KR970001939B1 - Combustion system - Google Patents

Abstract

A combustion system is disclosed. When the test switch(550) is pressed, the mode control circuit(55) converts the operation mode of a fan heater from a normal operation mode to a test mode. During the test mode, when the gas switch(551), a proportional valve switch(552), or the fan Lo/Hi switches(553,554) are pressed, the test mode is converted to a Lo/Hi side extinction determination level adjusting and writing mode, a proportional valve current adjusting and writing mode, or a Lo/Hi side current adjusting and writing mode. Thus, incorrect adjustment data is prevented from being stored in a semiconductor non-volatile memory.

Description

Combustion device

1 is a structural diagram of a gas warm air heater according to an embodiment of the present invention.

2 is a block diagram of the gas warm air heater.

3 is a flowchart for explaining the operation of the control unit of the gas warm air heater.

4 is a flowchart for explaining the operation of the control unit of the gas warm air heater.

5 is a flowchart for explaining the operation of the control unit of the gas warm air heater.

6 is a flowchart for explaining the operation of the control unit of the gas warm air heater.

7 is a flowchart for explaining the operation of the control unit of the gas warm air heater.

* Explanation of symbols for main parts of the drawings

R: Gas hot air heater (combustion device) 3: Proportional valve (combustion actuator)

42: motor (combustion actuator) 52: proportional valve drive circuit (control circuit)

53: fan control circuit (control circuit) 54: misfire detection circuit (safety circuit)

55 mode control circuit

56: E ² PROM (Semiconductor Nonvolatile Memory)

511: temperature setting switch (+) (adjustment means)

512: temperature setting switch (-) (adjustment means)

550: test switch (test mode setting switch)

551: gas switch (write mode setting switch)

552: Proportional valve switch (write mode setting switch)

553: Fan Lo switch (write mode setting switch)

554: fan Hi switch (write mode setting switch)

561: writing circuit 562: reading circuit

The present invention relates to a combustion apparatus of the type for storing adjustment data in a semiconductor nonvolatile memory.

Conventionally, a DIP switch and a semi-fixed VR have been used for adjustment of misfire determination level, adjustment of fan rotation speed, and adjustment of proportional valve current in a warm air heater.

However, since the DIP switch usually has only a capacity of about 4 to 7 circuits, the adjustment value cannot be adjusted accurately, and when used several times for accurate adjustment, a large amount of space is required and at the same time, the parts cost is high. In addition, the perturbation piece is moved by the vibration of the semiconductor VR, and the adjustment value is changed.

Therefore, the present inventors shifted to the adjustment sword writing mode in which the adjustment and writing mode setting switch is pressed in the normal operation mode, and the misalignment determination level, the fan current and the proportional valve current can be adjusted by adjusting means. The adjustment data about the adjustments resulted in a warm air heater stored in a semiconductor nonvolatile memory (E ² PROM).

However, in the above-mentioned hot air heater, when the adjustment and writing mode setting switch is pressed, the control unit suddenly switches to the adjustment and writing mode from the normal operation mode. An unreasonable point was found. In addition, if operation is performed while storing incorrect adjustment value data in the E ² PROM, normal operation is not performed and comfort is impaired.

SUMMARY OF THE INVENTION An object of the present invention is a combustion apparatus of a type in which an adjustment value data relating to an adjustment value of a safety circuit or a control circuit for controlling a combustion actuator is stored in a semiconductor nonvolatile memory, whereby an operator inputs wrong adjustment data to the semiconductor nonvolatile memory. To prevent them from being stored.

In order to solve the above problems, the present invention provides an adjustment means for adjusting an adjustment value of a control circuit for controlling a safety circuit or a combustion actuator, a nonvolatile memory on the peninsula where adjustment value data can be electrically rewritten, and an adjustment means. A write circuit converting the adjusted adjustment value into adjustment value data and storing it in the semiconductor nonvolatile memory, and a readout circuit that reads and converts the adjustment value data stored in the semiconductor nonvolatile memory to be the adjustment value of the safety circuit or control circuit. And a test mode for adjusting the operation state in which the adjustment means and the writing circuit are prohibited and the readout circuit is operated or in which the operation of the adjustment means and the writing circuit is prohibited and the adjustment of the combustion actuator is performed. A mode control circuit in any one of a write mode for activating the means and the write circuit, and the mode control A test mode setting switch and a write mode setting switch electrically connected to the furnace, and when the mode control circuit is operated during the normal operation mode, the operation state of the combustion device is transferred to the test mode and the test mode is changed. When the operation of the write mode setting switch is performed, a configuration is adopted in which the mode is shifted to the write mode.

In the normal operation mode, the readout circuit reads out adjustment value data stored in the semiconductor nonvolatile memory, converts the adjustment value data into the adjustment value, and the safety circuit monitors safety based on the adjustment value, and the control circuit controls the combustion actuator.

When the adjusting operator operates the test mode setting switch, the adjusting apparatus performs the adjustment of the combustion actuator so that the combustion apparatus moves from the normal operation mode to the test mode.

If the operator operates the write mode setting switch during the test mode, the combustion apparatus enters the write mode, where the operator adjusts the adjustment of the safety circuit or the control circuit by the adjustment means. The write circuit converts the adjustment value into adjustment value data and stores it in the semiconductor nonvolatile memory.

The operator shifts the test mode setting switch from the normal operation mode to the test mode, and then enters the write mode in which the adjustment value data can be stored in the semiconductor nonvolatile memory only when the write mode setting switch is operated.

By doing so, it is possible to greatly reduce the possibility that wrong adjustment value data is stored in the semiconductor nonvolatile memory due to an incorrect operation by an operator or the like.

An embodiment of the present invention will be described with reference to FIGS. 1 to 7.

As shown in FIG. 1, the gas warm air heater R includes a gas combustor 1 combusting at a combustion level of 1 to 8 speeds, a thermocouple 2 for detecting abnormal combustion, and a gas combustor 1 Control to control the proportional valve (3) for adjusting the amount of gas supplied to the gas, the convection fan (4) for supplying combustion air to the gas combustor (1), the proportional valve (3), the convection fan (4), and the like. The unit 5 is provided. In addition, 6 is a heater housing, 61 is an air induction path which guides indoor air K to the gas combustor 1, 611 is a dummyster which detects room temperature, and 7 is a gas pipe. The gas combustor 1 includes a combustion plate 11 made of ceramics, a combustion body 12 in which a spatter sp or a thermocouple 2 is disposed, and a nozzle disposed below the air induction path 61 ( It consists of the mixing chamber 13 which mixes the gas g blown out from 7) and the indoor air K guide | induced by the air flow path 61. As shown in FIG.

The thermocouple 2 is disposed in close proximity to the upper surface of the combustion plate 11 and is exposed to the flame to be burned to send out an electrical output according to the combustion state of the gas combustor 1.

The proportional valve 3 is a valve for adjusting the gas amount of the gas g ejected from the nozzle 7 and the amount of passing gas increases in proportion to the energization amount.

The convection fan 4 consists of the impeller 41 pivotally mounted in the duct 67 downstream of the gas combustor 1, and the motor 42 which drives the impeller 41. As shown in FIG. The gas pipe 7 sequentially arranges the solenoid valves 71 and 72 and the proportional valve 3 from the upstream side and is connected to the nozzle 7.

The proportional valve 3 also has a gas governor for keeping the secondary gas pressure constant and a gas amount adjusting screw for adjusting the gas supply amount at the combustion level 1 speed.

The heater housing 6 is provided with the suction inlets 64 and 65 of the indoor air K used for mixing and combustion in the upper upper part, and the blowout outlet 66 is provided in the lower part of the front surface. The suction holes 64 and 65 are freely detachable from the filter 60 for removing dust in the room, and the louver 661 is attached to the blowout port 66 to change the blowing direction of the warm air W. It is. In addition, 67 is a duct which communicates the suction port 65 and the blowout port 66. As shown in FIG.

As shown in FIG. 2, the control unit 5 includes a combustion amount determining circuit 51, a proportional valve driving circuit 52, a fan control circuit 53, a misfire detection circuit 54, a mode control circuit 55, and E. ^{2, a} PROM 56, a write circuit 561, a read circuit 562, an operation control circuit 57, and a notification circuit 58 are provided.

In the normal operation mode, the combustion amount determining circuit 51 burns on the basis of the difference between the set temperature set by the temperature setting switches 511, 512 (+) and (-) and the room temperature detected by the dummyster 611. Determine the level (1st to 8th speed).

In the test mode, the combustion level is fixed at 1 speed to adjust the gas volume adjustment screw.

When adjusting and writing the proportional valve current, and adjusting the fan Hi speed, the combustion level is fixed at 7 speeds and the fan Lo speed is adjusted to 1 speed.

The proportional valve driving circuit 52 is each proportional valve current value at 1 to 6 speeds and 8 speeds based on the proportional valve current adjustment value at 7 speeds read out from the E ² PROM 56 by the reading circuit 562. Determine. In the normal operation mode, the proportional valve current corresponding to the combustion level determined by the combustion amount determination circuit 51 is sent to the proportional valve 3.

The fan control circuit 53 controls the fan currents at the 2nd to 6th speeds and 8th speeds based on the fan current values at the 1st and 7th speeds read out from the E ² PROM 56 by the readout circuit 562. Decide In the normal operation mode, the fan current corresponding to the combustion level determined by the combustion amount determining circuit 51 is sent to the motor 42.

The misfire detection circuit 54 performs the gas combustor 1 when the magnitude of the electric output transmitted by the thermocouple 2 does not reach the Lo-side and Hi-side narrative determination levels described below corresponding to each combustion level group. Is judged to be in an abnormal combustion state (oxygen-depleted combustion, misfire) and transmits a misfire detection signal to the operation control circuit 57.

The mode control circuit 55 tests the operation state of the gas hot air heater R in the normal operation mode by the pressure of the test switch 555 on the substrate set in the test mode (a normally open push switch that closes only when pressed). Understand the mode and fix the combustion level at 1 speed. In the test mode, each adjustment value is not adjusted or the adjustment value data is written to the E ² PROM 56, but the gas supply amount adjustment at the combustion level 1 speed is performed by turning the gas amount adjustment screw.

In the test mode, the gas switch 551, the proportional valve switch 552, the fan Lo switch 553, and the fan Hi switch 554 on the board which are the write mode setting switches are always open-type push switches. The operating state of the gas hot air heater (R) in the test mode is adjusted and written mode of the Lo side and Hi side misfire determination level, respectively, by the pressure of the proportional valve current adjustment and writing mode, fan Lo speed adjustment and writing mode, and fan Hi rotation speed. The control and the writing mode are shifted to fix the combustion levels at predetermined speed numbers, respectively.

In addition, the gas switch 551 and the proportional valve switch 552 in the adjustment and writing mode of the Lo side and Hi side misfire measurement levels, the proportional valve current adjustment and writing mode, the fan Lo rotation speed adjustment and writing mode, and the fan Hi rotation speed adjustment and writing mode, respectively. By the repressurization of the fan Lo switch 553 and the fan Hi switch 554, the write circuit 561 converts each adjustment value into adjustment value data and stores it in the E ² PROM 56, and the mode control circuit 55 ) Transfers the operation mode of the gas warm air heater R to the normal operation mode (in the case of adjustment and writing mode of misfire determination level) or test mode (in the case of another adjustment and writing mode).

In the normal operation mode, the mode control circuit 55 prohibits the adjustment operation of each adjustment value and the operation of the write circuit 561 by the temperature setting switches 511, 512 (+) (-).

In this mode, the temperature setting switches 511, 512 (+) (-) are used to increase or decrease the set temperature. In the test mode, the mode control circuit 55 prohibits the adjustment operation of each adjustment value by the temperature setting switches 511 (512) (+) (-) and the operation of the write circuit 561.

In the adjustment and writing mode of the Lo side and Hi side misfire determination level, the proportional valve current adjustment and the writing mode, the fan Lo rotation speed adjustment and the writing mode, and the fan Hi rotation speed adjustment and the writing mode, the mode control circuit 55 is a temperature setting switch ( Setting of Lo and Hi side misfire determination levels for each combustion level group of 1st to 2nd speed and 3rd to 8th speed by 511) (512) (+) (-) and adjustment of proportional valve current at 7th speed Then, the fan current is adjusted at the 1st and 7th speeds, and the write circuit 561 is operated.

Number E ² PROM (56) having a capacity of K bits rewritable number of times sikineunde stores the adjustment value data by measuring the electric charge in the gate to form a Floating gate in the insulating material of SiO _2, and by using the tunnel effect is 10 ⁵ or more times The retention period is characterized by more than 10 years. The adjustment value data stored in the E ² PROM 56 relates to the Lo side and Hi side misfire determination levels, to the proportional valve current at 7 speed, and to the fan current at 1 speed and 7 speed. .

The write circuit 561 adjusts the Lo side and Hi side misfire determination level and the adjustment value of the proportional valve current at 7 speed or the fan current of the convection fan 4 at 1 speed and 7 speed in each adjustment and write mode. The circuit converts the stationary data into the E ² PROM 56.

The readout circuit 562 reads out each adjustment value data written to the E ² PROM 56 in all modes, and realizes the Lo side and Hi side misfires at the combustion amounts of 1 to 2 speeds and 3 to 8 speeds. It is converted into the adjustment value of the proportional valve current at the determination level and the 7th speed and the fan adjustment current value at the 1st speed and 7th speed, and sent to the misfire detection circuit 54, the proportional valve drive circuit 52, and the fan control circuit 53. do.

The operation control circuit 57 controls the solenoid valves 71 and 72 and the louver motor 572 when the operation switch 571 is turned on to bring the gas combustor 1 into a combustion state. do. In addition, when the misfire detection signal is input from the misfire detection circuit 54, the gas combustor 1 is stopped.

The notification circuit 58 has a gas lamp 581, a proportional valve lamp 582, a fan Hi lamp 583, and a fan Lo lamp 584 based on the respective control information signals inputted from the respective control circuits. Excreted above). Indicator (585) (4-digit 7-segment LED). Buzzer 586 and combustion monitor lamps (weak, medium, steel, grade) 587 are controlled.

Next, the operation of adjusting and writing the Lo side and Hi side misfire determination level of the gas warm air heater R, the proportional valve current adjusting and writing at the 7th speed, the fan Lo at the 1st speed and the 7th speed, and the Hi rotation speed adjusting and writing are performed. It demonstrates with the flowchart of FIGS. 3-7.

If the pressure of the test switch 550 is determined (YES at step s2) in the normal operation mode (Yes at step s2), the flow advances to step s3. If the pressure is not determined (NO at step s2), the flow returns to step s1 for normal operation. Continue to the mode.

Upon entering the test mode in step s3, the combustion level is fixed at one speed. In addition, the gas supply amount is adjusted during the loop in the test mode (NO to step s24 to NO to step s36 to NO → step s36 to NO → step s36 to NO → step s3 to NO → step s8 from NO to step s6). Is performed by a gas amount adjusting screw.

If it is determined in step S4 that the ON / OFF of the operation switch 571 is determined to be OFF (YES), the flow proceeds to step S5, at which time the gas warm air heater R is normally stopped. If it is determined to be ON (NO), the flow proceeds to step s6.

In step s6, it is determined whether or not there is an error (YES), and if there is an error (YES), the flow proceeds to step s7, where the gas warm air heater R is normally stopped. If it is determined that there is no abnormality (NO), the flow proceeds to step s8.

If the pressure of the gas switch 551 is determined in step s8, and the pressure is determined (YES), the process proceeds to step s9. If the pressure is not determined (NO), the process proceeds to step s24.

In step s9, the Lo side and Hi side misfire determination levels are shifted to the adjustment and write mode, the buzzer is driven a predetermined number of times, and the gas lamp 581 is turned on.

In step s10, if the pressure condition of the temperature setting switch 511 (+) is discriminated and pressure is determined (YES), the process proceeds to step s11. If pressure is not determined (NO), the process proceeds to step s17.

In step s11, the display of the Hi side misfire determination level to the display 585 is started (displayed in the left two digits), and the flow proceeds to step s12.

If the pressure of the gas switch 551 is determined in step s12, and the pressure is determined (YES), the flow proceeds to step s13. If the pressure is not determined (NO), the flow proceeds to step s14.

In step s13, the adjustment value data relating to the Hi side misfire determination level is written to the E ² PROM 56, the gas lamp 581 is turned off, and the flow returns to step s1 to the normal operation mode (display of the misfire determination level). Is replaced by a time indicator).

In step s14, if the pressure situation of the temperature setting switch 511 (+) is discriminated and pressure is determined (YES), the flow proceeds to step s15, and if pressure is not determined (NO), the flow proceeds to step s16.

Whenever the pressure of the temperature setting switch 511 (+) is pressed in step s15, the indication of the Hi side misfire determination level is changed from 12 mV (X) to 14 mV (Y) to 16 mV (Z) to 12 mV (X). … The flow returns to step s11 by replacing with.

In step s16, if the pressure situation of the temperature setting switch 512 (-) is determined and pressure is determined (YES), the flow proceeds to step s18. If pressure is not determined (NO), the flow returns to step s11.

In step s17, the pressure setting state of the temperature setting switch 512 (-) is determined to determine the pressure (YES). If the pressure is not determined (YES), the process returns to step s10.

In step s18, the display of the Lo side misfire determination level to the display 585 is started (displayed in the right two digits), and the flow proceeds to step s19.

If the pressure of the gas switch 551 is determined in step s19, and the pressure is determined (YES), the flow proceeds to step s20. If the pressure is not determined (NO), the flow proceeds to step s21.

In step s20, the adjustment value data relating to the Lo side misfire determination level is written to the E ² PROM 56, the gas lamp 581 is turned off, and the flow returns to step s1 to the normal operation mode (display of the misfire determination level). Is replaced by a time indicator).

In step s21, if the pressure situation of the temperature setting switch 512 (-) is determined and pressure is determined (YES), the flow proceeds to step s22, and if pressure is not determined (NO), the flow proceeds to step s23.

Whenever the pressure of the temperature setting switch 512 (-) is pressed in step s22, the indication of the Lo side misfire determination level is changed from 12 mV (X ₂ ) to 14 mV (Y ₂ ) to 16 mV (Z ₂ ) to 12 mV (X ₂ ). … And return to step s18.

In step s23, if the pressure situation of the temperature setting switch 511 (+) is determined and pressure is determined (YES), the process returns to step s11, and if pressure is not determined (NO), the process returns to step s18.

If the pressure of the proportional valve switch 552 is determined in step s24, and the pressure is determined (YES), the flow proceeds to step s25. If the pressure is not determined (NO), the flow proceeds to step s36.

In step s25, the control unit shifts to the proportional valve current adjusting and writing mode, drives the buzzer 586 a predetermined number of times, turns the proportional valve lamp 582 on, and then proceeds to step s26.

In step s26, the combustion level is fixed at seven speeds, and the flow proceeds to step s27.

In step s27, the display of the proportional valve current to the indicator 585 is started, and the flow proceeds to step s28.

If the pressure of the proportional valve switch 552 is determined in step s28 and pressure is determined (YES), the flow proceeds to step s29, and if pressure is not determined (NO), the flow proceeds to step s30.

In step s29, the adjustment value data regarding the adjustment value of the proportional valve current at the combustion level 7 speed is written into the E ² PROM 56, the buzzer 586 is driven a predetermined number of times, and the proportional valve lamp 582 is turned off. The flow advances to step s36 to return to the test mode.

In step s30, the pressure setting state of the temperature setting switch 511 (+) is discriminated, and if pressure is determined (YES), the flow proceeds to step s31. If pressure is not determined (NO), the flow proceeds to step s33.

In step s31, it is determined whether or not the correction current value is within 30 mA, and if it is within 30 mA (YES), the flow proceeds to step s32, and if it exceeds 30 mA (NO), the flow returns to step s27 without increasing the proportional valve current.

In step s32, the proportional valve current is increased by 1 mA and the flow returns to step s27.

In step s33, if the pressure situation of the temperature setting switch 512 (-) is determined and pressure is determined (YES), the flow proceeds to step s34. If pressure is not determined (NO), the flow returns to step s227.

In step s34, it is determined whether or not the correction current value is -30 mA or more, and if it is -30 mA or more (YES), the process proceeds to step s35. If it is less than -30 mA, the flow returns to step s27 without decreasing the proportional valve current. .

In step s35, the proportional valve current is reduced by 1 mA and the flow returns to step s27.

In step s36, if the pressing state of the fan Lo switch 553 is determined and pressure is determined (YES), the flow proceeds to step s37, and if pressure is not determined (NO), the flow proceeds to step s49.

In step s37, the process moves to the fan Lo rotation speed adjusting and writing mode, and the buzzer 586 is driven for a predetermined number of times, and the pin Lo lamp 584 is turned on to proceed to step s38.

In step s38, the combustion level is fixed at one speed, and the flow proceeds to step s39.

In step s39, the fan current display to the display 585 is started, and the flow proceeds to step s40.

In step s40, when the pressing state of the fan Lo switch 553 is determined and pressure is determined (YES), the flow proceeds to step s44. If pressure is not determined (NO), the flow proceeds to step s41.

In step s41, if the pressure situation of the temperature setting switch 511 (+) is discriminated and pressure is determined (YES), the flow proceeds to step s42, and if pressure is not determined (NO), the flow proceeds to step s46.

In step s42, it is determined whether or not the correction current value is within 50 mA, and if it is within 50 mA (YES), the flow proceeds to step s43, and when over 50 mA (NO), the flow returns to step s39 without increasing the fan current.

In step s43, the fan current is increased by 1 mA to return to step s39.

In step s44, the adjustment value data relating to the Lo side fan current is written to the E ² PROM 56, the buzzer 586 is driven a predetermined number of times to turn off the fan Lo lamp 584, and then the flow advances to the stem s45.

In step s45, the fan current display is turned off and the flow advances to step s50.

In step s46, the pressure setting state of the temperature setting switch 512 (-) is determined, and if pressure is determined (YES), the flow proceeds to step s47. If pressure is not determined (NO), the flow returns to step s39.

In step s47, it is determined whether or not the correction current value is -50 mA or more, and if it is -50 mA or more (YES), the flow proceeds to step s48.

In step s48, the fan current is reduced by 1 mA and the flow returns to step s39.

In step s49, if the pressure of the test switch 550 is determined and pressure is not determined (NO), the flow returns to step s3 to maintain the test mode. If pressure is determined (YES), the flow returns to step s1 to exit the test mode and shift to the normal operation mode.

In step s50, when the pressure of the fan Hi switch 554 is determined and pressure is determined (YES), the flow proceeds to step s51.

In step s51, the system enters the fan Hi rotation speed adjusting and writing mode, drives the buzzer 586 for a predetermined number of times, turns the fan Hi lamp 583 on, and then proceeds to step s52.

In step s52, the combustion level is fixed at seven speeds, and the flow proceeds to step s53.

In step s53, display of the fan current to the display 585 is started, and the flow proceeds to step s54.

In step s54, the pressure setting status of the temperature setting switch 511 (+) is determined to determine the pressure (YES), and if the pressure is not determined, the process proceeds to step s55.

In step S55, it is determined whether or not the correction current value is 50 mA or more, and when it is 50 mA or more (YES), the flow proceeds to step s56.

In step s56, the fan current is reduced by 1 mA and the flow returns to step s53.

In step s57, the pressure setting state of the temperature setting switch 512 (-) is determined, and if pressure is determined (YES), the flow proceeds to step s58, and if pressure is not determined (NO), the flow returns to step s60.

At step s58, it is determined whether or not the correction current value is -50 mA or more, and if it is -50 mA or more (YES), the flow proceeds to step s59. If it is less than -50 mA (NO), the flow returns to step s53 without reducing the fan current.

In step s59, the fan current is reduced by 1 mA and the flow returns to step s53.

In step s60, the pressure state of the fan Hi switch 554 is determined, and if pressure is determined (YES), the flow proceeds to step s61, and if pressure is not determined (NO), the flow returns to s53.

In step s61, the adjustment value data relating to the Hi-side fan current is written into the E ² PROM 56, the buzzer 586 is driven a predetermined number of times, the fan Hi lamp 583 is specified, and the flow proceeds to step s62.

In step s62, the fan current display is turned off, and the flow returns to step s49 to enter the test mode.

The gas warm air heater R has the following advantages.

(A) The operator presses the test switch 550, which is a test mode setting switch, shifts the operation state of the gas hot air heater R from the normal operation mode to the test mode, and during the test mode, the gas switch, which is the write mode setting switch, 551, the Lo side, Hi side misfire determination level, the proportional valve current in 7 speeds, and Lo side only when pushing-operating the proportional valve switch 552, the fan Lo switch 553, or the fan Hi switch 554. Shifts to adjustment of fan current on the Hi side and adjustment of the Lo side and Hi side misfire determination level, writable mode, proportional valve current adjustment and write mode, fan Lo speed adjustment and write mode, and fan Hi speed adjustment and write mode It is a constitution.

In other words, when the test switch 550 is pressed in the normal operation mode, the operator can prepare for the adjustment and writing work without performing the adjustment and writing mode immediately. Therefore, it is possible to reduce the possibility that wrong adjustment value data is stored in the E ² PROM 56 due to an incorrect operation by an operator or the like.

(B) The test switch 550, the gas switch 551, the proportional valve switch 552, and the fan Lo-Hi switches 553 and 554 are not directly contacted by the user, and the control unit 5 in the heater housing 6 is not present. Is disposed on the substrate. Therefore, it is safe because the general user does not accidentally convert misfire determination level, proportional valve current, and fan current.

(C) When an operator adjusts the lighting state of the gas lamp 581, the proportional valve lamp 582, the fan Hi lamp 583, or the fan Lo lamp 584 disposed on the substrate, any adjustment and writing mode is currently in effect. It can be determined whether it is selected.

(D) The gas hot air heater R includes adjustment value data on Lo and Hi side misfire determination levels for each combustion level group, adjustment value data on proportional valve current, and adjustment value data on fan current at the time of adjustment and writing. The readout circuit 562 reads these adjustment value data, and stores them in the E ² PROM 56, and misfires the Lo and Hi sides of the misfire detection circuit 54, the proportional valve drive circuit 52, and the fan control circuit 53. It is set as the judgment level, the proportional valve current in 7 speeds, and the fan current in 1 speed and 7 speeds. In addition, in the E ² PROM 56, even if a mechanical shock such as a vibration is applied to the control unit 5, each adjustment value data does not change in structure.

Thus, the misfire determination by the misfire detection circuit 54, the control of the proportional valve current by the proportional valve drive circuit 52, and the reliability of the control of the convection fan 4 by the fan control circuit 53 are excellent.

The present invention includes the following embodiments in addition to the embodiments described above.

a. E ² PROM 56 such as MNOS type or MASO type may be used.

b. In the above embodiment, the E ² PROM 56 stores the adjustment value data of the integer value, but a small numerical value may be stored.

c. When adjusting and writing the proportional valve current, and adjusting the fan Lo and Hi rotation speed, adding the auto ink or auto-creating function to the temperature setting switches 511, 512 (+) and (-) shortens the adjustment time. can do.

For example, if the pressure continues for more than 0.2 seconds, increase or decrease the fan current or proportional valve current by ± 1mA at intervals of 0.1 second.

Claims (1)

Adjusting means for adjusting an adjustment value of a control circuit for controlling a safety circuit or a combustion actuator, a semiconductor nonvolatile memory in which the adjustment value data can be improved electrically, and converting the adjustment value adjusted by the adjustment means into adjustment value data. A write circuit for storing in the semiconductor nonvolatile memory, a readout circuit for reading and converting the adjustment value data stored in the semiconductor nonvolatile memory to be an adjustment value of the safety circuit or the control circuit, the operation mode of the adjustment means and In the normal operation mode in which the operation of the write circuit is prohibited and the readout circuit is operated, or in the test mode in which the operation of the adjustment means and the write circuit is inhibited and the adjustment of the combustion actuator is performed, or the adjustment means and the write circuit are performed. A mode control circuit in any one of the write modes to be operated, and the mode control circuit And a test mode setting switch and a write mode setting switch connected to each other, and when the mode control circuit is operated during the normal operation mode, the operation mode of the combustion device is transferred to the test mode, and the test mode And a write mode when the write mode setting switch is operated.