KR0141792B1 - Lamp brighting control method and circuit for microwave oven - Google Patents

Abstract

The present invention relates to a method and a circuit for adjusting the oven lamp brightness of a microwave oven. In the related art, since only two kinds of electric wave driving states or half wave driving states exist when the oven lamps are brightened, a user can arbitrarily select a brightness range. Narrow there was a problem that gives inconvenience to the user. To improve this point, the present invention configures a circuit to drive the lamp twice during one cycle of AC power and adjusts the ON time of the lamp when the oven lamp is turned on, thereby adjusting the time that the AC power is applied to the oven lamp. The brightness of the oven lamp can be arbitrarily subdivided according to the program, and thus the brightness of the oven lamp can be arbitrarily adjusted according to the user's taste, and the power supply time can be adjusted. Can be maximized.

Description

Method and circuit for adjusting the brightness of the oven lamp in the microwave

1 is a conventional oven lamp brightness adjustment circuit diagram.

2 is an oven lamp brightness adjustment circuit diagram of the present invention.

3 is a waveform diagram according to the lamp operating time in FIG.

4 is a signal flow diagram for adjusting the oven lamp brightness of the present invention.

* Explanation of symbols for main parts of the drawings

1: microcomputer 2: linear drive

3: Oven Lamp OT: Opto Triac

TA: Triac

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to oven lamp brightness adjustment of a microwave oven, and more particularly, to a method and circuit for adjusting oven lamp brightness of a microwave oven that linearly adjusts oven lamp brightness according to an alternating current input.

1 is a conventional oven lamp brightness adjustment circuit diagram, as shown therein, which shows a microcomputer 101 for outputting driving control signals CTL1 and CTL2 in accordance with a user's key input, and a signal of the microcomputer 101. The electric wave driver 102 propagates AC power according to CTL1 and applies it to the lamp 104, and applies AC wave half-wave according to the control signal CTL2 of the microcomputer 102 to the lamp 104. It consists of the half-wave drive part 103.

Referring to the operation of the conventional circuit as follows.

First, when the user inputs a key to brighten the oven lamp of the microwave oven, the microcomputer 101 outputs the control signal CTL1 at high potential.

At this time, in the radio wave driver 102 to which the high potential control signal CTL1 of the microcomputer 101 is applied, since the transistor Q1 is turned on and the relay RY1 is turned on, AC power is applied to the lamp 104.

Accordingly, the oven lamp 104 to which the AC power is directly applied only through the relay RY1 emits bright light.

Since the microcomputer 101 outputs the control signal CTL2 at low potential, the half wave driver 103 does not operate.

When the user attempts to dim the light of the oven lamp slightly, the microcomputer 101 outputs the control signal CTL2 at high potential.

At this time, since the transistor Q2 is turned on and the relay RY2 is turned on, the half wave driver 103 to which the high potential control signal CTL2 of the microcomputer 101 is applied has the AC power source AC connected to the diode D1 and the above. The relay RY2 is sequentially applied to the oven lamp 104.

Accordingly, only the AC power half-waved by the diode D1 is applied to the oven lamp 104, so that the oven lamp 104 emits light a little darker than in the case of propagation driving.

Here, since the microcomputer 101 outputs the control signal CTL1 at low potential, the radio wave driver 102 does not operate.

However, in the related art, since only two kinds of electric wave driving states or half wave driving states exist when the oven lamp is brightened, there is a problem in that the user has a narrow selection range of the brightness that can be arbitrarily selected by the user, causing inconvenience to the user.

In order to solve this problem, the present invention configures a circuit to drive the lamp twice during one cycle of the AC power and adjusts the ON time of the lamp when the oven lamp is turned on so that the AC power is applied to the oven lamp. Invented a method and circuit for adjusting the oven lamp brightness of the microwave oven to control the brightness by adjusting the brightness.

The present invention comprises the steps of determining whether to turn on the lamp in order to achieve the above object, calculating the delay time according to the input of the brightness degree when setting the lamp on in the step, and the delay time calculated in the step has elapsed The lamp is turned on every half cycle and the lamp off is determined.

In addition, the present invention provides a control means for calculating the delay time for the lamp on by calculating the input value of the brightness degree in order to achieve the above object, and outputs a drive pulse when the delay time has elapsed, and the driving means in the control means Each time a pulse is input, it consists of linear drive means which applies power to an oven lamp.

The linear drive means comprises an opto triac operated by a drive pulse of a microcomputer, and a triac operated by a power applied through the opto triac to apply power to an oven lamp.

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

2 is a circuit diagram of an embodiment of the present invention, as shown therein, which calculates a delay time for lamp-on by calculating an input value of a degree of brightness, and outputs a driving pulse when the delay time after the interruption has elapsed. And a linear drive unit 2 for supplying power to the oven lamp 3 whenever a drive signal of the microcomputer 1 is input.

The linear driving unit 2 is turned on to an opto triac OT that supplies power to a gate and conducts power according to a drive signal of the microcomputer 1, and is turned on to output power of the opto triac OT. It consists of triac (TA) applied to the oven lamp (3).

The opto triac OT is initialized whenever the power level becomes zero.

The triac TA is triggered when a high potential is applied to the gate and is turned off when there is no current flow by turning the power to zero.

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

When the user inputs a lamp-on key to turn on the oven lamp 3, the microcomputer 1 determines what brightness degree n is, inputs the value n to the register x, and then registers the register ( The value n input to x) is loaded into the register y to calculate a delay time t _{D1 for} turning on the lamp 3 after the interruption.

When the delay time t _D1 for driving the lamp is calculated as described above, the microcomputer 1 determines whether it is an interrupt. When a predetermined time t _D1 elapses after the interrupt, the microcomputer 1 outputs a high-potential driving pulse to the linear driver 2. .

At this time, the linear driver 2 causes the opto triac OT to operate the high potential drive pulse of the microcomputer 1 to drive the triac TA by applying power to the gate of the triac TA. do.

Accordingly, when the triac TA operates, power is applied to the lamp 3, so that the oven lamp 3 is turned on to emit light.

Thereafter, when the power supply level becomes 0, the opto triac OT is initialized and at the same time, the operation of the triac TA is turned off, so that the oven lamp 3 is turned off by turning off the power.

At this time, when the delay time t _D1 elapses, that is, when a predetermined time T / 2 + t _D1 elapses after the interrupt signal is input, the microcomputer 1 outputs a high-potential driving pulse to the linear driver 2. Therefore, the opto triac OT is conducted to operate the triac TA.

Therefore, the oven lamp 3 that is powered by the operation of the triac TA emits light again until the power is zero.

That is, if the microcomputer (1) after when the data interrupt signal registered in one period (T) of the power input to output the two drive pulses within one period (T) of the AC power supply, the interrupt yi t _D1 time It is programmed to output the initial drive pulse and output the second drive pulse after (T / 2) + t _D1 time has elapsed. (Where t _D1 (T / 2), t _D1 = (T / 2) * (n / a), 0 ≦ n ≦ a, and n and a are integers).

Herein, when the driving time of the oven lamp 3 is calculated within one cycle of the power supply, t _D1 to T / 2 and (T / 2) + t _D1 to T, respectively. This is because the opto triac OT is initialized at the point where the power is zero.

In the above operation, when the time for applying power to the oven lamp 3 is divided into 10 steps and programmed, the delay time t _D1 is (T / 2) * (n / 10), where 0 ≦ n ≦ 10, n is an integer).

At this time, as in the conventional circuit, n = 0 may be set to turn on the oven lamp as in full-wave driving, and n = 5 may be set to turn on the oven lamp as in half-wave driving.

For example, when setting n = 5, when the microcomputer 1 outputs the driving pulse to the linear drive unit 2 as shown in FIG. 3 (a), turning on the oven lamp 3 and setting n = 7 As shown in FIG. 3 (b), a driving pulse is output.

As described above, the microcomputer 1 which outputs the driving pulse to the linear driver 2 and turns on the oven lamp 3 for a predetermined time determines whether the lamp-off key is input after one cycle T of the power is completed. .

At this time, when the lamp off key is input, the microcomputer 1 completes the driving operation of the oven lamp 3 to perform another task, and if there is no input of the lamp off key, the microcomputer 1 determines whether the lamp on key is input again.

Accordingly, when there is no input of the lamp on key, the driving operation of the oven lamp 3 is repeatedly performed based on the delay time t _D1 initially set, and when the lamp on key is input, the brightness setting value input by the user again ( The brightness of the oven lamp 3 is adjusted by calculating a) and the brightness step value n to calculate the delay time t _D1 .

The above operation is performed by the signal flow diagram of FIG. 4, in which the microcomputer 1 scans the key to check the lamp on key and, if the key is on, the brightness setting value (a) and the brightness to adjust the degree of brightness. The delay time t _D1 is calculated by calculating the input of the step value n.

For example, if the user sets n = 10 to set the division of brightness degree in '10' step, the microcomputer 1 inputs 10 into the register (x) and then 'Ta / 2n into the register (y). 'Will enter the value.

At this time, the microcomputer 1 determines whether it is an interrupt. If it is an interrupt, when the time t _D1 is delayed by the value of the register y, the microcomputer 1 outputs the first driving pulse to the linear driver 2 to turn on the oven lamp 3. Let's go.

When the power supply becomes 0 and the linear driver 2 is initialized and the time t _D1 is delayed again by the value of the register y, the microcomputer 1 outputs a driving pulse to the linear driver 2 to operate the oven. The lamp 3 is turned on.

In this case, as the value of n increases in the delay time t _D1 = Ta / 2n, the time for applying power to the oven lamp 3 becomes longer, so that the oven lamp 3 becomes brighter.

Accordingly, as described above, the microcomputer 1 which outputs the driving pulse twice during one cycle of the power source scans the key to check whether the lamp-off key is input.

At this time, when the lamp off key is input, the oven lamp 3 is turned off, and if there is no input of the lamp off key, it is again determined whether the lamp on key is input.

Accordingly, when there is no input of the lamp on key, the brightness of the lamp 3 is controlled according to the value of the initially set brightness level, and when there is a key input, the brightness level is adjusted again.

As described in detail above, the present invention can arbitrarily subdivide the brightness level of the oven lamp according to the program, so that the brightness of the oven lamp can be adjusted according to the user's taste, and the power-up time can be adjusted to maximize the power saving effect. It can be effective.

When the present invention is applied to the ventilation motor, the rotational speed of the motor can be adjusted according to the situation, thereby maximizing the power saving effect and the noise control effect.

Claims (8)

The first step of calculating the delay time t _D1 by calculating the brightness setting value a and the brightness step value n when the lamp on key is input, and the interrupt when the delay time t _D1 is calculated in the first step. A second step of determining a signal input, and a step of outputting a driving pulse to turn on the lamp when each time t _D1 (T / 2 + t _D1 ) elapses after the interrupt signal is input in the second step. In step 3, the ramp-off key determines the input when a period T after the interrupt in the third step has elapsed, and if the ramp-off key is not input in the fourth step, repeats the second step. The oven lamp brightness adjusting method of the microwave oven, characterized in that the fifth step of performing the on-operation. The method of claim 1, further comprising calculating the delay time t _D1 by recalculating the brightness setting value a and the brightness step value n when the lamp on key is input when there is no input of the lamp off key. The oven lamp brightness adjustment method of the microwave oven characterized by the above-mentioned. The oven lamp brightness adjustment method of the microwave oven according to claim 1 or 2, wherein the delay time t _D1 is calculated by the following formula. t _D1 = (T / 2) * (n / a) where 0≤n≤a, n and a are integers The oven lamp brightness adjusting method according to claim 1, wherein the lamp is turned off when the power is 0 after the lamp is turned on. When the lamp on key is input, the microcomputer outputs a driving pulse when a predetermined time t _D1 (T / 2 + t _D1 ) elapses after the interrupt signal is input, and the oven lamp is turned on by the driving pulse of the microcomputer. The oven lamp brightness adjustment circuit of the microwave oven comprised by the linear drive means to turn on. The electronic computer of claim 5, wherein the microcomputer is configured to calculate a delay time t _D1 by calculating a brightness setting value a and a brightness step value n when the lamp on key is input by the following formula. Oven lamp brightness adjustment circuit of the range. t _D1 = (T / 2) * (n / a), n and a are integers The linear drive means comprises an opto triac (OT) conducting to a drive pulse of a microcomputer, and a triac (TA) for applying power to the lamp when the opto triac (OT) operates. Microwave oven lamp brightness adjustment circuit. 8. The oven lamp brightness adjustment circuit according to claim 7, wherein the opto triac (OT) is configured to be initialized when the power is zero.