JP7393196B2 - Lens drive device, camera module, and method for manufacturing lens drive device - Google Patents

Description

The present disclosure relates to a lens driving device mounted on, for example, a camera-equipped mobile device, a camera module including the lens driving device, and a method for manufacturing the lens driving device.

Conventionally, a lens driving device is known that includes a yoke, a lens holder (lens holding member), a coil disposed around the outer periphery of the lens holding member, and a driving magnet attached to the yoke so as to face the coil. (See Patent Document 1.) In this device, the lens holding member is held movably in the optical axis direction by a conductive leaf spring. Further, the lens holding member includes a detection magnet for detecting the position of the lens holding member. The position of the lens holding member is derived based on the output of a Hall sensor attached to a substrate such as a flexible printed circuit board so as to face the detection magnet. The derived position of the lens holding member is used for feedback control of the drive current flowing through the coil.

In this lens driving device, the substrate is attached to the outer wall of the protrusion that constitutes the base member so as to be perpendicular to the leaf spring. This is because the board is configured such that the external connection terminal of the leaf spring is inserted into a cone-shaped recess formed in the board and joined to the recess with solder.

JP2016-38444A

However, the above-mentioned protruding portion to which the substrate is attached is a thin plate-shaped portion that is configured to protrude upward from one side of the base member, which has a substantially rectangular annular shape when viewed from above. Therefore, the protrusion is likely to warp or deform. The warpage or deformation is caused by variations in the distance between the substrate and the lens holding member between products, typically between the Hall sensor attached to the substrate and the detection magnet attached to the lens holding member. This may increase the dispersion of the distance between the two.

Therefore, it is desired to provide a lens driving device that can suppress variations in the distance between the substrate and the lens holding member.

A lens driving device according to an embodiment of the present invention includes a lens holding member capable of holding a lens body, a housing in which the lens holding member is housed, and a support that supports the lens holding member movably in an optical axis direction. a coil held by the lens holding member, a driving magnet facing the coil, and a substrate on which a conductive pattern is formed, the conductive pattern being electrically connected to the coil via the support member. In the lens driving device, the housing includes a case made of synthetic resin and a lid member made of synthetic resin, and the case has a bottom wall portion formed with an opening and a rectangular cylindrical shape. an outer circumferential wall portion , the upper side facing the subject is open, and the lid member is disposed above the bottom wall portion facing the subject, and has a housing space for accommodating the supporting member. a ceiling wall portion having an opening formed therein and facing the bottom wall portion and coupled to the outer peripheral wall portion ; the substrate is fixed to an outer surface of the outer peripheral wall portion; A magnetic detection member for detecting the magnetic field of a detection magnet fixed to the lens holding member is mounted on the inner surface, and a metal plate as a plate-like member is arranged on the outer surface of the substrate. .

The above means provides a lens driving device that can suppress variations in the distance between the substrate and the lens holding member.

It is an exploded perspective view of a lens drive device. FIG. 3 is a top perspective view and a front view of the lens driving device. It is a figure which shows the assembly procedure of an upper side assembly. It is a figure which shows the assembly procedure of an upper side assembly. FIG. 3 is an enlarged view of a portion of the upper assembly. It is a top view of a leaf spring. It is a figure which shows the assembly procedure of a lens drive device. It is a figure which shows the assembly procedure of a lens drive device. It is a figure which shows the assembly procedure of a lens drive device. It is a figure which shows the assembly procedure of a lens drive device. It is a figure showing a part of lens drive device. It is a figure which shows the example of a structure of a lid member. It is a figure showing an example of composition of a wiring board. FIG. 3 is a diagram showing a pattern layer formed on a wiring board. It is a top perspective view of a drive magnet, a detection magnet, and a balance magnet. It is a front view of a lens drive device.

Hereinafter, a lens driving device 101 according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is an exploded perspective view of the lens driving device 101. FIG. 2 is an overall view of the lens driving device 101. Specifically, FIG. 2(A) is a top perspective view of the lens driving device 101, and FIG. 2(B) is a front view of the lens driving device 101 seen from the X1 side.

As shown in FIG. 1, the lens driving device 101 includes a lens holding member 2, a leaf spring 6, a wiring board 10, a housing HS, a driving mechanism MK, and a metal plate MP.

The lens holding member 2 has a substantially rectangular ring shape when viewed from above, and is configured to hold a lens body (not shown). The lens body is, for example, a cylindrical lens barrel including at least one lens, and is configured such that its central axis extends along the optical axis direction. The "optical axis direction" includes the direction of the optical axis JD with respect to the lens body and the direction parallel to the optical axis JD.

The drive mechanism MK is configured to be able to move the lens holding member 2 along the optical axis direction (Z-axis direction). Specifically, as shown in FIG. 1, the drive mechanism MK includes a coil 3 having two oval-shaped winding parts 13A, and a winding part of the coil 3 in the radial direction (direction perpendicular to the optical axis direction). 13A, a detection magnet 8 and a balance magnet 9 attached to the lens holding member 2, and a magnetic detection member 11 and a capacitor 14 attached to the wiring board 10. include. The two winding portions 13A are held by two opposing sides of the four side surfaces 2A of the lens holding member 2. The drive mechanism MK generates Lorentz force (driving force or thrust) by the current flowing through the coil 3 and the magnetic field generated by the drive magnet 5A, and moves the lens holding member 2 up and down along the optical axis direction. .

The leaf spring 6 is configured as a support member that supports the lens holding member 2 so as to be movable in the optical axis direction. In this embodiment, the leaf spring 6 includes an upper leaf spring 16 and a lower leaf spring 26. The upper leaf spring 16 includes a first upper leaf spring 16A1 and a second upper leaf spring 16A2.

Specifically, the leaf spring 6 is made of a conductive metal plate mainly made of copper alloy. With the lens holding member 2 and each of the leaf springs 6 (upper leaf spring 16 and lower leaf spring 26) engaged, the leaf spring 6 allows the lens holding member 2 to move in the optical axis direction (Z-axis direction). The lens holding member 2 is supported so as to be possible. The first upper leaf spring 16A1 and the second upper leaf spring 16A2 function as power feeding members for supplying current to the coil 3. Therefore, the first upper leaf spring 16A1 is electrically connected to one end of the coil 3, and the second upper leaf spring 16A2 is electrically connected to the other end of the coil 3.

The housing HS is configured as a fixed side member to which the leaf spring 6 is fixed. In this embodiment, the housing HS constitutes a rectangular box-shaped outer case. Specifically, the housing HS includes a lid member 1 made of synthetic resin and a case 4 made of synthetic resin. In this embodiment, the lid member 1 and the case 4 are made of the same synthetic resin. However, the lid member 1 and the case 4 may be made of different synthetic resins.

The upper leaf spring 16 is arranged to connect the upper end of the lens holding member 2 and the case 4, and the lower leaf spring 26 is arranged so as to connect the lower end of the lens holding member 2 and the case 4.

The lid member 1 has a rectangular annular and flat plate shape, and has an opening 1K formed in the center. The lid member 1 is configured to cover the upper surface of the case 4, which is formed to be open at the upper surface. However, the lid member 1 may be configured to cover the lower surface of the case 4, which is formed to be open at the lower surface.

As shown in FIG. 1, the case 4 has a box-like outer shape defining a housing space 4S represented by dot hatching. Specifically, the case 4 includes a rectangular cylindrical outer circumferential wall portion 4A and a flat annular bottom wall portion 4B that is provided so as to be continuous with the lower end (Z2 side end) of the outer circumferential wall portion 4A. An opening 4K is formed in the bottom wall portion 4B.

The outer peripheral wall portion 4A includes a first side wall portion 4A1 to a fourth side wall portion 4A4. Specifically, the outer circumferential wall 4A has a first side wall 4A1 and a second side wall 4A2 that face each other across the accommodation space 4S in a first direction (Y-axis direction) perpendicular to the optical axis direction, and and a third side wall portion 4A3 and a fourth side wall portion 4A4 that face each other across the accommodation space 4S in a second direction (X-axis direction) perpendicular to each of the first directions. Each of the first side wall portion 4A1 and the second side wall portion 4A2 is perpendicular to each of the third side wall portion 4A3 and the fourth side wall portion 4A4.

The lens holding member 2 is arranged so that its side surface 2A faces the outer peripheral wall 4A. Specifically, the side surface 2A of the lens holding member 2 includes a first side surface 2A1 to a fourth side surface 2A4. More specifically, the side surface 2A includes a first side surface 2A1 disposed to face the first side wall portion 4A1, a second side surface 2A2 disposed to face the second side wall portion 4A2, and a third side surface 2A2 disposed to face the second side wall portion 4A2. It includes a third side surface 2A3 arranged to face the side wall portion 4A3 and a fourth side surface 2A4 arranged to face the fourth side wall portion 4A4.

The coil 3 is electrically connected to the magnetic detection member 11 via the upper leaf spring 16 and the conductive pattern (wiring pattern) of the wiring board 10 . When a current flows into the coil 3 from the current control circuit (driver IC) provided in the magnetic detection member 11, the drive mechanism MK generates an electromagnetic force along the optical axis direction.

The driving magnet 5A includes a first driving magnet 5A1 arranged inside the first side wall part 4A1 so as to face the first side wall part 4A1, and a second side wall part 4A2 arranged so as to face the second side wall part 4A2. a second driving magnet 5A2 disposed inside the second driving magnet 5A2. An adhesive (not shown) is provided between the first side wall portion 4A1 and the first driving magnet 5A1 and between the second side wall portion 4A2 and the second driving magnet 5A2. That is, the first driving magnet 5A1 is adhesively fixed to the first side wall portion 4A1 using an adhesive, and the second driving magnet 5A2 is adhesively fixed to the second side wall portion 4A2 using an adhesive.

In this embodiment, the first driving magnet 5A1 is composed of a combination of two dipole magnets. However, the first driving magnet 5A1 may be composed of one dipole magnet or one quadrupole magnet. The same applies to the second driving magnet 5A2.

Specifically, the first driving magnet 5A1 includes a first upper magnet 5A1U and a first lower magnet 5A1L, as shown in FIG. The second driving magnet 5A2 includes a second upper magnet 5A2U and a second lower magnet 5A2L. The first upper magnet 5A1U, the first lower magnet 5A1L, the second upper magnet 5A2U, and the second lower magnet 5A2L all have a substantially rectangular parallelepiped shape extending in the second direction (X-axis direction).

The driving magnet 5A is arranged outside the coil 3 (wound portion 13A). Specifically, the first driving magnet 5A1 is arranged on the outside of the first winding part 13A1 held on the first side surface 2A1 at a distance from the first winding part 13A1, and the second driving magnet 5A2 is arranged on the outside of the second winding part 13A2 held on the second side surface 2A2 at a distance from the second winding part 13A2.

In this way, the case 4 accommodates the lens holding member 2, the coil 3, the driving magnet 5A, and the leaf spring 6 in the accommodation space 4S, and as shown in FIG. They are combined together with the lid member 1 to form a housing HS.

The detection magnet 8 is a bipolar magnet attached to the lens holding member 2 in order to detect the position of the lens holding member 2 in the optical axis direction. The detection magnet 8 is arranged at one corner of the lens holding member 2. Specifically, as shown in FIGS. 3(A) and 3(B), the detection magnet 8 is inserted into the recess 8R formed at the corner between the second side surface 2A2 and the third side surface 2A3. is embedded in. The magnetism generated by the detection magnet 8 is detected by a magnetic detection member 11 attached to the wiring board 10.

The balance magnet 9 is a bipolar magnet attached to the lens holding member 2 in order to offset the influence of the weight of the detection magnet 8 on the weight balance of the lens holding member 2. In this embodiment, the balance magnet 9 is the same dipole magnet as the detection magnet 8 and has the same weight as the detection magnet 8. The balance magnet 9 is arranged at another corner of the lens holding member 2. Specifically, as shown in FIGS. 3(A) and 3(B), the balance magnet 9 is inserted into a recess 9R formed at a corner between the first side surface 2A1 and the fourth side surface 2A4. is embedded in. That is, the balance magnet 9 is arranged at a corner on the opposite side of the optical axis JD from the corner where the detection magnet 8 is arranged.

In this embodiment, both the detection magnet 8 and the balance magnet 9 are fixed to the lens holding member 2 with an adhesive AD1, as shown in FIG. 3(C). Specifically, the detection magnet 8 is adhesively fixed with an adhesive AD1 applied inside the recess 8R, and the balance magnet 9 is adhesively fixed with an adhesive AD1 applied inside the recess 9R.

The magnetic detection member 11 includes a magnetic sensor that detects the magnetism generated by the detection magnet 8 and a driver IC that includes a built-in current control circuit that controls the current flowing through the coil 3 . The magnetic sensor is, for example, a Hall element. In this embodiment, the magnetic detection member 11 is constituted by an electronic component in which a Hall element and a chip constituting a driver IC are housed in one package.

The wiring board 10 is a member on which a conductive wiring pattern as a conductive pattern is formed. In this embodiment, the wiring board 10 is a double-sided flexible printed circuit board, and is attached to the outer surface of the outer peripheral wall 4A of the case 4. Specifically, the wiring board 10 is adhesively fixed to the outer surface (the surface on the X1 side) of the third side wall portion 4A3 that constitutes the outer peripheral wall portion 4A.

The metal plate MP is a member that reinforces the outer peripheral wall portion 4A of the case 4. In this embodiment, the metal plate MP is made of a non-magnetic material such as austenitic stainless steel. The metal plate MP is connected to the wiring attached to the third side wall 4A3 in order to reinforce the third side wall 4A3 to which the wiring board 10 is attached among the four side walls forming the outer peripheral wall 4A. It is attached to the third side wall portion 4A3 on the outside of the substrate 10. This is because the third side wall portion 4A3 has lower rigidity than the other three side wall portions. The low rigidity of the third side wall portion 4A3 is mainly due to the presence of the through hole 4H for receiving the magnetic detection member 11 and the capacitor 14 attached to the wiring board 10. Specifically, the metal plate MP is adhesively fixed to the third side wall portion 4A3 so that the wiring board 10 is sandwiched between the metal plate MP and the third side wall portion 4A3. In this respect, the metal plate MP also has a function of protecting the wiring board 10 and a function of supporting the wiring board 10. An adhesive is typically placed between the inner surface of the metal plate MP and the outer surface of the wiring board 10. Note that the metal plate MP as a plate-like member may be replaced with a reinforcing plate (support plate) made of synthetic resin, or may be omitted.

The lens driving device 101 has a substantially rectangular parallelepiped shape and is mounted on a main substrate (not shown) on which an image sensor (not shown) is mounted. The camera module includes a main board, a lens driving device 101, a lens body attached to the lens holding member 2, and an image sensor mounted on the main board so as to face the lens body.

The lens drive device 101 realizes an automatic focus adjustment function by moving the lens holding member 2 along the optical axis direction on the Z1 side (subject side) of the image sensor using electromagnetic force generated by the drive mechanism MK. do. Specifically, the lens driving device 101 moves the lens holding member 2 in a direction away from the image sensor to enable macro photography, and moves the lens holding member 2 in a direction toward the image sensor to enable infinity photography. I have to.

Next, a method for assembling the upper assembly UA will be described with reference to FIGS. 3 and 4. 3 and 4 show the assembly procedure of the upper assembly UA. The upper assembly UA includes a lens holding member 2, a coil 3, a detection magnet 8, a balance magnet 9, and an upper leaf spring 16.

FIG. 3 includes three perspective views of the lens holding member 2 showing the lower surface (Z2 side surface) of the lens holding member 2. Specifically, FIG. 3(A) shows the lens holding member 2 before the detection magnet 8 and the balance magnet 9 are attached, and FIG. 3(B) shows the lens holding member 2 before the detection magnet 8 and the balance magnet 9 are attached. The lens holding member 2 is shown after being attached, and FIG. 3(C) shows the lens holding member 2 after being coated with adhesive AD1 for adhesively fixing the detection magnet 8 and the balance magnet 9 to the lens holding member 2. Part 2 is shown. In addition, in FIG. 3(B), a dot pattern is attached to the detection magnet 8 and the balance magnet 9 for clarity. In FIG. 3C, a dot pattern is attached to the adhesive AD1 for clarity.

FIG. 4 includes four top perspective views of the lens holding member 2 after the detection magnet 8 and the balance magnet 9 have been attached. Specifically, FIG. 4(A) shows the lens holding member 2 before the coil 3 is attached, FIG. 4(B) shows the lens holding member 2 after the coil 3 is attached, and FIG. (C) shows the lens holding member 2 after being coated with a conductive adhesive AD2 for adhesively fixing the coil 3 and the upper leaf spring 16 in a conductive manner. Moreover, FIG. 4(D) shows the lens holding member 2 after the upper leaf spring 16 is attached. That is, FIG. 4(D) shows a state in which the upper assembly UA is assembled. Note that in FIG. 4(B), a dot pattern is attached to the coil 3 for clarity. In FIG. 4C, a dot pattern is attached to the conductive adhesive AD2 for clarity. In FIG. 4(D), a dot pattern is attached to the upper leaf spring 16 for clarity.

Lens holding member 2 is typically made of synthetic resin. In this embodiment, the lens holding member 2 is manufactured by injection molding liquid crystal polymer (LCP).

As shown in FIG. 3(A), the end surface of the lens holding member 2 on the imaging element side (Z2 side) has a recess 8R for receiving the detection magnet 8 and a recess 9R for receiving the balance magnet 9. is formed. Specifically, a recess 8R is formed at the corner located between the second side surface 2A2 and the third side surface 2A3, and a recess 9R is formed at the corner located between the first side surface 2A1 and the fourth side surface 2A4. It is formed.

The recess 8R has an opening 8K that opens toward the third side surface 2A3 side (X1 side). Therefore, the detection magnet 8 fitted into the recess 8R exposes the flat surface 8A at the third side surface 2A3, as shown in FIGS. 1 and 3(B). With this configuration, the detection magnet 8 can bring the flat surface 8A close to the Hall element in the magnetic detection member 11.

On the other hand, the recess 9R does not have an opening like the opening 8K. Therefore, the balance magnet 9 fitted into the recess 9R does not have its surface exposed on the fourth side surface 2A4, as shown in FIG. 3(B). With this configuration, the lens holding member 2 can prevent the balance magnet 9 and the connecting portion 3C of the coil 3 (see FIG. 4(B)) from coming into contact with each other.

The recess 8R in which the detection magnet 8 is fitted and the recess 9R in which the balance magnet 9 is fitted are filled with adhesive AD1, as shown in FIG. 3(C). The detection magnet 8 and the balance magnet 9 are adhesively fixed to the lens holding member 2 by this adhesive AD1.

Further, as shown in FIG. 3(A), the lens holding member 2 includes a cylindrical portion 12 that extends along the optical axis direction and is formed with a through hole for receiving a lens body. The cylindrical portion 12 is provided with a thread groove on its cylindrical inner circumferential surface so that a lens body can be attached thereto. Further, as shown in FIG. 3(A), the cylindrical portion 12 is provided with a lower pedestal portion 12d having four depressions 12dh on the end surface on the imaging element side (Z2 side). The lower pedestal portion 12d is placed on the inner portion 26i (see FIG. 1) of the lower leaf spring 26 with adhesive (not shown) applied to the recess 12dh. The lower end portion of the lens holding member 2 is adhesively fixed to the lower leaf spring 26 with this adhesive.

As shown in FIGS. 3(A) and 4(A), a winding protrusion 12p for holding the winding portion 13A of the coil 3 is provided on the outer peripheral surface of the cylindrical portion 12. In the present embodiment, the winding protrusion 12p approximately protrudes from the outer peripheral surface of the cylindrical portion 12 in the radial direction (Y1 direction and Y2 direction) so that the winding portion 13A is wound around an axis perpendicular to the optical axis direction. It has a rectangular parallelepiped shape. Specifically, the winding projection 12p includes a first winding projection 12p1 around which the first winding portion 13A1 is wound, and a second winding projection 12p2 around which the second winding portion 13A2 is wound.

The coil 3 is formed by winding a conductive wire around a winding protrusion 12p, as shown in FIG. 4(B). Specifically, the coil 3 has a first winding portion 13A1 arranged to face the first side wall portion 4A1 (see FIG. 1), and a first winding portion 13A1 facing the second side wall portion 4A2 (see FIG. 1). It includes a second winding part 13A2 arranged as shown in FIG. In this embodiment, the winding portion 13A is fixed to the winding protrusion 12p without using an adhesive, but may be adhesively fixed to the winding projection 12p using an adhesive. Further, the winding direction of the winding portion 13A is arbitrary and determined according to the arrangement (magnetization direction) of the driving magnet 5A.

For clarity, FIG. 4B omits a detailed illustration of the winding state of the conductive wire whose surface is coated with an insulating member with respect to the winding portion 13A. The same applies to other figures illustrating the winding portion 13A.

As shown in FIG. 4(A), the lens holding member 2 includes two holding parts 72 as square convex protrusions that protrude upward (in the Z1 direction) from the end surface on the subject side (Z1 side), and a round holding part 72. It includes four protruding portions 2T having a convex shape.

As shown in FIG. 4(B), the holding part 72 includes a first holding part 72A1 corresponding to the first extending part 33A1, which is the wire rod part on the winding end side of the coil 3, and a wire rod part on the winding start side of the coil 3. A second holding portion 72A2 corresponding to the second extension portion 33A2 is included. In this way, both ends of the coil 3 are wound around and held by the holding part 72.

Specifically, the first extending portion 33A1 includes a wrapping portion 33m that is wound around the first holding portion 72A1, and a facing portion 33c that extends to face the upper surface (Z1 side surface) of the lens holding member 2. Similarly, the second extending portion 33A2 includes a wrapping portion 33m that is wound around the second holding portion 72A2, and a facing portion 33c that extends opposite to the upper surface (Z1 side surface) of the lens holding member 2.

In this embodiment, the second extending portion 33A2 is wound around the second holding portion 72A2 of the lens holding member 2 before the wire forming the coil 3 is wound around the outer periphery of the second winding protrusion 12p2. In the example shown in FIG. 4(B), the wire forming the coil 3 is wound around the second holding portion 72A2 for three turns. As a result, the wrapping portion 33m is formed on the second holding portion 72A2, and a portion of the second extending portion 33A2 is held on the second holding portion 72A2. However, the second extending portion 33A2 may be wound around the second holding portion 72A2 after the wire forming the coil 3 is wound around the outer periphery of the second winding protrusion 12p2.

After the second winding part 13A2 is formed, the connecting part 3C is formed by the wire pulled out from the second winding part 13A2. After the connecting portion 3C is formed, the wire is also wound around the outer periphery of the first winding protrusion 12p1. When the winding of the wire around the outer periphery of the second winding protrusion 12p2 and the winding of the wire around the outer periphery of the first winding protrusion 12p1 are completed, the first The extending portion 33A1 is pulled out to the upper surface side of the lens holding member 2. Specifically, the facing portion 33c extends to face the upper surface of the lens holding member 2, and the wrapping portion 33m is wound around the first holding portion 72A1. In the example shown in FIG. 4(B), the wire forming the coil 3 is wound around the first holding portion 72A1 in three turns.

Specifically, as shown in FIG. 5(A), the opposing portion 33c of the first extending portion 33A1 passes through the adhesive reservoir RS1, which is a recess formed in the upper end surface of the lens holding member 2. It is located. FIG. 5(A) is an enlarged view of a region R1 surrounded by a broken line in FIG. 4(B). Then, the conductive adhesive AD2 is applied to the adhesive reservoir RS1 before the upper leaf spring 16 is attached to the lens holding member 2, as shown in FIG. 5(B). The conductive adhesive AD2 is, for example, an adhesive in which a conductive filler such as silver particles is dispersed in a synthetic resin. FIG. 5(B) is an enlarged view of the region R2 surrounded by the broken line in FIG. 4(C). In the example shown in FIG. 5(B), the conductive adhesive AD2 is attached to the lower surface (Z2 side surface) of the connection plate portion 16h (see FIG. 4(D)) of the upper leaf spring 16. It is applied so as to protrude upward from the agent reservoir RS1. In this way, the connection plate portion 16h of the upper leaf spring 16 is electrically and physically connected to the coil 3.

After the conductive adhesive AD2 is applied to the adhesive reservoir RS1, the upper leaf spring 16 is placed on the upper surface of the lens holding member 2, as shown in FIG. 4(D). As shown in FIG. 6A, the upper leaf spring 16 includes a first upper leaf spring 16A1 and a second upper leaf spring 16A2 that are arranged substantially symmetrically when viewed from above. FIG. 6(A) is a top view of the upper leaf spring 16. Specifically, each of the first upper leaf spring 16A1 and the second upper leaf spring 16A2 has an outer portion 16e as a first fixing portion fixed to the case 4, and a second fixing portion fixed to the lens holding member 2. and two elastic arms 16g located between the inner portion 16i and the outer portion 16e. Each of the first upper leaf spring 16A1 and the second upper leaf spring 16A2 is configured to have a substantially semicircular inner shape so as to correspond to the shape of the cylindrical portion 12 of the lens holding member 2. .

Specifically, the inner portion 16i mainly includes a first joint portion 16c1, a second joint portion 16c2, a third joint portion 16c3, a first connecting portion 16p1, a second connecting portion 16p2, and a connecting plate portion 16h. has been done. The inner portion 16i is provided to face the upper pedestal portion 12u (see FIG. 4(C)) of the lens holding member 2.

More specifically, the first joint part 16c1, the second joint part 16c2, and the third joint part 16c3 are parts joined to the lens holding member 2, and are the parts of the upper pedestal part 12u shown in FIG. 4(C). They are placed on the first pedestal section 12u1, the second pedestal section 12u2, and the third pedestal section 12u3, respectively. The first connecting portion 16p1 is a portion that connects the connecting plate portion 16h and the second connecting portion 16c2, and the second connecting portion 16p2 is a portion that connects the first connecting portion 16c1 and the third connecting portion 16c3. . The connecting plate portion 16h is connected to the first joint portion 16c1, and is arranged to face the facing portion 33c of each of the first extending portion 33A1 and the second extending portion 33A2.

The outer portion 16e has two corner portions 16b and a crosspiece 16s connecting the two corner portions 16b.

When the upper leaf spring 16 is attached to the lens holding member 2, the inner portion 16i is placed on the upper pedestal portion 12u (see FIG. 4C) of the lens holding member 2. At this time, as shown in FIG. 4(D), the protruding portion 2T of the lens holding member 2 has a through hole 16R ( (See Fig. 6(A).). The protruding portions 2T include two protruding portions 2T corresponding to the first upper leaf spring 16A1 and two protruding portions 2T corresponding to the second upper leaf spring 16A2.

Fixing of the inner portion 16i and the lens holding member 2 is achieved by hot caulking or cold caulking the protruding portion 2T inserted through the through hole 16R. In FIG. 4(D), the protruding portion 2T is shown in a deformed state after being hot caulked. The same applies to other figures showing the protruding portion 2T.

Further, the inner portion 16i of the upper leaf spring 16 is attached to the lens holding member by the conductive adhesive AD2 (see FIG. 5(B)) applied to the adhesive reservoir RS1 formed on the upper end surface of the lens holding member 2. 2 and the coil 3 with adhesive. Specifically, the conductive adhesive AD2 applied so as to wrap around the facing portion 33c in the adhesive reservoir RS1 hardens while in contact with the lower surface (Z2 side surface) of the connecting plate portion 16h in the inner portion 16i.

In this way, the protruding portion 2T of the lens holding member 2 is caulked to join the lens holding member 2 and the upper leaf spring 16, and the conductive adhesive AD2 is thermoset to bond the coil 3 and the upper leaf spring 16. Spring 16 is connected. Application of the conductive adhesive AD2 to the adhesive reservoir RS1, caulking of the protruding portion 2T, and thermal curing of the conductive adhesive AD2 are performed when the lens holding member 2 is placed so that the holding portion 72 protrudes vertically upward. It is done in a closed state. Therefore, even if the conductive adhesive AD2 has fluidity, it can be appropriately held at a desired position (position within the adhesive reservoir RS1). A portion of the opposing portion 33c is disposed within the adhesive reservoir RS1 and is therefore buried within the conductive adhesive AD2. Note that the conductive adhesive AD2 is not limited to a thermosetting type, and may be an ultraviolet curing type or a moisture curing type.

Next, a method for assembling the lens driving device 101 will be described with reference to FIGS. 7 to 10. 7 to 10 show the assembly procedure of the lens driving device 101.

FIG. 7 includes three top perspective views of the case 4. FIG. Specifically, FIG. 7(A) shows the case 4 before the lower leaf spring 26 is attached, FIG. 7(B) shows the case 4 after the lower leaf spring 26 is attached, and FIG. (C) shows the case 4 after the first lower magnet 5A1L (invisible) and the second lower magnet 5A2L are further attached. In FIG. 7A, for clarity, a dot pattern is attached to a first accommodation space 4S1 and a second accommodation space 4S2, which will be described later. In FIG. 7(B), a dot pattern is attached to the lower leaf spring 26 for clarity. In FIG. 7C, a dot pattern is attached to the second lower magnet 5A2L for clarity.

FIG. 8, like FIG. 7, includes three top perspective views of the case 4. Specifically, FIG. 8(A) shows the case 4 after the first upper magnet 5A1U and second upper magnet 5A2U are further attached, and FIG. 8(B) shows the case 4 after the upper assembly UA is further attached. FIG. 8C shows the case 4 after the damping material DM is further attached. In FIG. 8(A), a dot pattern is attached to a protrusion 4C, which will be described later, for clarity. In FIG. 8(B), a dot pattern is attached to the upper assembly UA for clarity. In FIG. 8(C), a dot pattern is attached to the damping material DM for clarity.

FIG. 9, like FIG. 7, includes three top perspective views of the case 4. Specifically, FIG. 9(A) shows the case 4 after the lid member 1 is further attached, FIG. 9(B) shows the case 4 after the wiring board 10 is further attached, and FIG. 9(C) shows the case 4 after the metal plate MP is further attached. In FIG. 9(A), a dot pattern is attached to the lid member 1 for clarity. In FIG. 9B, a dot pattern is attached to the wiring board 10 for clarity. In FIG. 9C, a dot pattern is attached to the metal plate MP for clarity.

FIG. 10, like FIG. 7, includes two top perspective views of the case 4. Specifically, FIG. 10(A) shows the case 4 after the conductive adhesive AD4 has been applied between the upper leaf spring 16 and the wiring board 10, and FIG. 10(B) shows the case 4 after further sealing. Case 4 is shown after material EC has been applied. In FIG. 10A, a dot pattern is attached to the conductive adhesive AD4 for clarity. In FIG. 10(B), a dot pattern is attached to the sealing material EC for clarity.

Case 4 is typically made of synthetic resin. In this embodiment, the case 4 is manufactured by injection molding liquid crystal polymer (LCP). The case 4 has an accommodation space 4S for accommodating the lens holding member 2, the coil 3, the driving magnet 5A, and the leaf spring 6, as shown in FIG.

Specifically, as shown in FIG. 7(A), the housing space 4S includes a first housing space 4S1 for housing the first driving magnet 5A1, and a first housing space 4S1 for housing the second driving magnet 5A2. It includes a second accommodation space 4S2. For clarity, FIG. 7A shows the first accommodation space 4S1 and the second accommodation space 4S2 in a dot pattern.

As shown in FIG. 7(B), a part of the lower leaf spring 26 is fitted into the second accommodation space 4S2 before the second driving magnet 5A2 is accommodated. The same applies to the first accommodation space 4S1.

The lower leaf spring 26 has a substantially rectangular outer shape when viewed from above, as shown in FIG. 6(B). FIG. 6(B) is a top view of the lower leaf spring 26. Specifically, the lower leaf spring 26 includes an outer portion 26e as a first fixing portion fixed to the case 4, an inner portion 26i serving as a second fixing portion fixed to the lens holding member 2, and an outer portion 26e. and an elastic arm portion 26g provided between the inner portion 26i and the inner portion 26i. The outer portion 26e includes a first outer portion 26e1 fitted into the first accommodation space 4S1 and a second outer portion 26e2 fitted into the second accommodation space 4S2.

As shown in FIGS. 7(A) and 7(B), the bottom wall portion 4B of the case 4 includes a base portion 4B1 on which the outer portion 26e of the lower leaf spring 26 is placed, an inner portion 26i, and an elastic arm portion. 26g and a base portion 4B2 facing each other. Both the inner portion 26i and the elastic arm portion 26g are arranged so as not to contact the base portion 4B2.

Specifically, as shown in FIG. 11(C), the base portion 4B1 is configured to protrude upward (in the Z1 direction) from the upper surface of the base portion 4B2 by a height HT1. The base portion 4B1 functions as a placement portion on which the outer portion 26e of the lower leaf spring 26 is placed.

FIG. 11 is a diagram showing a part of the case 4. As shown in FIG. Specifically, FIG. 11(A) is a top view of the region R3 surrounded by the broken line in FIG. 7(B). FIG. 11(B) is a top view of the region R4 surrounded by the broken line in FIG. 7(C). FIG. 11(C) is a perspective view of a cross section in a virtual plane parallel to the YZ plane including the dashed line L1 shown in FIG. 11(B).

As shown in FIGS. 7(B) and 11(C), the second outer portion 26e2 of the lower leaf spring 26 is placed on the upper surface of the base portion 4B1 constituting the bottom surface of the second accommodation space 4S2. Similarly, although it is not visible in FIGS. 7(B) and 11(C), the first outer portion 26e1 of the lower leaf spring 26 is mounted on the upper surface of the base portion 4B1 that constitutes the bottom surface of the first accommodation space 4S1. placed. Due to this placement, the inner portion 26i and the elastic arm portion 26g located between the first outer portion 26e1 and the second outer portion 26e2 are held so as not to contact the base portion 4B2.

After the second outer portion 26e2 of the lower leaf spring 26 is fitted into the second housing space 4S2 as shown in FIG. 7(B), an adhesive (not shown) is applied to the inner surface of the second side wall portion 4A2. ) is applied. The adhesive may be applied to the inner surface of the second side wall portion 4A2 before the second outer portion 26e2 is fitted into the second accommodation space 4S2.

Thereafter, the second lower magnet 5A2L is accommodated in the second accommodation space 4S2, as shown in FIG. 7(C). Similarly, although it is not visible in FIGS. 7(B) and 7(C), the first outer portion 26e1 of the lower leaf spring 26 is fitted into the first housing space 4S1, and the first outer portion 26e1 of the first side wall portion 4A1 is fitted into the first accommodation space 4S1. After the adhesive is applied to the inner surface, the first lower magnet 5A1L is housed. As a result, the first outer portion 26e1 of the lower leaf spring 26 is sandwiched and fixed between the upper surface of the base portion 4B1 that constitutes the bottom surface of the first accommodation space 4S1 and the lower surface of the first lower magnet 5A1L. Similarly, as shown in FIG. 11(C), the second outer portion 26e2 of the lower leaf spring 26 is connected to the upper surface of the base portion 4B1 that constitutes the bottom surface of the second accommodation space 4S2 and the lower surface of the second lower magnet 5A2L. It is fixed by being sandwiched between.

Note that instead of forming the base portion 4B1 on the bottom wall portion 4B of the case 4, a spacer member as a separate member may be arranged on the bottom wall portion 4B (base portion 4B2). In this case, the spacer member is formed into a frame shape.

The second driving magnet 5A2 extends in the X-axis direction, which is a direction perpendicular to the optical axis direction. As shown in FIGS. 11(B) and 11(C), the inner surfaces of both ends (Y1 side surface) of the second driving magnet 5A2 in the extending direction It is in contact with the surface PS. Further, the outer surface (Y2 side surface) of the second driving magnet 5A2 comes into contact with two crush ribs CR formed on the inner surface (Y1 side surface) of the second side wall portion 4A2 that constitutes the outer peripheral wall portion 4A. ing. The same applies to the first driving magnet 5A1 accommodated in the first accommodation space 4S1.

The crush rib CR shown in FIG. 11(C) is a structure used when press-fitting the second driving magnet 5A2 into the second housing space 4S2. The crush rib CR is configured to be deformable (crushable) so that the second driving magnet 5A2 can be fixed without wobbling by the crush rib CR and the positioning surface PS. Therefore, the outer surface (Y2 side surface) of the second driving magnet 5A2 fixed in the second housing space 4S2 is not in contact with the inner surface (Y1 side surface) of the second side wall portion 4A2, except for the crush rib CR. I haven't. The number of crush ribs CR formed on the inner surface of the second side wall portion 4A2 may be one or three or more as long as the second driving magnet 5A2 can be fixed without wobbling. good.

The positioning surface PS is a flat surface formed on a part of the protrusion 4C provided at the four corners of the outer peripheral wall 4A, and is configured to face the inner surface of the outer peripheral wall 4A.

The protrusion 4C is a portion that protrudes upward (Z1 direction) from the bottom wall 4B along the optical axis direction, and includes a first protrusion 4C1 to a fourth protrusion 4C4. The protrusion 4C also serves to increase the rigidity of the outer peripheral wall 4A. Specifically, as shown in FIG. 8(A), the first protrusion 4C1 is formed at a corner located between the first side wall 4A1 and the fourth side wall 4A4, and the second protrusion 4C2 is formed at a corner located between the first side wall 4A1 and the fourth side wall 4A4. , is formed at a corner located between the first side wall portion 4A1 and the third side wall portion 4A3, and the third protrusion portion 4C3 is formed at a corner located between the second side wall portion 4A2 and the third side wall portion 4A3. The fourth protruding portion 4C4 is formed at a corner located between the second side wall portion 4A2 and the fourth side wall portion 4A4. Note that in FIG. 8(A), the first protrusion 4C1 to the fourth protrusion 4C4 are shown by dot hatching for clarity.

In the example shown in FIG. 11(C), the crush rib CR is configured such that the distance between the crush rib CR and the positioning surface PS in the Y-axis direction is slightly smaller than the thickness of the second driving magnet 5A2. ing. Therefore, when the second driving magnet 5A2 is housed (press-fitted) in the second housing space 4S2, the crush rib CR is crushed by the outer surface (Y2 side surface) of the second driving magnet 5A2. As a result, the second driving magnet 5A2 is fixed without wobbling between the crush rib CR and the positioning surface PS.

Specifically, the crush rib CR has a tapered portion CR1 and a parallel portion CR2, as shown in FIG. 11(C). The tapered portion CR1 is a structure for guiding the second driving magnet 5A2 to a desired fixed position. The parallel portion CR2 has a structure that extends parallel to the positioning surface PS in the Z-axis direction.

Thereafter, as shown in FIG. 8(A), the first upper magnet 5A1U is accommodated in the first accommodation space 4S1 in the same procedure as when the first lower magnet 5A1L is accommodated, and the first upper magnet 5A1U is accommodated in the second accommodation space 4S1. 4S2 accommodates the second upper magnet 5A2U in the same procedure as the case where the second lower magnet 5A2L is accommodated.

Thereafter, as shown in FIG. 8(A), an insulating adhesive AD3 is applied to the upper surface of each of the first upper magnet 5A1U and the second upper magnet 5A2U. In FIG. 8A, adhesive AD3 is cross-hatched for clarity.

Thereafter, as shown in FIG. 8(B), the upper assembly UA (see FIG. 4(D)) is attached within the accommodation space 4S. Adhesive AD3 is applied between the driving magnet 5A and the outer portion 16e of the upper leaf spring 16 in order to prevent the driving magnet 5A and the outer portion 16e of the upper leaf spring 16 from coming into direct contact.

Specifically, the upper assembly UA is adhered to the four depressions 12dh (see FIG. 3(A)) in the lower pedestal portion 12d formed on the end surface of the lens holding member 2 on the image sensor side (Z2 side). It is accommodated in the accommodation space 4S with the agent (not shown) applied thereto and with the lower pedestal portion 12d facing downward. The lower pedestal portion 12d is in contact with the inner portion 26i (see FIG. 8(A)) of the lower leaf spring 26, and the adhesive applied to the four depressions 12dh is on the upper surface (Z1 side surface) of the inner portion 26i. By adhering to and solidifying, it is adhesively fixed to the inner portion 26i.

The outer portion 16e of the upper leaf spring 16 is placed on the upper end surface of the protrusion 4C, as shown in FIG. 8(B). A protrusion 4P is formed on the upper end surface of the protrusion 4C. The protrusion 4P that protrudes upward from the upper end surface of the protrusion 4C is inserted into a penetration portion 16T (see FIG. 6A) formed in the corner portion 16b of the outer portion 16e of the upper leaf spring 16. In addition, in FIG. 8(B), the protrusion 4P is shown in a state in which the tip thereof is deformed after being hot caulked. The same applies to other figures showing the protrusion 4P.

The penetrating portion 16T includes a through hole 16T1 and a notch 16T2, as shown in FIG. 6(A). The cutout 16T2 is formed to open toward the X1 direction. This is to absorb variations in the distance between the two protrusions 4P due to dimensional tolerances of the lens holding member 2. Alternatively, this is to absorb variations in the distance between the through hole 16T1 and the notch 16T2 due to dimensional tolerances of the upper leaf spring 16.

Specifically, the protrusion 4P includes a first protrusion 4P1 to a fourth protrusion 4P4, as shown in FIG. 8(B). The first protrusion 4P1 protrudes upward from the upper end surface of the first protrusion 4C1. Similarly, the second protrusion 4P2 protrudes upward from the upper end surface of the second protrusion 4C2, the third protrusion 4P3 protrudes upward from the upper end surface of the third protrusion 4C3, and the fourth protrusion 4P4 protrudes upward from the upper end surface of the second protrusion 4C2. It protrudes upward from the upper end surface of the portion 4C4. The first projection 4P1 is inserted into the through hole 16T1 of the first upper leaf spring 16A1, the second projection 4P2 is inserted into the notch 16T2 of the first upper leaf spring 16A1, and the third projection 4P3 is inserted into the second upper leaf spring 16A1. The fourth protrusion 4P4 is inserted into the notch 16T2 of the side leaf spring 16A2, and the fourth protrusion 4P4 is inserted into the through hole 16T1 of the second upper leaf spring 16A2. With this configuration, the corner portion 16b of the upper leaf spring 16 is positioned with respect to the case 4.

In this way, the upper leaf spring 16 is connected to the lens holding member 2 via the inner portion 16i as shown in FIG. 4(D), and is connected to the lens holding member 2 via the outer portion 16e as shown in FIG. 8(B). Connected to case 4. With this configuration, the upper leaf spring 16 can support the lens holding member 2 in a well-balanced manner while being movable in the optical axis direction.

Thereafter, as shown in FIG. 8(C), a damping material DM is attached between the lens holding member 2 and the case 4. The damping material DM is a member for suppressing vibration of the lens holding member 2. The damping material DM is configured to be able to elastically expand and contract in accordance with the movement of the lens holding member 2. In this embodiment, the vibration damping material DM is configured to be able to suppress vibrations of the lens holding member 2 without affecting the original movement of the lens holding member 2. Specifically, the damping material DM is a gel-like damper material formed by curing a fluid adhesive with ultraviolet rays or heat, and the first damping material DM1 to the fourth damping material DM4 are include. The damping material DM may be made of other materials such as thermosetting resin, ultraviolet curable resin, thermosetting silicone rubber, or ultraviolet curable silicone rubber.

The first damping material DM1 has one end attached to the receiving surface CS1 (see FIG. 4(A)) that constitutes the end on the X2 side of the first side surface 2A1, which is the side surface on the Y1 side of the lens holding member 2, The other end is attached to the inner surface (Y2 side surface) of the first protruding portion 4C1 (see FIG. 8(A)) of the case 4.

The second damping material DM2 has one end attached to the receiving surface CS2 (see FIG. 4(A)) that constitutes the end on the X1 side of the first side surface 2A1, which is the side surface on the Y1 side of the lens holding member 2, The other end is attached to the inner surface (Y2 side surface) of the second protrusion 4C2 (see FIG. 8(A)) of the case 4.

The third damping material DM3 has one end attached to the receiving surface CS3 (see FIG. 4(A)) that constitutes the end on the X1 side of the second side surface 2A2, which is the side surface on the Y2 side of the lens holding member 2, The other end is attached to the inner surface (Y1 side surface) of the third protrusion 4C3 (see FIG. 8(A)) of the case 4.

The fourth damping material DM4 has one end attached to the receiving surface CS4 (see FIG. 4(A)) that constitutes the end on the X2 side of the second side surface 2A2, which is the side surface on the Y2 side of the lens holding member 2, The other end is attached to the inner surface (Y1 side surface) of the fourth protrusion 4C4 (see FIG. 8(A)) of the case 4.

Thereafter, as shown in FIG. 9(A), the lid member 1 is attached to the case 4 so as to cover the upper surface of the case 4. The lid member 1 is typically made of synthetic resin. In this embodiment, the lid member 1 is manufactured by injection molding liquid crystal polymer (LCP), which is the same synthetic resin material as the lens holding member 2.

Here, details of the lid member 1 will be explained with reference to FIG. 12. FIG. 12 includes three views of the lid member 1. FIG. Specifically, FIG. 12(A) is a perspective view of the lid member 1 showing the top surface (Z1 side surface) of the lid member 1, and FIG. 12(B) is a perspective view of the lid member 1 showing the bottom surface (Z2 side surface). 12(C) is a top view of the lid member 1. FIG.

As shown in FIG. 12(A), the lid member 1 is a member having a substantially rectangular ring shape when viewed from above, and has a substantially circular opening 1K formed in the center. Further, upper recesses 1R are formed at the four corners of the object side (Z1 side) surface (upper surface) of the lid member 1, and a through hole 1T as a penetrating portion is formed in the upper recess 1R. Specifically, the upper recess 1R includes a first upper recess 1R1 to a fourth upper recess 1R4. The through hole 1T includes a first through hole 1T1 to a fourth through hole 1T4. In FIG. 12A, the upper recess 1R is shown by dot hatching for clarity. The four through holes 1T are formed at positions corresponding to the protrusions 4P formed on the upper end surface of the protruding parts 4C (see FIG. 8(A)) at the four corners of the case 4.

The protrusion 4P is inserted into the through-hole 16T provided at the corner portion 16b of the upper leaf spring 16, and then inserted into the through-hole 1T provided at the four corners of the lid member 1, and heat caulked. The lid member 1 is fixed to the case 4 by this heat caulking. As a result, the upper leaf spring 16 is fixed while being sandwiched between the upper end surface of the protrusion 4C and the lower surface of the four corners of the lid member 1.

At this time, a part of the crosspiece 16s of the upper leaf spring 16 is also connected to the upper surface of each of the first side wall 4A1 and the second side wall 4A2 and the lid member 1 at a position where the upper wall 4W described later is not formed. It is sandwiched between the bottom surface of the

As shown in FIG. 12(B), the lower surface of the lid member 1 is formed with a lower recessed portion 1S recessed upward, at least in a portion facing the elastic arm portion 16g of the upper leaf spring 16. In FIG. 12(B), the lower recess 1S is shown by dot hatching for clarity. This configuration allows upward movement of the lens holding member 2 and elastic deformation of the elastic arm portion 16g accompanying this movement.

The upper recess 1R and the lower recess 1S are provided so as to hardly overlap in the optical axis direction, as shown in FIG. 12(C). In FIG. 12C, for clarity, the range of the lower recess 1S, which is actually invisible, is shown with a broken line. This configuration can prevent the thickness of the lid member 1 in the Z-axis direction from becoming excessively thin. Therefore, this configuration can increase the rigidity of the lid member 1. Note that the upper recess 1R and the lower recess 1S may be provided so as not to overlap at all in the optical axis direction.

Upper wall portions 4W are formed at the four corners of the case 4, as shown in FIGS. 8(C) and 9(A). The upper wall portion 4W is formed so as to be adjacent to the outer peripheral end surface at the corner of the lid member 1, which has a substantially rectangular outer shape, when the lid member 1 is attached to the case 4.

Specifically, the upper wall portion 4W includes a first upper wall portion 4W1 arranged to surround the outside of the first protrusion 4P1, and a second upper wall portion arranged to surround the outside of the second projection 4P2. 4W2, a third upper wall portion 4W3 disposed so as to surround the outside of the third protrusion 4P3, and a fourth upper side wall portion 4W4 disposed so as to surround the outside of the fourth protrusion 4P4 (see also FIG. 11(C)). ).

More specifically, as shown in FIG. 9(A), the first upper wall 4W1 is formed adjacent to the outer peripheral end surface of the first upper recess 1R1 of the lid member 1, and the second upper wall 4W2 is formed adjacent to the outer circumferential end surface (excluding the portion facing the third side wall 4A3) of the second upper recess 1R2 of the lid member 1, and the third upper wall 4W3 is formed adjacent to the outer peripheral end surface of the second upper recess 1R2 of the lid member 1. The fourth upper wall 4W4 is formed adjacent to the outer peripheral end surface of the upper recess 1R3 (excluding the portion facing the third side wall 4A3), and the fourth upper wall 4W4 is adjacent to the outer peripheral end surface of the fourth upper recess 1R4 of the lid member 1. It is formed to do so.

Thereafter, as shown in FIG. 9(B), the wiring board 10 is attached to the third side wall portion 4A3 of the case 4. Specifically, the wiring board 10 is adhesively fixed to the third side wall portion 4A3 with an adhesive applied in a recess RS2 (see FIG. 9(A)) formed in the third side wall portion 4A3.

Here, details of the wiring board 10 will be explained with reference to FIGS. 13 and 14. FIG. 13 includes three views of wiring board 10. FIG. Specifically, FIG. 13(A) is a perspective view of the wiring board 10. FIG. 13(B) is a rear view of the wiring board 10 when the wiring board 10 is viewed from the X2 side. FIG. 13(C) is a front view of the wiring board 10 when the wiring board 10 is viewed from the X1 side. FIG. 13A shows a state in which the magnetic detection member 11 and the capacitor 14 are attached to the inner surface (X2 side surface) of the wiring board 10 by soldering. The magnetic detection member 11 is housed in a first through hole 4H1 (see FIG. 9(A)), which is one of the through holes 4H, and is housed in a third side surface 2A3 (see FIG. 3(A)) of the lens holding member 2. B)) is arranged so as to face the detection magnet 8 that exposes the flat surface 8A. The capacitor 14 is housed in a second through hole 4H2 (see FIG. 9(A)), which is another one of the through holes 4H. Note that the gap between the wiring board 10 and the magnetic detection member 11 is sealed with an underfill UF as shown in FIG. 13(A). In FIG. 13(A), dot hatching is added to the underfill UF for clarity. In FIG. 13(B), illustration of the magnetic detection member 11 and the capacitor 14 is omitted for clarity. In addition, in FIG. 13(B), "VSS" represents the ground voltage, "VDD" represents the power supply voltage, "SDA" represents the data signal, "SCL" represents the clock signal, and "OUT1" represents the 1 current output, and "OUT2" represents the second current output.

FIG. 14 is a diagram showing two pattern layers formed on the wiring board 10. Specifically, FIG. 14(A) visually shows the actually invisible inner pattern layer 10L1 arranged on the inner surface (X2 side surface) of the wiring board 10, and FIG. 14(B) shows the wiring An actually invisible outer pattern layer 10L2 disposed on the outer surface (X1 side surface) of the substrate 10 is visually shown. 14(A) and 14(B), the size of the installation area of the magnetic detection member 11 is represented by a range P11 surrounded by a broken line, and the size of the installation area of the capacitor 14 is represented by a range P11 surrounded by a broken line. It is represented by range P14.

The wiring board 10 is a double-sided printed board on which conductive wiring patterns are formed on both sides, and includes an inner pattern layer 10L1 disposed on the inner surface of the base made of a heat-resistant polyimide film, and a base. and an outer pattern layer 10L2 arranged on the outer surface of the outer pattern layer 10L2. A portion of the inner pattern layer 10L1 is covered with an insulating inner resist layer 10R1 (see FIG. 13(B)), and a portion of the outer pattern layer 10L2 is covered with an insulating outer resist layer 10R2 (see FIG. 13(C). ). In this embodiment, the wiring board 10 is configured as a flexible wiring board, but it may be a rigid wiring board or a rigid-flexible wiring board.

The wiring patterns in each of the inner pattern layer 10L1 and the outer pattern layer 10L2 are made of copper, for example. In this embodiment, each of the inner pattern layer 10L1 and the outer pattern layer 10L2 includes a copper foil layer and a copper plating layer covering the copper foil layer.

The wiring board 10 is attached to the third side wall portion 4A3 so that the wiring pattern on the main board and the magnetic detection member 11 are electrically connected. In this embodiment, the wiring pattern on the wiring board 10 and the wiring pattern on the main board are joined by solder as a joining material. However, the wiring pattern on the wiring board 10 and the wiring pattern on the main board may be bonded using a conductive adhesive as a bonding material.

As shown in FIG. 13A, the magnetic detection member 11 and the capacitor 14 are attached to the inner surface (X2 side surface) of the wiring board 10 by soldering, and then the magnetic detection member 11 and the capacitor 14 are attached together with the wiring board 10, that is, the wiring board 10 It is attached to the case 4 in a state where it is attached to the case 4. Specifically, the magnetic detection member 11 and the capacitor 14 are housed in the through hole 4H, as shown in FIGS. 9(A) and 9(B).

The inner pattern layer 10L1 has a land portion, as shown in FIG. 14(A). The land portion includes a first land portion LD1 to an eighth land portion LD8. Specifically, the inner pattern layer 10L1 includes first land portions LD1 to sixth land portions LD6 connected to six connection portions (not shown) on the magnetic detection member 11, and two electrodes (not shown) on the capacitor 14. ), which are connected to a seventh land portion LD7 and an eighth land portion LD8.

In this embodiment, the six connecting portions (terminals) of the magnetic detection member 11 and the first land portion LD1 to the sixth land portion LD6 are joined by soldering. Similarly, the two electrodes of the capacitor 14 and the seventh land portion LD7 and the eighth land portion LD8 are joined by soldering. Capacitor 14 is a bypass capacitor connected between the power supply voltage and ground voltage.

The first land portion LD1 is a land portion connected to a terminal for ground voltage. The second land portion LD2 is a land portion connected to a power supply voltage terminal. The third land portion LD3 is a land portion connected to a data signal terminal. The fourth land portion LD4 is a land portion connected to a terminal for a clock signal. The fifth land portion LD5 and the sixth land portion LD6 are land portions used for outputting the current flowing through the coil 3. The output of the current flowing through the coil 3 is controlled by a driver IC (current control circuit) in the magnetic detection member 11.

The outer pattern layer 10L2 is configured such that the first terminal portion TM1 to the sixth terminal portion TM6 are exposed when the lens driving device 101 is assembled, as shown in FIG. 2(B).

The first terminal portion TM1 is a terminal for first current output. Specifically, the first terminal portion TM1 is connected to the first connection portion 10C1 via the wiring pattern of the outer pattern layer 10L2, as shown in FIG. 14(B). Further, the first terminal portion TM1 is connected to the first connecting portion 10C1 and the fifth land portion via the wiring pattern of the outer pattern layer 10L2, the via hole V1, and the wiring pattern of the inner pattern layer 10L1 (see FIG. 14(A)). It is connected to LD5.

The second terminal portion TM2 is a terminal connected to the ground voltage. Specifically, as shown in FIG. 14(B), the second terminal portion TM2 includes a wiring pattern of the outer pattern layer 10L2, a via hole V2, and a wiring pattern of the inner pattern layer 10L1 (see FIG. 14(A)). It is connected to the first land portion LD1 and the seventh land portion LD7 via.

The third terminal portion TM3 is a terminal connected to the power supply voltage. Specifically, as shown in FIG. 14(B), the third terminal portion TM3 includes a wiring pattern of the outer pattern layer 10L2, a via hole V3, and a wiring pattern of the inner pattern layer 10L1 (see FIG. 14(A)). It is connected to the second land portion LD2 and the eighth land portion LD8 via.

The fourth terminal portion TM4 is a terminal for data signals. Specifically, as shown in FIG. 14(B), the fourth terminal portion TM4 includes a wiring pattern of the outer pattern layer 10L2, a via hole V4, and a wiring pattern of the inner pattern layer 10L1 (see FIG. 14(A)). It is connected to the third land portion LD3 via.

The fifth terminal portion TM5 is a terminal for a clock signal. Specifically, as shown in FIG. 14(B), the fifth terminal portion TM5 includes a wiring pattern of the outer pattern layer 10L2, a via hole V5, and a wiring pattern of the inner pattern layer 10L1 (see FIG. 14(A)). It is connected to the fourth land portion LD4 via.

The sixth terminal portion TM6 is a terminal for second current output. Specifically, the sixth terminal portion TM6 is connected to the second connection portion 10C2 via the wiring pattern of the outer pattern layer 10L2, as shown in FIG. 14(B). Further, the sixth terminal portion TM6 is connected to the second connecting portion 10C2 and the sixth land portion via the wiring pattern of the outer pattern layer 10L2, the via hole V6, and the wiring pattern of the inner pattern layer 10L1 (see FIG. 14(A)). It is connected to LD6.

As shown in FIG. 13(A), a first recessed portion 10U1 and a second recessed portion 10U2 are formed in the upper end portion 10U of the wiring board 10 (see FIG. 16). The first connecting portion 10C1 is formed on both sides of the wiring board 10 adjacent to the first recessed portion 10U1, and the second connecting portion 10C2 is formed on both sides of the wiring board 10 adjacent to the second recessed portion 10U2. has been done.

Note that the first connection portion 10C1 of the inner pattern layer 10L1 and the first connection portion 10C1 of the outer pattern layer 10L2 are electrically connected to each other. The same applies to the second connection portion 10C2. The connecting portion 10C (the first connecting portion 10C1 and the second connecting portion 10C2) is a conductive pattern formed on the wiring board 10.

With this configuration, the driver IC in the magnetic detection member 11 can receive a command regarding the target position of the lens holding member 2 in the optical axis direction from an external control device or the like through the fourth terminal portion TM4, for example. Then, the driver IC identifies the current position of the lens holding member 2 based on the magnitude of the magnetic field detected by the Hall element, and determines the current position of the lens holding member 2 so that the difference between the current position and the target position becomes zero. The direction and magnitude of the current flowing through the coil 3 can be controlled. That is, the driver IC can realize feedback control of the position of the lens holding member 2 in the optical axis direction.

After the wiring board 10 is attached to the third side wall portion 4A3 of the case 4, a metal plate MP is attached to the outside of the wiring board 10 to the third side wall portion 4A3, as shown in FIG. 9(C). Specifically, the metal plate MP is adhesively fixed to the wiring board 10 with an adhesive (not shown) applied to the outer surface of the wiring board 10, and the recess RS3 and the recess RS3 formed in the third side wall 4A3. It is adhesively fixed to the third side wall portion 4A3 by an adhesive (not shown) applied in the recessed portion RS4 (see FIG. 9(B)).

Moreover, as shown in FIG. 9(C), a notch CT is formed in the metal plate MP. The cutout CT includes a first cutout CT1 to a fourth cutout CT4. The first notch CT1 is formed to fit into the protrusion PR1 (see FIG. 9(B)). The second notch CT2 is formed to fit into the protrusion PR2 (see FIG. 9(B)). The third notch CT3 is formed at a position corresponding to the first connecting portion 10C1 so that the first connecting portion 10C1 is exposed to the outside. The fourth notch CT4 is formed at a position corresponding to the second connecting portion 10C2 so that the second connecting portion 10C2 is exposed to the outside.

After the metal plate MP is attached to the third side wall portion 4A3, as shown in FIG. 10(A), a conductive adhesive AD4 is applied to each of the first connection portion 10C1 and the second connection portion 10C2. Specifically, the conductive adhesive AD4 is applied to the connection terminal portion PT1 of the first upper leaf spring 16A1 disposed within the second recessed portion 10U2 of the wiring board 10 (see FIGS. 6(A) and 8(B)). ) and the second connection portion 10C2 of the wiring board 10 to establish electrical continuity between the connection terminal portion PT1 and the second connection portion 10C2. Similarly, the conductive adhesive AD4 is applied to the connection terminal portion PT2 of the second upper leaf spring 16A2 disposed within the first recessed portion 10U1 of the wiring board 10 (see FIGS. 6(A) and 8(B)). and the first connection portion 10C1 of the wiring board 10 to establish electrical continuity between the connection terminal portion PT2 and the first connection portion 10C1. Note that, as shown in FIG. 6(A), the connection terminal portion PT1 is a part of the outer portion 16e of the first upper leaf spring 16A1, extends from the corner portion 16b, and faces the second connection portion 10C2. It is configured. Similarly, the connection terminal portion PT2 is a part of the outer portion 16e of the second upper leaf spring 16A2, extends from the corner portion 16b, and is configured to face the first connection portion 10C1.

After the wiring board 10 and the upper leaf spring 16 are connected with the conductive adhesive AD4, as shown in FIG. Encapsulant EC is applied. In the example shown in FIG. 10(B), the sealing material EC is attached to the outer peripheral end surface of the lid member 1 so as to fill the gap formed between the outer peripheral end surface of the lid member 1 and the outer peripheral wall portion 4A of the case 4. They are placed all around. Further, the sealing material EC is arranged around the protrusion 4P in the upper recess 1R of the cover member 1 so as to fill the gap formed between the through hole 1T of the cover member 1 and the protrusion 4P. Further, the sealing material EC is attached to the metal plate MP and the housing so as to fill the gap between the notch CT of the metal plate MP (see FIG. 9(C)) and the housing HS (lid member 1 and case 4). It is located between the body HS and the body HS. Note that the sealing material EC may be the same adhesive as the adhesive used for fixing the metal plate MP to the third side wall portion 4A3 of the case 4.

Next, with reference to FIG. 15, an example of the magnetic pole arrangement of each of the drive magnet 5A, the detection magnet 8, and the balance magnet 9 will be described. FIG. 15 is a top perspective view of the coil 3, drive magnet 5A, detection magnet 8, and balance magnet 9 that are built into the lens drive device 101. For clarity, FIG. 15 omits illustration of components other than the coil 3, drive magnet 5A, detection magnet 8, and balance magnet 9 among the components constituting the lens drive device 101. . Further, in FIG. 15, the north pole of the magnet is represented by diagonal hatching, and the south pole of the magnet is represented by cross hatching.

In the example of FIG. 15, the first upper magnet 5A1U and the first lower magnet 5A1L of the first driving magnet 5A1, the second upper magnet 5A2U and the second lower magnet 5A2L of the second driving magnet 5A2, and the detection magnet 8 , and the balance magnet 9 are all composed of dipole magnets.

Specifically, the first upper magnet 5A1U has its inner side (Y2 side) magnetized to the N pole, and its outer side (Y1 side) to the S pole. The first lower magnet 5A1L has an S pole magnetized on the inside (Y2 side) and a N pole on the outside (Y1 side). The second upper magnet 5A2U has an inner side (Y1 side) magnetized to a north pole, and an outer side (Y2 side) to a south pole. The second lower magnet 5A2L is magnetized to have an S pole on the inside (Y1 side) and a N pole on the outside (Y2 side).

The detection magnet 8 has an upper side (Z1 side) magnetized to an S pole, and a lower side (Z2 side) to an N pole. Similarly, the balance magnet 9 has an upper side (Z1 side) magnetized to the S pole, and a lower side (Z2 side) to the N pole.

In this configuration, when a current flows from the first connection portion 10C1 to the second connection portion 10C2 of the wiring board 10, the current flows as shown by arrows AR1 to AR5. Specifically, the current flows from the second extending portion 33A2 to the first extending portion 33A1 via the second winding portion 13A2, the connecting portion 3C, and the first winding portion 13A1. Note that the first extending portion 33A1 is electrically connected to the second connecting portion 10C2 via the first upper leaf spring 16A1, and the second extending portion 33A2 is electrically connected to the first connecting portion 10C2 via the second upper leaf spring 16A2. It is electrically connected to the connecting portion 10C1.

Therefore, in the upper part of the first winding part 13A1 facing the inner surface of the first upper magnet 5A1U, the current flows from the X1 side to the X2 side, and conversely, the current flows against the inner surface of the first lower magnet 5A1L. In the lower portion of the first winding portion 13A1, the current flows from the X2 side to the X1 side. Further, in the upper part of the second winding portion 13A2 facing the inner surface of the second upper magnet 5A2U, the current flows from the X2 side to the X1 side, and conversely, the current flows against the inner surface of the second lower magnet 5A2L. In the lower part of the second winding portion 13A2, the current flows from the X1 side to the X2 side.

Therefore, the upper and lower portions of the first winding portion 13A1 and the upper and lower portions of the second winding portion 13A2 are both subjected to upward Lorentz force. As a result, the lens holding member 2 to which the first winding part 13A1 and the second winding part 13A2 are attached moves upward.

When a current flows from the second connecting portion 10C2 to the first connecting portion 10C1 of the wiring board 10, the current flows from the first extending portion 33A1 to the first winding portion 13A1, the connecting portion 3C, and the second connecting portion 10C1. It flows to the second extending portion 33A2 via the winding portion 13A2.

Therefore, the upper and lower portions of the first winding portion 13A1 and the upper and lower portions of the second winding portion 13A2 are both subjected to the downward Lorentz force. As a result, the lens holding member 2 to which the first winding part 13A1 and the second winding part 13A2 are attached moves downward.

With this configuration, the lens driving device 101 can appropriately control the movement of the lens holding member 2 along the optical axis direction.

As described above, the lens driving device 101 according to the embodiment of the present invention includes a lens holding member 2 that can hold a lens body, a housing HS that accommodates the lens holding member 2, and a lens, as shown in FIG. A lower leaf spring 26 that supports the holding member 2 movably in the optical axis direction, an upper leaf spring 16 disposed on the upper side (Z1 side) closer to the subject than the lower leaf spring 26, and the lens holding member 2. It includes a held coil 3 and a driving magnet 5A facing the coil 3. The housing HS has a bottom wall 4B with an opening 4K formed therein and an outer circumferential wall 4A, and a synthetic resin case 4 with an open upper side facing the subject, and an opening 1K and a storage space 4S. It has a lid member 1 that faces the bottom wall portion 4B via. The upper leaf spring 16 is provided to connect the upper part of the lens holding member 2 and the case 4, and the lower leaf spring 26 is provided to connect the lower part of the lens holding member 2 and the case 4. The driving magnet 5A is fixed to the case 4.

This configuration can suppress variations in the distance between the coil 3 and the drive magnet 5A between products, compared to the case where the drive magnet 5A is fixed to a member other than the case 4. This is because the number of members that affect the distance between the coil 3 and the driving magnet 5A is reduced. That is, this is because the accumulation of dimensional tolerances of each member is suppressed.

Further, in the lens driving device 101, it is preferable that both the upper leaf spring 16 and the lower leaf spring 26 are fixed to the case 4. In this case, the lens driving device 101 can improve the positioning accuracy of the lens holding member 2 compared to the case where either the upper leaf spring 16 or the lower leaf spring 26 is fixed to a member other than the case 4. . This is because the number of members that affect the positioning accuracy of the lens holding member 2 is reduced. That is, this is because the accumulation of dimensional tolerances of each member is suppressed. As a result, the lens driving device 101 can suppress, for example, the central axis of the lens holding member 2 supported by the upper leaf spring 16 and the lower leaf spring 26 from tilting with respect to the central axis of the lens driving device 101. .

Further, the lens driving device 101 can suppress the influence on communication by communication devices disposed close to each other, compared to the case where the case 4 is made of metal. Specifically, even if the lens driving device 101 is installed in a small device such as a smartphone as a lens driving device of a front camera, and the lens driving device 101 and the communication device are placed close to each other, Since the case 4 is made of synthetic resin, the lens driving device 101 can suppress the influence on communication by the communication device. As a result, the lens driving device 101 can increase the degree of freedom in layout within the housing of a small device in which the lens driving device 101 is mounted, and can further promote miniaturization of the small device.

Note that when the lid member 1 is made of synthetic resin, metal may be embedded in the lid member 1 for reinforcement or the like. The same applies to case 4. In this case, metal for reinforcement or as a terminal may be embedded in the case 4 made of synthetic resin by insert molding or the like. Furthermore, when the lid member 1 that constitutes the housing HS together with the case 4 is made of synthetic resin, the lens driving device 101 further increases the degree of freedom in the layout within the housing of a small device in which the lens driving device 101 is mounted. be able to.

In the lens driving device 101, the outer peripheral wall 4A includes a first side wall 4A1 and a first side wall 4A1 facing each other with the lens holding member 2 in between in a first direction (Y-axis direction) perpendicular to the optical axis direction, as shown in FIG. 1, for example. A second side wall portion 4A2, and a third side wall portion 4A3 and a fourth side wall portion 4A4 that face each other across the lens holding member 2 in a second direction (X-axis direction) perpendicular to the optical axis direction and perpendicular to the first direction. It may have. In this case, the driving magnet 5A includes a first driving magnet 5A1 located inside the first side wall portion 4A1 (Y2 side) and a second driving magnet 5A1 located inside the second side wall portion 4A2 (Y1 side). It may have a magnet 5A2 for use. An adhesive may be provided between the first side wall portion 4A1 and the first driving magnet 5A1 and between the second side wall portion 4A2 and the second driving magnet 5A2.

This configuration can increase the adhesive strength between the driving magnet 5A and the case 4. This is because the adhesive can be applied over a wide range on the outer surface of the driving magnet 5A facing the outer peripheral wall 4A.

In addition, when the winding part of the coil 3 exists on each of the third side wall part 2A3 and the fourth side surface 2A4 of the lens holding member 2, the driving magnet 5A is placed inside the third side wall part 4A3 (X2 side). It may include a driving magnet arranged and a driving magnet arranged inside the fourth side wall portion 4A4 (on the X1 side).

In the lens driving device 101, the driving magnet 5A typically extends in a direction intersecting the optical axis direction. Specifically, the driving magnet 5A extends in a direction perpendicular to the optical axis direction (X-axis direction), as shown in FIG. 1, for example. In this case, the inner surfaces of both ends of the driving magnet 5A in the extending direction may be configured to come into contact with a positioning surface PS formed on the case 4, for example, as shown in FIG. 11(B). The outer surface of the driving magnet 5A may be configured to come into contact with a crush rib CR formed on the inner surface of the outer peripheral wall 4A, for example, as shown in FIG. 11(B).

This configuration can further reduce variations in the distance between the coil 3 and the driving magnet 5A. This is because the positioning surface PS increases the positioning accuracy of the driving magnet 5A.

In the lens driving device 101, the lower leaf spring 26 has an outer portion 26e as a first fixing portion fixed to the case 4, and a second portion fixed to the lens holding member 2, as shown in FIG. 6(B), for example. It may have an inner part 26i as a fixing part and an elastic arm part 26g provided between the outer part 26e and the inner part 26i. In this case, as shown in FIGS. 7(A) and 7(B), the bottom wall portion 4B includes a base portion 4B2 facing the elastic arm portion 26g in the optical axis direction, and a mounting portion higher than the base portion 4B2. It may have a base portion 4B1. The outer portion 26e may be held between the base portion 4B1 and the driving magnet 5A (second lower magnet 5A2L), for example, as shown in FIG. 11(C).

This configuration allows a space for elastic deformation of the elastic arm portion 26g of the lower leaf spring 26 to be secured even if a separate member such as a spacer is not disposed between the lower leaf spring 26 and the bottom wall portion 4B. do.

In the lens driving device 101, the upper plate spring 16 has an outer portion 16e as a first fixing portion fixed to the case 4, and a second portion fixed to the lens holding member 2, as shown in FIG. 6(A), for example. It may have an inner portion 16i as a fixing portion and an elastic arm portion 16g provided between the outer portion 16e and the inner portion 16i. In this case, the case 4 has a rectangular shape in plan view, and the outer peripheral wall 4A has protrusions 4C extending in the optical axis direction from the bottom wall 4B at the four corners, for example, as shown in FIG. 8(A). may be provided. The outer portion 16e of the upper plate spring 16 may be placed on the end surface of the protruding portion 4C, for example, as shown in FIG. 8(B).

This configuration enables accurate positioning of the outer portion 16e of the upper leaf spring 16 in the optical axis direction (the height of the outer portion 16e with respect to the bottom wall portion 4B). Furthermore, with this configuration, a preferable configuration is realized in which not only the outer portion 16e of the upper leaf spring 16 but also the outer portion 26e of the lower leaf spring 26 are positioned by the case 4, which is the same single member. This preferable configuration can improve the positioning accuracy of the lens holding member 2 supported by the upper leaf spring 16 and the lower leaf spring 26. This is because the number of members that affect the positioning accuracy of the lens holding member 2 is reduced. That is, this is because the accumulation of dimensional tolerances of each member is suppressed. As a result, the lens driving device 101 can suppress, for example, the central axis of the lens holding member 2 supported by the upper leaf spring 16 and the lower leaf spring 26 from tilting with respect to the central axis of the lens driving device 101. .

A protrusion 4P that protrudes upward along the optical axis direction may be formed on the end surface of the protrusion 4C. In this case, the protrusion 4P is inserted into the through-hole 16T of the outer portion 16e of the upper leaf spring 16 (see, for example, FIG. 6(A)) and the through-hole 1T of the lid member 1 (see, for example, FIG. 12(A)). In this state, the tip is deformed. For example, the tip of the protrusion 4P is deformed by hot caulking or cold caulking. This configuration can increase the productivity of manufacturing the lens driving device 101.

As shown in FIG. 12A, for example, the through holes 1T serving as the penetrating portions of the lid member 1 are formed at each of four corners of the lid member 1, which has a substantially rectangular shape in a plan view along the optical axis direction. may be provided. As shown in FIG. 12A, for example, an upper recess 1R as a first recess may be formed on the upper surface of the lid member 1 at a position corresponding to the tip of the protrusion 4P in the optical axis direction. good. Further, on the lower surface of the lid member 1, as shown in FIG. 12(B), for example, a second recessed portion recessed upward is provided at a position facing at least the elastic arm portion 16g of the upper leaf spring 16 in the optical axis direction. A lower recess 1S may be formed. When both the upper recess 1R and the lower recess 1S are formed, the through hole 1T of the lid member 1 is preferably arranged outside the lower recess 1S. That is, the through hole 1T is arranged at a position farther from the optical axis JD than the lower recess 1S in the radial direction perpendicular to the optical axis direction.

The upper recess 1R can suppress the protrusion of the protrusion 4P from the upper surface of the lid member 1. Alternatively, the upper recess 1R can prevent the tip of the protrusion 4P from protruding beyond the upper surface of the lid member 1. The lower recess 1S can provide a space for the elastic arm 16g of the upper leaf spring 16 to elastically deform even if another member such as a spacer is not disposed between the upper leaf spring 16 and the lid member 1.

In addition, the configuration in which the through hole 1T is arranged outside the lower recess 1S reduces the portion where the lower recess 1S and the upper recess 1R overlap in the optical axis direction, or eliminates the overlapping portion, so that the This has the effect of suppressing a decrease in the thickness (strength) of the lid member 1 due to the formation of the recess.

In addition, the configuration in which the upper recess 1R and the lower recess 1S overlap in the optical axis direction is reduced or does not overlap each other can improve the above-mentioned effects of the upper recess 1R and the lower recess 1S, respectively. While achieving this, it is possible to prevent the thickness of the lid member 1 from becoming excessively large. That is, with this configuration, the thickness of the lid member 1 can be reduced. Further, with this configuration, the strength of the lid member 1 can be ensured by ensuring that the upper recess 1R and the lower recess 1S hardly or not overlap in the optical axis direction.

In the lens driving device 101, for example, as shown in FIG. 1, a through hole 4H as an opening is formed in the third side wall portion 4A3, and even if a wiring board 10, which is a board on which components are mounted, is fixed. good. In the example of FIG. 1, a magnetic detection member 11 and a capacitor 14 are mounted on the wiring board 10 as components. In this case, the component is mounted on the wiring board 10 so that it is located within the through hole 4H when the wiring board 10 is fixed to the third side wall portion 4A3. Furthermore, a metal plate MP fixed to the case 4 may be located outside the wiring board 10 (on the X1 side). Note that the through hole 4H may be formed in the fourth side wall portion 4A4 instead of the third side wall portion 4A3. In this case, the wiring board 10 may be fixed to the fourth side wall 4A4 instead of the third side wall 4A3. This configuration can increase the degree of freedom in designing the lens driving device 101.

In the lens driving device 101, upper wall portions 4W serving as second wall portions adjacent to the outer peripheral end surface at the corners of the lid member 1 may be formed at the four corners of the outer peripheral wall portion 4A.

This configuration has the effect of facilitating attachment of the lid member 1 to the case 4. Further, this configuration can prevent the lid member 1 from coming off from the case 4 when the lens driving device 101 receives an impact due to a drop or the like. This is because the movement of the lid member 1 when receiving an impact is suppressed by the upper wall portion 4W.

When the lid member 1 is made of synthetic resin, a sealing material EC is disposed between the outer periphery of the lid member 1 and the outer peripheral wall portion 4A, as shown in FIG. 10(B), for example. Good too. This configuration can prevent the lid member 1 from coming off from the case 4 when the lens driving device 101 receives an impact due to a drop or the like. Further, this configuration can suppress foreign matter such as dust from entering the housing HS.

Further, as shown in FIG. 1, for example, the lens driving device 101 according to the embodiment of the present invention includes a lens holding member 2 capable of holding a lens body, a housing HS in which the lens holding member 2 is housed, and a lens holding member 2. A leaf spring 6 as a support member that supports the member 2 movably in the optical axis direction, a coil 3 held by the lens holding member 2, a driving magnet 5A facing the coil 3, and a conductive pattern (wiring pattern). The wiring board 10 is a board on which a wiring board 10 is formed. The conductive pattern formed on the wiring board 10 is electrically connected to the coil 3 via the upper leaf spring 16. The housing HS includes a bottom wall 4B in which an opening 4K is formed, an outer peripheral wall 4A, and is arranged above the bottom wall 4B on the subject side, and faces the bottom wall 4B with the accommodation space 4S in between. It has a lid member 1 as a ceiling wall portion in which an opening 1K is formed. The wiring board 10 is fixed to the outer surface of the outer peripheral wall 4A.

This configuration has the effect that the wiring board 10 is accurately supported by the housing HS. This is because the outer circumferential wall portion 4A constituting the housing HS has a rectangular cylindrical shape, and therefore is unlikely to warp or deform. As a result, this configuration can suppress variations in the distance between the wiring board 10 and the lens holding member 2, and furthermore, the magnetic detection member 11 attached to the wiring board 10 and the magnetic detection member attached to the lens holding member 2 can be suppressed. Variations in the distance between the magnet 8 and the magnet 8 can be suppressed.

As shown in FIG. 13A, for example, a magnetic detection member 11 for detecting the magnetic field of the detection magnet 8 fixed to the lens holding member 2 is mounted on the inner surface of the wiring board 10. A metal plate MP as a plate-like member may be arranged on the outer surface of 10, for example, as shown in FIG. 9(C). With this configuration, the metal plate MP can reinforce the wiring board 10 as a flexible printed circuit board. Further, the metal plate MP can protect the wiring board 10.

The housing HS may include a case 4 and a lid member 1. In the embodiment described above, the lid member 1 is attached to the upper surface (Z1 side surface) of the case 4 that includes the bottom wall portion 4B, but the lid member 1 is attached to the upper surface (Z1 side surface) of the case 4 that is provided with the bottom wall portion 4B. It may be attached to the lower surface (Z2 side surface) of 4. In this case, the functions of the upper leaf spring 16 and the lower leaf spring 26 may be replaced. That is, the lower leaf spring 26 is divided into two parts and is configured to function as a power supply member for supplying current to the coil 3, and is sandwiched between the case 4 and the lid member 1. and may be configured to be electrically connected to the wiring board 10. Further, the outer peripheral wall portion may be formed not only on the case 4 but also on the lid member 1.

The case 4 has a bottom wall part 4B and an outer circumferential wall part 4A, and the upper side facing the subject is open, and the lid member 1 constitutes a ceiling wall part facing the bottom wall part 4B through the accommodation space 4S. You may do so. In this case, the leaf spring 6 serving as the support member may include an upper leaf spring 16 and a lower leaf spring 26, as shown in FIG. 1, for example. The upper leaf spring 16 may be connected to a conductive pattern formed on the wiring board 10 via the connection terminal portions PT1 and PT2, as shown in FIGS. 8(B) and 10(A), for example. .

In this configuration, since the upper plate spring 16 is connected to the conductive pattern, even if the housing HS includes the case 4 and the lid member 1 with the upper side open, there is no need to create a complicated wiring route. , the conductive pattern of the wiring board 10 and the coil 3 can be electrically connected.

Specifically, as shown in FIG. 13A, for example, a recessed portion (a first recessed portion 10U1 and a second recessed portion 10U2) is formed in the upper end portion 10U of the wiring board 10, and the surface of the wiring board 10 is Conductive connecting portions (first connecting portion 10C1 and second connecting portion 10C2) may be provided at positions adjacent to the recessed portions. In this case, the connection terminal part PT2 (see FIG. 8(B)) of the second upper leaf spring 16A2 is arranged in the first recessed part 10U1, and the first upper leaf spring A connecting terminal portion PT1 (see FIG. 8(B)) of 16A1 is arranged. The first connecting portion 10C1 and the connecting terminal portion PT2 are connected by a conductive adhesive AD4 as a bonding material, as shown in FIG. 10(A). The same applies to the connection between the second connection portion 10C2 and the connection terminal portion PT1.

This configuration can improve the productivity of manufacturing the lens driving device 101 compared to the conventional configuration in which the connection terminal portion is passed through a hole (not a cutout) formed in the wiring board. This is because it is possible to increase the degree of freedom in handling the wiring board 10 when positioning the connection terminal portion in the concave space that is the concave space formed by the connection portion. For example, while moving the wiring board 10 along the outer surface (X1 side surface) of the third side wall portion 4A3, the operator positions the connection terminal portion PT2 within the first recessed portion 10U1, and This is because the connection terminal portion PT1 can be positioned within 10U2.

Further, in this configuration, after the lid member 1 is attached to the case 4, the connection between the first connection portion 10C1 and the connection terminal portion PT2 and the connection between the second connection portion 10C2 and the connection terminal portion PT1 are performed. make it possible to be Moreover, this configuration is possible immediately after the connection between the first connection part 10C1 and the connection terminal part PT2 and the connection between the second connection part 10C2 and the connection terminal part PT1, but before another process is performed. , allowing the encapsulant EC to be applied to their connection parts. Therefore, in this configuration, the connection between the first connection portion 10C1 and the connection terminal portion PT2 and the connection between the second connection portion 10C2 and the connection terminal portion PT1 are established at a relatively early stage in the assembly process of the lens driving device 101. Compared to the case where this is done, work efficiency can be improved and an increase in product loss can be suppressed. This is because workability can be prevented from deteriorating due to premature connection of the connection terminal portion to the connection portion. This is also because it is possible to prevent the connecting portion from being damaged in the subsequent assembly process.

For example, as shown in FIG. 1, the outer peripheral wall portion 4A includes a first side wall portion 4A1 and a second side wall portion 4A2 that face each other across the lens holding member 2 in a first direction (Y-axis direction) perpendicular to the optical axis direction. , even if it has a third side wall portion 4A3 and a fourth side wall portion 4A4 that face each other across the lens holding member 2 in a second direction (X-axis direction) perpendicular to the optical axis direction and perpendicular to the first direction. good. In this case, a through hole 4H as an opening may be formed in the third side wall portion 4A3, and a wiring board 10 as a board on which components disposed in the through hole 4H are mounted may be fixed. In the example of FIG. 1, the components are the magnetic detection member 11 and the capacitor 14. Note that the through hole 4H may be formed in the fourth side wall portion 4A4. In this case, the wiring board 10 is fixed to the fourth side wall portion 4A4.

As shown in FIG. 9A, the third side wall portion 4A3 to which the wiring board 10 is fixed has a recess RS2 in which an adhesive for adhesively fixing the wiring board 10 and the third side wall portion 4A3 is accommodated. may be formed. In addition, when the wiring board 10 is fixed to the fourth side wall part 4A4, the recessed part RS2 in which the adhesive is accommodated may be formed in the fourth side wall part 4A4. This configuration can increase the adhesive strength between the wiring board 10 and the third side wall portion 4A3.

The wiring board 10 may be fixed to the third side wall portion 4A3 so that a portion thereof is also located outside the lid member 1 serving as the ceiling wall portion. Specifically, the wiring board 10 may be fixed to the third side wall portion 4A3, as shown in FIG. 16, for example. FIG. 16 is a front view of the lens driving device 101 shown in FIG. 9(B) when viewed from the X1 side. In FIG. 16, dot hatching is added to the lid member 1 for clarity.

FIG. 16 shows the state of the lens driving device 101 before the metal plate MP is attached to the third side wall portion 4A3. Therefore, the conductive adhesive AD4 (see FIG. 10(A)) is not applied to the lens driving device 101 shown in FIG. 16, and the sealing material EC (see FIG. 10(B)) is not applied. Not yet. An upper end portion 10U, which is a part of the wiring board 10 and is represented by cross hatching in FIG. 16, is arranged to face the outer peripheral end surface of the lid member 1.

This configuration can suppress foreign matter such as dust from entering the housing HS through the gap between the lid member 1 and the third side wall portion 4A3 of the case 4.

As shown in FIG. 14(B), the lower part of the wiring board 10 is provided with a first terminal portion TM1 that is electrically connected to the second upper leaf spring 16A2 via the first connecting portion 10C1, and a second connecting portion TM1. A sixth terminal portion TM6 may be provided which is electrically connected to the first upper leaf spring 16A1 via 10C2. In this case, the first terminal portion TM1 and the sixth terminal portion TM6 may be used as terminal portions for electrical inspection. For example, the first terminal portion TM1 and the sixth terminal portion TM6 may be used when passing current through the coil 3 without passing through the magnetic detection member 11 in order to test the continuity of the coil 3.

For example, as shown in FIG. 3, the detection magnet 8 has a flat surface 8A exposed at the third side surface 2A3 of the lens holding member 2, and is configured to have a width W2 larger than the width W1 of the flat surface 8A. may have been done.

This configuration has the effect that the flat surface 8A can be directly opposed to the magnetic detection member 11 while preventing the detection magnet 8 from falling off the lens holding member 2. The state in which the flat surface 8A and the magnetic detection member 11 directly oppose each other means that there is no other member such as a part of the lens holding member 2 between the flat surface 8A and the magnetic detection member 11. Further, this configuration has the effect that the distance between the flat surface 8A and the magnetic detection member 11 can be reduced. However, the detection magnet 8 and the magnetic detection member 11 may be opposed to each other with a non-magnetic member such as a part of the lens holding member 2 interposed therebetween.

The upper leaf spring 16 preferably has an outer portion 16e as a first fixing portion fixed to the case 4 and a second fixing portion fixed to the lens holding member 2, as shown in FIG. 6(A). It has an inner portion 16i and an elastic arm portion 16g provided between the outer portion 16e and the inner portion 16i. An insulating adhesive AD3 may be placed in the gap between the outer portion 16e of the upper leaf spring 16 and the driving magnet 5A, as shown in FIG. 8(A).

This configuration has the effect of preventing direct contact between the upper leaf spring 16 and the driving magnet 5A. That is, the upper leaf spring 16, which functions as a power supply member for passing current through the coil 3, comes into contact with the driving magnet 5A, resulting in the effect that current can be prevented from flowing toward the driving magnet 5A.

The manufacturing method of the lens driving device 101 according to the embodiment of the present invention includes a step of assembling the case 4 and the lid member 1, and fixing the wiring board 10 to the outer surface of the outer peripheral wall 4A of the case 4 combined with the lid member 1. and a step of doing so. That is, the method for manufacturing the lens driving device 101 is characterized in that the wiring board 10 is attached to the case 4 after the lens holding member 2 and the like are housed in the case 4 and the lid member 1 is attached to the case 4. There is.

This procedure has the effect that productivity regarding manufacturing the lens driving device 101 can be increased. This is because it is possible to eliminate the step of assembling another member after the wiring board 10 and the upper leaf spring 16 are joined in a mutually perpendicular state.

The preferred embodiments of the present invention have been described above in detail. However, the present invention is not limited to the embodiments described above. Various modifications and substitutions may be made to the embodiments described above without departing from the scope of the present invention. Furthermore, the features described with reference to the above-described embodiments may be combined as appropriate unless technically inconsistent.

For example, in the above-described embodiment, the outer circumferential wall 4A of the case 4 is configured such that the first side wall 4A1 to the fourth side wall 4A4 are continuous, that is, the first side wall 4A1 to the fourth side wall 4A4 form the housing space. Although it is configured to surround the periphery of 4S without a gap, it may be configured so that the two side wall portions are continuous. For example, the first side wall portion 4A1 and the third side wall portion 4A3 constitute an L-shaped wall portion when viewed from above, and the second side wall portion 4A2 and the fourth side wall portion 4A4 constitute an L-shaped wall portion when viewed from above. A wall portion may be configured. That is, gaps may be formed between the first side wall portion 4A1 and the fourth side wall portion 4A4, and between the second side wall portion 4A2 and the third side wall portion 4A3.

Further, in the above-described embodiment, the outer circumferential wall 4A of the case 4 is configured so that the first side wall 4A1 to the fourth side wall 4A4 have the same height, but the heights are different. It may be configured as follows. Further, the first side wall portion 4A1 may be configured such that, for example, the height of the center portion is high and the height of both end portions is low. The same applies to the second side wall portion 4A2 to the fourth side wall portion 4A4.

Further, in the above-described embodiment, the driving magnet 5A is fixed to the side wall of the outer peripheral wall 4A, but may be arranged at corners such as the four corners of the outer peripheral wall 4A. Further, the coil 3 may be wound around the outer periphery of the lens holding member 2 so as to surround the optical axis JD.

1... Lid member 1K... Opening 1R... Upper recess 1R1... First upper recess 1R2... Second upper recess 1R3... Third upper recess 1R4... Fourth upper recess 1S ...Lower recessed part 1T...Through hole 1T1...First through hole 1T2...Second through hole 1T3...Third through hole 1T4...Fourth through hole 2...Lens holding Member 2A...Side surface 2A1...First side surface 2A2...Second side surface 2A3...Third side surface 2A4...Fourth side surface 2T...Protrusion portion 3...Coil 3C... Connecting portion 4... Case 4A... Outer peripheral wall part 4A1... First side wall part 4A2... Second side wall part 4A3... Third side wall part 4A4... Fourth side wall part 4B... Bottom wall part 4B1...Base part 4B2...Base 4C...Protrusion part 4C1...First protrusion part 4C2...Second protrusion part 4C3...Third protrusion part 4C4...Fourth Projection 4H...Through hole 4H1...First through hole 4H2...Second through hole 4K...Opening 4P...Protrusion 4P1...First protrusion 4P2...Second protrusion 4P3. ...Third projection 4P4...Fourth projection 4S...Accommodation space 4S1...First accommodation space 4S2...Second accommodation space 4W...Upper side wall part 4W1...First upper side wall part 4W2... Second upper wall part 4W3... Third upper wall part 4W4... Fourth upper wall part 5A... Drive magnet 5A1... First drive magnet 5A1U... First upper side Magnet 5A1L...First lower magnet 5A2...Second driving magnet 5A2U...Second upper magnet 5A2L...Second lower magnet 6...Plate spring 8...Detection magnet 8A ...Flat surface 8K...Opening 8R...Concave portion 9...Balancing magnet 9R...Concave portion 10...Wiring board 10C...Connection part 10C1...First connection part 10C2...・Second connection part 10L1...Inner pattern layer 10L2...Outer pattern layer 10R1...Inner resist layer 10R2...Outer resist layer 10U...Top end portion 10U1...First concave portion 10U2... - Second recessed part 11... Magnetic detection member 12... Cylindrical part 12d... Lower pedestal part 12dh... Recess 12p... Winding protrusion 12p1... First winding protrusion 12p2... Second winding protrusion 12u... Upper pedestal part 12u1... First pedestal part 12u2... Second pedestal part 12u3... Third pedestal part 13A... Winding part 13A1... First winding Part 13A2...Second winding part 14...Capacitor 16...Upper leaf spring 16A1...First upper leaf spring 16A2...Second upper leaf spring 16b...Corner part 16c1... First joint part 16c2... Second joint part 16c3... Third joint part 16e... Outer part 16g... Elastic arm part 16h... Connection plate part 16i... Inner part 16p1... First connecting part 16p2... Second connecting part 16R... Through hole 16s... Crosspiece 16T... Penetrating part 16T1... Through hole 16T2... Notch 26... Lower leaf spring 26e. ...Outer portion 26e1...First outer portion 26e2...Second outer portion 26g...Elastic arm portion 26i...Inner portion 33A1...First extension portion 33A2...Second extension Part 33c... Opposing part 33m... Winding part 72... Holding part 72A1... First holding part 72A2... Second holding part 101... Lens driving device AD1... Adhesive AD2. ...Conductive adhesive AD3...Adhesive AD4...Conductive adhesive CR...Crush rib CR1...Tapered part CR2...Parallel part CS1-CS4...Receiving surface CT... Notch CT1...first notch CT2...second notch CT3...third notch CT4...fourth notch DM...damping material DM1...first damping material DM2...first 2 damping material DM3... 3rd damping material DM4... 4th damping material EC... Sealing material HS... Housing JD... Optical axis LD1... 1st land part LD2 ...Second land portion LD3...Third land portion LD4...Fourth land portion LD5...Fifth land portion LD6...Sixth land portion LD7...Seventh land portion LD8...・8th land MK... Drive mechanism MP... Metal plate PR1, PR2... Raised portion PS... Positioning surface PT1, PT2... Connection terminal portion RS1... Adhesive reservoir RS2 to RS4 ... Recessed portion TM1... First terminal part TM2... Second terminal part TM3... Third terminal part TM4... Fourth terminal part TM5... Fifth terminal part TM6... Sixth terminal part Terminal part UA...Upper assembly UF...Underfill V1~V6...Via hole

Claims (11)

a lens holding member capable of holding a lens body;
a housing in which the lens holding member is housed;
a support member that supports the lens holding member movably in the optical axis direction;
a coil held by the lens holding member;
a driving magnet facing the coil;
A substrate on which a conductive pattern is formed,
A lens driving device in which the conductive pattern is electrically connected to the coil via the support member,
The housing includes a case made of synthetic resin and a lid member made of synthetic resin,
The case has a bottom wall portion in which an opening is formed and a rectangular cylindrical outer peripheral wall portion, and the upper side facing the subject is open;
The lid member has an opening that is disposed above the bottom wall portion on the subject side, and that is coupled to the outer peripheral wall portion and faces the bottom wall portion with an accommodation space for accommodating the support member in between . having a ceiling wall portion formed;
The substrate is fixed to the outer surface of the outer peripheral wall,
A magnetic detection member for detecting a magnetic field of a detection magnet fixed to the lens holding member is mounted on the inner surface of the substrate, and a metal plate as a plate-like member is arranged on the outer surface of the substrate. has been ,
A lens driving device characterized by: The support member has an upper leaf spring and a lower leaf spring,
the upper leaf spring is connected to the conductive pattern;
The lens driving device according to claim 1 . A recessed portion is formed at the upper end of the substrate, and a connecting portion is provided at a position adjacent to the recessed portion,
A connection terminal portion of the upper leaf spring is disposed within the recessed portion,
The connecting portion and the connecting terminal portion are connected by a bonding material,
The lens driving device according to claim 2 . The outer peripheral wall portion faces a first side wall portion and a second side wall portion that face each other across the lens holding member in a first direction, and faces across the lens holding member in a second direction perpendicular to the first direction. It has a third side wall part and a fourth side wall part,
An opening is formed in one of the third side wall part and the fourth side wall part, and the board on which components are mounted is fixed.
A lens driving device according to any one of claims 1 to 3 . A recess in which an adhesive is accommodated is formed in one of the third side wall and the fourth side wall to which the substrate is fixed.
The lens driving device according to claim 4 . a lens holding member capable of holding a lens body;
a housing in which the lens holding member is housed;
a support member that supports the lens holding member movably in the optical axis direction;
a coil held by the lens holding member;
a driving magnet facing the coil;
A substrate on which a conductive pattern is formed,
A lens driving device in which the conductive pattern is electrically connected to the coil via the support member,
The housing includes a case made of synthetic resin and a lid member made of synthetic resin,
The case has a bottom wall portion in which an opening is formed and a rectangular cylindrical outer peripheral wall portion, and the upper side facing the subject is open;
The lid member has an opening that is disposed above the bottom wall portion on the subject side, and that is coupled to the outer peripheral wall portion and faces the bottom wall portion with an accommodation space for accommodating the support member in between. having a ceiling wall portion formed;
The substrate is fixed to the outer surface of the outer peripheral wall,
A part of the substrate is also located outside the ceiling wall part,
A lens driving device characterized by: A terminal portion electrically connected to the upper leaf spring is provided at a lower portion of the substrate.
The lens driving device according to claim 2 or 3 . The detecting magnet has a flat surface at the exposed portion on the side surface of the lens holding member, and an unexposed portion of the detecting magnet in a direction parallel to the side surface and perpendicular to the optical axis direction. The total width of the included detection magnet is larger than the width of the flat surface.
The lens driving device according to claim 1 . The upper leaf spring includes a first fixing part fixed to the case, a second fixing part fixed to the lens holding member, and an elastic spring provided between the first fixing part and the second fixing part. and an arm;
an insulating adhesive is disposed in a gap between the first fixing part of the upper leaf spring and the driving magnet;
The lens driving device according to claim 2 or 3 . A lens driving device according to any one of claims 1 to 9,
the lens body;
an image sensor facing the lens body;
The camera module. a lens holding member capable of holding a lens body;
a housing in which the lens holding member is housed;
a support member that supports the lens holding member movably in the optical axis direction;
a coil held by the lens holding member;
a driving magnet facing the coil;
a substrate on which a conductive pattern is formed that conducts to the coil via the support member,
The housing includes a case made of synthetic resin and a lid member made of synthetic resin,
The case has a bottom wall portion in which an opening is formed and a rectangular cylindrical outer peripheral wall portion, and the upper side facing the subject is open;
The lid member has an opening that is disposed above the bottom wall portion on the subject side, and that is coupled to the outer peripheral wall portion and faces the bottom wall portion with an accommodation space for accommodating the support member in between . A method for manufacturing a lens driving device having a ceiling wall portion formed therein , the method comprising:
a step of combining the case and the lid member constituting the housing;
A method for manufacturing a lens driving device, comprising the step of fixing the substrate to the outer surface of the outer peripheral wall of the case combined with the lid member.

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