JP5423989B2 - Lens drive device - Google Patents

Description

  The present invention relates to a lens driving device, and more particularly to a lens driving device capable of moving a lens holder (movable part) holding a lens assembly (lens barrel) in the optical axis direction of the lens.

  A portable small camera is mounted on a camera-equipped mobile phone. This portable small camera uses an autofocus lens driving device. Conventionally, various autofocus lens driving devices have been proposed. As a driving source (driving method) used in such a lens driving device, a VCM system using a voice coil motor (VCM) is known. The VCM lens driving device includes a driving coil and a magnetic circuit including a yoke and a permanent magnet as a driving source. The lens driving device is also called an actuator.

  The lens driving device (actuator) includes a lens holder having a cylindrical portion for holding the lens assembly. The drive coil is fixed to the lens holder so as to be positioned around the cylindrical portion. The permanent magnet is disposed to face the drive coil. The yoke holds a permanent magnet. The yoke includes a cylindrical shield yoke in which a permanent magnet is disposed on an inner wall surface, and a plurality of back yokes facing the permanent magnet with a drive coil interposed therebetween. A magnetic circuit composed of a yoke and a permanent magnet works as a fixed part together with the base. A pair of leaf springs are provided on both sides in the optical axis direction of the cylindrical portion of the lens holder. The pair of leaf springs support the lens holder so that it can be displaced in the optical axis direction in a state where the lens holder is positioned in the radial direction. Therefore, the lens holder (movable part) is arranged to be displaceable in the optical axis direction with a clearance from the magnetic circuit (fixed part).

  Of the pair of leaf springs, one is called an upper leaf spring and the other is called a lower leaf spring. However, in an actual usage situation, the optical axis direction is the front-rear direction, so the upper leaf spring is also called a front spring, and the lower leaf spring is also called a rear spring. The upper leaf spring (front spring) and the lower leaf spring (rear spring) generally have substantially the same shape.

  Conventionally, various lens driving devices have been proposed as prior art documents (patent documents).

  For example, Patent Document 1 (Japanese Patent Laid-Open No. 2006-58662) discloses an inner peripheral side end attached to a movable part and an outer peripheral side end attached to a fixed part as each of the front spring and the rear spring. The lens drive device using the leaf | plate spring which consists of a part and three arm parts (arm part) which connects an inner peripheral side edge part and an outer peripheral side edge part is disclosed. In Patent Document 1, each arm portion (arm portion) of the front spring and each arm portion (arm portion) of the rear spring are arranged at the same position in the circumferential direction.

  In Patent Document 2 (Japanese Patent Laid-Open No. 2008-26619), the front spring and the rear spring each have two arm portions (arm portions), and the arm portions (arm portions) are provided at positions orthogonal to each other. A lens driving device is disclosed.

  Further, Patent Document 3 (Japanese Patent Application Laid-Open No. 2008-13981) discloses an outer connecting portion connected to a support (fixed portion), an inner connecting portion connected to a moving lens body (movable portion), and an inner connecting portion. The lens drive device which has a spring member provided with a plurality of arm parts which connect an outer side connection part and an outside connection part is indicated. In the lens driving device disclosed in Patent Document 3, the arm portion is composed of two arms, and the spring member is separated from the first spring member having substantially the same shape of the arm portion at two locations separated in the optical axis direction. An example is disclosed in which the first spring member and the second spring member are arranged as a second spring member, and the angular positions are arranged in a direction shifted by 90 °.

Japanese Patent Laying-Open No. 2006-58662 (FIG. 2) JP 2008-26619 A ([Claim 3], FIG. 1 and FIG. 2) Japanese Patent Laying-Open No. 2008-13981 ([Claim 15], FIG. 1, FIG. 8)

  The autofocus lens driving device having such a configuration is required to be miniaturized as the portable compact camera is miniaturized. Therefore, it is necessary to reduce the size of the components that constitute the autofocus lens driving device. Due to such a demand for miniaturization, the permanent magnet as a component is miniaturized, so that the magnetic force (magnetic field) generated from the permanent magnet is weak (small). The leaf spring (spring member) is similarly reduced in size, but if the number of arm portions (arm portions) is 3 or more, the spring constant becomes too strong (large). In order to weaken (decrease) the spring constant, it is conceivable to reduce the plate thickness of the leaf spring (spring member), but there is a limit. As a result, as disclosed in Patent Document 2 and Patent Document 3, in order to weaken (reduce) the spring constant, in a small lens driving device, a plate spring (spring member having two arm portions) is used. ) Is used.

  As described above, in the actual use situation (shooting situation) of a portable small camera, generally, shooting is performed in a state where the optical axis direction (lens focus direction) is the front-rear direction (horizontal direction). Therefore, at the time of photographing, the upper leaf spring (front spring) is disposed in front of the lens holder (movable portion), and the lower leaf spring (rear spring) is disposed in front of the lens holder (movable portion).

  In the case where the number of arm portions is two, in Patent Documents 2 and 3, the front spring and the rear spring are arranged so that the arm portions are positioned at right angles to each other. In other words, the first spring member (rear side spring) and the second spring member (front side spring) are arranged so that the angular positions are shifted by 90 °.

  However, when the number of arm portions is two, the spring constant of the leaf spring (spring member) changes at a position in the circumferential direction (rotation direction in a plane orthogonal to the optical axis). Therefore, in the arrangement of the leaf spring (spring member) disclosed in Patent Documents 2 and 3, the direction of the maximum value of the spring constant in the circumferential direction of the front spring (second spring member) and the rear spring (first spring) are disclosed. The direction of the maximum value of the spring constant in the circumferential direction of the spring member) is perpendicular to each other (developed by 90 °). If the spring constant is large, the displacement of the leaf spring is small, and if the spring constant is small, the displacement of the leaf spring is large. Therefore, in the arrangement of the leaf spring (spring member) disclosed in Patent Documents 2 and 3, The inclination angle of the lens holder (movable part) becomes large. In other words, the tilt angle of the lens in an arbitrary rotation direction (circumferential direction) about the optical axis direction (focus direction) changes greatly.

  Therefore, the subject of this invention is providing the lens drive device which can make the inclination angle of the lens at the time of imaging | photography small.

  Another object of the present invention is to provide a lens driving device capable of reducing the tilt angle of the lens during photographing in a wide angle range.

  Other objects of the invention will become apparent as the description proceeds.

A lens driving device (10) according to an aspect of the present invention is a lens driving device capable of adjusting the position of a lens assembly in the optical axis (O) direction, and a lens holder (14) for holding the lens assembly; A ring-shaped drive coil (16) fixed so as to be positioned on the outer periphery of the motor; a fixed part including a permanent magnet (18) facing the drive coil and a yoke (20) holding the permanent magnet; A lens driving device comprising: a front spring (22) provided on the front side in the optical axis (O) direction of the lens holder; and a rear spring (24) provided on the rear side in the optical axis (O) direction of the lens holder. The front spring (22) and the rear spring (24) are respectively connected to an inner peripheral end (222; 242) attached to the lens holder and the fixed portion. Ri Tagged outer end portion (224; 244) and, two along a circumferential direction by connecting the outer peripheral side end portion and the inner peripheral end portion is provided to extend in only one direction The two arm portions (226; 246) are point-symmetric with respect to the optical axis (O). Each of the portions (226; 246) has a shape that is not mirror-reversed with respect to a straight line orthogonal to the optical axis (O), and the front spring (22 ) with respect to the optical axis (O). ) In the circumferential direction of the plane perpendicular to the optical axis (O) and the optical axis (O) of the rear spring (24) on the basis of the optical axis (O). The angle of depression between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the Characterized in that is within the angle in degrees.

In the lens driving device (10) of the present invention, the depression angle is preferably within an angle of 30 degrees. The included angle that is not more preferable is substantially 0 degree.

  The reference numerals in the parentheses are given for ease of understanding, and are merely examples, and of course are not limited thereto.

In the present invention, the two arm portions that connect the inner peripheral end and the outer peripheral end are point-symmetric with respect to the optical axis, but each of them is a mirror with respect to a straight line orthogonal to the optical axis. A front spring based on the optical axis in a lens driving device having a front spring and a rear spring having a non-inverted shape and extending in only one direction along the circumferential direction The direction of the maximum value of the spring constant in the circumferential direction of the plane perpendicular to the optical axis of the direction of the spring constant in the circumferential direction of the plane perpendicular to the optical axis of the rear spring, based on the optical axis, Since the depression angle is set within an angle of 45 degrees, the tilt angle of the lens at the time of shooting can be reduced.

It is a disassembled perspective view of the lens drive device which concerns on one embodiment of this invention. FIG. 3 is a plan view showing an arrangement relationship (“0 degree arrangement”) of an upper leaf spring (front spring) and a lower leaf spring (rear spring) used in the lens driving device shown in FIG. 1. With respect to the front spring shown in FIG. 2, the mounting position of the two arm portions is rotated 90 degrees clockwise around the optical axis, and the positional relationship between the front spring and the rear spring ("90 degree It is a top view which shows arrangement | positioning "). In the first case where the weight distribution of the movable part in the lens driving device shown in FIG. 1 is 50% for the front spring and 50% for the rear spring, the arrangement relationship between the front spring and the rear spring is “0”. Of the front spring and the rear spring in the "position of the degree" and the lens of the lens when rotated in any rotation direction (circumferential direction) about the optical axis direction (focus direction) in the horizontal orientation It is a figure which shows the simulation result which shows the change of an inclination angle (tilt). In the first case where the weight distribution of the movable part in the lens driving device shown in FIG. 1 is 50% for the front spring and 50% for the rear spring, the arrangement relationship between the front spring and the rear spring is “15”. Of the front spring and the rear spring in the "position of the degree" and the lens of the lens when rotated in any rotation direction (circumferential direction) about the optical axis direction (focus direction) in the horizontal orientation It is a figure which shows the simulation result which shows the change of an inclination angle (tilt). In the first case where the weight distribution of the movable part in the lens driving device shown in FIG. 1 is 50% for the front spring and 50% for the rear spring, the arrangement relationship between the front spring and the rear spring is “30”. Of the front spring and the rear spring in the "position of the degree" and the lens of the lens when rotated in any rotation direction (circumferential direction) about the optical axis direction (focus direction) in the horizontal orientation It is a figure which shows the simulation result which shows the change of an inclination angle (tilt). In the first case where the weight distribution of the movable part in the lens driving device shown in FIG. 1 is 50% for the front spring and 50% for the rear spring, the arrangement relationship between the front spring and the rear spring is “− Lens in the case of rotating in an arbitrary rotation direction (circumferential direction) around the optical axis direction (focus direction) in the horizontal posture and the spring constant in the circumferential direction of the front spring and the rear spring in the “15 degree arrangement” It is a figure which shows the simulation result which shows the change of the inclination angle (tilt). In the first case where the weight distribution of the movable part in the lens driving device shown in FIG. 1 is 50% for the front spring and 50% for the rear spring, the arrangement relationship between the front spring and the rear spring is “− The lens when rotating in an arbitrary rotation direction (circumferential direction) with the optical axis direction (focus direction) as the axis in the lateral orientation and the spring constant in the circumferential direction of the front spring and the rear spring in the “30 degree arrangement” It is a figure which shows the simulation result which shows the change of the inclination angle (tilt). In the second case where the weight distribution of the movable part in the lens driving device shown in FIG. 1 is 70% for the front spring and 30% for the rear spring, the arrangement relationship between the front spring and the rear spring is “0”. Of the front spring and the rear spring in the "position of the degree" and the lens of the lens when rotated in any rotation direction (circumferential direction) about the optical axis direction (focus direction) in the horizontal orientation It is a figure which shows the simulation result which shows the change of an inclination angle (tilt). In the second case where the weight distribution of the movable part in the lens driving device shown in FIG. 1 is 70% for the front spring and 30% for the rear spring, the arrangement relationship between the front spring and the rear spring is “15”. Of the front spring and the rear spring in the "position of the degree" and the lens of the lens when rotated in any rotation direction (circumferential direction) about the optical axis direction (focus direction) in the horizontal orientation It is a figure which shows the simulation result which shows the change of an inclination angle (tilt). In the second case where the weight distribution of the movable part in the lens driving device shown in FIG. 1 is 70% for the front spring and 30% for the rear spring, the arrangement relationship between the front spring and the rear spring is “30”. Of the front spring and the rear spring in the "position of the degree" and the lens of the lens when rotated in any rotation direction (circumferential direction) about the optical axis direction (focus direction) in the horizontal orientation It is a figure which shows the simulation result which shows the change of an inclination angle (tilt). In the second case where the weight distribution of the movable part in the lens driving device shown in FIG. 1 is 70% for the front spring and 30% for the rear spring, the arrangement relationship between the front spring and the rear spring is “− Lens in the case of rotating in an arbitrary rotation direction (circumferential direction) around the optical axis direction (focus direction) in the horizontal posture and the spring constant in the circumferential direction of the front spring and the rear spring in the “15 degree arrangement” It is a figure which shows the simulation result which shows the change of the inclination angle (tilt). In the second case where the weight distribution of the movable part in the lens driving device shown in FIG. 1 is 70% for the front spring and 30% for the rear spring, the arrangement relationship between the front spring and the rear spring is “− The lens when rotating in an arbitrary rotation direction (circumferential direction) with the optical axis direction (focus direction) as the axis in the lateral orientation and the spring constant in the circumferential direction of the front spring and the rear spring in the “30 degree arrangement” It is a figure which shows the simulation result which shows the change of the inclination angle (tilt).

  Embodiments of the present invention will be described below with reference to the drawings.

  A lens driving device 10 according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is an exploded perspective view of the lens driving device 10.

  Here, as shown in FIG. 1, an orthogonal coordinate system (X, Y, Z) is used. In the state illustrated in FIG. 1, in the orthogonal coordinate system (X, Y, Z), the X-axis direction is the front-rear direction (depth direction), the Y-axis direction is the left-right direction (width direction), and the Z-axis direction is The vertical direction (height direction). In the example shown in FIG. 1, the vertical direction Z is the optical axis O direction (focus direction) of the lens.

  However, in the actual use situation, the optical axis O direction (focus direction), that is, the Z-axis direction is the front-rear direction. In other words, the upward direction of the Z axis is the forward direction, and the downward direction of the Z axis is the backward direction.

  The illustrated lens driving device 10 is provided in a camera-equipped mobile phone capable of autofocusing. The lens driving device 10 is for moving a lens assembly (lens barrel) (not shown) in the optical axis O direction (focus direction). Therefore, the optical axis O is a drive axis. The lens driving device 10 is called an actuator. The lens driving device 10 includes an actuator base 12 disposed on the lower side (rear side) in the Z-axis direction (optical axis O direction). Although not shown, an imaging device arranged on a sensor substrate is mounted on the lower part (rear part) of the actuator base 12. The image sensor picks up a subject image formed by the lens assembly and converts it into an electrical signal. The imaging device is configured by, for example, a CCD (charge coupled device) type image sensor, a CMOS (complementary metal oxide semiconductor) type image sensor, or the like. Therefore, a camera module is configured by a combination of the lens driving device 10, the sensor substrate, and the image sensor.

  The lens driving device 10 is made of a resin-made lens holder 14 having a cylindrical portion 140 for holding a lens assembly (lens barrel), and is fixed to the lens holder 14 so as to be positioned around the cylindrical portion 140. The drive coil 16, the permanent magnet 18 disposed to face the drive coil 16, the yoke 20 that holds the permanent magnet 18, and the cylindrical portion 140 of the lens holder 14 are provided on both sides in the optical axis O direction. A pair of leaf springs 22 and 24 are provided. The permanent magnet 18 and the yoke 20 constitute a magnetic circuit. The pair of leaf springs 22 and 24 support the lens holder 14 so as to be displaceable in the optical axis O direction with the lens holder 14 positioned in the radial direction. Of the pair of leaf springs 22, 24, one leaf spring 22 is called an upper leaf spring, and the other leaf spring 24 is called a lower leaf spring.

  As described above, in the actual use situation of the camera-equipped mobile phone, the upward direction in the Z-axis direction (optical axis O direction) is the forward direction, and the downward direction in the Z-axis direction (optical axis O direction) is the backward direction. It becomes. Therefore, the upper leaf spring 22 is also called a front spring, and the lower leaf spring 24 is also called a rear spring.

  The upper leaf spring (front spring) 22 and the lower leaf spring (rear spring) 24 are made of a metal such as stainless steel or beryllium copper, for example. The upper leaf spring (front spring) 22 and the lower leaf spring (rear spring) 24 are manufactured by pressing a predetermined thin plate or etching using a photolithography technique. Note that the etching process is more preferable than the press process. This is because residual stress does not remain in the leaf spring in the etching process.

  The yoke 20 has a rectangular tube shape. That is, the yoke 20 includes a rectangular cylindrical outer cylindrical portion 202, a rectangular ring-shaped end portion 204 that extends to the inside of the outer cylindrical portion at the upper end of the outer cylindrical portion 202, and the ring-shaped end portion 204. The four inner vertical extending portions 206 extend vertically downward in parallel with the optical axis O at the four inner corners. The outer cylindrical portion 202 is called a shield yoke, and each of the four inner vertical extending portions 206 is called a back yoke.

  On the other hand, the drive coil 16 has a substantially octagonal cylindrical shape. That is, the drive coil 16 includes four long side portions 162 and four short side portions 164 arranged between the four long side portions. The cylindrical portion 140 of the lens holder 14 has four contact surfaces 140-1 projecting radially outward at an angular interval of 90 °. The four long sides 162 of the drive coil 16 are bonded to the four contact surfaces 140-1. That is, the drive coil 16 is bonded by the four contact surfaces 140-1.

  On the other hand, the permanent magnet 18 is composed of four rectangular (flat plate) permanent magnet pieces 182 facing the four long side portions 162 of the drive coil 16. The four rectangular permanent magnet pieces 182 are arranged on the inner wall surfaces of the four sides of the outer cylindrical portion (shield yoke) 202 of the yoke 20. In any case, the permanent magnet 18 is composed of four rectangular (flat plate-shaped) permanent magnet pieces 182 arranged on each side of the rectangular tube-shaped outer tube portion (shield yoke) 202 of the yoke 20.

  A permanent magnet 18 is disposed on the inner peripheral surface of the outer cylindrical portion (shield yoke) 202 of the yoke 20 at a distance from the drive coil 16.

  The upper leaf spring (front spring) 22 is disposed on the upper end side (front end side) in the optical axis O direction of the lens holder 14, and the lower leaf spring (rear spring) 24 is disposed on the lower end side in the optical axis O direction of the lens holder 14 ( (Rear end side).

  The upper leaf spring (front spring) 22 has an inner peripheral end 222 attached to the upper end (front end) of the lens holder 14 and an outer peripheral end 224 attached to the ring-shaped end 204 of the yoke 20 as described later. And have. Two arms 226 are provided between the inner peripheral end 222 and the outer peripheral end 224. Each arm part 226 is provided along the circumferential direction, and connects the inner peripheral end 222 and the outer peripheral end 224.

  An outer peripheral side end 224 of the upper leaf spring 22 is fixed to the cover 28 via a ring-shaped end 204 of the yoke 20. More specifically, the cover 28 has a square ring shape with a circular opening 28a at the center. The cover 28 has four protrusions 282 that protrude downward at its four corners. The ring-shaped end portion 204 of the yoke 20 has four insertion holes 204a into which the four protrusions 282 are inserted at the four corners. The outer peripheral side end 224 of the upper leaf spring 22 has four insertion holes 224a into which these four protrusions 282 are inserted. Therefore, the four protrusions 282 of the cover 28 are inserted into the four insertion holes 224 a of the outer peripheral side end portion 224 of the upper leaf spring (front spring) 22 through the four through holes 204 a of the ring-shaped upper end portion 204 of the yoke 20. Inserted.

  The lower leaf spring (rear spring) 24 includes an inner peripheral end 242 attached to the lower end (rear end) of the lens holder 14 as described later, and an outer peripheral end attached to the actuator base 12 as described later. Part 244. Two arm portions 246 are provided between the inner peripheral end portion 242 and the outer peripheral end portion 244. Each arm portion 246 is provided along the circumferential direction, and connects the inner peripheral end 242 and the outer peripheral end 244.

  The lens holder 14 has two fixing convex portions (not shown) for fixing the inner peripheral end 242 of the lower leaf spring (rear spring) 24 at the lower end (rear end) thereof. The inner peripheral end 242 of the lower leaf spring (rear spring) 24 has two insertion holes 242a into which these two fixing projections are inserted. The inner peripheral end 242 is fixed to the lower end (rear end) of the lens holder 14 by thermally welding these two fixing convex portions.

  On the other hand, an outer peripheral end 244 of the lower leaf spring (rear spring) 24 is fixed to the actuator base 12 by a spacer 30. More specifically, the actuator base 12 has a square ring shape with a circular opening 12a at the center. The actuator base 12 has four protrusions 122 protruding upward at the four corners thereof. The outer end 244 of the lower leaf spring (rear spring) 24 has four through holes 244a through which the four protrusions 122 are penetrated. The spacer 30 has four insertion holes 30a into which the four protrusions 122 are inserted. Accordingly, the four protrusions 122 of the actuator base 12 are fitted into the four fitting holes 30 a of the spacer 30 through the four through holes 244 a of the outer peripheral side end 244 of the lower leaf spring (rear spring) 24. .

  The lower end (rear end) of the lens holder 14 is loosely fitted into the circular opening 12 a of the actuator base 12. In other words, the lower end (rear end) of the lens holder 14 faces the circular opening 12a of the actuator base 12 with a clearance.

  A female screw 142 is cut on the inner peripheral wall of the cylindrical portion 140 of the lens holder 14. On the other hand, although not shown, a male screw that is screwed into the female screw 142 is cut on the outer peripheral wall of the lens assembly (lens barrel). Therefore, in order to attach the lens assembly (lens barrel) to the lens holder 14, the lens assembly (lens barrel) is rotated around the optical axis O with respect to the cylindrical portion 140 of the lens holder 14 and along the optical axis O direction. By screwing together, the lens assembly (lens barrel) is accommodated in the lens holder 14 and joined together with an adhesive.

  The lens driving device 10 includes a pair of electrodes 36 for supplying power to the driving coil 16. The actuator base 12 has a pair of insertion grooves 12b for inserting the pair of electrodes 36.

  By energizing the drive coil 16 through the pair of electrodes 36, the lens holder 14 (lens assembly) is positioned in the direction of the optical axis O by the interaction between the magnetic field of the permanent magnet 18 and the magnetic field generated by the current flowing through the drive coil 16. It is possible to adjust.

In the lens driving device 10, the combination of the lens holder 14 that holds the lens assembly and the driving coil 16 functions as a columnar movable portion (14, 16) disposed in the center portion. The combination of the actuator base 12, the permanent magnet 18, the yoke 20, and the cover 28 serves as a fixed portion (12, 18, 20, 28) disposed around the outer periphery of the movable portion (14, 16). Further, the cylindrical portion 140 of the lens holder 14 is provided with four contact portions 140-2 at the upper end thereof. These four contact portions 140-2 are stoppers that restrict excessive movement of the lens holder 14 by contacting the corresponding positions of the lower surfaces of the four extending portions 284 forming the circular opening 28a of the cover 28. As a role.

  FIG. 2 shows the positional relationship between the upper leaf spring (front spring) 22 and the lower leaf spring (rear spring) 24 used in the lens driving device 10 shown in FIG.

  As described above, in the actual usage situation (imaging situation) of the camera-equipped mobile phone, the upward direction in the Z-axis direction (optical axis O direction) is the forward direction, and the downward direction in the Z-axis direction (optical axis O direction) is Be backwards. Therefore, the backward direction in the X-axis direction is the upward direction, and the forward direction in the X-axis direction is the downward direction. The right direction in the Y-axis direction is equal to the right direction, and the left direction in the Y-axis direction is equal to the left direction. In the following description, the direction will be described using the direction in the actual use situation (shooting situation). In addition, the posture of the camera-equipped mobile phone in the actual usage situation (shooting situation) will be referred to as a “lateral orientation”.

  The arrangement relationship between the front spring 22 and the rear spring 24 shown in FIG. 2 is referred to herein as “0 degree arrangement”.

  In this “0 degree arrangement”, the rear spring 24 is rotated by about 30 degrees counterclockwise with respect to the vertical direction X, and its inner peripheral side end 242 is fixed to the rear end of the lens holder 14. Has been. In other words, the rear spring 24 has its two arm portions 246 extending in the circumferential direction from a position rotated about 30 degrees counterclockwise with respect to the vertical direction X. On the other hand, the front side spring 22 has two arm portions 246 extending in the circumferential direction from a substantially upper end and a substantially lower end of the inner peripheral end 242 thereof. That is, as for the front side spring 22, the two arm parts 225 are extended in the circumferential direction from the 0 degree position with respect to the up-down direction X. Therefore, each arm part 226 of the front side spring 22 and each arm part 246 of the rear side spring 24 are arranged at positions shifted by about 30 degrees in the circumferential direction.

  FIG. 3 shows the front spring 22 and the rear spring 24 that are rotated 90 degrees clockwise around the optical axis O with respect to the front spring 22 shown in FIG. The arrangement relationship is shown. The arrangement of the rear spring 24 is the same as that of the rear spring 24 shown in FIG. The arrangement relationship between the front spring 22 and the rear spring 24 shown in FIG. 3 is referred to herein as “90 degree arrangement”.

  In this “90-degree arrangement”, the rear spring 24 is rotated by about 30 degrees counterclockwise with respect to the vertical direction X, as in the case of FIG. It is fixed to the rear end of the lens holder 14. In other words, the rear spring 24 has its two arm portions 246 extending in the circumferential direction from a position rotated about 30 degrees counterclockwise with respect to the vertical direction X. On the other hand, the front spring 22 is rotated by 90 degrees clockwise with respect to the vertical direction X, and the two arm portions 246 extend in the circumferential direction from the substantially right end and the substantially left end of the inner peripheral end 242 thereof. Exist. That is, the front spring 22 has its two arm portions 225 extending in the circumferential direction from a position rotated 90 degrees clockwise relative to the vertical direction X. Accordingly, the arm portions 226 of the front spring 22 and the arm portions 246 of the rear spring 24 are arranged at positions shifted by about 120 degrees in the circumferential direction.

  Therefore, in the present specification, the “arrangement of degree A” means that the arrangement of the front springs 22 shown in FIG. 2 is not changed without changing the arrangement of the rear springs 24 shown in FIG. This means an arrangement relationship in which the mounting position of the arm portion 226 is rotated A degrees clockwise around the optical axis O. Further, in this specification, “the arrangement of −A degrees” means that the arrangement of the front springs 22 shown in FIG. 2 is not changed without changing the arrangement of the rear springs 24 shown in FIG. This means that the mounting position of the arm portion 226 is rotated by A degrees counterclockwise around the optical axis O.

  Next, referring to FIG. 4 to FIG. 13, the circumferential spring constants of the front spring 22 and the rear spring 24 with respect to the arrangement relationship of the front spring 22 and the rear spring 24, and the optical axis O direction ( A change in the tilt angle (tilt) of the lens when rotating in an arbitrary rotation direction (circumferential direction) about the focus direction will be described.

  Below, the simulation result which set the weight distribution of the movable part (14, 16) of the front side spring 22 and the rear side spring 24 which supports a movable part (14, 16) as follows in two cases is shown. The first case is a case where the weight distribution of the movable parts (14, 16) is 50% for the front spring 22 and 50% for the rear spring 24. The second case is a case where the weight distribution of the movable parts (14, 16) is 70% for the front spring 22 and 30% for the rear spring 24.

  First, simulation results in the first case where the weight distribution of the movable parts (14, 16) is 50% for the front spring 22 and 50% for the rear spring 24 will be described.

  4 to 8 show that when the weight distribution of the movable parts (14, 16) is the first, the arrangement relation of the front spring 22 and the rear spring 24 is “0 degree arrangement” and “15 degree arrangement”, respectively. The spring constants in the circumferential direction of the front spring 22 and the rear spring 24 and the light in the lateral orientation at the time of “arrangement”, “30 degree arrangement”, “−15 degree arrangement”, and “−30 degree arrangement”. It is a figure which shows the simulation result which shows the change of the inclination angle (tilt) of a lens at the time of rotating to the arbitrary rotation directions (circumferential direction) on the axis | shaft O direction (focus direction).

  In each of FIGS. 4 to 8, (A) shows the spring constants (N / mm) in the circumferential direction of the rear spring 24 and the front spring 22 by a solid line (BTM) and a one-dot chain line (TOP), respectively. (B) and (C) are respectively the lens driving device 10 (portable) with the arrangement relationship as shown in FIG. 2 as a reference (0 degree) with the optical axis O direction (focus direction) as an axis in the horizontal orientation. FIG. 6 is a pie chart and a characteristic diagram showing a change in the tilt angle (tilt) of the lens assembly when the compact camera is rotated clockwise in the circumferential direction. In (C), the horizontal axis indicates the angle (degrees) and the vertical axis indicates the tilt (minutes). When the lens assembly is not tilted, the tilt is 0 (minutes). When the lens assembly is tilted forward, the tilt has a positive value. When the lens assembly is tilted later, the tilt has a negative value.

  As shown in FIG. 4A, in the “0 degree arrangement”, the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O of the front spring 22 and the light of the rear spring 24. The included angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the axis O is about 30 degrees. As described above, in the “0 degree arrangement” (see FIG. 2), each arm portion 226 of the front spring 22 and each arm portion 246 of the rear spring 24 are displaced by about 30 degrees in the circumferential direction. This is because they are arranged at different positions. In this case, as shown in FIG. 4C, the tilt is moderately within ± 1 (min) in a wide angle range of 0 to about 70 degrees, about 120 to about 250 degrees, and about 300 to 360 degrees. You can see that it has changed.

  As shown in FIG. 5A, in the “15-degree arrangement”, the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O of the front spring 22 and the light of the rear spring 24. The included angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the axis O is about 45 degrees. This is because in the “15-degree arrangement”, each arm portion 226 of the front spring 22 and each arm portion 246 of the rear spring 24 are arranged at positions shifted by about 45 degrees in the circumferential direction. It is. In this case, from FIG. 5C, in the angle ranges of 0 to 60 degrees, 150 to 250 degrees, and 340 to 360 degrees, the tilt is moderately within ± 1 (min). You can see that it is changing.

  As shown in FIG. 6A, in the “30 degree arrangement”, the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O of the front spring 22 and the light of the rear spring 24. The included angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the axis O is about 60 degrees. This is because in the “30 degree arrangement”, each arm part 226 of the front spring 22 and each arm part 246 of the rear spring 24 are arranged at positions shifted by about 60 degrees in the circumferential direction. It is. In this case, as shown in FIG. 6C, the tilt is within ± 1 (min) only in a narrow angle range of 0 to 60 degrees, 175 to 250 degrees, and 350 to 360 degrees. It can be seen that it is changing slowly.

  As shown in FIG. 7 (A), in the “position of −15 degrees”, the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O of the front spring 22 and the rear spring 24 The depression angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O is about 15 degrees. This means that, in the “−15 degree arrangement”, each arm part 226 of the front spring 22 and each arm part 246 of the rear spring 24 are arranged at positions shifted by about 15 degrees in the circumferential direction. Because. In this case, from FIG. 7C, in a wide angle range where the rotation angle is 0 degree to about 75 degrees, about 125 degrees to about 260 degrees, and about 300 to 360 degrees, the tilt is moderately within ± 1 (min). You can see that it is changing.

  As shown in FIG. 8A, in the “-30 degree arrangement”, the direction of the maximum value of the spring constant in the circumferential direction of the plane perpendicular to the optical axis O of the front spring 22 and the rear spring 24 The depression angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O is about 0 degree. This is because in the “arrangement of −30 degrees”, the arm portions 226 of the front spring 22 and the arm portions 246 of the rear spring 24 are arranged at substantially the same positions in the circumferential direction. is there. In this case, it can be seen from FIG. 8C that the tilt changes gently within a range of ± 1 (min) over the entire rotation angle range.

  Subsequently, a simulation result in the second case in which the weight distribution of the movable parts (14, 16) is 70% for the front spring 22 and 30% for the rear spring 24 will be described.

  9 to 13 show that when the weight distribution of the movable parts (14, 16) is the second, the arrangement relationship between the front spring 22 and the rear spring 24 is “0 degree arrangement” and “15 degree arrangement”, respectively. The spring constants in the circumferential direction of the front spring 22 and the rear spring 24 and the light in the lateral orientation at the time of “arrangement”, “30 degree arrangement”, “−15 degree arrangement”, and “−30 degree arrangement”. It is a figure which shows the simulation result which shows the change of the inclination angle (tilt) of a lens at the time of rotating to the arbitrary rotation directions (circumferential direction) on the axis | shaft O direction (focus direction).

  In each of FIGS. 9 to 13, (A) shows the spring constants (N / mm) in the circumferential direction of the rear spring 24 and the front spring 22 by a solid line (BTM) and a one-dot chain line (TOP), respectively. (B) and (C) are respectively the lens driving device 10 (portable) with the arrangement relationship as shown in FIG. 2 as a reference (0 degree) with the optical axis O direction (focus direction) as an axis in the horizontal orientation. FIG. 6 is a pie chart and a characteristic diagram showing a change in the tilt angle (tilt) of the lens assembly when the compact camera is rotated clockwise in the circumferential direction. In (C), the horizontal axis indicates the angle (degrees) and the vertical axis indicates the tilt (minutes). When the lens assembly is not tilted, the tilt is 0 (minutes). When the lens assembly is tilted forward, the tilt has a positive value. When the lens assembly is tilted later, the tilt has a negative value.

  As shown in FIG. 9A, in the “0 degree arrangement”, the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O of the front spring 22 and the light of the rear spring 24. The included angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the axis O is about 30 degrees. As described above, in the “0 degree arrangement” (see FIG. 2), each arm portion 226 of the front spring 22 and each arm portion 246 of the rear spring 24 are displaced by about 30 degrees in the circumferential direction. This is because they are arranged at different positions. In this case, from FIG. 9C, the tilt is moderately within ± 1 (min) in a wide angle range of 0 to 75 degrees, 150 to 260 degrees, and 340 to 360 degrees. You can see that it has changed.

  As shown in FIG. 10A, in the “15 degree arrangement”, the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O of the front spring 22 and the light of the rear spring 24. The included angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the axis O is about 45 degrees. This is because in the “15-degree arrangement”, each arm portion 226 of the front spring 22 and each arm portion 246 of the rear spring 24 are arranged at positions shifted by about 45 degrees in the circumferential direction. It is. In this case, as shown in FIG. 10C, the tilt is moderately within ± 1 (min) in the angle ranges of 0 to 75 degrees, 170 to 260 degrees, and 350 to 360 degrees. You can see that it is changing.

  As shown in FIG. 11A, in the “30 degree arrangement”, the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O of the front spring 22 and the light of the rear spring 24. The included angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the axis O is about 60 degrees. This is because in the “30 degree arrangement”, each arm part 226 of the front spring 22 and each arm part 246 of the rear spring 24 are arranged at positions shifted by about 60 degrees in the circumferential direction. It is. In this case, as shown in FIG. 11C, the tilt changes gently within ± 1 (min) only in a narrow angle range where the rotation angle is 0 degree to about 75 degrees and about 175 degrees to about 260 degrees. I understand.

  As shown in FIG. 12 (A), in the “position of −15 degrees”, the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O of the front spring 22 and the rear spring 24 The depression angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O is about 15 degrees. This means that, in the “−15 degree arrangement”, each arm part 226 of the front spring 22 and each arm part 246 of the rear spring 24 are arranged at positions shifted by about 15 degrees in the circumferential direction. Because. In this case, from FIG. 12C, in a wide angle range where the rotation angle is 0 degree to about 90 degrees, about 130 degrees to about 270 degrees, and about 320 to 360 degrees, the tilt is moderately within ± 1 (min). You can see that it is changing.

  As shown in FIG. 13 (A), in the “arrangement of −30 degrees”, the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O of the front spring 22 and the rear spring 24 The depression angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane orthogonal to the optical axis O is about 0 degree. This is because in the “arrangement of −30 degrees”, the arm portions 226 of the front spring 22 and the arm portions 246 of the rear spring 24 are arranged at substantially the same positions in the circumferential direction. is there. In this case, from FIG. 13C, the tilt is ± 1 (min) in a very wide angle range where the rotation angle is 0 degree to about 60 degrees, about 110 degrees to about 250 degrees, and about 290 degrees to 360 degrees. It can be seen that there is a gradual change within.

  From the above, when the weight distribution of the movable parts (14, 16) is the first and second cases, the direction of the maximum value of the spring constant in the circumferential direction of the plane perpendicular to the optical axis O of the front spring 22 If the depression angle between the direction of the maximum value of the spring constant in the circumferential direction of the plane perpendicular to the optical axis O of the rear spring 24 is within a range of 45 degrees, the tilt can be adjusted in a wide angle range of the rotation angle. It can be seen that can be reduced. If the depression angle is within a range of 30 degrees, the tilt can be reduced in a wider angle range of the rotation angle. Further, when the depression angle is substantially 0 degree, the tilt can be reduced in a very wide angle range of the rotation angle.

  Although the present invention has been described with reference to preferred embodiments, it is obvious that various modifications can be made by those skilled in the art without departing from the spirit of the present invention. For example, in the above-described embodiment, two arm portions are provided along the circumferential direction in each leaf spring. However, the present invention is not limited to this.

10 Lens drive device (actuator)
DESCRIPTION OF SYMBOLS 12 Actuator base 12a Circular opening part 12b Insertion groove 122 Protrusion 14 Lens holder 140 Cylindrical part 140-1 Contact surface 142 Female screw 16 Drive coil 162 Long side part 164 Short side part 18 Permanent magnet 182 Flat permanent magnet piece 20 York 202 Shield yoke (outer cylinder)
204 Ring-shaped end portion 204a Insertion hole 206 Back yoke (inner vertical extending portion)
22 Upper leaf spring (front spring)
222 Inner peripheral end 224 Outer peripheral end 224a Through hole 226 Arm 24 Lower leaf spring (rear spring)
242 Inner peripheral side end 244 Outer peripheral side end 244a Insertion hole 246 Arm part 28 Cover 28a Circular opening 282 Projection 30 Spacer 30a Insertion hole 36 Electrode O Optical axis (drive shaft)

Claims (3)

A lens driving device capable of adjusting the position of the lens assembly in the optical axis direction,
A lens holder for holding the lens assembly;
A ring-shaped drive coil fixed so as to be located on the outer periphery of the lens holder;
A fixed portion including a permanent magnet facing the drive coil, and a yoke for holding the permanent magnet;
A front spring provided on the optical axis direction front side of the lens holder;
A rear spring provided on the rear side in the optical axis direction of the lens holder;
In a lens driving device comprising:
Each of the front spring and the rear spring includes an inner peripheral end attached to the lens holder, an outer peripheral end attached to the fixed portion, the inner peripheral end, and the outer peripheral end. Two arm portions provided to extend in only one direction along the circumferential direction by connecting the portions,
The two arm portions have a point-symmetric shape with respect to the optical axis, but each of the two arm portions has a shape that is not mirror-inverted with respect to a straight line orthogonal to the optical axis. And
The direction of the maximum value of the spring constant in the circumferential direction of the plane perpendicular to the optical axis of the front spring with respect to the optical axis and the optical axis of the rear spring with respect to the optical axis A lens driving device characterized in that a depression angle between the direction of the maximum value of the spring constant in the circumferential direction of the flat surface is within an angle of 45 degrees.   The lens driving device according to claim 1, wherein the depression angle is within an angle of 30 degrees.   The lens driving device according to claim 1, wherein the depression angle is substantially 0 degree.

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