KR200153223Y1 - Overload for preventing circuit for microwave oven - Google Patents

Abstract

The present invention is to provide an overload protection circuit in a microwave oven that can effectively prevent the overload as well as the need for a separate fuse by simply implementing a circuit by using a DC relay and PTC thermistor.

To this end, the present invention is connected to the output side of the variable power controller 12b, rectifier (18) for rectifying the power input through the resistor (R1), the resistor (R2) and the capacitor (C) via the rectifier ( A DC relay RY connected to the output side of the circuit 18 to operate the high voltage transformer 16 and a switch S of the DC relay RY connected in parallel and above the predetermined value due to overload. 16) It is composed of a power cut-off element (PTC) that cuts off the power to the furnace, and can effectively prevent fire without the need for a separate fuse, and also has a simple structure and significant cost in comparison with the conventional circuit configuration.

Description

Overload Protection Circuit in Microwave Oven

The present invention relates to an overload protection circuit in a microwave oven, and more particularly, in a microwave oven in which a DC relay and a PTC thermistor are adopted to very easily prevent an overload (eg, inrush current) due to power supply. The overload protection circuit of the present invention.

In general, mechanical microwave ovens exported to Europe, etc., must pass the Flicker test to meet the CE standard. To this end, resistors and relays are used to prevent inrush current (transient current) generated when the initial power is applied.

That is, as shown in FIG. 1, a timer unit 12 (Timer Ass'y) for determining the cooking time of the microwave and the output mode of the magnetron, as shown in FIG. 12 is installed between the high voltage transformer 16 and the slow acting relay assembly 14 which absorbs the inrush current (transient current; flicker component) generated when the initial power is applied to increase the initial operating time. ) Will be equipped.

Here, the timer unit 12 is a variable for controlling the oscillation of the magnetron on the basis of the timer switch 12a that is on for a set time according to the user's timer knob operation and the output mode set according to the user's power knob operation. A power controller 12b and a timer motor 12c for turning on the timer switch 12a and the variable power controller 12b for a cooking time set by a user.

In addition, the slow acting relay unit 14 includes an AC relay 14a having a constant self-response speed (for example, about 10 msec), and a resistor R connected in parallel with a switch of the AC relay 14a (mainly a cement resistor). Is used).

In the conventional mechanical microwave oven configured as described above, the timer is set once the user operates the timer knob (not shown) and the power knob (not shown) installed on the control panel to set the cooking time and the output mode (strong or weak). The timer switch 12a and the variable power controller 12b in the unit 12 are kept in the on state according to the operation of the timer motor 12c during the set cooking time, and thus the AC flows through the power plug 10. Power is applied to the primary side of the high voltage transformer 16 via the slow acting relay portion 14.

Here, the slow acting operation will be described in more detail. In the slow acting relay unit 14, the AC relay 14a is activated as soon as the initial power is applied through the timer switch 12a and the variable power controller 12b. However, since there is a self-response speed, power is applied to the high voltage transformer 16 through the resistor R during the self-response speed (for example, about 10 msec), and the inrush current is reduced by the resistor R. When the self-response speed passes (ie, after the inrush current is turned down), the AC relay 14a is activated, so that power is applied to the high voltage transformer 16 through the switch of the AC relay 14a.

However, after the absorption of the inrush current is completed, if the abnormality such as the coil of the AC relay 14a is disconnected in the state where the magnetron is normally started by the high voltage transformer 16, the AC relay 14a is functioning. Since it is impossible to perform the power supply is applied to the high-voltage transformer 16 through the resistor (R). Therefore, in this case, the temperature of the resistor R rises vertically, acting as a ignition medium on the nearby mold, thereby causing a fire.

Accordingly, in order to prevent this, as shown in FIG. 2, the fuse F is installed at the front end of the resistor R to prevent overheating due to the temperature rise of the resistor R. FIG.

However, the AC relay 14a has a problem in that it takes up a lot of space when it is installed because of its large size, and additional cost is generated due to the additional installation of the fuse F to prevent overheating of the resistor R. Complexity arises.

Therefore, the present invention has been made to solve the above-mentioned conventional problems, and its purpose is to implement a circuit by simply adopting a DC relay and a PTC thermistor, so that not only a separate fuse installation is required, but also an overload can be effectively prevented. It is to provide an overload protection circuit in a microwave oven.

According to a preferred embodiment of the present invention for achieving the above object, a rectifier is connected to the output side of the variable power controller rectifying the power input through the resistor; A DC relay connected to an output side of the rectifier through a resistor and a capacitor to operate a high voltage transformer; And a power cut-off element connected in parallel to the switch of the DC relay and cut off the power to the high voltage transformer at a temperature higher than a certain value due to overload.

1 is a view showing an embodiment of an overload protection circuit in a general microwave oven.

2 is a view showing another embodiment of the overload protection circuit in a general microwave oven.

3 is a view showing an overload protection circuit in a microwave oven according to a preferred embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

10: power plug 12: timer

14: slow acting relay unit 16: high voltage transformer

18: rectifier 12a: timer switch

12b: variable power controller 12c: timer motor

14a: AC relay RY: DC relay

PTC: PTC Thermistor (Positive Temperature Coefficient Thermistor)

Hereinafter, with reference to the accompanying drawings for an embodiment of the present invention will be described in more detail.

3 is an overload prevention circuit diagram of a microwave oven according to an embodiment of the present invention. First, a resistor R1 connected to the output side of the variable power controller 12b for voltage distribution, and bridge diodes D1 and D2 connected to one end of the resistor R1 for full-wave rectification of the voltage passing through the resistor R1. And a rectifier (18) consisting of D3 and D4, connected to the output terminal of the rectifier (18) via a resistor (R2) and a capacitor (C) and activated by an output signal of the rectifier (18). 16 is connected in parallel to the DC relay RY for operating the switch and the switch S of the DC relay RY, and the overload is caused due to the failure of the DC relay RY, and the temperature rapidly exceeds a certain value. When raised, it is composed of a power cut-off device (PTC) that cuts off the power applied to the high voltage transformer 16.

In the same figure, although the timer motor 12c may be shown, since the timer motor 12c is installed at the same position and performs the same function in FIG. 1, illustration and description thereof are omitted.

Here, the DC relay RY is not only smaller in size than the conventional AC relay but also cheap in production cost. And, like the AC relay, the DC relay RY has a constant self-response speed (for example, about 20 msec).

In addition, the switch S of the DC relay RY is installed between the variable power controller 12b and the high voltage transformer 16, and one terminal of the switch S is connected to the variable power controller 12b and a resistor ( R1) and one end of the power cut-off element PTC, and the other terminal of the switch S is connected to one end of the primary side of the high voltage transformer 16 and the other end of the power cut-off element PTC.

In addition, in the embodiment of the present invention, the power cutoff device (PTC) is not only much smaller than the conventional cement resistance in size, but also has an initial resistance of about 39 kΩ, and a Curie Point (Curie Point) is used. PTC thermoster about 120 degreeC is employ | adopted. Therefore, in the embodiment of the present invention, the PTC thermistor PTC acts as a general resistor when the DC relay RY is normal, and generates heat when the DC relay RY is abnormal (for example, a failure due to coil breakage). Due to the increase in the ambient temperature, the resistance value of the unit changes in mega units, which cuts off the power.

Of course, the PTC thermistor (PTC) may be adopted to have a different initial resistance value and a Curie point as necessary.

Next, the operation of the overload protection circuit in the microwave oven according to the embodiment of the present invention configured as described above is as follows.

First, a case in which the DC relay RY is normal will be described. In the initial stage when power is applied as the timer switch 12a and the variable power controller 12b are turned on, the power divided by the resistor R1 is a rectifier. Rectified by (18), the DC relay (RY) is applied through the resistor (R2) and the capacitor (C) to activate the DC relay (RY), so the inrush current is lowered through the PTC thermistor (PTC) for about 150msec. It is applied to the primary side of the high-voltage transformer 16 in the state. In addition, when the delay time ends (that is, when the inrush current is absorbed), the switch S of the DC relay RY is turned on, and the power is supplied to the primary side of the high voltage transformer 16 through the switch S. Is approved.

When the DC relay RY burns out (for example, when the coil is disconnected) during normal operation, all the power flows to the PTC thermistor PTC because the switch S is turned off. Therefore, as time passes, the ambient temperature rises further due to the heat generation of the PTC thermistor (PTC), and as a result, the resistance value of the PTC thermistor (PTC) changes in mega units as the temperature increases to the Curie point, thereby increasing the pressure. The power applied to (16) is cut off.

As described above, according to the present invention, if the DC relay is damaged and excessive load is applied to the PTC thermistor after the slow acting operation by adopting the DC relay and the PTC thermistor, the power is automatically cut off, so a separate fuse installation is necessary. Not only can the fire prevention be effectively performed, but also there is a significant advantage in terms of cost and simple configuration compared to the conventional circuit configuration.

Claims (2)

A rectifier 18 connected to the output side of the variable power controller 12b for rectifying power inputted through the resistor R1; A DC relay RY connected to an output side of the rectifier 18 via a resistor R2 and a capacitor C to operate the high voltage transformer 16; And a power cut-off element connected in parallel to the switch S of the DC relay RY to cut off power to the high voltage transformer 16 when a temperature exceeding a reference value due to overload occurs. Circuit. The overload protection circuit of claim 1, wherein the power interrupting device (PTC) is a PTC thermistor.