JP4787719B2 - Imaging device - Google Patents

Description

  The present invention relates to an imaging device 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 camera body in which an imaging optical system is incorporated, an imaging element that captures a subject image guided by the imaging optical system, and a signal that performs predetermined signal processing by inputting an imaging signal output from the imaging element. A processing unit and a substrate attached to the camera body are included (see Patent Document 1).
JP-A-2005-86341

Incidentally, it is necessary to perform electromagnetic shielding of the camera module in order to prevent mutual electromagnetic interference between the camera module incorporated in the electronic device and the electronic component constituting the electronic device adjacent to the camera module. Become.
In particular, in recent years, since such a camera module is incorporated into a small electronic device that is carried and used, such as a mobile phone, the distance between the camera module and an adjacent electronic component tends to be shortened. Effective electromagnetic shielding of modules is required.
The present invention has been made in view of such circumstances, and an object of the present invention is to provide an imaging apparatus that is advantageous in reliably performing electromagnetic shielding of a camera module.

In order to achieve the above-described object, an imaging apparatus according to the present invention is guided by the camera body having a rectangular plate shape and incorporating a photographing optical system facing one surface in the thickness direction, and the photographing optical system. An image pickup device for picking up a subject image, a signal processing unit for inputting an image pickup signal output from the image pickup device and performing predetermined signal processing, and a substrate attached to the other surface in the thickness direction of the camera body A camera module including a plurality of contact pieces formed on a surface facing the camera body opposite to the camera body and connected to the signal processing unit; and a socket in which the camera module is mounted. The socket is formed of an insulating and elastic material, and has a rectangular bottom wall that is large enough to accommodate the camera module therein, and rises from four sides of the bottom wall 4. One A socket body having a side wall; and a plurality of connection terminals provided on the bottom wall and connectable to the plurality of contact pieces, wherein the four side walls are located on opposite sides of the inner surface facing each other. A plurality of socket shielding plates which are formed of a material having an outer surface and are electromagnetically shielded and elastic and are attached to the respective side walls to cover the outer surfaces of the four side walls; both ends of the extending direction is all around the entire electromagnetic shielding side of said socket body are superimposed at the corner adjacent side wall intersects the socket body are electrically connected by a plurality of socket shielding plates In addition, the end portions of the adjacent socket shielding plates are biased in the direction in which they are in contact with each other due to the elasticity of the socket shielding plates .

  Therefore, according to the present invention, the end portions of the adjacent socket shielding plates are overlapped and biased in the direction of contact with each other by the elasticity of the socket shielding plates. The entire outer surface is covered with a plurality of socket shielding plates, and even when subjected to shock or vibration, the plurality of socket shielding plates are electrically connected to each other, so the camera mounted on the socket This is advantageous in ensuring the electromagnetic shielding of the module.

Next, a first embodiment of the present invention will be described with reference to the drawings.
1A and 1B are external views illustrating an example of an electronic apparatus in which the imaging device 20 according to the present embodiment 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 line AA in FIG. 5, FIG. 7 is a sectional view taken along 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 camera body 28, an image sensor 29, a signal processing unit (not shown), a substrate 30, and a contact piece 32 (see FIG. 4). .
The camera body 28 has a rectangular plate shape (rectangular plate shape), and 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 2 positioned along two long sides. One long side surface 2806 and two short side surfaces 2808 positioned along two short sides are provided.
The camera body 28 incorporates a photographic optical system 34 that guides the subject image to the image sensor 29 (see FIG. 7). The photographic optical system 34 is disposed so as to face the upper surface 2802 of the camera body 28.
In this embodiment, the camera body 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 present embodiment, the camera body 28 is configured to include the camera body shielding plate 2810.
The camera body shielding plate 2810 is formed of a single plate made of a material having electromagnetic shielding properties. The camera body shielding plate 2810 has an upper surface portion 2810A covering the upper surface 2802 and a side surface covering the two long side surfaces 2806. Part 2810B.
As a material having electromagnetic shielding properties constituting the shielding plate 2810 for the camera body, a material obtained by plating a copper alloy such as phosphor bronze, white, tin, copper or phosphor bronze with nickel or the like, or stainless steel A material having conductivity and non-magnetism such as steel (for example, 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.

The image sensor 29 captures a subject image guided by the photographic optical system 34 and is incorporated in the camera main body 28 at a location behind the photographic 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 camera body 28 and has a rectangular shape (rectangular shape).
On the upper surface 3002 where the substrate 30 faces the camera body 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 camera body 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 68 (see FIG. 7).
The socket body 36 is formed of an insulating material, and in this embodiment, the socket body 36 is formed of an insulating synthetic resin.
The socket body 36 includes a rectangular (rectangular plate-like) bottom wall 3602 having a contour larger than that of the substrate 30 of the camera module 22, and four side walls 3604 erected from four sides of the bottom wall 3602. The camera module 22 is sized to be accommodated inside the four side walls 3604 above.
In this embodiment, the four side walls 3604 include 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 consists of and.
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 the present embodiment, 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 the present embodiment, the socket shielding plate 38 includes two long-side shielding plates 46 that are respectively assembled to the two long-side side walls 3606 and two short-side sides that are respectively assembled to the two short-side side walls 3608. And a shielding plate 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 main body 36, whereby the four side surfaces (long side side surface 2806, short side) of the camera main body 28 are covered. The side surface 2808) is covered and the four side surfaces of the camera body 28 are electromagnetically shielded. As the material having electromagnetic shielding properties and elasticity for forming the shielding plate 38 for socket, a material obtained by performing a plating process such as nickel on a copper alloy such as phosphor bronze, white, tin, copper, or phosphor bronze, 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. The bent portion 4002 is in contact with the long side surface 2806 and the short side surface 2808 of the camera body 28, so that a gap S 1 is secured between the side surfaces 2806 and 2808 and the inner surfaces of the side walls 3606 and 3608. The module 22 is elastically supported.
More specifically, the camera main body shielding plate 2810 is attached to the camera main body 28, and the side surface portion 2810B of the camera main body shielding plate 2810 is located on the long side surface 2806 of the camera main body 28. In the embodiment, the bent portion 4002 does not directly contact the long-side side surface 2806 of the camera body 28 but contacts the side surface portion 2810B of the camera body shielding plate 2810. In other words, the bent portion 4002 does not contact the camera body shielding plate 2810. It is indirectly in contact with the long side surface 2806 of the camera body 28 via the side surface 2810B. Therefore, in the present embodiment, the elastic body 40 of the long side shielding plate 46 abuts on the side surface portion 2810B of the camera body shielding plate 2810 so that the camera body shielding plate 2810 is interposed via the long side shielding plate 46. It will be grounded.
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 housed inside the four side walls 3604 on the bottom wall 3602, the engaging portion 68 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 68 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 camera body 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 68 is provided on the socket body 36. In the present embodiment, the engaging portion 68 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 When the 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 camera body 28, thereby separating from the bottom wall 3602 of the socket 24 of the camera module 22. Movement in the direction is prevented.

Further, as shown in FIGS. 5 and 7, a stopper 62 that prevents the cover 26 from being displaced in the direction of the upper surface 2802 of the camera body 28 by contacting the portion of the cover 26 on the short side wall 3608 of the socket body 36. Is provided.
In the present embodiment, the stopper 62 is composed of 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.
Further, in the present embodiment, as shown in FIG. 5, the long side wall 3606 of the socket body 36 is detachably engaged with the cover 26 and the cover 26 with respect to the socket 24 in the thickness direction of the camera body 28. A positioning engagement portion 64 is provided for performing positioning.
Further, in the present embodiment, the positioning engaging portion 64 has two engagements 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. A recess 6402 is formed.

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 having conductivity and not 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 camera body 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 engaged with the engagement convex portion 4802 of the shielding plate 38, so that the displacement of the cover 26 in the direction of the upper surface 2802 of the camera body 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 camera body 28 by engaging with the mating recess 6402.
In this way, the engaging recess 6402 that engages the side surface portion 52 of the cover 26 and the side wall 38 of the socket body 36 so as to be detachable and positions the cover 26 with respect to the socket 24 in the thickness direction of the camera body 28. Providing the engagement convex portion 5402 is advantageous in preventing the cover 26 from falling off the socket 24, improving workability when handling the imaging device 20 alone, or providing the imaging device 10 with the electronic device 10. This is advantageous in improving the workability during installation.
In the present embodiment, the engagement convex portion 5402 and the engagement concave portion 6402 engage with each other in a state where the cover 26 is attached to the socket 24 to which the camera module 22 is attached. The lower edge of 56 is locked to the locking 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 board 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.

With the above configuration, the following effects are achieved.
Since the lens cover 58 is provided on the cover 26 of the imaging device 20, there is no need to attach the lens cover to the electronic device 10, and it is of course advantageous for simplifying the assembly work of the electronic device 10. Since the cover 26 is locked to the socket 24 via the stopper 62, even if an external force in the direction toward the upper surface 2802 of the camera body 28 is directly applied to the lens cover 58, the external force is applied to the cover 26 and the stopper 62. It acts on the socket 24 via the, and does not act on the camera module 22, which is advantageous in reducing the influence of external force on the imaging device 20.
Therefore, an external force is applied to the image sensor 29 and the substrate via the camera body 28 of the camera module 22, and the image captured by the image sensor 29 is deformed, or mechanically applied to an electronic component mounted on the substrate. This is advantageous in effectively preventing the application of excessive stress.
In addition, since the camera module 22 is elastically supported by the elastic piece 40 and the connection terminal 42, the electronic device 10 hits an object, or the electronic device 10 falls on the floor, so that a large impact or vibration occurs. Even if it acts on the imaging device 20 incorporated in the electronic device 10, the impact and vibration are alleviated by the elastic piece 40 and the connection terminal 42 and transmitted to the camera module 22, so that the durability of the imaging device 20 against the impact and vibration is improved. This is advantageous for improvement.

Further, in the present embodiment, the camera body shielding plate 2810 of the camera module 22, the long side surface portion 54 and the short side surface portion 56 of the cover 26, the long side shielding plate 46 and the short side of the socket 24. The side shielding plate 48 is overlapped with each other to be electrically connected to each other, and the camera body shielding plate 2810 and the cover 26 are grounded via the socket shielding plate 38 of the socket 24.
Therefore, the camera module 22 is electromagnetically shielded by the camera body shielding plate 2810, the socket shielding plate 38, and the cover 26 that are superposed on each other. And the electronic circuit of the electronic device 10 arranged in the vicinity of the imaging device 20 can be reliably performed, and the imaging element 29 and the signal processing unit inside the camera body 28 and the electronic circuit Both electromagnetic radiations can be effectively suppressed. For this reason, the imaging device 20 and the electronic circuit can be arranged close to each other while preventing adverse effects due to electromagnetic radiation, which is advantageous in reducing the size, thickness, and size of electronic devices.
In particular, since the signal processing unit connected to the rear stage of the image sensor 29 provided in the camera module 22 uses a high frequency clock, there is a concern about the radiation of the high frequency clock noise. The overlapping camera body shielding plate 2810, socket shielding plate 38, and cover 26 can be effectively suppressed.
In addition, an actuator for moving a part of a lens constituting the photographing optical system 34 in the optical axis direction for focusing operation or zooming operation is incorporated in the camera module 22, and the actuator radiates electromagnetic waves. Even so, the radiation of the electromagnetic waves can be effectively suppressed by using the camera body shielding plate 2810, the socket shielding plate 38, and the cover 26 that overlap each other.
When electronic parts such as speakers, antennas, and liquid crystal display panel 1402 are mounted at a high density in a limited space, such as a mobile phone, the electronic equipment 10 and the camera module 22 There is concern about mutual electromagnetic interference (EMI: Electro Magnetic Interference), but by providing the camera body shielding plate 2810, the socket shielding plate 38, and the cover 26 as in the present embodiment, electromagnetic interference is provided. This is particularly advantageous when the imaging device 20 is incorporated into an electronic device in which electronic components are mounted at a high density, such as a mobile phone.
In the present embodiment, as shown in FIG. 7, the dust-proof member 60 of the cover 26 is connected to the upper surface portion 50 of the cover 26 and the upper surface 2802 of the camera body 28 with the cover 26 mounted in the socket 24. By closing the gap between the front portion of the photographic optical system 34 and the lens cover 58, the front portion of the photographic optical system 34 is sealed from the gap between the cover 26 and the camera body 28. On the other hand, it is possible to reliably prevent dust and dirt from entering.

Next, a second embodiment will be described.
In the second embodiment, the configuration of the stopper 62 is different from that of the first embodiment, and other configurations are the same as those of the first embodiment.
FIG. 10 is a cross-sectional view of the imaging apparatus 20 according to the second embodiment. In the following embodiment, the same parts and members as those in the first embodiment will be described with the same reference numerals.
In the first embodiment, the stopper 62 is configured by the two engaging projections 4802 that are formed on the outer surface of each short side shielding plate 48 so as to protrude in the extending direction. This embodiment is different from the first embodiment in that it is configured by the bent portion 4001 at the upper end of each short-side shielding plate 48, and the other configurations are the same as those in the first embodiment.
In the second embodiment, as shown in FIG. 10, an engaging portion 5610 that engages with the bent portion 4001 is formed on the short side surface portion 56 of the cover 26, and the bent portion 4001 and the engaging portion 5610 are provided. By locking, the displacement of the cover 26 in the direction of the upper surface 2802 of the camera body 28 is prevented.
It goes without saying that the same effect as described above is also achieved in the second embodiment.

In the above-described configuration, the stopper 62 is constituted by the two engaging projections 4802 formed to protrude from the outer surface of each short side shielding plate 48, and the stopper 62 is formed at the upper end of each short side shielding plate 48. However, the stopper 62 may be configured by the upper end of the side wall 38 of the socket main body 36.
Moreover, although the case where the four shielding plates 38 for sockets were provided was demonstrated, the number of the shielding plates 38 for sockets is arbitrary, therefore, it may be one, may be two, or There may be three.

Next, the elastic piece 40 and the elastic deformation notches 3620 and 3630 will be described in detail.
As shown in FIG. 2, in the imaging device 20, as described above, the four contact surfaces 32 of the camera body 28 are elastically contacted with the four side surfaces (the long side surface 2806 and the short side surface 2808). Elastic pieces 40 that secure a gap S1 between the four side walls 3604 while being connected to the terminal 42 and elastically support the camera module 22 on the bottom wall 3602 inside the four side walls 3604 are provided on the side walls 3604, respectively. Is provided.
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.
In the present embodiment, the elastic deformation notches 3620 and 3630 are formed through the side wall 3604 in the thickness direction.

In the present embodiment, as shown in FIG. 2, two elastic pieces 40 are provided so as to be elastically contacted at two locations spaced in the extending direction of the side walls 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 located opposite to the inner surface, and the socket shielding plate 38 is attached to each side wall 3604 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 through the second bent portion 3801 at a position at the upper end of the main body plate portion 3820 away from the bottom wall 3602 from a portion away from the first bent portion 4001. 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. The main body plate portion 3820 enhances 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.

With the above configuration, the following effects are achieved.
Since the camera module 22 is elastically supported on the bottom wall 3602 with a clearance S1 secured between the camera module 22 and the side wall 3604 by the elastic piece 40, the camera module 22 from the side to the electronic device 10 or from the side to the imaging device 20 Even if a large impact or vibration is applied, the impact or vibration is alleviated by the elastic piece 40.
The elastic piece 40 can be elastically deformed in the thickness direction of the side wall 3604, and elastic deformation notches 3620 and 3630 for the elastic piece 40 to elastically deform are formed on the side wall 3604. A large elastic stroke of the elastic piece 40 can be ensured without increasing the size.
Therefore, it is advantageous to surely elastically support the camera module 22 by the elastic piece 40 while reducing the size of the imaging device 20, and advantageous to improving the durability of the camera module 22 and the imaging device 20 against impact and vibration. It becomes.

Further, since the elastic deformation notches 3620 and 3630 are formed so as to penetrate in the thickness direction of the side wall 3604, it is advantageous to ensure a large elastic stroke of the elastic piece 40 without increasing the size of the imaging device 20. This is advantageous for securely supporting the camera module 22 by the elastic piece 40 while reducing the size of the imaging device 20, and is advantageous for improving the durability of the camera module 22 and the imaging device 20 against impact and vibration. Become.
Further, since the elastic deformation notches 3620 and 3630 are formed in an open shape at the upper end of the side wall 3604 separated from the side wall 3604, the socket main body 36 is easily and inexpensively manufactured when the socket main body 36 is molded. Therefore, it is advantageous in reducing the cost of the camera module 22 and the imaging device 20.

Further, since the elastic piece 40 is formed integrally with the socket shielding plate 38 using the socket shielding plate 38, the camera module 22 is compared with the case where the elastic piece 40 is provided separately from the socket shielding plate 38. In addition, it is advantageous in reducing the number of parts of the imaging device 20 and reducing the cost.
Further, by using the socket shielding plate 38, the elastic piece 40 is integrally formed with the socket shielding plate 38, the attachment piece 38A is integrally formed with the socket shielding plate 38, and the attachment piece 38A is formed as the attachment groove 36A. The socket shielding plate 38 is attached to the side wall 3604 by being inserted into the side wall 3604. Therefore, the elastic piece 40 and the socket shielding plate 38 can be easily assembled, and the cost of the camera module 22 and the imaging device 20 can be reduced. It will be advantageous.
In the present embodiment, as shown in FIGS. 6 and 7, the elastic piece 40 functions as a member that elastically supports the camera module 22 at the position where the elastic piece 40 is located, and the camera module 22 is electromagnetically operated. Since it functions also as a member to be shielded, electromagnetic shielding is performed twice by the elastic piece 40 and the main body plate portion 3820 at the location where the elastic piece 40 is located. Therefore, it is advantageous in electromagnetically shielding the camera module 22. It has become.

Next, the main part of the present invention 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.
In the embodiment shown in FIGS. 2 to 9, four socket shielding plates 38 are provided corresponding to the four side walls 3604, and the end portions 3810 and 3811 of each adjacent socket shielding plate 38 have four pieces. The corner portions 3650 are overlaid on each other and are biased in the direction of contacting each other by the elasticity of the socket shielding plates 38.
In the embodiment shown in FIG. 11, two socket shielding plates 38 are provided so as to cover two adjacent side walls 3604 of four side walls 3604, and the end of each adjacent socket shielding plate 38 is provided. The portions 3810 and 3811 are overlapped at the two corner portions 3650, respectively, and are biased in a direction in which they contact each other due to the elasticity of the socket shielding plates 38.

In the present embodiment, 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 to 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 direction of the inner surface 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 3810 and the second contact plate 3811 are overlapped with each other and are in contact with each other over the entire length in the height direction. .

According to the present embodiment, the first abutting plate portion 3810 and the second abutting plate portion 3811 of each adjacent socket shielding plate 38 are overlapped and brought into contact with each other by the elasticity of each of the socket shielding plates 38. Therefore, the entire outer periphery of the four side walls 3604 of the socket body 36 is covered with a plurality of socket shielding plates 38, and even when subjected to an impact or vibration, the plurality of sockets Since the shielding plates 38 are electrically and reliably connected to each other, it is advantageous in reliably performing electromagnetic shielding of the camera module 22 attached to the socket 24.
In the present embodiment, the first abutting plate portion 3810 and the second abutting plate portion 3811 are overlapped with each other at the corner portion 3650 where the adjacent side walls 3604 of the socket main body 36 intersect with each other. It is advantageous to ensure a large contact pressure generated between the first contact plate portion 3810 and the second contact plate portion 3811 due to the elasticity of the first contact plate portion 3810 and the electrical connection between the adjacent socket shielding plates 38. Is more advantageous.
Further, in the present embodiment, the first contact plate portion 3810 and the second contact plate portion 3811 are brought into contact with each other over the entire length in the height direction and biased in the contact direction. Also when it is received, it is advantageous to securely connect the plurality of socket shielding plates 38, and it is advantageous to surely shield the camera module 22 electromagnetically. In particular, in the present embodiment, the first abutting plate portion 3810 and the second abutting plate portion 3811 are formed with the same large dimension as the side wall 3604, and are in contact with each other over the entire length in the height direction. Since it is urged in the direction, it is advantageous in reliably performing electromagnetic shielding of the camera module 22 even when subjected to an impact or vibration.

In the present embodiment, the first contact plate portion 3810 and the second contact plate portion 3811 are overlapped in the recess 3660, so the first contact plate portion 3810 and the second contact plate portion 3811 are overlapped. Such a problem that the portion where the two are overlapped greatly bulges outside the socket 24 can be prevented, which is advantageous in making the imaging device 20 compact.
In the present embodiment, as shown in FIG. 9, the main body plate 3820 is displaced in the direction of the inner surface of the side wall 3604 by the thickness of the socket shielding plate 38 and connected to the end of the main body plate portion 3820 via a bent portion 3815. Since the first contact plate portion 3810 is overlapped with the second contact plate portion 3811 extending in parallel with the portion 3820 and this overlap is performed in the recess 3660, the first contact plate portion 3810 and the first contact plate portion 3810 are overlapped. The main body plate portion 3820 on which the abutting plate portion 3810 is overlapped extends on the same plane, and when viewed from above, the four socket shielding plates 38 form a rectangular outline without protrusions. This is advantageous in reducing the size of the imaging device 20.
Further, in the present embodiment, when the mounting piece 38A of the socket shielding plate 38 is inserted into the mounting groove 36A of the socket body 36 and the socket shielding plate 38 is attached to the side wall 3604, the displacement of the socket shielding plate 38 is displaced. Since the first contact plate portion 3810 and the second contact plate portion 3811 slide while being in pressure contact with each other, the first contact plate portion 3810 and the second contact plate portion 3811 can be easily stacked. This is advantageous for easy assembly and cost reduction.

  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 which concerns on this Embodiment 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 2nd Embodiment. It is a disassembled perspective view of the camera module 22 and the socket 24 which comprise the imaging device 20 of other embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Electronic device, 20 ... Imaging device, 22 ... Camera module, 24 ... Socket, 26 ... Cover, 28 ... Camera body, 29 ... Imaging element, 30 ... Substrate, 32 ... Contact 34 …… Shooting optical system, 36 …… Socket body, 3602 …… Bottom wall, 3604 …… Side wall, 3620, 3630 …… Elastic deformation notch, 3650 …… Square, 38 …… Socket shielding plate, 3810, 3811 ... end, 40 ... elastic piece, 42 ... connection terminal, 50 ... upper surface, 5002 ... opening, 58 ... lens cover, 54 ... side, 62 ... stopper, 68 ... ... engagement part.

Claims (9)

A camera body having a rectangular plate shape and incorporating a photographing optical system facing one surface in the thickness direction, an image sensor that captures a subject image guided by the photographing optical system, and an output from the image sensor A signal processing unit that inputs an imaging signal to perform predetermined signal processing, a substrate attached to the other surface in the thickness direction of the camera body, and a surface on which the substrate faces the opposite side of the camera body A camera module including a plurality of contact pieces formed and connected to the signal processing unit;
A socket in which the camera module is mounted;
An imaging device comprising:
The socket has a rectangular bottom wall that is formed of an insulating and elastic material and accommodates the camera module therein, and has four side walls that stand from four sides of the bottom wall. And a plurality of connection terminals provided on the bottom wall and connectable to the plurality of contact pieces,
Each of the four side walls has an inner surface facing each other and an outer surface located opposite to the inner surface;
A plurality of socket shielding plates that are formed of a material having electromagnetic shielding properties and elasticity and are attached to the respective side walls to cover the outer surfaces of the four side walls;
Both ends of the extending direction of each socket shielding plate adjacent the side surface of the socket body the are superimposed at the corner adjacent side wall intersects the socket body are electrically connected by a plurality of socket shielding plates The entire circumference of the socket is electromagnetically shielded, and due to the elasticity of each of the socket shielding plates, the ends of the adjacent socket shielding plates are biased in a direction in which they are in contact with each other.
An imaging apparatus characterized by that. The corner is provided with a recess,
The adjacent end portions of the socket shielding plates are overlapped in the recesses and are biased in a direction in contact with each other.
The imaging apparatus according to claim 1. The end of each adjacent socket shielding plate has the same height as the side wall,
The adjacent end portions of the socket shielding plates are overlapped over the entire length in the height direction and biased in a direction in contact with each other.
The imaging apparatus according to claim 1. The end of each adjacent socket shielding plate has the same height as the side wall,
The corner is provided with a recess extending over the entire length in the height direction of the side wall,
The end portions of the adjacent shielding plates for sockets are overlapped over the entire length in the height direction in the concave portion and are biased in a direction in contact with each other.
The imaging apparatus according to claim 1. Four socket shielding plates are provided corresponding to the four side walls,
The end portions of the adjacent shielding plates for sockets are overlapped at the four corners, respectively, and are urged in the direction in which they come into contact with each other due to the elasticity of the shielding plates for the sockets.
The imaging apparatus according to claim 1. Two of the socket shielding plates are provided so as to cover two adjacent side walls of the four side walls,
The end portions of the adjacent shielding plates for sockets are overlapped at the two corners, respectively, and are urged in the direction in which they come into contact with each other by the elasticity of the shielding plates for the sockets.
The imaging apparatus according to claim 1. One of the two adjacent shielding plates for socket is a shielding plate for the socket that is arranged in parallel to the side wall and covers the side wall, and is bent at a right angle from the end of the main body plate portion. 1 contact plate part,
Of the two adjacent socket shielding plates, the other socket shielding plate is connected in parallel to the side wall and covers the side wall, and is connected to the end of the main body plate portion via a bent portion. And a second abutting plate portion that is displaced in the direction of the inner surface of the side wall by the thickness of the socket shielding plate and extends in parallel with the main body plate portion,
The adjacent shielding plates for sockets are biased in a direction in which the first contact plate portion and the second contact plate portion are overlapped and contact each other.
The imaging apparatus according to claim 1. One of the two adjacent shielding plates for socket is a shielding plate for the socket that is arranged in parallel to the side wall and covers the side wall, and is bent at a right angle from the end of the main body plate portion. 1 contact plate part,
Of the two adjacent socket shielding plates, the other socket shielding plate is connected in parallel to the side wall and covers the side wall, and is connected to the end of the main body plate portion via a bent portion. And a second abutting plate portion that is displaced in the direction of the inner surface of the side wall by the thickness of the socket shielding plate and extends in parallel with the main body plate portion,
Each of the adjacent shielding plates for socket is biased in a direction in which the first contact plate portion and the second contact plate portion are overlapped and contact each other,
A mounting piece is integrally formed on the main body plate portion,
The mounting piece extends in the direction of the bottom wall at a location away from the main body plate portion toward the inner surface of the side wall via a bent portion from the location of the upper end of the main body plate portion away from the bottom wall,
The socket shielding plate is attached to the side wall by inserting the mounting piece into a mounting groove that opens at the upper end of the side wall and extends along the height direction of the side wall. It is made by sandwiching a portion of the side wall constituting the mounting piece groove with the plate portion,
The imaging apparatus according to claim 1. The corner is provided with a recess extending over the entire length in the height direction of the side wall,
One of the two socket shielding plates adjacent to the socket includes a main body plate portion that is arranged in parallel to the side wall and covers the side wall, and is bent at a right angle from an end of the main body plate portion. A first abutment plate portion having the same height as
Of the two adjacent socket shielding plates, the other socket shielding plate is connected in parallel to the side wall and covers the side wall, and is connected to the end of the main body plate portion via a bent portion. And a second abutting plate portion that is displaced in the inner surface direction of the side wall by the thickness of the socket shielding plate and extends in parallel with the main body plate portion at the same height as the side wall,
Each of the adjacent shielding plates for socket is biased in a direction in which the first contact plate portion and the second contact plate portion are overlapped over the entire length in the height direction and in contact with each other. ,
The imaging apparatus according to claim 1.

Images