Source: https://patents.google.com/patent/JP6049267B2/en
Timestamp: 2020-06-03 23:39:02
Document Index: 412047454

Matched Legal Cases: ['art 2', 'art 9', 'art 17', 'art 21', 'art 17', 'art 2', 'art 18', 'art 18', 'art, 5', 'art, 10', 'art, 10']

JP6049267B2 - Lens drive device - Google Patents
Lens drive device Download PDF
JP6049267B2
JP6049267B2 JP2012016877A JP2012016877A JP6049267B2 JP 6049267 B2 JP6049267 B2 JP 6049267B2 JP 2012016877 A JP2012016877 A JP 2012016877A JP 2012016877 A JP2012016877 A JP 2012016877A JP 6049267 B2 JP6049267 B2 JP 6049267B2
JP2012016877A
JP2013156436A (en
和雄 色摩
晴彦 万代
悠介 江原
渡部　伸昭
伸昭 渡部
2012-01-30 Application filed by 日本電産コパル株式会社 filed Critical 日本電産コパル株式会社
2012-01-30 Priority to JP2012016877A priority Critical patent/JP6049267B2/en
2013-08-15 Publication of JP2013156436A publication Critical patent/JP2013156436A/en
2016-12-21 Publication of JP6049267B2 publication Critical patent/JP6049267B2/en
The present invention relates to a lens driving device having a box structure.
Conventionally, there is JP 2010-96862 A as a technique in such a field. The lens driving device described in this publication includes a first box portion that houses a lens frame that drives in the optical axis direction, and a second box portion that houses a first box portion. A coil is attached to the outer surface of the lens frame in the box portion, and a magnet is fixed to the inner surface of the first box portion. The lens frame sandwiched between the leaf springs is moved in the optical axis direction in cooperation with the coil and the magnet. Further, an image sensor such as a CCD or a CMOS is fixed to the bottom of the first box portion. In this lens driving device, in order to achieve camera shake correction, the bottom portion of the first box portion is supported by the support protrusion formed on the bottom wall of the second box portion. Therefore, the first box portion is swung around the front end of the support protrusion together with the image pickup device by the driving force of the coil and the magnet.
JP 2010-96862 A
However, in the above-described conventional lens driving device, it is necessary to form the support protrusion at the center of the bottom of the second box portion, and the support protrusion is positioned on the extension of the optical axis. An image sensor such as a CCD or CMOS must be fixed to the bottom of the first box. In order to perform the camera shake correction, the first box portion needs to be swung together with the image sensor. Therefore, a large driving force is required to drive the first box portion in order to control the camera shake correction. As a result, there is a problem that the camera shake correction coil and magnet are enlarged, and as a result, the lens driving device itself is enlarged.
An object of this invention is to provide the lens drive device which enabled size reduction.
The present invention drives a first box portion containing a lens frame driven in the optical axis direction, a second box portion containing the first box portion, and the first box portion corresponding to image blur. In order to make the lens driving device, the driving means disposed between the first box portion and the second box portion,
A regulating surface provided between the first box portion and the second box portion, extending in a direction orthogonal to the optical axis, and a sliding portion including a curved surface contacting the regulating surface; Further comprising one regulating means having
First and second openings centered on the optical axis are formed at both ends in the optical axis direction of the first box portion,
At both ends in the optical axis direction of the second box part, third and fourth openings centered on the optical axis are formed,
The driving means includes a coil and a magnet that are arranged to face each other in the optical axis direction, and one of the coil and the magnet is located around the second opening portion in the first box portion. The other of the coil and the magnet is fixed to the second box portion around the fourth opening ,
The lens frame is sandwiched between two leaf springs in the optical axis direction,
The first box part is divided into two parts by a first member and a second member, one of the leaf springs is fixed to the first member, and the other outer part of the leaf spring is , Sandwiched between the first member and a frame portion formed so as to surround the first opening of the second member,
The two leaf springs include a terminal part and a connecting part that connects the outer peripheral part to the terminal part so as to be movable in a plane orthogonal to the optical axis .
In this lens driving device, an image pickup device such as a CCD or CMOS can be separately arranged on the third opening side or the fourth opening side in the second box portion. Therefore, the lens driving device itself can be reduced in size. Moreover, since image blur correction can be performed without considering the weight of the image sensor, it is not necessary to increase the size of the hand-shake correction coil and magnet for driving the first box part, The lens driving device can be reduced in size.
The lens frame is sandwiched between two leaf springs in the optical axis direction, the first box portion is divided into two parts by a first member and a second member, and one leaf spring is The outer peripheral portion of the other plate spring is sandwiched between the first member and a frame portion formed so as to surround the first opening of the second member.
Thus, by making the first box portion into a two-part structure, it is easy to incorporate the lens frame into the first box portion, and by adopting a leaf spring, the first member of the first box portion The leaf spring can be sandwiched and fixed with the second member. This ensures the fixing of the leaf spring and at the same time improves the workability of assembling the leaf spring. And since the outer peripheral part of a leaf | plate spring is pressed down with the frame part of the 2nd member, the situation where the outer peripheral part of a leaf | plate spring deform | transforms by the movement of a lens frame can be prevented reliably.
In addition, a protrusion projecting in the radial direction is formed on the outer peripheral surface of the lens frame, and the first box protrudes in a convex shape into the first opening, thereby moving the lens frame in the optical axis direction. An end stopper is provided that regulates when the protrusion comes into contact.
If the end surface of the lens frame exceeds the first box portion and hits the periphery of the third opening of the second box portion, the frictional resistance becomes too large, and the first image correction is performed by the driving means when the first image blur correction is performed. There is a possibility that the box portion cannot be moved in a plane perpendicular to the optical axis. Therefore, in order to reduce the contact area and reduce the frictional resistance, a protruding portion that protrudes in the radial direction is formed on the outer peripheral surface of the lens frame, and the first box portion has a convex shape in the first opening. A protruding end stopper is formed. In other words, when the lens frame is moved to the extreme end position in the optical axis direction, the projection of the lens frame is brought into contact with the end stopper protruding in a convex shape at the first box portion, thereby correcting the image blur. It is configured to minimize frictional resistance at the time.
According to the present invention, the lens driving device can be miniaturized.
It is a disassembled perspective view which shows embodiment of the lens drive device which concerns on this invention. It is sectional drawing of the lens drive device shown by FIG. It is a bottom view of the movable member shown by FIG. FIG. 2 is a plan view of the lens driving device shown in FIG. 1. FIG. 2 is a perspective view of the lens driving device shown in FIG. 1. It is a perspective view of the lens frame pinched | interposed into the leaf | plate spring shown by FIG. It is a disassembled perspective view of the lens frame pinched | interposed into the leaf | plate spring shown by FIG. It is a perspective view of the 1st box part shown by FIG.
Hereinafter, a preferred embodiment of a lens driving device according to the present invention will be described in detail with reference to the drawings.
As shown in FIGS. 1 and 2, a lens driving device 1 that is used in a digital camera by correcting camera shake has a box-shaped base member 2 that houses an image stabilization mechanism 3 and a focus adjustment mechanism 4 with an open end. The focus adjustment mechanism 4 includes a camera shake correction mechanism 3 that corrects camera shake by moving the focus adjustment mechanism 4 in a plane orthogonal to the optical axis C, and a focus adjustment mechanism that moves the lens in the direction of the optical axis C. 4, a lid member 5 for closing the base member 2, and a flexible printed board 6 for securing an electrical connection between the lens driving device 1 and an external circuit. Further, the base member 2 and the lid member 5 constitute a box part (second box part) P2. The lens driving device 1 is arranged and used in front of a CCD (Charge Coupled Device) image sensor or a CMOS (Complementary Metal Oxide Semiconductor) image sensor (not shown) which is an image sensor.
The above-described base member 2 and the camera shake correction mechanism 3 constitute a camera shake correction device 30. The camera shake correction is an aspect of image shake correction for correcting image shake.
The base member 2 is a rectangular parallelepiped box-shaped member having a rectangular opening 2 a centered on the optical axis C. Inside the base member 2, a support surface 2b extending perpendicular to the optical axis C is provided. The support surface 2b is provided with a recess 2c and a hole 2g, and the hole 2g is formed between a circular opening (fourth opening) 2d centered on the optical axis C and one corner 2h. Has been.
The camera shake correction mechanism 3 is for correcting camera shake by moving the focus adjustment mechanism 4 attached to the movable member 10 within a plane orthogonal to the optical axis C. The camera shake correction mechanism 3 includes a supporting unit 8 that forms a ball for supporting the movable member 10 having a frame shape, a movable member 10 to which the focus adjusting mechanism 4 is attached, and the movable member 10 in a direction orthogonal to the optical axis C. The movable member driving means 11 to be driven and the restricting means 15 for restricting the movement of the movable member 10 in the base member 2 are provided.
The support means 8 for movably supporting the movable member 10 in a plane orthogonal to the optical axis C includes three support portions 9. Each support portion 9 includes a metal spherical body 9a that supports the movable member 10, and a pair of sliding plates 9b that sandwich the spherical body 9a and reduce the rolling resistance of the spherical body 9a.
A movable member 10 for moving the focus adjustment mechanism 4 in a direction orthogonal to the optical axis C is housed inside the base member 2 while being supported by the support means 8. The movable member 10 is a rectangular parallelepiped member having a circular opening (second opening) 10 a centering on the optical axis C. The movable member 10 has a bottom surface 10 c that faces the support surface 2 b of the base member 2.
The bottom surface 10c of the movable member 10 is provided with a recess 10d for fixing one sliding plate 9b (see FIG. 3). In order to fix the other sliding plate 9b, a recess 2c is formed in the base member 2 at a position corresponding to the recess 10d. A spherical body 9a is disposed between the recess 2c and the recess 10d. The inner diameters of the recesses 2c and 10d are formed larger than the outer diameter of the spherical body 9a. For this reason, the spherical body 9a can roll within the range of the recessed part 2c. In addition, the support part 9 should just be supported so that the movable member 10 can move within a plane.
The camera shake correction driving means 11 for driving the movable member 10 in a direction orthogonal to the optical axis C includes three actuators 12, 13, and 14. On the diagonal line L1, the actuator 12 and the groove | channel 10b mentioned later are arrange | positioned. The actuator 12 and the groove 10b are provided to face each other with the optical axis C interposed therebetween. The actuator 12 applies a driving force F1 having a directional component along the diagonal line L1 to the movable member 10.
Actuators 13 and 14 are arranged on another diagonal L2 orthogonal to the diagonal L1. The actuators 13 and 14 are provided to face each other with the optical axis C interposed therebetween. The actuators 13 and 14 apply a driving force F2 having a directional component along the diagonal L2 to the movable member 10.
The actuators 12, 13, and 14 have the same configuration. Here, the configuration of the actuator 12 will be described as an example. As shown in FIGS. 1 and 2, the actuator 12 includes a magnet 12a and a coil 12b. The magnet 12 a is disposed in the recess 10 r on the bottom surface 10 c of the movable member 10, and the coil 12 b is disposed in the recess 2 p formed on the support surface 2 b of the base member 2. The magnet 12a is disposed so as to face the coil 12b.
The actuator 12 is disposed between a pair of yoke plates 12c and 12d, one of which is disposed on the magnet 12a side and the other is disposed on the coil 12b side. According to such an arrangement, the magnetic paths of the magnet 12a and the coil 12b are secured. Even when the coil 12b is not energized, the movable member 10 is maintained at a fixed position because a magnetic attractive force acts between the magnet 12a and the yoke plate 12d.
As shown in FIGS. 2 and 3, the restricting means 15 for restricting the movement of the movable member 10 includes a pin 7 fixed to the base member 2 and a groove 10 b provided in the movable member 10. ing.
The pin 7 is a cylindrical member extending in the direction of the optical axis C. The base end of the pin 7 is inserted and fixed in a hole 2g formed in the base member 2.
As shown in FIG. 3, the groove 10 b formed in the movable member 10 is a long groove extending along the diagonal line L <b> 1 in the movable member 10. The groove 10b is formed on the bottom surface 10c at a position corresponding to the position of the hole 2g into which the pin 7 is inserted. By forming at such a position, the pin 7 is inserted into the groove 10b. The width in the direction perpendicular to the longitudinal direction of the groove 10b is set to a width that allows the pin 7 to slide relative to the side surface of the groove 10b. The groove 10b having a rectangular cross section has a pair of side walls 10t facing each other for defining a width in which the pin 7 can slide.
A pin 7 is inserted into the groove 10b of the movable member 10, and the groove 10b extends along the diagonal line L1. Therefore, the movable member 10 can be linearly moved while being guided in the direction of the linear movement locus T1 set in the direction in which the side wall 10t of the groove 10b extends, and the pin 7 disposed on the linear movement locus T1. Can be rotated along a rotational movement trajectory T2 having the rotation center RC as the center of rotation. That is, the position of the movable member 10 corresponds to being expressed in a circular coordinate system based on one moving radius and one deflection angle. According to this combination of linear movement and rotation, the position of the optical axis C can be accurately moved to a desired position.
The movable range S of the optical axis C is based on a distance allowing linear movement and an angle allowing rotation. The distance in which the movable member 10 can move linearly is determined by the length of the groove 10b in the longitudinal direction. The angle at which the movable member 10 can be rotated is between the notches 10y and 10z provided on the outer edge of the movable member 10 and the contact portions 2y and 2z provided on the inner wall surface 2x of the base member 2. The contact portions 2y and 2z are determined by the gap and have a surface along the longitudinal direction of the groove 10b. The angle at which the movable member 10 can be rotated may be determined by the distance of the spherical body 9a in the recess 2c or the recess 10d.
As shown in FIG. 1, the focus adjustment mechanism 4 attached to the movable member 10 includes a lens frame 16 that holds a lens (not shown), a plate spring 17 that biases the lens frame 16 in the direction of the optical axis C, 18, a lens driving unit 19 that drives the lens frame 16 in the direction of the optical axis C, and a fixed frame 21 that reinforces the fixed state of the leaf spring 17 to the movable member 10. The movable member 10 and the fixed frame 21 constitute a box part (first box part) P1.
A lens frame 16 for holding a lens group (not shown) having a single lens or a plurality of lenses is a cylindrical member having a hole 16a into which the lens is fitted. The optical axis C is the optical axis of the lens disposed in the lens frame 16. The lens frame 16 is sandwiched between a pair of leaf springs 17 and leaf springs 18 in the direction of the optical axis C.
As shown in FIGS. 5 to 8, the leaf spring 17 fixed to one end surface 16 b (see FIG. 1) of the lens frame 16 is a rectangular thin plate having a circular opening 17 a centering on the optical axis C. It is a member. The conductive leaf spring 17 is fixed to the lens frame 16 and an arm portion (elastic portion) 17 b that gives elasticity in the direction of the optical axis C, an outer peripheral portion 17 c that holds the position of the entire plate spring 17, and the lens frame 16. And an inner peripheral portion 17d.
The leaf spring 17 is disposed between the fixed frame 21 and the lens frame 16. The outer peripheral portion 17c extending along the outer peripheral edge of the movable member 10 includes a top portion 10f of the upright piece 10s of the movable member (first member) 10 and an opening portion 21a of the fixed frame (second member) 21 described later. The frame portion 21e is formed so as to surround the four corner portions of the outer peripheral portion 17c (see FIGS. 1 and 2). An inner peripheral portion 17d disposed inside the outer peripheral portion 17c extends along one end surface 16b of the lens frame 16, and the inner peripheral portion 17d is provided with an opening 17a. The inner peripheral portion 17 d is bonded and fixed to one end surface 16 b of the lens frame 16. Further, the inner peripheral portion 17d is provided with a winding connection portion 17e to which one end 22c of the winding of the coil 22b is connected.
As described above, the first box portion P1 is divided into two parts by the fixed frame (second member) 21 and the movable member (first member) 10, so that a lens is formed in the first box portion P1. The frame 16 can be easily assembled, and the leaf spring 17 can be sandwiched and fixed between the fixed frame 21 and the movable member 10 of the first box portion P1. This ensures the fixing of the leaf spring 17 and also improves the workability of assembling the leaf spring 17. And since the outer peripheral part 17c of the leaf | plate spring 17 is pressed down by the frame part 21e of the fixed frame 21, the situation where the outer peripheral part 17c of the leaf | plate spring 17 deform | transforms by the movement of the lens frame 16 can be prevented reliably.
The leaf spring 17 is provided with four arm portions (elastic portions) 17b that connect the outer peripheral portion 17c and the inner peripheral portion 17d. One end 17f of the arm portion 17b extending in the circumferential direction about the optical axis C is connected to the outer peripheral portion 17c, and the other end 17g is connected to the outer peripheral portion 17c. Each arm portion 17b is arranged with a phase angle of 90 degrees around the optical axis C in a plane orthogonal to the optical axis C. That is, the pair of arm portions 17b are disposed to face each other with the optical axis C interposed therebetween. By this arm portion 17b, the leaf spring 17 has elasticity in the direction of the optical axis C.
The leaf spring 17 includes a terminal portion 17h that is an input / output portion for an external circuit, and a connecting portion 17j that connects the outer peripheral portion 17c to the terminal portion 17h so as to be movable within a plane orthogonal to the optical axis C. Have.
Here, the terminal fixing | fixed part 2j provided in the base member 2 is demonstrated. As shown in FIG. 4, the terminal portion 17 h of the leaf spring 17 and two terminal fixing portions 2 j for fixing a terminal portion 18 h of the leaf spring 18 described later are provided from the optical axis C to the rotation center RC of the regulating means 15. Are provided so as to face each other with a reference line L3 passing therethrough.
The deforming portion 17r of the connecting portion 17j has an S shape on a plane orthogonal to the linear movement locus T1. The deforming portion 17r having such a configuration is elastically deformed in the direction of the linear movement locus T1.
The leaf spring 18 includes an opening 18a, an arm portion (elastic portion) 18b, an outer peripheral portion 18c, an inner peripheral portion 18d, a winding connecting portion 18e, a terminal portion 18h, a connecting portion 18j, and a deforming portion 18r. It consists of and. The arm portion 18b has one end 18f connected to the outer peripheral portion 18c and the other end 18g connected to the inner peripheral portion 18d. Since the leaf spring 18 has substantially the same configuration as the leaf spring 17, here, a description will be given focusing on a portion different from the leaf spring 17. The leaf spring 18 disposed between the movable member 10 and the lens frame 16 has an outer peripheral portion 18c bonded and fixed to the bottom surface 10g of the movable member 10, and an inner peripheral portion 18d bonded and fixed to the other end surface 16c of the lens frame 16. (See FIG. 2). As for the outer peripheral part 18c of the leaf | plate spring 18, the whole flame | frame which comprises the outer peripheral part 18c is adhere | attached and fixed to the bottom face 10g of the movable member 10. FIG.
The elasticity of the deforming portion 18r of the leaf spring 18 is preferably configured to be equal to the elasticity of the deforming portion 17r of the leaf spring 17. According to such a configuration, the position control of the movable member 10 can be facilitated.
The lens driving means 19 for driving the lens frame 16 in the direction of the optical axis C includes four actuators 22 (see FIGS. 1 and 2). The actuators 22 are arranged with a phase difference of 90 degrees from each other on a plane orthogonal to the optical axis C. Each of the four actuators 22 is disposed between the arm portions 17 b and 18 b of the leaf springs 17 and 18. Each actuator 22 having the same configuration includes a magnet 22a and a coil 22b. The magnet 22 a is fixed to the upright piece 10 s of the movable member 10, and the coil 22 b is fixed on the outer peripheral surface of the lens frame 16.
Each of the four coils 22b is connected so as to be electrically in series. One end 22 c of the winding of the coil 22 b connected in series is connected to the winding connecting portion 17 e of the leaf spring 17, and the other end 22 d of the winding is connected to the winding connecting portion 18 e of the leaf spring 18. By connecting in this way, a circuit that can supply current to the coil 22b via the leaf springs 17 and 18 using the terminal portions 17h and 18h as electrical input / output terminals is configured.
The fixed frame 21 for reinforcing the fixed state of the leaf spring 17 to the movable member 10 is a plate-like member having a substantially square opening (first opening) 21 a centering on the optical axis C. The fixed frame 21 is fixed to the top 10 f of the upright piece 10 s of the movable member 10. The state where the lens frame 16 is located on the bottom surface 10g of the movable member 10 is set as a reference position (see FIG. 2). At this time, the arm portion (elastic portion) 17b of the leaf spring 17 is in a natural state.
The lens frame 16 moves from the reference position toward the lid member 5 along the optical axis C by supplying power to the coil 22b. At this time, the arm portion 17b is elastically deformed so as to bend along the optical axis C in the direction from the movable member 10 toward the lid member 5 (see FIG. 2).
On the other hand, the entire frame (the entire circumference) constituting the outer peripheral portion 17 c is pressed into the frame portion 21 e of the fixed frame 21. That is, one end 17f of the arm portion 17b of the leaf spring 17 is pressed into the frame portion 21e of the fixed frame 21 from the direction in which the arm portion 17b is elastically deformed. Therefore, even if the lens frame 16 moves from the reference position toward the lid member 5 along the optical axis C, the outer peripheral portion 17c of the leaf spring 17 does not deform.
The lid member 5 is a plate-like member that is fixed to the opening-side edge 2 f of the base member 2 and has a circular opening (third opening) 5 a centering on the optical axis C.
The lid member 5 is provided with two Hall elements 27 that are magnetic field detection elements. The hall element 27 detects the magnetic field of the magnet 22 a disposed on the movable member 10. Since these Hall elements 27 are arranged at intervals of 90 degrees, the position of the movable member 10 in a plane orthogonal to the optical axis C can be detected.
Further, when the end face of the lens frame 16 touches the peripheral edge of the third opening 5a of the second box part P2 beyond the first box part P1, the frictional resistance becomes too large, and the camera shake due to the driving means 11 occurs. In the correction, there is a possibility that the first box portion P1 cannot be moved in a plane perpendicular to the optical axis C.
Therefore, as shown in FIGS. 1, 4, and 7, the outer peripheral surface of the lens frame 16 is formed with a protruding portion 16d that protrudes in the radial direction, and the pair of protruding portions 16d have a phase angle of 180 degrees. They are arranged opposite to each other and extend in the direction of the optical axis C. Further, the frame portion 21e of the fixed frame 21 of the first box portion P1 protrudes convexly into the first opening 21a, and the movement of the lens frame 16 in the direction of the optical axis C is caused by the end of the projection portion 16d. An end stopper 21f is provided to be regulated by contacting the part. The pair of end stoppers 21f are arranged to face each other with a phase angle of 180 degrees.
With such a configuration, even if the lens frame 16 moves to the extreme end position in the optical axis C direction, the end of the projection 16d of the lens frame 16 contacts the end stopper 21f. The frictional resistance can be minimized by reducing it.
A flexible printed circuit board 6 which is a circuit board for ensuring electrical connection between the lens driving device 1 and an external circuit is connected to the Hall element 27.
Next, the operation of the camera shake correction mechanism 3 will be described. If camera shake occurs when shooting with a device (for example, a camera) in which the lens driving device 1 is incorporated, the position of the optical axis C may change. In this case, a sensor that detects camera shake, such as a gyro sensor, detects camera shake, and the control means (not shown) controls the camera shake correction mechanism 3 so that the position of the optical axis C on the image sensor is maintained at a predetermined position. A control signal for driving is output to the coils 12b of the actuators 12, 13, and 14.
In this case, as shown in FIG. 3, upon receiving the control signal, the actuator 12 generates a driving force F1 and linearly moves the movable member 10 in the direction of the linear movement locus T1. When receiving the control signal, the actuators 13 and 14 generate the driving force F2 and rotate the movable member 10 in the direction of the rotational movement locus T2. By this linear movement and rotation, the position of the optical axis C is moved to a predetermined position. At this time, the movement of the movable member 10 is restricted by the restricting means 15, and has two degrees of freedom that is a total of one degree of freedom by linear movement and one degree of freedom by rotation. For this reason, the movable member 10 can move the position of the optical axis C to a desired position within the range S. By this movement, the position of the optical axis C on the image sensor (for example, CMOS) is maintained at a predetermined position, and camera shake is corrected.
In the lens driving device 1 described above, an image pickup device such as a CCD or CMOS can be separately arranged on the third opening 5a side or the fourth opening 2d side in the second box portion P2. There is no need to consider the incorporation of elements, and the lens driving device 1 itself can be reduced in size. In addition, since image blur correction can be performed without considering the weight of the image sensor, it is not necessary to increase the size of the camera shake correction coil 12b and the magnet 12a for driving the first box portion P1. Thus, the lens driving device 1 can be reduced in size.
For example, in each of the actuators 12, 13, and 14, the coil 12 b is disposed in the recess 10 r of the bottom surface 10 c of the movable member 10, and the magnet 12 a is disposed in the recess 2 p formed on the support surface 2 b of the base member 2. May be.
The lens frame 16 of the focus adjustment mechanism 4 has a focus adjustment lens for focus adjustment, but may have a zoom lens for angle of view adjustment.
DESCRIPTION OF SYMBOLS 1 ... Lens drive device, 2d ... 4th opening part, 5a ... 3rd opening part, 10a ... 2nd opening part, 10 ... Movable member (1st member), 11 ... Driving means, 12a ... Magnet, 12b ... coil, 16 ... lens frame, 16d ... projection, 17, 18 ... leaf spring, 21 ... fixed frame (second member), 21a ... first opening, 21f ... end stopper, 21e ... frame, C: optical axis, P1: first box portion, P2: second box portion.
In order to drive the first box portion accommodating a lens frame driven in the optical axis direction, the second box portion accommodating the first box portion, and the first box portion corresponding to image blur. In a lens driving device comprising: driving means disposed between the first box portion and the second box portion;
The two leaf springs include a terminal portion and a connecting portion that connects the outer peripheral portion to the terminal portion so as to be movable in a plane orthogonal to the optical axis. apparatus.
A projecting portion protruding in the radial direction is formed on the outer peripheral surface of the lens frame, and the first box portion protrudes in a convex shape into the first opening, and extends in the optical axis direction of the lens frame. The lens driving device according to claim 1, further comprising an end stopper that restricts movement of the projection by contacting the projection.
JP2012016877A 2012-01-30 2012-01-30 Lens drive device Active JP6049267B2 (en)
JP2012016877A JP6049267B2 (en) 2012-01-30 2012-01-30 Lens drive device
JP2013156436A JP2013156436A (en) 2013-08-15
JP6049267B2 true JP6049267B2 (en) 2016-12-21
ID=49051674
JP2012016877A Active JP6049267B2 (en) 2012-01-30 2012-01-30 Lens drive device
JP (1) JP6049267B2 (en)
JP6192505B2 (en) * 2013-11-19 2017-09-06 日本電産コパル株式会社 Lens drive device
JP6192504B2 (en) * 2013-11-19 2017-09-06 日本電産コパル株式会社 Lens drive device
JP5369725B2 (en) * 2009-01-30 2013-12-18 株式会社ニコン Imaging device
JP5160467B2 (en) * 2009-02-16 2013-03-13 日本電産サンキョー株式会社 Lens drive device
JP5079049B2 (en) * 2009-11-17 2012-11-21 台湾東電化股▲ふん▼有限公司 Lens drive device
JP5063739B2 (en) * 2010-05-21 2012-10-31 Ｔｄｋ株式会社 Lens drive device
2012-01-30 JP JP2012016877A patent/JP6049267B2/en active Active
JP2013156436A (en) 2013-08-15
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JP4804564B2 (en) 2011-11-02 Optical apparatus having shake correction device
JP2013024938A (en) 2013-02-04 Lens drive device
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