KR200141940Y1 - Safety system for port carbulated type stove using petroleum - Google Patents

Abstract

The present invention relates to a pot vaporized petroleum stove safety device. In particular, a pot burner motor is forcibly driven when the port is overheated due to a malfunction of the microcomputer, thereby preventing safety accidents caused by port deformation or spontaneous combustion of residual gas. To prevent it. The present invention is characterized in that the burner motor forced circuit and the reset circuit are connected to the output amplifier by comparing the sensed voltage and the reference voltage by the split voltage connected to the microcomputer and the port thermistor to the op amp.

Description

Port Evaporative Oil Stove Safety Device

1 is a circuit diagram of the present invention.

2 is a conventional port vaporized oil stove operating circuit diagram.

* Explanation of symbols for main parts of the drawings

M: Micom IC ₁ , IC ₂ : Op amp

PTH: Port Thermistor 10: Reset Circuit

BM: burner motor 20: burner motor forced circuit

S.S.R: Solid State Relays

The present invention relates to a pot vaporized petroleum stove safety device. In particular, the pot burner motor is forcibly driven when the port is overheated due to a malfunction of the microcomputer, thereby preventing safety accidents caused by port deformation or spontaneous combustion of residual gas. To prevent it.

In the conventional pot-vaporized oil stove, as shown in FIG. 2, the port thermistor PTH, the resistor R ₁ , the R ₂ , and the capacitor C are connected in parallel and are configured to be input to the microcomputer M. The diodes of the solid state relay (SSR) and the photo triac (PT) are connected to the microcomputer (M), and the burner motor (BM) is connected to the triac of the solid state relay (SSR) and the photo triac (PT). , Triac, heater (H) and relay (RY) by connecting. In the figure, IC is a buffer, V _CC , V _DD is an input voltage, and R ₃ is a resistor.

In the prior art having such a configuration, the microcomputer M operates normally at a constant temperature, and stops the combustion stop and burner motor BM when the abnormal temperature, that is, the heater H is overheated.

That is, the microcomputer (M) reads the value of the port thermistor (PTH), when the normal temperature operates the solid state relay (SSR) and phototriac (PT) to heat the heater (H) and burner motor (BM) Perform the operation.

However, when a malfunction occurs due to noise or the like in the microcomputer M, the command control is not performed from the microcomputer M, so that the heater H may be overheated or the burner motor BM may be stopped.

Therefore, it is pointed out that a safety accident such as an explosion due to deformation of the port or spontaneous combustion of residual gas may occur.

The present invention was devised to solve the problems of the prior art as described above. When an abnormality occurs in the microcomputer due to noise, the microcomputer is forcibly reset and initialized while the burner motor is operated regardless of the microcomputer port. It is to eliminate the factor of incapacity due to deformation and to prevent safety accidents such as explosion caused by spontaneous ignition of residual gas.

The present invention for achieving the above object is characterized by connecting the burner motor forced circuit and the reset circuit for the output voltage by comparing the sensed voltage and the reference voltage by the distribution voltage and port thermistor connected to the microcomputer input to the op amp. It is done.

The present invention as described in detail with reference to FIG. 1 as follows.

First, the same parts that overlap with the first circuit, which is a conventional circuit, use the same reference numerals. In the case where the resistor R ₁ , the port thermistor PTH, and the resistor R ₂ are connected to the microcomputer M, the intermediate connection point A of the resistor R ₃ connected in series with the resistor R ₂ is connected. The intermediate connection point B of the resistors R ₄ , R ₅ and R ₆ connected to the inverting terminals of the op amps IC ₁ and IC ₂ and connected in series to the input voltage V _DD is Op amps (IC ₁ ) (IC ₂ ) are connected to each non-inverting terminal,

The output terminal of the operational amplifier (IC ₁ ) is connected to the reset terminal (RESET) of the microcomputer (M), and the output terminal of the operational amplifier (IC ₂ ) to be connected to the output terminal of the buffer (IC) and the microcomputer (M). .

In the above description, the sensing voltage portion of the port thermistor PTH, resistors R ₂ , R ₃ , the reference voltage portion of the resistors R ₄ , R ₅ , and R ₆ and the op amp IC ₁ In the present invention, the circuit section constituting the circuit is a reset circuit section 10. The sensing voltage section is formed by the port thermistor PTH, resistors R ₂ and R ₃ , and resistors R ₄ and R ₅ . The reference voltage section (R ₆ ) and the circuit section constituting the op amp (IC ₂ ) are the burner motor forced circuit section 20, and the op amp (IC ₁ ) (IC ₂ ) is composed of one op amp. For example, a comparator may be used instead of an op amp.

The technical gist of the present invention is a sensing voltage by a pot thermistor (PTH), a resistor (R ₂ ) (R ₃ ) and a reference voltage by a resistor (R ₄ ) (R ₅ ) (R ₆ ) in the microcomputer (M). Is configured by connecting the reset circuit unit 10 and the burner motor forced circuit unit 20 to be compared and compared with the operational amplifier IC ₁ (IC ₂ ).

Effects of the present invention configured as described above are as follows.

The microcomputer (M) is divided between port thermistor (PTH) and resistor (R ₂ ) + (R ₃ ) at the intermediate connection point (A). By determining the port temperature to control the burner motor (BM) and the heater (H) through the buffer (IC), solid state relay (SSR) and photo triac (PT) to perform a normal operation.

In this way, when the microcomputer (M) operates normally but the microcomputer (M) is abnormal due to noise or the like, or the port is overheated, the sensing voltage of the intermediate connection point (A) becomes higher than the reference voltage of the intermediate connection point (B). The output of the amplifier (IC ₂ ) is output from the high level to the low level so that the solid state relay (SSR) is turned on to operate the burner motor (BM) regardless of the output of the microcomputer (M).

That is, since the input voltage V _CC is applied to the anode terminal of the diode in the solid state relay SSR, and the output terminal of the microcomputer M and the diode are connected in the reverse direction, the input voltage V _CC is solid state. It is applied to the relay SSR and conducts regardless of the output of the microcomputer M.

As described above, the burner motor BM is operated and a low level signal is also output to the output terminal of the op amp IC ₁ and applied to the reset terminal RESET of the microcomputer M. Thus, the microcomputer M is initialized. do.

On the other hand, the present invention can also be applied to the abnormal state of the heater overheating of the rice cooker in addition to the carburetor oil stove.

As described above, the present invention allows the burner motor to operate regardless of the output of the microcomputer in case of a microcomputer abnormality, thereby preventing safety accidents caused by deformation of the port or delayed residual gas delay, and forcibly resetting the microcomputer to reset. It is a useful design to stabilize the circuit.

Claims (1)

The detection voltage of the resistor (R ₂ ) (R ₃ ) and the port thermistor (PTH) connected to the microcomputer (M) and the reference voltage of the resistor (R ₄ ) (R ₅ ) (R ₆ ) are the ohmic amplifiers (IC ₁ ). (IC ₂ ) A port vaporized oil stove stabilizer, characterized in that consisting of the burner motor forced circuit 20 and the reset circuit unit 10 to compare the input to each output.