JPH02287012A - Magnetic pump controller for oil burning apparatus - Google Patents

Abstract

PURPOSE:To enlarge the variable combustion range by a method wherein the pulse signal voltage and frequency applied to a pulse signal output device of a magnetic pump controller are kept low for low combustion rate, and high for high combustion rate. CONSTITUTION:A pulse signal output device 5 outputs pulse signals having a regular pulse width T1 according to the combustion rate determined by a combustion decision routine. The pulse signal voltage is regulated by a pulse signal voltage regulator 6 to control a magnetic pump 3. At this time, the pulse signal voltage V and interval T are changed to a voltage VH or VL and an interval TH or TL which fulfill conditions of VH > LL and TH<= TL (where H shows high calorie, and L shows low calorie) depending upon whether the combustion rate is in high calorie or in low calorie. By this constitution, high calorie combustion can be carried out with problems of the mechanical response of the magnetic pump avoided, and low calorie combustion can be performed without worries about abnormal combustion such as pulsating combustion.

Description

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

Conventional technology Conventionally, as shown in Fig. 1, the 1t [pump control device] of an oil-burning machine obtains an unstable DC voltage 1 with a transformer 101, a rectifier diode 102, and a smoothing capacitor 03, and then a transistor 04 and a zener. Diode 105 and resistor 1
Stable DC voltage ■ by the regulator circuit composed of 06 and 06. get. Furthermore, this DC voltage is applied to the tm pump 10.
A pulse signal S having a predetermined pulse width and a constant frequency is output from the output port OF of the microcomputer 108 to the transistor 107 connected in series with the transistor 07.
Stable DC voltage pulse ■ to the electromagnetic pump 106 by F control. is applied to suck up kerosene and supply it to the combustion section.

Problems to be Solved by the Invention However, in order to increase the range of combustion amount in the conventional configuration described above, it is necessary to increase the variable range of the pulse frequency applied to the electromagnetic pump. However, if you increase the pulse frequency to obtain high calories, the mechanical response of the electromagnetic pump becomes an issue, and you cannot increase the frequency very much.On the other hand, if you lower the pulse frequency to reduce calories, kerosene is sent intermittently and is burned. The problem was that the balance with the air used for combustion was disrupted, resulting in incomplete combustion, and the flame itself pulsed in time with the pulse, resulting in uneven combustion.

The present invention was made in view of these problems.When the amount of calories burned is high, the pulse signal voltage is increased without extremely increasing the pulse signal frequency to obtain high calories.On the other hand, when the amount of combustion is low, The structure is such that low calories can be obtained by lowering the pulse signal voltage without extremely lowering the pulse signal frequency, and the purpose is to provide a combustor with a wide combustion variable range.

yAI! In order to achieve the above object, the electromagnetic pump control device of the present invention includes a pulse signal output means for changing a pulse signal with a constant pulse width to a predetermined frequency and outputting the pulse signal, and a pulse signal output means for changing the pulse signal of a constant pulse width to a predetermined frequency. and a pulse voltage adjustment means for adjusting the signal voltage, and controls the pulse frequency from the pulse signal output means to vary according to the amount of combustion, and the voltage applied to the electromagnetic pump to obtain the desired amount of combustion. This configuration includes a combustion control means for controlling the combustion.

Effect of the present invention With the above-mentioned configuration, high calories can be obtained in the frequency range that the electromagnetic pump follows in the case of high calories, and conversely, even in the case of low calories, abnormal combustion such as pulsed flame combustion can be avoided. Therefore, it is possible to provide a combustor with an extremely wide variable combustion range.

Embodiment FIG. 1 is a configuration diagram showing an embodiment of the present invention, where ◯ is a burner, 2 is a burner motor that supplies air for combustion to the burner 1, and 3 is an electromagnetic unit that supplies kerosene for combustion to the burner 1. a pump; 3a is a tank for storing kerosene; 4 is combustion control means for controlling the burner motor 2, electromagnetic pump 3 and other loads (not shown); 5 is provided in the combustion control means 4; The pulse signal output means 6 is a pulse voltage adjustment means provided in the combustion control means 4.

Next, Fig. 2 shows the pulse signal waveform applied to the electromagnetic pump 3, and when the calorie is high, the pulse signal voltage 7 is as shown in 2-a.
, pulse signal width TI, pulse interval T, and when the calorie is low, the pulse signal voltage VL (Vt
<Vw ), pulse signal width Tl, pulse interval T, (T
L≧TN), and the pulse signal voltage (8) and pulse interval T (i) during high calorie times and the pulse signal voltage (vL) and pulse interval TL during low calorie times are respectively varied. Figure 3 is a graph showing the pulse signal voltage applied to the electromagnetic pump and the amount of kerosene sent from the electromagnetic pump. The amount of kerosene delivered is proportional. Therefore, the amount of kerosene sent from the electromagnetic pump can be controlled not only by varying the period of the pulse signal but also by varying the pulse signal voltage applied to the electromagnetic pump.

FIG. 4 shows an example of a specific circuit of the main part. The combustion control means 4 is composed of a microcomputer 7 and peripheral circuits (not shown). (The microcomputer 7 shown here is a so-called one-chip microcomputer that has a CPU, ROMRAM, and input/output.) The secondary side of the transformer 101 is rectified by a rectifying diode 102 and smoothed by a smoothing capacitor 103. The collector of the transistor 104 and the resistor 106 are connected to this non-z stable DC voltage, and the other end of the resistor 106 is connected to the base of the transistor 104. A Zener diode 8 is connected between the base of this transistor 104 and the ground.
and Zener diode 9 are connected in series, and the collector of transistor 1oO is connected between Zener diode 8 and Zener diode 9. The emitter of the transistor 100 is connected to the ground, and the base is connected to the output port 0) IL of the microcomputer 7 via a resistor 11. Now, when the output of output port 0IIL is '°l,'', 4Ji l-transistor 100
The cigarette is turned off■. -V,, -+-V. 〜■sy(=Vw).

Next, when the output of the output capacitor ()0 is "■]", the transistor lOO is ONL, the Zener diode 9 is the transistor 1. Since it is switched by OG, only the Zener diode 8 is connected between the base of the transistor 104 and the ground, and the emitter voltage V0 of the transistor 104 is ■. -V21 V□(-VL), and the voltage applied to the tm pump 3 is varied.

Further, the other end of the itm pump 3 is connected to the collector of the transistor 107, and the emitter of the transistor 107 is connected to the ground, and is also connected to the output port O1 of the microcomputer 7 via the base resistor 109. Output port 0 of microcomputer 7. When is ■1', the transistor 107 is turned on, and the DC voltage is applied to the magnetic pump 3. is applied.

Next, the output port 0° of the microcomputer 7 is “L”.
”, the transistor 107 is 0FFL, and the electromagnetic pump 3 receives no DC voltage ■, and the it&1 pump 3 stops. The output port of the microcomputer 7 is 0.
．． iui by repeating “11′1 “I2”
Pump 3 operates and kerosene is sent to burner 2. The diode 110 is a diode for absorbing back electromotive force when the electromagnetic pump 3 stops.

In the above configuration, each operation will be explained using the flowchart of FIG. 2. A control program is stored in advance in a ROM (non-volatile memory) of the microcomputer 7, and a combustion control routine 50 is provided at an arbitrary location in the control program. In the combustion control routine 50, the combustion amount is determined in the combustion amount determination routine 51.Next, in step S1, it is determined whether the combustion amount is strong or weak, and if it is strong, the pulse interval T2 is set in step S2. T
, and in step S3, the output port 0 of the microcomputer 7 is set to "■," and the transistor is set to 1.00.
Turn off the direct 2 voltage ■. Let be ■8. On the other hand, if the judgment in step Sl is weak, the pulse interval T2 is set to TL (TL≧T,) in step S4, and step S
5 sets the output port ost of the microcomputer 7 to “H”.
"ON" turns on the transistor 100 and increases the DC voltage v0.
2-0 Next, in step S6, the output cap of the micro combinator 7 is set to "H", in step S7, the timer T1 is activated, and in step s8, it is determined whether or not the timer 'r1 has overflowed. After making a judgment, if there is no overflow, the TI continues to operate. If there is an overflow, T1 is initialized in step s9. Step SlO
Then, the output port O7 of the microcomputer 7 is set to L'' to turn off the transistor 107, the pulse interval timer T2 is activated in step Sll, and it is determined in step 512 whether or not the timer T2 has overflowed. If so, I2 continues to operate.

If there is an overflow, I2 is initialized in step 513 and the combustion control routine is ended.

According to the configuration of the above embodiment, during strong combustion (high calorie), the pulse signal voltage 6 is set to VM (>VL), and
Set the pulse signal interval T2 to TM (≦'ri,), and set the pulse signal voltage v0 to VL during weak combustion (low calorie).
(<VM), and the pulse signal interval T2 is set to TL
(≧TM), therefore, during high calorie times, high calories can be obtained by increasing the pulse signal voltage without extremely increasing the pulse signal frequency (1/(TI+T2)), and weak combustion (low calorie), the pulse signal voltage ■. Since the pulse signal interval T2 is set to be VL (<VW) and the pulse signal interval T2 is set to TL (≦'r, l), the pulse signal voltage can be lowered without extremely lowering the pulse signal frequency (1/(T1+T2)). As a result, low calorie content can be obtained, and the amount of kerosene (calories) fed by the electromagnetic pump can be varied over a wide range from strong to weak.

More than the effects of the invention, as is clear from the description of the examples, the present invention can be applied according to the required calories! Since the frequency of the pulse signal of the magnetic pump is varied and the pulse signal voltage is also varied, high calories can be obtained without making the mechanical response of the electromagnetic pump an issue, and low calories can be obtained without abnormal combustion such as pulsed combustion. Therefore, it is possible to provide a combustor with a wider combustion range.

[Brief explanation of drawings]

Fig. 1 is a configuration diagram of an electromagnetic pump control device according to an embodiment of the present invention, Fig. 2 is a time chart of pulse signal voltage based on the same embodiment, and Fig. 3 is a graph showing the relationship between pulse signal voltage and flow rate. , Fig. 4 is a circuit diagram showing the driving part of the electromagnetic pump based on the same embodiment, Fig. 5 is a flowchart showing an example of the same combustion control program, and Fig. 6 shows the driving part of the electromagnetic pump of the conventional device. It is a circuit diagram. 3... Electromagnetic pump, 4... Combustion control means, 5... Pulse signal output means,

Claims (1)

[Claims] In an oil combustion machine that sucks up kerosene for combustion with an electromagnetic pump and supplies it to a combustion section, there is provided a pulse signal output means for changing a pulse signal of a constant pulse width to a predetermined frequency and outputting the pulse signal, and a pulse signal voltage of the pulse signal output means. and a pulse voltage adjusting means to adjust the pulse signal voltage and the frequency of the pulse signal when the combustion amount is low, and conversely, when the combustion amount is high, the pulse signal voltage and the frequency of the pulse signal are increased. An electromagnetic pump control device for an oil combustion machine, which is equipped with a combustion control means that controls the combustion so that the