KR20000010781U - Safety device using 3-terminal thermostat - Google Patents

Abstract

The present invention relates to a safety device of a microwave oven, and to prevent the system instability caused by frequent contact of the thermostat as the magnetron is heated under no load, and to prevent damage to the device due to the self heating of the magnetron. It relates to a safety device using a three-terminal thermostat.

Therefore, the present invention has a normal contact terminal (NC) and a non-normal contact terminal (NO) around a common terminal (COM) and a thermostat provided at an initial power input terminal and through the normal contact terminal (NC) of the thermostat. In addition, the fan motor is directly connected to the non-contact terminal (NO) at the same time, so that the overheating of the magnetron can be quickly suppressed in case of abnormal condition, so that the overheating and overheating of the magnetron is not repeated. It is possible to prevent damage to the magnetron device by deterioration and deterioration of the function, and to secure the stability of the microwave system.

Description

Safety device using 3-terminal thermostat

The present invention relates to a safety device for a microwave oven, and more particularly, to prevent instability of the system caused by frequent contact of the thermostat as the magnetron is heated under no load, and to breakage of the device due to the self heating of the magnetron. It relates to a safety device using a three-terminal thermostat that can prevent.

In general, a microwave oven is provided with a high voltage transformer for driving a magnetron, and a thermostat of the high voltage transformer is connected to the magnetron to be close to the magnetron. Therefore, when the magnetron increases its heating amount, the thermostat is turned off, thereby ensuring the stability of the system.

Next, the configuration of the microwave oven will be described in detail with reference to the accompanying drawings.

Fig. 1A is a circuit diagram showing a main configuration of a microwave oven. FIG. 1B is a circuit diagram according to another embodiment of the circuit diagram shown in FIG. 1A. The configuration of the microwave oven with reference to FIGS. 1A and 1B includes a thermostat 70 for interrupting supply power when the magnetron is heated to a predetermined temperature or more, and a predetermined low voltage for commercial power applied through the thermostat 70. A low voltage transformer (71) for converting to a low voltage transformer (71), and a system controller (72) for driving the system using a constant low voltage obtained through the low voltage transformer (71);

The system controller 72 includes a microcomputer 80 for overall control of the system, a relay controller 81 for controlling power supply according to the voltage output from the microcomputer 80, and the system controller 72. It is composed of a high voltage transformer 73 for applying a high voltage to the magnetron.

In addition, the front end of the thermostat 70 is supplied with power in parallel with the fuse 74 and the low voltage transformer 71 to cut off the power supply of the system when an overvoltage or overcurrent occurs, so that the microwave oven is opened and closed. Accordingly, the cavity switch 77, the gear motor 78, and the fan motor 79, which are provided to be operated according to the contact of the stable switch 76 and the relay controller 81, in which power cutoff is determined, are connected.

Hereinafter, the operation of the conventional microwave oven according to the above configuration will be described.

First, commercial power supplied to the microwave is transmitted to the thermostat 70 via the fuse 74. At this time, the thermostat 70 supplies power due to continuous contact unless the magnetron is heated above a predetermined temperature. Therefore, power is applied to the stable switch 76 and the low voltage transformer 71 through the thermostat 70 in the driving state of the normal microwave oven. The power applied to the stable switch 76 is switched according to whether the door is opened or closed, and the power applied to the low voltage transformer 71 induces a magnetic force generated in the primary coil to the secondary coil to generate a predetermined low voltage. Let's do it.

At this time, the low voltage generated from the secondary side of the low voltage transformer 71 is applied to the system control unit 72 and used for the rated control, which is the relay control unit 81 according to the control signal of the microcomputer 80. Will be driven. In addition, the drive signal of the relay controller 81 drives the cavity lamp 77, the gear motor 78, and the fan motor 79 to smoothly perform cooking.

On the other hand, excessive heating of the magnetron during cooking, for example, when the cooking time is set excessively, or when the magnetron is operated under no load and overheating occurs, the thermostat 70 near the magnetron senses heat to switch contacts. Let's go. Therefore, the power applied to the system is cut off, which causes the magnetron to stop running and at the same time the self heating of the magnetron is stopped. In addition, as the power supplied to the low voltage transformer 71 is cut off by the contact switching of the thermostat 70, the system controller 72 is inverted to a reset state. This is because the fan motor 79 is stopped despite the overheating of the magnetron, and the self-heating of the magnetron takes a long time.

However, as shown in FIG. 1B, when the thermostat 70 is connected to the power input terminal of the high voltage transformer 73, only the thermostat 70 switches the contact point when the magnetron is heated by itself. Therefore, since the power is continuously supplied to the system controller 72, the reset state of the microcomputer 80 is not achieved. On the other hand, when the overheat state of the magnetron is released, the thermostat 70 switches contacts again, and when the magnetron receives power and causes the overheat state again, the thermostat 70 switches contacts again.

As a result, the microwave oven according to the above two configurations takes a long time until the thermostat re-operates, or a frequent operation of the thermostat occurs, causing breakage or deterioration of the magnetron element. Therefore, a problem arises that the system is unstable regardless of the position of the thermostat 70.

The present invention was devised to solve the above problems, and the object of the present invention is that when the magnetron due to the abnormal state of the microwave is overheated, the thermostat is repeatedly operated by initializing the system at the same time to quickly remove the overheated state. It is to provide a safety device using a three-terminal thermostat to ensure the stability of the microwave oven so as not to perform.

Therefore, the safety device using the three-terminal thermostat according to the aspect of the present invention for achieving the above object, the thermostat is provided in the initial power input terminal having a normal contact terminal and a non-normal contact terminal around a common terminal; And a power supply in a normal state through a normal contact terminal of the thermostat, and a fan motor is directly connected to a non-contact terminal in a normal state to quickly suppress overheating of the magnetron in an abnormal state. .

Figure 1a is one embodiment showing a safety device of a microwave oven through a conventional thermostat.

1B is a circuit diagram illustrating another embodiment of FIG. 1A.

2 is a circuit diagram showing a safety device of a microwave oven according to the present invention.

<Explanation of symbols for main parts of drawing>

10: thermostat 16: low voltage transformer

18: cavity lamp 20: gear motor

22: fan motor 24: relay control unit

26: system control unit 28: microcomputer

30: high voltage transformer

Hereinafter, the present invention will be described in detail based on the accompanying drawings.

2 is a circuit diagram showing the present invention. The present invention with reference to Figure 2, when the magnetron is heated above a certain temperature to cut off the power supply and to operate the fan motor 22, the common terminal (COM), the normal contact terminal (NC), the non-normal terminal (NO) Using a thermostat 10 having a constant voltage, a low voltage transformer 16 for converting a commercial power applied through the thermostat 10 to a predetermined low voltage, and a constant low voltage obtained through the low voltage transformer 16. A system controller 26 for driving the system;

The system controller 26 includes a microcomputer 28 for overall control of the system, a relay controller 24 for controlling power supply according to the voltage output from the microcomputer 28, and the system controller 26. It consists of a high-voltage transformer 30 for applying a high voltage to the magnetron.

In addition, the front end of the thermostat 10 is supplied with power in parallel with the fuse 12 and the low voltage transformer 16, which cut off the power of the system when an overvoltage or an overcurrent occurs. Accordingly, the cavity switch 18, the gear motor 20, and the fan motor 22, which are provided to operate according to the contact of the stable switch 14 and the relay control unit 24, which determines whether to shut off the power, are connected.

Hereinafter, the operation of the present invention according to the above configuration will be described.

First, the commercial power supplied to the microwave oven is applied to the thermostat 10 through the fuse 12. As the thermostat 10 is connected to the common terminal COM and the normal contact terminal NC in a normal state, the commercial power is supplied to the primary side of the low voltage transformer 16. At this time, after the user places the food in the chamber of the microwave oven, when the cooking preparation is completed by operating the cooking start key, the door switch 14 forms a contact point. The commercial power is supplied to the system control unit 26, the microcomputer 28 outputs a plurality of control signals to perform the cooking function.

The control signal of the microcomputer 28 is transmitted to the relay control unit 24 so that the power is supplied to the high voltage transformer 30 to operate the magnetron, and at the same time, the cavity lamp 18 is turned on and the gear motor ( 20) to make cooking smooth.

If the user sets the cooking time excessively or drives the magnetron under no load without food, the magnetron may cause an overheating state. Will be detected. When this overheating state continues, the thermostat 10 gradually switches the contact point from the normal contact terminal NC to the non-normal contact terminal NO.

Therefore, the commercial power introduced through the fuse 12 is supplied to the fan motor 22 through the common non-contact terminal NO through the common terminal COM of the thermostat 10. The power supplied to the low voltage transformer 16 is cut off to stop the driving of the system controller 26. That is, the fan motor 22 is forcibly operated due to the overheating state of the magnetron, and the system controller 26 is initialized.

Thus, not only the temperature rise of the electric compartment due to the overheating state of the magnetron is suppressed, but also the temperature of the electric compartment due to the operation of the fan motor 22 is drastically lowered. When the temperature of the electric room is lowered below a certain value, the thermostat 10 switches the contact again, and the contact is switched from the non-normal contact terminal NO to the normal contact terminal NC. This stops the drive of the fan motor 22, and the temperature of the electrical equipment chamber is lowered below the reference value.

Then, the commercial power introduced through the fuse 12 is supplied to the low voltage transformer 16 through the common contact terminal NC through the common terminal COM of the thermostat 10. At this time, the microcomputer 28 is again supplied with power through the low-voltage transformer 16, but the power supply to the high-voltage transformer 30 is not made because it maintains the initialization state. As a result, the temperature in the battle room is continuously reduced, leading to a steady state.

As described above, the present invention allows the common terminal (COM) and the normal contact terminal (NC) to contact when the microwave oven is in a normal state, and the common terminal (COM) and the non-normal contact terminal (NO) when the magnetron is overheated. ) Is equipped with a three-terminal thermostat to form a contact point, but is installed in the power supply input terminal, so that when the thermostat is operated when an abnormal state of the magnetron occurs, the temperature of the electrical room is rapidly lowered and the microwave is initialized. It is possible to prevent breakage or deterioration of the magnetron device and to ensure the stability of the microwave system by preventing the magnetron from overheating and overheating.

As described above, the present invention has been described in detail with reference to the above-described embodiments, but the cooling circuit using the three-terminal thermostat of the present invention is not limited thereto, and modifications and improvements are possible within the ordinary knowledge of those skilled in the art.

Claims (1)

In the microwave safety device for suppressing the overheating state of the magnetron, In the normal state, commercial power is supplied to the system through the common contact terminal (NC) through the common terminal (COM), and in the overheat state of the magnetron, the common terminal (COM) and the normal non-contact terminal (NO) form a contact system. At the same time, the power supply is blocked, and the thermostat 10 is provided to force the fan motor 22 to be driven. And Safety device using a three-terminal thermostat, characterized in that the thermostat 10 is installed at the power input terminal of the system.