JPH09258294A - Shutter device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a high-performance shutter device for camera capable of obtaining especially a very high shutter speed. SOLUTION: Light transmission is controlled by changing light transmittance, for example, a characteristic shutter 18 by PLZT utilizing an electrochromic element or Pockels effect is serially arranged on a diaphragm device 17 in the mid-way of photographing lens systems 14, 15 and 16. A mechanical shutter 2 controlling the light transmission by moving mechanical light-shielding means 4 and 5 is arranged just before a photosensitive material 3 on an optical path for the photographing lens system. This device is provided with a controller CPU which controls the light transmittance of the characteristic shutter, so that the light transmittance is changed from a low condition to a high condition in a state where the mechanical shutter is operated to be opened, and changed to the low condition again, then which makes the mechanical shutter operated and closed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a shutter device for a camera which uses a combination of a physical shutter and a mechanical shutter, which are composed of an electro-magnetic optical element whose light transmittance can be changed by applying an electric field or a magnetic field. .

[0002]

2. Description of the Related Art Conventionally, liquid crystals, electrochromic elements (Electrochromic; hereinafter referred to as EC elements), Pockels effect (Pockels effect), Kell effect (Kerr effect), and Faraday effect (F
An opening / closing device for an optical path, which functions as a so-called physical property shutter, to which an electro-magnetic optical element based on the (araday effect) is applied is known. That is, such a physical property shutter can control the opening and closing of the optical path by electricity, magnetism, or the like, unlike a mechanical shutter that has existed in the past. Further, such a physical property shutter has advantages such as being capable of ultra-high speed shutter speed, easy opening / closing control, no mechanical reaction due to operation, and excellent durability.

As a shutter device using such a physical property shutter, for example, in Japanese Patent Application Laid-Open No. 5-127219, the physical property shutter is arranged at a position where a diaphragm device of a photographing lens system is provided, and the function as the diaphragm device and the shutter are provided. An electronic shutter device has been proposed in which a mechanical shutter is provided immediately in front of the film in combination with this physical property shutter. In such a device, the mechanical shutter is opened prior to the physical shutter in conjunction with the operation of pressing the release button of the camera, the physical shutter is opened and closed, and the mechanical shutter is closed after this. The shutter speed is 1 /
We are trying to realize a high-speed shutter of 10,000 seconds.

[0004]

However, the physical property shutter in the conventional shutter device as described above has both a shutter function and a diaphragm function, so that the structure is complicated and the control is complicated. There is a problem. Further, there is a problem in how to arrange the above-described physical property shutter and mechanical shutter in the optical path that passes through the photographing lens system of the camera and reaches the film surface.

That is, the above-mentioned physical property shutter, for example, one using an EC element, is not so responsive, so that it cannot be easily adopted especially for a camera requiring an ultra-high speed shutter speed. Further, if a physical property shutter is configured by using an element utilizing the Pockels effect, the Kell effect, or the like that can operate at high speed, the power supply voltage required for driving the shutter is high, the power supply circuit and others are large, and the element itself is thick. There's a problem.

Further, in any of the above-mentioned physical property shutters, it is unavoidable that non-uniformity of transparency and dust, which are generated during manufacturing, are attached, and these may cause the image on the film surface to be disturbed. It is necessary to consider the installation position. The problem of such an arrangement position is the same in the mechanical shutter, and since the drive unit and the mechanical connection unit of this shutter are additionally provided, the arrangement position in the camera is different from that of other components. It is necessary to consider it in the relationship.

Further, the above-mentioned physical property shutter does not have a sufficient light-shielding property when the shutter is closed, which causes a harmful light leakage problem in a camera using a silver salt film as a light-sensitive material. Consideration should be given to controlling the opening and closing in relation to.

The present invention has been made in view of such circumstances, and exhibits the effects of compensating for the drawbacks of the physical property shutter as described above, and of producing an ultra-high-speed shutter time characteristic of the physical property shutter. An object of the present invention is to obtain a shutter device for a still camera using a silver salt film that can be used.

[0009]

In order to meet such a demand, the shutter device according to the present invention operates a physical property shutter for controlling the passage of light by changing the light transmittance and a mechanical light shielding means. Is equipped with a mechanical shutter that controls the passage of light by means of a physical shutter, which is placed in series with a diaphragm device midway or immediately after the taking lens system, and a mechanical shutter is placed immediately before the photosensitive material on the optical path of the taking lens system. At the same time, the light transmittance of the physical property shutter is changed from a low state to a high state with the mechanical shutter opened.
A control device is provided to control the mechanical shutter so that the mechanical shutter is closed after the mechanical shutter is changed to the low state again.

Here, in the shutter device according to the present invention, the physical property shutter is arranged on the optical path of the photographing lens system at least 5 mm or more away from the photosensitive material behind the mechanical shutter, and the light generated by the photographing lens system is arranged. It is arranged so that the photographing light passes through the physical property shutter before the mechanical shutter on the road.

According to the present invention, by arranging a mechanical shutter in combination with a physical property shutter and controlling them in combination, it is possible to construct a high-performance shutter device capable of an ultra-high-speed shutter time. .

Further, according to the present invention, by the control device,
First, the mechanical shutter is opened, then the physical property shutter is opened by the open signal, the physical property shutter is closed after a predetermined time has elapsed, and the mechanical shutter is closed by the closing signal.
By performing shutter control in this way, a mechanical shutter ensures sufficient light-shielding performance except when shooting.
At the time of shooting, the final exposure time is determined on the physical property shutter side.

In particular, according to the present invention, since the exposure time on the film surface is controlled by the opening / closing operation of the physical property shutter, the mechanical shutter may be operated relatively slowly, so that the driving force may be small. Moreover, since the exposure time does not have to be accurate, this mechanical shutter control device may be simple.

The physical property shutter is a liquid crystal, an electrochromic element (EC element) utilizing an electrochemical reaction, or PLZT (transparent ferroelectric ceramic) utilizing the Pockels effect or the Kell effect, and further has a Faraday effect or an electrophoretic phenomenon. It is composed of a member using an electro-magnetic optical element such as the element used. What is a mechanical shutter?
For example, a focal plane shutter is illustrated, but the present invention is not limited to this. The drive system is also the same. The control device is a control circuit by a CPU that controls the physical property shutter and the mechanical shutter in conjunction with the pressing operation of the release button.

[0015]

1 to 3 show one embodiment of a shutter device according to the present invention. In these drawings, a shutter device generally designated by reference numeral 1 is widely known. It is applied to a still camera using a silver salt film. In FIG. 1, reference numeral 2 is a mechanical shutter main body having a widely known structure, which is arranged immediately in front of a silver salt film 3 which is a photosensitive material. Reference numerals 4 and 5 denote light-shielding blades of a mechanical shutter that open and close the opening 6.

Reference numerals 7 and 8 denote blade drive arms and auxiliary arms for driving the light-shielding blades 4 and 5. The light-shielding blades 4 and 5 are supported by these arms 7 and 8 and their axes 9a and 10 are rotated. The light-blocking blades 4 and 5 are shifted from each other and expanded by a link operation, which is widely known by the rotating motion at 1, and the opening 6 is closed, or the light-blocking blades 4 and 5 are overlapped and stored above the opening 6. The opening 6 can be opened. In the figure, reference numeral 9 is an electric motor for driving the mechanical shutter 1 in accordance with an electric signal.
The light-shielding blades 4 and 5 of the mechanical shutter 1 are opened and closed by rotating the light-shielding blades 4 and 5 clockwise or counterclockwise.

Reference numeral 11 denotes an opening detection switch for the light-shielding blades 4, 5 of the mechanical shutter 1, which comes into contact with the blades 4, 5 and turns on when the light-shielding blades 4, 5 open the opening 6.
Reference numeral 12 denotes a closing detection switch for the light shielding blades 4 and 5, which is turned on by coming into contact with the light shielding blades 4 and 5 to detect that the opening 6 is closed.

Reference numerals 14, 15 and 16 denote photographing lenses which are incorporated in a lens barrel of a camera to constitute a photographing lens system, and a diaphragm device 1 having a widely known structure on the way.
7 are arranged in between. Reference numeral 18 denotes a physical property shutter (here, an EC shutter) provided in parallel with the mechanical shutter 1 on the photographing optical path.
Diaphragm device 1 in photographing lens system by 4, 15 and 16
It is located just before 7.

FIG. 2 is a block diagram of a control circuit in the camera having the structure shown in FIG. 1 described above. In FIG. 2, 20 is a release button and 21 is a release switch which is turned on by pressing the release button 21. 22 are CPUs for controlling various sequence operations of the camera.

An EC drive circuit 23 for driving the EC 18 has transistors 24 and 25, and these transistors 24 and 25 determine positive or negative when the voltage of the power supply 26 is applied to the EC 18. A mechanical shutter drive circuit 27 controls stop, forward rotation, and reverse rotation of the motor 9. A diaphragm driving circuit 28 is for controlling the diaphragm device 17. In this embodiment, the diaphragm device 17 is composed of an electromagnetic diaphragm unit, and the circuit 28 can electrically determine the diaphragm aperture.

Next, the photographing operation of the camera having the above-mentioned structure will be described below with reference to FIGS. 2 and 3.
When the release button 20 of the camera is pressed, the release switch 21 is turned on, and the CPU 22 causes various shooting preparation operations, such as autofocus operation and mirror operation, which are necessary operations depending on the type of camera. During this photographing preparation operation, after the delay time of time t1 is counted by the built-in timer (not shown) of the CPU 22,
Next, the diaphragm control circuit 28 causes the diaphragm device 17 to start the diaphragm operation. Then, the diaphragm device 17 is controlled to have a predetermined aperture.

After the delay time t2 required for controlling the diaphragm device 17 is given by the built-in timer of the CPU 22, the mechanical shutter drive circuit 27 is operated, the motor 9 is driven to rotate, and the mechanical shutter drive circuit 27 is driven. The shutter 2 opens.
Then, the opening detection switch 11 is turned on by the light-shielding blades 4 and 5, whereby the CPU 22 sends a signal to the drive circuit 27 to stop the motor 9.

At the same time, the transistor 24 is turned on by the action of the EC shutter drive circuit 23, a positive voltage is applied to the EC shutter 18, and the transmittance of the EC shutter 18 increases. That is, the EC shutter 18 is opened. Further, the CPU 22 sends a close command to the EC shutter drive circuit 23 at a timing such that a predetermined shutter speed is achieved. Then, the transistor 25 turns on and EC
When a negative voltage is applied to the shutter 18, the EC shutter 18
Transmittance is reduced. That is, the EC shutter 18 is closed.

The CPU 22 is the EC shutter 1 described above.
At the same time as the close command to 8 or after some time has passed,
A closing command is also sent to the mechanical shutter drive circuit 27, the motor 9 rotates in the opposite direction to the above, and the mechanical shutter 2 is closed. Then, the light-shielding blades 4 and 5 turn on the closing detection switch 12, so that the CPU 22 sends a signal to the mechanical shutter drive circuit 27 in response to the ON signal, and the motor 9
To stop.

As described above, according to the present invention, the mechanical shutter 2 is performed after the photographing preparation operation is performed from the pressing operation of the release button 20 and the diaphragm control of the diaphragm device 17 is further performed.
By opening the EC shutter 18
The film 3 is exposed. Further, after a lapse of a predetermined time, the EC shutter 18 is closed, the exposure of the film 3 is completed, and the EC shutter 18 is closed so that the mechanical shutter 2 is controlled.

After the mechanical shutter 2 is closed, the preparatory shooting operation before release, which is determined by the type of the camera, such as feeding the film 3 and charging the mirror operating force, is performed. When the shooting preparation operation before the release is completed, the camera stops and returns to the state immediately before the release. These sequence controls are shown in the time chart of FIG.

The present invention is not limited to the structure described in the above-mentioned embodiment, and the shape, structure, etc. of each mechanism in the camera may be appropriately modified or changed. For example, in the above-described embodiment, the case where the mechanical shutter 2 has the structure using the two light-shielding blades 4 and 5 has been described. However, the present invention is not limited to this, and a mechanical diaphragm-shaped five is provided. It may be composed of one or six light shielding blades. Also,
It is possible to use a single light-shielding plate having a structure for taking in and out, or to use various light-opening / closing mechanisms having other widely known structures. Further, when performing high-speed continuous shooting, the mechanical shutter 2 may be configured so that once it is opened, the EC shutter 17 is repeatedly opened and closed and the film is advanced to perform continuous shooting in a short cycle. In this case, the mechanical shutter 2 is closed after the continuous shooting is completed.

Further, the drive source of the mechanical shutter 2 as described above is not limited to the electric motor 9 in the above-mentioned embodiment, but may be driven by using an elastic member such as a spring. When this spring is used, the shutter may be charged either during the feeding period of the film 3 in the time chart of FIG. 3 or during the period from immediately after the release to the opening operation of the mechanical shutter 2. Good.

Furthermore, the EC shutter 17 in the above-described embodiment is generally not very responsive. Therefore, although it is effective in simplifying the shutter mechanism, it is not so suitable for a camera that requires a high speed, in particular, an ultra high speed shutter speed. In such a case, if the shutter device is replaced by a physical property shutter device that utilizes the Pockels effect, the Kell effect, or the Faraday effect, which enables high-speed operation, the shutter device will be slightly larger, but ultra-high speeds such as nanoseconds and picoseconds. The shutter speed can be obtained.

Therefore, FIG. 4 shows another embodiment of the present invention, and the EC shutter 18 as the physical property shutter described above.
FIG. 6 is a principle diagram of a Pockels effect type PLZT shutter used in place of FIG. Figure 30 is PbTi O ₃ -PbZrO ₃
This is an optical shutter of so-called PLZT in which a La ₂ O ₃ based ceramic is sandwiched between two polarizing plates.
31 is a power source for the optical shutter 30 by PLZT, 3
2 is a PLZT control circuit, which is configured to be controlled by the CPU 22 of FIG.

Optical shutter 30 using such a PLZT
The operation of is as follows. That is, after the mechanical shutter 2 is opened, the PLZT control circuit 32 is set by the CPU 22.
A shutter open command signal is sent to. Then, the power supply 31
The high voltage generated by is applied between the electrodes 33 and 34, the transmittance of the optical shutter 30 by PLZT is increased, and the shutter is opened. Next, when a shutter closing command signal is sent from the CPU 22 so as to obtain a predetermined shutter speed, the PLZT control circuit 32 causes the electrodes 33 and 34 to operate.
Since the voltage applied to is released, the transmittance is reduced and the shutter returns to the closed state.

After the above, the mechanical shutter 2 is closed by the command of the CPU 22 in the same manner as the operation described in the first embodiment described above, and the operation thereafter is also the same as in the first embodiment described above. The description is omitted because it is the same.

Here, in such an embodiment, as described above, the voltage required for driving the shutter is higher than that in the first embodiment, and the power supply circuit and the like become large, but the conventional mechanical shutter is damaged. It is possible to realize an ultra-high-speed shutter speed that would cause the above.

In addition, the EC shutter 18 and PLZ described above
A physical property shutter such as the optical shutter 30 by T is
It is arranged near the principal points of the photographing lenses 14, 15 and 16. In this way, the electrodes of these physical property shutters,
For example, it is possible to prevent the electrodes 33 and 34 shown in FIG. In this case, the same effect can be obtained by disposing it just before the lens 14 or just after the lens 16.

Here, with respect to the disposition position of such a physical property shutter, the closer the disposition position is to the film 3, the more disadvantageous. The criteria for how close the image on the film 3 is adversely affected are unevenness of the transmittance on the shutter side, its range and size, dust, the distance from the exit pupil of the lens used to the film 3, the F number, and the film used. It depends on resolving power, contrast, enlargement ratio, and viewer distance. However, if the shutter is arranged within 5 mm from the film surface like the conventional focal plane shutter, the above-mentioned unevenness of transmittance and dust are surely exposed on the film. Therefore, it is necessary to place them at least 5 mm apart.

Next, the mechanical shutter 2 may be arranged anywhere, but it is arranged at a location convenient for design. Usually, the mechanical shutter 2 has a mechanical mechanism part with the camera. In other words, since there is a connecting part with a widely known charging mechanism and control magnet holding mechanism, in order to arrange these in a simple and efficient manner, they should be placed too far from the film in the camera, that is, on the lens side. You shouldn't do it.

Further, as in the above-described first embodiment, even if the mechanical shutter 2 is driven by a motor and is connected to the control section on the camera side only by electric wiring, the motor 9 is disposed. Considering the location and the driving force transmission system, it is preferable to arrange them in a place where a space can be easily taken in the form of the camera. Also, disposing the lens 3 away from the film 3 and closer to the photographing lens system side will unnecessarily increase the size of the camera and the lens unit.

On the other hand, since the physical property shutter is generally connected to the control section on the camera side only by electric wiring, the degree of freedom in arranging the physical property shutter is higher than that of the mechanical shutter 2. That is, according to the order of the shooting optical path, if the physical shutter is arranged on the front side and the mechanical shutter is arranged on the rear side, the simplest and fewest number of parts, high reliability, low cost, and a small camera, It is possible to configure a taking lens system.

[0039]

[Examples] Physical property shutters include liquid crystal, an electrochromic element (EC element) that utilizes an electrochemical reaction, PLZT (transparent ferroelectric ceramic) that utilizes the Pockels effect and the Kell effect, and those based on the Faraday effect and electrical properties. It is composed of a member using an electro-magnetic optical element such as an element utilizing the electrophoretic phenomenon. The mechanical shutter is, for example, a focal plane shutter. As the control device, a control circuit by a CPU 22 that controls the physical property shutter 18 and the mechanical shutter 2 in conjunction with the pressing operation of the release button 20 is used.

[0040]

As described above, according to the shutter device of the present invention, a physical mechanical shutter is additionally combined with a simple mechanical shutter, and a control circuit for sequentially controlling the opening and closing of these shutters is provided. , The shutter control by the ultra-high-speed shutter time in the camera is easy, there is no camera shake due to the reaction that accompanies the operation, and the durability is also high, while the advantages of the physical property shutter are obtained, but the drawback is that the light-shielding property is poor. It is possible to obtain a high-performance shutter device that supplements the above.

Further, according to the present invention, by providing the physical property shutter away from the image plane, it is possible to reduce the influence of the element that disturbs the image due to the unevenness of the transmittance and the adhesion of dust which occur during the manufacture of the physical property shutter. Further, according to the present invention, by providing the physical shutter first with respect to the incident light in the photographing optical path and then arranging the mechanical shutter, the interlocking relationship in the camera becomes rational, and the operation is simple and operational. You can get a reliable, low-cost camera in.

In particular, according to the present invention, since the exposure time is controlled by the opening / closing operation of the physical property shutter, the driving force may be small because the mechanical shutter may be operated relatively slowly. The control device may be simple.

[Brief description of drawings]

FIG. 1 is a perspective view showing one embodiment of a shutter device according to the present invention and is a perspective view for explaining the shutter device including a photographing optical system of a camera.

FIG. 2 is a block diagram of a control circuit in the camera, showing one embodiment of the shutter device according to the present invention.

FIG. 3 is a time chart for explaining one embodiment of the shutter device according to the present invention and for explaining a sequence control operation of each unit in the camera.

FIG. 4 shows another embodiment of the shutter device according to the present invention, in which P due to the Pockels effect as a physical property shutter.
It is a principle view of an optical shutter by LZT.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Shutter device, 2 ... Mechanical shutter main body, 3 ... Film, 4, 5 ... Shading blade, 6 ... Shutter opening part, 7 ... Blade drive arm, 8 ... Auxiliary arm, 9 ... Electric motor, 9a
... axis, 10 ... axis, 11 ... shutter open detection switch, 1
2 ... Shutter close detection switch, 14, 15, 16 ... Photographing lens that constitutes the phototaking lens system, 17 ... Diaphragm device, 2
0 ... Release button, 21 ... Release switch, 22 ... CP
U, 23 ... EC drive circuit, 24, 25 ... Transistor,
26 ... Power source, 27 ... Mechanical shutter drive circuit, 28 ... Aperture drive circuit.

Claims (3)

[Claims] 1. A physical property shutter for controlling the passage of light by changing the light transmittance, and a mechanical shutter for controlling the passage of light by moving a mechanical light shielding means, wherein the physical property shutter is a photographing lens. The mechanical shutter is arranged in series with the diaphragm device in the middle of or immediately after the system, the mechanical shutter is arranged immediately before the photosensitive material on the optical path of the taking lens system, and the physical shutter is opened in a state where the mechanical shutter is opened. The shutter device is provided with a control device that controls the light transmittance of the mechanical shutter to change from a low state to a high state and then to a low state again to close the mechanical shutter. 2. The shutter device according to claim 1, wherein the physical property shutter is arranged on the optical path of the taking lens system at least 5 mm away from the photosensitive material behind the mechanical shutter. . 3. A shutter device according to claim 1, wherein the shutter device is arranged such that the photographing light passes through the physical property shutter before the mechanical shutter on the optical path of the photographing lens system.