KR900001988Y1 - Aperture controlling apparatus - Google Patents

Abstract

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Description

Camera's Aperture Control

1 is a circuit diagram of the subject innovation.

2 is a timing diagram of the present invention.

3 is a plan view for explaining the operation of the mechanical element in accordance with the present invention.

* Explanation of symbols for main parts of the drawings

1: Receiver 2: Aperture driving control unit

3: aperture driving unit 4: low brightness display unit

11: aperture 12: magnet lever

16: Charge lever 17: Charge lock lever

18: release lever

The present invention relates to an aperture control device of a camera, and in particular, in order to provide direct exposure to a film surface, the light emitted from the projectile is sensed in three stages to automatically control the aperture of the camera and visually determine whether a low luminance flash is used. The present invention relates to an aperture control device of a camera.

In conventional cameras, a variable aperture method for controlling exposure by changing the aperture of the aperture steplessly or multistage with a complicated control device and a fixed aperture method for controlling exposure by shutter speed with an aperture set to a constant aperture are typical. Has been used.

The former has a problem of increasing the production cost of the product because it must be equipped with a complex control device, the latter has a disadvantage that the brightness of the subject that can be taken is limited because the aperture of the aperture is fixed.

As a compromise that improves the problems of the above methods, there is a method of manually controlling apertures each having two or two small cooking holes, and controlling the exposure of these holes.

The purpose of the present invention is to detect the amount of light reflected from the projectile body by a photo-resistance element in order to solve the above problems, divided into three stages to automatically control the movement of the aperture and at the same time low luminance to use the flash The present invention provides a iris control device of a camera that enables automatic exposure by visually displaying this.

Another object of the present invention is to provide an aperture control device for a camera which is easy to manufacture and low in manufacturing cost, while allowing automatic exposure.

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

The present invention provides a first contact of a release button interlocking switch SW having a collector of transistor Q ₁ having a first contact portion 21 and a second contact portion 22 through a resistor R ₃ . The diaphragm drive control unit 2 is configured by connecting the terminal 21 to the terminals b and d, connecting the emitter to the negative terminal of the battery 5, and the terminal of the second contact unit 22 of the interlocking switch SW. The photoresist element CDS connected to the variable resistor R ₂ and the variable drop R ₁ connected to the terminal b and the terminal d, respectively, and the negative terminal of the battery 5 is processed in the base of the transistor Q ₁ . To form the light receiving portion 1, and the collector of the transistor Q ₂ is connected to the terminals b and d of the first contact portion 21 of the interlocking switch SW via the magnet MG. - connected to the terminal and base are transfected via the resistor (R ₁₎ resistance (R ₅₎ of the transistor (Q ₁₎ connected to the collector aperture hayeoseo drive configuration (3), and a transistor (Q ₃₎ of the through The master battery 5 is connected to the collector of the (Q ₁₎ to the emitter of the iris driving section configured to (3), and a transistor (Q ₃₎ via an interlocking switch (SW) and a light emitting diode (LED) - connected to a terminal The base is connected to the collector of the transistor Q ₁ through the resistor R ₅ to form the low brightness display unit 4, where the common terminal C of the first contact unit 21 of the interlock switch SW is a dry cell. It is connected to the + terminal of (5), and it is connected to the common terminal c of the 2nd contact part 22 through terminals b and d, and the terminal a of the 1st, 2nd contact parts 21 and 22 is a non-connection terminal. to be.

In addition, the resistance values of the resistor R ₁ and the resistor R ₂ of the light receiving unit 1 are set to R ₁ <R ₂ .

Reference numeral 11 is aperture, 12 is magnet lever, 13 is aperture side, 14 is protrusion, 15 is leaf spring, 16 is charge lever, 17 is charge lock lever, 18 is release lever (Release Lever), A and B are sputum holes.

Next, the operation of the present invention will be described.

In FIG. 1, the light receiving unit 1 senses the amount of light of the subject's attention according to the switch of the interlock switch SW of the aperture driving control unit 2, and outputs a light conversion signal to the aperture driving control unit 2, and the aperture driving control unit 2. ) Outputs a control signal in three steps together with the switching operation of the interlock switch (SW) to send to the aperture driver (3).

The aperture driving unit 3 operates the magnet NG for an appropriate time in response to the movement operation signal, and selects one of the large and small apertures of the aperture, so that the proper exposure is made on the film surface of the camera.

In addition, the output signal of the iris drive control unit 2 is connected to the low luminance display unit 4 to light up the light emitting diodes (LEDs) in a low level where the external light amount is small to indicate the necessity of flash operation.

2 is a timing diagram showing the waveform of each element in the operation of the present invention in association with, Figure 3 is a plan view showing the mechanical elements of the camera in conjunction with the present invention, the film winding lever (Winding) to take pictures When the lever is lifted, the protrusion 14 on the aperture shaft 13 of the aperture 11 is moved by the leaf spring 15 fixed to the right end while the charge lever 16 shown in FIG. ) Is pushed from the right to the left, so the aperture of the aperture switches from A to B.

Then, it is locked by the charge lock lever 17. In this state, when the release button is pressed in the first step (RL1 in FIG. 2), the interlock switch SW of FIG. 1, which is interlocked with the release lever 18, has its contact portion from terminal a to terminal b so that the operating power of the battery 5 (Vcc) is supplied to the entire circuit.

At this point, the photoresist CDS receives the amount of light from the direction of the body and changes its internal resistance value according to the amount of light.

The operating power supply (Vcc) is turned on the variable resistance (R ₁₎ and the light resistance is divided by elements (CDS) is applied between the base-emitter of the partial pressure voltage signal transistor (Q ₁₎ transistor (Q ₁₎ / Turned off.

In the first luminance (see FIG. 2), which is low luminance enough to use a flash, the resistance of the photoresist element CDS increases, so that the transistor Q ₁ is forward biased, and the low potential signal on the collector side is a transistor. Turn off (Q ₂ ) but turn on transistor (Q ₃ ) to turn on light emitting diode (LED).

Therefore, the user can detect whether the flash is used.

In the second release button RL2, the contact portions 21 and 22 of the interlock switch SW are switched from the terminal b to the terminal d, so that the supply of the operating power Vcc is cut off to the transistor Q ₃ so that the light emitting diode ( LED) goes out and the light-receiving part 1 continuously turns on the transistor Q ₁ by the variable resistor R ₁ connected to the terminal d of the second contact part of the interlocking switch SW, so that the transistor Q ₃ also continues. Will remain off.

In the release button 3 stage RL3, as shown in FIG. 3, the charge lever is released from the charge lock lever, and the leaf spring 15 that pushes the protrusion 14 on the aperture shaft 13 is charged lever 16. Since the diaphragm 11 is moved with the movement from the right side to the left side of the diaphragm 11, the diaphragm 11 is switched to the diaphragm state from the B diameter to the A diameter by the spring, and is opened and closed so that the sufficient amount of light is supplied to the film surface.

When the released shutter release button is released, the release lever 18 is restored by the spring, and the contact parts 21 and 22 of the interlock switch SW are switched to the terminal a state, thereby supplying the operating power Vcc to the circuit. Is blocked.

In the second luminance state (see FIG. 2), which does not use a flash but has a low luminance, the amount of light detected by the photoresist CDS is increased compared to the first luminance state, and thus the transistor Q ₁ is blocked. Since the transistor Q ₂ is forward biased by the high potential signal on the collector side, the collector current flows through the magnet MG to the collector and emitter of the transistor Q ₁ .

Therefore, the magnet MG operates to pull the magnet lever 12 shown in FIG.

The release button 2 step (RL2) in the second contact portion 22 from the terminal b, and switch to the terminals d, so small in the resistance value of the resistor (R ₁₎ than the resistance (R ₂₎ between the base-emitter of the transistor (Q ₁₎ Since the forward bias is made so that the transistor Q ₁ conducts and sends a low potential signal to the collector side, the transistor Q ₂ is cut off and the magnet MG connected to the collector side also stops operating.

Therefore, in the third release button RL3, the aperture is operated in the same manner as the first luminance, and the aperture is controlled to a large A aperture.

When the luminance from the subject is high (see FIG. 2), the resistance of the photoresist element CDS becomes very low, so that the transistor Q ₁ is turned off in the release button 1 and ₂ , whereby the transistor Q ₂ is turned off. The magnet MG is operated continuously by keeping it on.

Although the charge lever 16 is disassembled in the release button 3 step RL3 and the pressure by the leaf spring 15 which maintains the aperture 11 in the B aperture state is removed, the magnet MG in operation is moved to FIG. 3. Since the magnet lever 12 is being pulled out, the aperture keeps the B aperture state and operates the shutter opening and closing device installed by the charge lever 16 moving from the right side to the left side. It becomes exposure.

As such, the present invention automatically controls the aperture according to the amount of external light, so the user does not need to manually adjust the aperture size according to the amount of light, which is convenient to use.

In addition, the low-luminance display indicates whether the flash is used, so that the flash can be used accurately, and has a simple structure, which is easy to manufacture and very low in manufacturing cost.

Claims (1)

In a semi-fixed diaphragm system in which exposure is controlled by operating a diaphragm 11 having large and small diaphragm holes respectively, the light receiving unit 1 including the photoresist element CDS and the light receiving unit 1 According to the control signal of the aperture driving control unit 2 and the virtual machine aperture driving control unit 2 including a release button interlock switch (SW) and a transistor (Q ₁ ) to receive an output and generate a three-step control signal. Combined with the aperture driving unit 3 for driving the magnet (MG) that restrains the aperture 11, the output end of the aperture driving control unit (2) using a light emitting diode (LED) to display the use of flash low Aperture control apparatus for a camera, characterized in that configured in connection with the display (4).