KR200227310Y1 - Microwave System Malfunction Prevention Circuit - Google Patents

Abstract

The present invention relates to a system malfunction prevention circuit of a microwave oven, and in the related art, all the loads are controlled by the microcomputer, so that the system malfunctions when the microcomputer is congested, when a program bug or migration occurs.

Therefore, the present invention provides a microcomputer 5 for controlling the overall operation of the microwave system, a fan driver 6 for driving a fan according to a fan control signal output from the microcomputer 5, and a tray output from the microcomputer 5. The tray driver 7 drives the tray according to the control signal and the fan drive signal output from the fan driver 6, the magnetron control signal output from the microcomputer 5, and the tray drive signal output from the tray driver 7. Therefore, by providing the magnetron driver 8 for driving the magnetron, even when the microcomputer runaway, program bug or migration occurs, it is possible to prevent damage or malfunction of the system.

Description

Microwave System Malfunction Prevention Circuit

The present invention relates to a system malfunction prevention circuit of a microwave oven, and more particularly, a fan, a tray, and a magnetron driver are configured to be interconnected to each other when a microcomputer is congested or a bug occurs in a program. Alternatively, the present invention relates to a system malfunction prevention circuit of a microwave oven which prevents a malfunction of a system when a migration occurs.

In general, a microwave oven is an electronic device that cooks food using high frequency oscillated from a magnetron, and includes a thawing function, a warming function, and a cooking function by a multi-stage output of the magnetron.

In addition to the magnetron, there is a grill cooking function using a heater and a combination function using a heater and a magnetron at the same time. There is also an oven function for circulating hot air inside a cooking chamber with a convection heater and a convection pan installed at the rear of the cooking chamber.

In such a microwave oven, the cooking method is a sensor type automatic cooking control method that detects humidity generated from a food according to heating by using a humidity sensor and automatically controls cooking time, and cooking amount according to cooking name and serving. There is a program type automatic cooking control method that finds the cooking time set by experiment in advance and controls the heating during the cooking time by manually inputting.

In order to cook in a microwave oven as described above, the food is put into the cooking chamber with the power connected, the door is closed, the output level is selected, the cooking function is selected, and the start key is pressed to start cooking.

When the microwave oven is installed and the cavity lamp is being installed, the cavity lamp is turned on when cooking, and the cooking state of the food can be checked from the outside, and the food can be easily introduced into or taken out of the cooking chamber before or after cooking. The cavity lamp will automatically light when the door is opened.

On the other hand, the system driving circuit in the general battery range as described above is as shown in FIG.

As shown therein, the microcomputer 1 controls the overall functions of the microwave oven, the fan driver 2 generating a fan driving signal according to the fan control signal output from the microcomputer 1, and the microcomputer 1 The tray driver 3 generates a tray drive signal according to the tray control signal outputted from the control panel), and the magnetron driver 4 generates a magnetron drive signal according to the magnetron control signal outputted from the microcomputer 1.

In the conventional microwave oven configured as described above, power is supplied to the system first, and when the cooking start key is pressed after the cooking function is selected by the user's key operation, the microcomputer 1 performs the entire operation of the system according to the cooking selected by the user. Control to perform the cooking function.

That is, at the start of cooking, a low signal is output to the port P1, and the fan driver 2 turns the switching element TR1 on by driving the relay RY1 by driving the relay RY1 by the low signal. Let's go.

Subsequently, the microcomputer 1 outputs a low signal to the port P2, and the tray driver 3 turns on the switching element TR2 to drive the tray RY2 by driving the relay RY2. do.

In addition, the microcomputer 1 outputs a low signal to the port P3 while the fan and the tray are driven as described above, and the switching device TR3 is turned on by the magnetron driver 4 by the low signal. By driving the relay RY3, the magnetron is driven.

In this way, when cooking is started, the pan is first driven, the tray is next driven, and the magnetron is driven to perform cooking.

On the other hand, after the cooking is completed, the high signal is first outputted to the port P3 in reverse to the above, and the magnetron driver 4 turns off the switching element TR3 to turn off the relay RY3 by the high signal. Turning off turns off the magnetron.

Next, a high signal is output to the port P2, and the tray driver 3 turns off the switching element TR2 by turning off the relay RY2 by turning off the drive of the tray.

Finally, a high signal is output to the port P1, and the high frequency signal causes the fan driver 2 to turn off the switching element TR1 to turn off the drive of the tray by turning off the relay RY1.

That is, after the cooking is completed, the magnetron is first turned off, the tray is turned off next, and the pan is turned off last.

As described above, the conventional microwave oven performs all operations from the start of cooking to the completion of cooking in the microcomputer 1.

However, the conventional microwave oven as described above is controlled by the microcomputer to control all the operations from the start of cooking to the completion of the cooking, when the microcomputer congestion or program bug (Bug), the system malfunctions due to the malfunction of the microcomputer, or cooking is not properly made This damaged problem occurred.

In addition, even when the migration occurs, the system is not able to control the system under the control of the microcomputer, so there is a problem that the system malfunctions.

Therefore, an object of the present invention is to solve the conventional problems, and the fan, tray, magnetron (MAGNETRON) driving unit is configured to be interconnected when the micom congestion or program bug (bug) occurs or migrate ( Migration) It is to provide a system malfunction prevention circuit of the microwave oven to prevent the system from malfunctioning in advance.

An object of the present invention as described above, the fan drive unit for driving the fan according to the fan control signal output from the microcomputer to control the overall operation of the system; A tray driver for driving the tray by controlling the driving by an output signal of the microcomputer and the fan driver; The drive is controlled by the output signal of the microcomputer and the tray driver, and is achieved by having a magnetron driver for driving the magnetron.

1 is a configuration diagram of a driving circuit of a conventional microwave oven,

Figure 2 is a schematic diagram of the system malfunction prevention circuit of the microwave oven according to the present invention.

Explanation of symbols for the main parts of the drawings

5: micom 6: fan drive

7 tray drive 8 magnetron drive

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, the technical configuration and operation of which are as follows.

2 is a diagram illustrating a system malfunction prevention circuit of the microwave oven to which the present invention is applied.

As shown here, the microcomputer 5 for controlling the overall operation of the system, the fan drive unit 6 for driving the fan in accordance with the fan control signal output from the microcomputer 5, and is output from the microcomputer 5 A tray driver 7 for driving a tray according to a tray control signal and a fan drive signal output from the fan driver 6, a magnetron control signal output from the microcomputer 5 and an output from the tray driver 7. It consists of a magnetron driver 8 for driving the magnetron in accordance with the tray drive signal.

In the above, the fan driver 6 generates a fan driving signal by a switching element TR4 whose driving is controlled according to the fan control signal output from the microcomputer 5 and a signal output from the switching element TR4. It consists of the relay RY4.

In addition, the tray driver 7 is driven according to the tray control signal output from the microcomputer 5, the switching element (TR5) for driving the relay (RY5) by the signal output from the fan driver (6) ) And a relay RY5 for generating a tray driving signal by the signal output from the switching element TR5.

In addition, the magnetron driver 8 controls the driving according to the magnetron control signal output from the microcomputer 5, and the switching element TR6 for driving the relay RY6 by the signal output from the tray driver 7. ) And a relay RY6 for generating a tray driving signal by the signal output from the switching element TR6.

The operation of the system malfunction prevention circuit of the microwave oven according to the present invention configured as described above is as follows.

First, power is supplied to the system, when a cooking function is selected by a user's key operation, and a cooking start key is pressed, the microcomputer 5 performs the cooking function by controlling the entire operation of the system according to the cooking selected by the user. .

That is, at the start of cooking, a low signal is output to the port P1, and the fan driver 6 turns the switching element TR4 on by driving the relay RY4 by the low signal. Let's go.

Subsequently, the microcomputer 5 outputs a low signal to the port P2. The low driving signal causes the tray driver 7 to turn on the switching element TR5, wherein the switching element TR5 is the fan. The fan drive signal must be output from the switching element TR4 in the drive unit 6, but the relay RY5 drive signal is output, and the relay RY5 is driven by the drive signal to drive the tray.

In addition, the microcomputer 5 outputs a low signal to the port P3 while the fan and the tray are driven as described above, and the switching device TR6 is turned on by the magnetron driver 8 by the low signal. At this time, the switching element TR6 also outputs a driving signal from the switching element TR5 in the tray driving unit 7 but outputs a relay RY6 driving signal, and drives the relay RY6 by the driving signal. To drive the magnetron.

In this way, when cooking is started, the pan is first driven, the tray is next driven, and the magnetron is driven to perform cooking.

On the other hand, after the cooking is completed, the high signal is first outputted to the port P3 in reverse to the above, and the magnetron driver 8 turns off the switching element TR6 to turn off the relay RY6 by the high signal. By turning off, the magnetron is turned off.

Next, a high signal is outputted to the port P2. The high signal causes the tray driver 7 to switch off the switching element TR5 to turn off the relay RY5 and to turn off the drive of the tray. .

Finally, a high signal is output to the port P1, and the high signal causes the fan driver 6 to turn off the switching element TR4, turn off the relay RY4, and turn off the drive of the tray. .

That is, after the cooking is completed, the magnetron is first turned off, the tray is turned off next, and the pan is turned off last.

On the other hand, when the runaway of the microcomputer 5 or a bug or migration of the program occurs during cooking, the tray drive unit 7 or the magnetron drive unit 8 according to the present invention must operate the drive unit connected directly above each other to use the output. Since it is running, it can prevent the system from malfunctioning even in case of congestion of micom, bug of program or migration.

For example, if the fan driver is not driven, the tray driver using the output thereof does not operate, and thus the magnetron driver does not operate.

Therefore, if there is an abnormality in the pan during cooking, driving of the tray and the magnetron is automatically stopped, and if the tray is abnormal during cooking, the magnetron is not driven.

As described above, the present invention does not operate the tray and the magnetron consecutively if there is an abnormality in the pan due to congestion, program bug or migration phenomenon during cooking, and the magnetron also stops driving immediately when an abnormality occurs in the tray. Even when the micom congestion, program bug or migration occurs, there is an effect that can prevent the system from malfunctioning.

Claims (4)

The microcomputer 5 for controlling the overall operation of the microwave system, the fan driver 6 for driving the fan in accordance with the fan control signal output from the microcomputer 5, and the tray control signal output from the microcomputer 5 And a tray driver 7 for driving a tray according to a fan drive signal output from the fan driver 6, a magnetron control signal output from the microcomputer 5, and a tray drive signal output from the tray driver 7. And a magnetron driver (8) for driving the magnetron according to the present invention. 2. The fan drive unit (6) according to claim 1, wherein the fan driver (6) is driven by a switching element (TR4) whose drive is controlled in accordance with a fan control signal output from the microcomputer (5) and a signal output from the switching element (TR4). A system malfunction prevention circuit of a microwave oven, characterized by comprising a relay (RY4) for generating a fan drive signal. 2. The drive of claim 1, wherein the drive of the tray driver 7 is controlled according to a tray control signal output from the microcomputer 5, and the relay RY5 is driven by a signal output from the fan driver 6. And a relay (RY5) for generating a tray driving signal by a signal output from the switching element (TR5). 2. The magnetron driver 8 according to claim 1, wherein the driving is controlled according to the magnetron control signal output from the microcomputer 5, and the relay RY6 is driven by the signal output from the tray driver 7. And a relay (RY6) for generating a tray driving signal by a signal output from the switching element (TR6).