JP2008111876A - Camera module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a camera module advantageous in improvement of durability and anti-shock. <P>SOLUTION: The camera module includes a lens barrel part 66, a lens holding part 68, a spring 70, an imaging element 29, and a drive part 72. The drive part 72 is composed to include a magnet 82, and a coil 84. The lens barrel part 66 is composed to include a front lens barrel 78 and a rear lens barrel 80. The drive part 72 moves the lens holding part 68 along the optical axis of a photographing optical system 34 and is composed to include the magnet 82 and the coil 84. The two magnets 82 are arranged in parallel to a single virtual plane passing through the optical axis in a part of the lens holding part 68 sandwiching the optical axis. The coil 84 is formed by winding a lead wire around the optical axis to present a frame-shape centering the optical axis when viewed from an optical axis direction. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a camera module incorporated in, for example, a portable electronic device.

2. Description of the Related Art In recent years, mobile phones incorporating camera modules or electronic devices such as PDAs (Personal Digital Assistants) have been provided.
The camera module includes a lens holding unit that holds the imaging optical system, a lens barrel unit that houses the lens holding unit, and a spring that supports the lens holding unit in the lens barrel so as to be movable along the optical axis of the imaging optical system. An image pickup device for picking up a subject image guided by the photographing optical system, and a drive unit for moving the lens holding unit along the optical axis.
And the drive part is comprised including the coil provided in the lens holding part, and the magnet provided in the location of the lens-barrel part which faces this coil (refer patent document 1).
JP2002-23037

In such a conventional camera module, since a magnet is provided in the lens barrel portion and a coil is provided in the lens holding portion, there is a concern that stress may act on the conducting wire constituting the coil as the lens holding portion moves. This is disadvantageous in ensuring the durability and impact resistance of the camera module.
The present invention has been made in view of such circumstances, and an object of the present invention is to provide a camera module that is advantageous in improving durability and impact resistance.

  In order to achieve the above-described object, a camera module of the present invention includes a lens barrel portion having an accommodation space, a lens holding portion that holds a photographing optical system and is accommodated in the accommodation space, and is disposed in the accommodation space. A spring that supports the lens holding unit movably along the optical axis of the imaging optical system, an imaging device that is provided in the lens barrel unit and that captures a subject image guided by the imaging optical system, and the lens holding unit. A driving unit that moves along the optical axis of the photographing optical system, and the driving unit includes a magnet provided in the lens holding unit and a coil provided in the lens barrel unit and facing the magnet. The coil is configured such that a conducting wire is wound around the optical axis and has a frame shape centered on the optical axis when viewed from the optical axis direction.

  Therefore, according to the present invention, since the magnet is provided in the lens holding portion that holds the photographing optical system, and the coil is provided in the lens barrel portion, stress does not act on the conducting wire of the coil as the lens holding portion moves, This is advantageous in improving durability and impact resistance.

First, the first reference example will be described before the embodiment of the present invention is described.
1A and 1B are external views illustrating an example of an electronic apparatus in which an imaging device 20 having a camera module 22 according to a first reference example is incorporated.
As shown in FIG. 1, the electronic device 10 is a mobile phone, and includes first and second housings 14 and 16 that are swingably connected by a hinge portion 12.
A liquid crystal display panel 1402 is provided on the inner surface of the first housing 14, and operation switches 1602 such as numeric keys and function keys are provided on the inner surface of the second housing 16.
The imaging device 20 is incorporated in the proximal end portion of the first housing 14, and an image captured by the imaging device 20 is configured to be displayed on the liquid crystal display panel 1402.

2 is an exploded perspective view of the camera module 22 and the socket 24 constituting the imaging device 20, FIG. 3 is a plan view of the socket 24, FIG. 4 is a plan view of the substrate 30, and FIG. 6 is a sectional view taken along the line AA in FIG. 5, FIG. 7 is a sectional view taken along the line BB in FIG. 5, and FIG. 8 is an enlarged view of a portion A in FIG.
As shown in FIGS. 2 and 5, the imaging device 20 includes a camera module 22, a socket 24 in which the camera module 22 is mounted, and a cover 26 that is mounted in the socket 24.
As shown in FIG. 2, the camera module 22 includes a case 28, an image sensor 29 (see FIG. 7), a signal processing unit, a substrate 30, and a contact piece 32 (see FIG. 4). Yes.
The case 28 has a rectangular plate shape (rectangular plate shape), and includes an upper surface 2802 positioned on one side in the thickness direction, a lower surface 2804 positioned on the other side in the thickness direction, and two positioned along two long sides. A long side surface 2806 and two short side surfaces 2808 positioned along two short sides are provided.
The case 28 incorporates a photographic optical system 34 that guides the subject image to the image sensor, and the photographic optical system 34 is disposed so as to face the upper surface 2802 of the case 28.
In the first reference example, the case 28 is made of synthetic resin, and as shown in FIG. 2, a camera body shielding plate 2810 is provided so as to cover the upper surface 2802 and the two long side surfaces 2806.
Therefore, in the first reference example, the case 28 is configured to include the camera body shielding plate 2810 having conductivity.

The image sensor 29 captures a subject image guided by the photographing optical system 34, and is incorporated inside the case 28 at a location behind the photographing optical system 34.
The signal processing unit inputs an imaging signal output from the imaging element 29 and performs predetermined signal processing.

As shown in FIG. 2, the substrate 30 is attached to the lower surface 2804 of the case 28 and has a rectangular shape (rectangular shape).
On the upper surface 3002 where the substrate 30 faces the case 28, the image pickup device 29 and a plurality of electronic components 31 constituting the signal processing unit are mounted.
As shown in FIG. 4, the plurality of contact pieces 32 (connection pads) are formed side by side along two long sides of the lower surface 3004 where the substrate 30 faces the side opposite to the case 28.

As shown in FIG. 2, the socket 24 includes a socket body 36, a socket shielding plate 38, an elastic piece 40, a plurality of connection terminals 42, and an engaging portion 41 (see FIG. 7).
The socket body 36 is formed of an insulating material, and in this example, is formed of an insulating synthetic resin.
The socket body 36 has a rectangular (rectangular plate-like) bottom wall 3602 having a larger outline than the substrate 30 of the camera module 22, and four side walls 3604 that stand up from four sides of the bottom wall 3602, and the bottom wall 3602. The camera module 22 is sized to be accommodated inside the four side walls 3604 above.
In this example, the four side walls 3604 are two long side walls 3606 that stand up from two long sides of the bottom wall 3602 and two short side walls 3608 that stand up from two short sides of the bottom wall 3602. It is configured.
As shown in FIGS. 2 and 3, a plurality of notches 3610 for arranging a plurality of connection terminals 42 are arranged along two long sides of two long sides of the bottom wall 3602 facing each other. Has been.
As shown in FIGS. 3, 6, and 7, the plurality of connection terminals 42 can be connected to the notch 3610 of the bottom wall 3602 to the contact piece 32 of the substrate 30 and elastically deform in the thickness direction of the bottom wall 3602. It is arranged to be possible.
The socket 24 is mounted on a substrate (not shown) provided in the electronic device 10, and the base ends of the plurality of connection terminals 42 are electrically connected to the connection pads on the substrate via soldering.
Further, as shown in FIG. 2, each long side wall 3606 is provided with a notch 3620 for accommodating the elastic piece 40 extending along the longitudinal direction of the long side wall 3606. The side wall 3608 is provided with two notches 3630 for accommodating the elastic piece 40 at intervals in the longitudinal direction of the short wall 3608.

Four socket shielding plates 38 are provided and assembled to the four side walls 3604 of the socket body 36.
In this example, the socket body 36 includes a socket shielding plate 38.
The four side walls 3604 have an inner surface facing each other and an outer surface located opposite to the inner surface, and the socket shielding plates 38 are provided so as to cover the outer surfaces of the side walls 3604, respectively.
In this example, the socket shielding plate 38 includes two long-side shielding plates 46 that are assembled to the two long-side side walls 3606 and two short-side shielding plates that are respectively assembled to the two short-side side walls 3608. 48.
The socket shielding plate 38 is formed of a material having electromagnetic shielding properties and elasticity, and covers the outer surfaces of the four side walls 3604 of the socket body 36, so that the four side surfaces (long side side surface 2806, short side side) of the case 28 are covered. The side surface 2808) is covered, and the four side surfaces of the case 28 are electromagnetically shielded. The material having electromagnetic shielding properties and elasticity for forming the socket shielding plate 38 includes phosphor bronze, white, tin, copper, or a copper alloy such as phosphor bronze plated with nickel or the like, or A conductive and non-magnetic material such as stainless steel (eg, SUS304) can be used. In addition, if a magnetic body is used as the material having electromagnetic shielding properties, a magnetic flux shielding effect can be achieved in addition to the electromagnetic shielding effect.
More specifically, on the upper edge of each socket shielding plate 38 (long-side shielding plate 46, short-side shielding plate 48), attachment pieces 38A are bent at intervals in their extending direction, These mounting pieces 38A are inserted into mounting grooves 36A provided on the end surfaces of the side wall 3604 (long side wall 3606, short side wall 3608) of the socket body 36, whereby the socket shielding plate 38 is connected to each side wall 3604 (long side). The side wall 3606 and the short side wall 3608) are attached to the outer surfaces.
The socket shielding plate 38 is connected to the reference potential (ground level) of the electronic device 10 and grounded. For example, a portion of the socket shielding plate 38 is connected to a reference potential (ground level) connection pad provided on the substrate of the electronic device 10 on which the socket 24 is mounted, and is grounded.

The elastic pieces 40 are provided integrally with the socket shielding plates 38, and two elastic pieces 40 are provided at intervals in the extending direction of the socket shielding plates 38.
As shown in FIG. 2, the elastic piece 40 is formed integrally with each socket shielding plate 38, and the bottom is formed on the inner surface side of the side wall 3604 from the upper end of the socket shielding plate 38 away from the bottom wall 3602 via the bent portion 4001. It extends in the direction of the wall 3602.
The elastic piece 40 is provided so as to be positioned inside the inner surface of each of the side walls 3606 and 3608 in a state where each of the socket shielding plates 38 is attached to the side walls 3606 and 3608 of the socket main body 36 via the attachment pieces 38A. Yes.
More specifically, in each long side wall 3606, the elastic piece 40 is provided so as to face the notch 3620, and in each short side wall 3608, the elastic piece 40 is provided so as to face the notch 3630. The piece 40 can be elastically deformed in the thickness direction of the side walls 3606 and 3608. More specifically, elastic deformation in the outer surface direction of each of the side walls 3606 and 3608 of the elastic piece 40 is performed in the notches 3620 and 3630.

As shown in FIGS. 6 and 7, a bent portion 4002 protruding inside the socket body 36 is provided in the middle portion of the elastic piece 40, and the camera module 22 is accommodated inside the socket body 36. When the bent portion 4002 contacts the long side surface 2806 and the short side surface 2808 of the case 28, the camera module is secured with a gap S 1 between the side surfaces 2806 and 2808 and the inner surfaces of the side walls 3606 and 3608. 22 is elastically supported.
More specifically, since the camera body shielding plate 2810 is attached to the case 28, and the side surface portion 2810B of the camera body shielding plate 2810 is located on the long side surface 2806 of the case 28, in this example, The portion 4002 does not directly contact the long side surface 2806 of the case 28 but contacts the side surface 2810B of the camera body shielding plate 2810. In other words, the bent portion 4002 passes through the side surface portion 2810B of the camera body shielding plate 2810. The case 28 is indirectly in contact with the long side surface 2806 of the case 28. Therefore, in this example, the camera body shielding plate 2810 is grounded via the long side shielding plate 46 when the elastic piece 40 of the long side shielding plate 46 contacts the side surface portion 2810B of the camera body shielding plate 2810. Will be.
Further, as shown in FIG. 9 which is a C arrow view of FIG. 5, both ends in the extending direction of each socket shielding plate 38 are overlapped with each other at the four corners of the socket body 36 and are electrically connected. Thus, the entire circumference of the side surface of the socket body 36 is electromagnetically shielded by the four socket shielding plates 38. More specifically, for example, a bent plate portion 3810 is formed at one end portion of the socket shielding plates 38 adjacent to each other, and this bent plate portion 3810 is the other end portion 3811 of the socket shield plates 38 adjacent to each other. The bent plate portion 3810 and the end portion 3811 are always urged in the direction in which they are in contact with each other due to the elasticity of the socket shielding plate 38.

As shown in FIG. 7, when the camera module 22 is accommodated inside the four side walls 3604 on the bottom wall 3602, the engaging portion 41 engages with the camera module 22 and the camera module 22 is connected to the socket 24. The camera module 22 is housed inside the four side walls 3604 on the bottom wall 3602, and the engaging portion 41 engages with the camera module 22 portion. Thus, the mounting state of the camera module 22 in the socket 24 is formed.
In the mounted state of the camera module 22, the plurality of connection terminals 42 are elastically deformed to be electrically connected to the plurality of contact pieces 32 of the substrate 30 and urge the camera module 22 toward the upper surface 2802 of the case 28. As a result, the contact piece 32 of the substrate 30 and the connection terminal 42 are always reliably contacted with the clearance S2 secured between the substrate 30 of the camera module 22 and the bottom wall 3602 of the socket 24.
The engaging portion 41 is provided in the socket main body 36. In this example, the engaging portion 41 is formed by a bent portion 4002 of the elastic piece 40 of the shielding plate 38 attached to the short side wall 3608, and the camera module 22. Is inserted into the socket 24, the bent portion 4002 is engaged with the convex portion 2820 of the short side surface 2808 of the case 28, so that the camera module 22 moves away from the bottom wall 3602 of the socket 24. Movement is prevented.

Further, as shown in FIGS. 5 and 7, a stopper 62 is provided on the short side wall 3608 of the socket body 36 so as to abut against the cover 26 and prevent the cover 26 from being displaced in the direction of the upper surface 2802 of the case 28. Is provided.
In this example, the stopper 62 is configured by two locking projections 4802 that are formed on the outer surface of each short-side shielding plate 48 so as to protrude in the extending direction.
In this example, as shown in FIG. 5, the long side wall 3606 of the socket body 36 is detachably engaged with the cover 26 to position the cover 26 with respect to the socket 24 in the thickness direction of the case 28. An engaging portion 64 for positioning is provided.
In this example, the positioning engaging portion 64 includes two engaging recesses 6402 formed on the outer surfaces of the two long side shielding plates 46 at intervals in the extending direction of the long side shielding plate 46. It is constituted by.

The cover 26 is formed of a material having electromagnetic shielding properties and elasticity. Examples of the material having electromagnetic shielding properties and elasticity include phosphor bronze, white, tin, copper, or a copper alloy such as phosphor bronze plated with nickel, or stainless steel (for example, SUS304). A material that has conductivity and does not have magnetism can be used. In addition, if a magnetic body is used as the material having electromagnetic shielding properties, a magnetic flux shielding effect can be achieved in addition to the electromagnetic shielding effect.
As shown in FIGS. 5 and 7, the cover 26 includes an upper surface portion 50 and a side surface portion 52.
The upper surface portion 50 covers the upper surface 2802 of the case 28, and the side surface portion 52 covers the four socket shielding plates 38.
An opening 5002 is formed at a position where the upper surface portion 50 faces the photographing optical system 34, and a transparent lens cover 58 is provided in the opening 5002.
More specifically, the lens cover 58 has a disk shape and is bonded to the outer surface of the upper surface portion 50 via an annular double-sided adhesive tape 5802.
An annular dustproof member 60 made of an elastic material extending along the periphery of the opening 5002 is provided on the inner surface of the upper surface portion 50. The dustproof member 60 is bonded to the inner surface of the upper surface portion 50 via an annular double-sided adhesive tape 6002. As the elastic material constituting the dustproof member 60, a sponge-like material such as foamed polyurethane can be used.

As shown in FIG. 5, the side surface 52 has a long side surface 54 that covers the two long side shielding plates 46 of the socket 24 and a short side surface that covers the two short side shielding plates 48 of the socket 24. Part 56.
Then, the lower edge of the short side surface portion 56 of the cover 26 is locked to the locking projection 4802 of the shielding plate 38, so that the displacement of the cover 26 in the direction of the upper surface 2802 of the case 28 is prevented.
Further, an engagement convex portion 5402 that engages with and disengages from the engagement concave portion 6402 is provided at an inner portion of the long side surface portion 54 of the cover 26 corresponding to the engagement concave portion 6402 of the socket 24, and the engagement convex portion 5402 is engaged. The cover 26 is positioned in the thickness direction of the case 28 by engaging with the mating recess 6402.
As described above, the engaging recess 6402 is engaged with the side surface portion 52 of the cover 26 and the side wall 38 of the socket body 36 so as to be detachable from each other, and positions the cover 26 with respect to the socket 24 in the thickness direction of the case 28. Providing the joint convex portion 5402 is advantageous in preventing the cover 26 from falling off from the socket 24, improving workability when the imaging device 20 is handled alone, or incorporating the imaging device 10 into the electronic apparatus 10. This is advantageous for improving workability.
In this example, the engagement convex portion 5402 and the engagement concave portion 6402 are engaged with the socket 24 to which the camera module 22 is attached in the state where the cover 26 is attached, and at the same time, the short side surface portion 56 of the cover 26 is engaged. The lower edge engages with the engaging projection 4802 of the shielding plate 38.

The imaging device 20 is assembled by attaching the camera module 22 to the socket 24 mounted on the substrate of the electronic device 10 and attaching the cover 26 to the socket 24 from above, thereby completing the imaging device 20.
The imaging device 20 configured as described above has the lens cover 58 facing the opening 1410 provided in the first housing 14 of the electronic device 10 as illustrated in FIG. It is incorporated in the first housing 14.

Next, a modified example of the socket 24 will be described.
In this modification, the configuration of the stopper 62 is different, and the other configuration is the same as that of the socket 24 described above.
FIG. 10 is a cross-sectional view of the imaging apparatus 20, and the same parts and members as those in FIGS. 1 to 9 will be described below with the same reference numerals.
In the above-described configuration, the stopper 62 is configured by the two locking projections 4802 formed on the outer surface of each short-side shielding plate 48 so as to protrude in the extending direction thereof. The point which was comprised by the bending part 4001 of the upper end of the side shielding board 48 differs from the above-mentioned structure, and the other structure is the same as the above-mentioned structure.
In the modified example, as shown in FIG. 10, a locking portion 5610 that locks to the bent portion 4001 is formed on the short side surface portion 56 of the cover 26, and the bent portion 4001 and the locking portion 5610 are locked. Thus, the displacement of the cover 26 in the direction of the upper surface 2802 of the case 28 is prevented.

Next, the camera module support structure will be described.
As shown in FIG. 2, in the imaging device 20, as described above, the four contact surfaces 32 and the plurality of connection terminals are elastically contacted with the four side surfaces (the long side surface 2806 and the short side surface 2808) of the case 28. The elastic pieces 40 are provided on the respective side walls 3604 so as to secure the gap S1 between the four side walls 3604 while being connected to the four side walls 3604 and elastically support the camera module 22 on the bottom wall 3602 inside the four side walls 3604. It has been.
The elastic piece 40 is provided so as to be elastically deformable in the thickness direction of the side wall 3604 on which the elastic piece 40 is provided.
In addition, elastic deformation notch portions 3620 and 3630 for elastic deformation of the elastic piece 40 are formed at positions of the side walls 3604 corresponding to the elastic piece 40.
The elastic deformation notches 3620 and 3630 are formed through the side wall 3604 in the thickness direction.

In addition, as shown in FIG. 2, two elastic pieces 40 are provided so as to elastically contact two locations spaced in the extending direction of each side wall 3604.
Then, the elastic deformation notch portions 3630 provided on the short side wall 3608 are provided at two locations on the side wall 3604 corresponding to the two elastic pieces 40, respectively.
In addition, the elastic deformation notch 3620 provided on the long side wall 3606 is formed of a single notch having a size such that the two elastic pieces 40 can be elastically deformed.
These elastic deformation notches 3620 and 3630 are formed in an open shape at the upper end of the side wall 3604 that penetrates in the thickness direction of the side wall 3604 and is separated from the bottom wall 3602.

In the imaging device 20, as described above, the socket shielding plate 38 that is formed of a material having electromagnetic shielding properties and elasticity and covers the four sidewalls 3604 is provided, and the socket shielding plate 38 is attached to each sidewall 3604. The elastic piece 40 is formed integrally with the socket shielding plate 38.
Each of the four side walls 3604 has an inner surface facing each other and an outer surface positioned opposite to the inner surface, and the socket shielding plate 38 is attached to each side wall 3604 and disposed as shown in FIG. A main body plate portion 3820 covering the outer surface of each side wall 3604 is provided.
The elastic piece 40 is formed integrally with the main body plate portion 3820.
As shown in FIG. 2, the elastic piece 40 has a bottom at a position away from the upper end of the main body plate portion 3820 away from the bottom wall 3602 from the main body plate portion 3820 via the first bent portion 4001 toward the inner surface of the side wall 3604. It extends in the direction of the wall 3602.
Further, a mounting piece 38A is formed integrally with the main body plate portion 3820.
The attachment piece 38A is arranged in the direction of the inner surface of the side wall 3604 from the main body plate portion 3820 via the second bent portion 3801 from a position distant from the first bent portion 4001 at the upper end portion of the main body plate portion 3820 away from the bottom wall 3602. It extends in the direction of the bottom wall 3602 at a location far from the center.
To attach the socket shielding plate 38 to the side wall 3604, the mounting piece 38A is inserted into a mounting groove 36A that opens at the upper end of the side wall 3604 and extends along the height direction of the side wall 3604. The portion 3820 and the portion 3820 sandwich the portion of the side wall 3604 that constitutes the attachment groove 36A.
Further, at a position corresponding to the elastic deformation notch 3620 that forms a single notch provided on the long side wall 3606, the third bent portion 3802 is formed from the upper end of the main body plate portion 3820 apart from the bottom wall 3602. A folded piece 3803 extending in the direction of the bottom wall 3602 and covering the elastic deformation notch 3620 (single missing part) is provided at a location away from the main body plate portion 3820 in the inner surface direction of the side wall 3604. And the main body plate portion 3820 improve electromagnetic shielding properties.
The two elastic pieces 40 provided on the long side wall 3606 are formed in the folded piece 3803 through the notch 3804 together with the two first bent portions 4001.

Next, the configuration of the socket shielding plate will be described.
As described above, in the imaging device 20, as shown in FIG. 2, the four side walls 3604 each have an inner surface facing each other and an outer surface positioned opposite to the inner surface, and are made of a material having electromagnetic shielding properties and elasticity. A plurality of socket shielding plates 38 that are formed and attached to the respective side walls 3604 to cover the outer surfaces of the four side walls 3604 are provided. The socket shielding plates 38 are formed by inserting the attachment pieces 38A into the attachment grooves 36A. It is configured to be attached to 3604.
As shown in FIG. 9, the end portions 3810 and 3811 of the adjacent socket shielding plates 38 are overlapped at a corner portion 3650 where the adjacent side walls 3604 of the socket body 36 intersect, and the respective socket shielding plates 38 are formed. It is urged | biased by the direction which mutually contacts with the elasticity which has.
Four socket shielding plates 38 are provided corresponding to the four side walls 3604, and the end portions 3810 and 3811 of the adjacent socket shielding plates 38 are overlapped at four corners 3650, respectively. The shield plate 38 is biased in the direction in which the shield plates 38 come into contact with each other.
As shown in FIG. 11, two socket shielding plates 38 are provided so as to cover two adjacent side walls 3604 of the four side walls 3604, and end portions 3810 of the adjacent socket shielding plates 38. , 3811 are overlapped at the two corners 3650 and are biased in the direction of contacting each other by the elasticity of the socket shielding plates 38.

End portions 3810 and 3811 of adjacent socket shielding plates 38 have the same height as the side walls 3604.
As shown in FIGS. 2, 9, and 11, the corner 3650 is provided with a recess 3660 extending over the entire length of the side wall 3604 in the height direction.
The end portions 3810 and 3811 of adjacent socket shielding plates 38 are overlapped over the entire length in the height direction in the recess 3660 and are biased in a direction in contact with each other.
The end portions 3810 and 3811 of the adjacent socket shielding plates 38 will be described in detail. As shown in FIG. 9, one end portion 3810 is arranged in parallel with the side wall 3604 and covers the side wall 3604. The first abutting plate portion 3810 is bent at a right angle from the end of the first contact plate portion 3810. The first contact portion 3810 has the same height as the side wall 3604.
The other end 3811 is connected to the end of the main body plate portion 3820 via a bent portion 3815 and is displaced in the inner surface direction of the side wall 3604 by the thickness of the socket shielding plate 38 and extends in parallel with the main body plate portion 3820. The second abutting plate portion 3811 is formed. The second contact plate portion 3811 has the same height as the side wall 3604.
The adjacent shielding plates 38 for sockets are urged in such a direction that the first contact plate portion 3810 and the second contact plate portion 3811 are overlapped and contact each other over the entire length in the height direction. .

Next, the configuration of the camera module 22 will be described in detail.
12 and 13 are perspective views of the camera module 22, FIG. 14 is an exploded perspective view of the camera module 22, FIG. 15 is an assembly explanatory view of the camera module 22, and FIG. 16 is a sectional view taken along line AA in FIG.
As described above, the camera module 22 includes the case 28, the image sensor 29, the signal processing unit, the substrate 30, and the contact piece 32, as shown in FIGS. A spring 70, a drive unit 72, and the like are included.
In the first reference example, the case 28 includes a lens barrel portion 66, and the lens barrel portion 66 includes a front lens barrel 78 and a rear lens barrel 80.

FIG. 17 is a rear view of the front lens barrel 78 with the front spring 70A attached thereto.
As shown in FIG. 16, the lens barrel portion 66 has an accommodation space S for accommodating the lens holding portion 68.
The lens barrel portion 66 is configured by coupling a front lens barrel 78 and a rear lens barrel 80, and the front lens barrel 78 is configured to transmit light of the photographing optical system 34 as shown in FIGS. It is configured to include a peripheral wall 7802 that is located around the shaft and partitions the side surface of the accommodation space S.
The front lens barrel 78 is formed by molding a synthetic resin material with a mold, and the peripheral wall 7802 has a rectangular frame shape having four side walls.
More specifically, as shown in FIG. 17, the peripheral wall 7802 has a set of first side walls 7802A that face each other and a remaining set of second side walls 7802B that face each other.
The side walls 7802A and 7802B have a height along the optical axis direction and a width in a direction perpendicular to the height. In the first reference example, as shown in FIGS. On the inner surface of 7802A, a bulging wall 7808 is formed extending in the height direction at the center in the width direction.
Projections 7810 are formed at the front end of the bulging wall 7808 so as to protrude from both ends in the width direction of the bulging wall 7808. At the rear end of the bulging wall 7808, as shown in FIG. 7812 is protrudingly formed.
Engagement pins 7814 for coupling to the rear lens barrel 80 project from the rear ends of the two first side walls 7802A.

18 and 19 are perspective views of the rear lens barrel 80 to which the coil 76 is attached, FIGS. 20 and 21 are perspective views of the rear lens barrel 80 to which the coil 76 and the substrate 30 are attached, and FIG. 22 is a rear mirror. 23 is a plan view of the tube 80, FIG. 23 is a plan view of the lens barrel 80 after the substrate 30, the optical filter 31, and the coil 76 are attached, and FIG. 24 is a sectional view taken along line BB of FIG.
As shown in FIGS. 14, 16, and 22, the rear lens barrel 80 includes a rear end surface wall 8002, a coil attachment wall portion 8004, an opening 8006, and an engagement protrusion 8001.
The rear end surface wall 8002 is formed in a rectangular shape that extends on a plane orthogonal to the optical axis and closes the rear end of the accommodation space S in the optical axis direction.
As shown in FIGS. 18, 19, and 20, the rear end face wall 8002 has two sets of sides 8002 </ b> A and 8002 </ b> B that face each other, and an engagement pin 7814 is engaged with one set of sides 8002 </ b> A. An engagement hole 8030 is formed.
The remaining one set of sides 8002B are provided with coil attachment wall portions 8004. In other words, the coil attachment wall portions 8004 are provided at two locations on the rear end face wall 8002 across the optical axis.
The coil attachment wall portion 8004 is for attaching the coil 76, and the coil attachment wall portion 8004 protrudes from the rear end face wall 8002 so as to be accommodated inside the peripheral wall 7802 of the front barrel 78.

As shown in FIGS. 18 and 22, each coil mounting wall portion 8004 includes two pillar walls 8020 projecting from the rear end face wall 8002 on both sides of the side 8002B, and the height direction of the two pillar walls 8020. Connection wall 8022 for connecting the middle of the two.
In the first reference example, as shown in FIGS. 22 and 23, the surfaces of the two column walls 8020 facing the outside are formed as coil abutting surfaces 8020A extending on the same surface.
Further, in the first reference example, the connection wall 8022 is formed in an elongated shape along the extending direction of the side 8002B bulging outward from the coil abutting surface 8020A of the two column walls 8020.
The opening 8006 is provided in a rectangular shape at a location of the rear end face wall 8004 located on the optical axis, and the opening 8006 accommodates the image sensor 29.
The engaging protrusions 8001 are formed so as to protrude from the outer end surface (the remaining set of sides 8002B) of the rear end surface wall 8002 provided with the coil attachment wall portion 8004.

As shown in FIG. 19 and FIG. 24, a mounting portion 8010 for mounting the rear spring 70B is provided at a position of the side 8002A on the front surface of the rear end surface wall 8002, and the mounting portion 8010 includes two mounting surfaces 8012, Each mounting surface 8012 has a pin 8014 projecting therefrom.
As shown in FIGS. 18 and 22, four abutting surfaces 8008 extending on a single plane orthogonal to the optical axis are formed on the front surface of the rear end surface wall 8002 and on the inner side of each column wall 8020, respectively. Has been.
In the first reference example, as shown in FIG. 24, the substrate 30 surrounding the outer periphery of the image sensor 29 is adhered to the rear surface of the rear end face wall 8002 in a state where the image sensor 29 is positioned in the opening 8006, and the rear The image sensor 29 is sealed by adhering the optical filter 31 covering the opening 8006 to the front surface of the end face wall 8002.
In the first reference example, the rear lens barrel 80 is formed by molding a synthetic resin material with a mold.
In the first reference example, as shown in FIGS. 12 and 15, the engagement grooves 2830 formed on the two side surface portions 2810 </ b> B of the camera body shielding plate 2810 are engaged with the two engagement protrusions 8001. The front lens barrel 78 is sandwiched between the upper surface portion 2810A of the camera body shielding plate 2810 and the rear end surface wall 8002 of the rear lens barrel 80, whereby the front lens barrel 78 and the rear lens barrel 80 are coupled. .

25 is a perspective view of the lens holding portion 68 with the magnet 74 attached, FIG. 26 is a perspective view of the lens holding portion 68 with the magnet 74 and the rear spring 70B attached, and FIG. 27 shows the magnet 74 and the rear spring 70B. FIG. 28 is a rear view of the lens holding portion 68, and FIG. 29 is a rear view of the lens holding portion 68 to which the rear spring 70B is attached.
The lens holding portion 68 holds the photographing optical system 34 and is accommodated in the accommodation space S as shown in FIGS.
In the first reference example, as shown in FIGS. 14 and 16, the photographing optical system 34 includes a first group lens to a third group lens 34A, 34B, 34C arranged side by side from the front to the rear, and a first group lens 34A. And a diaphragm 34D disposed between the second group lens 34B and a spacer 34E disposed between the second group lens 34B and the third group lens 34C.

As shown in FIGS. 25 and 26, the lens holding portion 68 has a cylindrical portion 6802, and the cylindrical portion 6802 has an inner surface on which the photographing optical system 34 is disposed and an outer surface positioned opposite to the inner surface. Yes.
A front flange 6804 and a rear flange 6806 are formed on the front and rear of the outer surface of the cylindrical portion 6802, respectively.
Further, as shown in FIG. 25, spring contact surfaces 6805 are formed on the outside of the cylindrical portion 6802 at four positions spaced equally in the circumferential direction so as to be positioned in front of the front flange 6804. The spring contact surface 6805 extends on a plane orthogonal to the optical axis.
Further, as shown in FIGS. 25 and 27, magnet mounting surfaces 6808 that are parallel to a single virtual plane passing through the optical axis are formed at two opposing positions on the outer surface of the cylindrical portion 6802. .
A pair of clamping pieces 6810 for clamping the magnet are formed at the front end of the mounting surface 6808 in the optical axis direction.
As shown in FIGS. 25 and 29, four abutting surfaces 6812 extending on a single plane orthogonal to the optical axis are formed at the four corners of the rear surface of the rear flange 6806, respectively. .
The lens holding portion 68 is formed by molding a synthetic resin material with a mold.

As shown in FIGS. 14 and 16, the spring 70 is disposed in the accommodation space S and supports the lens holding portion 68 so as to be movable along the optical axis of the photographing optical system 34.
In the first reference example, the spring 70 is composed of two springs, a front spring 70A and a rear spring 70B, and these springs 70A, 70B are sandwiched in the accommodation space S along the optical axis of the lens holding portion 68. They are respectively disposed between the projecting portion and the lens barrel portion 66.
The front spring 70A is disposed between the front lens barrel 78 and the lens holding portion 68, and the rear spring 70B is disposed between the rear lens barrel 80 and the lens holding portion 68.
As shown in FIG. 29, these two springs 70A and 70B are formed in an annular shape so that an opening 7001 for the optical path of the photographing optical system 34 is secured in the center from a thin piece having a small width.
More specifically, as shown in FIG. 17, it has an annular plate portion 7002 having an opening 7001 formed therein, and two support pieces 7004 connected to the outer periphery of the annular plate portion 7002, and the optical axis. It is formed to be elastically deformable in the direction.
In the front spring 70A, two support pieces 7004 on the outer periphery are attached to the projection 7810 of the front lens barrel 78, the front part of the cylindrical part 6802 of the lens holding part 68 is inserted into the opening 7001, and the annular plate part 7002 is connected to the lens holding part. 68, which are in contact with the four spring contact surfaces 6805 (see FIG. 25) and disposed between the front lens barrel 78 and the lens holding portion 68.
In the first reference example, the two support pieces 7004 are attached to the protrusions 7810 (see FIG. 17) by insert molding that is embedded when the front lens barrel 78 is molded.

As shown in FIG. 29, the rear spring 70 </ b> B includes an annular plate portion 7010 having an opening 7001 formed therein, and two support pieces 7012 connected to the outer periphery of the annular plate portion 7010.
In the rear spring 70 </ b> B, the ring plate portion 7010 is bonded to the rear surface of the rear flange 6806 of the lens holding portion 68.
Then, holes 7014 (see FIG. 29) formed in the two support pieces 7012 of the rear spring 70B are inserted into the pins 8014 (see FIG. 19) of the rear lens barrel 80, and portions around the holes 7014 of the support piece 7012 are formed. The spring holding piece 7812 (see FIG. 17) of the front lens barrel 78 and the mounting surface 8012 (see FIG. 19) of the rear lens barrel 80 are sandwiched between the rear spring 70B and the rear spring 70B. And the lens holding portion 68.

The front spring 70 </ b> A and the rear spring 70 </ b> B are configured so that the lens holding portion 68 is placed on each of the contact surfaces of the lens holding portion 68 in a state where no current is applied to the coil 76 and no thrust is applied to the magnet 74 (lens holding portion 68). 6812 (see FIGS. 25 and 29) is in contact with each abutment surface 8008 (see FIGS. 18 and 22) of the rear end wall 8002 of the rear barrel 80, in other words, the rearmost in the optical axis direction. It is biased to be positioned at the end.
In the first reference example, each abutting surface 6812 of the lens holding portion 68 abuts on each abutting surface 8008 of the rear end surface wall 8002 of the rear lens barrel 80, so that the optical axis of the photographing optical system 34 is imaged. The state is orthogonal to the imaging surface of the element 29, and the focal length of the subject image photographed by the photographing optical system 34 is infinite, so that the infinite position of the lens holding unit 68 (photographing optical system 34) is It is formed.

The driving unit 72 moves the lens holding unit 68 along the optical axis, and includes a magnet 74 and a coil 76 as shown in FIG.
In the first reference example, as shown in FIGS. 25 and 26, two magnets 74 are provided, and these magnets 74 have a height extending along the optical axis direction and a size larger than this height. It is formed in a rectangular plate shape having a width extending along a direction orthogonal to the height.
The two magnets 74 are arranged in parallel with a single virtual plane passing through the optical axis at a position of the lens holding portion 68 sandwiching the optical axis.
Specifically, the magnet 74 is disposed on each attachment surface 6808 and bonded to the attachment surface 6808 while being sandwiched between the pair of sandwiching pieces 6810.
In the first reference example, the magnet 74 is magnetized so that the N pole and the S pole are located at both ends along the optical axis, and each magnet 74 efficiently guides the magnetic flux to the coil 76. The plate-like yoke 7402 is bonded to the attachment surface 6808.

As shown in FIGS. 18 to 24, the coils 76 are respectively provided at two positions of the lens barrel portion 66 facing the magnet 74, and these two coils 76 are respectively arranged around the axis center where the conducting wire is orthogonal to the optical axis. And is formed in an elongated shape having a height extending along the optical axis direction and a width larger than the height and extending along a direction perpendicular to the height.
The two coils 76 are arranged in parallel to a single virtual plane passing through the optical axis at a position of the lens barrel portion 66 sandwiching the optical axis.
Specifically, the two coils 76 are configured by winding a conducting wire. As shown in FIG. 18, in the first reference example, two parallel straight portions and both ends of the straight portions are connected. It has an oval shape having two curved portions, and an elongated central opening 7602 is formed at the center.
As shown in FIGS. 14 and 18, the coil 76 has both ends in the longitudinal direction aligned with the column wall 8020, the two curved portions are applied to the coil application surface 8020 A, and the coil 76 has a central opening 7602. The connecting wall 8022 is attached with an adhesive while being fitted.
As shown in FIG. 14, the two coils 76 are connected in series via an intermediate portion 7604 of the conductive wire. As shown in FIG. 18, the end portion 7605 of the conductive wire of each coil 76 is connected to the rear end face wall 8002. As shown in FIG. 20, the wound portions are wound around the protruding protrusions 8003 and connected to the soldering pads 3010 on the surface of the substrate 30 by soldering.
A drive signal is supplied to the conducting wire from the substrate 30 via each soldering pad 3010, whereby a magnetic field is generated from the coil 76.
Therefore, a force (thrust) in the optical axis direction is generated in the coil 76 by the interaction between the magnetic field generated by the coil 76 and the magnetic field generated from the magnetic pole of the magnet 74, and thereby the lens held by the spring 70. The holding unit 68 and the photographic optical system 34 move in the optical axis direction, and the subject image focused on the imaging surface of the image sensor 29 is focused by the photographic optical system 34.

FIG. 33 is a diagram for explaining the operation of the magnet 74 and the coil 76.
Specifically, as shown in FIG. 33, the lens holding portion 68 has an optical axis direction due to the interaction between the magnetic field generated by the drive signal flowing in the coil 76 in the direction of arrow A and the magnetic field generated from the magnet 74. A force F in the direction of the arrow acts along and the lens holding portion 68 is moved.
When a drive signal flows through the coil 76 in a direction opposite to the above, a magnetic field in the opposite direction to the above is generated from the coil 76, so that the lens holding unit 68 has a direction opposite to the above along the optical axis direction. The lens holding portion 68 is moved by the action of the above.

  In the first reference example, two positions sandwiching the center of gravity of the lens holding portion 68 provided with the photographing optical system 34 and the magnet 74 are configured as force points at which thrust is generated by the coil 76, and the front spring 70A and the rear spring 70A are arranged. The operating point of the spring 70B is configured to be located between the gravity center and the force point, which is advantageous for the lens holding portion 68 to move accurately along the optical axis direction. This is advantageous in suppressing distortion of the subject image formed on the surface.

Next, a method for assembling the camera module 22 will be described.
As shown in FIG. 15, the first unit U1 in which the front spring 70A is incorporated in the front barrel 78, and the second unit U2 in which the photographing optical system 34, the magnet 74, and the rear spring 70B are incorporated in the lens holding portion 68. The third unit U3 in which the coil 76, the imaging device 29, and the substrate 30 are assembled to the rear lens barrel 80 is separately assembled and prepared.
Then, the second unit U2 is assembled to the third unit U3. In other words, the pin 8014 (see FIG. 38) of the rear barrel 80 is inserted into the hole 7014 of the rear spring 70B, and the second unit U2 and the third unit U3 are aligned.
Next, the first unit U1 is assembled to the assembled one. In other words, the front portion of the cylindrical portion 6802 of the lens holding portion 68 is inserted into the opening 7001 of the front spring 70A, and the annular plate portion 7002 is brought into contact with the four spring abutting surfaces 6805 of the lens holding portion 68. And the third unit U3.
Finally, the camera body shielding plate 2810 is placed on the first unit U1, and the engaging groove 2830 is engaged with the engaging protrusion 8001. In other words, the camera body shielding plate 2810 is placed on the first unit U1, and the front lens barrel 78 is sandwiched between the upper surface portion 2810A of the camera body shielding plate 2810 and the rear end surface wall 8002 of the rear lens barrel 80. Let
As a result, the first unit U1 and the third unit U3 are combined, and the camera module 22 is completed.

In the first reference example, each abutment surface 6812 of the lens holding portion 68 abuts on each abutment surface 8008 of the rear end surface wall 8002 of the rear lens barrel 80, so that the lens holding portion 68 (the photographing optical system). The case where the infinite position of 34) is formed has been described.
However, when each abutting surface 6812 of the lens holding portion 68 abuts on each abutting surface 8008 of the rear end surface wall 8002 of the rear lens barrel 80, an infinite position is formed with the lens holding portion 68 tilted. Then, there is a concern that the optical axis of the imaging optical system 34 is inclined with respect to the imaging surface of the imaging device 29, and the subject image formed on the imaging surface by the imaging optical system 34 is distorted.
Such a phenomenon is caused by the center of gravity of the lens holding portion 68 including the photographing optical system 34, the location where the lens holding portion 68 and each of the springs 70A and 70B are connected, that is, the action point (fulcrum) and the two magnets. It is structurally impossible to match the three positions with the force point where the thrust force is generated at 76, and the three positions are caused by variations due to part processing errors, assembly errors, and the like.
In this type of camera module 22, in many cases, the distance between the camera module 22 and the subject is about 1 m or more, and therefore the subject is photographed at an infinite position of the lens holding unit 68 (the photographing optical system 34). The ratio is 80% or more. Therefore, prevention of distortion of an image captured at an infinite position is most important in actually using the camera module 22.

Such inclination of the lens holding portion 68 at the infinity position of the lens holding portion 68 (the photographing optical system 34) can be prevented by adopting the configuration described below.
30 is a cross-sectional view of the camera module 22 that can prevent the lens holding portion 68 from tilting, FIG. 31 is a plan view of the rear barrel 80 of the camera module 22, and FIG. 32 is a rear view of the lens holding portion 68.
As shown in FIGS. 30 and 31, the rear end wall 8002 of the rear lens barrel 80 has an engagement recess 8040 made of a conical surface formed along an axis perpendicular to the plane in which the rear end wall 8002 extends. Two are formed.
The two engaging recesses 8040 are provided at two locations that sandwich the optical axis and are equal in distance from the optical axis.

As shown in FIGS. 30 and 32, at the position of the rear flange 6808 of the lens holding portion 68 facing the two engaging recesses 8040, the two engaging recesses 8040 are formed along the axis parallel to the optical axis. Engaging convex portions 6840 each having a conical surface having a shape matching the conical surface are provided.
Therefore, when energization of the coil 76 is stopped, the lens holding portion 68 is moved rearward by the urging force of the springs 70A and 70B, and the two engaging convex portions 6840 of the lens holding portion 68 are moved to the rear lens barrel 80. The two engaging recesses 8040 are engaged with each other, thereby forming an infinite position of the lens holding portion 68 (the photographing optical system 34).
At this time, the conical surfaces of the engaging convex portion 6840 and the engaging concave portion 8040 are overlapped with each other so that the posture of the lens holding portion 68 is determined so that the axes of the conical surfaces coincide with each other. The inclination of the lens holding unit 68 at the infinity position of the holding unit 68 (the photographing optical system 34) is prevented.
Therefore, distortion is prevented from occurring in the subject image formed on the imaging surface by the photographing optical system 34.
Note that the same configuration as described above is adopted even when the front end position of the lens holding portion 68 (the photographing optical system 34), which is the position opposite to the infinity position, that is, when the camera module 22 and the subject are closest to each other. Of course, the distortion of the image may be prevented. In that case, an engaging convex part and an engaging concave part may be provided in the lens holding part 68 and the front lens barrel 78, respectively.

(First embodiment)
Next, a first embodiment of the camera module 22 according to the present invention will be described.
FIG. 34 is an exploded perspective view of the camera module 22 in the first embodiment, FIG. 35 is an assembly explanatory view of the camera module 22, FIG. 36 is a cross-sectional view of the camera module 22, and FIG. 38 is a cross-sectional view taken along the line AA in FIG. 37, and FIG. 39 is a perspective view showing a state in which the lens holding portion 68 is accommodated in the rear lens barrel 80.
The first embodiment is different from the first reference example described above in the configuration of the coil, and the other configurations are the same as those in the first reference example. The same reference numerals are given to the drawings and the description thereof is omitted.
As shown in FIGS. 34 to 36, the camera module 22 includes a lens barrel portion 66, a lens holding portion 68, a spring 70, an image sensor 29, and a drive portion 72. The drive portion 72 includes a magnet 82. And a coil 84.
The configurations of the lens holding portion 68, the spring 70, and the image sensor 29 are the same as those in the first reference example.

Similar to the first reference example, the two magnets 82 are arranged in parallel with a single virtual plane passing through the optical axis at a position of the lens holding portion 68 sandwiching the optical axis.
As in the first reference example, the two magnets 82 are rectangular having a height extending along the optical axis direction and a width extending along a direction perpendicular to the height with a dimension larger than the height. It is formed in the shape of a plate.
The arrangement of the magnet 82 is the same as that of the first reference example. As shown in FIGS. Are attached to the mounting surface 6808 of the lens holding portion 68.
The magnetized form of the magnet 82 will be described later.

The coil 84 has a frame shape with the optical axis as the center when the conductive wire is wound around the optical axis and viewed from the optical axis direction. In the present embodiment, the coil 84 has a rectangular frame shape.
The coil 84 includes two coils: a first coil 84A that faces the front portion of the magnet 82 in the optical axis direction, and a second coil 84B that faces the rear portion of the magnet 82 in the optical axis direction.
As shown in FIG. 35 and FIG. 36, the first coil 84A and the second coil 84B have two coil portions 8402 extending parallel to a single virtual plane and facing the two magnets 82, respectively. Have.
Each coil portion 8402 has a height extending along the optical axis direction, a width larger than the height, a width extending along a direction perpendicular to the height, and a thickness smaller than the height and the width. It has a rectangular flat plate shape.

As shown in FIG. 34, the lens barrel portion 66 has a front lens barrel 78 and a rear lens barrel 80.
As shown in FIG. 34, the front lens barrel 78 includes a peripheral wall 7802 located around the optical axis.
As shown in FIGS. 37 and 38, the rear lens barrel 80 includes a rear end surface wall 8002 that extends on a surface orthogonal to the optical axis and closes the rear end in the optical axis direction of the peripheral wall 7802, and a rear end surface wall. A cylindrical wall portion 8050 that protrudes from 8002 and is accommodated inside the peripheral wall 7802 and that divides the side surface of the accommodating space S and is wound with the coil 84, and a rear end surface wall 8002 located on the optical axis. And an opening 8006 in which the image pickup element 29 is accommodated.
A first coil mounting groove 8052A and a second coil mounting groove 8052B are provided on the outer periphery of the cylindrical wall portion 8050 at an interval in the optical axis direction, and a flange 8054 projects between the coil mounting grooves 8052A and 8052B. It is installed.
As shown in FIG. 38, the bottom surface of the first coil mounting groove 8052A and the bottom surface of the second coil mounting groove 8052B have two bottom surface portions 8056A and 8056B facing each other in parallel to a single virtual plane. is doing.
The first coil 84A is mounted and disposed in the first coil mounting groove 8052A.
The second coil 84B is mounted and disposed in the second coil mounting groove 8052A.
As shown in FIGS. 37 and 38, the first coil mounting groove 8052A has a bottom surface portion 8056A and a second coil mounting groove 8054B has a bottom surface portion 8056B. Openings 8058 that face each other are formed.

Next, a method for assembling the camera module 22 will be described.
As shown in FIG. 15, the first unit U1 in which the front spring 70A is incorporated in the front barrel 78, and the second unit U2 in which the photographing optical system 34, the magnet 82, and the rear spring 70B are incorporated in the lens holding portion 68. The third unit U3 in which the coil 84, the imaging device 29, and the substrate 30 are assembled to the rear lens barrel 80 is separately assembled and prepared.
Then, the second unit U2 is assembled to the third unit U3. In other words, the pin 8014 (see FIG. 38) of the rear barrel 80 is inserted into the hole 7014 of the rear spring 70B, and the second unit U2 and the third unit U3 are aligned.
Next, the first unit U1 is assembled to the assembled one. In other words, the front portion of the cylindrical portion 6802 of the lens holding portion 68 is inserted into the opening 7001 of the front spring 70A, and the annular plate portion 7002 is brought into contact with the four spring abutting surfaces 6805 of the lens holding portion 68. And the third unit U3.
Finally, the camera body shielding plate 2810 is placed on the first unit U1, and the engaging groove 2830 is engaged with the engaging protrusion 8001. In other words, the camera body shielding plate 2810 is placed on the first unit U1, and the front lens barrel 78 is sandwiched between the upper surface portion 2810A of the camera body shielding plate 2810 and the rear end surface wall 8002 of the rear lens barrel 80. Let
As a result, the first unit U1 and the third unit U3 are combined, and the camera module 22 is completed.

The first coil 84A and the second coil 84B are connected in series via an intermediate portion (not shown) of the conducting wire, and as in the first reference example, as shown in FIG. The ends of the lead wires 84B are respectively wound around convex portions 8003 projecting from the rear end wall 8002 of the rear lens barrel 80, and these wound portions are soldered to solder pads on the surface of the substrate 30. Connected by soldering.
A drive signal is supplied to the conducting wire from the substrate 30 via the soldering pads, whereby a magnetic field is generated from the first coil 84A and the second coil 84B.
Therefore, the interaction between the magnetic field generated by the first coil 84A and the second coil 84B and the magnetic field generated by the magnetic pole of the magnet 82 causes the first coil 84A and the second coil 84B to move in the optical axis direction. A force (thrust) is generated, whereby the lens holding unit 68 and the imaging optical system 34 held by the spring 70 move in the optical axis direction, and the imaging optical system 34 forms an image on the imaging surface of the imaging element 29. Subject image focusing operation is performed.

Next, the winding direction of the first coil 84A and the second coil 84B and the magnetized form of the magnet 82 will be described in detail.
40 and 41 are diagrams for explaining the operation of the magnet 82 and the coil 84. FIG.
First, with reference to FIG. 40, the case where the winding direction of the conducting wire of the first coil 84A and the winding direction of the conducting wire of the second coil 84B are opposite to each other will be described.
In this case, the magnet 82 is magnetized so that the N pole and the S pole are located at both ends along the optical axis.
A drive signal flows in the first coil 84A (coil portion 8402) in the direction of arrow A, and a magnetic field generated by the drive signal flowing in the second coil 84B (coil portion 8402) in the direction of arrow B and the magnet 82 Due to the interaction with the generated magnetic field, the lens holding portion 68 is moved by the force F acting on the lens holding portion 68 along the optical axis direction.
Further, when a drive signal flows through the first and second coils 84A and 84B (coil portion 8402) in the opposite direction, a magnetic field in the opposite direction from the first and second coils 84A and 84B. As a result, a force F acts on the lens holding portion 68 in the opposite direction to move the lens holding portion 68.

Next, a case where the winding direction of the conducting wire of the first coil 84A and the winding direction of the conducting wire of the second coil 84B are set in the same direction will be described with reference to FIG.
The magnet 82 is magnetized so that the N pole and the S pole are located on both sides in the thickness direction.
The lens holding portion 68 receives light by the interaction between the magnetic field generated by the drive signal flowing in the direction of arrow A in the first and second coils 84A and 84B (coil portion 8402) and the magnetic field generated from the magnet 82. A force F acts along the axial direction to move the lens holding portion 68.
When a drive signal flows through the first and second coils 84A and 84B (coil portion 8402) in the opposite direction, a magnetic field in the opposite direction is generated from the first and second coils 84A and 84B. As a result, a force F acts on the lens holding portion 68 in the direction opposite to the above, and the lens holding portion 68 is moved.

As described above, according to the camera module 22 of the present embodiment, the magnet 82 is provided in the lens holding portion 68 that holds the photographing optical system 34, and the coil 84 is provided in the lens barrel portion 66. In addition, the following effects can be obtained as compared with a camera module in which a coil is provided in the lens holding portion and a coil is provided in the lens barrel portion.
Conventionally, since the lens holding portion is provided with a coil, stress acts on the conducting wire constituting the coil as the lens holding portion moves. Therefore, when an impact is applied to the camera module and the lens holding part moves, a large force is applied to the coil lead wire, and there is a concern about the occurrence of disconnection or the like. In this embodiment, the coil is attached to the lens holding part. Since it is not provided, occurrence of such a problem is prevented, which is advantageous in improving durability and impact resistance.
Conventionally, since the lens barrel is provided with a magnet and the lens holding part is provided with a coil, a spring for holding the lens holding part is formed of a conductive member, and the spring is soldered to the coil. A drive signal is supplied to the coil via
Therefore, in order to improve the workability of soldering, a dedicated member for attaching the coil is prepared, soldering is performed with the coil attached to the dedicated member, and then the dedicated member is attached to the lens holding portion. However, this method is troublesome. On the other hand, in the present embodiment, since the coil is not provided in the lens holding portion, a dedicated member for attaching the coil is not necessary, and the coil can be easily attached, the number of parts can be reduced, and the size can be reduced. This is advantageous in reducing the manufacturing cost.

Conventionally, when a coil provided in the lens holding portion generates heat by energization, the heat is transmitted to the photographing optical system via the lens holding portion, and the lens is affected by the heat (for example, deformation due to thermal expansion). Although there is a concern about the deterioration of the characteristics, in the present embodiment, since no coil is provided in the lens holding portion, the occurrence of such a problem is prevented, and the optical characteristics of the photographing optical system are improved. This is advantageous.
Conventionally, in the process of soldering the coil to the lens holding portion, there is a concern that the heat is transmitted to the photographing optical system via the lens holding portion and the optical characteristics are deteriorated due to the influence of the lens by the heat. On the other hand, in the present embodiment, since no coil is provided in the lens holding portion, the occurrence of such a problem is prevented, which is advantageous in improving the optical characteristics of the photographing optical system.
Conventionally, since the drive signal is supplied to the coil via the spring, the material of the spring is limited to the conductive material. In the present embodiment, the drive signal can be supplied directly to the coil 84 and the spring is used. Therefore, it is not necessary to supply a drive signal, so the material of the spring may be a non-conductive material, which is advantageous in securing the degree of freedom in design.
Conventionally, since the coil around which the conductive wire is wound is provided in the lens holding portion, there is a problem that the balance of the center of gravity of the lens holding portion is influenced by the variation in the center of gravity of the coil. Since the lens holding portion is provided with a magnet that is easy to obtain the accuracy of shape and size as compared with the coil, it is easy to balance the center of gravity of the lens holding portion, which is advantageous in suppressing the inclination of the optical axis of the photographing optical system.
Conventionally, since the lens holding portion is provided with a coil, when the lens holding portion is incorporated into the lens barrel portion, the coil lead wire and soldering are complicated, but in the present embodiment, Since the lens holding part is provided with a magnet and the lens barrel part is provided with a coil, as described above, the camera module can be easily assembled by assembling the first to third units U1, U2, U3 separately. It can be completed, and it is not necessary to carry out complicated operations such as drawing the coil conductor and soldering, which is advantageous in improving the assembly workability.

Further, according to the present embodiment, the coil 84 has a lens barrel portion because the conducting wire is wound around the optical axis and has a frame shape centered on the optical axis when viewed from the optical axis direction. The coil 84 can be attached to the lens barrel portion at the same time as the coil 84 is formed by winding a conducting wire around 66.
Therefore, for example, as in the first reference example, a conductor formed by winding a wire in advance in an annular shape is prepared, and then the molded coil 84 is attached to the lens barrel portion by bonding. This is advantageous in simplifying assembly work and reducing costs.

(Second Embodiment)
Next, a second embodiment will be described.
The second embodiment is different from the first embodiment in the configuration of the coil, and the other configurations are the same as those in the first reference example. Therefore, in the same places as in the first embodiment, The same reference numerals are given to the drawings and the description thereof is omitted.
42 is a perspective view showing a state in which the lens holding portion 68 of the camera module 22 in the second embodiment is accommodated in the rear lens barrel 80, FIG. 43 is a sectional view of the camera module 22, and FIG. FIG.
Although the case where the two coils 84A and 84B are used has been described in the first embodiment, only one coil 84 is used in the second embodiment.
As shown in FIGS. 42 and 43, the coil 84 has two coil portions 8402 that extend in parallel to a single virtual plane passing through the optical axis and face the two magnets 82.
The coil portion 8402 corresponds to the shape of the magnet 82, the height extending along the optical axis direction, the width larger than this height, the width extending along the direction orthogonal to this height, and the height thereof. And a rectangular flat plate having a thickness smaller than the width.

Similarly to the first embodiment, the lens barrel portion 66 includes a front lens barrel 78 and a rear lens barrel 80. As shown in FIGS. 42 and 45, the cylindrical wall portion of the rear lens barrel 80 is provided. A coil mounting groove 8460 is provided on the outer periphery of 8450.
The bottom surface of the coil mounting groove 8460 has two bottom surface portions 8462 that face each other in parallel with the single virtual plane.
The coil 84 is mounted and disposed in the coil mounting groove 8460, and an opening 8464 that makes the coil 84 face the magnet 82 is formed in the bottom surface portion 8462 of the coil mounting groove 8460.

Both ends of the conductive wire of the coil 84 are wound around a convex portion 8003 projecting from the rear end wall 8002 of the rear lens barrel 80, and the wound portions are soldered pads on the surface of the substrate 30 by soldering. It is connected with soldering.
A drive signal is supplied to the conducting wire from the substrate 30 through the soldering pads, whereby a magnetic field is generated from the coil 84.
Therefore, a force (thrust) in the optical axis direction is generated in the coil 84 by the interaction between the magnetic field generated by the coil 84 and the magnetic field generated by the magnetic pole of the magnet 82, and thereby the lens held by the spring 70. The holding unit 68 and the photographic optical system 34 move in the optical axis direction, and the subject image focused on the imaging surface of the image sensor 29 is focused by the photographic optical system 34.

Next, the winding direction of the coil 84 and the magnetized form of the magnet 82 will be described in detail.
FIG. 45 is an explanatory view of the operation of the magnet 82 and the coil 84.
The magnet 82 is magnetized so that the N pole and the S pole are located on both sides in the thickness direction.
Due to the interaction between the magnetic field generated when the drive signal flows in the coil 84 (coil portion 8402) in the direction of arrow A and the magnetic field generated from the magnet 82, the force F is applied to the lens holding portion 68 along the optical axis direction. The lens holding part 68 is actuated and moved.
When a drive signal flows through the coil 84 (coil portion 8402) in the opposite direction, a magnetic field in the opposite direction is generated from the coil 84, so that the lens holding portion 68 has a direction opposite to the above. A force F acts on the lens holding portion 68 to move it.

  Of course, in the second embodiment, the same effect as in the first embodiment can be obtained. In the first embodiment, the two coils of the first and second coils 84A and 84B are provided. Although the coil is used, in the second embodiment, since only one coil 84 is required, it is further advantageous in simplifying the assembly work and reducing the cost.

Next, the camera module 22 of the second reference example will be described.
The second reference example has a locking plate 86 that holds the inner and outer lens barrels as a main part.
In the second reference example, the front lens barrel 78 described in the first reference example is the outer lens barrel 78, and the rear lens barrel 80 is the inner lens barrel 80.
As described above, the camera module 22 holds the lens barrel 66 having the accommodation space S and the imaging optical system 34 and is accommodated in the accommodation space S and supported so as to be movable along the optical axis of the imaging optical system 34. A lens holding unit 68, an image pickup device 31 that is provided in the lens barrel unit 66 and picks up a subject image guided by the shooting optical system 34, and a drive unit that moves the lens holding unit 68 along the optical axis of the shooting optical system 34. 72.
The lens barrel portion 66 includes an inner lens barrel 80 in which the accommodation space S is formed, and an outer lens barrel 78 disposed outside the inner lens barrel 80.
The inner lens barrel 80 extends on a plane orthogonal to the optical axis, closes the rear end of the outer lens barrel 78 in the optical axis direction, and has a rear end surface wall 8002 in which an opening 8006 for accommodating the image sensor 31 is formed. have.

In a state where the outer lens barrel 78 is disposed outside the inner lens barrel 80, the lens barrels 78 and 80 are coupled without rattling in the direction orthogonal to the optical axis.
In the second reference example, the four columnar walls 8020 shown in FIG. 18 are engaged with the four corners 7820 inside the peripheral wall 7802 of the outer barrel 78 shown in FIG. Are coupled without rattling in a direction perpendicular to the optical axis.
Further, as shown in FIG. 15, a first abutting surface 8062 extending on a virtual plane orthogonal to the optical axis is formed at a location where the rear end face wall 8002 faces forward in the optical axis direction, and the outer mirror A second abutment surface 7822 extending on a virtual plane orthogonal to the optical axis is formed at the rear end in the optical axis direction of the cylinder 78, and the outer lens barrel 78 is disposed outside the inner lens barrel 80. In the state, the first abutting surface 8062 and the second abutting surface 7822 are brought into contact with each other.
That is, the inner lens barrel 80 and the outer lens barrel 78 are clamped in the optical axis direction by the locking plate 86 in a state where the first abutting surface 8062 and the second abutting surface 7822 are in contact with each other.

The locking plate 86 includes a front plate portion 86A and two side plate portions 86B as shown in FIGS.
The locking plate 86 includes the inner lens barrel 80 and the outer lens barrel 78 in a state where the front plate portion 86A is locked to the front end of the outer lens barrel 78 and the front ends of the two side plate portions 86B are locked to the rear end surface wall 8002. Is sandwiched in the optical axis direction.
The locking plate 86 is the camera body shielding plate 2810 described in the first reference example.
In the second reference example, the locking plate 86 is formed of a material having magnetic shielding properties, electromagnetic shielding properties, and conductivity.
As such a material, for example, various conventionally known materials such as a highly permeable metal, permalloy, and iron oxide can be used.
Further, the outer surface 8602 located on the opposite side to the inner surface where the front plate portion 86A of the locking plate 86 faces the front end of the outer lens barrel 78 is subjected to surface treatment that prevents light reflection and has conductivity. .
As such a surface treatment, for example, paint coating for preventing light reflection or plating for preventing light reflection can be employed. The paint may be any paint that can prevent light reflection, such as black paint.

As shown in FIGS. 12 and 15, the front plate portion 86 </ b> A is formed in a rectangular shape with a size that covers the front end by engaging with the front end of the outer lens barrel 78 in the optical axis direction.
An opening 8604 for securing an optical path of the photographing optical system 34 is formed in the center of the front plate portion 86A.
The lens barrel portion 66 has a rectangular plate-like contour having a thickness along the optical axis direction and a length and width larger than the thickness in a state where the outer lens barrel 78 is disposed outside the inner lens barrel 80. The front plate portion 86A has a rectangular shape.
As shown in FIG. 15, a third abutment surface 7824 extending on a virtual plane orthogonal to the optical axis is formed at the front end of the outer lens barrel 78 in the optical axis direction, and the front plate portion 86A is a third plate. The front plate portion 86 </ b> A is locked to the front end of the outer barrel 78.
In the second reference example, the third abutting surface 7824 extends in a rectangular frame shape as seen from the optical axis direction, as shown in FIG.
As shown in FIGS. 12 and 15, the third abutting surface 7824 is provided with a convex portion 7826, the front plate portion 86A is provided with a notch portion 8606 that can be engaged with the convex portion 7826, and the convex portion 7826 is provided. And the notch portion 8606 engage with each other, whereby the front plate portion 86A is positioned with respect to the front end of the outer lens barrel 78 in the optical axis direction on a virtual plane orthogonal to the optical axis.

As shown in FIG. 15, the side plate portion 86B is bent from a pair of opposing sides of the front plate portion 86A.
A locking notch 2830 is provided at the tip of the side plate portion 86B.
Locking projections 8001 are provided at two locations on the outer periphery of the rear end surface wall 8002 across the optical axis, and the two side plate portions 86B are locked to the rear end surface wall 8002 at the ends by the protrusions 8001 and the notches. This is easily and reliably achieved by locking with 2830.
As shown in FIG. 15, a plane portion 7830 that is parallel to a single virtual plane passing through the optical axis is formed at a position sandwiching the optical axis on the outer periphery of the outer barrel 78, and the front plate portion 86A. Are engaged with the front end of the outer lens barrel 78 and the front ends of the two side plate portions 86B are engaged with the rear end surface wall 8002, and the two side plate portions 86B are brought into contact with the flat surface portion 7830, respectively.

According to the second reference example, the inner lens barrel 80 and the outer lens barrel 78 can be easily sandwiched in the optical axis direction by using the locking plate 86, and the inner lens barrel 80 and the outer lens barrel 78 are bonded. Compared to bonding with adhesives, it is not necessary to adjust and manage the amount of adhesive applied and curing conditions, and it is not necessary to secure the curing time of the adhesive, which greatly simplifies assembly work. This is advantageous for cost reduction.
Further, by removing the notch 2830 from the protrusion 8001, the locking plate 86 can be easily removed. By removing the locking plate 86 from the inner lens barrel 80 and the outer lens barrel 78, the inner lens barrel 80 and the outer lens barrel 80 can be removed. 78 can be easily disassembled, which is advantageous for quick and easy adjustment and repair of the lens holding portion 68 and the driving portion 72 incorporated in the inner lens barrel 80 and the outer lens barrel 78.

Further, as in the second reference example, when the driving unit 72 includes a magnet provided in the lens holding unit 68 and a coil provided in the inner barrel 80, the magnet There is a risk of moving by a force generated by a mutual magnetic field effect caused by a magnetic field acting from the outside of the camera module 22 and being displaced from a position where it should be originally located. In that case, inconveniences such as defocusing of the subject image formed on the image sensor 29 by the photographing optical system 34 occur.
In the second reference example, since the locking plate 86 has magnetic shielding properties, the magnetic field from the outside is shielded by the locking plate 86 and does not affect the drive unit. This is advantageous for improvement.
In addition, since the magnetic field generated from the coil of the drive unit is shielded by the locking plate 86, it is possible to prevent the magnetic field from being radiated to the electronic components and electronic circuits around the camera module, which is advantageous. .

In particular, when the camera module 22 is incorporated into a mobile phone, a coil or magnet that generates a magnetic field, such as a motor for generating an incoming call vibration (vibration) or a receiver (speaker), is provided in the vicinity of the camera module 22. The parts using the are placed.
In recent years, since the mobile phone has been further reduced in size and thickness, the distance between the component and the camera module is close, and therefore the drive unit of the camera module has a magnetic field generated in the mobile phone. Is more susceptible to
However, in the second reference example, since the locking plate 86 is formed of a material having magnetic shielding properties, the influence of the magnetic field from the parts is prevented while realizing the downsizing and thinning of the mobile phone, and imaging. This is advantageous in improving the quality of an image picked up by the element 29.

In the second reference example, since the locking plate 86 has electromagnetic shielding properties in addition to magnetic shielding properties, the electromagnetic wave generated from the drive unit 72 is shielded by the locking plate 86, so that the camera module. Therefore, it is possible to prevent electromagnetic waves from being radiated to the outside of the camera 22, which is advantageous in preventing the influence of electromagnetic waves on electronic components and electronic circuits arranged in the vicinity of the camera module 22.
Furthermore, in the second reference example, since the locking plate 86 has conductivity, the electromagnetic wave can be more effectively shielded by grounding the locking plate 86 via the socket 24. It will be advantageous.

Unlike the driving unit 72 of the second reference example, when the driving unit is configured to include a coil provided in the lens holding unit and a magnet provided in the lens barrel, the magnet is a mirror. An electronic component or electronic circuit in which the magnetic field generated from the coil of the drive unit is arranged close to the camera module, although it is not easily affected by the magnetic field from the outside of the camera module because it is provided and fixed to the tube unit There is concern that it will affect
Therefore, in this case, the inconvenience described above can be prevented by configuring the locking plate 86 with a material having electromagnetic shielding properties.
Examples of such a material having magnetic shielding properties include various conventionally known magnetic shielding properties such as a plate material formed of a metal material, a metal net, a punching metal, and a plate material provided with a metal film (metal foil, vapor deposition, plating). Materials can be used.

As shown in FIG. 46, when the camera module 22 is incorporated into the housing of an electronic device such as a mobile phone, the camera module 22 is provided with the opening of the front plate portion 86A of the locking plate 86 in the housing. It is arranged facing the opening on the housing side.
In many cases, the cover glass 2 shown in FIG. 46 (corresponding to the lens cover 58 shown in FIG. 1) is attached to the housing side opening, and the outer surface 8602 of the front plate portion 86A of the locking plate 86 of the camera module, A gap is formed between the inner surface of the cover glass 2 facing the outer surface.
At this time, a part of the light L that has passed through the cover glass 2 from the outside of the housing is repeatedly reflected between the outer surface 8602 of the front plate portion 86A and the inner surface of the cover glass 2, and enters the photographing optical system 34. Then, a problem such as a blurred image called a ghost being picked up by the image pickup device 29 occurs.
In the second reference example, the outer surface 8602 of the front plate portion 86A of the locking plate 86 is subjected to a surface treatment for preventing light reflection. This can be prevented, which is advantageous in improving the quality of the image captured by the image sensor 29.
Needless to say, the surface treatment may be performed on the entire outer surface of the front plate portion 86A and the side plate portion 86B of the locking plate 86. In this case, if the paint or plating used in the surface treatment is conductive, the conductivity of the locking plate 86 can be secured, and the locking plate 86 can be easily grounded via the socket 24. This is advantageous in securing electromagnetic shielding by the stop plate 86.

In the second reference example, the locking plate 86 has a front surface portion 86A that covers the front end of the outer lens barrel 78, and two side plate portions 86B that cover two opposing surfaces of the peripheral wall 7802 of the outer lens barrel 78. The side plate portion is bent from three or four sides of the front surface portion 86A, and the three or four side plate portions cover the three or four surfaces of the peripheral wall 7802 of the outer barrel 78. Also good. Further, the rear surface portion that covers the rear surface of the substrate 30 from the side located at the tip of the side plate portion 86B may be bent.
As described above, the greater the number of surfaces of the lens barrel portion 66 covered with the locking plate 86, the more advantageous is the magnetic shielding effect and the electromagnetic shielding effect.

Next, a third reference example will be described.
47 is an assembly explanatory diagram of the dust-proof cover 31, the lens barrel 66, the image pickup device 29, and the substrate 30, FIG. 48 is a plan view of the rear end surface wall 8002, FIG. 49 is an installation explanatory diagram of the dust-proof cover 31, and FIG. , (B) is a cross-sectional explanatory view showing a state where the dust cover 31 is attached.
In the third reference example, the optical filter 31 described in the first reference example is the dust cover 31.
As described above, the camera module 22 includes the lens barrel portion 66 and the lens holding portion 68 that holds the photographing optical system 34 and is accommodated in the lens barrel portion 66 and supported so as to be movable along the optical axis of the photographing optical system 34. An imaging device 29 that is provided in the lens barrel portion 66 and that captures a subject image guided by the imaging optical system 34, a substrate 30 on which the imaging device 29 is mounted, and a lens holding portion 68 that are connected to the optical axis of the imaging optical system 34. And a drive unit 72 that is moved along.
The lens barrel portion 66 extends on a plane orthogonal to the optical axis, closes the rear end of the lens barrel portion 66 in the optical axis direction, and is formed with an opening 8006 in which the imaging element 29 is accommodated. A face wall 8002 is provided.
As shown in FIGS. 47 and 48, the rear end face wall 8002 has a front face 8070A facing forward in the optical axis direction and a rear face 8070B facing rearward in the optical axis direction.
The substrate 30 is attached to the rear face 8070B of the rear end face wall 8002 with an adhesive in a state where the image pickup element 29 is accommodated in the opening 8006. By this substrate 30 and the adhesive, the rear surface 8070B of the rear end surface wall 8002 around the opening 8006 is closed and sealed.
The transparent dustproof cover 31 is attached to the front surface 8070A of the rear end face wall 8002 by the adhesive B, and the opening 8006 is closed.
The dust-proof cover 31 may be anything that prevents the entry of dust into the opening 8006. For example, the dust-proof cover 31 may be an infrared cut filter, or may be glass or synthetic resin that does not have an optical filter function. Good.

In the third reference example, as shown in FIGS. 48 and 49, the periphery of the opening 8006 of the front surface 8070A of the rear end face wall 8002 is continuous in the circumferential direction of the opening 8006 and orthogonal to the optical axis of the photographing optical system 34. A flat abutting surface 8060 extending on the virtual plane is formed.
Then, an adhesive filling groove 8062 filled with the adhesive B is formed at the location of the abutting surface 8060 around the opening 8006.
The adhesive filling groove 8062 extends continuously in the circumferential direction of the opening 8006.
Then, a portion 8060A of the abutting surface 8060 where the adhesive filling groove 8062 is not formed remains between both ends of the adhesive filling groove 8062 in the extending direction.

In the third reference example, the transparent dust-proof cover 31 is applied to the contact surface 8060, and the dust-proof cover 31 is bonded to the front surface 8070A (the contact) of the rear end surface wall 8002 by the adhesive B filled in the adhesive filling groove 8062. It is attached to the attaching surface 8060).
More specifically, the adhesive filling groove 8062 is filled between the annular portion around the opening 8006 of the front surface 8070A of the rear end face wall 8002 and the outer peripheral portion of the dust-proof cover 31 located around the opening 8006. An adhesive portion 90A (FIG. 50A) where the adhesive B is located and a non-adhesive portion 90B (FIG. 50B) not filled with the adhesive B intervene, and the non-adhesive portion 90B is an adhesive. The portion 8060A of the abutting surface 8060 in which the filling groove 8062 is not formed is configured.
Therefore, in the adhesive portion 90A, the dust-proof cover 31 is applied to the abutting surface 8060, and the adhesive B is interposed therebetween, so that the opening 8006 is airtightly closed in the adhesive portion 90A. .
Further, since the dustproof cover 31 is applied to the abutting surface 8060 in the non-adhesive portion 90B, the opening 8006 is closed in the non-adhesive portion 90B although it cannot be strictly speaking airtight.
Therefore, in the third reference example, the bonding portion 90A extends continuously around the opening 8006, and the non-bonding portion 90B is located between both ends of the bonding portion 90A in the extending direction. .
Further, the lens barrel 66 is made of synthetic resin, and as shown in FIG. 48, a weld line WL at the time of molding exists on the front surface 8070A of the rear end face wall 8002, and the weld line WL is formed by the non-adhesive portion 90B. It is located in an annular portion around the opening 8006 of the front surface 8070A of the intervening rear end face wall 8002.

According to the third reference example, the imaging device 29 is accommodated in the opening 8006 provided in the rear end face wall 8002 located at the rear end of the lens barrel 66, and the front part of the opening 8006 is covered with the dust-proof cover 31. By covering the rear portion of 8006 with the substrate 30 on which the imaging element 29 is mounted, the package can be omitted, and the lens barrel portion 66 can be reduced in size and thickness.
In this case, since the volume of the space formed inside the opening 8006 is larger than the volume of the housing recess of the conventional package, the air in the space expands as the temperature rises. Then, since the non-adhesive portion 90B having a configuration in which the dustproof cover 31 and the abutting surface 8060 are combined is provided, the intrusion of dust between the dustproof cover 31 and the abutting surface 8060 is prevented and the air flow is allowed. A small gap is formed, thereby preventing dust from entering the opening 8006 and at the same time allowing air to enter and exit through the non-adhesive portion 90B, so that there is no risk of deformation of the dust cover 31 and the imaging element. This is advantageous in securing the quality of the image picked up at 29.
In addition, since the weld line WL formed at the time of forming the lens barrel portion 66 is generally a fine concave groove, it is advantageous in securing the above-described entry and exit of the air by the weld line WL.
Further, compared to the case where the weld line WL is positioned at the position of the contact surface 8060 where the adhesive filling groove 8062 is formed, the weld line WL is applied to the contact surface where the adhesive filling groove 8062 is not formed. Since it is located at the location 8060A of 8060, it is advantageous in securing the thickness of the abutting surface 8060 around the opening 8006 and securing the strength of the abutting surface 8060.

Next, a fourth reference example in which the configuration of the third reference example is applied to a solid-state imaging device will be described.
51A is an exploded perspective view of the solid-state imaging device, and FIG. 51B is a plan view of the solid-state imaging device.
The solid-state image pickup device 92 includes a package 93, an image pickup device 29, and a dustproof cover 94.
An accommodation recess 95 is formed in the package 93.
The housing recess 95 is open to the flat upper surface 93 </ b> A of the package 93.
The image sensor 29 is accommodated in the accommodating recess 95.
The dustproof cover 94 is applied to the upper surface 93A, and the dustproof cover 94 is attached to the upper surface 93A by the adhesive B, and closes the opening 95A of the housing recess 95.
The adhesive portion 96A filled with the adhesive B and the adhesive B are filled between the annular portion around the opening 95A of the upper surface 93A and the outer peripheral portion of the dust-proof cover 94 located around the opening 95A. A non-adhesive portion 96B is interposed.

In the fourth reference example, an adhesive filling groove 97 filled with the adhesive B constituting the adhesive portion 96A is formed on the upper surface 93A.
The adhesive filling groove 97 extends continuously around the opening 95 </ b> A, and the upper surface portion where the adhesive filling groove 97 is not formed between both ends in the extending direction of the adhesive filling groove 97. 93B remains.
In the fourth reference example, the dust cover 94 is attached to the upper surface 93 </ b> A of the package 93 by the adhesive B filled in the adhesive filling groove 97.
Therefore, the adhesive portion 96A filled with the adhesive B and the adhesive B are filled between the annular portion of the upper surface 93A around the opening 95A and the outer peripheral portion of the dust cover 94 positioned around the opening 95A. An unbonded portion 96B that is not present is interposed. In other words, the adhesive portion 96A and the non-adhesive portion 96B are interposed between the upper surface 93A and the dust cover 94 around the opening 95A. The non-adhesive portion 96B includes an upper surface portion 93B in which the adhesive filling groove 97 is not formed. In the non-adhesive portion 96B, the dust cover 94 is applied to the upper surface 93A.
In the adhesive portion 96A, the dustproof cover 94 is applied to the upper surface 93A, and the adhesive B is interposed therebetween, so that the opening 95A is airtightly closed in the adhesive portion 96A.
Further, in the non-adhesive portion 96B, the dustproof cover 94 is applied to the upper surface 93A. Therefore, in the non-adhesive portion 96B, although not strictly airtight, the opening 95A is closed.
Therefore, in the fourth reference example, the bonding portion 96A extends continuously around the opening 95A, and the non-bonding portion 96B is located between both ends of the bonding portion 96A in the extending direction. .
As shown in FIG. 52, the adhesive filling groove 97 may be formed open on the side surface of the package 93 intersecting the upper surface 93A.

  According to the fourth reference example, even if the air in the space inside the housing recess 95 expands as the temperature rises, the non-adhesive portion 96B having the configuration in which the dustproof cover 94 and the upper surface 93A are combined is provided. A minute gap is formed between the dust cover 94 and the upper surface 93 </ b> A to prevent dust from entering and allow air to flow. Air enters and exits through the non-adhesive portion 96B, and there is no risk of deformation of the dust cover 31, which is advantageous in securing the quality of an image captured by the image sensor 29.

  In the present embodiment, the case where the electronic device 10 in which the imaging device 20 is incorporated is a mobile phone, but the imaging device of the present invention may be a portable information terminal such as a PDA or a notebook personal computer, or It can be widely applied to various electronic devices such as digital still cameras and video cameras.

(A), (B) is an external view which shows an example of the electronic device with which the imaging device 20 was integrated. 2 is an exploded perspective view of a camera module 22 and a socket 24 that constitute the imaging device 20. FIG. 3 is a plan view of a socket 24. FIG. 3 is a plan view of a substrate 30. FIG. 2 is an exploded perspective view of a camera module 22, a socket 24, and a cover 26. FIG. It is AA sectional view taken on the line of FIG. FIG. 6 is a sectional view taken along line BB in FIG. 5. It is the A section enlarged view of FIG. It is C arrow line view of FIG. It is sectional drawing of the imaging device 20 of a modification. It is a disassembled perspective view of the camera module 22 and the socket 24 which comprise the imaging device 20 of a modification. 2 is a perspective view of a camera module 22. FIG. 2 is a perspective view of a camera module 22. FIG. 2 is an exploded perspective view of a camera module 22. FIG. FIG. 3 is an assembly explanatory diagram of the camera module 22. It is AA sectional view taken on the line of FIG. 7 is a rear view in which a front spring 70A is attached to a front lens barrel 78. FIG. It is a perspective view of the lens barrel 80 after the coil 76 is attached. It is a perspective view of the lens barrel 80 after the coil 76 is attached. It is a perspective view of the lens barrel 80 after the coil 76 and the substrate 30 are attached. It is a perspective view of the lens barrel 80 after the coil 76 and the substrate 30 are attached. 3 is a plan view of a rear lens barrel 80. FIG. It is a top view of the lens barrel 80 after the substrate 30, the optical filter 31, and the coil 76 are attached. It is BB sectional drawing of FIG. It is a perspective view of the lens holding | maintenance part 68 to which the magnet 74 was attached. It is a perspective view of the lens holding | maintenance part 6868 with which the magnet 74 and the rear spring 70B were attached. It is a top view of the lens holding | maintenance part 6868 with which the magnet 74 and the rear spring 70B were attached. 7 is a rear view of the lens holding unit 68. FIG. It is a rear view of the lens holding part 68 to which the rear spring 70B is attached. It is sectional drawing of the camera module 22 which enabled it to prevent the inclination of the lens holding part 68. FIG. 3 is a plan view of a rear barrel 80 of the camera module 22. FIG. 7 is a rear view of the lens holding unit 68. FIG. FIG. 7 is an operation explanatory diagram of a magnet 74 and a coil 76. 2 is an exploded perspective view of a camera module 22. FIG. FIG. 3 is an assembly explanatory diagram of the camera module 22. 2 is a cross-sectional view of a camera module 22. FIG. 4 is a perspective view of a rear lens barrel 80. FIG. It is AA sectional view taken on the line of FIG. FIG. 6 is a perspective view showing a state in which a lens holding portion 68 is accommodated in a rear lens barrel 80. FIG. 6 is an operation explanatory diagram of a magnet 82 and a coil 84. FIG. 6 is an operation explanatory diagram of a magnet 82 and a coil 84. 4 is a perspective view showing a state in which a lens holding portion 68 of the camera module 22 is accommodated in a rear lens barrel 80. FIG. 2 is a cross-sectional view of a camera module 22. FIG. 3 is a cross-sectional view of a rear lens barrel 80. FIG. FIG. 6 is an operation explanatory diagram of a magnet 82 and a coil 84. It is explanatory drawing of ghost generation | occurrence | production. FIG. 4 is an assembly explanatory diagram of the dust cover 31, the lens barrel portion 66, the image sensor 29, and the substrate 30. It is a top view of the rear end surface wall 8002. FIG. FIG. 4 is an explanatory diagram of attachment of a dustproof cover 31. (A), (B) is sectional explanatory drawing which shows the attachment state of the dust-proof cover 31. FIG. (A) is an exploded perspective view of a solid-state imaging device, and (B) is a plan view of the solid-state imaging device. It is a disassembled perspective view of another solid-state imaging device.

Explanation of symbols

  22... Camera module, 29... Image sensor, 34 .. Imaging optical system, 66... Lens barrel section, 68. ... Coil, S ... Storage space.

Claims (18)

A lens barrel having a housing space;
A lens holding unit that holds the photographing optical system and is housed in the housing space;
A spring disposed in the housing space and movably supporting the lens holding portion along the optical axis of the photographing optical system;
An imaging device that is provided in the lens barrel and that captures a subject image guided by the imaging optical system;
A drive unit that moves the lens holding unit along the optical axis of the imaging optical system;
The drive unit is
A magnet provided in the lens holding portion;
A coil provided on the lens barrel and facing the magnet;
The coil has a frame shape centered on the optical axis as viewed from the optical axis direction with a conducting wire wound around the optical axis.
A camera module characterized by that. Two magnets are provided in the form of a plate,
The two magnets are arranged in parallel to a single virtual plane passing through the optical axis at the position of the lens holding part across the optical axis,
The coil has two coil portions extending parallel to the single virtual plane and facing the two magnets.
The camera module according to claim 1. Two magnets are provided in the form of a plate,
The two magnets are arranged in parallel to a single virtual plane passing through the optical axis at the position of the lens holding part across the optical axis,
The coil is wound around the outer periphery of the lens barrel,
The coil has two coil portions extending parallel to the single virtual plane and facing the two magnets,
Openings that allow the coil portions to face the magnet are formed at the positions of the lens barrel portions where the coil portions are located, respectively.
The camera module according to claim 1. Two magnets are provided,
The two magnets are formed in a rectangular plate shape having a height extending along the optical axis direction and a width extending along a direction perpendicular to the height with a dimension larger than the height,
The two magnets are arranged in parallel to a single virtual plane passing through the optical axis at the position of the lens holding part across the optical axis,
The coil has two coil portions extending parallel to the single virtual plane and facing the two magnets,
The coil portion has a height extending along the optical axis direction, a width larger than the height, a width extending along a direction perpendicular to the height, and a thickness smaller than the height and the width. Presenting a rectangular flat plate shape having
The camera module according to claim 1. The lens barrel portion has a front lens barrel and a rear lens barrel,
The front lens barrel includes a peripheral wall located around the optical axis,
The rear barrel extends on a plane orthogonal to the optical axis and closes the rear end surface wall of the peripheral wall in the optical axis direction, and projects from the rear end surface wall and is accommodated inside the peripheral wall. A cylindrical wall portion that divides a side surface of the accommodation space and on which the coil is wound, and an opening that is provided at a location of the rear end face wall located on the optical axis and accommodates the imaging element. Configured,
A coil mounting groove is provided on the outer periphery of the cylindrical wall portion,
The coil is mounted and disposed in the coil mounting groove.
The camera module according to claim 1. The lens barrel portion has a front lens barrel and a rear lens barrel,
The front lens barrel includes a peripheral wall located around the optical axis,
The rear barrel extends on a plane orthogonal to the optical axis and closes the rear end surface wall of the peripheral wall in the optical axis direction, and projects from the rear end surface wall and is accommodated inside the peripheral wall. A cylindrical wall portion that divides a side surface of the accommodation space and on which the coil is wound, and an opening that is provided at a location of the rear end face wall located on the optical axis and accommodates the imaging element. Configured,
Two magnets are provided in a plate shape,
The two magnets are arranged in parallel to a single virtual plane passing through the optical axis at the position of the lens holding part across the optical axis,
A coil mounting groove is provided on the outer periphery of the cylindrical wall portion,
The bottom surface of the coil mounting groove has two bottom surface portions facing each other in parallel to the single virtual plane,
The coil is mounted and disposed in the coil mounting groove,
An opening for allowing the coil to face the magnet is formed in the bottom surface portion of the coil mounting groove.
The camera module according to claim 1. The coil includes two coils, a first coil facing the front part of the magnet in the optical axis direction and a second coil facing the rear part of the magnet in the optical axis direction.
The camera module according to claim 1. The coil includes two coils, a first coil facing the front portion of the magnet in the optical axis direction and a second coil facing the rear portion of the magnet in the optical axis direction,
The first coil and the second coil have conductive wires wound in opposite directions,
The camera module according to claim 1. The coil includes two coils, a first coil facing the front portion of the magnet in the optical axis direction and a second coil facing the rear portion of the magnet in the optical axis direction,
The first coil and the second coil have conductive wires wound in the same direction,
The camera module according to claim 1. The coil includes two coils, a first coil facing the front portion of the magnet in the optical axis direction and a second coil facing the rear portion of the magnet in the optical axis direction,
Two magnets are provided in a plate shape,
The two magnets are arranged in parallel to a single virtual plane passing through the optical axis at the position of the lens holding part across the optical axis,
The first coil and the second coil respectively have two coil portions extending in parallel to the single virtual plane and facing the two magnets.
The camera module according to claim 1. Two magnets are provided in a plate shape,
The two magnets are arranged in parallel to a single virtual plane passing through the optical axis at the position of the lens holding part across the optical axis,
A first coil mounting groove and a second coil mounting groove are provided on the outer periphery of the lens barrel portion at intervals in the optical axis direction,
The bottom surface of the first coil mounting groove and the bottom surface of the second coil mounting groove each have two bottom surface portions facing each other in parallel to the single virtual plane,
The coil includes two coils, a first coil facing the front portion of the magnet in the optical axis direction and a second coil facing the rear portion of the magnet in the optical axis direction,
The first coil is mounted and disposed in the first coil mounting groove;
The second coil is mounted and disposed in the second coil mounting groove;
Openings are formed in the bottom surface portion of the first coil mounting groove and the bottom surface portion of the second coil mounting groove so that the first coil and the second coil face the magnet, respectively.
The camera module according to claim 1. Two magnets are provided,
The two magnets are formed in a rectangular plate shape having a height extending along the optical axis direction and a width extending along a direction perpendicular to the height with a dimension larger than the height,
The two magnets are arranged in parallel to a single virtual plane passing through the optical axis at the position of the lens holding part across the optical axis,
The coil includes two coils, a first coil facing the front portion of the magnet in the optical axis direction and a second coil facing the rear portion of the magnet in the optical axis direction,
The first coil and the second coil respectively have two coil portions extending in parallel to the single virtual plane and facing the two magnets.
Each of the coil portions has a height extending along the optical axis direction, a width larger than the height, a width extending along a direction perpendicular to the height, and a thickness smaller than the height and the width. Presents a rectangular flat plate having a thickness,
The camera module according to claim 1. The lens barrel portion has a front lens barrel and a rear lens barrel,
The front lens barrel includes a peripheral wall located around the optical axis,
The rear barrel extends on a plane orthogonal to the optical axis and closes the rear end surface wall of the peripheral wall in the optical axis direction, and projects from the rear end surface wall and is accommodated inside the peripheral wall. A cylindrical wall portion that divides a side surface of the accommodation space and on which the coil is wound, and an opening that is provided at a location of the rear end face wall located on the optical axis and accommodates the imaging element. Configured,
The coil includes two coils, a first coil facing the front portion of the magnet in the optical axis direction and a second coil facing the rear portion of the magnet in the optical axis direction,
A first coil mounting groove and a second coil mounting groove are provided on the outer periphery of the cylindrical wall portion at an interval in the optical axis direction,
The first coil is mounted and disposed in the first coil mounting groove;
The second coil is mounted and disposed in the second coil mounting groove.
The camera module according to claim 1. The lens barrel portion has a front lens barrel and a rear lens barrel,
The front lens barrel includes a peripheral wall located around the optical axis,
The rear barrel extends on a plane orthogonal to the optical axis and closes the rear end surface wall of the peripheral wall in the optical axis direction, and projects from the rear end surface wall and is accommodated inside the peripheral wall. A cylindrical wall portion that divides a side surface of the accommodation space and on which the coil is wound, and an opening that is provided at a location of the rear end face wall located on the optical axis and accommodates the imaging element. Configured,
Two magnets are provided in a plate shape,
The two magnets are arranged in parallel to a single virtual plane passing through the optical axis at the position of the lens holding part across the optical axis,
A first coil mounting groove and a second coil mounting groove are provided on the outer periphery of the cylindrical wall portion at an interval in the optical axis direction,
The bottom surface of the first coil mounting groove and the bottom surface of the second coil mounting groove each have two bottom surface portions facing each other in parallel to the single virtual plane,
The coil includes two coils, a first coil facing the front portion of the magnet in the optical axis direction and a second coil facing the rear portion of the magnet in the optical axis direction,
The first coil is mounted and disposed in the first coil mounting groove;
The second coil is mounted and disposed in the second coil mounting groove;
Openings are formed in the bottom surface portion of the first coil mounting groove and the bottom surface portion of the second coil mounting groove so that the first coil and the second coil face the magnet, respectively.
The camera module according to claim 1. Two springs are provided, and these springs are respectively disposed between both ends of the lens holding portion in the optical axis direction and the lens barrel portion.
The camera module according to claim 1. Two springs are provided, and these springs are respectively disposed between both ends of the lens holding portion in the optical axis direction and the lens barrel portion.
The two springs are formed in an annular shape so that an opening for the optical path of the photographing optical system is secured in the center from a thin, small-width piece.
Each of the two springs has an inner peripheral portion attached to the lens holding portion, and an outer peripheral portion attached to the lens barrel portion.
The camera module according to claim 1. The lens holding portion has an inner surface on which the photographing optical system is disposed, and an outer surface positioned opposite to the inner surface,
At two locations on the outer surface of the lens holding portion facing each other, a mounting surface parallel to a single virtual plane passing through the optical axis is formed,
A pair of sandwiching pieces for sandwiching the magnet project from the mounting surface,
The magnet has a plate shape, is disposed on each attachment surface, and is bonded to the attachment surface in a state of being sandwiched between the pair of sandwiching pieces,
The camera module according to claim 1. The pair of clamping pieces are provided at a front end of the mounting surface in the optical axis direction,
The camera module according to claim 17.

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