JPH0534766A - Shutter device for camera - Google Patents

Abstract

PURPOSE:To develop a shutter device for a camera constituted by adding an electronic shutter device which can steplessly control a shutter time, to a mechanical shutter device which can set the stepwise shutter time. CONSTITUTION:In this mechanical shutter device which is provided with a time controlling lever 20, which advances by advancing quantity corresponding to the set value of the shutter time, in the cam turning area of a rotary cam body 10 which controls the opening and the closing of a shutter and which controls the shutter according to the braking of the cam body 10 added by the lever 20, an auxiliary trigger mechanism 42 which delays the start of the cam body 10 in a prescribed time in comparison with the start time of the cam body 10 which is rotated as the mechanical shutter is provided. Then, an electronic time controlling lever 30 controlled by an electronic shutter control circuit is advanced into the cam turning area of the cam body 10 under a state that the lever 20 is retreated from the cam turning area and the rotating time of the cam body 10 started by the action of the auxiliary trigger mechanism 42 is adjusted.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shutter device used in a camera for photographing.

[0002]

2. Description of the Related Art As a shutter device for a camera for taking photographs, a mechanical shutter device (hereinafter referred to as a mechanical shutter device) which mechanically determines a shutter time by operation settings.
Then, there is an electronic shutter device whose shutter time is determined by electrical calculation. In addition, among recent electronic shutter devices, there is a device additionally provided with a mechanical shutter device that allows the shutter to be operated immediately when the shutter does not operate due to exhaustion of a power battery. However, the shutter device additionally configured as described above can only set the shutter time in two stages.

There are various types of mechanical shutter devices, and the principle configuration of an example thereof is shown in FIG. In this figure, reference numeral 10 is a rotary cam body that rotates around a support shaft 11, and has a two-tiered structure in which a cam body 12 that interlocks the shutter and a cam body 13 that determines the shutter time are integrated. This rotating cam body 10 is a shutter
The locking portion 10a is locked by the trigger lever 15 in a state in which it is rotated counterclockwise by the jogging operation and the spring force of the charge spring 14 is stored, and the state shown in the figure is maintained.

One end of the concave portion 12a formed around the cam body 12 serves as a cam portion 12b for driving the shutter curtain. That is, within the turning range of the cam portion 12b,
The starter shutter 16 of the shutter front curtain and the starter lever 17 of the shutter rear curtain are advanced. The front and rear curtains of the shutter are locked at the position where they are rolled up by the shutter charge operation.
7 is interlockingly driven by the cam portion 12b, and is pivoted about the support shafts 18 and 19 so that the lock is released and the curtain travels.

Further, one end of the concave portion 13a formed around the cam body 13 serves as a timing cam portion 13b for determining the shutter time. That is, this cam portion 13b
The protruding portion 20a of the timing lever 20 advances into the turning range of the. As a result, the cam portion 13b turns so as to push out the protruding portion 20a, so that the rotary cam body 10 is braked, and the start point of the shutter rear curtain is determined by the degree of this braking.

The timing lever 20 is pivotally supported by a support shaft 21 and receives a clockwise turning force by a spring, so that the protruding portion 20a is always advanced into the turning region of the cam portion 13b. Further, a time setting lever 22 having a dogleg shape is connected to the timing lever 20 for determining the advancing distance (extending amount) of the protrusion 20a. The time setting lever 22 is pivotally supported by a support shaft 23 and is constantly subjected to a counterclockwise turning force by a spring. Then, the protruding pin 2 of the timing lever 20 is provided in the long hole 22a of the one arm.
0b has entered, and the protruding pin 22b of the other arm is in contact with the shutter time setting cam 24.

When the shutter time setting cam 24 is operated, it rotates about the support shaft 25 as a support shaft, and the time setting lever 22 is rotated to the left or right according to the shape of the cam. That is, as shown in FIG. 13, the turning amount of the time setting lever 22 according to the rotation of the shutter time setting cam 24 is transmitted to the timing lever 20 and the amount of advance of the protrusion 20a is determined.

In the mechanical shutter device described above, the trigger lever 15 is rotated clockwise in association with the mirror jumping lever driven by the pressing operation of the shutter button to release the lock. The rotation cam body 10 rotates clockwise by releasing the lock, and the cam portion 12b causes the starter lever 16 to rotate.
To move the shutter front curtain.

By the subsequent rotation of the rotary cam body 10, the cam portion 13b abuts the protruding portion 20a of the timing lever 20 as can be seen from FIG. Therefore, the rotation of the rotating cam body 10 causes the cam portion 13b to push out the protruding portion 20a, so that the rotating cam body 10 continues to rotate while receiving the braking force according to the amount of advance of the protruding portion 20a.

After the protruding portion 20a is pushed out from the cam portion 13b, the rotary cam body 10 is further rotated, and the start portion 17 is pushed by the cam portion 12b to move the shutter rear curtain.

As described above, in this mechanical shutter device, the protrusion amount of the protrusion 20a provided on the timing lever 20, that is,
The time from the running of the shutter front curtain to the running of the shutter rear curtain is determined according to the amount of advance of the protrusion 20a that is determined by the operation setting of the shutter time setting cam 24. As shown in FIG. 12, when the shutter time setting cam 24 is set to operate so that the protruding portion 20a of the timing lever 20 is moved out of the turning range of the cam portion 13b, the rotary cam body 10 is completely restrained. Since it receives no power, it has the fastest shutter time. Further, the timing lever 20 is switched to the delay cover in conjunction with the shutter time setting cam 24 so as to respond to the time setting over a wide range even to a slow shutter time.

[0012]

The above-mentioned mechanical shutter device has a conventional shutter time step (for example, B, 1,
2, 4, 8 ... 1/1000, 1/2000, 1
/ 4000 shutter speeds), the present invention provides an electronic shutter control circuit for controlling the shutter time steplessly by adding a simple structure to the mechanical shutter device to provide a mechanical shutter function and an electronic shutter. It is an object of the present invention to develop a shutter device for a camera capable of selecting a function and shooting according to a shooting situation and shooting.

[0013]

In order to achieve the above-mentioned object, in the present invention, the trigger lever which operates in accordance with the shutter release is unlocked to rotate by the spring force, and when the first rotation angle is reached. To open the shutter and close the shutter at the second rotation angle, and to advance the cam rotation area of this rotation cam body by the spring force, and after the shutter is opened, the cam is pushed by the cam to move from the cam rotation area. The timing lever to be withdrawn and a mechanical shutter time setting mechanism for holding the timing lever at the exit position and determining the amount of advance from this withdrawal position In a camera shutter device having a structure in which the shutter time is controlled according to the rotation time of the rotating cam body that changes according to the amount, in accordance with the operation of the shutter time setting mechanism for retracting and holding the timing lever outside the cam rotation range. Electronic Yatta operating mode - moves to de, Shattareri - an electronic shutter control circuit for determining the shutter time according to's, Shattareri - the trigger accordance's - lever - unlocking after a predetermined time static between the rotating cam body -
Control by the auxiliary trigger mechanism for stopping the shutter and the electronic shutter control circuit to advance the cam rotation range of the rotary cam body to delay the rotation of the rotary cam body after the shutter is opened and end the shutter time. There is proposed a shutter device for a camera, which is provided with an electronic timing lever which allows rotation of a rotating cam body so that the shutter is closed by sometimes retreating out of the cam rotation range.

[0014]

The above shutter device operates in the electronic shutter mode by operating the shutter time setting mechanism so that the timing lever is moved out of the cam rotation range of the rotary cam body. When the shutter is released in this operation mode, the electronic shutter control circuit calculates the shutter time and advances the electronic timing lever into the cam rotation range of the rotary cam body, and then locks the trigger lever. Upon release, the electronic shutter control circuit starts counting shutter time. The shutter release activates the auxiliary trigger mechanism to stop the start of the rotary cam body for a predetermined time, and then start the rotation of the rotary cam body.

The shutter is opened by the rotation of the rotary cam body. Thereafter, the cam of the rotary cam body hits the electronically controlled lever and the rotation of the rotary cam body is delayed. When the shutter time has been counted, the electronic shutter control circuit controls the electronic timing lever so that it is moved out of the cam turning range. This allows
The rotating cam body rotates without being braked by the lever during electronic adjustment to close the shutter.

In the above shutter device, if the shutter time setting mechanism is operated so that the timing lever is advanced into the cam rotation range of the rotary cam body, the operation mode of the electronic shutter is changed.
Mode is automatically switched to the mechanical shutter operation mode,
Shutter control can be performed as in the conventional example.

[0017]

Embodiments of the present invention will now be described with reference to the drawings. FIG. 1 is a principle configurational diagram for explaining a first embodiment of a shutter device according to the present invention. The same members and parts as those in the conventional example are designated by the same reference numerals, and the description thereof will be omitted.

As shown in the figure, the cam body 13 of the rotary cam body 10 has a concave portion 13c formed symmetrically with the concave portion 13a.
Is provided, and one end of the concave portion 13c serves as a cam portion 13d. In addition, the protruding portion 30a of the electronic timepiece lever 30 is configured to advance and retract in the turning region of the cam portion 13d. The electronic time adjustment lever 30 is axially supported by a support shaft 31 and is constantly provided with a counterclockwise turning force by a spring, and as shown in the drawing, is brought into contact with a substantially semicircular speed control cam 32.

The speed control cam 32 rotates coaxially with the interlocking gear 33, and rotates about a shaft 35 within a range where it contacts the stopper 34 from the position shown in the figure. The interlocking gear 33 meshes with the pinion gear 37 of the stepping motor 36.

The stepping motor 36 controls power supply by an electronic shutter control circuit (not shown). The electronic shutter control circuit includes a known shutter time calculation circuit that calculates the shutter time based on the brightness information of the subject, the diaphragm information, the film sensitivity information and other exposure factors. The arithmetic circuit includes a microcomputer having a CPU and a RAM. Then, the electronic shutter control circuit operates in conjunction with the shutter time setting cam 24.
In response to the ON signal of the mode changeover switch 38, the operation mode is set. That is, the mode changeover switch 38 is turned on by operating the shutter time setting cam 24 so that the protruding portion 20a of the timing lever 20 is moved out of the turning range of the cam portion 13b. In other words, by setting the mechanical shutter device to the maximum shutter speed, the mode changeover switch 38 is turned on and the electronic shutter control circuit operates.

The above-mentioned electronic shutter control circuit inputs a shutter release signal (ON signal of a switch interlocked with depression of a shutter button) to calculate a shutter time, and
The shutter time is counted in response to the ON signal of the trigger switch 39 interlocking with the trigger lever 15. That is, counting the shutter time is started by turning on the trigger switch 39 in conjunction with the release of the lock of the trigger lever 15.

Further, the electronic shutter control circuit described above includes a drive circuit 41 for controlling power supply to the stepping motor 36, as shown in FIG. When the shutter time calculation circuit 40 shifts to the shutter time calculation operation, the drive circuit 41 causes the stepping motor 36 to rotate clockwise according to a command from the calculation circuit 40. At this time, the speed control cam 3 that receives the driving force via the interlocking gear 33
2 swivels from the position indicated by the chain double-dashed line in FIG. 1 to the position indicated by the solid line, and pushes the electronic timing lever 30 around to project the protruding portion 30.
a is advanced to the turning range of the cam portion 13d.

When the shutter time has been counted, the drive circuit 41 receives the command from the shutter calculation circuit 40 and causes the stepping motor 36 to rotate counterclockwise, contrary to the above. At this time, the speed control cam 32 turns from the solid line position in FIG.
The electronic timed lever 30 is rotated counterclockwise so that a goes out of the turning range of the cam portion 13d. (See the chain double-dashed line in Figure 1)

On the other hand, in the cam body 12 of the rotary cam body 10,
Forming another locking part 10b similar to the locking part 10a,
The auxiliary trigger lever 42 can be locked to the locking portion 10b. This auxiliary trigger lever 42 has a support shaft 43.
The armature 44, which is supported by an electromagnet 45, is attached to one end of the armature 44.

The above-mentioned auxiliary trigger lever 42 and electromagnet 45 constitute an auxiliary trigger mechanism. After the trigger lever 15 is unlocked, the rotary cam body 1 is briefly held.
Operates to lock 0 rotation. That is, when the electronic shutter control circuit inputs the trigger signal and shifts to the calculation of the shutter time, the electromagnet 45 is supplied with power by the electronic shutter control circuit and enters the locked state shown in FIG. Further, after the trigger lever 15 is unlocked, the power supply is controlled to stop in a short time.

That is, in the operation mode of the electronic shutter, the rotation cam body 1 is released by releasing the lock of the auxiliary trigger lever 42.
0 starts and controls the shutter front and rear curtains. By delaying the start of the rotary cam body 10 in this way, the shutter time calculation time and the timing of the retracting operation of the electronic timing lever 30 and the speed control cam 32 can be set sufficiently, so that no malfunction occurs. It is also advantageous for obtaining a high-speed shutter.

Next, the flowchart shown in FIG. 3 and FIG.
The operation of the shutter device will be described with reference to the time chart shown in FIG. Since the operation in the mechanical shutter mode is similar to that of the conventional example, the operation of the electronic shutter mode in which the shutter time setting cam 24 is operated at the position of the maximum shutter time as shown in FIG. 1 will be described.

When the shutter is released from the camera, the shutter time calculation circuit 40 judges the ON state of the mode changeover switch 38 at the half-pressed stage (half-press of the shutter button), and the calculation of the shutter time is started. In addition, this arithmetic circuit 40
Detects that the mode changeover switch 38 is ON, and controls the drive circuit 41 so that the stepping motor 36 is stepped to the right. Therefore, the speed control cam 32 turns counterclockwise to the start position shown by the solid line in FIG. 1, and advances into the turning range of the protrusion 13d of the electronic timepiece lever 30.
When the above-mentioned electronic shutter control circuit inputs a shutter release signal, the electromagnet 45 is supplied with power. Therefore,
The armature 44 is attracted by the electromagnet 45, and the auxiliary trigger lever 42 locks the locking portion 10b of the rotary cam body 10. (See time point T _{1 in} Fig. 4)

At the stage where the shutter release is fully pressed, the trigger lever 15 is interlocked with the mirror flipping up and withdraws from the engaging portion 10a of the rotary cam body 10, and the trigger switch 39 is turned on. From the time point, the shutter time calculation circuit 40 starts counting the shutter time. (Fig. 4
(Refer to T ₂ point of)

The shutter control circuit is a shutter release circuit.
Power is supplied to the electromagnet 45 for a time period ΔT from the time point T ₁ when the shift signal is input to the time point T ₃ shown in FIG. Therefore, the start of the rotary cam body 10 is delayed by ΔT. After the time point T _3, the attraction force of the electromagnet 45 is released and the auxiliary trigger lever 42 is in the unlocked state. As a result, the rotary cam body 10 is rotated clockwise by the spring force of the shutter charge spring, and the cam portion 12b is rotated by the starter lever 16.
To move the shutter front curtain. (See time point T _{4 in} FIG. 4) In this case, the auxiliary trigger lever 42 is engaged by the locking portion 1.
It is pushed around by 0b. When the rotary cam body 10 further rotates, the cam portion 13d hits the protruding portion 30a of the electronically controlled lever 30, and the rotation of the rotary cam body 10 stops, as shown in FIG. It will be time adjustment.

On the other hand, when the count value of the shutter time reaches the calculated value of the shutter time, the drive circuit 41 receives a command from the calculation circuit 40 again and the stepping mode is received.
Step 36. In this case, stepping motor 3
6 steps counterclockwise, and the speed-control cam 32 is turned clockwise as indicated by the chain double-dashed line in FIG. From this, electronic timing lever
As shown by the chain double-dashed line in FIG. 1, 30 turns counterclockwise, and its protruding portion 30a retreats out of the turning range of the cam portion 13d.

With the above operation, the rotary cam body 10 starts rotating clockwise from the rotational position shown in FIG. 5, and when the cam portion 12b pushes the starter lever 17, the shutter rear curtain runs. (See time T ₆ in FIG. 4) Incidentally, in FIG.
Tx represents the time taken into account the calculation of the shutter time and the operation delay of the electronic timing lever 30, etc., and the operating time of the electronic timing lever 30 for timing operation can be absorbed by ΔT. T
s indicates the actual shutter time.

In the shutter device of the first embodiment described above,
At the end of counting the shutter time, the electronic timing lever 30 is swung counterclockwise at a high speed to cope with the high-speed shutter time. Therefore, it is necessary to speed up the counterclockwise step of the stepping motor 36. Therefore, as shown in FIG. 6 as the second embodiment, this problem can be solved by determining the start position of the electronic timing lever 30 according to the calculated value of the shutter time.

In the second embodiment, the speed control cam 3 is used when the low shutter speed is reached according to the calculated shutter time.
2 to A start position, and B for medium speed shutter time
When the shutter speed is high, it is turned to the start position of C. By doing so, the cam portion 13
As shown by the chain double-dashed line, the amount of protrusion of the protruding portion 30a with respect to the turning range of d decreases as the high-speed shutter time increases. A wide range of shutter speeds can be created by combining this advance amount and the motor rotation speed.

FIG. 7 is a principle block diagram of the shutter device showing the third embodiment. In this embodiment, the speed control cam 32 is driven by the moving coil device 46 shown in FIG. Others have substantially the same configuration as the first embodiment. The moving coil device 46 includes the lower yoke plate 4
Two arc-shaped magnets 48 and 49 are fixed to the magnet 7 so as to show the polarities shown in FIG.
Two moving coils 52, 53 fixed to a rotary shaft 51 are rotatably provided between the upper yoke plate 50 and the upper yoke plate 50.

The speed control cam 32 is attached to the rotary shaft 51 and is rotated on the outer surface of the upper yoke plate 50. Then, a clockwise turning force is applied to the speed adjusting cam 32 by a spring, and in the normal state, the turning position is in contact with the stopper-54 as shown in FIG.

The moving coils 52 and 53 of the moving coil device 46 are powered by the drive circuit 41 shown in FIG. 9 and rotate counterclockwise. That is, when the shutter time calculation circuit 40 inputs the shutter release signal as in the first embodiment, the moving coil device 4 is operated.
The drive circuit 41 is controlled so as to supply 6 to the power supply. By this power feeding, the moving coil device 46 causes the speed control cam 32 to move.
Is rotated counterclockwise until it contacts the stopper 55.

The electronically controlled lever 30 is pushed by the speed-adjusting cam 32 that turns left as described above, and the protrusion 30a thereof advances into the turning range of the cam 13d. In this state, the rotation of the rotary cam body that has run the shutter front curtain is stopped. Further, since the drive circuit 41 is controlled so as to stop the power supply to the moving coil device 46 when the shutter time calculation circuit 40 finishes counting the shutter time, the speed control cam 32 is rotated clockwise by the spring force. Contact the stopper 54.
As a result, the protruding portion 30a of the timing lever 30 becomes the cam portion 13.
It retreats out of the turning range of d and releases the rotation stop of the rotating cam body 10. As a result, the rotary cam body 10 rotates again to drive the shutter rear curtain.

The other operations of the third embodiment are similar to those of the first embodiment, and are the operations shown in the flow chart shown in FIG. At the end of counting the shutter time, a reversing current is passed through the moving coil device 46 to cause the speed adjusting cam 3 to move.
2 may be configured to swivel rapidly to the normal position (contact position of the stopper 54).

FIG. 11 is a principle block diagram showing a fourth embodiment.
In this embodiment, an electromagnetic actuator 56 and a swing lever 5 are used.
The electronic timing lever 30 by the electromagnetic drive mechanism consisting of 7 and
It is configured to interlock. In this embodiment, the support shaft 58
The turning lever 57, which turns about the center, receives a spring force and turns as shown by a two-dot chain line in the drawing to be in a normal state. When the shutter time calculation circuit detects that the mode changeover switch 38 is turned on, the electromagnetic actuator 56 is supplied with power by the drive circuit, and the swing lever 57 is circulated to the solid line position in the figure.

Therefore, the electronic timing lever 30 interlocked by the turning lever 57 turns clockwise, and the protruding portion 30a thereof advances into the turning area of the cam portion 13d. At the end of counting the shutter time, the driver circuit cuts off the power supply to the electromagnetic actuator 56. As a result,
The turning lever 57 returns to the normal position indicated by the chain double-dashed line in the figure by the spring force, and the projection 30a is withdrawn from the turning range of the cam portion 13d by the counterclockwise turning of the electronic timed lever 30. Other configurations and operations are similar to those of the first embodiment.

In the above-described embodiment, when the mechanical shutter device is set to the maximum shutter time, the mode changeover switch 38 is turned on to enter the operation mode of the electronic shutter, but the time setting lever 22 is used. By providing the operation member for turning clockwise, it is possible to switch to the operation mode of the electronic shutter while the mechanical shutter device is set to an arbitrary shutter time. In this case, the mode changeover switch 38 is turned on in response to the time setting lever 22 or its operating member. Further, since ΔT becomes longer by setting the power feeding time of the electromagnet 45 to, for example, about 10 seconds, it can be used as a self-timer.

[0043]

As described above, according to the present invention, there is provided a shutter device having a mechanical shutter function capable of setting a shutter time in multiple stages and an electronic shutter function capable of steplessly controlling the shutter time. Therefore, it is possible to provide a camera capable of taking a picture by selecting a mechanical shutter or an electronic shutter according to the shooting situation, and even when the electronic shutter cannot be operated due to exhaustion of the power battery, the shutter time can be set in multiple stages. The shutter device for a camera is practically convenient in that it can take an image at an arbitrary shutter time by using a mechanical shutter. Further, in the present invention, in addition to the trigger lever for starting the rotary cam body in the operation mode of the mechanical shutter, an auxiliary trigger for delaying the start of the rotary cam body in the operation mode of the electronic shutter for a predetermined time. Since the shutter is provided with the mechanism, the shutter can be configured in consideration of the operating characteristics and the operating time of the electronic timing lever and its drive mechanism, which increases the degree of freedom in design and provides a highly accurate shutter device.

[Brief description of drawings]

FIG. 1 is a principle configuration diagram of a shutter device showing a first embodiment of the present invention.

FIG. 2 is a block diagram for explaining an electronic shutter control circuit of the shutter device according to the first embodiment.

FIG. 3 is a flowchart showing the operation of the shutter device according to the first embodiment.

FIG. 4 is a time chart for explaining the operation of the shutter device according to the first embodiment.

FIG. 5 is a simplified diagram showing an operation process of the shutter device according to the first embodiment.

FIG. 6 is a principle configuration diagram of a shutter device according to a second embodiment.

FIG. 7 is a principle configuration diagram of a shutter device according to a third embodiment.

FIG. 8 is an exploded perspective view showing a moving coil device included in a shutter device according to a third embodiment.

FIG. 9 is a block diagram illustrating an electronic shutter control circuit of a shutter device according to a third example.

FIG. 10 is a flowchart showing the operation of the shutter device according to the third embodiment.

FIG. 11 is a principle configuration diagram of a shutter device according to a fourth embodiment.

FIG. 12 is a schematic configuration diagram of a mechanical shutter device shown as a conventional example.

13 is an operation process diagram of the mechanical shutter device shown in FIG.

[Explanation of symbols]

 10 Rotating cam body 10a, 10b Locking part 12 Cam body 12b Cam part 13 Cam body 13b, 13d Cam part 15 Trigger lever 16 Start shutter lever of shutter front shutter 17 Start lever of shutter rear curtain 20 Time adjustment Lever 20a Projection 22 Time setting lever 24 Shutter time setting cam 30 Electronic timing lever 30a Projection 32 Speed control cam 36 Stepping motor 38 Mode changeover switch 39 Trigger switch 40 Shutter time calculation circuit 41 Drive Circuit 42 Auxiliary trigger lever 45 Electromagnet 46 Moving coil device 56 Electromagnetic actuator 57 Swivel lever

Claims (1)

Claim: What is claimed is: 1. A trigger lever, which operates according to shutter release, is unlocked to rotate by a spring force, the shutter is opened at a first rotation angle, and a second rotation angle is set. At this time, the rotary cam body that closes the shutter, the timing lever that advances into the cam rotation range of this rotation cam body by the spring force, and is pushed by the cam after the shutter is opened to exit the cam rotation range. It holds a time lever at the exit position and has a mechanical shutter time setting mechanism for determining the amount of advance from this exit position, and of a rotary cam body that changes according to the amount of advance of the timing lever. In a camera shutter device having a structure in which the shutter time is controlled in accordance with the rotation time, the electronic shutter operation mode is entered in accordance with the operation of the shutter time setting mechanism for retracting and holding the timing lever outside the cam rotation range, Shatter The electronic shutter control circuit that determines the shutter time in accordance with the shutter release, an auxiliary trigger mechanism that stops the start of the rotating cam body for a predetermined time after unlocking the trigger lever according to the shutter release, and Controlled by the electronic shutter control circuit, the rotation of the rotary cam body is advanced to the cam rotation range described above to delay the rotation of the rotation cam body after the shutter is opened, and at the end of the shutter time, it is moved out of the cam rotation range to close the shutter. A shutter device for a camera, comprising: an electronic timing lever that allows the rotation of a rotating cam body to be rotated.