JP3756573B2 - Camera drive unit - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a driving device for an operation member such as a light shielding blade incorporated in a camera. More specifically, the present invention relates to a pulse energization control technique for a pulse motor used as a power source for a camera drive device.
[0002]
[Prior art]
In general, a camera driving device includes a base plate having an opening, an operating member such as a light-shielding blade arranged to be movable with respect to the opening, a pulse motor arranged around the opening and driving the operating member, And a drive circuit for supplying a pulse to the pulse motor. FIG. 12 shows a general configuration of a conventional camera driving device. The pulse motor is composed of a rotor composed of a multi-pole magnetized permanent magnet, an iron core (yoke) facing the peripheral surface, and a coil wound around the iron core. For example, two U-shaped yokes are used as the iron core, and coils A and B are wound around each. In order to energize these coils A and B with pulses, two systems of drive circuits 21A and 21B are provided. These drive circuits 21A and 21B are controlled by a control circuit 22 comprising a CPU or the like. One drive circuit 21A is composed of four transistors TR1 to TR4, and is on / off controlled by the control circuit 22 to energize one coil A with pulses. The drive circuit 21A is provided between the power supply line Vcc and the ground line GND. When TR1 and TR4 are turned on and TR2 and TR3 are turned off, a positive pulse is applied to coil A. On the contrary, when TR2 and TR3 are turned on and TR1 and TR4 are turned off, the negative pulse is energized to the coil A. Similarly, the drive circuit 21B corresponding to the coil B is composed of four transistors TR5 to TR8. By controlling on / off of these transistors, a positive pulse or a negative pulse is applied to the coil B. Can do. In addition, by changing the relative phase of the pulses applied to the coils A and B, the rotation of the pulse motor can be switched between the forward direction and the reverse direction.
[0003]
[Problems to be solved by the invention]
As described above, the conventional camera drive device is provided with the two systems of drive circuits 21A and 21B, and each of the coils A and B is independently pulse-energized. However, current consumption increases when both of the pair of coils are energized. For this reason, the replacement frequency of the battery built in as a power supply becomes high, and there exists a subject that a user's burden increases. In addition, the configuration of the drive circuit is complicated because two coils are energized. Therefore, the number of pins for connecting the drive circuit and the control circuit increases. In some cases, the number of pins provided in the control circuit 22 is insufficient, and an external component may be necessary to compensate for this. For this reason, an extra electrical space must be provided. In addition, the capacity of software used for controlling the two drive circuits is increased. Furthermore, since the conventional pulse motor generally uses a U-shaped yoke, a space for storing it is required. The above has a problem that it has become a major obstacle to the recent trend toward miniaturization and cost reduction of cameras.
[0004]
[Means for Solving the Problems]
In order to solve the above-described problems of the conventional technology, the following measures were taken. That is, the camera drive device according to the present invention has, as a basic configuration, a ground plane having an opening, an operation member that is movably arranged with respect to the opening, and an operation member that is arranged around the opening. A pulse motor for driving the member and a drive circuit for energizing the pulse motor with a pulse are provided. As a characteristic matter, the pulse motor has a rotor composed of permanent magnets magnetized with four or more poles, and a single pole that is arranged on the left and right of a straight line passing through the opening and the rotor and that faces the circumferential surface of the rotor. A pair of iron cores provided, and a pair of coils wound around the pair of iron cores, respectively. Further, the drive circuit has a system of output terminals provided in common for the pair of coils. When this output terminal is switched to rotate the rotor in the forward direction, only one coil is pulsed. When energized and driven to rotate in the reverse direction, only the other coil is energized with a pulse.
[0005]
Specifically, a switch is provided for switching the output terminal of the drive circuit for the pair of coils. The actuating member is a blade member capable of shielding the opening, and reciprocates between a fully closed position and a fully opened position in accordance with forward rotation and reverse rotation of the pulse motor. In this case, detection means for detecting the position of the blade member and switching the rotation direction of the pulse motor is provided. The detecting means is the blade member. All of Detect open position. The detection means is a micro switch that mechanically detects the position of the blade member. Alternatively, the detection means may be a photoelectric switch that optically detects the position of the blade member. The photoelectric switch is composed of a combination of a light receiving element fixed to the ground plane side and a pair of movable pieces provided on a driving member that connects between the blade member and the pulse motor. The position of the blade member is detected based on the difference between the output when matched with the element and the output when the other movable piece is matched with the light receiving element. The pair of movable pieces have different reflection amounts. In addition, the said detection means may serve also as the detection of the rest position of this blade member.
[0006]
According to the present invention, the pulse motor uses a new structure iron core having a single pole instead of a U-shaped iron core having a conventional bipolar structure. Using a pair of iron cores with a single pole structure, a rotor composed of permanent magnets magnetized to four or more poles is rotated in both directions. By adjusting the relative positional relationship between the pair of monopolar iron cores and the rotor, the rotor can be driven only by energization on one side. Also, by selecting the iron core to be energized, the rotation of the rotor can be switched between the forward direction and the reverse direction. In view of this point, in the present invention, the pulse motor is driven by only one system of drive circuits provided in common for the pair of coils. That is, by switching a single drive circuit, a pulse is energized only to one coil when the rotor is driven to rotate in the forward direction, and a pulse energization is performed only to the other coil when the rotor is rotated in the reverse direction. With this configuration, the structure of the pulse motor itself can be made compact, and the peripheral drive circuit configuration can be simplified.
[0007]
DETAILED DESCRIPTION OF THE INVENTION
The best mode for carrying out the present invention will be described below in detail with reference to the drawings. FIG. 1 is a block diagram showing a basic configuration of a camera drive device according to the present invention. This camera drive device basically has a base plate having an opening, an operating member such as a light-shielding blade arranged so as to be movable with respect to the opening, and is arranged around the opening to drive the operating member. And a drive circuit for supplying a pulse to the pulse motor. FIG. 1 shows a pulse motor and a drive circuit 21.
[0008]
The pulse motor includes a rotor 6 composed of permanent magnets magnetized with four or more poles, and a single unit that is disposed on the left and right of an opening (not shown) and a straight line passing through the rotor 6 and faces the circumferential surface of the rotor 6. A pair of iron cores 9 each having a pole and a pair of coils 10 wound around the pair of iron cores 9 are configured. The coil 10 is fitted on the bobbin 11. In this example, the rotor 6 is magnetized into four poles each having two N and S poles. Therefore, the peripheral surface of each pole is opposed to the magnetic pole portion 9a of the iron core 9 in a 90 ° angle range. On the other hand, the magnetic pole portion 9a only has an opposing surface in an angle range narrower than 90 °, and the two magnetic pole portions 9a rotate the rotor 6 with respect to one magnetic pole portion and the other magnetic pole portion. They are arranged so that they are slightly rotated with respect to the center. With the arrangement configuration of the magnetic pole portion 9a, the stable position of the rotor 6 is defined, and the rotation direction when one iron core is excited can be defined. The coil 10 is wound around a winding portion 9 b that is bent vertically from the magnetic pole portion 9 a of the iron core 9.
[0009]
On the other hand, the drive circuit 21 has one system of output terminals provided in common for the pair of coils 10 and 10. By switching the output terminal, when the rotor 6 is driven to rotate in the forward direction (counterclockwise in the figure), a pulse is energized only to the right coil 10 (hereinafter sometimes referred to as coil A), and the reverse direction. When rotating in the clockwise direction (in the example shown in the figure), a pulse is energized only to the left coil 10 (hereinafter also referred to as coil B). A switch 23 for switching the output terminal of the drive circuit 21 with respect to the pair of coils 10 is provided. The drive circuit 21 is connected between the power supply line Vcc and the ground line GND, and includes four transistors TR1 to TR4. On / off of these transistors TR1 to TR4 is controlled by a control circuit 22 comprising a CPU or the like. In the figure, the switch 23 is turned on the right coil A side. Therefore, the drive circuit 21 of one system energizes only the coil A to rotate the rotor 6 in the forward direction (counterclockwise). Specifically, by turning on / off the transistors TR1 to TR4, a positive pulse and a negative pulse are alternately applied to the coil A to perform forward step driving of the rotor 6. When TR1 and TR4 are turned on and TR2 and TR3 are turned off by the control circuit 22, a positive pulse is applied to the coil A. Conversely, when TR2 and TR3 are turned on and TR1 and TR4 are turned off, a negative pulse is applied to coil A. Similarly, when the switch 23 is turned on to the left coil B, the drive circuit 21 of one system energizes only the coil B, and by alternately energizing the positive and negative pulses, the rotor 6 Steps in the reverse direction (clockwise).
[0010]
FIG. 2 is a schematic diagram showing a specific operation when the rotor 6 is rotated counterclockwise. (A) has shown the state which is not supplying with electricity to the coil 10 on either side. At this time, the rotor 6 is pulled clockwise with the right N pole in a positional relationship with the right magnetic pole portion 9a. Conversely, the left N pole is pulled counterclockwise due to the positional relationship with the left magnetic pole portion 9a. The rotor 6 is kept in a very stable state by the balance between the two.
[0011]
When a positive pulse current is applied to the right coil A in this state, an N pole appears in the right magnetic pole portion 9a as shown in FIG. On the other hand, since the left magnetic pole portion 9a is connected to the right magnetic pole portion 9a via a support member (not shown), a weak S pole appears on the left magnetic pole portion 9a. For this reason, the rotor 6 rotates counterclockwise and temporarily stops because the magnetic force balance occurs at the position (c).
[0012]
Next, when a negative polarity pulse is applied to the coil A in the state (c), the S pole appears in the right magnetic pole portion 9a and the N pole is weak in the left magnetic pole portion 9a as shown in (d). Appear. Therefore, the rotor 6 further rotates counterclockwise and stops at the position (e). Thereafter, the rotor 6 continues to rotate stepwise by energizing positive and negative pulses alternately.
[0013]
FIG. 3 schematically shows the reverse (clockwise) rotation operation of the rotor 6. (A) shows a state in which no pulse is supplied to any of coils A and B. This state is substantially the same as that of the rotor 6 shown in FIG. 2A and is in a stable position. When a positive pulse is applied to the left coil B from this state, an N pole appears at the left magnetic pole portion 9a and an S pole appears weakly at the right magnetic pole portion 9a as shown in FIG. Therefore, the rotor 6 rotates in the reverse direction (clockwise) as indicated by the arrow.
[0014]
The rotor 6 is temporarily stopped at the position (c). When a negative polarity pulse is further applied to the coil B in this state, an S pole appears on the left magnetic pole portion 9a as shown in (d). The N pole appears weakly on the right magnetic pole portion 9a. Therefore, the rotor 6 further rotates clockwise and stops at the position (e).
[0015]
FIG. 4 shows another embodiment of the camera drive device according to the present invention. Parts corresponding to those in the embodiment shown in FIG. 1 are given corresponding reference numerals for easy understanding. The drive circuit 21 is composed of six transistors TR1 to TR6, and is one system as in the previous embodiment. On / off of these transistors TR1 to TR6 is controlled by the control circuit 22 in accordance with a predetermined sequence. In the present embodiment, the camera drive device drives the blade member capable of shielding the opening of the base plate as an operating member. The blade member reciprocates between the fully closed position and the fully open position in accordance with the forward rotation and reverse rotation of the pulse motor. Detection means 24 for detecting the position of the blade member and switching the rotation direction of the pulse motor is provided. In this embodiment, the detection means 24 is composed of a photoelectric switch that optically detects the position of the blade member. This photoelectric switch is a combination of a light receiving element 24a and a light emitting element 24b, and is called a so-called photocoupler. The control circuit 22 controls on / off of the transistors TR1 to TR6 included in the drive circuit 21 in accordance with the output from the light receiving element 24a, and energizes only one of the coils A and B on one side. For example, when the coil A is energized with pulses, TR5 and TR6 are always in the off state. A positive pulse can be applied to the coil A by turning on TR1 and TR4 and turning off TR2 and TR3. Conversely, a negative pulse can be applied to coil A by turning on TR2 and TR3 while turning off TR1 and TR4. On the other hand, when the coil B is energized, TR1 and TR2 are always turned off. A positive pulse can be applied to the coil B by turning on TR3 and TR6 and turning off TR4 and TR5. Conversely, a negative pulse can be applied to the coil B by turning on TR4 and TR5 and turning off TR3 and TR6.
[0016]
Next, a specific configuration example of the camera drive device according to the present invention will be described with reference to FIGS. 5 and 6. In this embodiment, the present invention is applied to a driving mechanism of a diaphragm blade for a single-lens reflex camera. FIG. 5 is a plan view partially showing a perspective view, and FIG. 6 is a cross-sectional view of the main part of FIG. FIG. The configuration of the present embodiment will be described with reference to FIGS. The ground plate 1 having a circular outer shape is made of a synthetic resin, and a circular opening 1a is formed at the center of the ground plate 1 around the optical axis. A cover plate 2 (FIG. 6) having substantially the same shape is attached to the back side of the base plate 1, that is, the film side. Although not shown, an opening having substantially the same shape as the opening 1a is formed at the center of the cover plate 2. These openings form exposure openings for introducing subject light into the film surface. Three blades 3 are accommodated in a blade chamber formed between the base plate 1 and the cover plate 2 and are rotatably attached to the pins 1 b of the base plate 1. However, for simplicity of illustration, only one of the three diaphragm blades 3 is shown. In FIG. 5, the fully open position of the aperture blade 3 is indicated by a dotted line, while the fully closed position (closed position) is indicated by a one-dot chain line. The drive ring 4 constituting the drive member is fitted into the circular groove 1d in a state where the notches 4a formed at three positions are aligned with the retaining portions 1c formed on the base plate 1. The drive ring 4 is rotatable around the optical axis. Three pins 4 b provided on the drive ring 4 pass through a hole 1 e formed in an arc shape in the base plate 1 and a cam hole 3 a formed in the diaphragm blade 3. The tip of the pin 4b is further fitted into a groove 2a formed in an arc shape in the cover plate 2. The motor frame 5 is made of synthetic resin. By fitting two pins 5a into the holes 1f of the base plate 1 and engaging two flexible hook portions 5b with the locking portions 1g of the base plate 1, Attached to the main plate 1. The two pins 5c provided on the surface side of the motor frame 5 are for attaching a printed wiring board (not shown).
[0017]
A rotor 6 having permanent magnets magnetized in four poles is supported by a base plate 1 and a motor frame 5 as shown in FIG. 6, and a tooth portion 6a is formed below a shaft made of synthetic resin. Recently, a rotor is also known in which particles of a magnetic material are mixed into a synthetic resin material, and the entire portion including the tooth portion 6a is manufactured by a single molding process. Instead of the rotor 6 of the present embodiment, such an integrally molded rotor 6 may be adopted. A parent-child gear 8 is rotatably attached to a shaft 7 that is caulked to the main plate 1. The master gear meshes with the tooth portion 6 a of the rotor 6, while the slave gear meshes with the tooth portion 4 c of the drive ring 4.
[0018]
Two iron cores 9 are divided symmetrically on the left and right sides of a straight line connecting the rotation axis of the rotor 6 and the optical axis. As shown in FIG. 6, each iron core 9 has one magnetic pole portion 9a extending perpendicular to the optical axis and a winding portion 9b extending parallel to the optical axis. Further, as shown in FIG. 5, a protruding portion 9c is formed in the vicinity of the magnetic pole portion 9a, and a coupling portion 9d is formed at the tip of the winding portion 9b. A bobbin 11 around which a coil 10 is wound is fitted in each winding portion 9b. Each overhanging portion 9 c is fitted in a groove 1 h formed in the thick portion of the ground plate 1, and each magnetic pole portion 9 a is opposed to the circumferential surface of the rotor 6. Both the iron cores 9 are connected to each other by fitting each coupling portion 9d into a hole of a support member 12 made of a magnetic material. Further, the two pins 5d provided on the motor frame 5 and the bearing portion of the rotor 6 are fitted into holes formed in the support member 12, respectively, and the support member 12 and each iron core 9 are fixed. Yes.
[0019]
The blade 6 reciprocates between the fully closed position and the fully opened position in accordance with forward rotation and reverse rotation of the rotor 6 of the pulse motor via the drive ring 4. In this embodiment, a detecting means 24 for detecting the position of the blade 3 and switching the rotation direction of the pulse motor is provided. This detection means 24 detects the substantially fully closed position and the fully open position of the blade 3. The detection means 24 is composed of a photoelectric switch that optically detects the position of the blade 3. This photoelectric switch is composed of a combination of a light receiving element 24a fixed to the base plate 1 side and a pair of movable pieces 24d and 24e provided on a drive ring 4 connecting the blade 3 and the pulse motor. The position of the blade 3 is detected based on the difference between the output when one movable piece 24d is aligned with the light receiving region 24c of the light receiving element 24a and the output when the other movable piece 24e is aligned with the light receiving region 24c. The shape or surface reflectivity of the pair of movable pieces 24d and 24e is set so that the reflection amounts are different from each other. The detection means 24 also serves to detect a rest position (for example, a fully closed position) of the blade 3.
[0020]
The operation of the driving apparatus according to the present embodiment will be described in detail with reference to FIGS. This embodiment is an aperture opening / closing mechanism of a single-lens reflex camera as already described. In such an aperture opening / closing mechanism, it is usual to narrow down the aperture blade 3 as a measure for preventing light leakage from the focal plane shutter when the camera is not used. In this embodiment, a type in which the opening for exposure is completely closed is shown. However, the present invention is not limited to such a type, and can be applied to a type in which only the minimum aperture position is closed. It is. Alternatively, the present invention can be applied to a type in which the exposure opening is fully opened when the camera is not used.
[0021]
In the present embodiment, the initial position (rest position) of the diaphragm blade 3 is the fully closed position of the alternate long and short dash line shown in FIG. Therefore, in this initial state, the drive ring 4 is in a position rotated clockwise from the position shown in FIG. When the power switch is turned on from such a closed state (fully closed state) prior to photographing, the right coil 10 (coil A) is energized with pulses, and the rotor 6 rotates in the forward direction (counterclockwise). This rotation is decelerated from the tooth portion 6 a via the parent gear 8 and transmitted to the drive ring 4. For this reason, the drive ring 4 rotates counterclockwise, and the aperture blade 3 fully opens the opening 1a. The position of the aperture blade 3 stopped in the fully opened state is shown by a dotted line in FIG.
[0022]
As shown in FIG. 5, in the fully opened state, the subject light guided to the finder by the mirror is maximized, so that the subject image is easy to see. Next, when the shutter is released, a shutter blade (not shown) is opened and closed. In this embodiment, before that, the left coil 10 (coil B) is energized with a pulse before and after the mirror is raised, and the rotor 6 is rotated in the reverse direction (clockwise). This rotation is transmitted to the drive ring 4 via the parent-child gear 8 and rotates the drive ring 4 in the clockwise direction. Therefore, the diaphragm blade 3 gradually narrows the opening area of the opening 1a and stops at a predetermined aperture position.
[0023]
The size of the aperture at this time may be selected in advance by the photographer or may be automatically determined. Thereafter, the shutter blades are opened and closed to perform photographing. When the operation of the shutter blade is completed, the mirror returns to the original position. At the same time, the coil A is energized with pulses, and the rotor 6 rotates in the forward direction (counterclockwise). For this reason, the aperture blade 3 is opened via the drive ring 4 and stops in the fully open state shown by the dotted line in FIG. Therefore, the next shooting can be continued. When canceling such a shooting standby state without performing the next shooting, the power switch of the camera is turned off. At this time, the rotor 6 rotates in the reverse direction (clockwise), and the aperture blade 3 completely closes the opening 1a and stops at the position indicated by the alternate long and short dash line.
[0024]
FIG. 7 is a time chart showing the relationship between the rotation of the pulse motor and the aperture opening. When the positive pulse and the negative pulse are alternately supplied to the coil A in a state where the diaphragm blade is in the rest position (fully closed position), the diaphragm blade travels stepwise from the fully closed position toward the fully opened position. When the detection means detects that the aperture blade has reached the fully open position, the pulse energization is switched from the coil A side to the coil B side. As a result, the diaphragm blades travel from the fully open position toward the fully closed position. A desired F value can be obtained by stopping the pulse energization to the coil B at an intermediate stage. Thus, according to the present embodiment, the opening operation is performed on the diaphragm blades by energizing the positive and negative pulses to the coil A, and the closing operation is performed on the diaphragm blades by energizing the positive and negative pulses to the coil B. It is something to be done. In either operation, the power consumption is almost half compared to the case where both coils are energized at the same time. When a single 3V lithium battery needs to be used like a recent camera, Is extremely effective. In the description of this embodiment, the description has been made on the assumption that the rotor is in a stable state even when the coil is not energized. However, there may be a case where the rotor may not be in a predetermined position due to an unexpected cause. If there is such a concern, for example, in the state of FIG. 2 (a), the coil A is first energized with a negative pulse to generate an S pole in the magnetic pole part of the right iron core, and the rotor is initialized. Positioning is surely performed at the position, and then, as shown in FIG. 2 (b), a positive pulse current is applied to rotate counterclockwise. Similarly, when rotating clockwise, in the state of FIG. 3A, first, the coil B is first pre-energized to generate the S pole in the magnetic pole part of the left iron core, and the rotor is brought to the initial position. After positioning with certainty, it may be rotated as shown in FIG.
[0025]
Further, although the above embodiment has been described in the case where the present invention is applied to the diaphragm blade driving mechanism, the present invention can also be applied to the shutter blade driving mechanism. Further, the drive member in the present invention is not limited to the ring member, and may be a lever member or a link member. Further, in the embodiment, the output of the rotor is taken out by a gear, but it may be taken out by a cam member such as an eccentric cam.
[0026]
FIG. 8 is a schematic partial plan view showing a specific configuration example of the detection means 24. When the aperture blade is in the fully open position, one movable piece 24d is aligned with the light receiving region 24c of the light receiving element 24a. The movable piece 24d has a large area, and the light receiving region 24c is largely shielded from light. On the other hand, when the drive ring 4 rotates counterclockwise and the light shielding blade reaches the fully closed position, the other movable piece 24e is aligned with the light receiving region 24c. The movable piece 24e has a small area, and the light shielding area of the light receiving region 24c is reduced.
[0027]
FIG. 9 is a graph showing the output voltage of the light receiving element 24a. In the fully open state, the light receiving region 24c is largely covered with the movable piece 24d, so that the output voltage is low. On the other hand, in the fully closed state, the light receiving region 24c is covered with a relatively small movable piece 24e, and thus the output voltage rises. By detecting the difference in output voltage between the fully open state and the fully closed state, the current position of the light shielding blade can be detected.
[0028]
FIG. 10 is a schematic partial plan view showing a modification of the detection means 24 shown in FIG. In this modification, the pair of movable pieces 24d and 24e have different surface reflectivities, and the output voltage of the light receiving element 24a varies accordingly.
[0029]
FIG. 11 is a schematic plan view showing another example of the detection means 24. In this example, the detection means 24 comprises a microswitch 24f, and mechanically detects the position of the light shielding blade. That is, the microswitch 24f is switched by the movable pieces 24d and 24e corresponding to the fully open position and the fully closed position of the light shielding blade. Such a micro switch 24f can be used as the switch 23 shown in FIG.
[0030]
【The invention's effect】
As described above, according to the present invention, when the drive circuit has one output terminal provided in common for the pair of coils and the output terminal is switched to rotate the rotor in the forward direction. Only one coil is energized with a pulse, and when rotating in the opposite direction, only the other coil is energized with a pulse. Since both sides energization is adopted instead of simultaneous energization as in the prior art, the current consumption can be reduced and the battery life can be increased. In addition, since the configuration of the drive circuit can be simplified, the circuit configuration can be reduced accordingly, and the manufacturing cost of the circuit can be reduced.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a basic configuration of a camera drive device according to the present invention.
FIG. 2 is a schematic diagram for explaining the operation of the pulse motor shown in FIG. 1;
FIG. 3 is a schematic diagram for explaining the operation of the pulse motor.
FIG. 4 is a circuit diagram showing another embodiment of the camera drive device according to the present invention.
FIG. 5 is a plan view showing an embodiment of a camera drive device according to the present invention.
FIG. 6 is a partial sectional view showing an embodiment of a camera drive device according to the present invention.
7 is a timing chart for explaining the operation of the pulse motor incorporated in the embodiment shown in FIGS. 5 and 6. FIG.
8 is a partial plan view showing a specific configuration example of detection means incorporated in the embodiment shown in FIGS. 5 and 6. FIG.
FIG. 9 is a graph for explaining the operation of the detection means shown in FIG.
FIG. 10 is a partial plan view showing another example of detection means.
FIG. 11 is a partial plan view showing another example of detection means.
FIG. 12 is a circuit diagram showing an example of a conventional camera drive device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Base plate, 1a ... Opening part, 3 ... Diaphragm blade, 6 ... Rotor, 9 ... Iron core, 10 ... Coil, 21 ... Drive circuit, 22 ... Control circuit, 23 ... Switch, 24 ... Detection means

Claims (9)

A ground plane having an opening, an operating member arranged to be movable with respect to the opening, a pulse motor arranged around the opening and driving the operating member, and a drive for energizing the pulse motor with a pulse In a camera drive device comprising a circuit,
The pulse motor includes a rotor composed of permanent magnets magnetized with four or more poles, and a pair of single poles arranged on the left and right sides of a straight line passing through the opening and the rotor, each facing a circumferential surface of the rotor. And a pair of coils wound respectively around the pair of iron cores,
The drive circuit has a single output terminal provided in common for the pair of coils, and when the output terminal is switched to rotate the rotor in the forward direction, only one coil is energized. A camera driving device characterized in that, when rotationally driven in the reverse direction, a pulse is applied only to the other coil.   2. The camera drive device according to claim 1, further comprising a switch for switching an output terminal of the drive circuit for the pair of coils.   The actuating member is a blade member capable of shielding the opening, and reciprocates between a fully closed position and a fully opened position in accordance with forward rotation and reverse rotation of the pulse motor, and the position of the blade member is changed. 2. The camera driving device according to claim 1, further comprising detection means for detecting and switching the rotation direction of the pulse motor. The detection means able to detect the full open position according to claim 3 camera driving device, wherein the the vane member.   4. The camera driving device according to claim 3, wherein the detecting means is a micro switch that mechanically detects the position of the blade member.   4. The camera driving device according to claim 3, wherein the detecting means is a photoelectric switch for optically detecting the position of the blade member.   The photoelectric switch is composed of a combination of a light receiving element fixed to the ground plane side and a pair of movable pieces provided on a driving member that connects between the blade member and the pulse motor. 7. The camera driving device according to claim 6, wherein the position of the blade member is detected based on a difference between an output when matched with the element and an output when the other movable piece is matched with the light receiving element. .   The camera drive device according to claim 7, wherein the pair of movable pieces have different reflection amounts.   4. The camera driving device according to claim 3, wherein the detecting means also serves to detect a rest position of the blade member.

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