JPH0849840A - Electromagnetic pump-controlling apparatus for combustion machine - Google Patents

Abstract

PURPOSE:To burn the fuel in the most suitable state of combustion at all times, by a method wherein when a constant voltage-determining part determines the drop of voltage, a pulse-compensating part compensates a pulse so that the amount of fuel to be supplied becomes constant, either by increasing pulse width or by shortening its cycle. CONSTITUTION:A pulse-presetting part 2 presets a pulse to be applied to an electromagnetic pump 7 on the basis of a signal from a combustion-controlling part 11. A constant voltage-determining part 8 determines whether constant voltage or not by receiving a signal from the pulse-presetting part 2 and by reading a value on a source voltage- -detecting part 4 in a specified time after raising the pulse outputted from the pulse-presetting part 12. When the constant voltage-controlling part 8 determines the drop of voltage, the pulse- compensating part 9 compensates a pulse so that the amount of fuel to be supplied becomes constant either by increasing a pulse width preset by the pulse-presetting part 12 or by shortening its cycle. In this way, the fuel can be burned in the most suitable state of combustion at all times.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic pump control device for a combustor in which liquid fuel is supplied by an electromagnetic pump and burned.

[0002]

2. Description of the Related Art FIG. 7 is a block diagram showing a structure of a conventional combustion control device disclosed in, for example, Japanese Patent Laid-Open No. 1-184324.

In the figure, reference numeral 1 is a combustion control device for controlling fuel supply to a combustor (not shown). The combustion control device 1 comprises a microcomputer 2, a power supply voltage detection part 4, an electromagnetic pump power supply part 5, and a drive part 6. The microcomputer 2 compares a set signal from a temperature setter (not shown) with a detection signal from a room thermometer (not shown) that detects the room temperature, and outputs a control signal capable of obtaining a discharge flow rate such that the room temperature is kept at the set temperature. It has a function to generate and pulse width modulation (PWM) this control signal to the pulse width corresponding to the value.
Then, the pulse width modulation circuit unit 3 which outputs this as a drive pulse is built in. The drive pulse from the pulse width modulation circuit section 3 is given to the drive section 6, and the drive section 6 controls the application of the power output output from the electromagnetic pump power supply section 5 to the electromagnetic pump 7 to drive the electromagnetic pump 7. To do.

The electromagnetic pump power source unit 5 rectifies an external power source such as a commercial power source and converts the external power source into a constant voltage suitable for driving the electromagnetic pump, and outputs the voltage. It is detected and input to the microcomputer 2 as power supply voltage information. The microcomputer 2 also has a function of calculating and updating the period and pulse width set in the pulse width modulation circuit unit 3 based on this power supply voltage information.

In the combustion control device 1 having such a configuration, the microcomputer 2 determines the liquid fuel discharge flow rate of the electromagnetic pump 5 based on the detection voltage of the power supply voltage detection unit 4, the set temperature value and the room temperature detection value of the room thermometer. A drive pulse having a pulse period and a pulse width that provides an optimum amount for maintaining the set room temperature is generated via the built-in pulse width modulation circuit unit 3 and given to the drive unit 6. Then, the drive unit 6 controls the application of the power output output from the electromagnetic pump power supply unit 5 to the electromagnetic pump 7 by switching control according to the drive pulse, and supplies the electromagnetic pump 7 with the power, thereby driving the electromagnetic pump 7.
The electromagnetic pump power supply unit 5 rectifies a commercial power supply, converts it into a constant voltage to an optimum voltage for driving the electromagnetic pump, and outputs it. Since the stability is good, the optimum pulse cycle is usually set under a constant voltage of the electromagnetic pump power output. , A drive pulse having a pulse width corresponding to the difference between the room temperature and the set temperature is output, and the electromagnetic pump 7
Will be driven, and this will perform combustion control so as to maintain the set temperature.

On the other hand, in the electromagnetic pump power source section 5 which is a constant voltage power source, the output voltage may vary due to the variation of the commercial power source. In this case, since the microcomputer 2 calculates and corrects the pulse width and cycle of the drive pulse according to the detection voltage of the power supply voltage detection unit 4, even if the voltage value of the electromagnetic pump power supply unit 5 fluctuates, it can be dealt with. The electromagnetic pump 7 is operated so as to maintain the optimum discharge flow rate for maintaining the room temperature at the set temperature.

[0007]

In the conventional device as described above, when the commercial power source fluctuates greatly, the power source voltage detector 4 can easily detect it and correct the drive pulse. However, when the voltage of the commercial power supply is slightly reduced, the voltage of the electromagnetic pump power supply unit 5 drops in a ripple shape only when the pulse is turned on as shown in FIG. 8 because of the current flowing when the electromagnetic pump 7 is turned on. The phenomenon of doing appears.

On the other hand, such a ripple voltage is difficult to detect by the conventional power supply voltage detecting section 4, and for example, even if it is detected by the method of always sampling, the voltage only occasionally drops. Since the voltage has returned to the voltage, the voltage fluctuation cannot be accurately detected, and the drive pulse cannot be corrected. In such a state, the discharge flow rate decreases because a part of the drive pulse is missing,
The amount of combustion decreases. Then, the room temperature cannot be maintained, and the amount of combustion decreases in the case where the balance with the combustion air is electronically controlled, the amount of combustion decreases, resulting in lift combustion, causing odors during combustion, and flame current There were problems such as extinguishing the fire on the way due to deterioration.

The present invention has been made in order to solve the above-mentioned problems, and by accurately detecting the voltage fluctuation of the electromagnetic pump power source section and correcting the drive pulse in any fluctuation of the commercial power source. An object of the present invention is to provide a highly reliable electromagnetic pump control device for a combustor that can always burn in an optimum combustion state.

[0010]

An electromagnetic pump control device for a combustor according to the present invention includes a combustion control section and a pulse setting section for setting a pulse applied to the electromagnetic pump based on a signal from the combustion control section. , A drive unit that applies a drive pulse to the electromagnetic pump by the output from the pulse setting unit, an electromagnetic pump power supply unit that supplies a constant DC voltage to the drive unit to make the drive pulse a constant voltage, and this electromagnetic pump power supply unit A power supply voltage detection unit that detects the voltage of the power supply voltage detection unit, a constant voltage determination unit that determines whether the voltage is a constant voltage by reading the value of the power supply voltage detection unit after a predetermined time from the rise of the pulse output from the pulse setting unit, And a pulse correction unit that corrects the pulse width or pulse period set by the pulse setting unit based on the determination of the voltage determination unit.

Further, the constant voltage judging section is adapted to read the value of the power supply voltage detecting section at the falling edge of the pulse output from the pulse setting section and judge it.

Further, a combustion control section, a pulse setting section for setting a pulse to be applied to the electromagnetic pump based on a signal from the combustion control section, and a drive pulse is applied to the electromagnetic pump by an output from the pulse setting section. A drive unit, an electromagnetic pump power supply unit that supplies a constant DC voltage to the drive unit to make a drive pulse a constant voltage, a power supply voltage detection unit that detects the voltage of the electromagnetic pump power supply unit, and a pulse from the pulse setting unit. Is not output or the rising edge of the pulse and the value of the power supply voltage detecting section after a predetermined time from the rising edge of the pulse, the constant voltage determining section for determining whether the voltage is a constant voltage and the determination of the constant voltage determining section. And a pulse correction unit for correcting the pulse width or pulse period set by the pulse setting unit based on the above.

Further, the constant voltage judging section judges by the deviation between the pulse output from the pulse setting section or the rising of the pulse and the value of the power supply voltage detecting section after a predetermined time from the rising of the pulse. It is something that is done.

[0014]

In the present invention, when the constant voltage determination unit determines that the voltage has dropped, the pulse correction unit corrects the fuel supply amount by increasing the pulse width or shortening the cycle.

Further, since the constant voltage determination unit reads the value of the power supply voltage detection unit at the time of pulse falling to make a determination, it also accurately detects a ripple voltage and determines a voltage drop. be able to.

The constant voltage determination unit reads the value of the power supply voltage detection unit when a pulse is not output from the pulse setting unit or when the pulse rises and when the pulse rises and a predetermined time elapses from the rise of the pulse. Since the determination is made as to whether or not the ripple-like voltage drop has occurred, it can be determined more accurately.

Furthermore, the constant voltage determination unit determines by the deviation between the pulse output from the pulse setting unit or the rise of the pulse and the value of the power supply voltage detection unit after a predetermined time from the rise of the pulse. As a result, the fluctuation range of ripple voltage can be detected accurately, and
It is possible to suppress the fluctuation of the fuel supply amount by applying the optimum correction to the pulse correction unit.

[0018]

【Example】

Example 1. An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing the configuration of the present control device. 10 is a temperature setting unit for inputting a set room temperature in a heating device using a combustor, 11 is combustion based on the set temperature from the temperature setting unit 10. Combustion control unit for controlling 12
Is a pulse generation unit that generates a pulse for driving the electromagnetic pump 7 in order to burn at a combustion amount determined by the combustion control unit 11.

The power supply voltage detection unit 4, the electromagnetic pump power supply unit 5, the drive unit 6, and the electromagnetic pump 7 have substantially the same construction as the conventional example, and therefore their explanations are omitted. 8 is a pulse setting unit 12
A constant voltage determination unit 9 that receives a signal from the power supply voltage detection unit 4 after a predetermined time has elapsed from the rise of the output pulse and determines whether the voltage is a constant voltage, based on the determination by the constant voltage determination unit 8. This is a pulse correction unit that corrects the pulse width or period set by the pulse setting unit 12.

The combustion control unit 11, the pulse setting unit 12, the constant voltage determination unit 8 and the pulse correction unit 9 are constituted by the microcomputer 2.

FIG. 2 is an electric circuit diagram of the block diagram of the above configuration. In FIG. 2, 14 is a commercial power source,
Reference numeral 15 is a step-down transformer, 16 is a diode bridge for full-wave rectifying the alternating current of the commercial power supply 14, 17, 18, 19, 20
Is a resistor and a transistor that generate a zero-cross pulse from the full-wave rectified voltage, the output of which is input to the microcomputer 2.

Reference numeral 21 is a diode for current block, 22
Is a smoothing capacitor, 23 is a three-terminal regulator for producing a constant voltage for an electromagnetic pump, 24 and 25 are resistors and zener diodes for producing a power supply VDD for the microcomputer 2, and 26 and 27 are signals from the microcomputer 2. Are a resistor and a transistor that pulse-drive the electromagnetic pump 7. The microcomputer 2 has a ceramic oscillator 28 and a capacitor 2 which operate as a clock circuit.
9 and 30 are connected to generate a clock pulse based on the resonance frequency of the ceramic oscillator 28 to make the reference time of the microcomputer 2.

Further, reference numerals 31 and 32 are temperature setting switches and resistors, which input a set temperature to the microcomputer 2, and the microcomputer 2 controls the electromagnetic pump 7 and the load group 33 so as to reach these temperatures. Reference numerals 34 and 35 are a Zener diode and a resistor for detecting a constant voltage of the three-terminal regulator 23, and an analog voltage applied to the resistor 35 is converted into a digital value through an AD conversion circuit 36 and input to the microcomputer 2. 3 of the above
Reference numerals 4, 35 and 36 correspond to the power supply voltage detection section 4, 23 corresponds to the electromagnetic pump power supply section 5, 26 and 27 correspond to the drive section, respectively.

Next, the operation will be described with reference to the control flowchart of FIG. First, when the temperature is set by the temperature setting switch 31 (step 40), the microcomputer 2 determines the optimum combustion amount so as to reach that temperature (step 41), and the electromagnetic pump 7 corresponding to this combustion amount. The period and pulse width of the driving pulse of are set (step 42).

Next, the drive pulse is first turned on based on the set value (step 43), and the pulse width timer and the cycle timer are simultaneously started (step 44). These timers are realized by software based on the clock of the microcomputer 2. Next, it is determined whether or not the pulse width timer has passed the set time (step 45), and if it has passed, the drive pulse is turned off at the same time when the pump power supply voltage is read through the AD conversion circuit 36 (step 46). At this time, it is determined whether the pump power supply voltage is within the reference value (step 47), and if it is within the reference, waits until the period timer elapses the set time (step 49), and then returns to step 43 to restart the pulse Repeat on and off.

On the other hand, when the pump power supply voltage is out of the reference value, the routine proceeds to step 48, where a pulse width correction amount corresponding to the voltage fluctuation is calculated and a new pulse width is set. Hereafter, the pulse is turned on by this new pulse width,
Repeat off. Note that once the pulse width is corrected, if the reference value of the pump power supply voltage in step 47 is also changed, the pulse width is only corrected the first time, and if the power supply voltage does not change thereafter, the pulse width will be Not changed

FIG. 4 is a voltage waveform diagram for explaining the above operation. A is an input voltage of the three-terminal regulator 23, and the voltage fluctuates according to the voltage fluctuation of the commercial power supply 14. In addition, when the load current is large, the output voltage of the step-down transformer 15 is reduced, and the input voltage A is also reduced, depending on the voltage fluctuation rate of the step-down transformer 15. B is the output voltage of the three-terminal regulator 23 and is the input voltage A
Is used as a power source for the electromagnetic pump 7.

In FIG. 4, (a) is a voltage waveform diagram when the commercial power supply 14 is normal, for example, 100V. When the pulse is on, a large current flows, so the input voltage A drops, but since the difference with the output voltage B is large,
The output voltage B is kept constant. At this time, the constant voltage determination unit 8 detects the output voltage B at points a, b, and c, but the drive pulse is not corrected because it is a constant voltage.

Next, (b) is a voltage waveform diagram when the voltage of the commercial power source 14 drops. The input voltage A drops and the output voltage B keeps a constant voltage while the pulse is off, but the pulse When turned on, the input voltage A drops due to the influence of the load current, the output voltage B cannot maintain a constant voltage, and a ripple occurs each time the pulse turns on.

At this time, the constant voltage judging section 8 detects the output voltage B at each of the points a, b, and c, so that the valley point of the ripple voltage can be accurately detected. Then, at the time of the second pulse, the lack of the pulse area due to the voltage drop is compensated by widening the pulse width, and by making the pulse of the same area, the decrease of the fuel supply amount by the electromagnetic pump 7 is prevented, and the constant fuel is maintained. The supply can be maintained.

Embodiment 2 FIG. In the first embodiment, the pump power supply voltage is detected at one point when the pulse rises and is compared with the reference value preset in the microcomputer 2. However, as shown in the control flowchart of FIG. It may be performed at two points at the time of rising and the time of falling, and the deviation may be corrected.

In FIG. 5, first, in step 50, the pump power supply voltage V ₁ is read before the drive pulse is turned on. Thereafter, in step 46, the pump power supply voltage V ₂ is read again before turning off the drive pulse. Next, at step 47 (V
The deviation of ( _1- V ₂ ) is calculated, and the pulse width is corrected based on this value. The value of V ₁ may be read at any time when the pulse is not turned on. If the voltage of the commercial power supply 14 drops extremely, the voltage of V ₁ cannot maintain a constant voltage either. Therefore, the value of V ₁ becomes a reference value preset in the microcomputer 2 as in the first embodiment. You may make it compare.

FIG. 6 is a voltage waveform diagram in the second embodiment. By measuring the pump power supply voltage at two points of V ₁ and V ₂ and calculating the deviation thereof, it is possible to detect the fluctuation of the voltage power supply more accurately.

Example 3. FIG. 7 shows Embodiment 3 of the present invention, which is a voltage waveform diagram when the pump power supply voltage is measured at two points V ₁ and V ₂ and the pulse period is corrected based on the deviation. Thus, the same effect as that of the second embodiment can be obtained.

[0035]

As described above, according to the present invention, the combustion control section, the pulse setting section for setting the pulse applied to the electromagnetic pump based on the signal from the combustion control section, and the pulse setting section Drive unit for applying a drive pulse to the electromagnetic pump by the output of, an electromagnetic pump power supply unit for supplying a constant DC voltage to the drive unit to make the drive pulse a constant voltage, and a power supply for detecting the voltage of the electromagnetic pump power supply unit. A voltage detector,
A constant voltage determination unit that determines the constant voltage by reading the value of the power supply voltage detection unit after a predetermined time from the rise of the pulse output from the pulse setting unit, and the pulse setting based on the determination of this constant voltage determination unit Since it is equipped with a pulse correction unit that corrects the pulse width or pulse period set in the section, it is possible to accurately detect voltage fluctuations in the electromagnetic pump power supply section, regardless of any fluctuations in the commercial power supply. Is corrected, it is possible to always perform combustion in an optimum combustion state, and a highly reliable electromagnetic pump control device for a combustor can be obtained.

Further, since the constant voltage determination unit reads the value of the power supply voltage detection unit at the time of pulse falling to make a determination, it also accurately detects a ripple voltage and determines a voltage drop. Therefore, the drive pulse is accurately corrected, and the optimum combustion state is always obtained even if the voltage changes.

Further, the constant voltage determination unit reads the value of the power supply voltage detection unit when a pulse is not output from the pulse setting unit or when the pulse rises and after a predetermined time has elapsed from the rise of the pulse, and determines whether the voltage is a constant voltage. Since the determination is made as to whether or not the ripple-like voltage drop has occurred, it can be determined more accurately.

Furthermore, the constant voltage determination unit determines by the deviation between the pulse output from the pulse setting unit or the rise of the pulse and the value of the power supply voltage detection unit after a predetermined time from the rise of the pulse. I did so,
It is possible to accurately detect the fluctuation range of the ripple-shaped voltage and suppress the fluctuation of the fuel supply amount by performing the optimum correction in the pulse correction unit.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an electromagnetic pump control device showing an embodiment of the present invention.

FIG. 2 is an electric circuit diagram of an electromagnetic pump control device showing an embodiment of the present invention.

FIG. 3 is a control flowchart showing the operation of the electromagnetic pump control apparatus according to the first embodiment of the present invention.

FIG. 4 is a voltage waveform diagram for explaining the operation of the electromagnetic pump control device according to the first embodiment of the present invention.

FIG. 5 is a control flowchart showing an operation according to the second embodiment of the present invention.

FIG. 6 is a voltage waveform diagram illustrating the operation of the second embodiment of the present invention.

FIG. 7 is a voltage waveform diagram illustrating the operation of the third embodiment of the present invention.

FIG. 8 is a block diagram showing a configuration of a conventional combustion control device.

FIG. 9 is a voltage waveform diagram illustrating an electromagnetic pump control operation of a conventional combustion control device.

[Explanation of symbols]

 2 Microcomputer 4 Power supply voltage detection unit 5 Electromagnetic pump power supply unit 6 Driving unit 7 Electromagnetic pump 8 Constant voltage determination unit 9 Pulse correction unit 11 Combustion control unit 12 Pulse setting unit

Claims (4)

[Claims] 1. A combustion control unit, a pulse setting unit that sets a pulse to be applied to an electromagnetic pump based on a signal from the combustion control unit, and a drive pulse is applied to the electromagnetic pump by an output from the pulse setting unit. A drive unit, an electromagnetic pump power supply unit that supplies a constant DC voltage to the drive unit to make a drive pulse a constant voltage, a power supply voltage detection unit that detects the voltage of the electromagnetic pump power supply unit, and an output from the pulse setting unit. The constant voltage determination unit that reads the value of the power supply voltage detection unit after a predetermined time from the rise of the pulse and determines whether it is a constant voltage, and the pulse set by the pulse setting unit based on the determination of the constant voltage determination unit An electromagnetic pump control device for a combustor, comprising: a pulse correction unit that corrects a width or a pulse period. 2. The electromagnetic wave of a combustor according to claim 1, wherein the constant voltage determination unit reads and determines a value of a power supply voltage detection unit at the time of falling of a pulse output from the pulse setting unit. Pump controller. 3. A combustion control unit, a pulse setting unit that sets a pulse to be applied to the electromagnetic pump based on a signal from this combustion control unit, and a drive pulse is applied to the electromagnetic pump by the output from this pulse setting unit. A drive unit, an electromagnetic pump power supply unit that supplies a constant DC voltage to the drive unit to make a drive pulse a constant voltage, a power supply voltage detection unit that detects the voltage of the electromagnetic pump power supply unit, and a pulse from the pulse setting unit. Is not output, or when the pulse rises and the value of the power supply voltage detector after a predetermined time from the pulse rise is read, a constant voltage determination unit that determines whether the voltage is a constant voltage and a constant voltage determination unit of this constant voltage determination unit. An electromagnetic pump control device for a combustor, comprising: a pulse correction unit that corrects a pulse width or a pulse period set by the pulse setting unit based on a determination. 4. The constant voltage determination unit makes determination based on a deviation between a pulse output from the pulse setting unit or a rise of the pulse and a value of the power supply voltage detection unit after a predetermined time from the rise of the pulse. 4. The method according to claim 3, wherein
An electromagnetic pump control device for the described combustor.