected by a slide movement detection sensor 27.

  Next, the configuration of the manual operation unit S will be described. On the front side of the gas stove, as a manual operation unit S, there are three heating state adjusting units 28 for commanding ignition, extinguishing and fire power adjustment to the standard burner 1a, small burner 1b and high thermal burner 1c, respectively. A setting input panel 45 for instructing cooking settings and a setting input panel 46 for instructing the grill burner 2 to ignite and extinguish and adjust the heat power are provided. Since the three heating state adjusting units 28 have the same configuration, the configuration of the heating state adjusting unit 28 for the standard burner 1a will be described as a representative, and the description of the other components will be omitted.

  As shown in FIG. 5, a cylindrical rotation operation unit 31 is provided in a state of being inserted from the back side through an insertion hole 30 formed in the front panel 29 of the gas stove, and this rotation operation unit 31 is provided by a position holding mechanism (not shown). Each time a pressing operation is performed, the front panel 29 is configured to be switchable between a non-operating state that is flush or substantially flush with the front panel 29 and an operating state that protrudes forward, and the rotation operation unit 31 is switched to the operating state. In addition, it is configured such that it can be rotated in each of the forward rotation direction and the reverse rotation direction. An ignition switch 32 is provided inside the front panel 29. The ignition switch 32 is turned off when the rotation operation unit 31 is in an inactive state and turned on when the rotation operation unit 31 is in an operation state. The switching signal of the ignition switch 32 is input to the control unit H. The control unit H starts the ignition operation for the standard burner 1a when the ignition switch 32 is switched on, and the standard when the switch is switched off. The combustion operation of the burner 1a is stopped. Therefore, in this embodiment, the ignition switch 32 corresponds to a point fire extinguishing command means for the standard burner 1a. Similarly, the ignition switch 32 corresponds to the fire extinguishing command means for the other burners 1b and 1c.

In addition, a rotary encoder 33 that outputs a pulse signal in accordance with the rotation operation of the rotation operation unit 31 is provided in the front panel 29. That is, the rotary operation unit 31 is connected to the operation shaft 34 of the rotary encoder 33 so as to be rotatable together and allow relative movement in the axial direction. The rotary encoder 33 will be briefly described. The rotary encoder 33 includes two output terminals, and is configured to output pulse signals having different phases from the two output terminals. The phase of one of the two pulse signals A and B advances from the other pulse signal with the rotation operation in the direction, and the other pulse signal with the rotation operation in the other direction of the rotation operation unit 31. Is configured to output two pulse signals having different phases in accordance with the rotation operation of the rotation operation unit 31 in a state in which the phase advances from the one pulse signal. Then, the control unit H determines the rotation operation direction and the rotation operation amount of the rotation operation unit 31 based on the pulse signal output from the rotary encoder 33, and makes the rotation operation direction and the rotation operation amount correspond to the determined rotation operation direction and rotation operation amount. Thus, the heating amount of the standard burner 1a is adjusted.
Accordingly, the rotation operation unit 31, the ignition switch 32, and the rotary encoder 33 constitute a heating state adjustment unit 28 for the standard burner 1a. Similarly, the heating state adjusting unit 28 is configured for the other burners 1b and 1c, and the heating amount is adjusted in the same manner.

  As shown in FIG. 8, the setting input panel 46 is constituted by a push-operated switch and switches between an on state in which ignition is commanded to the grill burner 2 and an off state in which extinguishing is commanded each time a push operation is performed. An ignition switch 32 is provided. In addition, although not described in detail, other than that, a timer setting unit 47 for setting cooking time, a thermal power changeover switch 48 for switching the combustion state of the upper surface burner 2a and the lower surface burners 2b and 2c, and switching the combustion state according to the menu There are provided a menu switch 49, a switch 50 for adjusting baking, a switch 51 for canceling various settings, and the like.

  As shown in FIGS. 6 and 7, a thermal power display unit 36 is provided in a state where a plurality of LED lamps 35 for displaying the heating amount are arranged around each rotation operation unit 31 on the outer surface side of the front panel 29. . The thermal power display unit 36 uses a plurality of LED lamps 35 as a level meter and displays the magnitude of the thermal power (heating amount) set by the rotary operation unit 31 by lighting any one of the LED lamps 35. ing. Further, as shown in FIG. 2, a buzzer 37 is provided as a notification means for notifying various states as described later by voice, and as shown in FIGS. A time display unit 38 for displaying values is provided, and when the ignition process check state is set as will be described later, the remaining time until the ignition process check state is released is obtained, and the remaining time is displayed as a time display unit. 38 is configured to be displayed.

  When the ignition is commanded by the ignition switch 32, the control unit H supplies the fuel to the burner and performs the ignition operation until the thermocouple 8 detects the ignition state. When the ignition switch 32 is instructed to extinguish, the combustion is performed during and after the ignition process. Stop processing for controlling the operation of the igniter 7, the original electromagnetic valve 12, and the flow control valve 18 so as to stop the fuel supply to the burner in any of them and stop the ignition operation during the execution of the ignition processing. Is configured to run.

  In addition, the control unit H supplies the fuel to the burner while the fuel has been supplied to the burner while the thermocouple 8 has not detected the ignition state. However, whether or not the ignition to the burner should be controlled based on the elapsed stop time from when the fuel supply to the burner is stopped without being ignited until the fuel supply is stopped. When the ignition check state is determined, the ignition check process is executed so that the ignition process is not executed regardless of the ignition command from the ignition switch 32.

  Further, when the supply elapsed time becomes longer than the stop elapsed time by the determination setting time, the control unit H is configured to enter the ignition check state until the check standby time elapses from that time. ing. Further, when ignition is instructed by the ignition switch 32 and the ignition process is executed, the stop process is executed when the non-ignition determination time elapses without the thermocouple 8 being detected to be in the ignition state. When the stop process is executed as the non-ignition determination time elapses, the non-ignition determination time is set as the supply elapsed time.

  In addition, when the ignition check process is being performed, the control unit H obtains the remaining time until the ignition check process ends after the check standby time has elapsed, and the remaining time is displayed as a time display unit 38. And a notification process for performing a notification operation of the buzzer 37 when it is determined that the ignition check state has been established. Further, when the ignition check process according to the command of the ignition switch 32 is not executed, a notification process for notifying the buzzer 37 is executed.

  Next, the control operation of the control unit H will be specifically described based on the flowcharts of FIGS. Of the three burner burners 1a, 1b, 1c and the grill burner 2, the control for the standard burner (hereinafter simply referred to as the burner) 1a will be described, and the other burners have the same contents, and the description thereof will be omitted.

  First, it is determined whether or not the ignition switch 32 is on. If it is on, it is determined whether or not the burner 1a is already ignited and burning (steps 1 and 2), and the burner 1a is burning. If not, it is determined whether or not the ignition error flag is on. If not, it is next determined whether or not the ignition operation inhibition mode is set to on (steps 3 and 4). If the ignition operation inhibition mode is not set to ON, it is determined whether or not the original solenoid valve 12 is open. If not, the flow control valve 18 for the burner 1a to which ignition is commanded The stepping motor 19 is rotated so that the opening degree is set to the large side so that the adjustment position detected by the slide movement detection sensor 27 becomes the low thermal power position, and when the low heating power position is reached, the operation of the stepping motor 19 is stopped. Then, the original solenoid valve 12 is switched to the open state (steps 5 to 9).

  After switching the original solenoid valve 12 to the open state, the explosion prevention timer count-up control 1 is executed (step 10). As shown in FIG. 11, the explosion prevention timer count-up control 1 is a process for starting the count-up if the explosion prevention timer is not counting up (steps 100 and 101). Then, the stepping motor 19 is opened so that the adjustment position of the flow control valve 18 becomes the ignition thermal power position, and when the ignition power position is reached, the operation of the stepping motor 19 is stopped and the ignition operation by the igniter 7 is started. (Steps 11-14). After the ignition operation by the igniter 7 is started, if the ignition error detection timer is not in operation, counting by the ignition error detection timer is started, and the output of the thermocouple 8 is 1.8 mV or more and the burner 1a is ignited. If it discriminate | determines, the ignition operation by the igniter 7 will be stopped, an explosion prevention timer will be reset, a count will be stopped, an ignition error detection timer will be reset, and a count will be stopped (steps 15-20).

  After the ignition operation by the igniter 7 is started, the ignition error detection timer is set to the non-ignition determination time T1 (for example, the output of the thermocouple 8 is not 1.8 mV or more and the burner 1a is not ignited). When it is detected that more than 7 seconds have elapsed, the ignition error flag is turned on, and the buzzer 37 is sounded for a predetermined time to notify that it is an ignition error (steps 21 to 23). Then, the ignition error detection timer is reset and the count is stopped (step 20).

If it is determined in step 3 that the ignition error flag is on, if the adjustment position of the flow control valve 18 is not in the closed position, the ignition operation by the igniter 7 is stopped, and the other burners 1b, 1c, If any one of 2 is not in combustion, the original solenoid valve 12 is switched to the closed state, explosion prevention timer countdown control as will be described later is executed, and the adjustment position of the flow control valve 18 is set to the closed position. Then, the stepping motor 19 is closed (steps 26 to 31). On the other hand, if any of the other burners 1b, 1c, 2 is burning in step 28, an explosion prevention timer count-up control 2 as will be described later is executed and the flow control valve 18 is adjusted. The stepping motor 19 is closed so that the position becomes the closed position (steps 34 and 35). When the adjustment position of the flow control valve 18 becomes the closed position, explosion prevention timer countdown control is executed, and the closing operation of the stepping motor 19 is stopped (steps 26, 32, 33).
In this embodiment, the series of operations from Step 5 to Step 23 corresponds to the ignition process, and the operations of Steps 27, 29, 31, 33, and 35 correspond to the stop process.

Next, the explosion prevention timer count-up control 2 will be described.
As shown in FIG. 12, the explosion prevention timer count-up control 2 first starts counting up the explosion prevention timer if the explosion prevention timer is not counting up (steps 200 and 201). Then, if the explosion prevention timer counts up and the timer count is equal to or greater than the determination set time T2 (for example, 7 seconds), the ignition operation prohibition mode is set, and the buzzer 37 continues for a certain period of time. To notify the user that the count value of the explosion prevention timer is the set time for determination T2 (steps 202 to 204).

Next, explosion prevention timer countdown control will be described.
As shown in FIG. 13, this explosion prevention timer countdown control first determines whether or not the ignition operation prohibition mode is set. If not, the timer count value of the explosion prevention timer is determined. It is determined whether or not the set time T2 or more. If the set time T2 for determination or more, the ignition operation inhibition mode is set, and the buzzer 37 is sounded and informed for a predetermined time (step 300). ~ 303). This process corresponds to the notification process. Then, the countdown of the explosion prevention timer is started (step 304). In step 301, when the timer count value of the explosion prevention timer is not equal to or greater than the determination set time T2, if the timer count value is not zero and the count is being executed, the countdown of the explosion prevention timer is started ( Steps 305 and 304). When the timer count value becomes zero and the count is finished, the explosion prevention timer is reset and the count is stopped (step 306).

  If it is determined in step 300 that the ignition operation prohibition mode is set to ON, if the timer count value of the explosion prevention timer is not zero, the explosion prevention timer starts to count down (step 307, 308) When the timer count value becomes zero and the count is stopped, if the ignition operation prohibition timer is not operating, the count by the ignition operation prohibition timer is started (steps 309 and 310). When the count value of the ignition operation prohibition timer exceeds the prohibition state continuation set value T3 (for example, 5 seconds), the ignition operation prohibition mode is turned off and the ignition operation prohibition timer is reset to stop the count (step) 311, 312, 313).

  That is, in this explosion prevention timer countdown control, the explosion prevention timer counts down from when the flow control valve 18 for the burner to which ignition is commanded is in the closed position or when the original solenoid valve 12 is in the closed state. In addition, when the ignition operation prohibition mode is set to ON, the ignition operation is performed until the count value of the explosion prevention timer becomes zero until the count value of the ignition operation prohibition timer reaches the prohibition state continuation set time T3 or more. The prohibition mode is maintained in the on state, and the ignition operation prohibition mode is turned off when the count value reaches or exceeds the prohibition state continuation set time T3.

  Therefore, after the timer count value of the explosion prevention timer is equal to or greater than the set time T2 for determination and the ignition operation inhibition mode is set to ON, the time during which the explosion prevention timer counts down (7 seconds), and the ignition operation inhibition timer The time (12 seconds) that is the sum of the time until the count value reaches the prohibited state continuation setting time T3 (5 seconds) corresponds to the check standby time.

  In this embodiment, the non-ignition determination time T1 for detecting the non-ignition error is set to the same value as the determination set time T2 for the timer count value of the explosion prevention timer, for example, 7 seconds, When the non-ignition error is determined, the ignition operation inhibition mode is set in the subsequent explosion prevention timer countdown control.

The integrated value of the count value counted up by the explosion prevention timer count-up control 1 and the explosion prevention timer count-up control 2 is the integrated value of the elapsed supply time while the fuel is being supplied to the burner 1a. The integrated value of the count value counted down by the explosion prevention timer countdown control corresponds to the integrated value of the elapsed stop time while the fuel supply to the burner 1a is stopped. When the count value of the explosion prevention timer that sequentially changes becomes equal to or longer than the determination set time T2, this corresponds to the supply elapsed time being longer than the stop elapsed time by the determination set time (7 seconds) or more. .
Incidentally, the adjustment position of the flow control valve 18 is the ignition thermal power position from the start of fuel supply to the burner 1a until it is detected that the burner 1a has been ignited, and the fuel for the burner 1a. The supply amount is the set supply amount for ignition.

  When the ignition switch 32 is turned off, the ignition error flag is turned off, the buzzer notification completed flag is turned off, the processing from step 26 is executed, and the explosion prevention timer countdown control as described above is performed. Execute (steps 26 to 35).

  When the ignition switch 32 is turned on again after the ignition switch 32 is turned off, the ignition operation inhibition mode as described above is set to on at that time, and this is determined in step 4. And execute the ignition check process. That is, the remaining time until the end of the ignition check process after the check standby time has elapsed is obtained, and the remaining time is displayed on the time display unit 38 (step 36). If the buzzer notification flag is off, the buzzer 37 is sounded for a predetermined time (steps 37 and 38). This process corresponds to the notification process. Then, the buzzer notification flag is turned on (step 39), and the processing from step 1 to step 4 and step 37 to step 39 is repeatedly executed. Therefore, until the ignition operation prohibition flag is turned off, the ignition process is not executed even when the ignition switch 32 is turned on and ignition is commanded. Such a process corresponds to the ignition check process.

  If it is determined in step 2 that the burner 1a is in combustion, the amount of heating of the burner 1a, specifically, the flow rate of the fuel gas by the flow control valve 18 in accordance with the rotation operation direction and the rotation operation amount of the rotation operation unit 31. The flow rate is changed and adjusted (step 40). That is, the fuel supply to the burner 1a is continuously executed, and the stepping motor 19 is adjusted so that the adjustment position detected by the slide movement detection sensor 27 becomes a position corresponding to the heating power commanded by the rotation operation unit 31. It is rotated.

  In the control as described above, even when the ignition process is not detected by the thermocouple 8 and the ignition switch 32 is operated and the ignition process and the stop process are repeated a plurality of times, the above-described control is performed. Since the explosion prevention timer count-up control 1 and 2 and the explosion prevention timer count-down control are executed, the count values counted up by the explosion prevention timer count-up control 1 and 2 are integrated. The supply elapsed time and the stop elapsed time are integrated over a plurality of times. Similarly, since the count value counted down by the explosion prevention timer countdown control is accumulated for a plurality of times, the count value of the explosion prevention timer that changes sequentially is changed from the supply elapsed time to the stop elapsed time. Can be obtained as a value appropriately reflecting the detention amount of the fuel gas in the unburned state at that time.

  Although the control operation of the control unit H based on the command of the manual operation unit S as described above has been described for the standard burner 1a, the other burners 1b and 1c and the grill burner 2 are similarly performed.

[Second Embodiment]
Next, a second embodiment of the combustion apparatus according to the present invention will be described.
The second embodiment is different in the control configuration of the control unit in the first embodiment, but the other configurations are the same as those in the first embodiment, and thus detailed description thereof is omitted.
In other words, in the first embodiment, the control unit performs the determination process as to whether or not the ignition check state is present after stopping the fuel supply to the burner. In the second embodiment, the ignition check state is not determined by performing the determination process as to whether or not the ignition switch is in the middle of executing the ignition process when the ignition is commanded by the ignition switch 32. When ignition is instructed by the ignition switch 32 in the state and the ignition process is being executed, the stop process is executed if it is determined that the ignition check state is set.

Specifically, in the second embodiment, as the explosion prevention timer count-up control 1 in the first embodiment, a control as shown in FIG. 14 is executed instead of the control shown in FIG. Yes.
That is, not only the timer count-up of the explosion prevention timer is started, but also the explosion prevention timer starts counting up, and the timer count value of the explosion prevention timer is set to the discrimination setting value T2 (for example, 7 seconds). If it is equal to or greater than the set value for determination T2, the ignition error flag is turned on to set the ignition operation prohibition mode to on, and the buzzer 37 is kept for a certain period of time. Is sounded for notification (steps 100 to 105).

  If comprised in this way, even if it is in the middle of performing an ignition process, the process after step 26 of FIG. 9, FIG. 10 in 1st Embodiment will be performed by setting ignition operation prohibition mode to ON. Therefore, the stop operation of the ignition operation by the igniter 7 in step 27, the closing operation of the original electromagnetic valve 12 in step 29, the closing operation of the flow control valve 18 in step 31, and the flow control valve 18 in step 35. The closing operation corresponds to the forced stop process. Also in this embodiment, while the ignition operation inhibition mode is set to ON, even if the ignition switch 32 is turned off and then turned on again, the ignition process is not performed.

[Third Embodiment]
Next, a third embodiment of the combustion apparatus according to the present invention will be described.
Although the control configuration of the control unit in the first embodiment is different in the third embodiment, the other configurations are the same as those in the first embodiment, and thus detailed description thereof is omitted.

In other words, in this third embodiment, the control unit H is the number of times that the stopping process during execution of the pre-Symbol ignition process is set number, the fuel supply is stopped for the burner by the last of the stop process The ignition check process is performed so that the ignition process is not executed even if the ignition is instructed by the point fire extinguishing command means until the check standby time elapses. In addition, a notification process for performing a notification operation of the notification means is performed when the ignition process according to the command of the point fire extinguishing command means is not executed by the ignition check process.

Next, the control operation of the control unit H will be specifically described with reference to a flowchart.
As shown in FIGS. 15 and 16, when it is detected that the ignition switch 32 has changed from the off state to the on state, the ignition prevention timer is not counting and the non-ignition time interval measurement timer is not counting. Control is executed (steps 41 to 44). As shown in FIG. 17, in this ignition control, if the original solenoid valve 12 is not open, the flow control valve 18 is opened to the low heating power position, and then the original solenoid valve 12 is opened. If it is in the open state, the flow control valve 18 is opened to the ignition thermal power position and the igniter 7 is turned on (steps 400 to 404). That is, this ignition control corresponds to the ignition process.

  Then, when the ignition switch 32 is turned off while ignition is not detected by the thermocouple 8, the number of times of non-ignition is counted up (steps 45, 46, 47), and the non-ignition time interval measurement timer is counted. Start and execute fire extinguishing control (steps 48 and 49). This fire extinguishing control is performed as shown in FIG. That is, if the ignition operation is in progress, the igniter 7 is turned off, and if the other burners are not in combustion, the original solenoid valve 12 and the flow rate control valve 18 are closed (steps 500 to 504), respectively. If the burner is in combustion, the flow control valve 18 corresponding to the burner to be controlled is closed (step 505). That is, in this embodiment, the fire extinguishing control corresponds to the stop process.

  If ignition is not detected by the thermocouple 8 and the ignition switch 32 is not turned off, if the non-ignition error detection timer is not activated, counting by the non-ignition error detection timer is started (step 53, 54), when the count value of the non-ignition error detection timer reaches the non-ignition determination time T1, the buzzer 37 is sounded for a predetermined time to notify that a non-ignition error has occurred (steps 55, 56).

  Then, after the ignition switch 32 is turned on, the number n of fire extinguishing operations when the ignition is not detected by the thermocouple 8 or a non-ignition error occurs is the set number of times within the set time. When it is determined that the value is greater than or equal to m, the explosion prevention timer starts counting and resets the misfire error detection timer (steps 50, 51, 52). Note that the non-ignition time interval measured by the non-ignition time interval measurement timer after the previous non-ignition extinguishing operation is performed until the next non-ignition extinguishing operation is performed is the set value T4. If it is in the above state, the count value of the number of times of non-ignition is cleared and the non-ignition time interval measurement timer is also reset (steps 43, 57, 58, 59). This is because there is no possibility of explosion ignition if there is a long time after the ignition switch 32 is turned off and the ignition operation is performed again in a state where ignition is not detected by the thermocouple 8. When ignition is detected by the thermocouple 8 in step 45, the igniter 7 is turned off to stop the ignition operation, and the counter of the number of times of non-ignition is reset to zero (steps 60 and 61).

  If the explosion prevention timer starts counting in step 51, the ignition switch 32 is turned on again. If it is determined in step 42 that the explosion prevention timer is counting, ignition control is executed. Instead, the buzzer 37 is sounded for a predetermined time and the process is returned (step 62). This operation corresponds to the ignition check process, and the operation to sound the buzzer 37 for a certain time corresponds to the notification process. When the ignition switch 32 is turned off, the fire extinguishing control is executed in the same way as in step 49 if the combustion is in progress, and the count value of the explosion prevention timer that is executing the count is equal to or greater than the set time for determination T2. Then, the explosion prevention timer is reset (steps 63 to 68).

  When the ignition switch 32 is not turned off and the burner 1a maintains the combustion state, the amount of heating of the burner 1a, specifically the flow rate, corresponding to the rotation operation direction and the rotation operation amount of the rotation operation unit 31. The flow rate of the fuel gas by the control valve 18 is changed and adjusted (step 69). This state corresponds to the continuous combustion state.

  Therefore, in the third embodiment, the elapsed time from when the explosion prevention timer starts counting until the count value becomes equal to or greater than the determination set time T2 corresponds to the check standby time. Further, in this embodiment, if the number of times of determination “m” in step 50 is set as “a number of 2 or more”, when the number of times of performing the stop process during the execution of the ignition process becomes equal to or greater than the set number of times, Ignition during the period from when the fuel supply to the burner is stopped by the last stop processing until the check waiting time elapses, that is, until the count value of the explosion prevention timer reaches the determination set time T2 or more. Even if the ignition is instructed by the switch 32, an ignition check process is performed in which the ignition process is not executed.

[Another embodiment]
Hereinafter, other embodiments are listed.

(1) In the first embodiment, when the supply elapsed time becomes longer than the stop elapsed time by a set time for determination, a check waiting time set longer than the set time for determination elapses from that time. In the above, the ignition check state is configured. However, the present invention is not limited to this configuration, and the check standby time is set to the same time as the determination set time or set to a time shorter than the determination set time. You can also

(2) In the first embodiment, the non-ignition determination time T1 for detecting a non-ignition error is set to the same value as the determination set time T2 for the timer count value of the explosion prevention timer, for example, 7 seconds. Thus, when a non-ignition error is determined once, the ignition operation inhibition mode is set in the subsequent explosion prevention timer countdown control. The ignition determination time T1 may be set to a time shorter than the determination setting time T2.

(3) In the first embodiment, a supply elapsed time during which fuel is being supplied to the burner in a state where the ignition state detection unit does not detect that the ignition state is detected, and While the fuel is supplied to the burner, the ignition to the burner is suppressed based on the elapsed time of the stop while the fuel supply is stopped in the state where the fuel supply to the burner is stopped without being ignited. Although it was set as the structure which discriminate | determines whether it is the ignition check state which should be performed, it may replace with such a structure and may be comprised as follows.

  Whether or not an ignition check state is established using the fuel supply amount during the fuel supply to the burner instead of the supply elapsed time during the fuel supply to the burner. It may be configured to discriminate. For example, instead of obtaining an integrated value for the elapsed supply time for supplying fuel to the burner, the fuel supply amount actually supplied to the burner is sequentially calculated during the supply elapsed time for supplying fuel to the burner. The time integral value of the fuel supply amount may be calculated while the supply elapsed time is detected.

(4) In the first embodiment, when the ignition check state is set, the remaining time of the standby time for checking is obtained and the remaining time is displayed on the time display unit. In addition to displaying the time, the remaining time may be notified by voice. Moreover, it is good also as a structure which does not display such remaining time.

  In the third embodiment, the configuration in which the process of displaying the remaining time on the time display unit as described above is exemplified, but the process of displaying the remaining time of the waiting time for checking on the time display unit is executed. It is good also as a structure.

(5) In the first embodiment, when it is determined that the ignition check state has been established, and when ignition is commanded by the point fire extinguishing command means during execution of the ignition check process, the notification means is used. However, instead of such a configuration, a notification process is performed only when it is determined that the ignition check state has been established, or the ignition check process is being executed. In this case, the notification processing may be performed only when ignition is commanded by the point fire extinguishing command means.

(6) In the third embodiment, when the stop process is performed during the execution of the ignition process, fuel is supplied to the burner in a state where the ignition state detection unit does not detect the ignition state. Although the ignition check process is performed regardless of the length of the supply elapsed time during the period when the ignition is performed, the following configuration may be used instead of such a configuration.
For example, to set before Symbol determination number of times "m" as the value of 2 or more, when the set number of times of execution of the stop processing during the ignition process execution, the fuel supply to the burner by the last of the stop process In the case where the ignition check process is performed until the check waiting time elapses after the engine is stopped, fuel is supplied in an unignited state in each of the set stop processes. It can be implemented in various forms such as not performing the ignition check process when the sum of the set number of elapsed supply times is shorter than the preset allowable time for the set number of times. .

(7) In each of the above embodiments, the case of a gas stove is illustrated as the combustion device. However, the present invention is not limited to the gas stove, and is applicable to various combustion devices such as a gas combustion type rice cooker and a gas combustion type hot water supply device. can do.

Gas stove perspective view Control block diagram Cross section of flow control valve The figure which shows the flow adjustment state of the flow control valve Cross-sectional view of the heating state adjuster A perspective view of the heating state adjustment unit Front view of heating state adjuster Front view of setting input panel for grill Flowchart of control operation of the first embodiment Flowchart of control operation of the first embodiment Flowchart of control operation of the first embodiment Flowchart of control operation of the first embodiment Flowchart of control operation of the first embodiment Flowchart of control operation of the second embodiment Flowchart of control operation of the third embodiment Flowchart of control operation of the third embodiment Flowchart of control operation of the third embodiment Flowchart of control operation of the third embodiment

Explanation of symbols

1a, 1b, 1c, 2 Burner 7 Ignition means 8 Ignition state detection means 18 Fuel supply state adjustment means 32 Point fire extinguishing command means 37 Notification means H Control means

Claims (8)

Gas combustion type burner, ignition means for performing an ignition operation on the burner, fuel supply state adjusting means capable of changing and adjusting the fuel supply state to the burner, and point-extinguishing command means for commanding ignition and extinguishing of the burner And an ignition state detection means for detecting whether or not the burner is in an ignition state, and a control means for controlling the operation of the ignition means and the fuel supply state adjustment means,
The control means is
When ignition is commanded by the point fire extinguishing command means, fuel is supplied to the burner, and the ignition operation is performed until the ignition status detecting means detects that the ignition status is detected. And an ignition process for controlling the operation of the ignition means and the fuel supply state adjusting means, and
When fire extinguishing is instructed by the point fire extinguishing command means, the fuel supply to the burner is stopped both during the execution of the ignition process and during the subsequent combustion, and the ignition operation is performed during the execution of the ignition process. A combustion apparatus configured to execute a stop process for controlling the operation of the ignition means and the fuel supply state adjusting means,
The control means is
When the ignition is instructed by the point fire extinguishing command means and the ignition process is being executed, if the non-ignition determination time elapses without the ignition state detecting means being detected as being in the ignition state, Configured to perform stop processing, and
After the ignition is commanded by the point fire extinguishing command means and fuel supply to the burner is started, the fire extinguishing command means extinguishes the fire in a state where the ignition state detecting means does not detect the ignition state. When the fuel supply to the burner is stopped , the fuel supply amount or the supply elapsed time obtained by integrating the fuel supply amount or the supply elapsed time while the fuel supply is being performed to the burner When the ignition is instructed by the point fire extinguishing command means and fuel is supplied to the burner, it remains unignited, and the fire extinguishing is instructed by the point extinguishing command means and the fuel supply to the burner is stopped. stop time elapsed between maintained in the stop state of the fuel supply based on the stop elapsed time obtained by integrating from the said fuel supply amount or the supply time elapsed The relationship between the stop elapsed time, Until the elapse of the check for configuration elapsed time to determine whether or not the ignition restraint condition to be restraining the ignition for the burner, when determining that the a spark restraining state The combustion apparatus is configured to perform an ignition check process in which the ignition process is not executed regardless of an ignition command from the point-extinguishing command means until the check set elapsed time elapses . Gas combustion type burner, ignition means for performing an ignition operation on the burner, fuel supply state adjusting means capable of changing and adjusting the fuel supply state to the burner, and point-extinguishing command means for commanding ignition and extinguishing of the burner And an ignition state detection means for detecting whether or not the burner is in an ignition state, and a control means for controlling the operation of the ignition means and the fuel supply state adjustment means,
The control means is
When ignition is commanded by the point fire extinguishing command means, fuel is supplied to the burner, and the ignition operation is performed until the ignition status detecting means detects that the ignition status is detected. And an ignition process for controlling the operation of the ignition means and the fuel supply state adjusting means, and
When fire extinguishing is instructed by the point fire extinguishing command means, the fuel supply to the burner is stopped both during the execution of the ignition process and during the subsequent combustion, and the ignition operation is performed during the execution of the ignition process. A combustion apparatus configured to execute a stop process for controlling the operation of the ignition means and the fuel supply state adjusting means,
The control means is
When the ignition is instructed by the point fire extinguishing command means and the ignition process is being executed, if the non-ignition determination time elapses without the ignition state detecting means being detected as being in the ignition state, Configured to perform stop processing, and
After the ignition is commanded by the point fire extinguishing command means and fuel supply to the burner is started, the fire extinguishing command means extinguishes the fire in a state where the ignition state detecting means does not detect the ignition state. When the fuel supply to the burner is stopped, the fuel supply amount or the supply elapsed time obtained by integrating the fuel supply amount or the supply elapsed time while the fuel supply is being performed to the burner When the ignition is instructed by the point fire extinguishing command means and fuel is supplied to the burner, it remains unignited, and the fire extinguishing is instructed by the point extinguishing command means and the fuel supply to the burner is stopped. stop time elapsed between maintained in the stop state of the fuel supply based on the stop elapsed time obtained by integrating from, than the supply elapsed time is the stop lapse time If longer than another setting period, its until the waiting time has elapsed for supervision from the time to determine that the ignition restraint condition to be restraining the ignition for the burner, when determining that the a spark restraining state, A combustion apparatus configured to perform an ignition check process in which the ignition process is not executed regardless of an ignition command from the point fire extinguishing command means until the check set elapsed time elapses . It said control means, before SL is when executing the stop processing with the elapses misfire determination time, according to claim 1 or 2, wherein is composed of the misfire determination time to the said supply elapsed time Combustion equipment. The control means is
When the ignition is instructed by the point fire extinguishing command means and the ignition process is being executed in a state where the ignition check state is not determined, the stop process is executed if it is determined that the ignition check state is in effect The combustion apparatus of any one of Claims 1-3 comprised. The control means is
When the ignition check process is being performed, the remaining time until the ignition check process ends after the check standby time has elapsed is determined, and the remaining time is displayed on the time display unit. The combustion apparatus according to any one of claims 2 to 4. Gas combustion type burner, ignition means for performing an ignition operation on the burner, fuel supply state adjusting means capable of changing and adjusting the fuel supply state to the burner, and point-extinguishing command means for commanding ignition and extinguishing of the burner And an ignition state detection means for detecting whether or not the burner is in an ignition state, and a control means for controlling the operation of the ignition means and the fuel supply state adjustment means,
The control means is
When ignition is commanded by the point fire extinguishing command means, fuel is supplied to the burner, and the ignition operation is performed until the ignition status detection means detects that the ignition status is detected. An ignition process for controlling the operation of the ignition means and the fuel supply state adjustment means is executed, and
When fire extinguishing is instructed by the point fire extinguishing command means, the fuel supply to the burner is stopped both during the execution of the ignition process and during the subsequent combustion, and the ignition operation is performed during the execution of the ignition process. A combustion apparatus configured to execute a stop process for controlling the operation of the ignition means and the fuel supply state adjusting means,
The control means is
When the ignition is instructed by the point fire extinguishing command means and the ignition process is being executed, if the non-ignition determination time elapses without the ignition state detecting means being detected as being in the ignition state, Configured to perform stop processing, and
The number of times that the fire extinguishing is commanded by the point fire extinguishing command means during the ignition process and the stop process is performed, and the number of times that the non-ignition determination time elapses and the stop process is performed during the ignition process. If the total number is the set count and until the elapse of the check for the waiting time after the fuel supply is stopped for the burner by the last of the stop process, be ignited commanded by the point extinguishing command means the A combustion apparatus configured to perform an ignition check process that does not execute an ignition process.   The control means according to any one of claims 1 to 5, wherein the control means is configured to execute a notifying process for notifying the notifying means when it is determined that it is in an ignition suppression state in which ignition to the burner is to be suppressed. The combustion apparatus according to Item 1.   The control unit according to claim 1, wherein the control unit is configured to execute a notification process that causes the notification unit to perform a notification operation when the ignition suppression process does not execute the ignition process according to the command of the point fire extinguishing command unit. The combustion apparatus of any one of them.

Images