KR0122496B1 - Combustion system - Google Patents

Abstract

a fan for supplying air to a burner; a rotation number designating circuit; a rotation number detecting circuit; a fan rotation number control circuit for outputting a rotation number control signal; a fan driving circuit for rotating the fan with the designated number of rotation of the fan; a compensation coefficient setting circuit for obtaining a compensation coefficient for the designated number of rotation of the fan; and a compensated rotation number designating circuit for designating a compensation rotation number indication value to the fan rotation number control circuit.

Description

Combustion device

1 is a schematic view showing an embodiment in which the present invention is applied to a hot water heater.

2 is a graph for explaining a calculation method of the correction coefficient.

3 is a block diagram for explaining the control of the blowing amount to the gas burner by the combustion fan and the opening degree control of the proportional control valve.

* Explanation of symbols for main parts of the drawings

6 gas burner 9 proportional control valve

10: combustion fan 19: rotation speed designation circuit

20: rotation speed detection circuit 23: fan rotation speed control circuit

24: fan drive circuit R _AIR : correction factor

31: complementary coefficient setting circuit 34: corrected rotation speed indicating circuit

35: fuel supply amount setting circuit 36: current value conversion circuit

38: Correction current value designation circuit 39: Proportional valve driving circuit

40: current value detection circuit 41: current value control circuit

The present invention relates to a combustion apparatus having a combustion fan for supplying combustion air to a burner and a proportional control valve for controlling fuel supplied to the burner.

Conventionally, in this type of combustion apparatus, the opening degree of the proportional control valve is set according to the set temperature set by the temperature control volume, etc., fuel is supplied to the burner, and air is supplied to the burner by the combustion fan, whereby fuel is supplied from the burner. Is burned, and it is known that the supply amount of combustion air by the combustion fan is controlled in accordance with the output of the combustion detection sensor that detects the flame state of the burner.

In such a combustion apparatus, however, the opening degree of the proportional control valve changes rapidly in response to the change of the temperature regulating volume when the temperature regulating volume is changed, but the supply amount of combustion air by the combustion fan is first proportionally controlled. The combustion detection sensor detects a flame change caused by a change in the valve opening degree and changes the rotation speed of the combustion fan according to the output change of the combustion detection sensor. There was a problem that sex is very bad.

Therefore, by controlling the rotation speed of the combustion fan based on the set temperature by the temperature control volume and controlling the view of the proportional control valve according to the rotation speed, the opening degree of the proportional control valve A so-called fan leading type combustion device capable of quickly responding the supply amount of combustion air by the combustion fan has been proposed (see Japanese Patent Laid-Open No. 3-59332).

Such a combustion apparatus has a fan rotation speed (designated) according to a set temperature (combustion amount) by a temperature control volume based on a correlation between a combustion amount of a burner and a rotation speed of a combustion fan set in advance. Fan speed) is assigned to the fan speed control circuit, and the fan speed control circuit outputs a signal corresponding to the designated fan speed to the fan drive circuit to rotate the combustion fan according to the combustion amount, and the rotation at this time. The number of revolutions is detected by the rotation speed detection circuit and fed back to the fan rotation speed control circuit, and the rotation speed of the combustion fan is controlled by the rotation speed detection circuit to control the rotation speed of the combustion fan so as to match the designated fan rotation speed. The ratio of fuel to fuel (hereinafter referred to as air-fuel ratio) is maintained appropriately.

However, when the exhaust passage is closed or steel is blown out from the outside, a blowing load is applied to the blowing of the combustion fan. In this case, the rotation speed of the combustion fan is kept constant by the above feedback control. In addition, the blowing amount of the combustion fan is gradually lowered as the blowing load increases, and as a result, there is a problem of deterioration of air-fueling, resulting in incomplete combustion.

Therefore, in order to solve such a problem, in the case where a blowing load is applied to the combustion fan, a combustion device having correction means for correcting the designated fan speed output from the low water storage designation circuit to the fan speed control circuit has been proposed. (See Japanese Patent Laid-Open No. 3-186113).

Such a combustion apparatus includes a current designation circuit for designating a drive current of a combustion fan according to the combustion amount, a current detection circuit for detecting an actual drive current of the combustion fan, and a current value detected by the current detection circuit. When the ground current value becomes smaller than the ground current value by the circuit (when the rotational speed of the combustion fan is kept constant by the above-described feedback control under the blowing load), the rotation speed designation circuit is arranged so that the detected current value coincides with the low constant current value. It is to provide a maintenance circuit for correcting the designated fan rotation speed output to the pin rotation speed control circuit, by the correction control to increase the rotation speed of the combustion fan to maintain the air-fuel ratio appropriately.

However, such a combustion apparatus includes a current detection circuit for detecting a fan driving current in addition to the rotation speed detection circuit for detecting the rotation speed of the combustion fan during correction control, so that two sensors are required and the circuit configuration is reduced. There was a problem of complexity and high manufacturing costs.

The present invention has been made to solve such a problem, and an object of the present invention is to provide a combustion apparatus capable of correcting the rotational speed of a combustion fan with respect to a blowing load with a simple circuit configuration.

In addition, the present invention can correct the rotational speed of the combustion fan to the blowing load with a simple circuit configuration, and in addition to the opening of the proportional control valve and the combustion air by the combustion fan to change the temperature control volume and the like. An object of the present invention is to provide a combustion device capable of quickly responding to a supply amount.

In order to achieve the above object, the combustion apparatus of the present invention includes a proportional control valve for controlling fuel supplied to a burner, a combustion fan for supplying combustion air to the burner, and the combustion fan according to the combustion amount of the burner. A rotation speed designation circuit for sweeping the rotation speed of the engine, a rotation speed detection circuit for detecting the rotation speed of the combustion fan, and a detection fan rotation speed detected by the rotation speed detection circuit and the rotation speed designation circuit A fan rotation speed control circuit for outputting a rotation control signal for controlling the rotation speed of the combustion fan such that the detection fan rotation speed matches the designated fan rotation speed by comparing a designated fan rotation speed with the fan rotation speed control circuit; A fan driving circuit which rotates the combustion fan at the designated fan speed in accordance with the output value of?, And a blowing load is not applied to blowing by the combustion fan. A correction coefficient setting circuit for obtaining a correction coefficient for the designated fan rotation speed based on a comparison between a characteristic determined by the relationship between the output value and the detection fan rotation speed in And a maintenance rotation speed designation circuit which designates the maintenance rotation speed indication value obtained by multiplying the number to the fan rotation speed control circuit as a designated fan rotation speed.

The present invention also provides a fuel supply amount setting circuit for obtaining a fuel supply amount supplied to the proportional control valve according to the detection fan rotation speed, a current value conversion circuit for converting the fuel supply amount to a current value, and the current value conversion circuit. A correction rectified value designating circuit obtained by dividing the current value converted by the correction coefficient by the correction coefficient, a proportional valve driving circuit driving the proportional control valve based on the corrected current value, and the proportional control valve in the proportional valve driving circuit. A current value detection circuit for detecting a current value indicated by, and comparing the current value detected by the current value detection circuit with the correction current value so that the current value matches the correction current value. And a current value control circuit for controlling the current value.

According to the combustion apparatus of claim 1, the rotation speed designation circuit designates the rotation speed of the combustion fan according to the burn amount of the burner to the fan rotation speed control circuit, and based on the output value output from the fan rotation speed control circuit. The fan drive circuit rotates the combustion fan at the designated fan speed. At this time, the rotation speed of the combustion fan is detected by the rotation speed detection circuit and fed back to the fan rotation speed control circuit, which is compared with the designated fan rotation speed in the fan rotation speed control circuit. When the detected fan rotation speed detected by the rotation speed detection circuit is different from the designated fan rotation speed, the fan rotation speed control circuit controls the rotation speed of the combustion fan so that the detected fan rotation speed matches the designated fan rotation speed. . Therefore, the rotation speed of the combustion fan is controlled to rotate at the designated fan speed corresponding to the combustion amount specified in the rotation speed designation circuit.

Further, in the rotation control state, when the fan speed changed by applying the blowing load to the combustion fan is returned to the designated fan speed by the feedback control described above, the correction coefficient setting circuit blows the combustion fan. The characteristics determined by the relationship between the output value in the fan speed control circuit and the detection fan speed when no load is applied, and the relationship between the output value and the detection fan speed when the blower load is applied. The correction factor for the designated fan speed is calculated based on a comparison with the characteristics determined by the function, and the correction speed indication circuit calculates the correction speed indication value obtained by multiplying the correction factor by the specified fan speed and the fan speed control circuit. By outputting as a correction of the designated fan speed, and moreover, the rotation speed of the combustion fan is corrected to ensure an appropriate amount of air according to the combustion amount.

According to the combustion apparatus of claim 2, the detection fan rotation speed detected by the rotation speed detection circuit is output to the fuel supply amount setting circuit, and the fuel supply amount setting circuit is provided to the proportional control valve according to the detection fan rotation speed. The fuel supply amount is calculated. The fuel supply amount is converted into a current value by the current value conversion circuit and output to the correction current value designation circuit. The correction current value designating circuit is for adjusting this fuel amount so that the amount of fuel supplied to the burner is not changed by this correction when the rotation speed correction of the combustion fan described above is made, and is converted by the current value converting circuit. The proportional control valve is driven based on the correction current value for the proportional control valve by dividing the current value by the correction factor.

At this time, the current value actually indicated by the proportional control valve in the proportional valve driving circuit is detected by the current value detecting circuit, which is compared with the corrected current value by the current value controlling circuit. When the two are different, the current value for the proportional control valve is controlled by the current value control circuit so that the current value coincides with the correction current value. In addition, when correction of the designated fan rotation speed is not performed, the current value converted by the current value conversion circuit is not corrected by the correction current value designation circuit, that is, the conversion current value is instructed to the proportional drive circuit as it is.

Hereinafter, embodiments of the present invention will be described with reference to FIGS.

1 is a schematic diagram showing an embodiment in which the present invention is applied to a hot water heater, FIG. 2 is a graph for explaining a method of calculating a correction factor, and FIG. 3 is a control of air flow to a burner by a combustion fan and opening degree control of a proportional control valve. It is a block diagram for explaining.

Referring to the overall configuration of the hot water heater according to FIG. 1, reference numeral 1 denotes a combustion housing, 2 denotes a water pipe arranged to pass through a heat exchanger 3 installed in the combustion housing 1, and 3a denotes a water pipe. Water flow rate sensor for detecting the flow rate of the water flowing in the water pipe (2) upstream of (2), 4 is a temperature sensor for detecting the temperature of water flowing in the water pipe (2) downstream from the heat exchanger (3) The thermistor, 5 is a gas supply pipe for supplying gas to the gas burner 6 installed in the combustion housing 1, 7, 8, 9, respectively, the main solenoid valve, hot water supply electrons are sequentially installed in the gas supply pipe 5 from the upstream side Valve and proportional control valve, 10 is a combustion fan for supplying combustion air to the gas burner 6, 11 is an exhaust passage for evacuating the combustion exhaust gas burned by the gas burner 6 on the upper side of the heat exchanger (3). 12 is an igniter for igniting the gas burner 6, and 13 is a flame furnace for detecting the ignition of the gas burner 6; , 14 is a control unit that controls the operation of the hot water heater, 15 is a temperature-controlled volume for users to set the tapping temperature and so on (combustion quantity). The hot water supply tap which is not shown in figure is attached to the downstream end of the water pipe 2. The control unit 14 includes a control device having a blowing amount control means for controlling the blowing amount to the gas burner 6 by the combustion fan 10 and a proportional control means for controlling the opening degree of the proportional control valve 9. It consists of a microcomputer.

The basic operation of such a water heater is as follows.

That is, when a hot water supply not shown is opened, the control unit 14 detects this through the water quantity sensor 3a, and this control unit 14 makes a combustion fan based on the set temperature by the temperature control volume 15. By controlling the rotation speed of (10) to supply the air according to the amount of combustion to the gas burner (6), opening the main solenoid valve (7) and the hot water solenoid valve (8) and at the same time the air of the combustion fan 10 The opening degree of the proportional control valve 9 is controlled according to the supply amount, and the igniter 12 is driven to ignite the gas burner 6. Accordingly, the gas burner 6 starts combustion and is heated through the heat exchanger 3 so that the water flowing in the water supply pipe 2 toward the hot water supply field coincides with the set temperature of the temperature control volume 15.

Next, a control apparatus for controlling the blowing amount of the combustion fan 10 to the gas burner 6 and the opening degree of the proportional control valve 9 will be described with reference to FIGS. 2 and 3.

In Fig. 3, reference numeral 16 denotes a control device for controlling their operation, and the control device 16 is a blowing amount control means 17 and a proportional control valve 9 for controlling the blowing amount of the combustion fan 10. Proportional valve control means 18 for controlling the opening degree of the.

The blowing amount control means 17 includes a rotation speed designation circuit 19 for designating a rotation speed of the combustion fan 10 according to the combustion amount, a rotation speed detection circuit 20 for detecting the rotation speed of the combustion fan 10, and rotation The detection fan rotation speed fed back from the number detection circuit 20 and the designated fan rotation speed designated by the rotation speed designation circuit 19 are compared in the comparison circuit 21 so that the detection fan rotation speed matches the designated fan rotation speed. Fan rotation control circuit 23 for indicating a current value (or voltage value) for controlling the rotation speed of the combustion fan 10 in the rotation control signal output circuit 22, the combustion fan according to the current value When a blowing load is applied to the combustion fan 10 due to a blockage of the fan drive circuit 24 and the exhaust passage 11 and a strong wind from outside the exhaust passage 11 to rotate the fan 10 at a predetermined fan speed. The fan speed designated by the fan speed control circuit 23 is corrected by the rotation speed designation circuit 19 at It is provided with a correction circuit (25).

The rotation speed designation circuit 19 calculates the combustion amount of the gas burner 6 in the combustion amount calculation circuit 26 on the basis of the output value of the temperature control volume 15, and the rotation speed indicating circuit 27 The fan rotation speed accordingly is instructed to the fan rotation speed control circuit 23 through the correction circuit 25.

When the blower load is applied to the combustion fan 10, the correction circuit 25 maintains that the rotation speed of the combustion fan 10 is kept constant by the above-described feedback control so that the blowing amount to the gas burner 6 changes. Compensation circuit 28, correlation detection circuit 29, and correction for correcting the designated fan rotation speed specified by the fan speed storage control circuit 23 in the rotation speed designation circuit 19 to maintain an appropriate blowing amount. A correction coefficient setting circuit 31 having a coefficient calculating circuit 30, and a correction speed indicating circuit 34 having a correction speed calculating circuit 32 and a correction speed indicating value circuit 33, In the case where the blowing load is applied, the rotation coefficient designation circuit 19 instructs the rotation speed designation circuit 19 to calculate the correction coefficient R _AIR for the designated fan rotation speed, and also corrects the rotation speed correction circuit ( The correction meter at the designated fan rotation speed instructed by the rotation speed designation circuit By multiplying (R _AIR) calculating a corrected revolution number instruction value, and outputs this revolution speed correction value being a fan revolution speed control circuit 23 as the specified number of fan rotation.

The correction coefficient R _AIR is determined by the relationship between the current value instructed by the fan speed control circuit 23 and the detection fan speed when no blowing load is applied to the fan 10 for combustion. It is calculated | required based on the comparison with the characteristic, and the characteristic determined by the relationship between the electric current value and the detection fan rotation speed when a blow load is applied, and is computed as follows.

That is, the blowing amount Q and the rotational speed ψ of the combustion fan 10 are approximately Q = a × ψ (hereinafter referred to as equation (1)), and in accordance with the blowing load for the combustion fan. By using the change of the value a, the correction coefficient R _AIR is defined as Q = R _AIR × a × ψ (hereinafter referred to as Expression (2)). Here, since the blowing amount Q is basically determined by the current value A instructed by the fan driving circuit 24 in the fan speed control circuit 23, the blowing amount Q is converted into the current value A. In addition to the substitution, the relationship between the case where no fan load is applied to the combustion fan 10 and the case where it is applied is set as the detection fan speed detected by the speed detection circuit 20. It is shown in FIG.

2 shows the relationship between the current value A and the detection fan rotation speed (ψ) with or without the blowing load for the combustion fan, with the vertical axis representing the current value (A) and the horizontal axis representing the detection fan rotation speed (ψ). It is a graph.

Reference numeral (a) denotes a relationship between both when no blowing load is applied to the combustion fan 10, and (b) a blowing load is applied to the combustion fan 10 due to a blockage of the exhaust passage 11 or the like. The relationship between both of the fact that the current value A decreases (the air flow rate decreases) is maintained by the feedback control described above that the rotation speed of the combustion fan 10 tends to increase, and (c) is strong wind. The rotational speed of the combustion fan 10 tends to decrease when a blowing load is applied to the combustion fan 10 due to the negative pressure of the outlet passage 11 being negative. Both of these relationships indicate that the current value A becomes large (the amount of blown air is excessive) by maintaining the rotational speed constant by the feedback control.

Looking at each characteristic of (A), (B), and (C) from the relation of Eq. (1), the value of a in Eq. (1) is from the origin (0) of (A), (B) and (C). If the value of a is temporarily set to 1 corresponding to the respective slopes of (a) and there is no pine cone load, the values of a in (b) and (c) are 0.9 and 1.1, respectively. (These slopes are detected by the correlation detection circuit 29 after the current value A and the detection fan rotational speed ψ are compared in the comparison circuit 28).

Here, in order to obtain a constant blowing amount regardless of the presence or absence of the blowing load, first, in the formula (2), the correction coefficient (R _AIR ) in the case of (A) is set to 1, and (B) and (C) Each correction coefficient R _AIR of R is calculated to be R _AIR × a = 1 (calculated by the calculation processing of the correction coefficient calculating circuit), and the correction coefficient R is corrected by the correction rotation speed calculating circuit 32. _AIR ) is multiplied by the designated fan rotation speed designated by the rotation speed branch circuit 19 to calculate a correction speed indication value, and the correction speed indication value is stored in the maintenance speed indication value circuit 33 by the fan speed control circuit ( By instructing 23 as the instructed fan rotation speed, a constant current value A is output from the fan rotation speed control circuit 23 to the fan drive circuit 24 with or without a blower load, thereby obtaining an appropriate amount of blowing. Further, in (b), the correction coefficient R _AIR = 1 / 0.9 = 1.1 increases and compensates for the rotational speed of the combustion fan 10, and in (c), the correction coefficient R _AIR = 1 / 1.1 = 0.9 becomes the combustion fan. The rotation speed of 10 is corrected to decrease.

Next, the proportional valve control means 18 will be described. The proportional valve control means 18 is supplied to the proportional control valve 9 in accordance with the detection fan rotation speed detected by the rotation speed detection circuit 20. This correction is performed when the rotation speed correction of the fuel supply amount setting circuit 35 for obtaining the fuel supply amount, the current value conversion circuit 36 for converting the fuel supply amount to the current value, and the combustion fan 10 are performed. In order to adjust the amount of fuel so that the amount of fuel supplied to the gas burner 6 does not change, the current value I (ψ) converted by the current value converting circuit 36 is divided by the correction coefficient R _AIR . A proportional valve for driving a proportional control valve 9 based on a correction current value calculation circuit 37 for obtaining a correction current value, a correction current value designation circuit 38 for outputting the correction current value, and the correction current value. Current directed to the proportional control valve 9 in the drive circuit 39 The proportional control valve is configured to compare the current value detected by the current value detection circuit 40 and the current value detected by the constant current value detection circuit 40 with the correction current value so that the current value matches the correction current value. And a current value control circuit 41 for controlling the current value for (9).

Next, the above-described air flow rate control of the combustion fan 10 and opening degree control of the proportional control valve 9 will be described with reference to FIG.

When the tapping temperature is set by the temperature control volume 15, the combustion amount calculation circuit 26 calculates the combustion amount of the gas burner 6 according to the set temperature, and the gas burner 6 is operated by the rotation speed indicating circuit 27. The rotation speed of the combustion fan 10 according to the combustion amount of the control unit is instructed to the fan rotation speed control circuit 23 through the correction rotation speed indicating circuit 34, and the current value indicated by the rotation control signal output circuit 22. Based on (A), the fan drive circuit 24 rotates the combustion fan 10 at a predetermined fan speed.

At this time, the rotation speed of the combustion fan 10 is detected by the rotation speed detection circuit 20 and fed back to the comparison circuit 21 of the fan rotation speed control circuit 23 and compared with the designated fan rotation speed. When the rotation speed of the combustion fan 10 is different from the detection fan speed detected by the rotation speed detection circuit 20, the fan drive circuit 24 is rotated by the rotation control signal output circuit 22 so as to match the designated fan speed. ), The current value is specified to control the rotation speed of the combustion fan 10. Therefore, the rotation speed of the combustion fan 10 is controlled by the fan rotation speed according to the combustion amount designated by the rotation speed indication circuit 27.

Further, in the rotation control state, the detection fan rotation speed and the current value A are compared in the comparison circuit 28 of the correction coefficient setting circuit 31 so that the correlation detection circuit 29 calculates the inclination a described above. The correction coefficient calculating circuit 30 calculates the correction coefficient R _AIR based on the inclination a. When there is no blowing load for the combustion fan 10, the correction coefficient R _AIR is 1 as described above, so the designated fan rotation speed designated by the rotation speed indicating circuit 27 is calculated by the correction rotation speed. It is output from the correction speed indication value circuit 33 to the fan speed control circuit 23 without being corrected in the circuit 32.

On the other hand, when the blowing load is applied, the correction speed calculation circuit 32 corrects the correction speed so that the changed fan rotation speed by applying the blowing load to the combustion fan 10 does not return to the designated fan rotation speed by the above feedback control. (R _AIR ) is multiplied by the designated fan speed designated by the rotation speed indicating circuit 27 to obtain a correction speed indication value, and the correction speed indication value circuit 33 converts the correction speed indication value to a fan speed control circuit. The fan driving circuit 24 is output from the rotation control signal output circuit 22 according to the deviation between the designated fan rotation speed and the detected fan rotation speed corrected to the comparison circuit 21 of (23). The furnace current value is instructed, and the increase or decrease of the rotation speed of the combustion fan 10 is corrected so that an appropriate amount of air according to the combustion amount is secured.

In addition, the detection fan rotation speed detected by the rotation speed detection circuit 20 on one side is output to the fuel supply amount setting circuit 35, and is proportional to the detection fan rotation speed by the fuel supply amount setting circuit 35. The fuel supply amount to the control valve 9 is obtained. The fuel supply amount is converted into a current value by the current value conversion circuit 36 and output to the correction current value calculation circuit 37.

The correction current value calculation circuit 37 has a current value conversion circuit so that the amount of fuel supplied to the burner is not changed by this correction when the rotation speed of the combustion fan 10 is increased or decreased by the blowing load. The correction current value is obtained by dividing the current value converted by 36) by the correction coefficient R _AIR instructed by the correction coefficient calculating circuit 30. The guaranteed current value calculated by the correction current value calculation circuit 37 is instructed by the correction current value designating circuit 38 to the proportional valve driving circuit 39, and the proportional valve driving circuit 39 is the correction current. The opening degree of the proportional control valve 9 is controlled based on the value. In addition, when the rotation speed correction of the combustion fan 10 is not performed because there is no blowing load, the current value converted by the current value conversion circuit 36 is not corrected by the correction current value calculation circuit 37, that is, The proportional valve driving circuit 39 is instructed as it is.

The current value actually directed from the proportional valve drive circuit 39 to the proportional control valve 9 is detected by the current value detection circuit 40, and this detection current value is detected by the current value detection circuit 40. Is compared to a value. When the two are different, the current value for the proportional control valve 9 is controlled by the current value control circuit 41 so that the current value coincides with the correction current value, and thus combustion is performed regardless of the presence or absence of a blower load. The combustion amount of the gas burner 6 in accordance with the blowing amount of the fan 10 is secured, so that an appropriate air-fuel ratio can be obtained.

In the above water heater, the rotation speed of the combustion fan 10 is controlled based on the set temperature by the temperature control volume 15, and the opening degree of the proportional control valve 9 is controlled according to the rotation speed. Therefore, the supply amount of the combustion air by the combustion fan 10 and the opening degree of the proportional control valve 9 can be immediately corresponded to the change of the temperature control volume 15.

In addition, since the sensor necessary for the rotation speed correction control of the combustion fan 10 with respect to the blowing load is sufficient only by the rotation speed detection circuit 20 for detecting the rotation speed of the combustion fan 10, A current detection circuit for detecting the drive current of the fan drive current becomes unnecessary, and therefore, a simple circuit configuration can reduce the manufacturing cost.

As can be seen from the above description, according to the present invention, since the rotation speed of the combustion fan can be appropriately corrected in response to the blowing load, and only the rotation speed detection circuit is sufficient for the sensor necessary for this correction control. As a conventional method, the current detecting circuit for detecting the drive current of the fan driving current is no longer necessary, so that the circuit configuration of the screw can be simplified and the cost of the device can be reduced.

In addition, by controlling the opening degree of the proportional control valve according to the rotational speed of the combustion fan, the supply amount of combustion air by the combustion fan and the opening degree of the proportional control valve can be quickly corresponded to changes in the temperature control volume. In one case, when the rotation speed of the combustion fan is corrected by the blowing load, the current value converted by the current value converting circuit is divided by the correction coefficient so as not to change the amount of fuel supplied to the burner by this correction. Since the current value for the valve is specified, even when the rotation speed of the combustion fan is adjusted by the blowing load, the opening degree of the proportional control valve is not affected by this correction, so that a constant amount of fuel can be supplied to the burner. Therefore, the appropriate air-fuel ratio can be maintained regardless of whether or not the blowing load is present.

Claims (2)

A proportional control valve for controlling fuel supplied to a burner, a combustion fan for supplying combustion air to the burner, a rotation speed designation circuit for designating a rotation speed of the combustion fan according to the combustion amount of the burner, and A rotation speed detection circuit for detecting the rotation speed of the combustion fan, a detection fan rotation speed detected by the rotation speed detection circuit, and a designated fan rotation speed specified by the rotation speed designation circuit, and comparing the detection fan rotation speed with the rotation speed detection circuit; A fan rotation speed control circuit for outputting a rotation control signal for controlling the rotation speed of the combustion fan so as to match a designated fan rotation speed, and the combustion fan according to an output value from the fan rotation speed control circuit. A fan drive circuit which rotates at a rotational speed, and a pipe between the output value and the detection fan rotational speed when a blowing load is not applied to the blowing by the combustion fan. Setting a correction coefficient for obtaining a correction coefficient for the designated fan rotation speed based on a comparison between the characteristic determined by the power supply and the characteristic determined by the relationship between the output value and the detection fan rotation speed when the blowing load is applied. And a correction speed designation circuit for designating a correction speed indication value obtained by multiplying the correction coefficient by the designated fan speed as the designated fan speed control circuit to the fan speed control circuit. The fuel supply amount setting circuit for obtaining a fuel supply amount supplied to the proportional control valve according to the detection fan rotation speed, a current value conversion circuit for converting the fuel supply amount to a current value, and the current value conversion circuit according to claim 1 A correction current value designating circuit for designating a correction current value obtained by dividing the current value converted by the correction coefficient by the correction coefficient, a proportional valve driving circuit for driving the proportional control valve based on the correction current value, and the proportional valve driving circuit A current value detection circuit for detecting a current value indicated by the proportional control valve in the furnace, and a current value detected by the current value detection circuit and the correction current value so that the current value matches the correction current value. And a current value control circuit for controlling a current value for the proportional control valve.