JP2013114169A - Imaging apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an imaging apparatus having a camera shake correction mechanism with a slim configuration.SOLUTION: An imaging apparatus 100 comprises a camera shake correction mechanism 9 which corrects a camera shake by moving an imaging element 81 with respect to a lens unit 7. The imaging apparatus further comprises: a plurality of plates 50, 60, 70 connecting the imaging element 81 and the lens unit 7 so as to be movable in a yz-direction and each having an opening 8 for guiding light from the lens unit 7 to the imaging element 81; a first actuator 91 provided outside the opening 8 on one end side of the opening 8 and moving the imaging element 81 in a z-direction; and a second actuator 92 provided outside the opening 8 in the other end side of the opening 8 opposed to the one end, and moving the imaging element 81 in a y-direction.

Description

  The present invention relates to an imaging apparatus, and more particularly to an imaging apparatus having a camera shake correction mechanism.

  Some imaging apparatuses such as digital cameras have a camera shake correction function. For example, a method of performing camera shake correction by moving an image sensor with respect to a lens is disclosed (Patent Document 1). In such a camera shake correction mechanism, it is required to move the image sensor at a high speed so as to follow the camera shake and to move the image sensor with high straightness.

JP 2007-65041 A

  In such a camera shake correction mechanism, the image sensor is moved in a plane. Usually, an actuator for moving the image sensor in two directions is required. In Patent Document 1, two actuators are arranged on one end side of the opening. For example, the actuator is disposed in the vicinity of both corners on one side of the rectangular opening. With this configuration, it is difficult to make the camera shake correction mechanism slim.

  The present invention has been made in view of the above problems, and an object thereof is to provide an imaging apparatus having a camera shake correction mechanism with a slim configuration.

An imaging apparatus (100) according to an aspect of the present invention is an imaging apparatus having a camera shake correction mechanism (9) that performs camera shake correction by moving an image sensor (81) with respect to a lens unit (7). The image sensor (81) and the lens unit (7) are connected to be movable in the first and second directions, and the light from the lens unit (7) is guided to the image sensor (81). A plurality of plates (50, 60, 70) having an opening (8), a first actuator (91) for moving the image sensor (81) in the first direction, and the image sensor (81). ) In the second direction, and in the plan view orthogonal to the optical axis of the lens unit (7), the first actuator (91) and the second actuator (92) Actuator (9 ) And between said opening (8) in which is disposed. As a result, both outer portions of the opening where no actuator is disposed can be saved in space, and the imaging device can be slimmed.
In the imaging apparatus, the plurality of plates include a first plate (base plate 50), a second plate (z plate 60), and a third plate (y plate 70), and the first plate ( The base plate 50) and the second plate (z plate 60) are connected by a first shaft (z shaft 51) along the first direction, and the second plate (z plate 60) and the first plate are connected. Three plates (y plate 70) may be connected by a second shaft (y shaft 61) along the second direction. Thereby, it can be moved in two directions with a simple configuration, and camera shake can be corrected effectively.
In the imaging apparatus, the first actuator (91) includes a first magnet (permanent magnet 41) attached to the first plate (base plate 50) on one end side of the opening, and the first actuator (91). A second coil (z plate 60) and a first coil (63) that moves relative to the first magnet (permanent magnet 41), and the second actuator (92) On the other end side opposite to the one end side of the opening, a second magnet (permanent magnet 31) attached to the first plate (base plate 50) and a third plate (y plate 70) are provided. And a second coil (76) that is attached and moves relative to the second magnet (permanent magnet 41). Thereby, an actuator can be reduced in size and an imaging device can be further reduced in size.
In the imaging apparatus, it is preferable that the first and second actuators (91, 92) are not arranged in a region between the one end and the other end outside the opening. Thereby, it can slim.

  As described above, according to the present invention, it is possible to provide an imaging apparatus having a camera shake correction mechanism with a slim configuration.

It is the perspective view which looked at the composition of the imaging device from the side upper part. It is the perspective view which looked at the imaging device from the side lower part on the monitor part side. It is a perspective view which shows the structure of the camera unit incorporated in the main-body part. It is a perspective view which decomposes | disassembles and shows the lens unit and camera-shake correction mechanism which were provided in the camera unit. It is a perspective view which shows the structure of the camera-shake correction mechanism of the state which removed the rear cover. It is a perspective view which shows the structure of the camera-shake correction mechanism of the state which removed the rear cover and the sensor unit. It is a side view which shows notionally the structure of the camera-shake correction mechanism. It is a top view which shows arrangement | positioning of the z shaft with respect to z plate and a rotation sphere. It is a top view which shows arrangement | positioning of the y shaft and rotating sphere with respect to y plate. It is a top view which shows typically the example of arrangement | positioning of a shaft and a rotation sphere. It is a top view which shows typically the other example of arrangement | positioning of a shaft and a rotation sphere. It is a side view which shows the structure of an upper holder. It is a side view which shows the structure of a lower holder. It is a rear view for demonstrating the position detection mechanism of a camera-shake correction mechanism. It is a rear view for demonstrating the position detection mechanism of a camera-shake correction mechanism. It is a perspective view for demonstrating the position detection mechanism of a camera-shake correction mechanism. It is a perspective view for demonstrating the position detection mechanism of a camera-shake correction mechanism. It is side surface sectional drawing which shows the holding state by an upper holder. It is a top view which shows arrangement | positioning of a coil. It is a top view which shows arrangement | positioning of an actuator. It is a perspective view which shows the structure of a cover unit. It is a disassembled perspective view which shows the structure of a cover unit. It is side surface sectional drawing which shows the structure of a cover unit.

  Embodiments of the present invention will be described below with reference to the drawings. 1 and 2 are perspective views showing an overall configuration of the imaging apparatus 100 according to the present embodiment. FIG. 1 is a perspective view of the imaging device 100 as viewed from the left front, and FIG. 2 is a perspective view of the imaging device 100 as viewed from the right front. In the following description, an xyz orthogonal coordinate system as shown in the figure is used for clarity of explanation.

  Here, the x-axis indicates the front-rear direction of the imaging apparatus 100, the y-axis indicates the up-down direction (vertical direction) of the imaging apparatus 100, and the z-axis indicates the left-right direction (lateral direction) of the imaging apparatus 100. That is, the x direction is a direction parallel to the optical axis of the lens provided in the imaging apparatus 100, and the y direction and the z direction are directions perpendicular to the optical axis of the lens provided in the imaging apparatus 100. Further, in a state where the user grips the imaging device 100 with the lens 6 side facing the subject (object) side, the opposite side to the lens 6 facing the user side, and the operation unit 16 facing upward, the imaging device 100 is The direction is specified based on the gripping user. That is, the + x side is the rear side, the -x side is the front side, the + y side is the upper side, the -y side is the lower side, the + z side is the left side, and the -z side is the right side. Of course, the above directions are relative and change according to the orientation of the imaging apparatus 100.

(overall structure)
As shown in FIGS. 1 and 2, the imaging apparatus 100 includes a main body unit 5, a monitor unit 3, a lens 6, a lens barrier 10, and an operation unit 18. The imaging apparatus 100 has a camera shake correction mechanism.

  The main body 5 has a substantially rectangular parallelepiped shape, and incorporates a lens barrel having a lens 6, a camera shake correction mechanism having an image sensor, a control circuit, a memory, and the like. A lens barrier 10 that covers the lens 6 is provided on the front surface of the main body 5. When the lens barrier 10 is opened, the lens 6 is exposed, and an image can be captured. Further, a lever 17 for switching opening and closing of the lens barrier 10 is provided on the front side of the right side surface of the main body 5. An operation unit 18 having operation buttons and the like is provided on the upper surface of the main body unit 5. The operation unit 18 includes a recording start button, a recording end button, and the like. The user can take an image of the subject by operating the operation unit 18.

  As shown in FIG. 2, the monitor unit 3 is provided on the left side surface of the main body unit 5. The monitor unit 3 is connected to the main body unit 5 via a hinge 4. The monitor unit 3 is attached to the main body unit 5 by the hinge 4 so as to be opened and closed. The monitor unit 3 includes a subject, a stored image data, setting information, a liquid crystal display for displaying other information, and the like. In the state where the monitor unit 3 is opened, the monitor of the monitor unit 3 is arranged facing the rear side, that is, the user side. When the touch panel function is provided, the display of the monitor unit 3 becomes a part of the operation unit.

  The lens 6 guides external light to the image pickup device in the image pickup apparatus 100. The main body 5 is provided with an image sensor, a control circuit, and the like. The imaging device 100 receives light propagating through the lens 6 and images a subject. Further, a battery is housed on the right side surface of the main body unit 5 facing the left side surface on which the monitor unit 3 is provided. The battery is detachably attached to the main body unit 5 and supplies power to the monitor unit 3 and the imaging device of the imaging device 100.

(Configuration of camera shake correction mechanism)
Next, the camera shake correction mechanism housed in the main body 5 will be described with reference to FIGS. FIG. 3 is a perspective view of the camera unit 2 housed in the main body 5 as seen from the rear side. As shown in FIG. 3, the camera unit 2 includes a lens unit 7 having a lens, and a camera shake correction mechanism 9 disposed on the rear side of the lens unit 7. The lens unit 7 includes a lens barrel that holds a plurality of lenses. The camera shake correction mechanism 9 includes an image sensor such as a CMOS sensor or a CCD sensor, and performs camera shake correction by moving the image sensor relative to the lens unit 7.

  FIG. 4 is an exploded perspective view of the camera unit 2. As shown in FIG. 4, the camera shake correction mechanism 9 includes a cover unit 20, an upper holder 30, a lower holder 40, a base plate 50, a z plate 60, a y plate 70, a sensor unit 80, and a rear cover 90. And.

  FIG. 5 is a perspective view showing the camera shake correction mechanism with the rear cover 90 removed as viewed from the rear side. FIG. 6 is a perspective view of the camera shake correction mechanism 9 with the rear cover 90 and the sensor unit 80 removed, as viewed from the rear side.

  As shown in FIG. 4, on the rear side of the lens unit 7, a base plate 50, a z plate 60, and a y plate 70 (plate portion) are arranged in this order. The base plate 50, the z plate 60, and the y plate 70 overlap each other, and the z plate 60 is disposed between the base plate 50 and the y plate 70. The base plate 50, the z plate 60, and the y plate 70 are formed of a resin material.

  The base plate 50, the z plate 60, and the y plate 70 are formed with openings 8 for allowing the light of the lens 6 of the lens unit 7 to pass therethrough (see also FIG. 6). The opening 8 is formed in a rectangular shape. Then, the image sensor of the sensor unit 80 is disposed in the opening 8 (see also FIG. 5). Specifically, the sensor unit 80 is attached to the back side of the y plate 70.

  Furthermore, the cover unit 20 for protecting the image sensor is attached to the sensor unit 80. The cover unit 20 is attached to the front side of the image sensor of the sensor unit 80 and is disposed in the opening 8. That is, the cover unit 20 is disposed between the lens 6 and the sensor unit 80. A rear cover 90 is provided on the back side of the sensor unit 80. The back side of the sensor unit 80 is covered with a rear cover 90. A wiring board 93 and the like to be described later are attached to the rear cover 90.

  The upper holder 30 is disposed on the upper side (+ y side) of the base plate 50, the z plate 60, and the y plate 70, and the lower holder 40 is disposed on the lower side (−y side). The upper holder 30 is disposed above the opening 8, and the lower holder 40 is disposed below the opening 8. Each of the upper holder 30 and the lower holder 40 is attached to the base plate 50. For example, the upper holder 30 can be fitted into the base plate 50 from above, and the lower holder 40 can be fitted into the base plate 50 from below. Each of the upper holder 30 and the lower holder 40 is fixed to the base plate 50. Further, the z plate 60 is sandwiched between the base plate 50 and the y plate 70.

  The base plate 50 is fixed to the lens unit 7. The z plate 60 is attached to the base plate 50 so as to be swingable in the z-axis direction. Specifically, a z shaft 51 extending in the z direction is provided on the back side of the base plate 50. The base plate 50 and the z plate 60 are coupled via the z shaft 51. The z plate 60 slides along the z shaft 51. A rotating sphere 52 is arranged on the back side of the base plate 50. The rotating sphere 52 is disposed between the base plate 50 and the z plate 60. The rotating sphere 52 is disposed on a ball receiver provided on the base plate 50 and rolls in the ball receiver in accordance with the sliding movement of the z plate 60. Thereby, the frictional force generated by the movement of the z plate 60 can be reduced.

  The y plate 70 is attached to the z plate 60 so as to be swingable in the y-axis direction. Specifically, a y shaft 61 extending in the y direction is provided on the back side of the z plate 60. The y plate 70 and the z plate 60 are connected via the y shaft 61. The y plate 70 slides along the y shaft 61. A rotating sphere 62 is disposed on the back side of the z plate 60. The rotating sphere 62 is disposed between the y plate 70 and the z plate 60. The rotating sphere 62 is disposed in a ball receiver provided on the z plate 60 and rolls in the ball receiver in accordance with the sliding movement of the y plate 70. Thereby, the frictional force generated by the movement of the y plate 70 can be reduced.

  As described above, the base plate 50 is fixed to the lens unit 7, and the sensor unit 80 is fixed to the y plate 70. Therefore, when the y plate 70 moves in the y direction with respect to the z plate 60, the position of the sensor unit 80 with respect to the lens 6 changes. Further, when the z plate 60 moves in the z direction with respect to the base plate 50, the position of the sensor unit 80 with respect to the lens 6 changes. The sensor unit 80 moves freely with respect to the lens 6 in the yz plane. The sensor unit 80 swings in a direction in which camera shake of the imaging apparatus 100 is corrected.

  The lower holder 40 is a yoke to which a permanent magnet 41 is attached. On the other hand, the z-plate 60 is provided with a coil 63. The permanent magnet 41 and the coil 63 are arranged to face each other. That is, the permanent magnet 41 and the coil 63 are arranged so as to overlap in the yz plane. Similarly, the upper holder 30 is a yoke to which a permanent magnet 31 is attached, and this permanent magnet 31 is arranged to face a coil (not shown in FIG. 4) provided on the y plate 70. . That is, in the yz plane, the permanent magnet 31 and the coil of the y plate 70 are arranged so as to overlap each other. As will be described later, the permanent magnet 41 and the coil 63 are used as actuators in the z direction, and the permanent magnet 31 and the coil provided on the y plate 70 are used as actuators in the y direction.

  A permanent magnet 42 is attached to the lower holder 40, and a permanent magnet 32 is attached to the upper holder 30. As will be described later, the permanent magnet 42 and the permanent magnet 32 are used for detecting the position of the camera shake correction mechanism 9. A wiring board 93 is attached to the y plate 70, and a wiring board 94 is attached to the z plate 60. The wiring boards 93 and 94 are, for example, an FPC (Flexible Printed Circuit board). The wiring boards 93 and 94 are formed with wirings for coils and position detecting elements.

(Conceptual explanation of operating principle)
Next, the operation of the camera shake correction mechanism 9 will be described with reference to FIG. FIG. 7 is a side view conceptually showing the structure of the camera shake correction mechanism. In FIG. 7, the cover unit 20 and the rear cover 90 are omitted. First, the principle for moving the image sensor 81 will be described. A base plate 50 is fixed to the lens unit 7. An upper holder 30 and a lower holder 40 are attached to the base plate 50.

  The base plate 50 is connected to the z plate 60 via the z shaft 51. A rotating sphere 52 is interposed between the base plate 50 and the z plate 60. The permanent magnet 41 provided on the lower holder 40 is disposed to face the coil 63 provided on the z plate 60. Therefore, the permanent magnet 41 and the coil 63 constitute an actuator. When the voltage supplied to the coil 63 is controlled, the z plate 60 slides in the z direction. Thus, the permanent magnet 41 and the coil 63 of the lower holder 40 function as a motor that moves linearly in the z direction. At this time, the z plate 60 moves linearly along the z shaft 51. Further, the rotating sphere 52 rotates within the ball receiver by the direct movement of the z plate 60. Thereby, the frictional force due to the slide movement is reduced, and a quick movement becomes possible. Since the z shaft 51 is used, the z plate 60 is not substantially displaced in the y direction with respect to the base plate 50. Thereby, the z plate 60 can be moved with good straightness.

  The z plate 60 is connected to the y plate 70 via the y shaft 61. A rotating sphere 62 is interposed between the y plate 70 and the z plate 60. The permanent magnet 31 provided on the upper holder 30 is disposed to face the coil 76 provided on the y plate 70. Therefore, the permanent magnet 31 and the coil 76 constitute an actuator. That is, the permanent magnet 31 and the coil 76 are arranged so as to overlap in the yz plane. Therefore, when the voltage supplied to the coil 76 is controlled, the y plate 70 slides in the y direction. Thus, the permanent magnet 31 and the coil 76 of the upper holder 30 function as a motor that moves linearly in the y direction. At this time, the y plate 70 moves linearly along the y shaft 61. Further, the rotating ball 62 rotates in the ball receiver by the direct movement of the y plate 70. Thereby, the frictional force due to the slide movement is reduced, and a quick movement becomes possible. Since the y shaft 61 is used, the y plate 70 is not substantially displaced in the z direction with respect to the base plate 50. Thereby, the y plate 70 can be moved with good straightness.

Thus, with respect to the base plate 50, the z plate 60 moves in the z direction, and the y plate 70 moves in the y direction. A sensor unit 80 is fixed to the y plate 70. Furthermore, since the z plate 60 and the y plate 70 are movably connected, the y plate 70 is also displaced in the z direction in accordance with the linear movement of the z plate 60 in the z direction. Thereby, the image sensor 81 provided in the sensor unit 80 moves in the yz plane. In other words, the y plate 70 is movably connected to the base plate 50.
Since the rotating sphere 52 is disposed between the base plate 50 and the z plate 60, a gap is generated. The gap communicates with the space outside the lens unit 7 through the space inside the upper holder 30. Similarly, a gap between the z plate 60 and the y plate 70 communicates with a space outside the lens unit 7.

  An opening 8 that penetrates the base plate 50, the z plate 60, and the y plate 70 is disposed on the rear side of the lens 6. Therefore, the light refracted by the lens 6 passes through the opening 8 and enters the image sensor 81. The image sensor 81 freely moves in the opening 8. A sensor provided in the imaging apparatus 100 detects a displacement in the yz direction of the image sensor 81 due to camera shake, and controls a current supplied to the coils 63 and 76 according to the displacement. In this way, camera shake correction can be performed.

  The position of the y plate 70 is detected by the Hall elements 72 and 74. The voltage supplied to the coil 76 and the coil 63 is controlled based on the position detection result. The camera shake correction mechanism 9 can be feedback-controlled, and camera shake correction can be performed effectively. Hereinafter, a configuration for detecting the position of the image sensor 81 will be described.

  A permanent magnet 32 and a permanent magnet 42 are used for position detection. For example, the permanent magnet 32 is fixed to the upper holder 30 so as to face the hall element 74. In the yz plan view, the Hall element 74 and the permanent magnet 32 are arranged to be fixed to the lower holder 40 so as to overlap. The hall element 74 is fixed to the y plate 70 via the suction yoke 73.

  The hall element 74 detects a magnetic field generated by the permanent magnet 32. When the relative position between the permanent magnet 32 and the hall element 74 changes, the detection result of the hall element 74 changes. Therefore, the displacement amount of the y plate 70 relative to the base plate 50 can be detected by the output signal output from the hall element 74. In other words, the hall element 74 detects the position of the image sensor 81.

  Similarly, the permanent magnet 42 is attached to the lower holder 40 so as to face the hall element 72. In the yz plan view, the hall element 72 and the permanent magnet 42 are arranged so as to overlap each other. The hall element 72 detects a magnetic field generated by the permanent magnet 42. When the relative position between the permanent magnet 42 and the hall element 72 changes, the detection result of the hall element 72 changes. Therefore, the displacement amount of the y plate 70 relative to the base plate 50 can be detected by the output signal output from the hall element 72. In other words, the hall element 72 detects the position of the image sensor 81.

  Thus, the Hall elements 72 and 74 detect the relative position of the imaging element 81 with respect to the base plate 50. For example, one of the hall elements 72 and 74 detects the position in the y direction, and the other detects the position in the z direction. That is, the Hall elements 72 and 74 are used as linear position sensors, respectively. The voltage supplied to the coil 63 and the coil 76 is controlled by output signals from the Hall elements 72 and 74. By doing so, it is possible to perform feedback control of the image sensor 81 and to perform camera shake correction more effectively.

  Further, the permanent magnet 32 generates a magnetic force that attracts the suction yoke 73. The y plate 70 is attracted to the base plate 50 by this magnetic force. Thereby, the rotating spheres 52 and 62 are held between the plates.

(Linear guide with shaft and rotating sphere)
As described above, camera shake correction is performed by sliding the z plate 60 and the y plate 70 in the z direction and the y direction, respectively. Hereinafter, a guide mechanism for guiding the slide movement using the y shaft 61, the z shaft 51, the rotating sphere 52, and the rotating sphere 62 will be described. FIG. 8 is a front view showing the configuration of the z plate 60, and shows the z shaft 51 and the rotating sphere 52 together. FIG. 9 is a front view showing the configuration of the y plate 70, and shows the y shaft 61 and the rotating sphere 62 together.

  As shown in FIG. 8, a rectangular opening 60a is provided in the central portion of the z plate 60, and the opening 60a corresponds to the opening 8 described above. Further, two shaft holes 64 are provided on the lower side (−y side) of the opening 60a. The two shaft holes 64 are arranged along the z direction. In the z direction, one of the two shaft holes 64 is disposed on the right side of the opening 60a, and the other is disposed on the left side of the opening 60a.

  And the z shaft 51 along the z direction is inserted into the two shaft holes 64. Of course, the shaft hole 64 is disposed so that the z shaft 51 does not overlap the opening 60a. The z shaft 51 is arranged so as to be shifted in the −y direction from the opening 60a. The z shaft 51 is longer than the opening 60a and protrudes from the opening 60a in the z direction. Similarly, an axial hole for inserting the z shaft 51 is formed on the back side of the base plate 50, and the z shaft 51 is fixed to the base plate 50. Thereby, the base plate 50 and the z plate 60 are connected via the z shaft 51.

  A ball receiver 65 is formed on the upper side (+ y side) of the opening 60a. For example, the ball receiver 65 is formed by forming a tapered recess (V groove) in the z plate 60. A rotating ball 52 is disposed on the ball receiver 65. Although not shown, a similar ball receiver is formed at the position of the rotating ball 52 on the back side of the base plate 50. Within the ball receiver 65, the rotating ball 52 is sandwiched between the base plate 50 and the z plate 60. Between the base plate 50 and the z plate 60, the rotating sphere 52 is rotatably held in the ball receiver 65. Further, a coil 63 for driving the z plate 60 is provided below the z shaft 51. The coil 63 is turned around the x axis as a winding axis. Then, the actuator having the coil 63 moves the z plate 60 in the z direction.

  As shown in FIG. 9, a rectangular opening 70a is provided in the central portion of the y plate 70, and this opening 70a corresponds to the opening 8 described above. Therefore, the opening 60a and the opening 70a are arranged so as to overlap each other. In addition, two shaft holes 77 are provided on the −z side of the opening 70a. The two shaft holes 77 are arranged along the y direction. In the y direction, one of the two shaft holes 77 is disposed above the opening 70a, and the other is disposed below the opening 70a.

  Then, the y shaft 61 along the y direction is inserted into the shaft hole 77. Of course, the shaft hole 77 is arranged so that the z shaft 51 does not overlap the opening 70a. The y shaft 61 is disposed so as to be offset from the opening 70a. The y shaft 61 is longer than the opening 70a and protrudes from the opening 70a in the y direction. Similarly, a shaft hole for inserting the y shaft 61 is formed on the back side of the z plate 60, and the y shaft 61 is fixed. Thereby, the y plate 70 and the z plate 60 are connected via the y shaft 61.

  A ball receiver 75 is formed on the upper side (+ y side) of the opening 70a. For example, the ball receiver 75 is formed by forming a tapered recess (V groove) in the y plate 70. A rotating ball 62 is disposed in the ball receiver 75. Although not shown, a similar ball receiver is formed at the position of the rotating ball 62 on the back side of the z plate 60. The rotating sphere 62 is sandwiched between the y plate 70 and the z plate 60. Between the y plate 70 and the z plate 60, the rotating sphere 62 is rotatably held in the ball receiver 75. Further, a coil 76 for driving the y plate 70 is provided above the opening 60a. The coil 76 is turned around the x axis as a winding axis. Then, the actuator having the coil 76 moves the y plate 70 in the y direction.

  As described above, both the shaft and the rotating sphere are used to guide the unidirectional slide. By doing so, the plate can be moved with good straightness. For example, when only a rotating sphere is used without using a shaft, it is necessary to arrange at least three rotating spheres between the plates. In this case, since the image sensor 81 rotates about one rotating sphere, the straight traveling performance is deteriorated. Furthermore, it becomes necessary to arrange a plurality of mechanisms for holding the plate.

  On the other hand, when only the shaft is used without using the rotating sphere, the shaft is arranged on both sides of the opening. In order to pass the two shafts through the shaft hole, it is necessary to widen the gap between the shaft hole and the shaft. That is, the straight running performance is deteriorated by the gap between the shaft hole and the shaft. As in this embodiment, by using both the shaft and the rotating sphere, it can be moved with good straightness. Thereby, camera shake can be corrected effectively.

Here, the arrangement of the rotating sphere 62 and the rotating sphere 52 will be described with reference to FIG. FIG. 10 is a diagram schematically illustrating a planar arrangement of the rotating sphere 62 and the rotating sphere 52 with respect to the z shaft 51 and the y shaft 61. As shown in FIG. 10, the rotating sphere 52 is disposed on the upper side of the opening 8, and the z shaft 51 is disposed on the lower side. In other words, the opening 8 is disposed between the rotating sphere 52 and the z shaft 51 in the y direction. The rotating sphere 52 is disposed near the center of the z shaft 51 in the z direction. By doing so, straightness in the z direction can be improved. Further, the y shaft 61 is disposed on the left side of the opening 8, and the rotating sphere 62 is disposed on the upper right of the opening 8.
A rotating sphere 52 is disposed between the openings 8 in the z direction. Specifically, the rotating sphere 52 is disposed outside the opening 8 between one end (left end) and the other end (right end) of the opening 8 in the z direction. Thereby, the amount of inclination of the z shaft 51 due to the rotation of the z plate 60 can be reduced. Therefore, the image sensor 81 can be moved with good straightness.

  Therefore, the rotating sphere 62 and the rotating sphere 52 are arranged on one end side of the opening, here on the upper side. By doing so, it is only necessary to generate a suction force for sandwiching the rotating sphere between the plates only above the opening 8. That is, since it is not necessary to generate a suction force below the opening 8, the number of parts can be reduced. For example, a permanent magnet or a yoke for generating an attractive force is not necessary. Furthermore, by reducing the number of parts, the assembly process can be simplified and the cost can be further reduced. Further, since the rotating sphere 52 is disposed in the vicinity of the center of the z shaft 51 in the z direction, the straight traveling performance in the z direction can be improved.

Further, another arrangement example of the rotating sphere 62 will be described with reference to FIG. FIG. 11 is a yz plan view showing another arrangement example of the z shaft 51, the y shaft 61, the rotating sphere 52, and the rotating sphere 62. The arrangement example shown in FIG. 11 differs from the arrangement example shown in FIG. 10 in the position of the ball receiver with the rotating sphere 62. Here, the rotating sphere 62 is disposed near the center of the opening 8 in the y direction. That is, the rotating sphere 62 is disposed outside the opening 8 in the vicinity of the center between one end (upper end) and the other end (lower end) of the opening 8 in the y direction. Thereby, the straightness of movement in the y direction can be improved. Further, the z-direction has the same configuration. That is, the rotating sphere 52 is arranged outside the opening 8 in the vicinity of the center between one end (left end) and the other end (right end) of the opening 8 in the z direction. Thereby, the straightness of the movement in the z direction can be improved.
Thus, the rotating sphere 52 is arranged near the center of the opening 8 in the z direction, and the rotating sphere 62 is arranged near the center of the opening 8 in the y direction. By doing so, the influence of rotation can be reduced in the movement in the y direction and the movement in the z direction. Thereby, an image pick-up element can be moved with sufficient straightness. Further, the rotating sphere 52 and the rotating sphere 62 are arranged so as to be shifted from each other in the yz plane. As a result, it is not necessary to provide a ball receiver at the same position on the front and back of the z plate 60, so that assembly can be easily performed. In addition to the configuration of FIG. 10, a rotating sphere 62 is disposed between the openings 8 in the y direction. Thereby, the amount of inclination of the y shaft 61 due to the rotation of the y plate 70 can be reduced. Therefore, the image sensor 81 can be moved with good straightness.

(Camera shake correction mechanism position detection)

  As described above, the Hall elements 72 and 74 detect the position of the y plate 70 to perform feedback control. The position detection will be described below.

  FIG. 12 is a side view showing the configuration of the upper holder 30. The upper holder 30 includes a permanent magnet 31, a permanent magnet 32, and a yoke 33. The permanent magnet 31 and the permanent magnet 32 are fixed to the yoke 33. The yoke 33 is formed in a U shape in the xy plan view. Here, the space between the U-shaped yokes 33 is defined as a recess 34. The recess 34 is arranged facing downward. The permanent magnet 31 is disposed in the recess 34. The magnetic field generated by the permanent magnet 31 is closed with the yoke 33. The coil 76 described above is inserted into the recess 34. As a result, the coil 76 and the permanent magnet 31 are opposed to each other, and thus function as a motor. A permanent magnet 32 for position detection is attached to the end surface of the yoke 33 on the + x side. The magnetic force of the permanent magnet 32 becomes an attractive force for attracting the y plate 70.

  FIG. 13 is a side view showing the configuration of the lower holder 40. The lower holder 40 has a permanent magnet 41, a permanent magnet 42, and a yoke 43. The permanent magnet 41 and the permanent magnet 42 are fixed to the yoke 43. The yoke 43 is formed in a U shape in the xy plan view. Here, the space between the U-shaped yokes 43 is defined as a recess 44. The recess 44 is arranged facing upward. A permanent magnet 41 is disposed in the recess 44. The magnetic field generated by the permanent magnet 41 closes with the yoke 43. Then, the coil 76 described above is inserted into the recess 44. As a result, the coil 63 and the permanent magnet 41 are disposed to face each other, and thus function as a motor. A permanent magnet 42 for position detection is attached to the end surface of the yoke 43 on the + x side.

  A state in which the upper holder 30 and the lower holder 40 are attached to the base plate 50 will be described with reference to FIGS. 14 and 15 are rear views showing a state in which the z plate 60 and the y plate 70 are attached to the base plate 50 by the upper holder 30 and the lower holder 40, and FIGS. 16 and 17 are perspective views thereof. FIG. In FIGS. 14 and 16, the wiring boards 93 and 94 for supplying current to the coil are omitted for the sake of clarity. FIG. 18 is a cross-sectional view of the camera shake correction mechanism.

  The upper holder 30 is fixed to the base plate 50, and the coil 76 of the y plate 70 is inserted into the recess 34 of the upper holder 30. It is assumed that the magnetic field generated by the permanent magnet 31 and the current of the coil 76 are orthogonal in the x direction and the z direction. By controlling the current flowing through the coil 76, the y plate 70 moves directly in the y direction with respect to the upper holder 30. At this time, the hall element 74 provided on the y plate 70 and the permanent magnet 32 are arranged to face each other. When the y plate 70 moves in the y direction with respect to the upper holder 30, the relative positions of the permanent magnet 32 and the hall element 74 change. The hall element 74 detects a change in the magnetic field. Based on the output signal output from the Hall element 74, the amount of displacement of the y plate 70 relative to the base plate 50 is detected. In other words, the hall element 74 detects the position of the image sensor 81.

  The lower holder 40 is fixed to the base plate 50, and the coil 63 of the z plate 60 is inserted into the recess 44 of the lower holder 40. It is assumed that the magnetic field of the permanent magnet 41 and the current flowing through the coil 63 are orthogonal in the x direction and the y direction. By controlling the current flowing through the coil 63, the z plate 60 moves directly in the z direction with respect to the lower holder 40. At this time, the Hall element 72 provided on the z plate 60 and the permanent magnet 42 are arranged to face each other. When the z plate 60 moves in the z direction with respect to the lower holder 40, the relative positions of the permanent magnet 42 and the hall element 72 change. The hall element 72 detects a change in the magnetic field. Based on the output signal output from the Hall element 74, the amount of displacement of the y plate 70 relative to the base plate 50 is detected. In other words, the hall element 74 detects the position of the image sensor 81. By doing so, feedback control of the image sensor 81 can be performed, and camera shake correction can be performed more effectively. Note that the output signals of the Hall element 72 and the Hall element 74 are taken out via the wiring board 93.

(Rotating sphere holding mechanism)
In order to hold the rotating sphere 52 and the rotating sphere 62 between the plates, the y plate 70 is sucked toward the base plate. Hereinafter, a configuration for sucking the y plate 70 to the base plate 50 and holding the rotating spheres 52 and 62 will be described. The magnetic force generated by the permanent magnet 32 is used as an attractive force so that the distance between the base plate 50 and the y plate 70 is kept constant.

  As shown in FIGS. 17 and 18, a suction yoke 73 is disposed on the back side of the Hall element 74. Specifically, the suction yoke 73 is attached to the wiring board 93. Therefore, the attraction yoke 73 and the permanent magnet 32 are disposed to face each other with the hall element 74 interposed therebetween. As a result, the suction yoke 73 is attracted to the permanent magnet 32 by the magnet. The permanent magnet 32 is attached to the base plate 50 via the upper holder 30, and the wiring board 93 is attached to the y plate 70. For this reason, the permanent magnet 32 attracts the y plate 70 to the base plate 50. A constant attractive force is generated in the permanent magnet 32 by the magnetic force. The y plate 70 can be prevented from coming off the base plate 50, and the rotating sphere 52 and the rotating sphere 62 are held between the plates. Since the rotating spheres 52 and 62 are held by the permanent magnet 32 used for position detection, the number of parts can be reduced. Thereby, an assembly process can be simplified and productivity can be improved. The suction yoke 73 may be any material that is attracted to the permanent magnet 32, and for example, a ferromagnetic material or the like can be used.

  Further, in the present embodiment, both the rotating sphere 52 and the rotating sphere 62 are arranged above the opening 8. Therefore, it is only necessary to perform attraction by magnetic force only above the opening 8. That is, since it is not necessary to attach a suction yoke to the lower side of the opening 8, the number of parts can be reduced. In addition, the assembly process can be simplified and productivity can be improved. The position where the rotating sphere 52 and the rotating sphere 62 are arranged is not limited to the upper side of the opening 8. That is, it is only necessary to be disposed on one end side of the opening 8. By doing so, it is possible to generate a suction force for preventing the rotating balls 52 and 62 from falling off with a simple configuration.

  Further, as shown in the side sectional view of FIG. 18, the U-shaped upper holder 30 holds the y plate 70 with respect to the base plate 50. The upper holder 30 is attached to the base plate 50 so that the y plate 70 is inserted into the recess 34 of the upper holder 30 in a state where the base plate 50, the z plate 60 and the y plate 70 are overlapped. That is, among the base plate 50, the z plate 60, and the y plate 70, the end of the y plate 70 closest to the image sensor 81 is inserted into the recess 34. Thereby, the position of the y plate 70 is restricted, and the gap between the base plate 50 and the y plate 70 can be prevented from becoming a certain level or more.

  That is, even when an external impact is applied to the imaging apparatus 100, it is possible to prevent the rotating balls 52 and 62 from falling off. In other words, when the upper holder 30 is not provided, there is a possibility that the attractive force due to the magnetic force is removed when an impact is applied. In this case, the rotating spheres 52 and 62 may fall off.

  However, the z plate 60 can be held on the base plate 50 using the U-shaped upper holder 30. Similarly, the lower holder 40 regulates the position of the z plate 60. Therefore, even when an external impact is applied to the imaging apparatus 100, it is possible to prevent the rotating sphere 62 from falling off. The upper holder 30 and the lower holder 40 hold the z plate 60 and the y plate 70 so as to be movable on both the upper and lower sides. Thereby, the z plate 60 and the y plate 70 can be reliably held with respect to the base plate 50, and the rotation balls 52 and 62 can be prevented from falling off. Of course, the concave portion 34 and the concave portion 44 are designed with dimensions such that the rotating balls 52 and 62 do not fall off.

(Actuator arrangement)
Next, the arrangement of actuators for moving in the y direction and the z direction will be described with reference to FIGS. 18 and 20. 19 is a yz plan view showing the arrangement of the coil 76 and the coil 63, and FIG. 20 is a yz plan view showing a state in which the upper holder 30 and the lower holder 40 are attached to the configuration of FIG.

  As shown in FIG. 19, the coil 76 is disposed on the upper side of the opening 8, and the coil 63 is disposed on the lower side. As shown in FIG. 20, a motor using the coil 63 is an actuator 91, and a motor using the coil 76 is an actuator 92. The actuator 91 is constituted by the coil 76 and the permanent magnet 31, and the actuator 92 is constituted by the coil 63 and the permanent magnet 41.

  The actuator 91 that drives the z plate 60 in the z direction is disposed above the opening 8, and the actuator 92 that drives the y plate 70 in the y direction is disposed below the opening 8. That is, one actuator 91 of the actuators 91 and 92 disposed outside the opening 8 is disposed on one end side of the opening 8, and the other actuator 92 is disposed on the other end on the opposite side. The opening 8 is disposed between the actuator 91 and the actuator 92 in the yz plan view.

  In the yz plan view, the actuator 91 and the actuator 92 are opposed to each other so as to sandwich the opening 8. Thus, the region between the upper end and the lower end of the opening on the outside of the opening 8, that is, the opening 8. Actuators 91 and 92 are not arranged on the left side and the right side. By doing so, the actuator is not disposed on both the left and right sides of the opening 8. It is not necessary to provide a space for arranging the actuator on both sides of the opening 8 in the z direction. Therefore, the imaging device 100 can be slimmed in the z direction. Of course, by arranging the actuators 91 and 92 on the left and right sides, it is possible to make them slim in the vertical direction.

(Cover unit 20)
Next, the configuration of the cover unit 20 will be described with reference to FIGS. 21 is a perspective view showing a state where the sensor unit 80 and the cover unit 20 are attached to the y plate 70, FIG. 22 is an exploded perspective view thereof, and FIG. 23 is a sectional view thereof.

  As shown in FIG. 21, the substrate 85 of the sensor unit 80 is fixed to the y plate 70. The substrate 85 includes wiring, a control circuit, a memory circuit, and the like that are connected to the image sensor 81. For example, the substrate 85 of the sensor unit 80 is attached from the back side of the y plate 70, and the image sensor 81 of the sensor unit 80 is disposed in the opening 70 a of the y plate 70. In other words, the image sensor 81 is disposed on the y plate located at the rear end of the base plate 50, the z plate 60, and the y plate 70 disposed between the lens unit 7 and the image sensor 81. The image sensor 81 is fixed to the substrate 85 with a photocurable resin or the like. A cover unit 20 for protecting the image sensor 81 is disposed on the front side of the sensor unit 80.

  As shown in FIG. 22, the cover unit 20 (filter unit) includes a frame body 21, a filter 22, and a holding frame 23. The frame body 21 is formed in a frame shape and has an opening 21 a corresponding to the light receiving region of the image sensor 81. The frame body 21 is made of urethane foam such as Polon (registered trademark) and has a thickness of about 2.0 mm. Of course, the frame body 21 is not limited to urethane foam, and the numerical value of the thickness is an example. For example, an elastic body such as rubber or resin can be used as the frame body 21. It is preferable to use a dustproof material as the frame body 21.

  The filter 22 is, for example, a flat rectangular plate having a thickness of 1.4 mm, and cuts infrared rays toward the image sensor 81. Therefore, the filter 22 is an IR filter that shields infrared rays that have passed through the lens 6. The frame body 21 is disposed on the light receiving surface of the image sensor 81, and the filter 22 is disposed on the frame body 21. That is, the frame body 21 is interposed between the filter 22 and the image sensor 81. A space corresponding to the thickness of the frame body 21 is formed in the vicinity of the light receiving surface of the image sensor 81. In other words, a space corresponding to the opening 21 a of the frame body 21 is created on the light receiving surface of the image sensor 81. That is, the cover unit 20 positions the filter 22 with a predetermined interval from the light receiving region of the image sensor 81.

  The holding frame 23 attaches the frame body 21 and the filter 22 to the substrate 85. Specifically, the holding frame 23 includes a frame portion 23a, a leg portion 23b, and a wall portion 23c. The frame portion 23a is formed in a frame shape, defines an opening 23d, and the leg portion 23b extends toward the substrate 85 from two opposing sides of the frame portion 23a. Furthermore, wall portions 23c are formed on two sides other than the two sides on which the leg portions 23b of the frame portion 23a are provided. Wall portions 23c are formed on two sides along the y direction of the frame portion 23a, and leg portions 23b are formed on two sides along the z direction. The wall portion 23c extends toward the substrate 85 side.

  On the other hand, the y plate 70 is formed with a claw portion 79 for locking the leg portion 23b. The nail | claw part 79 latches with the leg part 23b in the state by which the frame 21 and the filter 22 were clamped between the holding frame 23 and the board | substrate 85 (refer also FIG. 23 together). The cover unit 20 is fixed to the sensor unit 80. The holding frame 23 urges the frame body 21 through the filter 22. Therefore, the filter 22 and the frame body 21 can be held between the holding frame 23 and the substrate 85. In this state, the filter 22 and the frame body 21 are disposed between the two opposing wall portions 23c. Therefore, it can prevent that the position of the filter 22 and the frame 21 shifts | deviates. The cover unit 20 is disposed in the opening 8.

  Further, the frame-shaped frame body 21 is arranged so as to be in contact with the image sensor 81. The filter 22 seals the space formed on the light receiving surface of the image sensor 81 by the frame body 21. As a result, dust and dust can be prevented from adhering to the light receiving surface of the image sensor 81, and the filter 22 and the light receiving surface are separated by a sufficient distance. In the above example, when the frame body 21 having a thickness of 1.4 mm and the filter 22 having a thickness of 2.0 mm are disposed, the frame body 21 formed of urethane foam is slightly contracted, and the front surface of the filter 22 and the image sensor 81. The distance to the light receiving surface is about 2.9 mm. The front surface of the filter 22 and the light receiving surface of the image sensor 81 are separated by the thickness of the frame body 21 and the filter 22. Accordingly, dust or the like adhering to the surface of the filter 22 opposite to the sealed space can form an image on the image sensor 81 only at a negligible level on the light receiving surface. Therefore, the influence of dust and the like can be reduced. Furthermore, it is not necessary to provide a mechanism for vibrating the image sensor 81 in order to remove dust attached to the surface of the filter 22. Thereby, the components driven by the camera shake correction mechanism 9 can be reduced in weight.

  Visible light passing through the lens 6 passes through the opening 23 d, passes through the filter 22, passes through the opening 21 a, and enters the image sensor 81. Thereby, the subject can be imaged by the imaging element 81. By attaching such a cover unit 20 to the y plate 70, the cover unit 20 also moves according to the movement for camera shake correction. Further, by arranging the cover unit 20 in the opening 8, the camera shake correction mechanism 9 can be reduced in thickness and size. Further, by using a sponge such as urethane foam, the weight can be reduced, and the image sensor 81 can be driven at high speed.

DESCRIPTION OF SYMBOLS 2 Camera unit 3 Monitor part 4 Hinge 5 Main body part 6 Lens 7 Lens unit 8 Opening part 9 Camera shake correction mechanism 10 Lens barrier 14 Battery cover 17 Opening / closing lever 18 Operation part 20 Cover unit 21 Frame body 21a Opening part 22 Filter 23 Holding frame 23a Frame portion 23b Leg portion 23c Wall portion 24c Opening portion 30 Upper holder 31 Permanent magnet 32 Permanent magnet 33 Yoke 34 Opening portion 40 Lower holder 41 Permanent magnet 42 Permanent magnet 50 Base plate 51 z shaft 52 Rotating sphere 60 z plate 61 y shaft 62 Rotating sphere 63 Coil 64 Shaft hole 65 Ball receiver 70 Y plate 72 Hall element 73 Suction yoke 74 Hall element 75 Ball receiver 76 Coil 77 Shaft hole 80 Sensor unit 81 Image sensor 90 Rear cover 100 Imaging device Place

Claims (4)

An image pickup apparatus having a camera shake correction mechanism that performs camera shake correction by moving the image sensor with respect to the lens unit,
A plurality of plates having an opening for connecting the image sensor and the lens unit movably in first and second directions, and guiding light from the lens unit to the image sensor;
A first actuator for moving the image sensor in the first direction;
A second actuator for moving the image sensor in the second direction,
An imaging apparatus in which the opening is disposed between the first actuator and the second actuator in a plan view perpendicular to the optical axis of the lens unit. The plurality of plates includes a first plate, a second plate, and a third plate,
The first plate and the second plate are connected by a first shaft along the first direction;
The imaging apparatus according to claim 1, wherein the second plate and the third plate are connected by a second shaft along the second direction. The first actuator comprises:
A first magnet attached to the first plate at one end of the opening;
A first coil provided on the second plate and moving relative to the first magnet;
The second actuator comprises:
A second magnet attached to the first plate on the other end side opposite to the one end side of the opening;
The imaging apparatus according to claim 2, further comprising a second coil attached to the third plate and moving with respect to the second magnet.   The imaging apparatus according to claim 3, wherein the first and second actuators are not arranged in a region between the one end and the other end outside the opening.

Images