KR100628041B1 - Safety circuit for operating heater of cook machine - Google Patents

Abstract

The present invention relates to a relay driving safety circuit of a cooking appliance capable of preventing a relay malfunction due to a microcomputer congestion, at least two or more loads, a relay for one-to-one connection with the load to drive each load, and the relay A microcomputer for outputting a control signal and a square wave signal indicating a system state for controlling the operation of the drive; a square wave detector for detecting a system state by receiving a square wave signal output from the micom; and a system state detected by the square wave detector In consideration of the control signal output from the microcomputer is configured to switch to start the relay.

Accordingly, the present invention can improve product safety and reliability by providing a safety circuit for recognizing a micom congestion by using a square wave signal indicating a system state and also preventing a relay malfunction due to the micom congestion.

Relay, drive circuit, safety design, microcomputer runaway, square wave

Description

Safety Circuit for Operating Heater of Cooker

1 is a view showing a relay driving circuit of a cooking apparatus according to the prior art

2 is a circuit diagram showing a relay driving safety circuit of the cooking appliance according to the present invention;

3 is a diagram illustrating input and output signal waveforms for a square wave detection unit of the present invention;

* Explanation of symbols for main parts of the drawings

10: micom 20, 20 ': relay

31, 31 ': first switching unit 33: shift register

40: square wave detector

Q20, Q33: first and second protective transistors

The present invention relates to a relay driving circuit of a cooking appliance, and more particularly, to a relay driving safety circuit capable of preventing a relay malfunction due to a microcomputer runaway.

In recent years, as well as cooking appliances that use gas as a heat source, such as gas ranges and gas ovens, cooking appliances that use electricity as heat sources, such as electric ovens and microwave ovens, have been widely used in homes.

In general, the electric heater (heater) that converts electrical energy to obtain heat energy is freely controlled, hygienic, and remotely controlled, compared to other types of heat sources, and thus, even in the field of cooking equipment for cooking foods. It has been developed in various forms of products.

Here, the microwave oven is a device for cooking by heating the object to be cooked in the interior (Cavity) by using a microwave (Microwave) generated from the built-in magnetron as the main heating source.

In addition, the electric oven is an electric heater (Heater) as the main heating source, in the case of an electric range is a commercial appliance for cooking food using a halogen lamp or a heater as a heat source is mounted on the top (cook-top) of the electric oven, etc. are commercialized. .

 In addition, recently, a microwave oven with a built-in heater (Heater) has been developed and commercially available to provide a variety of heating conditions.

Such a microwave oven is configured to selectively use a cooking mode using a magnetron, a cooking mode using a heater, and a combination cooking mode using a magnetron and a heater together.

Various driving elements (magnetrons, heaters, motors, etc.) constituting such a cooking appliance mostly control the operation by using a relay. Control of each relay is performed by a microcomputer (aka, microcomputer) that controls the operation of the system as a whole.

Hereinafter, a relay driving circuit of the related art will be described with reference to FIG. 1.

As shown in the drawing, in the conventional relay driving circuit, relays RY11 to RY14 1 are connected in a one-to-one correspondence to each load in order to start operation of various loads such as a heat source or a motor, and drive the relay 1. As a switching element, transistors Q11 to Q14 are connected one to one to each relay 1.

In addition, the transistors 2 are connected in one-to-one connection to the output ports (out ports 0 to 3) of the microcomputer 3 that outputs the driving signal of the relay 1.

According to this configuration, the microcomputer 3 outputs the driving signal of the load through the output ports (out ports 0 to 3), depending on the level (high / low signal) of the driving signal output from the microcomputer 3. The transistor 2 is turned on / off to drive the corresponding relay 1.

For example, when a high signal is output through the out port 2 of the microcomputer 3, a high signal is applied to the base terminal of the transistor Q13 connected to the corresponding out port 2.

At this time, the transistor Q13 is turned on and the driving power supply Vdd is conducted to the DC terminal of the relay RY13, so that the relay RY13 is driven and power supply to the corresponding load (load 3) is started. do.

However, in the conventional relay driving circuit, a control signal for relay operation is directly output from the microcomputer. When the microcomputer congestion occurs due to the internal error of the microcomputer, the relay malfunctions regardless of the user's intention, thereby causing an unwanted load to operate.

In particular, in the case of a heater load, if a relay malfunctions due to the congestion of the microcomputer in a situation where the user is not aware of it, it causes a safety accident such as system damage or fire.

In addition, the micom congestion leads to a situation in which no key input is recognized, and the user could not take any action except removing the power cord.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a relay drive safety circuit for preventing a relay malfunction due to the microcomputer congestion.

Another object of the present invention is to provide a relay drive safety circuit that can prevent the system malfunction due to the microcomputer congestion through a more secure circuit design in hardware.

In order to achieve the above object, the present invention provides at least two or more loads, a relay connected one-to-one with the load to drive each load, a control signal for controlling the driving of the relay and a square wave signal indicating a system state. Driving of the relay according to the control signal output from the micom in consideration of the output microcomputer, the square wave detector for sensing the system state by receiving the square wave signal output from the micom, and the system state detected by the square wave detector It provides a relay driving safety circuit of the cooking appliance composed of a switching unit for starting.

Here, the square wave detector includes a capacitor C51 having one end connected to the square wave signal output port of the microcomputer and outputting a DC level signal with respect to the square wave signal output from the microcomputer, and a base connected to the other end of the capacitor and having an emitter. Is connected to a power supply and is configured to include a pnp-type transistor (Q51) on / off according to the output of the capacitor (C51).

In the present invention, the switching unit, the first switching unit is connected to the relay on / off according to the control signal output from the microcomputer, the first switching unit dependently connected to the output terminal of the square wave detection unit And a second switching unit which is turned on / off to initiate a switching operation of the first switching unit according to the output signal of the square wave detector.

As a first embodiment of the first switching unit, the collector is an npn transistor Q23 connected to the input terminal of the relay and the emitter is connected to the ground terminal, and the second switching unit is connected to the control signal output port of the microcomputer. The emitter is connected to the output of the square wave detector and the collector is a pnp type transistor Q33 connected to the base of the transistor Q23.

As a second embodiment of the switching unit, connected to the microcomputer for serial communication to receive a control signal of the serial data (serial data) from the microcomputer to output the input control signal to the first switching unit in parallel data (parallel data) The first switching unit further includes a shift register for the npn type transistor Q11 to which the base is connected to the output port of the shift register, the emitter is connected to the ground terminal, and the collector is connected to the input terminal of the relay. Q14) wherein the second switching unit has a base connected to the output terminal of the square wave detection unit, an emitter connected to the ground terminal, and a collector connected to the output enable port of the shift register to output the square wave detection unit. Composed of npn type transistor (Q20) which enables / disables output of shift register according to signal It is desirable to.

Accordingly, the present invention provides a safety circuit for recognizing a micom congestion by using a square wave signal indicating a system state, and also to prevent a relay malfunction due to the micom congestion.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention that can specifically realize the above object will be described.

Referring to Figure 2, when describing the relay drive safety circuit of the electric device according to the present invention.

First, as shown in the lower part of FIG. 2, the relay driving circuit of the electric device is connected to the relays RY11 to RY14 20 for driving various loads (loads 1 to 4) in one-to-one correspondence with the relay 20. The first switching unit 31 is turned on / off to start driving of the relay 20 according to the control signal of the microcomputer 10, and is connected to the microcomputer 10 so that serial communication is possible. The shift register 33 receives a control signal of serial data and outputs the input control signal as parallel data to the first switching unit 31.

In this case, the first switching unit 31 has a base connected to the output ports Q1 to Q4 of the shift register 33, an emitter connected to a ground terminal, and a collector connected to an input terminal of the relays RY11 to RY14. npn type transistors Q11 to Q14.

The microcomputer 10 outputs an output port (out port 5) for outputting a control signal to the relay 20 as serial data, and a shift clock signal for shifting data of the output serial data. An output port (out port 6) for outputting a latch clock signal (latch clock) for controlling data output through the output ports Q1 to Q4 of the shift register 33; in need.

At least one micom output port is required for one relay, but by applying a shift register 33 capable of serial communication with the microcomputer 10, an output port of the microcomputer 10 required for driving control of the relay 20 is provided. Can be reduced.

According to this configuration, the control signal output from the microcomputer 10 to the shift register 33 is output as serial data and shifted by one bit in synchronization with the shift clock signal, and the output signal Q1 to Q4 is applied to all the output ports Q1 to Q4. At the time when the data for each bit is shifted, the output is simultaneously output to the base terminals of the first switching units Q11 to Q14 31 through the output ports Q1 to Q4 in synchronization with the latch clock signal.

At this time, the transistors Q11 to Q14 of the first switching unit 31 are turned on / off according to the signal level (high / low signal) of each control signal output from the microcomputer 10 through the shift register 33. Controls the driving of the relays RY11 to RY14.

Meanwhile, the load driving circuit according to the North American standard is connected to the sub relays RY21 and RY22 for driving each heater 1 and 2 and the sub relays RY21 and RY22 as shown in the upper part of FIG. 2. The main relay RY23 for starting the power to the heater and the main and sub relays RY21 to RY23 20 'are connected one-to-one and connected in parallel with the control signal output port of the microcomputer 10 to the microcomputer 10. A first switching unit (Q21 to Q23, Q31 to Q32) 31 'that is turned on / off to start driving the main and sub relays (RY21 to RY23) 20' according to the control signal output from .

Here, for the sub relays RY21 to RY22, two transistors are configured for one sub relay as shown to drive the heater through the dual slave control for the safety of the product.

For example, with respect to the sub relay RY21 for controlling the heater 1, a first transistor having a base connected to an output port (out port 0) of the microcomputer 10 and a collector connected to an input terminal of the relay RY21 ( Q21), and a second transistor Q31 having a base connected to an output port (out port 1) of the microcomputer 10, an emitter connected to a ground terminal, and a collector connected to an emitter of the first transistor Q21. It consists of.

That is, when outputting the same driving condition, that is, a high level control signal at the same time under (out port 0) and (out port 1) of the microcomputer 10, the corresponding relay RY21 may be driven.

The main relay RY23 for the double line breaker DLB is simultaneously driven together with the sub relays RY21 and RY22 to supply power to the heaters 1 and 2.

For example, when the heater 1 is to be driven, a high signal is output from (out port 0) and (out port 1) of the microcomputer 10, and a high signal is output from (out port 4) at the same time. ) And (RY23) are on at the same time, driving power is supplied to both ends of heater 1.

In the relay driving circuit configured as described above, the present invention provides a first switching unit according to a square wave signal output from the microcomputer 10 so as to prevent a malfunction of the relays 20 and 20 'due to congestion of the microcomputer 10. (31) It is characterized in that the square wave detector 40 for controlling the on / off operation of (31 ').

According to the present invention, a square wave detector 40 detects a system state by receiving a square wave signal of a predetermined frequency from an output port 13 of the microcomputer 10, and a system state detected by the square wave detector 40. The second switching unit (Q20) (Q33) for controlling the switching operation of the first switching unit (31) (31 ') according to the configuration.

Here, the second switching unit for the first protective transistor (Q20) and the second protective transistor (Q33) for controlling the switching operation of the first switching unit (31) (31 ') according to the square wave signal of the microcomputer 10, respectively. It consists of.

At this time, the first protective transistor (Q20) is of the npn type, the base is connected to the output terminal of the square wave detector 40, the emitter is connected to the ground terminal, the collector is the output control terminal (output) of the shift register (33) It is connected to the enable port to enable / disable the signal output of the shift register 33 in accordance with the output signal of the square wave detector 40.

The second protective transistor Q33 is of the pnp type, and a base is connected to an output port (out port 4) of the microcomputer 10 for the main relay RY23 among the first switching units 31 ′, and the square wave is connected. An emitter is connected to the output terminal of the detector 40 and a collector is connected to the base of the transistor Q23 connected to the main relay RY23, and the main relay for double line brakes is output in accordance with the output signal of the square wave detector 40. The driving of (RY23) is controlled.

In addition, the square wave detector 40 is one end of the capacitor (C41) is connected to the square wave signal output port (out port 13) of the microcomputer 10 to output a DC level signal for the square wave signal output from the microcomputer 10 ), A base is connected to the other end of the capacitor C41, an emitter is connected to a power supply terminal, and a collector is connected to the base terminal of the first protective transistor Q20 and the emitter terminal of the second protective transistor Q33. It consists of a transistor Q41 to be connected.

By this configuration, in a normal state, the microcomputer 10 outputs a square wave signal (1 in FIG. 3) having a predetermined frequency having different levels, for example, 0V and -5V levels, through an output port (out port 13). .

The square wave signal is smoothed to the DC level through the capacitor C41, and then output to the DC terminal of the low level (-5V) (2 in FIG. 3) and input to the base terminal of the transistor Q41. When the square wave signal is continuously output from the microcomputer 10, the transistor Q41 maintains a turn on state (high level signal output) (3 in FIG. 3).

At this time, when the transistor Q41 is turned on, the square wave detector 40 outputs a high level signal to turn on the first protective transistor Q20 and supply the emitter voltage of the second protective transistor Q33. do.

That is, when the first protective transistor Q20 is turned on, the output control terminal of the shift register 33 is enabled, and the control signal of the microcomputer 10 to the relays RY11 to RY14 is output to the output ports Q1 to Q4. Through the first switching unit 31 is a state capable of output.

In addition, when the emitter voltage is applied to the second protective transistor Q33, the second protective transistor Q33 is turned on / off according to the control signal of the microcomputer 10 with respect to the main relay RY23, and thus the main relay RY23. The switching operation of the transistor Q23 connected to the control panel is controlled.

On the other hand, when the microcomputer 10 is damaged or congested due to external influences such as electric shock or noise interference, the microcomputer 10 does not output a normal square wave signal and maintains a constant level (a continuous high signal or a low signal). Will print

As such, when a signal of a predetermined level rather than a square wave is output through the output port (out port 13) due to the congestion of the microcomputer 10, the capacitor C41 of the square wave detector 40 blocks the signal without a signal output due to device characteristics. It plays a role.

At this time, the transistor Q41 of the square wave detector 40 maintains an off state. As a result, the first protective transistor Q20 disables the output control terminal of the shift register 33 and the second protective transistor Q33. ) May remain off because the emitter voltage is not supplied, and as a result, the switching operation of the first switching units 31 and 31 ′ may be blocked.

Therefore, the relay drive safety circuit of the present invention essentially blocks the operation of the switching means for the relay when the micom congestion occurs in order to prevent the relay malfunction due to the micom congestion.

The present invention is not limited to the above-described embodiments, and as can be seen in the appended claims, modifications can be made by those skilled in the art to which the invention pertains, and such modifications are within the scope of the present invention.

The relay driving safety circuit of the cooking appliance according to the present invention described above has the following effects.

First, by recognizing the micom congestion using the square wave signal output from the microcomputer, it is possible to prepare for a relay malfunction for the microcomputer congestion.

Second, by providing a safety circuit that can prevent the malfunction of the relay due to congestion of the microcomputer, it is possible to improve the safety of the product by preventing product safety accidents in advance.

Claims (7)

With at least two loads, A relay connected one-to-one with the load to drive each load; A microcomputer for outputting a control signal for controlling the driving of the relay and a square wave signal indicating a system state; A square wave detector for detecting a system state by receiving a square wave signal output from the microcomputer; And a switching unit which starts driving of the relay according to a control signal output from the microcomputer in consideration of the system state sensed by the square wave detection unit. The method of claim 1, The square wave detector A capacitor C51 having one end connected to the square wave signal output port of the microcomputer and outputting a DC level signal with respect to the square wave signal output from the microcomputer; The base is connected to the other end of the capacitor and the emitter is connected to the power supply terminal relay drive safety circuit of the cooking appliance, characterized in that composed of a pnp-type transistor (Q51) on / off in accordance with the output of the capacitor (C51) . The method of claim 1, The switching unit A first switching unit connected to the relay and turned on / off according to a control signal output from a microcomputer; And a second switching unit connected to the first switching unit subordinately and connected to an output terminal of the square wave detection unit and switched on / off to initiate a switching operation of the first switching unit according to the output signal of the square wave detection unit. Relay drive safety circuit of equipment. The method of claim 3, wherein The first switching unit is an npn transistor Q23 having a collector connected to an input terminal of a relay and an emitter connected to a ground terminal. The second switching unit has a base connected to a control signal output port of a microcomputer and an emitter detecting a square wave. And a collector is a pnp-type transistor (Q33) connected to the base of the transistor (Q23). The method of claim 3, wherein The switching unit A shift register connected to the microcomputer for serial communication and receiving a control signal of serial data from the microcomputer and outputting the input control signal as parallel data to the first switching unit. Relay drive safety circuit of a cooking appliance, characterized in that it further comprises. The method of claim 5, wherein The first switching unit And npn transistors (Q11 to Q14) having a base connected to an output port of the shift register, an emitter connected to a ground terminal, and a collector connected to an input terminal of a relay. The method of claim 5, wherein The second switching unit A base is connected to the output terminal of the square wave detector, an emitter is connected to the ground terminal, and a collector is connected to an output enable port of the shift register to enable / disable the output of the shift register according to the output signal of the square wave detector. Relay drive safety circuit of the cooking appliance, characterized in that consisting of npn transistor (Q20) to disable.

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