KR0171929B1 - Combustion control method for oil-combustor - Google Patents

Abstract

The present invention relates to a combustion control method of an oil combustor capable of preventing tar generation or abnormal combustion by sensing a temperature of a carburetor and controlling an air volume, and the present invention relates to a combustion control method of an oil combustor having a vaporizer. The method may include: detecting a temperature of a vaporizer through a temperature sensing element attached to the vaporizer; comparing the temperature of the vaporizer detected by the temperature sensing element with a predetermined temperature of a preset vaporizer; Increasing the number of revolutions of the blower fan when the detected temperature of the vaporizer is higher than the preset temperature of the carburetor; and if the temperature of the vaporizer detected by the temperature sensing element is lower than the preset temperature of the carburetor, The invention comprises a step of reducing the number of revolutions.

Description

Combustion Control Method of Oil Combustor

1 is a cross-sectional view of main parts of an oil burner for implementing the present invention.

2 is a schematic diagram for implementing a combustion control method of an oil combustor according to the present invention.

3 is a view showing the relationship between the flow rate of the electromagnetic pump and the fan speed during combustion of the oil burner.

4 is a flowchart illustrating a combustion control method of an oil combustor according to the present invention.

* Explanation of symbols for main parts of the drawings

10: burner 11: carburetor

12 heater 13 dispersion fan

14: nozzle 15: diffusion motor

FM: Blowing motor TH: Temperature sensing element

FG: Rotation speed detection element EP: Electronic pump

20: microcomputer 30: vaporizer temperature detection unit

40: electronic pump drive unit 50: blowing fan drive unit

60: blower fan speed detection unit

The present invention relates to a control method of an oil combustor such as a rotary heater, and more particularly, to a combustion control method of an oil combustor capable of preventing the generation of tar or abnormal combustion by adjusting the airflow amount by sensing a temperature of a vaporizer. The burner 10 structure and operation of the general rotary heater, as shown in FIG. 1, when the start operation command is input, energizes the heater 12 to preheat the vaporizer 11. Then, the temperature of the vaporizer 11 is detected through the temperature sensing element TH attached to the vaporizer 11, and when the temperature of the vaporizer 11 is detected as the ignition temperature, the blowing fan is not shown. After the blower fan is driven, the rotation speed (RPM) of the blower fan becomes constant, that is, when the amount of airflow to the vaporizer 11 and the flame net (burner head) becomes constant, the electronic pump is not shown. The fuel is injected into the dispersion fan 13 which is rotated by the driving of the diffusion motor 15 through the nozzle 14, and the fuel is evenly injected on the inner wall of the vaporizer 11 and vaporized at the same time. To the net. At this time, the ignition operation is started while the igniter installed on the upper part of the ball network sparks, and when it is ignited, a normal combustion operation is performed. In addition, the combustion operation compares the temperature set by the user with the room temperature, and when the difference is greater than or equal to a certain value, the combustion proceeds to "strong" combustion, and when the difference is smaller than the predetermined value, the combustion operation proceeds to "weak" combustion. Combustion and "weak" combustion are determined by the rotational speed (RPM) of the blower fan and the flow rate of the electromagnetic pump as shown in FIG. 3, and the rotational speed of the blower fan is linearly changed as the flow rate is changed from α1 to α2. It varies from β1 to β2, and when it is "strong" combustion, it is the thermal power when the flow rate is α2 and the blowing fan rotation is around β2. When it is "weak" combustion, when the flow rate is α1 and the blowing fan rotation is about β1, It represents firepower. However, in performing the combustion operation of such "strong" combustion or "weak" combustion, the flow rate or air volume injected into the vaporizer 11 at the time of "strong" combustion and "weak" combustion becomes different, As the temperature of the vaporized gas is changed and tar formation and stable vaporization conditions cannot be maintained, the ignition point of the flame from the flame network of the burner 10 head to the outside during `` strong '' combustion is increased. The sparking (LIFTING) is released, and when the `` weak '' burning occurs a flash back to the combustion point of the flame into the inside of the ball network, causing tar and odor, which causes the set conditions (carburetor structure) ) Could have occurred more frequently.

The present invention is invented to improve the above-mentioned problems of the prior art, the object of the present invention is to reduce or increase the number of revolutions of the blower fan according to the temperature of the vaporized gas vaporized in the vaporizer to maintain an ideal combustion state A combustion control method of an oil combustor is provided.

Features of the combustion control method of the oil combustor according to the present invention for realizing the above object. A combustion control method of an oil combustor having a vaporizer, the method comprising: detecting a temperature of a vaporizer through a temperature sensing element attached to the vaporizer; specifying a temperature of the vaporizer detected through the temperature sensing element and a preset vaporizer; Comparing the temperature, if the temperature of the vaporizer detected by the temperature sensing element is higher than the predetermined temperature of the preset vaporizer, increasing the number of revolutions of the blowing fan, the temperature of the vaporizer detected through the temperature sensing element is And reducing the number of revolutions of the blowing fan when the temperature is lower than the preset temperature of the vaporizer.

Hereinafter, with reference to the accompanying drawings an embodiment of a combustion control method of an oil burner according to the present invention.

The present invention will be described in more detail with reference to the accompanying drawings.

2 is a schematic configuration diagram for implementing the combustion control method of the oil combustor according to the present invention, reference numeral 20 denotes a microcomputer, a predetermined program according to the present invention is incorporated, and the entire operation of the apparatus is controlled.

Reference numeral 30 denotes a vaporizer temperature sensing unit, which is composed of a temperature sensing element TH, a resistor R1, a R2, and a condenser C1, and resists a resistance of the temperature sensing element TH that varies according to the temperature of the vaporizer 11. The input signal P1 of the microcomputer 2 is inputted as a voltage distribution signal with the R1 to allow the microcomputer 20 to recognize the temperature of the vaporizer 11.

Reference numeral 40 denotes an electronic pump driving unit, which is composed of an electronic pump EP, a relay RY, a resistor R3, a diode D1, an inverter l1, l2, and a photocoupler PC, and the microcomputer 20 ) Outputs a high signal to the port P3, the output high signal energizes the relay RY through the inverter 12, and its switch contact is turned on so that the power supply AC is applied to the electronic pump EP. At the same time, by outputting a pulse of a predetermined frequency to the port (P2) to turn on the photocoupler (PC) intermittently through the inverter (11) to apply a predetermined voltage to the electromagnetic pump (EP) pumping action Initiate.

Reference numeral 50 denotes a blower fan driver, which is composed of a resistor R4, an inverter l3, a phototriac PT, and a blower motor FM, and the microcomputer 20 outputs a predetermined pulse signal to the port P4. Power to drive the blower motor FM by energizing the phototriac PT through the inverter l3, and the power applied to the blower motor FM according to the ON time of the phototriac PT. The effective value of AC is varied to control the blowing amount by varying the rotation speed RPM of the blowing motor FM.

Reference numeral 60 denotes a fan fan speed detection unit, which is composed of a rotation speed detection element FG, a resistor R5 to R7, a diode D2, a capacitor C2, C3, and a transistor Q1. When the FM is driven, the rotation speed detecting element FG generates a predetermined pulse signal proportional to the rotation speed of the blower motor FM and applies it to the base of the transistor Q1 through the resistor R5. Accordingly, the transistor Q1 operates to input a predetermined pulse signal to the port P5 of the microcomputer 20 through the resistor R7 and the capacitor C3. Therefore, the microcomputer 20 detects the signal at this time and detects the rotation speed of the blower motor FM.

The operation and effect of the present invention configured as described above will be described with reference to the control flowchart of FIG.

First, when power is applied and the operation start signal is input by a key input circuit (not shown), the microcomputer 20 generates the vaporizer 11 preheating heater 12 and heats the temperature of the vaporizer 11. When the ignition temperature that can be detected by (TH) and attempt to ignite is detected, the blower motor (FM) is driven by a predetermined output to the port (P4), and after a certain time (for example, 5 seconds) the blower motor When the RPM of the FM is stabilized through the rotation speed detection unit 60, the ignition is attempted. The fuel is supplied to the nozzle P 14 by driving the electron pump EP by performing a predetermined output to the ports P2 and P3. Through the injection into the dispersion fan 13 which is rotated by the drive of the diffusion motor 15 through the fuel is evenly injected to the inner wall of the vaporizer 11 is vaporized at the same time to rise above the burner (10). At this time, the ignition is started by the spark of an igniter (not shown) installed on the salt network (step S1), and when the current of the flame is detected as a ignition success current through a flame detection rod (not shown), the ignition is started. If the success is successful, and if the current of the flame through the flame detection rod is not detected as the ignition success current immediately above a predetermined value, the ignition operation to retry the ignition is performed (step S2).

Then, normal combustion control is performed based on the temperature set by the user (step S3).

While the oil combustor performs a normal combustion operation, the microcomputer 20 determines whether a fire extinguishing command is input (step S4) and performs a fire extinguishing operation if a fire extinguishing command is input (step S4).

If the extinguishing command is not input, the temperature of the vaporizer 11 is detected through the temperature sensing element TH attached to the vaporizer 11 (step S6). Here, the reason for detecting the temperature of the vaporizer 11 is that, if backfire or lifting occurs in the burner 10 head, the temperature of the vaporizer 11 is affected by the conduction phenomenon. It penetrates into the inside of the vaporizer 11 so that the temperature of the vaporizer 11 rises more than normal, and during the sparking, the flame escapes out of the ball network and the temperature of the vaporizer 11 relatively decreases. Therefore, this phenomenon is to stabilize the flame by varying the air volume of the blowing fan by detecting such a phenomenon.

By performing the step S6, if the temperature of the vaporizer 11 is detected to be higher than the predetermined temperature of the vaporizer already set the output frequency to the output port (P4) increases the number of revolutions of the blower motor (FM) (S7, Step S8).

In addition, by performing the step S6, if the temperature of the vaporizer 11 is detected lower than the predetermined temperature of the vaporizer already set, the output frequency to the output port (P4) is reduced to reduce the number of revolutions of the blower motor (FM) ( Steps S9 and S10).

Therefore, the flame can be maintained in the normal position, that is, the flame network of the burner 10 due to the change in the blowing amount, thereby maintaining a stable combustion state.

As described above, the present invention is a useful invention in which the burner head part is kept in a constant combustion state by adjusting the air blowing amount, thereby improving tar generation due to a flow rate change or shaking of salt during combustion.

Claims (1)

A combustion control method of an oil combustor having a vaporizer, the method comprising: detecting a temperature of a vaporizer through a temperature sensing element attached to the vaporizer; Comparing the temperature of the vaporizer detected by the temperature sensing element with a predetermined temperature of a preset vaporizer; Increasing the number of revolutions of the blower fan when the temperature of the vaporizer detected by the temperature sensing element is higher than a predetermined temperature of a preset vaporizer; And reducing the number of revolutions of the blower fan when the temperature of the vaporizer detected by the temperature sensing element is lower than a preset temperature of the preset vaporizer.