KR0117544Y1 - Over-heat protecting power circuits of household electric appliances - Google Patents

Abstract

The present invention relates to a power circuit for preventing overheating of home appliances, and in the related art, since power is continuously supplied to a load driving constant voltage unit regardless of whether a load is driven, there is a concern that there is no concern about overheating and cooling time.

The present invention, in view of such a conventional problem, in the power supply circuit of the home appliance, by connecting the power input terminal of the microcomputer power supply constant voltage section 4a to the power output terminal of the load-driven power supply constant voltage section 4b, the smoothing At least one of the selection unit 20 and the load 5 for selectively applying the output power of the unit 3 to the microcomputer power supply constant voltage unit 4a or the load driving power supply constant voltage unit 4b. Based on the control signal of the microcomputer 10 which controls the selection unit 20 to apply the output power of the smoothing unit 3 to the constant voltage unit 4b for the load driving power only when driving the above. By providing the overheat prevention power supply circuit of the home appliance including the selection driver 30 for driving the selection unit 20, it is possible to have a cooling time to prevent overheating.

Description

Overheating prevention power supply circuit of home appliance

1 is a power circuit diagram of a conventional home appliance.

2 is a circuit diagram for preventing overheating of a home appliance according to the present invention.

* Explanation of symbols for main parts of the drawings

1: power supply transformer 2: rectifier

3: smooth part 4: constant voltage part

4a: constant voltage section for microcomputer power supply 4b: constant voltage section for load driving

5: load 10: microcomputer

11: Load drive section 20: Selection section

30: Selection drive Q1: Transistor

RY1: Relay RY11: Relay Switch

The present invention relates to a power supply circuit of a home appliance, in particular, in a DC power supply circuit used in a microwave oven, by operating only the constant voltage unit for the microcomputer power supply when there is no load driving, it is possible to prevent overheating of the DC power supply circuit An overheating prevention power supply circuit of a home appliance.

In general, a DC power supply circuit applied to a home appliance includes a power supply transformer 1 for stepping down an input power supply as shown in FIG. 1, and full-wave rectification of the secondary output power supply of the power supply transformer 1 to a DC power supply. The rectification part 2, the smoothing part 3 which smoothes the output power of the rectifying part 2, and the several power failure which stabilizes the output power of the smoothing part 3 to a suitable constant voltage according to a load, and supplies it to a load. It consists of Abu (4).

In the DC power supply circuit of such a conventional home appliance, when the input power source AC is applied to the primary side of the power supply transformer 1, the voltage according to the turns ratio is induced on the secondary side thereof.

For example, if 24V, 12V, 5V, etc. are needed for the low voltage power required to drive the electric equipment of home appliances, the power supply transformer (1/110) is used to induce 110 / 220V of household input power more than 24V on the secondary side. Will be designed).

Here, it is also possible to design not only both ends of the secondary winding of the power transformer 1 but also to configure the intermediate taps so that the necessary secondary power can be obtained separately. It is designed to obtain only the maximum voltage required for the load, and low voltage AC power is used through the intermediate tap.

The secondary side power source stepped down in the power supply transformer 1 is full-wave rectified through the rectifying unit 2, which is a bridge diode, which is connected directly through the resistor R1 of the smoothing unit 3 and the smoothing capacitor C1 (C2). Smoothed to power.

Subsequently, the smoothed DC power supply is stabilized at a constant voltage suitable for each load through the constant voltage unit 4 serving as a regulator and supplied to the load.

That is, since the 5V DC power is used as the power supply of the microcomputer 5a, and the other loads 5b use the required voltages, the constant voltage unit 4a for supplying power to the microcomputer 5a and a plurality of other loads are used. A plurality of constant voltage units 4b for supplying power of 5b are separately provided to stabilize and supply voltages smoothed at the smoothing unit 3 to voltages required for the respective loads.

However, since the standby power should always be applied to the microcomputer 5a while the main power is applied, the constant voltage unit 4a should always be operated, but the load driving constant voltage unit 4b does not operate when the load is not driven. You don't have to.

However, even when the load is not driven, the power is supplied to the load driving constant voltage unit 4b. However, since the load is not driven, heat is generated in the load driving constant voltage unit 4a. In addition to shortening the life of each component, there was a disadvantage that can cause a malfunction.

The present invention is to provide an overheat prevention power supply circuit of a home appliance to achieve a cooling effect naturally by switching the power supply is not supplied to the load driving constant voltage unit when the load is not driven in view of such a conventional problem. .

The purpose of the present invention is to reduce the input power to a predetermined voltage, rectify and smooth it to a DC voltage, and then supply it to the microcomputer and various loads through the constant voltage part, respectively, to the power output terminal of the constant voltage part for the load driving power supply. When connecting the power input terminal of the constant voltage unit for the microcomputer power supply, and driving any one of a plurality of loads under the control of the microcomputer, apply the output power of the smoothing unit to the constant voltage unit for the load driving power, and do not drive all the loads. If not, it is achieved by including a selection unit for applying the output power of the smoothing unit only to the constant voltage unit for the microcomputer power supply and a selection driving unit for driving the selection unit.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a circuit diagram for preventing overheating of home appliances according to the present invention, and as shown therein, the input power is stepped down to an appropriate voltage through the power supply transformer 1 to supply DC power through the rectifying unit 2 and the smoothing unit 3. After converting the power to the driving power of the various loads 5 through the constant voltage unit 4b for the load driving power supply, the various loads 5 are applied to the load driving unit 11 through the microcomputer power supply constant voltage unit 4a. In the power supply circuit of the home appliance, which is configured to be applied to the respective microcomputers 10 to be controlled, the power input terminal of the microcomputer power supply constant voltage unit 4a is connected to the power output terminal of the load driving power supply constant voltage unit 4b. Selects to selectively apply the output power of the smoothing part 3 to the microcomputer power supply constant voltage unit 4a or the load driving power supply constant voltage unit 4b through a voltage drop resistor R2. And the selector 20 applies the output power of the smoothing part 3 to the constant voltage part 4b for the load driving power only when driving at least one of the load 20 and the load 5. And a selection driver 30 for driving the selection unit 20 based on the control signal of the microcomputer 10.

Here, the selector 20 connects the common terminal C of the relay switch RY11 of the relay RY1 to the output terminal of the smoothing unit 3, and a contact terminal (a) of the relay switch RY11. a) is connected to the constant voltage part 4b for driving the load, and the b contact terminal b of the relay switch RY11 is connected to the constant voltage part 4 for the microcomputer power supply through the voltage drop resistor R2, The relay RY1 for operating the relay switch RY11 has a power supply terminal 5V connected to one terminal of the relay coil, the other terminal connected to the selection driver 30, and one terminal and the other side of the relay coil. It is configured by connecting the relay protection diode (D1) between the terminals.

The selection driver 30 connects the base of the transistor Q1 having the emitter grounded to the control signal output port P4 of the microcomputer 10 through a resistor R3 and a ground resistor R4. The collector of the transistor Q1 is connected to the other terminal of the relay coil of the selector 20.

Referring to the operation and effect of the embodiment according to the present invention configured as described above are as follows.

When the input power source AC is applied to the primary side of the power supply transformer 1, an appropriate voltage is induced on the secondary side according to the turns ratio.

Subsequently, the secondary power source of the power supply transformer 1 is full-wave rectified through the rectifying section 2, which is a bridge diode, which is connected directly through the resistor R1 of the smoothing section 3 and the smoothing capacitor C1 (C2). Smoothed to power.

The smoothed DC power supply selectively supplies power to the load driving constant voltage unit 4b or the microcomputer constant voltage unit 4a according to the switching selection of the selector 20.

At this time, if the relay of the selector 20 is off, that is, the relay switch RY11 is short-circuited to the b contact terminal b, the power is supplied to the microcomputer constant voltage unit 4a through the voltage drop resistor R2. It is supplied, stabilized by the DC 5V power supply by the microcomputer constant voltage part 4a, and is supplied by the power supply voltage of the microcomputer 10. Here, the output power of the microcomputer constant voltage unit 4a is not necessarily supplied only to the microcomputer 10, but is supplied to a portion requiring 5V as needed.

When the power supply voltage is supplied to the microcomputer 10 in this manner, the microcomputer 10 is operated to maintain the standby state, and in the standby state, the microcomputer 10 outputs the output port (based on an operation signal such as a keyboard (not shown). The load driving signal is output through P0-P3 to selectively drive the load 5 through the load driver 11.

In addition, when any one of the loads 5 of the microcomputer 10 is driven as described above, a high-voltage potential is output from the control signal output port p4 of the microcomputer 10 and connected to the control signal output port p4. The power is applied to the transistor Q1 of 30, and accordingly the power is applied to the relay RY1 connected to the selection driver 30 so that the relay switch RY11 is used for load driving under the control of the relay RY1. The output power of the smoothing unit 3 is applied to the load driving constant voltage unit 4b while being connected to the a contact terminal a connected to the constant voltage unit 4b.

When the power is supplied to the load driving constant voltage unit 4b as described above, the load driving constant voltage unit 4b supplies the power of each load 5, that is, the load A-load D, and the load driving constant voltage unit. Since the input terminal of the microcomputer driving constant voltage section 4a is connected to the output terminal of 4b, the constant voltage section for load driving when the relay switch RY11 of the selector 20 is short-circuited to the contact b. Both the 4b and the microcomputer driving constant voltage section 4a output the constant voltage of the rated designation, respectively.

At this time, the power supply voltage should be supplied to the microcomputer 10 without interruption. This means that the power input of the microcomputer constant voltage unit 4a is momentarily interrupted at the moment when the relay switch RY11 is switched, but the microcomputer has not responded to the momentary power failure. Since the constant voltage unit 4a is designed to have a sufficiently stable power output, there is no problem in supplying stable power to the microcomputer 10.

In addition, when different power voltages are required among the load A-load D, a plurality of constant voltage units 4b for load driving are configured accordingly, and when a plurality of constant voltage units 4b for load driving are configured, The constant voltage unit 4a may be configured by being connected so that any one of the plurality of load driving constant voltage units 4b to which an output of at least 5V is output is applied as an input.

On the other hand, when the loads 5 are not all driven, the low potential signal is output through the control signal output port P4, and the transistor Q1 of the selection driver 30 is turned off by the low potential signal. As the transistor Q1 is turned off, the current path of the relay coil of the selector 20 is interrupted and the magnetic force is removed, so that the relay switch RY11 is shorted to the b contact terminal b.

Thereby, the power of the smoothing part 3 is supplied only to the microcomputer constant voltage part 4a, and power is not supplied to the load drive constant voltage part b.

Therefore, in the present invention, the power is not supplied to the load driving constant voltage unit 4b in a state in which the output power of the smoothing unit 3 does not drive all of the loads under the control of the microcomputer 10, thereby driving the load. The constant voltage unit 4b can have a cooling time.

As described in detail above, according to the present invention, it is designed not to supply power to the load driving constant voltage unit when there is no load driving, thereby cooling heat that may be generated in the constant voltage unit during load driving. It can have a cooling time, it is effective to prevent the extension of the life of the parts, malfunction and failure.

Claims (2)

A power supply transformer 1 for stepping down the input voltage, a rectifying part 2 for full-wave rectifying the output power of the power supply transformer 1, a smoothing part 3 for smoothing the rectified power of the rectifying part 2, and a relay switch (RY11) and a relay (RY1) for controlling it, a selection unit for selectively applying the output power of the smoothing unit 3 to either the microcomputer power supply constant voltage unit 4a or the load driving power supply constant voltage unit 4b. A load driving constant voltage unit 4b connected to a contact terminal a of the relay switch RY11 of the selection unit 20 and applying power to the load 5, and the constant voltage unit for load driving; A constant voltage unit 4 which is connected to the output terminal of (4b) and the b contact terminal (b) of the relay switch RY11 and which supplies the power to the microcomputer 10, and the constant voltage unit 4 consisting of the microcomputer constant voltage unit 4a and whether the load is driven or not; A selector driven by a control signal of the microcomputer 10 for controlling the relay RY1 of the selection unit 20; Thermal protection unit of the appliance, characterized in that consisting of 30, the power supply circuit. According to claim 1, wherein the selector 20 connects the input terminal (c) to the output terminal of the smoothing unit 3, the b contact terminal (b) through the voltage drop resistor (R2) for the microcomputer constant voltage unit ( A contact terminal (a) connected to 4a) is driven by a relay switch RY11 connected to the constant voltage unit 4b for load driving and the selection driver 30 to load the relay switch RY11 to the load 5. Is connected to the contact a terminal (a) connected to the load driving constant voltage unit 4b, and if the load 5 is not driven to the b contact terminal (b) connected to the microcomputer constant voltage unit 4a. Overheating protection power circuit of the home appliance, characterized in that consisting of a relay (RY1) to control to connect.