JP4450489B2 - Camera shutter device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a camera shutter device mounted as an exposure shutter device or a light-shielding shutter device in various types of cameras such as a digital still camera, a silver salt film camera, and a range finder camera, and in particular, a shutter. The present invention relates to a camera shutter device in which a blade is directly driven by an electromagnetic drive source.
[0002]
[Prior art]
From the viewpoint of simplifying the structure of the camera shutter device, a type of camera shutter device that directly drives shutter blades using an electromagnetic drive source such as a motor has been developed. In this type of camera shutter device, since the driving force generated by the electromagnetic drive source or the holding force for holding the shutter blade in a predetermined position in a non-energized state is small, the traveling operation when the shutter blade is traveling is unstable. There is a possibility that the shutter blade held in the closed position easily moves due to an external impact or vibration, and the opening is opened during a time other than the exposure operation.
In particular, as a camera shutter device that takes measures against the shortage of the holding force, for example, the one described in Japanese Utility Model Laid-Open No. 56-7922 is known. In the camera shutter device disclosed in this publication, when the shutter blade is in a position where the opening is closed, a lock mechanism including a lever or the like that locks the rotation shaft of the electromagnetic drive source is provided, and prior to the release operation. The lock mechanism is configured to release the lock.
[0003]
[Problems to be solved by the invention]
By the way, in order to cope with a shortage of holding force or the like, when adopting a lock mechanism including the lever as described above, a lever constituting the lock mechanism or a peripheral member engaged with the lever is required. In addition, a drive source for performing a locking operation or a releasing operation thereof is required, and the original purpose of simplifying the structure cannot be achieved. In addition, since the driving force of the electromagnetic drive source is relatively small, the shutter blades are prevented from rattling or the like immediately after the lock state by the lock mechanism is released, and the shutter blades travel at a predetermined timing from a predetermined position. It is necessary to ensure that this is performed stably.
[0004]
The present invention has been made in view of such problems, and an object of the present invention is to reduce the cost by simplifying the structure, reducing the number of parts, etc. It is an object of the present invention to provide a camera shutter device that can be reliably held in position and can reliably perform a stable running operation when driving shutter blades.
[0005]
[Means for Solving the Problems]
The camera shutter device of the present invention comprises at least one shutter blade, a drive arm that supports the shutter blade, and a support arm, and is provided between an open position for opening an exposure opening and a closed position for closing. Can run Established The light shielding means, a first electromagnetic drive source that directly applies a driving force to the light shielding means when energized, and generates a holding force that holds the light shielding means in the closed position when not energized, and the light shielding means is in the closed position. Sometimes shading means Vs. And the same direction as the holding force Directly to It has the 2nd electromagnetic drive source which gives urging | biasing force and controls the movement, It is characterized by the above-mentioned.
According to this configuration, when the light shielding unit is in the closed position, the magnetic holding force generated by the first electromagnetic drive source acts on the light shielding unit, and the light generated by the second electromagnetic drive source is applied to the light shielding unit. Power is acting. That is, by adding the urging force of the second electromagnetic drive source to the holding force of the first electromagnetic drive source, the light shielding means is reliably held in the closed position without moving against external impact or vibration. The
[0006]
In the above configuration, the second electromagnetic drive source is connected to the light shielding unit immediately before the light shielding unit travels from the closed position to the open position. for Direction that antagonizes the holding power of the first electromagnetic drive source Directly to A configuration that exerts a biasing force can be employed.
According to this configuration, immediately before the light shielding means travels, the second electromagnetic drive source releases the biasing force toward the closed position and generates a biasing force in a direction that antagonizes the holding force of the first electromagnetic drive source. Then, the shading means is pressed against a predetermined travel start position to perform backlash. When the light shielding means starts traveling in this state, it travels stably at a predetermined timing.
[0007]
The said structure WHEREIN: The structure currently formed so that the 2nd electromagnetic drive source may generate | occur | produce said energizing force in a non-energized state is employable.
According to this configuration, the second electromagnetic drive source has a biasing force that biases the light shielding means in the same direction as the holding force of the first electromagnetic drive source in the non-energized state and also holds the first electromagnetic drive source. A biasing force that biases in a direction that antagonizes the force is generated, and power consumption is reduced.
[0008]
In the above configuration, the light shielding means that directly engages with the second electromagnetic drive source is a support arm or a shutter blade, and the support arm or the shutter blade has an urging force of the second electromagnetic drive source when in the closed position. The first driven part that is engaged and pushed by the output part that outputs the output, and the output part that outputs the urging force of the second electromagnetic drive source immediately before the light shielding means travels from the closed position to the open position. It is possible to adopt a configuration in which a second pushed portion that is pushed together is formed.
According to this configuration, the urging force of the second electromagnetic drive source is transmitted to the shutter blades via the first pushed portion or the second pushed portion formed on the support arm. In addition, when the first pushed portion or the second pushed portion is formed not on the support arm but on the shutter blade, the urging force is directly transmitted to the shutter blade.
[0009]
The said structure WHEREIN: The structure which the spring which exerts urging | biasing force in the direction which positions a light-shielding means in a closed position can be employ | adopted for the 2nd electromagnetic drive source.
According to this configuration, the biasing force of the spring is added to the holding force of the first electromagnetic driving source and the biasing force of the second electromagnetic driving source, and the light shielding means is more reliably held in the closed position.
[0010]
In the above configuration, the light shielding means includes a front blade and a rear blade pivoted by two sets of drive arms and a support arm, and the second electromagnetic drive source exerts a biasing force on at least the front blade. It is possible to adopt a configuration that is arranged as described above.
According to this configuration, the urging force by the second electromagnetic drive source acts on the leading blade, thereby reliably preventing the opening from being opened before the shutter operation.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
1 to 3 show an embodiment of a camera shutter device according to the present invention. FIG. 1 shows a state in which the shutter blade is in a closed position where the opening is closed, and FIG. 2 shows the shutter blade in the opening. 3 shows a state immediately before traveling and FIG. 3 shows a state in which the shutter blades are in an open position where the opening is opened by traveling.
The camera shutter device according to this embodiment is arranged so as to be movable between a ground plate 10 that defines an opening 10a for exposure and an open position that opens the opening 10a and a closed position that closes the ground plate 10 on the ground plate 10. The shutter blade 20, the first electromagnetic drive source 30 that exerts a direct driving force on the shutter blade 20 when energized or a holding force when the power is not energized, and the second electromagnetic drive that exerts a predetermined urging force on the shutter blade 20 A source 40 and the like are provided as its basic configuration.
[0012]
The first electromagnetic drive source 30 includes a rotor 31 having a drive pin (output unit) 31a that is magnetized to N and S poles and outputs a drive force, an excitation coil 32, and a cylinder that forms a magnetic path. This is a moving magnet type electromagnetic actuator called an iris motor composed of a yoke 33 and magnetic pins 34, 35 and the like.
As shown in FIG. 1, when the shutter blade 20 is in the closed position, the N pole of the rotor 31 is pulled by the magnetic pin 34 in a non-energized state of the coil 32, and the rotor 31 rotates clockwise. As shown in FIG. 3, when the shutter blade 20 is in the open position, the south pole of the rotor 31 is pulled by the magnetic pin 35 in a non-energized state so as to exert an urging force (holding force). 31 is adapted to exert a rotational biasing force (holding force) counterclockwise.
[0013]
Similar to the first electromagnetic drive source 30 described above, the second electromagnetic drive source 40 includes a rotor 41 having a drive pin (output unit) 41a that is magnetized at the north and south poles and outputs a drive force, Coil 42, a cylindrical yoke 43 forming a magnetic path, magnetic pins 44, 45, and the like.
As shown in FIG. 1, when the shutter blade 20 is in the closed position, the N pole of the rotor 41 is pulled by the magnetic pin 44 in a non-energized state of the coil 42, and the rotor 41 rotates clockwise. As shown in FIG. 2, when the shutter blade 20 is in a state immediately before traveling from the closed position to the open position, the S pole of the rotor 41 is applied to the magnetic pin 45 in a non-energized state. As a result, the rotor 41 exerts a rotational biasing force counterclockwise.
[0014]
As described above, by configuring the first electromagnetic drive source 30 and the second electromagnetic drive source 40 to have the same configuration, it is possible to share components while using two electromagnetic drive sources, and to manage costs by reducing the number of components. In addition, the cost of parts can be reduced.
[0015]
As shown in FIGS. 1 and 2, the light shielding means includes a shutter blade 20 composed of a plurality of (here, three) blades 21, 22, and 23, and these blades 21, 22, and 23 are rotatable. The drive arm 24 and the support arm 25 are connected to each other. The drive arm 24 and the support arm 25 are rotatably supported by support shafts 10b and 10c provided on the back surface of the main plate 10, respectively.
The drive arm 24 is formed with a long hole 24a with which the drive pin 31a of the first electromagnetic drive source 30 is engaged. The drive pin 31a of the first electromagnetic drive source 30 is loosely inserted into a long hole 10d formed in the main plate 10, and the drive pin 31a comes into contact with both end portions of the long hole 10d, so that the first electromagnetic The rotation range of the drive source 30 (rotor 31) is regulated. In FIG. 1, the lower edge of the blade 23 is an open edge, and when the shutter blade 20 travels to the open position, the opening 10a is opened by the open edge.
[0016]
As shown in FIG. 1, when the shutter blade 20 is in the closed position, the support arm 25 is engaged with and pushed by the drive pin 41a of the second electromagnetic drive source 40. As shown in FIG. 2, immediately before the shutter blade 20 travels from the closed position to the open position, the second driven portion 25b is engaged and pushed by the drive pin 41a of the second electromagnetic drive source 40. And are formed.
The drive pin 41a of the second electromagnetic drive source 40 is loosely inserted into a long hole 10e formed in the main plate 10, and the drive pin is connected to the right end of the long hole 10e and the first driven portion 25a. The rotation range of the second electromagnetic drive source 40 (rotor 41) is restricted by the contact of 41a.
[0017]
Next, the operation when the camera shutter device according to this embodiment is mounted on a digital still camera as an exposure shutter device will be described with reference to the time charts of FIGS. 1 to 3 and FIG. .
The CCD (imaging device) used in the digital still camera according to the present embodiment has an electronic shutter function in itself, and the photographer can capture the subject image with the optical viewfinder even when the shutter blade 20 is in the closed position. Can be observed. Therefore, first, when the main switch of the camera is turned on, the CCD is also energized, and in this standby state waiting for photographing, the shutter blade 20 is in the closed position as shown in FIG. At this time, the drive pin 31a of the first electromagnetic drive source 30 is in a non-energized state and abuts against one end portion of the long hole 10d, and further clockwise rotation is restricted, while the clockwise rotation biasing force ( Holding power). On the other hand, the drive pin 41a of the second electromagnetic drive source 40 is in a non-energized state and is in contact with the first driven portion 25a (the left end portion of the long hole 10e is in a non-contact state) or more. While the clockwise rotation is restricted, the shutter blade 20 is pressed slightly clockwise to exert a rotational biasing force.
In this state, the shutter blade 20 is reliably held in the closed position because the urging force of the second electromagnetic drive source 40 is applied to the shutter blade 20 in addition to the holding force of the first electromagnetic drive source 30. become.
[0018]
In this standby state, when the photographer performs a release operation, as shown in FIG. 4, the second electromagnetic drive source 40 rotates forward (rotates counterclockwise) by a predetermined angle by energizing the coil 42, As shown in FIG. 2, the drive pin 41a abuts against the second driven portion 25b and exerts a rotational urging force to move the shutter blade 20 slightly toward the open position. In other words, the biasing force of the second electromagnetic drive source 40 acts in a direction that antagonizes the holding force of the first electromagnetic drive source 30, whereby the shutter blade 20 is rattled via the support arm 25, and the shutter blade 20 Is opened at a predetermined exposure start position.
[0019]
Subsequently, while the electromagnetic urging force by the second electromagnetic drive source 40 is acting, the first electromagnetic drive source 30 is rotated forward (counterclockwise) by energizing the coil 32 as shown in FIG. As shown in FIG. 3, the shutter blade 20 travels to the open position. Thereafter, the drive pin 31a comes into contact with the other end of the long hole 10d, and further rotation is restricted, and the coil 32 is deenergized. At this time, the holding force of the first electromagnetic drive source 30 is acting in the direction of holding the shutter blade 20 in the open position.
When the shutter blade 20 starts to travel toward the open position, the second driven portion 25b is detached from the drive pin 41a of the second electromagnetic drive source 40, and the drive pin 41a is the right end of the long hole 10e. Further rotation is restricted in contact with.
Further, when the opening 10a is opened by the travel of the shutter blade 20, as shown in FIG. 4, the electronic shutter of the CCD (imaging device) is turned on for a predetermined time (exposure time), and imaging is performed. To do.
At this time, since the open edge of the shutter blade 20 is positioned at the predetermined exposure start position described above, from the start of energization to the coil 32 until the electronic shutter of the CCD is turned on after the opening 10a is opened. Since the timing is constant, control of the CCD becomes easy.
[0020]
Thereafter, the first electromagnetic drive source 30 is reversely rotated (rotated clockwise) by energization in the reverse direction to the coil 32, and as shown in FIG. 1, the shutter blade 20 travels again to the closed position, and the drive pin 31a. Comes into contact with one end of the long hole 10d, and further rotation is restricted, the shutter blade 20 stops, and the coil 32 is deenergized. Further, the reverse energization of the coil 42 causes the second electromagnetic drive source 40 to reversely rotate (rotate clockwise), the drive pin 41a comes into contact with the first pushed portion 25a, and the shutter blade 20 is slightly moved. While pressing toward the closed position, further rotation is restricted, and the power supply to the coil 42 is cut off. Thereby, the shutter blade 20 is reliably held at the closed position by the holding force of the first electromagnetic drive source 30 and the urging force of the second electromagnetic drive source 40 and is again in the standby state. In the subsequent photographing, the above sequence is repeated.
[0021]
In the above embodiment, as shown in FIG. 5, the second electromagnetic drive source 40 may be provided with a spring 50 that exerts an urging force in the direction in which the shutter blade 20 is positioned at the closed position.
That is, as shown in FIG. 5, a tension type spring 50 is stretched between the projection 10f of the base plate 10 and the drive pin 41a. According to this configuration, as shown in FIG. 5A, when the shutter blade 20 is in the closed position, the urging force of the spring 50 is applied as a force for holding the shutter blade 20 in the closed position. Is more securely held in the closed position.
On the other hand, immediately before the shutter blade 20 travels, as shown in FIG. 5B, an urging force acting against the force to rotate the rotor 41 in the forward direction acts. In addition, since the load applied to the second electromagnetic drive source 40 is originally small, the second electromagnetic drive source 40 surely performs a desired function.
[0022]
Further, in the present embodiment, the first pushed portion 25a and the second pushed portion 25b are formed on the support arm 25, but the first pushed portion is not formed on the shutter blade 20 without doing so. And a second driven part can be formed.
That is, the side of the shutter blade 20 that is rotatably connected to the support arm 25 of the blade 21 is extended in the direction of the drive pin 41a, and the first driven portion 25a and the second driven portion are further extended to the extended portion. By forming a shape equivalent to the portion 25b, a first pushed portion and a second pushed portion that engage with the drive pin 41a can be formed.
Even in such a case, since the urging force of the second electromagnetic drive source 40 is directly applied to the shutter blade 20, the shutter blade 20 is securely held in the closed position, and is further moved back to perform a predetermined exposure start position. Will be positioned.
[0023]
6 to 9 show another embodiment of the camera shutter device according to the present invention. There are two sets of light shielding means, which are pivotally supported by a pair of drive arm and support arm, respectively. It consists of a leading blade and a trailing blade. 6 shows a state where the leading blade is in the closed position, FIG. 7 shows a state immediately before the traveling, FIG. 8 shows a state where the leading blade is in the open position, and FIG. 9 shows a state where the trailing blade is in the closed position. .
The camera shutter device according to this embodiment is arranged to be movable between a base plate 100 that defines an opening 100a for exposure, and an open position that opens the opening 100a and a closed position that closes the base plate 100. The first blade 120 and the first electromagnetic drive source 140 for the first blade that exerts a driving force on the first blade 120 when energized or a holding force when the current is not energized. A second electromagnetic drive source 150 for the leading blade that exerts a predetermined biasing force, a first electromagnetic drive source 160 for the trailing blade that exerts a direct driving force on the rear blade 130 when energized or a holding force when de-energized, etc. Is provided as its basic configuration.
[0024]
The first electromagnetic drive source 140 for the leading blade includes a rotor 141 including a drive pin (output unit) 141a that is magnetized to the N pole and the S pole and outputs a driving force, an excitation coil 142, a magnetic path This is a moving magnet type electromagnetic actuator called an iris motor composed of a cylindrical yoke 143 forming a magnetic pin 144, magnetic pins 144, 145 and the like.
As shown in FIG. 6, when the leading blade 120 is in the closed position, the N pole of the rotor 141 is pulled by the magnetic pin 144 while the coil 142 is not energized, and the rotor 141 rotates clockwise. As shown in FIGS. 8 and 9, when the leading blade 120 is in the open position, the south pole of the rotor 141 is pulled by the magnetic pin 145 in a non-energized state so as to exert an urging force (holding force). Thus, the rotor 141 applies a rotational biasing force (holding force) counterclockwise.
[0025]
Similar to the first electromagnetic drive source 140 described above, the second electromagnetic drive source 150 includes a rotor 151 having a drive pin (output unit) 151a that is magnetized at the N pole and the S pole and outputs a drive force, Coil 152, a cylindrical yoke 153 forming a magnetic path, magnetic pins 154 and 155, and the like.
Then, as shown in FIG. 6, when the leading blade 120 is in the closed position, the N pole of the rotor 151 is pulled by the magnetic pin 154 in a non-energized state of the coil 152, and the rotor 151 rotates clockwise. When the leading blade 120 is in a state immediately before traveling from the closed position to the open position as shown in FIG. 7 so as to exert an urging force, the S pole of the rotor 151 is applied to the magnetic pin 155 in a non-energized state. As a result, the rotor 151 exerts a rotational biasing force counterclockwise.
[0026]
The first electromagnetic drive source 160 for the rear blades, like the electromagnetic drive sources 140 and 150, is a rotor including a drive pin (output unit) 161a that is magnetized at the N pole and the S pole and outputs a driving force. 161, an exciting coil 162, a cylindrical yoke 163 forming a magnetic path, magnetic pins 164, 165, and the like.
6 to 8, when the rear blade 130 is in the open position, the N pole of the rotor 161 is pulled by the magnetic pin 164 in a non-energized state of the coil 162, and the rotor 161 is As shown in FIG. 9, when the rear blade 130 is in the closed position, the south pole of the rotor 161 is pulled by the magnetic pin 165 in a non-energized state so as to exert a rotational biasing force (holding force). Thus, the rotor 161 exerts a rotational biasing force (holding force) counterclockwise.
[0027]
Thus, by using the same configuration for the first electromagnetic drive source 140, 160 and the second electromagnetic drive source 150, it is possible to share components while using three electromagnetic drive sources, and to manage by reducing the number of components. Costs and component costs can be reduced.
[0028]
As shown in FIG. 6, one of the light shielding means is a front blade 120 composed of a plurality of (here, three) blades 121, 122, 123, and these blades 121, 122, 123 are rotatably connected to each other. Drive arm 124 and support arm 125. The drive arm 124 and the support arm 125 are rotatably supported by support shafts 100b and 100c provided on the back surface of the main plate 100, respectively.
The drive arm 124 is formed with a long hole 124a with which the drive pin 141a of the first electromagnetic drive source 140 is engaged. The drive pin 141a of the first electromagnetic drive source 140 is loosely inserted into a long hole 100d formed in the main plate 100, and the drive pin 141a comes into contact with both ends of the long hole 100d so that the first electromagnetic The rotation range of the drive source 140 (rotor 141) is restricted.
In FIG. 6, the lower edge of the blade 123 is an open edge, and when the leading blade 120 travels to the open position, the opening 100a is opened by the open edge.
[0029]
As shown in FIG. 6, the support arm 125 has a first driven portion 125a that is engaged and pushed by the drive pin 151a of the second electromagnetic drive source 150 when the leading blade 120 is in the closed position. As shown in FIG. 7, immediately before the leading blade 120 travels from the closed position to the open position, the second driven portion 125b that is engaged and pushed by the drive pin 151a of the second electromagnetic drive source 150. And are formed.
The drive pin 151a of the second electromagnetic drive source 150 is loosely inserted into a long hole 100e formed in the main plate 100, and the drive pin is connected to the right end of the long hole 100e and the first driven portion 125a. With the contact of 151a, the rotation range of the second electromagnetic drive source 150 (rotor 151) is restricted.
[0030]
As shown in FIG. 9, the other light-shielding means is configured such that a rear blade 130 composed of a plurality of (here, three) blades 131, 132, and 133 and these blades 131, 132, and 133 are rotatably connected to each other. The drive arm 134 and the support arm 135 are configured. The drive arm 134 and the support arm 135 are rotatably supported by support shafts 100g and 100h provided on the back surface of the main plate 100, respectively.
The drive arm 134 is formed with a long hole 134a with which the drive pin 161a of the first electromagnetic drive source 160 is engaged. The drive pin 161a of the first electromagnetic drive source 160 is loosely inserted into a long hole 100j formed in the main plate 100, and the drive pin 161a comes into contact with both ends of the long hole 100j so that the first electromagnetic The rotation range of the drive source 160 (rotor 161) is restricted.
In FIG. 9, the upper edge of the blade 133 is a closed edge, and when the rear blade 130 travels to the closed position, the opening 100a is closed by this closed edge.
[0031]
Further, as shown in FIG. 6, the drive arm 134 is hooked with the other end of the spring 170 with one end hooked to the base plate 100, so that the rear blade 130 is always pulled toward the open position. Is exerting a biasing force. As a result, the rear blade 130 is rattled and the closing edge is positioned at a predetermined exposure start position before traveling.
Note that such a backlash spring 170 acts as a load on the first electromagnetic drive source 160 when the rear blade 130 travels for exposure, and thus affects the exposure time. Further, when the rear blade 130 is arranged so as to always exert an urging force toward the closed position, there is a possibility that the holding force of the first electromagnetic drive source 160 will be insufficient when affected by an impact or the like. Therefore, instead of the spring 170, a second electromagnetic drive source similar to the second electromagnetic drive source 150 of the leading blade 120 may be provided on the support arm 135 side.
[0032]
Next, operations when the camera shutter device according to this embodiment is mounted on a film camera as an exposure shutter device will be described with reference to the time charts of FIGS. 6 to 9 and FIG. .
First, when the camera main switch is turned on and in a standby state waiting for photographing, the leading blade 120 is in the closed position and the trailing blade 130 is in the open position, as shown in FIG. At this time, the drive pin 141a of the first electromagnetic drive source 140 is in a non-energized state and abuts against one end of the long hole 100d, and further clockwise rotation is restricted, while the clockwise rotation biasing force ( Holding power). On the other hand, the drive pin 151a of the second electromagnetic drive source 150 is in a non-energized state and is in contact with the first pushed portion 125a (the left end portion of the long hole 100e is in a non-contact state) or more. While the clockwise rotation is restricted, the leading blade 120 is pressed slightly clockwise to exert a rotational biasing force.
In this state, the leading blade 120 is reliably held in the closed position because the biasing force from the second electromagnetic driving source 150 is applied to the leading blade 120 in addition to the holding force from the first electromagnetic driving source 140. become.
On the other hand, the drive pin 161a of the first electromagnetic drive source 160 is in a non-energized state and abuts against one end portion of the long hole 100j, and further clockwise rotation is restricted. The rotational biasing force (holding force) is exerted. Further, the rear blade 130 is loosely moved by a spring 170.
[0033]
In this standby state, when the photographer performs a release operation, the second electromagnetic drive source 150 rotates forward (rotates counterclockwise) by a predetermined angle by energizing the coil 152 as shown in FIG. As shown in FIG. 7, the drive pin 151a abuts against the second driven portion 125b and exerts a rotational urging force to move the leading blade 120 slightly toward the open position. That is, the biasing force of the second electromagnetic drive source 150 acts in a direction that antagonizes the holding force of the first electromagnetic drive source 140, whereby the leading blade 120 is rattled and the open edge of the leading blade 120 is a predetermined edge. Positioned at the exposure start position.
[0034]
Subsequently, while the urging force by the second electromagnetic drive source 150 is acting, the first electromagnetic drive source 140 rotates forward (rotates counterclockwise) by energizing the coil 142 as shown in FIG. Then, as shown in FIG. 8, the leading blade 120 travels to the open position. Thereafter, the drive pin 141a comes into contact with the other end of the long hole 100d, and further rotation is restricted, and the coil 142 is deenergized. At this time, the holding force of the first electromagnetic drive source 140 is acting in a direction to hold the leading blade 120 in the open position.
When the leading blade 120 starts traveling toward the open position, the second pushed portion 125b is detached from the drive pin 151a of the second electromagnetic drive source 150, and the drive pin 151a is at the right end of the long hole 100e. Further rotation is restricted in contact with.
Furthermore, after a predetermined time has elapsed since the activation of the first electromagnetic drive source 140, as shown in FIG. 10, the first electromagnetic drive source 160 rotates forward (rotates counterclockwise) by energizing the coil 162, As shown in FIG. 9, the rear blade 130 travels to the closed position. Thereafter, the drive pin 161a abuts against the other end of the long hole 100j, and further rotation is restricted, and the energization to the coil 162 is cut off. At this time, the holding force of the first electromagnetic drive source 160 is acting in a direction to hold the rear blade 130 in the closed position.
By the traveling of the leading blade 120 and the traveling of the trailing blade 130, the exposure operation is performed and the photographing is completed.
[0035]
Thereafter, reverse energization of the coil 142 causes the first electromagnetic drive source 140 to reversely rotate (rotate clockwise), and as shown in FIG. 6, the leading blade 120 again travels to the closed position, and the drive pin 141a Is in contact with one end of the long hole 100d, further rotation is restricted, the leading blade 120 is stopped, and the coil 142 is de-energized.
Further, in order to maintain the closed state of the opening 10a, the first electromagnetic drive source 160 is reversed (clockwise) by the reverse energization of the coil 162 with a slight delay from the reverse energization of the coil 142. 6, the rear blade 130 again travels to the open position, the drive pin 161 a abuts against one end of the long hole 100 j, and further rotation is restricted, and the rear blade 130 stops. Then, the power supply to the coil 162 is cut off.
[0036]
Further, simultaneously with the stop of the leading blade 120, the coil 152 is energized in the reverse direction, so that the second electromagnetic drive source 150 rotates in the reverse direction (rotates clockwise), and the drive pin 151a contacts the first driven portion 125a. In contact therewith, the leading blade 120 is pressed slightly toward the closed position and further rotation is restricted, and the coil 152 is de-energized.
Thus, the leading blade 120 is reliably held in the closed position by the holding force of the first electromagnetic driving source 140 and the biasing force of the second electromagnetic driving source 150, and the trailing blade 130 is held by the first electromagnetic driving source 160. The holding force and the urging force of the spring 170 are securely held in the open position, and a standby state is established. In the subsequent photographing, the above sequence is repeated.
[0037]
In both the above embodiments, an example in which the camera shutter device is applied as an exposure shutter device has been described. However, the present invention is not limited to this. For example, in a range finder camera, the front of the exposure shutter device is used. It can also be applied as a light shielding shutter device by being arranged on the (subject side).
In this case, the light-shielding shutter device is less susceptible to impact and the like, and the exposure start position of the open edge of the shutter blade is constant for each release, so that the light-shielding shutter device starts the opening operation, The timing at which the exposure shutter device starts exposure after opening the opening is preferably obtained.
Furthermore, since the light-blocking shutter device and the exposure shutter device are linked by electrical control rather than by a mechanical mechanism, the number of parts is reduced as compared with the case of using the mechanical mechanism, and the shutter device is manufactured. In this case, the adjustment man-hours can be reduced and the cost can be reduced.
[0038]
In addition, the shutter blades in each embodiment are each composed of a plurality of blades, but it is not always necessary to have such a configuration, and each shutter blade may be composed of one blade.
In addition, the first pushed portion and the second pushed portion are provided on either the support arm or the shutter blade. However, the first pushed portion is provided on the support arm, and the second pushed portion is provided. The part may be provided on the shutter blades, and each pressed part may be provided in the opposite manner.
[0039]
【The invention's effect】
As described above, according to the camera shutter device of the present invention, the light-shielding means is securely closed in a standby state such as waiting for photographing while reducing the cost by simplifying the structure and reducing the number of parts. Can be held in. Further, the light shielding means can be positioned at the exposure start position, and the light shielding means can be made to travel stably.
[Brief description of the drawings]
FIG. 1 is a plan view showing a state where a shutter blade is in a closed position, showing an embodiment of a camera shutter device according to the present invention.
FIG. 2 is a plan view illustrating a camera shutter device according to an embodiment of the present invention, in which a shutter blade is in a state immediately before traveling.
FIG. 3 is a plan view showing a shutter device for a camera according to an embodiment of the present invention and showing a state where shutter blades are in an open position.
FIG. 4 is a time chart for explaining the operation of the camera shutter device.
5A and 5B show another embodiment of the camera shutter device according to the present invention, in which FIG. 5A is a plan view showing a state in which the shutter blades are in an open position, and FIG. It is a top view which shows a state.
FIG. 6 shows another embodiment of the camera shutter device according to the present invention, and is a plan view showing a state in which the leading blade is in the closed position and the trailing blade is in the open position.
FIG. 7 shows another embodiment of the camera shutter device according to the present invention, and is a plan view showing a state immediately before the leading blade travels.
FIG. 8 shows another embodiment of the camera shutter device according to the present invention, and is a plan view showing a state in which a leading blade has traveled to an open position.
FIG. 9 shows another embodiment of the camera shutter device according to the present invention, and is a plan view showing a state where a rear blade has traveled to a closed position.
FIG. 10 is a time chart for explaining the operation of the camera shutter device.
[Explanation of symbols]
10a opening
20 Shutter blade
21, 22, 23 feathers
24 Drive arm
24a long hole
25 Support arm
25a First driven part
25b Second driven part
30 First electromagnetic drive source
31a Drive pin (output part)
40 Second electromagnetic drive source
41a Drive pin (output part)
50 Spring
100a opening
120 Leading blade (shutter blade)
121, 122, 123 feathers
124 Drive arm
124a long hole
125 Support arm
125a First driven part
125b Second driven part
130 Rear blade (shutter blade)
131,132,133 blades
134 Drive arm
134a long hole
135 Support arm
140 First electromagnetic drive source
141a Drive pin (output unit)
150 Second electromagnetic drive source
151a Drive pin (output unit)
160 First electromagnetic drive source
161a Drive pin (output unit)
170 Spring

Claims (6)

A light-shielding means comprising at least one shutter blade, a drive arm that supports the shutter blade, and a support arm. The light-shielding means is provided so as to be able to travel between an open position for opening the opening for exposure and a closed position for closing. When,
A first electromagnetic drive source that exerts a driving force directly on the light shielding means when energized and generates a holding force that holds the light shielding means in the closed position when not energized;
Wherein when the light blocking means is in said closed position, has a second electromagnetic drive source for restricting the movement has a direct biasing force in the same direction as the holding force against the shielding means,
A shutter device for a camera. The second electromagnetic drive source is:
Wherein immediately before the shielding means travels to the open position from the closed position, exerts a direct biasing force in a direction which antagonizes the holding force of the first electromagnetic drive source for said light blocking means,
The camera shutter device according to claim 1. The second electromagnetic drive source is formed to generate the urging force in a non-energized state.
3. The camera shutter device according to claim 1, wherein the shutter device is a camera shutter device. The light shielding means that directly engages with the second electromagnetic drive source is the support arm or the shutter blade,
In the support arm or the shutter blade,
A first driven portion that is engaged and pushed by an output portion that outputs a biasing force of the second electromagnetic drive source when in the closed position;
A second driven part that is engaged and pushed by an output part that outputs the urging force of the second electromagnetic drive source immediately before traveling from the closed position to the open position;
The camera shutter device according to any one of claims 1 to 3. The second electromagnetic drive source includes
A spring that exerts an urging force in a direction in which the light shielding means is positioned in the closed position;
The camera shutter device according to claim 1, wherein the shutter device is a camera shutter device. The shading means is
A leading blade and a trailing blade pivoted by two sets of the drive arm and the support arm;
The second electromagnetic drive source is:
Arranged to exert a biasing force on at least the leading blade,
The camera shutter device according to claim 1, wherein the shutter device is a camera shutter device.

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