KR19980085393A - Inrush current prevention and fire protection device of electronic microwave oven - Google Patents

Abstract

The present invention relates to an inrush current prevention and fire protection device of an electronic microwave oven. In order to prevent the occurrence of a fire during abnormal operation such as a malfunction of a slow acting relay in a conventional microwave oven, a fuse is used or an inrush current is applied to the bottom plate of the electric room. To install cement resistor for prevention, there is inconvenience of after-fuse after service, that is, need to replace when using fuse, safety of fire prevention when cement register is installed on the floor of electrical equipment room, and cement resistor is installed with screw There is a problem in that the productivity is reduced because the workman is increased because it is installed on the bottom plate.

Accordingly, the present invention is connected to the PTC thermistor 10 in front of the input terminal of the switch 3 of the slow acting relay RY3 which is installed on the PCB substrate 20 and turned on when the set is started. On the other hand, by installing the Piti thermistor on the PCB substrate to prevent fire and inrush current due to its own characteristics, and to install on the PCB substrate to achieve cost reduction and productivity.

Description

Inrush current prevention and fire protection device of electronic microwave oven

The present invention relates to a microwave oven, in particular, to prevent inrush current during normal operation of the slow acting relay when the microwave is started, and a fire occurs during a malfunction in which the turn-off time is long after the slow acting relay is turned on. It is to provide an inrush current prevention and fire protection device of an electronic microwave oven, which can be installed on the PCB substrate to achieve the labor and cost reduction.

In general, the microwave oven is a kitchen appliance for cooking food by the high frequency emitted from the magnetron. When the user selects the cooking time and the output level of the high frequency, the output level of the high frequency is controlled during the cooking time to perform cooking.

Looking at the electronic microwave driven in this manner through the driving circuit diagram of FIG. One end is connected to the first door switch (SW1) and the monitor switch (M _SW ), the slow of the fuse (1), the terminal type cement register (2) and the control board connected in series with the monitor switch (M _SW ) The switch 3 of the acting relay RY3 and the switch 4 of the main relay RY1 of the control board are connected in parallel, and the switches 3 and 4 of the slow acting relay RY3 and the main relay RY1 are connected in parallel. Is connected to one end of the primary winding of the high-voltage transformer (HVT) through the magnetron thermostat (M _TH ) for preventing overheating of the magnetron (MG).

The input terminal of the switch 4 of the main relay RY1 is commonly connected to one end of the cavity lamp CL, the turntable motor GM, and the cooling fan motor FM through the switch 5 of the sub relay RY2. Connected.

The other end of the input power source is connected to the other end of the primary winding of the high voltage transformer HVT through the second door switch SW2 while the cavity lamp CL is connected to the output end of the second door switch SW2. It is commonly connected to the other end of the turntable motor GM and the cooling fan motor FM, and the secondary winding of the high voltage transformer HVT is connected to the magnetron MG through the high voltage capacitor HVC and the high voltage diode HVD. Connected.

The driving circuit of the electronic microwave oven configured as described above automatically closes the door when cooking is completed, and the first and second door switches SW1 and SW2 are turned on. It can be done.

That is, when the cooking function and the cooking time are selected after the door is closed, the power is applied to the low voltage transformer (HVT) of the control board and driven by the slow acting relay RY3, the sub relay RY2, and the main relay RY1. The cavity lamp CL, the turntable motor GM, and the cooling fan motor FM are driven, and power is applied to the high voltage transformer HVT through the main relay switch 4.

The secondary winding output of the high-voltage transformer (H.V.T) is applied to the magnetron (MG) through the high-voltage capacitor (H.V.C) and the high-pressure diode (H.V.D) to cook according to the driving of the magnetron (MG).

As described above, the slow acting relay RY3 and the terminal cement register 2, which are initially driven in the circuit configuration of the electronic microwave oven, are turned on after the slow acting relay RY3 turns on the inrush current flowing in when the microwave is started. It is for attenuation by passing through the cement resistor 2 by slow acting during the turn-off time.

That is, since the power is applied to the high voltage transformer HVT through the cement resistor 2 during the contact turn-on time of the slow acting relay switch 3, the voltage is lowered by the resistance value of the cement resistor 2 so that the inrush current is attenuated. Will be.

After the inrush current is attenuated by the cement resistor 2 during the turn-on time, the slow acting relay RY3 is turned off, and the main relay RY1 is turned on so that the rated voltage, that is, the stable power supply, does not pass through the cement resistor 2. It is applied to this high voltage transformer (HVT).

This attenuation of the inrush current flowing into the circuit is important to apply a stable power supply to the high voltage transformer (HVT), but in particular, the European market, which is further strengthening the quality standards of electronic devices by adding a new regulation item called FLICKER. It is also important to respond.

In addition, the fuse 1 connected to the front end of the cement resistor 2 has a circuit in which the slow acting relay RY3 malfunctions while the power is applied to the circuit, that is, when the turn-off time becomes long after the switch 3 is turned on. Since the power applied to the cement resistor 2 becomes longer, the heat generation degree of the cement resistor 2 increases, so that the power applied to the cement resistor 2 is installed to prevent the risk of fire caused by the heat generation.

Although the fuse 1 may be used as described above, the cement resistor 2 may be installed as a screw 7 on the base plate 6 of the electric chamber without using the fuse as shown in FIG. 2 to prevent the risk of fire.

However, if the fuse is used in preparation for abnormal operation such as a malfunction of the slow acting relay, there is an inconvenience of after-fuse after service, that is, the need to replace the fuse. There is a problem in that the safety is lowered and the productivity of the work is increased due to the increase in the number of work due to the installation of the cement resistor on the floor of the electrical equipment room with a screw.

Accordingly, an object of the present invention is to solve the conventional problems, and to prevent inrush current during normal operation of the slow acting relay when the microwave is started, and to malfunction when the slow acting relay is turned on after a long time. In the abnormal operation, such as to prevent the occurrence of fire, and to install on the PCB substrate to reduce the cost and improve the productivity to provide an inrush current prevention and fire protection device of the microwave oven.

The object of the present invention is to connect a finite thermistor embedded in a heat-resistant cap in front of a switch input terminal of a slow acting relay installed on the PCB and being turned on when the microwave is started, while installing the finite thermistor on the PCB. Is achieved.

In the present invention, when the slow acting relay is in an abnormal operating state, the fitness thermistor acts as a fuse by preventing current from flowing into the inrush current prevention circuit due to the resistance value due to its own characteristics, and generates heat due to resistance by the heat resistant cap. Since the fire is prevented from being emitted to the outside, and the slow acting relay is in a normal operating state, the fitness thermistor prevents inrush current and thus serves as a conventional cement resistor, thereby achieving the above object.

1 is a rush current prevention and fire prevention before using a conventional cement resistor and fuse

Driving circuit diagram of child microwave oven

2 is a perspective view showing a conventional cement resistor installation state

Figure 3 is an inrush current prevention and fire prevention electronic using the fitness thermistor of the present invention

Microwave Drive Circuit Diagram

Fig. 4 shows the installation state of the fitness thermistor on the PCB substrate according to the present invention.

Yobu Sashido

Explanation of symbols for main parts of the drawings

1: fuse 2: cement resistor

3: Slow Acting Relay Switch 4: Main Relay Switch

6: base plate 7: screw

10: PTC thermistor 11: heat-resistant cap

20: PCB substrate RY1: main relay

RY3: Slow Acting Relay

Hereinafter, with reference to the accompanying drawings the technical configuration and effect as a preferred embodiment that can effectively achieve the object of the present invention will be described.

FIG. 3 is a configuration circuit diagram of the present invention using a finite thermistor, and FIG. 4 is a perspective view showing a state in which a finite thermistor is installed on a PCB substrate. As shown in the present invention, the present invention is a driving circuit of a microwave oven. A PTC thermistor 10 is connected to an input terminal of the switch 3 of the slow acting relay RY3 which is installed on the set 20 and turned on at the start of the set, and the PCB is placed on the PCB 20. Installed and configured.

The fitness thermistor 10 is a device having a role of preventing inrush current and preventing fire, and is installed in a heat resistant cap 11 that withstands heat generated by its own characteristics.

The thermistor 10 having the same function as above maintains the initial resistance value by its temperature-resistance characteristics, and then the resistance value rapidly increases when the temperature of its Curie temperature reaches about 120 ° C. In other words, the resistance increases as the temperature increases.

As described above, the present invention connects the fuse 1 and the cement resistor 2 between the input terminal and the output terminal of the conventional slow acting relay RY3 or the cement resistor 2 is connected to the electric chamber bottom plate 6 without connecting the fuse 1. In order to prevent the occurrence of fire by installing in the), it is possible to prevent the cost reduction and the occurrence of fire as well as to prevent the occurrence of cost and fire by using the function of the fuse thermistor (10) as the conventional fuse (1) and cement resistor (2). It is intended to reduce the labor and cost by installing the 10 to the PCB substrate 20.

The purpose of this invention will be described through the action of the fitness thermistor how the fitness thermistor is achieved as follows.

That is, when the slow acting relay RY3 is turned on normally after turning on, the current flows into the fitness thermistor 10 during the turn-on time when the normal operation is performed. The inrush current is attenuated by the resistance value.

After the slow acting relay RY3 is turned on to attenuate the inrush current, the switch 4 of the main relay RY1 is turned on to supply power to the high voltage transformer H.V.T through the switch 4.

On the other hand, when an abnormal operation such as a malfunction in which the turn-off time is long after the slow acting relay RY3 is turned on, the current from the power input flows through the fitness thermistor 10 for a long time, thereby causing the fitness thermistor 10 to fail. ) Generates a considerable heat, and the current reaches the Curie temperature due to its own characteristic, that is, the resistance value increases with increasing temperature, and the resistance value rapidly rises vertically. Since it does not flow to act as a conventional fuse is applied to the high voltage transformer (HVT) normally through the main relay (RY1).

In addition, the high heat generated by the characteristics of the finite thermistor 10 is not released to the outside by the heat resistant cap 11.

The exothermic temperature of the fitness thermistor 10 increased during abnormal operation of the slow acting relay RY3 does not adversely affect the destruction of the fitness thermistor 10.

As described above, the fitness thermistor 10 prevents the inrush current in the same role as the conventional cement resistor 2 when the slow acting relay RY3 operates normally, and the conventional fuse 1 during the abnormal operation. In the same role as will open the inrush current prevention circuit.

As described above, the use of a fitness thermistor which serves as a conventional fuse and cement resistor prevents fires that may occur during cost reduction and abnormal operation of a slow acting relay, and by installing a fitness thermistor on a PCB substrate Since wires and work processes are eliminated due to the installation of cement resistors on the bottom of a conventional electric room, cost reduction and productivity are improved.

In addition, by using a fitness thermistor, there is no after-sales service such as replacement after the conventional fuse blowdown, thereby increasing convenience.

Claims (1)

In a microwave driving circuit including a slow acting relay (1) installed on a PCB and turned on at start-up, a pith (PTC) thermistor (10) embedded in a heat resistant cap (20) in front of a switch input terminal of the slow acting relay (10). And an electric current insulator and fire protection device according to claim 1, wherein the fitness thermistor is installed on the PCB 20.