JPH0519048B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention relates to an electromagnetic pump control device for an indoor open oil combustor.

Conventional technology In general, indoor open-air oil combustors provide heating by releasing the combustion gas combusted inside the device into the room. It is becoming common to mix the air with air from a fan and blow it out as warm air from between the hot air blowing louvers on the front of the device.

The electromagnetic pump control device used in such an indoor open type oil combustor will be explained along with its operation using the circuit diagram shown in Figure 6.The commercial AC voltage 1 is stepped down by the transformer 2, and the voltage of the transformer 2 is reduced. 2
An alternating current voltage v _a is generated between the next side p and q. AC voltage
v _a is an unstable DC voltage that is rectified and smoothed by diode 3 and capacitor 4 of constant voltage power supply circuit A.
Generate Va. This voltage Va becomes a stable DC voltage Vb by the series regulator circuit constituted by the resistor 5, the Zener diode 6, and the transistor 7 of the same circuit A. Here with Va
The relationship between Vb can be expressed by the following formula, assuming that the Zener voltage of the Zener diode 6 is Vz ₆ , the Zener current is Iz6, the DC current amplification factor of the transistor 7 is ∞, and the base-emitter voltage is V _BE7 .

Vb≒Vz ₆ −V _BE7 −I Since the Zener voltage and the transistor base-emitter voltage are generally considered to be constant,
Vz ₆ and V _BE7 are constant, and Vb is a constant value regardless of Va as shown in formula I. Now, when the output terminal O1 of the microcomputer 11 in which the combustion control section, pulse generation section, etc. are provided in the nonvolatile memory is "H", no power is supplied to the photodiode 8a of the pump driving photocoupler. Therefore, the phototransistor 8b of the photocoupler for driving the pump is
Since it is in the OFF state, transistor 9 is turned on,
A constant DC voltage Vb is supplied to the electromagnetic pump 10. Next, O1 of the output terminal of the microcomputer 11
When is "L", the photodiode 8a of the pump driving photocoupler is supplied with power, so the phototransistor 8b is turned on and the base-emitter of the transistor 9 is shot. Therefore, the transistor 9 is turned off, and the electromagnetic pump 10 is turned off.
will not be supplied with power. By repeating the above steps, the pump drive circuit B operates the electromagnetic pump 10 to supply petroleum to the combustor for vaporization and combustion. Based on the signal from the pulse generator provided in the microcomputer 11, the transistor 9
By controlling the ON/OFF interval of the combustion engine, the combustion state can be changed from strong to weak.

Problems to be Solved by the Invention However, in this pump control device, the constant voltage power supply circuit A fails for some reason and the electromagnetic pump 1
When the voltage applied to Vb becomes larger than Vb, the discharge amount of the electromagnetic pump 10 changes significantly.

For example, if the Zener diode 6 becomes open for some reason, Vz ₆ =∞, that is, Vb = ∞ (actually Va≒
Vb), and an excessive voltage is applied to the electromagnetic pump 10. FIG. 5 is a diagram showing such a state. In general, the unstable DC voltage Va is the stable DC voltage, taking into account fluctuations in commercial AC voltage.
It is set to a higher level than Vb. Vp is a pulse waveform applied to the electromagnetic pump 10 during normal operation. That is, the voltage Vp applied to the electromagnetic pump 10 becomes approximately equal to Vb. Due to an open failure of the Zener diode 6 or a short failure between the collector and emitter of the transistor 9, an excessive voltage as indicated by the broken line Vp' in FIG. 5 is applied to the electromagnetic pump 10. Furthermore, the same situation as described above occurs when the collector-emitter of the transistor 9 is shorted. When an excessive voltage is applied to the electromagnetic pump 10, the stroke of a plunger (not shown) in the electromagnetic pump 10 becomes longer, and the amount of oil supplied per pulse increases. For this reason, the length of the flame within the burner increases, and in some cases, the flame may blow out from the outlet louver of the heater. Note that there are cases where the oil decreases, but in that case, the flame rod will detect it. However, in the above-mentioned case, the flame rod will not detect any abnormality because there will be a lot of flame. Therefore, to solve such problems, it was necessary to rely on improving quality.

The present invention was made in view of these points.
The purpose is to prevent flames from emitting outside the device.

Means for Solving the Problems In order to achieve the above object, the present invention includes a combustion control section, a pump drive circuit that drives an electromagnetic pump based on a signal from the combustion control section, and a direct current to the pump drive circuit. A configuration including a constant voltage power supply circuit that supplies a constant voltage, and an abnormal voltage control section that detects abnormal output voltage of the constant voltage power supply circuit and stops combustion to prevent flame from emitting outside the device body. be.

Effect: With the above configuration, the present invention detects and stops combustion when excessive voltage is applied to the electromagnetic pump due to component failure, etc., so that flames do not come out from the hot air outlet, etc. You can use it without any worries.

Embodiment An embodiment of the present invention will be described below based on the drawings. The constant voltage power supply circuit A, the pump drive circuit B, and other parts with the same numbers as in FIG.
It is the same as the figure, and the explanation will be omitted. In this circuit, an abnormal voltage detection section C is provided between the constant voltage power supply circuit A and the pump drive circuit B, and the microcomputer 11 stops combustion upon receiving a signal from the abnormal voltage detection section C. A stop control section and an alarm generating section are provided. An abnormal voltage control section D is newly provided.

Abnormal voltage detection section C detects the output of constant voltage power supply circuit A.
A resistor 14 and a Zener diode 15 between Vb,
Photodiodes 16a of photocouplers for abnormal voltage detection are connected in series. Here, the Zener voltage Vz15 of the Zener diode 15 is
As shown in FIG. 5, Vb is set to be equal to Vs, which is set to a higher level than Vb. Next, a resistor 18 and a light emitting diode 19 are connected in series between the output terminal O3 of the microcomputer 11 and the DC converter 17. Note that 20 in the figure represents all load groups such as fan motors.

In the above configuration, when the constant voltage power supply circuit A is normal, Vz ₁₅ >Vb. At this time, since the internal resistance of the Zener diode 15 becomes a very large value, no current flows through the photodiode 16a of the abnormal voltage detection photocoupler. Therefore, phototransistor 1 of the photocoupler for abnormal voltage detection
6b is turned off, an "H" signal is input to the input terminal _I1 of the microcomputer 11. Next, when the constant voltage power supply circuit A generates an abnormal voltage (Vs or more), since Vz ₁₅ <Vp, the internal resistance of the Zener diode 15 becomes a very small value, and the voltage is applied to the photodiode 16a of the photocoupler for abnormal voltage detection. Power is applied. Therefore, the phototransistor 16b of the abnormal voltage detection photocoupler is turned on.
Therefore, an "L" signal is input to _I1 . Next, the stop control section provided on the control program in the microcomputer 11 will be explained using FIG. 2. Assuming that the constant voltage power supply circuit A is normal and an "H" signal is input to the input terminal _I1 of the microcomputer 11, in step 21,
Since I ₁ =“H”, the process branches to NO and performs normal main processing 22 without performing abnormality processing. If the constant voltage power supply circuit A is abnormal, I ₁ = “L” in step 21, so the branch goes to Yes, and in step 23, the output terminal of the microcomputer 11 is
_O1 is set to "L" to drive the phototransistor 8b of the photocoupler for driving the pump, shoot the base and emitter of the transistor 9, and turn off the transistor 9 to stop power supply to the electromagnetic pump 10. Next, in step 24, the output terminal _O3 of the microcomputer 11 is set to "L", the light emitting diode 19 is turned on, and the abnormality is notified to the outside. In step 25, each load is controlled when combustion is stopped.

Next, another embodiment of the abnormal voltage detection section C of the present invention will be described using FIG. 3. This abnormal voltage detection section C obtains a constant voltage V ₁ determined by the Zener voltage of the Zener diode 27 from the output Vb of the constant voltage power supply circuit using the resistor 26 and the Zener diode 27 .
This _V1 always remains a constant voltage (Zener voltage of the Zener diode 27) even if the value of Vb changes.
Then, V ₁ is divided by a resistor 28 and a resistor 29 to obtain a reference voltage V ₂ . On the other hand, Vb is divided by a resistor 30 and a resistor 31 to obtain a detected voltage _V3 . Here, V ₃ is as shown in Figure 5, when Vb becomes larger due to Vs set to a higher level than Vb, V ₃ > V ₂
It is set so that And each of the above V ₁ ,
The voltages of V ₂ and V ₃ are the power supply terminals of the comparator 34,
It is connected to the inverting input terminal 34a and the inverted input terminal 34b, respectively. The output of the comparator 34 is connected to the base of a transistor 35 through a resistor 32, and the collector of the transistor 35 is connected to a photodiode 16a of a combustion control photocoupler.
and is connected to Vb via a resistor 36.

In the above configuration, when the constant voltage power supply circuit A is normal, Vb<Vs. Therefore, V ₂ > V ₃ and the output of the comparator 34 becomes “L”.
The transistor 35 is turned off and no power is supplied to the photodiode 16a of the abnormal voltage detection photocoupler. At this time, the phototransistor 16b of the abnormal voltage detection photocoupler is turned off, and an "H" signal is input to the input terminal _I1 of the microcomputer 11. Next, when the constant voltage power supply circuit A generates an abnormal voltage, Vb>Vs. Therefore, the output terminal of the comparator 34 becomes "H", the transistor 35 is turned on, and the photodiode 16a of the abnormal voltage detection photocoupler is energized. At this time,
Since the phototransistor 16b of the abnormal voltage detection photocoupler is turned on, an "L" signal is input to the input terminal _I1 of the microcomputer 11.
Note that the other circuit configurations and processing within the microcomputer 11 are the same as in the previous embodiment, and their explanations will be omitted. With the circuit configuration as above,
The Zener voltage can be freely selected considering the temperature characteristics of the Zener diode 27, and the resistor 3
The abnormal voltage detection level can be easily varied by simply changing the voltage division ratio of 0 and 31, thereby improving detection accuracy and simplifying the design.

Furthermore, as shown in FIG. 4, the abnormal voltage detection section is configured as a window comparator. That is, Vb
The voltage of is divided by resistors 37, 30, and 31, and two divided voltage levels are provided for each, V ₃ and V _4. V ₄ is applied to the inverting input 31a of the open collector output type comparator 38, and V 4 is applied to the inverted input 31b. V ₂ is connected to the inverting input 34a of the open collector output type comparator 34, and V ₂ is connected to the inverting input 34a of the open collector output type comparator 34.
Connect V ₃ to b, comparators 34 and 38
The output of is wired OR connected with a resistor 39, and this wired OR output K is an inverter (inverted) composed of a resistor 40, a transistor 41, and a resistor 42.
The circuit inverts the logic and connects it to the resistor 32. In addition, each comparator 34 and 3
Connect the power supply of 8 to V ₁ (V ₁ > V ₄ > V ₃ ), and connect V ₂ to V ₁
If the configuration is set to an appropriate value below, when the value of Vb changes and becomes a voltage such that V ₂ < V ₄ or V ₂ > V ₃ , the wired OR connected point K will be It becomes "L", turns off the transistor 41, turns on the transistor 35, and transmits an abnormal voltage signal to the microcomputer through the photo diode 16a of the photo coupler for abnormal voltage detection.

If you configure the circuit as above and set V ₃ and V ₄ to appropriate values, the voltage will be reduced only when Vb exceeds a certain range, that is, when Vb becomes higher than the normal voltage. It can also be detected when the temperature is low or low, further improving safety.

Effects of the Invention As is clear from the description of each embodiment above, according to the present invention, it is possible to prevent an increase or decrease in oil supply amount in the event that the voltage applied to the pump becomes abnormal, and to This prevents flames from blowing out of the device itself, which is a problem unique to devices. It is also possible to prevent abnormal combustion due to insufficient oil supply. In particular, the present invention has the advantage of rapid operation and dramatically improved safety. In other words, as in the present invention, a possible method for preventing flames from blowing out is to provide a temperature sensing element such as a thermistor or thermostat at a suitable location on the main body of the device, for example at the hot air outlet, and to stop the operation due to the rise in temperature. While all of them have operation delays, the present invention has almost no detection delay and ensures extremely high safety.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram of an electromagnetic pump control device according to one embodiment of the present invention, FIG. 2 is an explanatory diagram of the operation of the same essential parts, FIGS. 3 and 4 are circuit diagrams showing other embodiments of the invention, and FIG. FIG. 5 is an explanatory diagram of a voltage pulse waveform, and FIG. 6 is a conventional circuit diagram. 11... Combustion control section (microcomputer),
A... Constant voltage power supply circuit, B... Pump drive circuit,
D...Abnormal voltage control section.

Claims (1)

[Claims] 1. A combustion control section, a pump drive circuit that drives an electromagnetic pump based on a signal from the combustion control section, a constant voltage power supply circuit that supplies a constant DC voltage to this pump drive circuit, and An indoor open type oil combustor that has an abnormal voltage control section that detects the output voltage of a constant voltage power supply circuit and stops combustion when it exceeds a preset value to prevent flames from emitting outside the device body. Electromagnetic pump control device. 2. The electromagnetic pump is configured to adjust the supply amount of petroleum based on the pulse width or pulse period of a pulse signal from a pulse generator provided in the combustion control unit. Electromagnetic pump control device for type oil combustor. 3 The abnormal voltage control section includes an abnormal voltage detection section that detects the voltage applied to the electromagnetic pump and compares it with a predetermined voltage, and a stop control section that stops combustion based on the signal from the abnormal voltage detection section. and,
An electromagnetic pump control device for an indoor open oil combustor according to claim 1, comprising an alarm unit that notifies the outside of an abnormality.