JPH06213430A - Regulating value setter - Google Patents

Abstract

PURPOSE:To precisely set a regulating value and to eliminate variation of the set value due to vibration, etc. CONSTITUTION:The regulating value setter comprises a gas burner to be burnt at first-eighth speeds, a convection fan for supplying burning air to the burner, a writing circuit 561 for converting fan currents regulated at first.seventh speeds to regulating value data to be stored in an EEPROM 56, a reader 562 for reading the data stored in the EEPROM 56 and converting it to fan currents at the first.seventh speeds, and a fan controller 53 for controlling the fan based on the fan currents at the first.seventh speeds.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an adjustment value setting device for setting an adjustment value.

[0002]

2. Description of the Related Art For example, in a hot air heater, a DIP switch or a semi-fixed VR has been conventionally used for setting a misfire determination level, adjusting a fan rotation speed, and adjusting a proportional valve current.

[0003]

However, the above-mentioned conventional techniques have the following problems. Since the DIP switch usually has a capacity of only about 4 to 7 circuits, the adjustment value cannot be set finely, and when a large number of DIP switches are arranged and used, a large space is required and the parts cost is increased. The set value of the semi-fixed VR changes when the sliding piece moves due to vibration or the like. An object of the present invention is to provide an adjustment value setting device capable of finely setting the adjustment value and not changing the setting value due to vibration or the like.

[0004]

[Means for Solving the Problems] In order to solve the above problems,
The present invention has the following configurations. (1) At the time of setting, setting means for setting an adjustment value of the control circuit, a semiconductor nonvolatile memory in which the adjustment value data is electrically rewritable, and the adjustment value set by the setting means is converted into adjustment value data, The semiconductor non-volatile memory includes a writing circuit, and a read circuit that reads out and converts the adjustment value data stored in the semiconductor non-volatile memory into an adjustment value of the control circuit. (2) A burner with a variable combustion amount, a combustion detection sensor arranged in the vicinity of the burner, level setting means for setting each misfire detection level corresponding to the combustion amount at the time of setting, and adjustment value data. An electrically rewritable semiconductor non-volatile memory, a write circuit for converting the misfire detection level set by the setting means into adjustment value data and storing the adjustment value data, and an adjustment value stored in the semiconductor non-volatile memory. When the data read out, converted and used as the misfire determination level of the misfire detection circuit described below, and the electrical output sent by the combustion detection sensor do not reach the respective misfire determination levels set corresponding to the combustion amount. , A misfire detection circuit for determining that the burner is in an abnormal combustion state. (3) A burner with a variable combustion amount, a proportional valve for adjusting the amount of gas supplied to the burner, a pressure adjusting device for adjusting the proportional valve current at a predetermined combustion amount at the time of setting, and the adjustment value data is electric. Rewritable semiconductor nonvolatile memory,
A writing circuit for converting the proportional valve current adjusted by the pressure adjusting means into adjustment value data and storing it in the semiconductor non-volatile memory, and reading the adjustment value data stored in the semiconductor non-volatile memory, converting it and performing a predetermined combustion. And a proportional valve drive circuit for controlling the proportional valve current for each combustion amount based on the proportional valve current for the predetermined combustion amount. (4) A burner having a variable combustion amount, a fan for supplying combustion air to the burner, and a fan rotation speed adjusting means for adjusting each fan current at a predetermined low combustion amount and a predetermined high combustion amount at the time of setting, A semiconductor non-volatile memory in which adjustment value data is electrically rewritable, a writing circuit for converting each fan current adjusted by the fan rotation speed adjusting means into each adjustment value data and storing the adjustment value data in the semiconductor non-volatile memory, and the semiconductor Read each adjustment value data stored in the non-volatile memory,
A read circuit for converting each fan current into a predetermined low / high combustion amount and a fan controller for controlling the fan based on each fan current in the predetermined low / high combustion amount is provided.

[0005]

[Action]

[Claim 1] The setting value of the control circuit is set by the setting means. The writing circuit converts the set value set by the setting means into adjustment value data and stores it in the semiconductor nonvolatile memory. The read circuit reads the adjustment value data stored in the semiconductor nonvolatile memory and converts the adjustment value data into the adjustment value of the control circuit.

[Claim 2] Each misfire detection level corresponding to the amount of combustion is set by the level setting means. The writing circuit converts each misfire detection level set by the setting means into each adjustment value data and stores it in the semiconductor nonvolatile memory. The read circuit reads each adjustment value data stored in the semiconductor nonvolatile memory and converts the adjustment value data to obtain a misfire detection level for each combustion amount. Then, the misfire detection circuit determines that the burner is in the abnormal combustion state when the electrical output sent by the combustion detection sensor does not reach each misfire determination level set corresponding to the combustion amount.

[Claim 3] The proportional valve current at a predetermined combustion amount is adjusted by the pressure adjusting means. The writing circuit is
The proportional valve current at the predetermined combustion amount adjusted by the pressure adjusting means is converted into adjustment value data and stored in the semiconductor nonvolatile memory. The reading circuit reads the adjustment value data stored in the semiconductor nonvolatile memory and converts the adjustment value data into a proportional valve current at a predetermined combustion amount. Then, the proportional valve drive circuit controls the proportional valve current for each combustion amount based on the proportional valve current for the predetermined combustion amount.

[Claim 4] With the rotation speed adjusting means,
Each fan current at a predetermined low combustion amount and a predetermined high combustion amount is adjusted. The writing circuit converts each fan current adjusted by the fan rotation speed adjusting means at a predetermined low combustion amount and a predetermined high combustion amount into each adjustment value data, and stores the adjustment value data in the semiconductor nonvolatile memory. The reading circuit reads each adjustment value data stored in the semiconductor nonvolatile memory and converts the adjustment value data into fan currents at a predetermined low combustion amount and a predetermined high combustion amount. Then, the fan controller controls the fan current in each combustion amount based on each fan current in the predetermined low combustion amount and the predetermined high combustion amount.

[0009]

【The invention's effect】

[Claim 1] Since the adjustment value of the control circuit is stored in the semiconductor nonvolatile memory, the set value data does not change even if a shock such as vibration is applied, and the control performed by the control circuit is excellent in reliability. . In addition, since the semiconductor nonvolatile memory can store a large number of adjustment value data due to its structure, it is possible to set the adjustment values finely.

[Claim 2] The level setting means sets each misfire detection level corresponding to the combustion amount, and the writing circuit converts each misfire detection level into each adjustment value data and stores it in the semiconductor nonvolatile memory. is doing. For this reason, each set value data does not change even if shock such as vibration is applied, so each misfire detection level set corresponding to the combustion amount does not change, and the reliability of misfire determination of the misfire detection circuit is excellent. . Further, since the semiconductor nonvolatile memory can store a large number of adjustment value data due to its structure, it is also possible to set the misfire detection level according to the combustion amount.

[Claim 3] The proportional valve current at a predetermined combustion amount is adjusted by the pressure adjusting means, and the writing circuit converts the proportional valve current into adjusted value data and stores it in the semiconductor nonvolatile memory. . Therefore, even if a shock such as vibration is applied, the set value data does not change.Therefore, the proportional valve current adjusted in accordance with the predetermined combustion amount does not fluctuate, and the proportional valve current control by the proportional valve drive circuit is performed properly. Can be done.

[Claim 4] The fan rotation speed setting means adjusts each fan current at a predetermined low combustion amount and a predetermined high combustion amount, and the writing circuit converts each fan current into each adjustment value data. , Stored in the semiconductor nonvolatile memory.
Therefore, even if a shock such as vibration is applied, each set value data does not change, so the fan speed adjusted corresponding to the predetermined low combustion amount and the predetermined high combustion amount does not change, and the fan controller controls the fan. The current can be controlled accurately.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described with reference to FIGS. As shown in FIG. 1, a gas warm air heater R incorporating an adjustment value setting device includes a gas combustor 1 that burns at a combustion level of 1st speed to 8th speed, a thermocouple 2 that detects abnormal combustion, and a gas combustion. A proportional valve 3 that adjusts the amount of gas supplied to the gas combustor 1, a convection fan 4 that supplies combustion air to the gas combustor 1, and a control unit 5 that controls the proportional valve 3, the convection fan 4, and the like. 6 is a heater housing, 61
Is an air guide path for guiding the indoor air k to the gas combustor 1, 6
Reference numeral 11 is a thermistor for detecting the room temperature, and 7 is a gas pipe.

The gas combustor 1 is a ceramic combustion plate 1.
1, a combustion barrel 12 having a sparker sp and a thermocouple 2, a gas g ejected from a nozzle n arranged downstream of the air guide passage 61, and room air k guided by the air guide passage 61. And a mixing chamber 13 for

The thermocouple 2 is arranged close to the upper surface of the combustion plate 11, is exposed to the combustion flame, and sends out an electric output according to the combustion state of the gas combustor 1.

The proportional valve 3 has a gas g ejected from the nozzle n.
Is a valve for adjusting the amount of gas, and the amount of passing gas increases in proportion to the amount of energization.

The convection fan 4 has an impeller 41 pivotally mounted in a duct 67 downstream of the gas combustor 1, and an impeller 41.
And a motor 42 for driving the.

The gas pipe 7 is provided with solenoid valves 71, 72 and a proportional valve 3 arranged in this order from the upstream side and connected to a nozzle n.
Further, the proportional valve 3 has a gas governor for keeping the secondary side gas pressure constant, and the gas governor is further provided with a gas amount adjusting screw for adjusting the gas supply amount at the first speed combustion level. There is.

The heater housing 6 is provided with suction ports 64, 65 for the indoor air k used for mixing and combustion in the upper part of its rear surface.
The air outlet 66 is provided in the lower part of the front surface. Above suction port 6
A filter 60 for removing dust in the room is detachably attached to the nozzles 4 and 65, and a louver 661 for changing the blowing direction of the warm air w is attached to the blowout port 66. Incidentally, 6
Reference numeral 7 is a duct that connects the suction port 65 and the air outlet 66.

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

In the normal operation mode, the combustion amount determination circuit 51 determines the combustion level (based on the difference between the set temperature set by the temperature setting switches (+) (-) 511 and 512 and the room temperature detected by the thermistor 611. 1st speed to 8th speed). In the test mode, the combustion level is fixed to the first speed because the gas amount adjusting screw is adjusted. Further, when adjusting and writing the POV current and adjusting the fan Hi speed and writing,
The combustion level is fixed at 7th speed and fixed at 1st speed when adjusting the fan Lo rotational speed and writing.

The proportional valve drive circuit 52 determines each proportional valve current value in the first speed to the sixth speed and the eighth speed based on the proportional valve current adjustment value in the seventh speed read out from the E ² PROM 56 by the reading circuit 562. Then, in the normal operation mode, the PO corresponding to the combustion level determined by the combustion amount determination circuit 51
V current is passed through the proportional valve 3.

The fan control circuit 53 determines the fan currents in the second speed to the sixth speed and the eighth speed based on the fan current values in the first speed and the seventh speed read by the read circuit 562 from the E ² PROM 56. Then, in the normal operation mode, a fan current corresponding to the combustion level determined by the combustion amount determination circuit 51 is supplied to the motor 42.

The misfire detection circuit 54, when the magnitude of the electric output sent by the thermocouple 2 does not reach the Lo side and Hi side misfire determination levels, which will be described later, set corresponding to each combustion level group, gas combustion. It is determined that the container 1 is in an abnormal combustion state (oxygen deficiency combustion, misfire), and a misfire detection signal is sent to the operation control circuit 57.

The test mode control circuit 55 shifts to the test mode by pressing a test switch (a normally open push switch that closes only when pressed) 550 on the substrate, and fixes the combustion level at the first speed. In this test mode, the gas supply amount for the first combustion speed is adjusted with the gas amount adjusting screw.

In the test mode, the temperature setting switches (+) (-) 511 and 512 are the gas switches 5 on the substrate.
The level setting means is configured by a cooperative operation with 51, and sets the Lo side and Hi side misfire determination levels for each combustion level group of the first speed to the second speed and the third speed to the eighth speed. Further, the pressure adjusting means is constituted by the cooperative operation with the POV switch 552 on the board to adjust the POV current in the seventh speed. Furthermore, the fan rotation speed Hi / Lo switch 553 on the board,
The fan rotation speed adjusting means is configured in cooperation with 554 to adjust the fan current in the first speed and the seventh speed.

E ² PROM 56 having a capacity of several k bits
Adjusts data by storing a floating gate in an insulator of SiO ₂ and accumulating charges in the gate by utilizing the tunnel effect. In addition, the number of rewritable times is 10 ⁵ or more, and the retention period is 10 years or more.
The adjustment value data stored in the E ² PROM 56 is related to the Lo side / Hi side misfire determination level,
It relates to the proportional valve current in the seventh speed and to the fan current in the first speed and the seventh speed.

The writing circuit 561 converts the Lo side / Hi side misfire determination level, the adjusted value of the POV current in the seventh speed or the fan current of the convection fan 4 in the first speed and the seventh speed into each adjusted value data. It is a circuit for writing to the E ² PROM 56.

The read circuit 562 reads each adjustment value data written in the E ² PROM 56, and determines the Lo-side / Hi-side misfire determination levels at the combustion amounts of the first speed to the second speed and the third speed to the eighth speed, and the seventh speed. The POV current adjustment value in step 1 and the fan adjustment current value in 1st speed and 7th speed are converted to a misfire detection circuit 54, a proportional valve drive circuit 52, and a fan control circuit 53.
Send to.

The operation control circuit 57 includes an operation switch 571.
Is turned on, the bypass solenoid valve 751, the solenoid valves 71 and 72, the sparker sp, and the louver motor 572 are controlled in a predetermined sequence to bring the gas combustor 1 into the combustion state. When the misfire detection signal is input from the misfire detection circuit 54, the gas combustor 1 stops burning.

The notifying circuit 58 is based on each control information signal input from each control circuit, and the gas lamp 581, PO.
V lamp 582, fan Hi lamp 583, fan Lo
Lamp 584 (the above is arranged on the board), indicator 585 (four-digit seven-segment LED), buzzer 58
6 and combustion monitor lamp (weak, medium, strong, sudden) 587
To control.

Next, the Lo side / H of the gas warm air heater R
i-side misfire determination level setting / writing, PO in 7th speed
V current adjustment and writing, fan Lo in 1st speed / 7th speed,
The operation related to the Hi rotation speed adjustment / writing will be described with reference to the flowcharts of FIGS.

During the normal operation mode (step s1), the pressing of the test switch 550 is discriminated (step s2).
If YES is selected, the process proceeds to step s3. If the pressing is not determined (No in step s2), the process returns to step s1.
Continue normal operation mode. In step s3, the test mode is entered and the combustion level is fixed to the first speed. During the loop of this test mode (NO in step s8 → NO in step s24 → NO in step s36 → step s
No. 49), the gas supply amount is adjusted by the gas amount adjusting screw 761. In step s4, the operation switch 5
71 is turned on / off, and is turned off (YE
S) and step s5, the gas warm air heater R is normally stopped. If it is determined to be ON (NO), step s
Go to 6. In step s6, it is determined whether or not there is an abnormality,
If it is determined to be abnormal (YES), the process proceeds to step s7, and the gas warm air heater R is abnormally stopped. If it is not determined to be abnormal (NO), the process proceeds to step s8. Step s8
Then, the pressing state of the gas switch 551 is determined, and if the pressing is determined (YES), the process proceeds to step s9, and if the pressing is not determined (NO), the process proceeds to step s24. In step s9, the mode shifts to the misfire determination level setting / writing mode, the buzzer sounds a predetermined number of times, and the gas lamp 581
To turn on.

In step s10, the temperature setting switch (+)
The pressing state of 511 is determined, and the pressing is determined (YE
S), the process proceeds to step s11, and the pressing is not discriminated (N
O), the process proceeds to step s17. In step s11,
Display of the Hi-side determination level on the display unit 585 is started (displayed in the left two digits), and the process proceeds to step s12. Step s12
Then, the pressing state of the gas switch 551 is determined, and if the pressing is determined (YES), the process proceeds to step s13, and if the pressing is not determined (NO), the process proceeds to step s14.
In step s13, the gas lamp 581 is turned off, the process returns to step s1, and shifts to the normal operation mode (display of the misfire determination level is switched to time display or the like). Step s14
To determine the pressing status of the temperature setting switch (+) 511,
When pressing (YES) is determined, the process proceeds to step s15, and when pressing is not determined (NO), step s16.
Proceed to. In step s15, set the temperature setting switch (+) 51
Each time you press 1, the Hi side judgment level is displayed at 12 mV.
(X) → 14 mV (Y) → 16 mV (Z) → 12 mV
At the same time as switching to (X) ..., the displayed adjustment value data regarding the Hi-side determination level is written in the E ² PROM 56, and the process returns to step s11. In step s16, it is determined whether or not the temperature setting switch (-) 512 is pressed, and if it is pressed (YES), the process proceeds to step s18.
If the pressing is not determined (NO), the process returns to step s11. In step s17, it is determined whether the temperature setting switch (-) 512 is pressed, and if it is pressed (YES),
The process proceeds to step s18, and if the pressing is not determined (NO), the process returns to step s10. In step s18, the display of the Lo side determination level on the display 585 is started (displayed in the right two digits), and the process proceeds to step s19. In step s19, the pressing condition of the gas switch 551 is determined, and if pressing is determined (YES), the process proceeds to step s20, and if pressing is not determined (NO), the process proceeds to step s21. In step s20, the gas lamp 581 is turned off, the process returns to step s1, and shifts to the normal operation mode (display of the misfire determination level is switched to time display or the like). In step s21, the pressing condition of the temperature setting switch (-) 512 is determined. If the pressing is determined (YES), the process proceeds to step s22, and if the pressing is not determined (NO), the process proceeds to step s23. At step s22, each time the temperature setting switch (-) 512 is pressed, the Lo side judgment level is displayed by 12 mV.
(X ₂ ) → 14 mV (Y ₂ ) → 16 mV (Z ₂ ) → 12
mV (X ₂ ) ... and the displayed L
The adjustment value data relating to the o-side judgment level is stored in the E ² PROM 5
6, and the process returns to step s18. Step s23
To determine the pressing status of the temperature setting switch (+) 511,
If the pressing is determined (YES), the process returns to step s11, and if the pressing is not determined (NO), step s18.
Return to.

In step s24, the POV switch 552
If the pressing state is determined and the pressing is determined (YES), the process proceeds to step s25, and the pressing is not determined (N).
O), the process proceeds to step s36. In step s25,
Buzzer 586
Sound for a predetermined number of times to turn on the POV lamp 582, and the process proceeds to step s26. In step s26, the combustion level is fixed at 7th speed, and the process proceeds to step s27. In step s27, the display of the POV current on the display 585 is started, and the process proceeds to step s28. In step s28, POV
When the pressing state of the switch 552 is determined, if the pressing is determined (YES), the process proceeds to step s29. If the pressing is not determined (NO), the process proceeds to step s30. In step s29, the POV current adjustment / writing mode is exited and the test mode is returned to. The buzzer 586 is sounded a predetermined number of times to turn off the POV lamp 582, and the process proceeds to step s36. In step s30, the pressing condition of the temperature setting switch (+) 511 is determined, and if the pressing is determined (YES),
The process proceeds to step s31, and if the pressing is not determined (NO), the process 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 process proceeds to step s32 and 30 mA.
If NO (NO), the process returns to step s27 without increasing the POV current. In step s32, the POV current is increased by 1 mA, and the process returns to step s27. Step s3
In step 3, it is determined whether or not the temperature setting switch (-) 512 is pressed, and if the pressing is determined (YES), step s34.
If the pressing is not discriminated (NO), step s
Return to 27. The correction current value is -30 mA in step s34.
It is determined whether or not it is more than -30 mA, it is more than -30 mA (YE
If S), the process proceeds to step s35. If it is lower than -30 mA (NO), the POV current is not reduced and step s2 is performed.
Return to 7. In step s35, the POV current is reduced by 1 mA, and the process returns to step s27.

In step s36, the pressing condition of the fan rotation speed Lo switch 554 is determined, and the pressing is determined (Y
If ES), the process proceeds to step s37, and if the pressing is not determined (NO), the process proceeds to step s49. Step s3
In 7, the mode shifts to the fan Lo rotation speed adjustment / write mode,
Sounds the buzzer 586 a predetermined number of times, and the fan Lo lamp 58
4 is turned on and the process proceeds to step s38. Step s
At 38, the combustion level is fixed to the first speed, and the process proceeds to step s39. In step s39, the display of the fan current on the display 585 is started, and the process proceeds to step s40. Step s4
At 0, the pressing condition of the fan rotation speed Lo switch 554 is determined, and when the pressing is determined (YES), step s4
When the pressing is not discriminated (NO), the process proceeds to step s41. In step s41, set temperature switch
(+) The pressing condition of 511 is determined, and the pressing is determined (Y
If ES), the process proceeds to step s42, and if the pressing is not determined (NO), the process proceeds to step s46. Step s4
It is determined whether the correction current value is within 50 mA in 2 and 5
If it is within 0 mA (YES), the process proceeds to step s43, and if it exceeds 50 mA (NO), the process returns to step s39 without increasing the fan current. Step s43
Then, the fan current is increased by 1 mA, and the process returns to step s39. In step s44, the buzzer 586 is sounded a predetermined number of times, the fan Lo lamp 584 is turned off, and step s45
Proceed to. At step s45, the fan current display is turned off,
It proceeds to step s50. In step s46, the pressing condition of the temperature setting switch (-) 512 is determined, and the pressing (YES)
If No is determined, the process proceeds to step s47, and if no pressure is determined (NO), the process returns to step s39. In step s47, it is determined whether or not the correction current value is -50 mA or more. If it is -50 mA or more (YES), the process proceeds to step s48. If it is less than -50 mA (NO), the fan current is not reduced and the step is performed. Return to s39. In step s48, the fan current is reduced by 1 mA, and in step s39
Return to. In step s49, the pressing state of the test switch 550 is determined, and if the pressing is not determined (YES),
In order to maintain the test mode, the process returns to step s3. If the pressing is determined (YES), the process returns to step s1, exits the test mode, and shifts to the normal operation mode.

In step s50, the pressing condition of the fan rotation speed Hi switch 553 is judged, and the pressing is judged (Y
ES), the process proceeds to step s51. Step s51
Then, the mode shifts to the fan Hi rotation speed adjustment / write mode, the buzzer 586 is caused to ring a predetermined number of times, and the fan Hi lamp 583
Is turned on and the process proceeds to step s52. Step s5
At 2, the combustion level is fixed at 7th speed and the process proceeds to step s53. In step s53, the display of the fan current on the display 585 is started, and the process proceeds to step s54. Step s54
To determine the pressing status of the temperature setting switch (+) 511,
If the pressing is determined (YES), the process proceeds to step s55, and if the pressing is not determined (NO), step s57.
Proceed to. In step s55, it is determined whether or not the correction current value is within 50 mA. If it is within 50 mA (YES), the process proceeds to step s56 and exceeds 50 mA (N
If it is O), the process returns to step s53 without increasing the fan current. In step s56, increase the fan current by 1mA,
Return to step s53. In step s57, the pressing condition of the temperature setting switch (−) 512 is determined. If the pressing is determined (YES), the process proceeds to step s58, and if the pressing is not determined (NO), the process proceeds to step s60. In step s58, it is determined whether or not the correction current value is -50 mA or more. If it is -50 mA or more (YES), the process proceeds to step s59, and if it is less than -50 mA (NO), the fan current is not reduced and the step is performed. Return to s53. In step s59, the fan current is reduced by 1 mA, and in step s53
Return to. In step s60, the fan Hi switch 553
If the pressing state is determined (YES), the process proceeds to step s61. If the pressing is not determined, the process returns to step s53. In step s61, the buzzer 586 is sounded a predetermined number of times to turn on the fan Hi lamp 583, and the fan Hi rotation speed adjusting / writing mode is exited to return to the test mode. Therefore, the process returns to step s49.

The gas warm air heater R has the following advantages. (A) The gas warm air heater R is set to the first speed during each adjustment and writing.
Lo / Hi for each combustion level group of 2nd speed, 3rd speed to 8th speed
The adjustment value data regarding the side misfire determination level, the adjustment value data regarding the POV current in the seventh speed, and the adjustment value data regarding the fan current in the first speed and the seventh speed are stored in the E ² PROM 5
6 and the read circuit 562 reads out these adjustment value data to detect the misfire detection levels of the misfire detection circuit 54, the proportional valve drive circuit 52, and the fan control circuit 53 on the Lo / Hi side.
The POV current at the 7th speed and the fan current at the 1st and 7th speeds are used. In the E ² PROM 56, each adjustment value data does not change due to its structure even if a mechanical shock such as vibration is applied to the control unit 5. Therefore, misfire determination by the misfire detection circuit 54 and PO by the proportional valve drive circuit 52
The reliability of the control of the V current and the control of the convection fan 4 by the fan control circuit 53 is excellent.

(I) Test switch 550, gas switch 551, POV switch 552, and fan speed H
Since the i / Lo switches 553 and 554 are arranged on the substrate of the control unit 5 which is not touched by the user, the user mistakenly detects the Lo / Hi side misfire determination level, the POV current at the seventh speed, Also, it does not change the fan current in 1st and 7th speed.

(U) A gas lamp 581, a POV lamp 582, and a fan Hi lamp 58 arranged on the substrate.
3 or the service person can see the lighting status of the fan Lo lamp 584, it is easy to know which adjustment / writing mode is currently selected.

The present invention includes the following embodiments in addition to the above embodiments. a. An MNOS type or MAOS type E ² PROM 56 may be used. b. In the above embodiment, the E ² PROM 56 stores the adjustment value data of an integer value, but it may store a decimal value. c. When the control circuit requires a plurality of adjustment values, the setting means sets the plurality of adjustment values, the writing circuit stores the plurality of adjustment value data in the semiconductor nonvolatile memory, and the reading circuit reads the respective adjustment value data. This may be done (Claim 1). d. In the above embodiment, the thermocouple is shown as the combustion detection sensor, but it may be a frame rod. e. Addition of auto increment and auto decrement functions to the temperature setting switches (+) (-) 511, 512 when adjusting and writing POV current in 7th speed and adjusting fan Lo, Hi speed in 1st and 7th speed. Adjustment time can be shortened. For example, when the pressing state continues for more than 0.2 seconds, the fan current and POV current are increased / decreased by ± 1 mA at 0.1 second intervals. f. The combustion speed at the time of adjustment is not limited to that in the above embodiment, and may be any preset speed.
In the above embodiment, the combustion amount is changed stepwise, but it may be changed proportionally.

[Brief description of drawings]

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

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

FIG. 3 is a flowchart illustrating an operation of an adjustment value setting device incorporated in a gas warm air heater.

FIG. 4 is a flowchart illustrating an operation of an adjustment value setting device incorporated in a gas warm air heater.

FIG. 5 is a flowchart illustrating an operation of an adjustment value setting device incorporated in the gas warm air heater.

FIG. 6 is a flowchart illustrating an operation of an adjustment value setting device incorporated in the gas warm air heater.

FIG. 7 is a flowchart illustrating an operation of an adjustment value setting device incorporated in the gas warm air heater.

[Explanation of symbols]

1 Gas Combustor (Burner) 2 Thermocouple (Combustion Detection Sensor) 3 Proportional Valve 4 Convection Fan (Fan) 52 Proportional Valve Drive Circuit 53 Fan Control Circuit (Fan Rotation Speed Adjustment Means) 54 Misfire Detection Circuit 56 E ² PROM (Semiconductor) Non-volatile memory) 511 Temperature setting switch (+) (level setting means, pressure adjusting means, fan rotation speed adjusting means) 512 Temperature setting switch (-) (level setting means, pressure adjusting means, fan rotation speed adjusting means) 561 Write circuit 562 Read circuit

Claims (4)

[Claims] 1. A setting means for setting an adjustment value of a control circuit at the time of setting, a semiconductor nonvolatile memory in which the adjustment value data is electrically rewritable, and an adjustment value set by the setting means is converted into adjustment value data. An adjustment value setting device comprising: a write circuit for storing the semiconductor nonvolatile memory; and a read circuit for reading and converting the adjustment value data stored in the semiconductor nonvolatile memory to obtain an adjustment value of the control circuit. 2. A burner having a variable combustion amount, a combustion detection sensor arranged in proximity to the burner, level setting means for setting each misfire detection level corresponding to the combustion amount at the time of setting, and an adjustment value. A semiconductor non-volatile memory in which data is electrically rewritable, a writing circuit for converting the misfire detection level set by the setting means into adjustment value data, and storing the adjustment value data in the semiconductor non-volatile memory; A read circuit that reads out the adjustment value data and converts it into the misfire determination level of the misfire detection circuit described later, and the electric output sent by the combustion detection sensor reach each misfire determination level set corresponding to the combustion amount. If not, a misfire detection circuit that determines that the burner is in an abnormal combustion state. 3. A burner having a variable combustion amount, a proportional valve for adjusting the amount of gas supplied to the burner, a pressure adjusting device for adjusting a proportional valve current at a predetermined combustion amount at the time of setting, and adjustment value data. Is an electrically rewritable semiconductor non-volatile memory, a write circuit for converting the proportional valve current adjusted by the pressure adjusting means into adjustment value data and storing the adjustment value data in the semiconductor non-volatile memory, and a writing circuit stored in the semiconductor non-volatile memory. A read circuit that reads out the adjusted value data and converts the adjusted value data into a proportional valve current at a predetermined combustion amount; and a proportional valve drive circuit that controls the proportional valve current at each combustion amount based on the proportional valve current at the predetermined combustion amount. An adjustment value setting device provided. 4. A burner with a variable combustion amount, a fan for supplying combustion air to the burner, and a fan speed adjusting means for adjusting each fan current at a predetermined low combustion amount and a predetermined high combustion amount at the time of setting. A semiconductor non-volatile memory in which the adjustment value data is electrically rewritable, a writing circuit for converting each fan current adjusted by the fan rotation speed adjusting means into each adjustment value data and storing the adjustment value data in the semiconductor non-volatile memory, A read circuit that reads out and converts each adjustment value data stored in the semiconductor nonvolatile memory into each fan current at a predetermined low / high combustion amount, and the fan based on each fan current at the predetermined low / high combustion amount An adjustment value setting device comprising a fan controller for controlling the.