KR900008113Y1 - Rear view mirror - Google Patents

Abstract

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Description

Auto-viewing circuit of automobile

1 is a block diagram according to the present invention.

2 is a concrete circuit diagram of one embodiment of the block diagram of FIG.

* Explanation of symbols for main parts of the drawings

10: first positive voltage output circuit 20: first negative voltage output circuit

30: second positive voltage output circuit 40: second negative voltage output circuit

The present invention relates to a rear-Vioison-Mirror control circuit of a vehicle, and more particularly to a rearview auto-adjustment circuit of a vehicle that can automatically adjust the rearview mirror as a switch operation inside the vehicle.

In general, a car has a rearview mirror to check the following cars to prevent accidents, and the rearview mirror having the above purpose is attached to the outside of the car, so that the car is kicked and parked in a parking lot on the street. When the backsight was twisted by passers-by, it was a defect that I could not fully fulfill my purpose.

On the other hand, the driver was unable to identify the following vehicle or overtaking vehicle when the rearview mirror was twisted, causing an accident, and even if found early, there was an uncomfortable problem of adjusting the rearview mirror after stopping the car.

Accordingly, an object of the present invention is to provide an endoscope control circuit for controlling an endoscope of an automobile in a vehicle.

The present invention for achieving the above object is a first positive voltage output circuit for outputting a positive (+) voltage by inputting a predetermined signal voltage, and a predetermined signal voltage input to the first positive voltage output circuit A first negative voltage output circuit for outputting a negative voltage, a second negative voltage output circuit for inputting and outputting a predetermined signal voltage, and a predetermined signal voltage input to the second positive voltage output circuit, A second negative voltage output circuit for outputting a negative voltage and a motor for inputting voltages respectively output from the first, second and negative voltage output circuits to rotate left and right according to the polarity of the power supply.

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

1 is a block diagram according to the present invention, a first positive voltage output circuit 10 for inputting a predetermined signal voltage to output a positive voltage, and a predetermined signal voltage input to the first positive voltage output circuit. A first negative voltage output circuit 20 for outputting a negative voltage, a second positive voltage output circuit 30 for inputting a predetermined signal voltage, and outputting a positive voltage, and the second positive voltage circuit 30. The second negative voltage output circuit 40 for outputting a negative voltage by inputting a predetermined signal voltage input to the), and the positive voltage and negative output from the first positive, negative voltage output circuit 10 (20) The motor rotates to the left by inputting the voltage, and inputs the positive voltage and the negative voltage output from the second positive voltage output circuits 30 and 40 to the right to rotate the rearview mirror.

Therefore, when a predetermined signal voltage is input to the terminal 100, the first positive voltage output circuit 10 outputs a constant amount of DC voltage to the input point A of the motor 20 and at the same time the first negative voltage. In the output circuit 20, a constant negative voltage is output and input to the input point B of the motor 50.

At this time, the motor 50, which inputs the positive voltage and the negative voltage output from the first positive and negative voltage output circuits 10 and 20, respectively, to the input points A and B, rotates left.

Therefore, the rotation direction of the motor 50 is changed by the signals input to the terminals 100 and 200.

FIG. 2 is a specific circuit diagram of an embodiment of the block diagram of FIG. 1, which shows an upswitch SW1, resistors R ₁ -R ₃ , transistors Q ₁ -Q ₂ , and a photo coupler PC ₁ . A first positive voltage output circuit 10 composed of a second negative voltage output circuit 20 composed of resistors R ₄ -R ₆ , transistors Q ₃ -Q ₄ , and a photocoupler PC ₂ , The second positive voltage output circuit 30 composed of the down switch SW ₂ , the resistors R _7- R ₉ , the transistors Q _5- Q ₆ , and the photocoupler PC ₃ , and the resistors R _10- R _12. ) And a second negative voltage output circuit 40 composed of transistors Q ₇ -Q ₈ and photocoupler PC ₁ , and a motor 50 to rotate the rotating mirror left and right.

Therefore, when a predetermined signal voltage is input to the terminal 100, when the up switch SW ₁ is pressed and turned on, the divided signal is divided by the voltage dividers of the resistors R ₁ and R ₄ . ₁ ) It is input to the base of (Q ₃ ).

At this time, the transistor Q ₁ and Q ₂ inputted with the divided voltage divider are turned “on”, so that the photocoupler PC ₁ connected to the resistors R ₂ and R ₅ of each collector terminal in the forward direction. a photodiode (PD ₁₎ (PD ₂₎ of the (PC ₂₎ to emit light.

Accordingly, the phototransistor PT ₁ of the photocoupler PC ₁ is “on” and outputs a predetermined signal voltage input through the collector resistor R ₃ to the base of the transistor Q ₂ .

In addition, the transistor Q ₂ , which inputs the signal output from the emitter of the phototransistor PT ₁ as a base, is “on” and the power source B ⁻ input to the collector terminal is the emitter of the transistor Q ₂ . It is input to the power input point (A) of the motor 50 through.

On the other hand, when the photodiode PD ₂ of the photo coupler PC ₂ illuminates, the phototransistor PT ₂ is "on" and the potential of the collector is "low".

Therefore, when the phototransistor PT ₂ is "on", it is "turned on" to the transistor Q ₄ , whereby the voltage entry point B of the motor 50 becomes negative potential and the motor 50 is turned left.

On the other hand, when a predetermined signal voltage is input to the end plate 200, the second positive voltage output circuit 30 outputs a constant amount of DC voltage and is input to the input voltage point B of the motor 50.

On the other hand, the second negative voltage output circuit 30 inputs a predetermined signal voltage input to the second positive voltage output circuit 30 to output a constant negative voltage to input voltage point A of the motor 50. Is entered.

At this time, the motor 50 which inputs the positive voltage and the negative voltage output from the second positive and negative voltage output circuits 30 and 40 to the input voltage points B and A, respectively, rotates right.

Therefore, the rearview mirror RVM is also moved to the left by the rotation of the motor 50.

On the other hand, when a predetermined signal voltage is input to the terminal 200, when the down switch SW ₂ is pressed and turned on, the signal voltage is divided by the voltage divider of the resistors R ₇ and R ₁₀ . Q ₅ , Q ₆ ) is input to the base.

At this time, the transistors Q ₅ and Q ₆ inputted with the divided voltage divider as a base are “turned on” so that the phototransistor PC ₃ (PC ₄ ) connected in the forward direction to the resistors R ₆ and R ₁₁ of each collector terminal. Photodiode PD ₃ (PD ₄ ) is emitted.

Therefore, the predetermined signal voltage input through the photoresistor DT ₃ of the photocoupler PC ₃ and input through the collector resistor R ₈ is output to the base of the transistor Q ₆ .

In addition, the transistor Q ₆ inputs the signal output from the emitter of the phototransistor PT ₃ as a base is turned “on” and the power supply B ⁻ input to the collector terminal is connected to the emitter of the transistor Q ₆ . The positive voltage is input to the power input point B of the motor 50.

In addition, when the photodiode PD ₄ of the photocoupler PC ₁ (PC ₄ ) emits light, the phototransistor PT ₄ is "on" and the potential of the collector is "low".

Therefore, when the phototransistor PT ₄ is "on", the transistor Q ₈ is also "turned on", whereby the voltage entry point A of the motor 50 becomes negative potential and the motor 50 is rotated to the left.

Therefore, the rearview mirror RVM is also moved to the right by the rotation of the motor 50.

At this time, the output of the signal for driving the motor 50 is output as a signal output from a Darlington-connected transistor, that is, a signal having a large current amplification.

Therefore, the motor 50 is sufficiently driven, and the speed of the motor 50 can be controlled by adjusting the emitter or collector resistance of each phototransistor PT ₁ -PT ₄ .

As described above, the present invention has an advantage that the rearview mirror adjustment of the vehicle can be adjusted in the vehicle, so that the rearview mirror can be easily adjusted even if the rearview mirror is twisted while driving.

Claims (1)

In the vehicle endoscope control circuit, a first positive voltage output circuit 10 for inputting a predetermined signal voltage and outputting a positive voltage, and a negative signal input for inputting a predetermined signal voltage input to the positive voltage output circuit 10 A first negative voltage output circuit 20 for outputting a voltage, a second positive voltage output circuit 30 for inputting a predetermined signal voltage to output a positive voltage, and a positive voltage output circuit 30 A second negative voltage output circuit 40 for inputting a predetermined signal and outputting a negative voltage; and the first and second positive voltage circuits 10 and 30 and the first and second negative voltage circuits 20 and 40. The endoscope control circuit of the vehicle, characterized in that consisting of a rear endoscope rotating motor 50 is rotated in accordance with the polarity direction of the power input signal output from.