KR0169802B1 - Ac fan control method for gas-boiler - Google Patents

Abstract

The present invention relates to an exhaust fan attached to an exhaust hood of a gas boiler for discharging the burned gas to the outside, and more particularly, to a method of controlling an exhaust fan of a gas boiler driven by an AC power source.

The method of the present invention comprises: a first step of measuring a temperature of heating water when a boiler is operated and detecting whether the measured heating water temperature is below a set value; A second step of performing an ignition stroke when the temperature measured in the first step is equal to or higher than a set value, and measuring a non-operation time of the boiler when equal to or lower than the set value; A third step of performing an ignition stroke when the non-operation time measured in the second step is less than or equal to a predetermined time, and measuring the rotational speed of the exhaust fan if it is more than or equal to a predetermined time; A fourth step of measuring whether or not the rotation speed of the exhaust fan is an appropriate rotation speed, and performing an ignition stroke if the rotation speed is appropriate, and starting time measurement if the rotation speed is not appropriate; And a fifth step of detecting whether a predetermined time has elapsed while the exhaust fan rotation speed measured in the fourth step is not an appropriate rotation speed, and displaying an error occurrence when the predetermined time elapses.

Description

AC boiler control method of gas boiler

1 is a schematic configuration diagram of a gas boiler conventionally used.

2 is a partial block circuit diagram of a gas boiler used in the present invention.

3 is a flowchart for explaining the method of the present invention.

* Explanation of symbols for main parts of the drawings

1: gas valve 2: burner

3: heat exchanger 4: exhaust hood

5: exhaust pipe 6: driving motor

7: exhaust fan 8: heating water supply pipe

9: heating return pipe 10: direct water supply pipe

11: hot water supply pipe 12: flow valve

21: microcomputer 22: fan drive unit

23: timer 24: rotation speed detection unit

25: error display unit 26: temperature detection unit

The present invention relates to an exhaust fan attached to an exhaust hood of a gas boiler for discharging the burned gas to the outside, and more particularly, to a method of controlling an exhaust fan of a gas boiler driven by an AC power source.

Since gas boilers use clean fuel gas to prevent environmental pollution, they are increasingly used in homes due to their convenience in operation.

1 is a partial configuration diagram showing a schematic configuration of a conventionally used gas boiler, and an operation state thereof will be described with reference to this. The gas whose gas supply amount is controlled by the gas valve 1 is supplied to the burner 2 via a gas supply pipe. The gas supplied to the burner 2 is ignited and combusted by a spark discharged from a spark igniter operated by a control signal output from a main controller (not shown). The hot heat generated by the combustion heats the heat exchanger 3 located on the upper side.

The gas valve 1 opens the gas valve 1 by applying a predetermined current value to the gas valve 1 so that the gas pressure is determined by the main controller according to the temperature set by the user and to generate the determined gas pressure. Thereafter, the main controller outputs a control signal to the exhaust fan driver 6 in order to rotate the exhaust fan 7 at a predetermined rotation speed in order to supply the air volume suitable for the gas pressure.

In the heating mode state, the heating water heated in the heat exchanger (3) is moved through the heating water supply pipe (8) connected to the heating pipe of each room while discharging the heat, and then again through the heating return pipe (9). Flows into).

In addition, in the hot water mode, the direct water (cold water) flows into the heat exchanger 3 through the direct water supply pipe 10 and is heated by heat exchange with the heating water in the heat exchanger 3, and then the user through the hot water supply pipe 11. Is supplied to. Reference numeral 12 denotes a flow valve for detecting inflow of water and informing the main controller.

In addition, although not described, the switching between the heating mode and the hot water mode is performed by three directions, and the heating water is forced to circulate the indoor piping by a circulation pump connected to the heating return pipe 9 side.

In some models of the conventional gas boiler configured as described above, an exhaust fan for AC that uses an AC power source for the exhaust fan 7 may be used. This is difficult to control and inaccurate operation state compared to using a DC power source, but because of the low price is also used in some models.

Since the AC fan has a weak torque, it cannot exert a strong exhaust force, and as a mechanical problem, there is a problem in that the characteristic is easily changed depending on the viscosity change of the grease injected into the rotating part of the exhaust fan. In other words, when the boiler is not used for a certain period of time during the cold season, the viscosity of the grease is lowered and it is fixed.The torque of the exhaust fan is low, so the rotation speed of the exhaust fan is low. Was not output normally. Therefore, the microcomputer of the boiler detects this and determines that an abnormality has occurred in the exhaust fan, so that the operation of the boiler is frequently stopped.

However, this is because the temperature gradually rises when the exhaust fan starts to rotate, and if it is not a mechanical failure of the exhaust fan, it will return to its normal viscosity after a certain time. Therefore, the rotational speed of the exhaust fan also becomes the normal rotational speed after a certain time. Therefore, even if it is not a mechanical defect, there is a difficulty in management because there is an A / S request.

The present invention has been made to solve the above problems, an object of the present invention is to provide an AC of the gas boiler to prevent the occurrence of errors in the boiler caused by a decrease in viscosity of the grease injected into the rotating part of the AC exhaust fan in winter. To provide a fan control method.

Another object of the present invention is to provide a method for controlling an AC fan of a gas boiler which can detect a failure of an AC exhaust fan in winter.

AC fan control method of the gas boiler of the present invention for achieving the above object, in the gas boiler having an exhaust fan driven by AC power, when the boiler is operated, measuring the temperature of the heating water, the measured heating water temperature A first step of detecting whether is equal to or less than a set value; a second step of performing an ignition stroke when the temperature measured in the first step is equal to or greater than a set value, and measuring a non-operation time of a boiler if less than or equal to a set value; A third step of performing an ignition stroke when the non-operating time measured in the second step is less than or equal to a predetermined time, and measuring rotational speed of the exhaust fan if it is more than or equal to a predetermined time; A fourth step of performing an ignition stroke at a rotation speed and starting a time measurement at a suitable rotation speed; And a fifth step of detecting whether a predetermined time has elapsed while the exhaust fan rotation speed measured in the fourth step is not an appropriate rotation speed, and displaying an error occurrence after a predetermined time elapses.

Hereinafter, the AC fan control method of the gas boiler according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a partial block diagram of a circuit used in the present invention. As shown, a microcomputer 21 for controlling the entire stroke, a fan driver 22 for driving the exhaust fan 7 in accordance with a control signal output from the microcomputer 21, and for measuring the passage of time. An error display unit for detecting an abnormal occurrence of the timer 23, the rotational speed detection unit 24 for detecting the rotational speed of the exhaust fan 7 and inputting it to the microcomputer 21, and the exhaust fan 7 to the outside ( 25 and a temperature sensor 26 for measuring the temperature of the heating water.

Of course, it will be apparent to those skilled in the art that the above block diagrams are only extracting and displaying specific parts used in the present invention. All of the above circuits are conventionally used. The timer 23 may be built in the microcomputer 21 itself or may be used by connecting an external timer.

The method of the present invention using the circuit as described above comprises: a first step of measuring the temperature of the heating water when the boiler is operated and detecting whether the measured heating water temperature is below a set value; A second step of performing an ignition stroke when the measurement tube temperature is greater than or equal to the set value in the first step, and measuring an inoperable time of the boiler if less than or equal to the set value; Performing a third step of measuring the rotational speed of the exhaust fan if the predetermined time or more; A fourth step of measuring whether or not the rotation speed of the exhaust fan is an appropriate rotation speed, and performing an ignition stroke if the rotation speed is appropriate, and starting time measurement if the rotation speed is not the proper rotation speed; And a fifth step of detecting whether a predetermined time has elapsed while the exhaust fan rotation speed measured in the fourth step is not an appropriate rotation speed, and displaying an error occurrence when the predetermined time elapses.

In the first step of the present invention, first the water temperature of the heating water is measured. This is to judge whether it is winter or not. If the temperature of the heating water actually measured is in 10-20 degreeC, the external temperature will be 0 degrees C or less. The above temperature is determined by an experiment, and the optimum condition is to determine a temperature condition in which an error occurs due to a decrease in the viscosity of the grease and the failure of the exhaust fan.

If the temperature of the heating water is higher than the set value (temperature determined in the experiment as described above and stored in the memory of the microcomputer), the ignition stroke is normally performed. If the temperature of the heating water is below the set point, remember its condition and measure the downtime from the last run time of the boiler, the next step.

That is, if it is determined that a predetermined time has elapsed since the last operating time of the boiler while the temperature is lower than the set value, it is stored and the exhaust fan is rotated. The time can also be determined experimentally and in conjunction with the temperature set point. In the present invention, the temperature is set to about 3 to 5 hours.

It also measures the rotation speed from the exhaust fan and if it turns out to be the proper rotation speed, performs a normal ignition stroke. If the proper speed is not reached, the timer is operated and the speed is continuously measured while measuring the passage of time. If the time measured using the timer exceeds a certain time, the microcomputer determines that the rotation speed of the exhaust fan has not returned to the normal state and displays an error occurrence. In the present invention, the time is set to about 10 minutes. This is the time until the grease stuck by the rotation of the exhaust fan has the normal viscosity again.

The method of the present invention as described above will be described in detail using the flowcharts of FIG. 2 and FIG.

The microcomputer 21 receives a temperature value t data signal from the temperature sensor 26 to measure the temperature of the heating water. The temperature data signal is a voltage or current value that changes corresponding to temperature. When the temperature data value t is input, the microcomputer 21 compares the temperature set value T1 set in advance by the user or the designer with the temperature data value t input from the temperature sensor 26. If the comparison result is higher than the set value T1 of the input temperature data value t, the combustion stroke is performed in a normal operation.

If the value of the temperature data (t) is lower than the set value (T1), it is determined to be winter, and the downtime of the boiler is measured again. This can be done using a timer 23 stored therein, which finally measures the operating time interval from the time the boiler is used to the present. If the boiler is not operated for a predetermined time D while the temperature is low, the microcomputer 21 stores this in the internal memory and outputs a control signal to the fan driver 22 to operate the exhaust fan 7 to exhaust the exhaust fan. (7) is driven.

At the same time, the microcomputer 21 compares a signal corresponding to the rotation speed input from the rotation speed detection unit 24 with the rotation speed data stored in advance. The rotation speed data is control data stored in advance in the memory unit of the microcomputer 21.

As a result of the comparison, if the input rotational speed inputted from the rotational speed detection unit 24 and the stored rotational speed data are the same, it is regarded as a normal operating state, and the microcomputer 21 performs a normal combustion stroke.

However, if the input rotation speed input from the rotation speed detection unit 24 is lower than the stored rotation speed data as a result of the comparison, the microcomputer 21 detects the variation of the rotation speed for a predetermined time using the timer 22. In this case, an error caused by a decrease in the number of revolutions is ignored for a certain time.

If the rotational speed of the exhaust fan 7 returns to the normal rotational speed and rotates during this time, the microcomputer 21 outputs a control signal to perform a normal combustion stroke. As for the measurement time of the rotation speed change, it is usually preferable that the viscosity of the grease adhering to the rotating part of the exhaust fan 7 is restored to its normal viscosity by the temperature rise generated by the rotation of the rotating part of the exhaust fan. In the present invention, the time is set to about 10 minutes.

If the rotation speed does not recover normally during this time, the microcomputer 21 determines that an abnormality has occurred in the exhaust fan 7 and outputs an error generation signal. The error occurrence signal is input to the error display unit 25 to notify an external user of the failure of the exhaust fan.

The method of the present invention as described above may be designed in the program to perform a function in the winter or the boiler is always operated by the user using an external input key.

As described above, according to the method of the present invention, it is possible to prevent an error of a boiler caused by a decrease in viscosity of grease injected into a rotating part of the AC exhaust fan in winter, and also to detect a failure of the AC exhaust fan in winter. Is there.

Although the invention has been described in detail only with respect to the described embodiments, it will be apparent to those skilled in the art that modifications and variations can be made within the spirit and scope of the invention, and such variations or modifications will belong to the appended claims. .

Claims (4)

A microcomputer 21 for controlling the entire stroke, a fan driver 22 for driving the AC exhaust fan 7 in accordance with a control signal output from the microcomputer 21, and a timer 23 for measuring the passage of time. ), A rotation speed detection unit 24 for detecting the rotation speed of the exhaust fan 7 and inputting it to the microcomputer 21, an error display unit 25 for displaying an abnormal occurrence of the exhaust fan 7 to the outside, And a temperature detector (26) for measuring the temperature of the heating water, wherein the boiler measures the temperature of the heating water when the boiler is operated and detects whether the measured heating water temperature is lower than or equal to a set value. ; A second step of performing an ignition stroke when the temperature measured in the first step is equal to or higher than a set value, and measuring a non-operation time of the boiler when equal to or lower than the set value; A third step of performing an ignition stroke when the non-operation time measured in the second step is less than or equal to a predetermined time, and measuring the rotational speed of the exhaust fan if it is more than or equal to a predetermined time; A fourth step of measuring whether or not the rotation speed of the exhaust fan is an appropriate rotation speed, and performing an ignition stroke if the rotation speed is appropriate, and starting time measurement if the rotation speed is not appropriate; And a fifth step of detecting whether a predetermined time has elapsed while the exhaust fan rotation speed measured in the fourth step is not an appropriate rotation speed, and displaying an error occurrence when the predetermined time elapses. AC fan control method. The method of controlling an AC fan of a gas boiler according to claim 1, wherein the heating water temperature set value in the first step is in a range of 10 to 20 ° C. The method of controlling an AC fan of a gas boiler according to claim 1, wherein the non-operating time of the boiler in the third step is 3 to 5 hours. The method of controlling an AC fan of a gas boiler according to claim 1, wherein the rotation speed abnormality detection time in the fourth step is 10 minutes.