KR910009530B1 - Rewinding circuit for a camera - Google Patents

Abstract

The circuit for rewinding a film automatically when the film reaches its end point by using a simple and low cost circuit operates as follows. A switch of motor wind stop (10) controls the stop and start operation of the motor winding according to the film position. When the operation of motor winding is completed, the switch keeps connecting to B point, and a timer (12) drives the motor to rewind the film in reverse direction.

Description

Film automatic rewind circuit of the camera

1 is a schematic block diagram for explaining the operation of the film automatic rewind circuit;

2 is a circuit diagram of FIG.

The present invention relates to a circuit that loads a film in a camera and automatically rewinds the film after the completion of photographing regardless of the number of films.

In the conventional film automatic rewinding circuit, a circuit composed of a microprocessor or a sensor is complicated, and the life of the sensor is short, so that it is applied only to a specific camera and has been driven by a combination of electronic elements, mechanical elements, and sensors. Therefore, the manufacturing cost in the circuit structure of the said apparatus is expensive, and since this has a complicated circuit structure and the relative volume ratio which a camera occupies is large, it cannot apply to the compact camera. Therefore, the present inventors have invented the film automatic rewinding circuit of the present invention by the necessity of a rewind device capable of overcoming the above problems and suitable for all existing cameras and at low cost and functioning sufficiently with a simple circuit configuration.

According to the present invention, as shown in FIG. 1, the film automatic rewinding circuit includes a timer block 12 consisting of a rewind timer and a wind timer composed of a comparator and an RC time constant circuit, and eight transistors; The motor drive block 13 which is electrically connected to the timer block 12 is formed by forming a winding and rewind motor driving device having a circuit configuration of one diode and four transistors among them. And electrically connected to the motor driving devices 7 and 8 via the timer block 12, and mechanically recognizes the film transfer time and the film transfer completion time to start the winding operation stop or the rewind operation of the motor. Is electrically connected to the motor wind stop switching switch 10 and the timer block to control the rewinding operation. The rewind stop switch 11 is configured to press a camera shutter bolt switch so that a signal of a power supply voltage is simultaneously input to each of the wind timer and the rewind timer constituting the timer block. The input signal is output to each output terminal (5) and (6) via each timer circuit. At this time, the output terminal (6) of the timer circuit outputs a low level and output terminal (5) of the timer circuit. Outputs a high level. However, since the time constant of the rewind RC time constant circuit is longer than that for the wind, when the output voltage level of the wind becomes low, the output voltage level of the rewind becomes low delayed by the time time constant.

Due to the time difference, the output voltage of the wind is connected to the output terminal 6 of the timer for the wind, and is connected to the output terminal 6 of the timer circuit in the timer block 12 and is composed of four transistors and resistors. The micro motor connected to the wind motor drive 8 in the drive block 13 is driven. Thus the motor rotates clockwise. In the case of the motor winding, the motor wind stop switch 10, which switches the terminal connected to the motor drive block, is originally located at the contact point on the B side, and then a frame of mechanical film (that is, one cut) passes. Each time the switch is switched to the stop position on the A side, the rotation of the motor is stopped when the switch is switched from B to A. When the motor winding operation is completed, that is, when the picture is taken, the wind stop switching switch is not switched to the A side but remains in contact with the B side, and at this time, the power supply power Vcc is supplied through this B terminal. Therefore, the rewind timer and the rewind motor driving device are driven from this point, which in turn drives the micromotor to rotate the motor counterclockwise. Since the rewind stop switch is in an open state when the film is loaded, and a short state when the film is not loaded, the rewind stop switch is in a ground state, thereby forming a short circuit. Therefore, at this point, the rewind stop signal is input to the rewind timer circuit to stop the film transfer.

Therefore, as described above, the circuit of the present invention is easy to configure the film rewinding circuit, and operates only by the circuit configuration of the electronic element, without the complicated circuit configuration by the combination of electronic elements, mechanical elements, sensors, and the like. In addition, it is inexpensive and fully functional without the need for expensive components such as a microprocessor or a sensor, and can be applied to all existing compact cameras.

Accordingly, it is an object of the present invention to provide a rewind circuit with a simple, easy and inexpensive circuit configuration.

It is also an object of the present invention to provide a rewanide circuit in which the circuit configuration consists only of electronic elements.

Then, the operation principle of the present invention will be described in detail with reference to FIG.

)이다. 상기 구형파는 상기 트랜지스터 Q₁의 베이스에 입력되어 이를 구동시키므로, 따라서 트랜지스터 Q₁의 콜렉터에 출력되는 파형은 하이 레벨(

)이며, 이것은 다시, 콜렉터가 마이크로 모터 M의 한 단자에 접속되어 있는 트랜지스터 Q₂의 베이스로 상기와 동일 레벨로 입력되어서 그의 콜렉터에서는 로우 레벨(

)파형이 출력된다. 그리하여 이 로우 레벨은 마이크로 모터 M의 한 단자에 공급된다.Pressing the shutter button on the camera (not shown) supplies the power supply voltage Vcc to the winding terminal W and the rewind terminal RW, and inputs them to the RC time constant circuits connected to the input terminals of the comparators COM ₁ and COM ₂ , respectively. do. The input voltage Vcc input here is delayed by the time constant circuits RC, respectively, because the time constant of the first time constant circuit R ₁ C ₁ is shorter than that of the second time constant circuits R ₂ , C ₂ . The voltage through the first time constant circuit R ₁ C ₁ is output before the voltage through the second time constant circuit R ₂ C ₂ via the rewind terminal RW. This output voltage is input to the base of transistor Q ₁ and to the input terminal of the first comparator COOM ₁ , which has an output terminal commonly connected to one terminal of diode D provided to prevent rewinding operation. Therefore, the input voltage is generated as a square wave by the first comparator COM ₁ and the voltage level of the square wave is low (

)to be. Since the square wave is input to the base of the transistor Q ₁ and drives it, the waveform output to the collector of the transistor Q ₁ is therefore at a high level (

Again, the collector is input at the same level as above to the base of the transistor Q ₂ connected to one terminal of the micromotor M, and the collector has a low level (

The waveform is output. This low level is thus supplied to one terminal of the micromotor M.

)로 출력한다. 따라서 상기 트랜지스터 Q₃의 콜렉터에는 하이 레벨(

)파형이 나타나게 된다. 이 하이 레벨(

)파형은 마이크로 모터 M의 다른 단자에 공급된다. 따라서 트랜지스터 Q₂측의 모터 M의 한 단자에는 로우 레벨(

)파형이, 그리고 트랜지스터 Q₃측의 모터 M의 다른 단자에는 하이 레벨(

)파형이 각각 입력되므로 마이크로 모터 M은 시계방향으로 회전하여 모터 와인딩 동작을 시작하게 된다.On the other hand, the first comparator base of COM ₁ the transistor Q ₄ is connected to the output terminal of there is a first comparator at the same level of the waveform and the output waveform of the COM ₁ type emitter common power supply voltage from the same viewpoint as described above Vcc , the collector-emitter output waveform at a low level of the motor M in which the transistor Q is connected to the other terminal of the transistor Q ₃ is connected directly to the base ₄ (

) Therefore, the collector of the transistor Q ₃ has a high level (

The waveform will appear. This high level (

The waveform is fed to the other terminal of the micromotor M. Therefore, one terminal of the motor M of the transistor Q ₂ has a low level side (

) Waveform, and the other terminal of the motor M of the transistor Q ₃ has a high level side (

As the waveforms are input, the micro motor M rotates clockwise to start the motor winding operation.

In this motor winding operation, the motor wind stop switching switch 10 is originally located on the B side terminal which is commonly connected to the emitter of transistor Q ₁ and the output terminal of the second comparator COM ₂ , and then mechanically passes one frame of film. Each time the film is taken, that is, each time a film is taken, the motor is switched to the A side terminal connected to one terminal of the motor M, and the rotation of the motor M is stopped when switching the switch from B to A. This is because a power supply voltage Vcc is supplied to one terminal of the motor M via the motor wind stop switching switch 10, and a high level voltage is applied to both terminals of the motor M. When the motor winding operation is completed for the specified number of films, that is, when the film is no longer transferred after the film is finished, the motor wind stop switching switch 10 cannot be switched to the A side terminal and remains in contact with the B side terminal contact. At this time, the common power supply voltage Vcc such as the emitter of the transistor Q _{6 and} the emitter of the transistor Q ₃ is supplied with the motor wind stop switching switch 10 to the output terminal of the second comparator COM ₂ to start the rewind operation.

In this rewind operation, the supply voltage Vcc is accumulated in a rewind time sustain capacitor (hereinafter referred to simply as a "rewind capacitor") C ₃ and is input to the base of the transistor Q ₅ connected to one terminal thereof, and then the transistor. Drive Q ₅ . Since the voltage supplied to the base of the transistor Q ₅ is a power supply voltage Vcc, i.e., a high level, the output at its collector is also output at a high level, which means that the base is connected to the collector of the transistor Q ₅ , and the emitter is the common. Since the collector is input at the same level as the voltage level of the collector of the transistor Q _5, the collector outputs a high level voltage. Thus, the output voltage is supplied to one terminal of the micromotor M through a conductor connected to its collector.

)전압을 출력한다. 그리고 콜렉터가 트랜지스터 Q₃의 콜렉터와 모터 M의 다른 단자에 공통 접속되어 있고 에미터가 접지되어 있으며 베이스가 상기 트랜지스터 Q₇의 에미터에 직접 연결되어 있는 트랜지스터 Q₈, 그의 상기 베이스에 상기 트랜지스터 Q₇의 에미터와 동일 레벨, 즉 하이 레벨 전압으로 구동시키면 상기 트랜지스터 Q₈의 콜렉터에는 로우 레벨이 출력되어 모터 M의 다른 단자에 공급된다. 따라서, 모터 M의 한 단자에는 트랜지스터 Q₂의 콜렉터 전위, 즉 로우 레벨이, 모터 M의 다른 단자에는 트랜지스터 Q₈의 콜렉터 전위, 즉 하이 레벨이 공급되어 상기 와인딩 모터 동작과는 반대 상태로 되므로, 모터 M은 전술한 바와 같은 방향과 반대 방향, 즉 반시계방향으로 회전하여 리와인딩 동작을 시작하게 된다.On the other hand, at the same time as described above, the base of the transistor Q ₇ connected to one terminal of the rewind capacitor connected between the ground and the output terminal of the second comparator COM ₂ and the other terminal of the diode D is connected. A common power supply voltage Vcc is supplied to drive the transistor Q ₇ . So in his actors,

Output voltage. And the collectors commonly connected to the other terminal of the transistor Q ₃ the collector and the motor M, and the emitter thereof is grounded, and the transistor is the base is connected directly to the emitter of the transistor Q ₇ Q _8, wherein the transistor on its said base Q When driven at the same level as the emitter of ₇ , i.e., a high level voltage, a low level is output to the collector of the transistor Q ₈ and supplied to the other terminal of the motor M. Therefore, the collector potential of the transistor Q ₂ , that is, the low level is supplied to one terminal of the motor M, and the collector potential of the transistor Q ₈ , that is, the high level is supplied to the other terminal of the motor M, so that the state of the winding motor is reversed. The motor M rotates in a direction opposite to that described above, that is, counterclockwise to start the rewinding operation.

In this rewinding operation, the motor wind stop switching switch is mechanically switched from A to B and B to A, but the discharge voltage and power supply voltage of the rewind capacitor C ₃ are used as the base input voltage of transistor Q ₅ . Since Vcc is supplied alternately to each other, the rewinding operation can be maintained continuously. Accordingly, the rewind capacitor C ₃ supplies a voltage to the base of the transistor Q ₅ while the power supply voltage Vcc is not supplied in the rewinding operation.

On the other hand, when the rewinding operation is completed, that is, the film is automatically rewound, the rewind stop switch with one terminal connected to ground and the other terminal connected in common with the resistor R ₂ and the input terminal of the second comparator COM ₂ (11) opens the switch if the original film is mounted, and shorts the switch if the film is not mounted. Therefore, the rewind stop switch 11 is shorted and connected to the input terminal of the second comparator COM ₂ so that its input Since the output terminal of the second comparator COM ₂ is grounded, the rewinding operation is stopped at this point.

Therefore, as described above, the film automatic rewinding circuit according to the present invention can exhibit a low cost and sufficient function by simply constructing a circuit with an electronic element without a complicated circuit configuration by a combination of an electronic element, a mechanical element, and a sensor. It is obvious that it can be applied to all existing compact cameras.

Claims (2)

The circuit consists of a timer means consisting of a winding timer having a first time constant circuit and a first comparator circuit, a rewinding timer having a second time constant circuit and a second comparator circuit, and eight transistors and a diode. Wherein the diode is provided to prevent the rewind operation during the winding operation and forms the motor driving means for the winding and the rewind in units of four of the transistors, the motor driving means being electrically connected to the timer means; And a motor wind switching switch means electrically connected to the motor driving means via the timer block and mechanically recognizing the film transfer time and the film transfer completion time to start the winding stop or the rewind operation of the motor. Electrical rewinding It is composed of the rewind stop switch means for controlling the operation, so it is short enough to start the winding operation first, and the power supply voltage is connected between the output terminal of the second comparator and the ground by the mechanical switching operation of the motor wind switching switch means. A film automatic rewinding circuit which is input to an existing rewind capacitor and starts the rewind operation at its discharge voltage. The method of claim 1, wherein the motor driving device for the wind in the motor driving means is composed of transistors Q ₁ , Q ₂ , Q ₃ , Q and Q ₁ , Q ₃ , Q ₄ of the transistors are pnp type, Q ₂ motor driving apparatus is the npn type cross-section, rewind the transistors Q _5, Q _6, Q _7, was done by Q ₈ of the transistor Q _5, Q _7, Q ₈ is a npn type and the type is Q ₆ pnp film automatically Rewind circuit.

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