JPH0363413A - Device for controlling electromagnetic pump for kerosene burner - Google Patents

Abstract

PURPOSE:To enable nullifying a change in applied voltage by a method wherein the voltage applied to an electromagnetic pump is detected and, according to the detected amount, the pulse width and the pulse period of the drive pulse applied to the electromagnetic pump are made variable and corrected. CONSTITUTION:A device for controlling an electromagnetic pump in equipped with a constant voltage-generating means 1b for generating a constant voltage, a detective means 1c for the output voltage, a switching means 1e for turning on and off the electromagnetic pump 1d, a pulse-controlling means 1g for the pulse fed to the switch, and a pulse-correcting means 1h which acts in accordance with signals from the means 1c. Furthermore, a counter-abnormality means 1i functioning to stop the machine when the correction exceeds a specified range is provided. Even when the voltage becomes variable because of lack of coordination among parts in the constant voltage-generating means 1b, this constitution corrects the pulse and, if the correction exceeds a certain range, stops the machine. Thus this constitution ensures stability of the combustion and safety of the combustion device.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to an electromagnetic pump control device for an oil combustor that sucks oil for combustion using an electromagnetic pump and supplies it to a combustion section.

BACKGROUND OF THE INVENTION As shown in FIG. 9, a conventional electromagnetic pump control device for a kerosene stove uses a transformer 9a, a rectifier diode 9b, and a smoothing capacitor 9C to obtain an unstable DC voltage. [Stable DC voltage due to the regulator consisting of [■] get. Furthermore, this DC voltage is applied to the transistor 9h connected in series with the electromagnetic pump 9g, and a pulse signal S1 of a predetermined pulse width and constant frequency is output from the output port (OF) of the microcomputer 91 to the transistor 9h. By controlling ON10 F F, a stable DC voltage pulse is applied to the electromagnetic pump 9g, and the plunger (not shown) in the electromagnetic pump is driven up and down by one magnetic force,
It is designed to supply kerosene to the combustion section.

Problems to be Solved by the Invention However, in the conventional configuration, the DC voltage (O) not only varies due to component variations in the Zener diode 9e, but also varies depending on the ambient temperature. For example, a Zener diode with a Zener voltage of 24 V In general, the Zener voltage component variation is about ±1 V, and the temperature coefficient is about 25 mV/'C, so if the guaranteed operation range of the device is -10°C to 40°C, the pump applied voltage will be about 22V. It varies by about ~2GV (±8%). As a general characteristic of electromagnetic pumps, there is a proportional relationship between the pump applied voltage and the discharge flow rate of the electromagnetic pump, so fluctuations in the applied voltage directly result in fluctuations in the combustion amount (±8%), which has a large effect on the combustion state. was there.

The present invention has been made in view of such problems, and it detects the voltage applied to the electromagnetic pump and corrects it by varying the pulse width and pulse period of the drive pulse applied to the electromagnetic pump according to the detected amount. As a result, the structure is such that fluctuations in applied voltage are canceled out, and the purpose is to improve combustion performance and equipment safety.

Means for Solving the Problems In order to achieve the above object, the electromagnetic pump YSM device for an oil combustor of the present invention includes constant voltage generating means for generating a constant voltage, and detecting the output voltage from the constant voltage generating means. Voltage detection means and the above! 0N10FI magnetic pump? a switch means for controlling the pulses supplied to the switch; a pulse control means for controlling the pulses supplied to the switch; and a pulse correction means for correcting the pulses in accordance with a signal from the voltage detection means, and a correction amount of the pulse correction means. The configuration includes an abnormality processing means that stops the equipment when the value exceeds a predetermined range.

According to the above structure, the present invention corrects the pulse even when the voltage varies due to variations in the parts in the constant voltage generating means, and also stops the device when the amount of correction exceeds a certain range. Therefore, it is possible to provide a combustor with stable and safe combustion.

Embodiment FIG. 1 is a block diagram showing an embodiment of the present invention, la
is a power source, lb is a constant voltage generating means, IC is a voltage detecting means for detecting the voltage of the two-voltage generating means 1b, ld is a magnetic pump for supplying kerosene to the combustion section (not shown), and 1e is an electromagnetic pump. This is a switch means for turning on/off the pump ld. Further, 1f is a combustion control means for controlling a combustion load group (not shown) such as a burner motor that supplies air for combustion, and 1g is an electromagnetic pump 1d provided in the combustion control means lf. 1h is provided in the pulse control means 1g and corrects the pulse signal in accordance with the signal from the voltage detection means 1c; 11 is the combustion control means; This is an abnormality processing means provided in the pulse correction means 1h that stops the equipment when the correction amount of the pulse correction means 1h exceeds a certain range.

Next, FIG. 2a shows the pulse signal waveform applied to the electromagnetic pump 1d, and the output voltage 2 from the constant voltage generating means 1b. By turning on/off the switch means 1e according to the pulse signal S1 from the pulse control means 1g, a pulse signal having an ON time (pulse width) A, and a pulse period B is obtained. Figure 2 shows the output voltage ■ due to variations in internal elements of the constant voltage generating means 1b. In the pulse waveform diagram showing the correction when V is varied, when vo becomes Vt (VL < VO), the ON time of the switch means 1e is AL (AL>
Ao) The pulse period is Bo. Conversely, when the output voltage vo becomes Vw (Vs>Vo) as shown in FIG. Then, the pulse signal is corrected.

The pulse signal voltage applied to the tifi pump and the amount of kerosene delivered from the electromagnetic pump are generally as shown in Figure 3a. On the other hand, the pulse width of the pulse signal (the ON time of the switch means 1e) and the amount of kerosene delivered from the magnetic pump 1d are generally as shown in FIG. Now, in Fig. 3a, if the output voltage vo changes from v0 to vIl and the amount of kerosene fed changes from Q0 to Q, the pulse correction means th has to absorb the fluctuation in the flow rate. ,
In Figure 3, the amount of kerosene fed is Q,
The pulse width A0 is set to A8 so that the voltage fluctuation is corrected by the pulse width (ON time) so that Qo )/Q, ).

FIG. 4 shows an example of a specific circuit of the main part. The combustion control means 1" is composed of a microcomputer lj and peripheral circuits. (The microcomputer shown here is
It is a so-called one-chip microcomputer that has a CPU, ROM, RAM, and input/output. ) The secondary side of the transformer 4a is rectified by a rectifier diode 4b, smoothed by a smoothing capacitor 4c, and connected to the collector of a transistor 4d, a resistor 4e, and a Zener diode 4.
A DC voltage Vo is obtained by a regulator configured with f. The DC voltage Vo is divided by a resistor 4g and a resistor 4h to form a pulse correction voltage VAN (hereinafter referred to as VAN). ■
□ is connected to an analog port AN that can directly read the analog voltage of the microcomputer. A transistor 4j is connected in series with the electromagnetic pump 1df, and a DC voltage vo is applied to both ends thereof. Further, the base of the transistor 4j is connected to the output terminal OF of the microcomputer lj via a resistor 4χ. The operation of the electromagnetic pump is based on the output port O of the microcomputer 1j.
, is H'', the transistor 4j is the ONL electromagnetic pump 1
d is a DC voltage V. is applied. Next, when the output port 02 of the microcomputer 1j is L", the transistor 4j is 0FFL. The DC voltage vo is no longer applied to the electromagnetic pump 1d, and the electromagnetic pump 1d stops. )O, is “H” “L”
By repeating ', the electromagnetic pump 1d is activated and kerosene is sent to the burner. Diode 41 is electromagnetic pump 1
This is a diode for absorbing the back electromotive force when d stops.

In the tank bottom as described above, each operation will be explained using the flowchart shown in FIG. A control program is stored in advance in a ROM (non-volatile memory) (not shown) of the microcomputer 1j, and a combustion control routine 5a is provided anywhere in the control program.

In the combustion control routine 5a, first, in step ST1, the voltage VAN from the analog boat AN is compared with a preset value VAN@, and is applied to an area D (hereinafter referred to as below) preset in the RAM of the microcomputer. In the 0th steno knob ST where the V AN V ANOO value is stored, the absolute value of D and the pre-sent (i D + ) are compared, and if D1≧D, the circuit is considered abnormal and step ST1 Dl< If D, proceed to step ST as normal.In step ST, it is determined whether the value of D is negative, 0, or positive.D
is negative, that is, V□<vA, and in the case of 10, in step ST1, AL is sent to A preliminarily provided in the RAM of the microcomputer, and D is 0, that is, VAN=
In the case of VAN@, ○ is set in A in step ST. If D is positive, that is, VAN>VAN@), step ST.

A is set to A, respectively. Next step S
At step ST, timer T1 that determines the pulse width is set to A, and timer T2 that determines the pulse period is set to Bo, and at step ST, the output port of the microcomputer 1j is set to or@'i-i'', and the transistor 4j is set to O.
N and apply a DC voltage vo to the electromagnetic pump 1d to operate the electromagnetic pump.

Start timer T1 and timer T2 in step ST,
In step ST, it is determined whether or not the timer TI has overflowed, and if it has not overflowed, the TI continues to operate. If there is an overflow, step ST
, set the output port ○ of the microcomputer lj to “L”
”, the transistor 4j is turned off in the 0th step ST.

It is determined whether or not timer T2 has overflowed. If there is no overflow, timer T2 continues to operate. If there is an overflow, the combustion control routine is terminated.

According to the configuration of the above embodiment, the voltage v applied to the electromagnetic pump
Vo = V* (VAN=VA
In the case of N,), the analog input voltage of the microcomputer becomes VANII, and the time Tl during which the switching transistor 4j is turned on is set to 60.

will be played. Voltage V applied to the electromagnetic pump. V. 〈■. In the case of (V<VANI+), AL (A
t > As ) is set, and the voltage vo applied to the zero-order electromagnetic pump varies and becomes V. >vo(v AN>V
□. ), the switch transistor 4j is turned on.
AH (AH × Ao) is cented at the time TI. That is, when the voltage vo applied to the electromagnetic pump varies and the flow rate of the electromagnetic pump varies, the time TI during which the switching transistor 4j is turned on is varied and corrected so that the flow rate does not vary. Furthermore, if the value of VAN exceeds a certain value, it is determined that the circuit is abnormal and the equipment is stopped.

Other Embodiments Another embodiment of the present invention will be described. However, the pronk configuration diagram and the specific circuit diagram of the main parts are the same as those in FIGS. 1 and 4 in the above embodiment.

Next, FIG. 6 shows the output voltage V due to variations in internal elements of the constant voltage generating means IC. In the pulse waveform diagram showing the correction when V is varied, when Vo becomes
<Be)ONN time.

Conversely, when the output voltage vo becomes Vll (VN is >■,), the ON period of the switch means 1e becomes Bn (BH<B
, ) ON time is A, and the pulse signal is corrected.

The pulse signal voltage applied to the electromagnetic pump and the amount of kerosene delivered from the electromagnetic pump are generally as shown in FIG. 3a. On the other hand, the ON period of the pulse signal (the period during which the switch means 4j is ON) and the amount of kerosene sent from the electromagnetic pump are generally as shown in FIG. Now the 4th
In Figure a, if the amount of kerosene fed changes from Q to Q, the pulse correction means 1h adjusts the amount of kerosene fed to Q*X in FIG. (1-(
The voltage fluctuation can be corrected by the ON period so that Q, -Q, )/Q, ).

In the above configuration, each operation will be explained using the flowchart of FIG. 8.

In the combustion control routine 8a, first, in step 5Tzt, the voltage V from the analog port (AN) is input. The value VAN that was confirmed. is compared with V□-V in D in RAM.
In the ninth step ST□ where the AND value is stored, the absolute value of D is compared with the pre-cented value Dl, and the IDI
If ≧D1, the circuit is abnormal and step 5Tzz
Process the abnormality and stop the equipment. If lDl<D, proceed to step 5Tzt as normal, step sTo
Then, it is determined whether the value of D is negative, 0, or positive. D is negative, that is, V
If ANI<VANI, BL is sent to B pre-provided in the RAM of the microcomputer at step 5Tzt, and when D is O1, that is, ■□=VANO, 80 is set to B at step ST□. D is positive, that is, VAN>v□. In this case, select B at step 5Tzt.
and B are set respectively. Next step 5Tzt
Ao is sent to the timer TI which determines the pulse width, and B is set to the timer T2 which determines the pulse period, and the output port O2 of the microcomputer 1j is set to "
Turn on the transistor 4j as H'' and turn on the electromagnetic pump ld.
■ DC voltage. is applied to operate the electromagnetic pump. The following operations are similar to those in the previous embodiment.

According to the above other embodiments, the voltage V applied to the electromagnetic pump,
■ There is no lightness. -Vo (VAN=VAN, ), the analog input voltage of the microcomputer is V
It becomes ANO and the switch transistor 4j turns on.
B is set to the cycle T2.

The voltage vo applied to the electromagnetic pump varies and v.

<Vo (VaH<Vase), when the switching transistor 4j is turned on, BL is
(Bt > 13.) is set.The voltage vo applied to the zero-order electromagnetic pump varies and Vo>V. (VAN>
VAN. ), B is set at period T2 when the switching transistor 4j is turned on. (BN<B@) is set. That is, when the voltage Vo applied to the electromagnetic pump varies and the flow rate of the electromagnetic pump varies, the cycle T2 in which the switching transistor 4j is turned on is varied and corrected so that the flow rate does not vary.

In one embodiment and other embodiments of the present invention, three cases have been described in which the voltage applied to the electromagnetic pump is lower than, equal to, or higher than the reference value, but depending on the degree of variation with respect to the reference value, It is also possible to perform multi-step or stepless correction. Further, the correction method may also be configured such that the pulse width and pulse period are varied at the same time.

Effects of the Invention As is clear from the above-mentioned embodiments, the present invention has the advantage of varying the pulse width of the pulse signal of the electromagnetic pump when the combustion amount varies due to variations in circuit components in the voltage supplied to the electromagnetic pump. By varying the period of the pulse signal, the flow rate is stabilized, and the equipment is stopped when the voltage applied to the electromagnetic pump is abnormally high or low, making it possible to provide an extremely safe combustor.

[Brief explanation of drawings]

Fig. 1 shows the constituent countries of the control device in one embodiment and another embodiment of the present invention, Fig. 2 shows a time chart of pulse signal voltage based on the same embodiment, and Fig. 3 shows the relationship between the pulse signal voltage and flow rate. and a graph showing the relationship between pulse width (ON time) and flow rate, Figure 4 is a circuit diagram showing the driving part of an electromagnetic pump based on the same embodiment and other embodiments, and Figure 5 is a graph showing the relationship between the pulse width (ON time) and flow rate. Based on the example (a flowchart showing an example of a combustion control program, FIG. 6 is a time chart of pulse signal voltage based on another embodiment, and FIG. 7 is a flowchart showing the pulse period of a pulse signal based on another embodiment). 8 is a flowchart showing an example of a combustion # control program based on another embodiment, and FIG. 9 is a circuit diagram showing the drive section of the tm pump of the conventional device. lb... ...constant voltage generation means, 1c...voltage detection means, 1d...electromagnetic pump, 1e...
...Switch means, Ig...Pulse control means, lh...Pulse correction means, 1i...
Abnormality processing means, lj...microcomputer.

Claims (4)

[Claims] (1) An electromagnetic pump that sucks up kerosene for combustion and supplies it to the combustion section, and a constant voltage generating means that generates a constant voltage.
Voltage detection means for detecting the output voltage from the constant voltage generation means; switch means for turning on/off the electromagnetic pump; pulse control means for controlling pulses supplied to the switch means; An electromagnetic pump control device for an oil combustor, comprising a pulse correction means for correcting the pulse according to the voltage. (2) The pulse correction means has a first level serving as a reference for comparison, and compares the voltage from the pulse correction means with the first level, and when the voltage from the pulse correction means is high, the voltage from the pulse correction means is high. Claim (1) wherein correction is made to shorten the time during which the switch means is ON, and to extend the time during which the switch means is ON when conversely, the time when the switch means is ON is low.
) Electromagnetic pump control device for an oil combustor. (3) The pulse correction means has a first level serving as a reference for comparison, and compares the voltage from the pulse correction means with the first level, and when the voltage from the pulse correction means is high, the voltage from the pulse correction means is high. increases the frequency with which the switch means is turned on,
2. An electromagnetic pump control device for an oil combustor according to claim 1, wherein, when the frequency is low, correction is made to reduce the frequency at which the switch means is turned on. (4) The pulse correction means has a first level serving as a reference for comparison, and compares the voltage from the pulse correction means with the first level, and when the compared value exceeds a certain range. The electromagnetic pump control device for an oil combustor according to any one of claims 1 to 3, further comprising an abnormality processing means for stopping the equipment as a circuit abnormality when the abnormality occurs.