KR0170439B1 - Method of detecting mis-operation gasfier sensor for a fan heater - Google Patents

Abstract

The present invention provides a method of detecting a carburetor sensor malfunction of a fan heater, which detects an operating characteristic of a temperature sensor detecting a carburetor temperature in a fan heater and prevents incomplete combustion caused by incomplete preheating of the initial carburetor due to a malfunction of the temperature sensor. It is about.

The present invention detects the vaporizer temperature with a temperature sensor at the beginning of the microcomputer, detects the disconnection of the heater after driving the heater, and if the heater is normal, the carburettor temperature with the temperature sensor again after driving the heater for a set time Re-detects and compares the initial detected vaporizer temperature and the re-detected vaporizer temperature to determine whether there is an abnormality of the temperature sensor to display this when malfunctioning.

Description

How to detect malfunction of carburetor sensor of fan heater

1 is a structural diagram showing a schematic configuration of a general fan heater.

2 is a block diagram of a vaporizer sensor malfunction detection device of the present invention.

3 is a control flow chart showing a malfunction detection method of the carburetor sensor of the present invention.

* Explanation of symbols for main parts of the drawings

10: carburetor 20: heater

30, 500: temperature sensor 100: micom

200: heater driving unit 400: heater disconnection detection unit

The present invention relates to a method of detecting a carburetor sensor malfunction of a fan heater which detects an operating characteristic of a temperature sensor detecting a carburetor temperature in a fan heater and prevents incomplete combustion caused by incomplete preheating of an initial carburetor due to a malfunction of the temperature sensor. will be.

In general, the fan heater preheats the carburetor at the beginning of combustion, and detects the temperature of the carburetor with a temperature sensor, and when the optimum preheating is achieved, the electronic pump is driven to supply fuel from the fuel tank to the carburetor. Air is supplied to the burner at the same time to perform normal combustion after ignition.

1 is a schematic configuration diagram of such a general fan heater.

As shown in the drawing, the conventional fan heater is formed at one side of the vaporizer 10 for vaporizing fuel to generate a heat source, and a vaporizer 10 heated by the heat source generated from the heater 20. And a fuel supply control signal output from a microcomputer (not shown) controlling the fuel supply according to the temperature of the temperature sensor 30 for detecting the temperature of the sensor and the vaporizer 10 detected from the temperature sensor 30. The solenoid valve 50 for supplying and blocking the fuel stored in the fuel tank 40 according to.

The conventional fan heater configured as described above heats the vaporizer 10 by driving the heater 20 formed in the vaporizer 10 in the microcomputer when there is a heating demand from the user.

In addition, while driving the heater 20 and at the same time detect the temperature of the vaporizer 10 through the temperature sensor 30, when the detected temperature of the vaporizer 10 reaches the preheating completion temperature (usually 300 ℃) electronic pump (Not shown in the drawing) is driven and the solenoid valve 50 is controlled so that the fuel stored in the fuel tank 40 is supplied to the vaporizer 10.

In addition, the combustion air is introduced to allow the vaporized fuel and air from the vaporizer 10 to be supplied to the burner at the same time, the igniter is discharged to perform ignition, and then normal combustion is performed.

However, the fan heater depends on the vaporizer temperature detected from the carburetor temperature sensor to supply fuel. If the power supply to the heater is sensed, the disconnection or short-circuit state of the heater can be detected. There was a problem that can not detect this.

For example, if an abnormality occurs in the temperature sensor, the carburetor temperature cannot be detected normally. If the carburetor is not preheated normally but is detected as a normal preheating due to the abnormality of the sensor, incomplete combustion during initial combustion due to abnormal preheating of the carburetor. There was a problem that caused.

The present invention is to solve the above conventional problems, an object of the present invention is to detect the operating characteristics of the vaporizer temperature sensor to prevent incomplete combustion caused by incomplete preheating of the initial vaporizer due to malfunction of the temperature sensor. The present invention provides a method of detecting a malfunction of a carburetor sensor of a fan heater.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to FIGS. 2 and 3.

2 is a circuit diagram of a carburetor sensor malfunction detection circuit of a fan heater to which the present invention is applied, and a heater according to a heater driving signal output from the microcomputer 100 and a heater driving signal output from the microcomputer 100. Heater disconnection unit 400 including a heater driving unit 200 for driving 300 and a photocoupler PC and resistors R1 and R2 for detecting the disconnection of the heater 300 and inputting the same to the microcomputer 100. ) And a temperature sensor 500 that detects the temperature of the vaporizer (not shown) and inputs it to the microcomputer 100.

Referring to the carburetor sensor malfunction detection method of the present invention in the fan heater configured as described above with reference to FIG.

First, in order to know whether the vaporizer temperature sensor 500 operates normally, the microcomputer 100 detects an initial temperature value of the vaporizer using the vaporizer temperature sensor 500 (step S1).

The detected initial temperature value A is stored in an internal memory, and the high temperature signal is output again through the port P2 to drive the heater driving unit 200.

In this case, the high potential signal output from the microcomputer 100 is inverted in phase through the inverter 201 to become a low potential signal, thereby applying a voltage to the photodiode of the photocoupler 202.

When the photodiode emits light, the optical signal turns on the phototriac. As a result, current flows through the gate of the secondary triac 203 for the high current, thereby driving the secondary triac 203. AC is supplied to the heater 300 so that the heater 300 generates heat (step S2).

On the other hand, the microcomputer 100 outputs a control signal to heat the heater 300, and reads the output value of the heater disconnection detection unit 400 to determine whether the heater is disconnected (step S3).

That is, when the heater driving unit 200 is driven to supply power to the heater 300 as described above, the phase of the AC power source AC is 180 ° to the photodiode of the photocoupler PC of the heater disconnection detecting unit 400. Whenever the power is applied, the photodiode emits light.

The light of the photodiode is sensed at the base of the port transistor constituting the port coupler (PC) so that the phototransistor repeats the on / off operation in the same way as the operation of the photodiode.

When the photocoupler PC is turned on, a low potential signal is applied to the port P3 of the microcomputer 100. When the photocoupler PC is turned off, the voltage divided by the resistors R6 and R7 is applied. This is applied at high potential.

The microcomputer 100 determines that the heater 300 is normal when the low potential / high potential signal is periodically applied to the port P3 while the heater 300 is driven. When the above signal is applied, it is determined that the heater 300 is disconnected.

If it is determined that the heater 300 is disconnected, the heater driver 200 is turned off to cut off the power supplied to the heater 300 and stop the heating of the heater 300 (step S4).

When the heater 300 is determined to be normal, the heater 300 is continuously driven for a predetermined time (for example, 3 minutes) from the moment when the heater is determined to be normal to detect the malfunction of the temperature sensor 500. (Step S5).

When the set time has elapsed, the current vaporizer temperature value B is detected through the temperature sensor 500 (step S6), and the initial temperature value A of the vaporizer previously read and stored in the memory and the currently detected vaporizer temperature. The value B is compared to determine whether there is an abnormality of the temperature sensor (step S7).

Comparing the two temperature values, if the temperature difference is 200 ℃ or more, it is determined that the vaporizer temperature sensor 500 is normal (step S8), and continuously reads the temperature sensor value and performs normal combustion when the preheating end temperature is reached. (Step S9).

After comparing the two temperature values, if the temperature difference is within 200 ° C., it is determined that the vaporizer temperature sensor 500 is abnormal (step S10), and the heater 300 is further heated for a predetermined time (eg, 1 minute). (Step S11) The characteristic amount of the temperature sensor 500 is notified to the outside and all the operations are completed.

As described above, the present invention detects a malfunction of the vaporizer temperature sensor at the initial stage of the fan heater, so that the accurate vaporizer temperature can be detected, thereby preventing incomplete combustion due to abnormality of the vaporizer preheating temperature.

Claims (2)

Sensing the initial vaporizer temperature, driving the heater to preheat the vaporizer, and detecting the disconnection of the heater; Sensing the temperature of the vaporizer after driving the heater for a predetermined time when the heater is normal; Comparing the initial temperature value of the carburetor with the re-detected carburetor temperature value and determining whether there is an abnormality of the carburetor temperature sensor. The method of claim 1, wherein the determining whether the vaporizer temperature sensor is abnormal comprises: comparing the vaporizer temperature value initially detected with the vaporizer temperature value detected again; If the difference between the two temperature values is more than a predetermined value, determining that the temperature sensor is normal and continuously searching for the temperature of the vaporizer; Detecting malfunction of the carburetor fan heater characterized in that the step of determining that the difference between the two temperature value is within a predetermined value and indicating the malfunction of the temperature sensor.