JP2009086465A - Camera module - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a camera module of high performance by preventing shift of an optical axis due to heating processing for manufacture of the camera module. <P>SOLUTION: The camera module 1 comprises: a lens unit 2 including lenses 4, 6 and a cylindrical barrel 2a; a sensor 16 for converting light formed as an image through the lenses 4, 6 into an electric signal; and a seat mount 3 for storing the sensor 16 and mounting the lens unit 2. The seat mount 3 includes a barrel storage part 3c which stores the cylindrical barrel 2a of the lens unit 2 and has a polygonal, at least square inside cross-sectional shape, and an adhering fixing part with which a gap between the barrel 2a stored in the barrel storage part 3c and the inner side face of the barrel storage part 3c is filled and which sticks the barrel 2a to the barrel storage part 3c. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a camera module and the like, and more particularly to a camera module and the like mounted on, for example, a mobile phone.

In recent years, camera modules that form a subject image on an image sensor using a microlens are widely used in camera systems mounted on various devices such as mobile phones. In such a camera module, an optical element such as a lens is usually fixed to a fixing member such as a lens barrel using an adhesive.
For example, Patent Document 1 describes that at least one of an adhesive surface of an optical element and an adhesive surface of a fixing member is roughened when a lens is fixed to a lens barrel or the like using an adhesive.
Further, in Patent Document 2, in order to ensure the coaxiality at the initial time and to prevent the influence of the expansion and contraction of the lens and the lens barrel due to changes in temperature and humidity on the lens surface, A rim structure is formed, and the inner periphery of the rim structure and the lens barrel are fitted to regulate the coaxiality of the lens and the lens barrel at the initial time, and between the outer periphery of the rim structure and the lens barrel. Describes provision of fitting backlash to absorb dimensional changes during environmental changes.

JP 2006-178388 A JP 2000-187144 A

FIG. 8 is a diagram for explaining a conventional camera module 10. As shown in FIG. 8, the conventional camera module 10, a lens unit 20 housing the lens, and a configured base mount 30 from the cylindrical portion 3a ₀ and rectangular portion 3b ₀ Prefecture. The lens unit 20 having a circular cross section is attached to the pedestal mount 30 by fitting with the cylindrical portion 3 a ₀ of the pedestal mount 30.
In the manufacturing process of the camera module 10, heat treatment in a reflow furnace is usually performed with the lens unit 20 attached to the pedestal mount 30. At this time, since the lens unit 20 and the pedestal mount 30 are formed of materials having different thermal expansion coefficients, the lens unit 20 and the cylindrical portion 3a ₀ are caused by expansion during heat treatment and contraction during cooling. There may be a gap (clearance) between the two.

FIG. 9 is a plan view for explaining a fitting state between the conventional lens unit 20 and the pedestal mount 30. As shown in FIG. 9 (a), the lens unit 20, by the size of approximating the inner diameter of the cylindrical portion 3a ₀ of the outer diameter and the base mount 30 of the circular lens unit 20, without generation of a gap Attached to the pedestal mount 30. When heat treatment in a reflow furnace is performed in this state, as shown in FIG. 9 (b), the outer diameter is increased by the expansion of the lens unit 20, to deform the cylindrical portion 3a _0.
Subsequent cooling process, the lens unit 20 is contracted to the original outer diameter, cylindrical portion 3a ₀ of the deformed inner diameter be contracted not irreversible. For this reason, as shown in FIG. 9C, a clearance C ₀ is generated between the lens unit 20 and the cylindrical portion 3 a ₀ of the pedestal mount 30. When such clearance C ₀ occurs, displacement of the optical axis occurs, the performance of the camera module 10 (see FIG. 8) there is a problem that one of the causes to deteriorate.

  The present invention has been made to solve the technical problems described above. That is, an object of the present invention is to provide a high-performance camera module that prevents optical axis deviation due to heat treatment during manufacturing.

  Thus, according to the present invention, a lens unit having a lens and a cylindrical barrel that accommodates the lens, an image sensor that converts light imaged by the lens into an electrical signal, and the image sensor are accommodated. A pedestal mount to be mounted, and the pedestal mount accommodates a cylindrical barrel of the lens unit, the inner cross-sectional shape forms a polygon, and the barrel and barrel storage stored in the barrel storage unit There is provided a camera module comprising: an adhesive fixing portion that fills a gap with the inner side surface of the portion and adheres the barrel to the barrel housing portion.

Here, in the camera module to which the present invention is applied, the cylindrical barrel of the lens unit includes a lens storage unit that stores the lens and has a polygonal inner cross-sectional shape, and the lens stored in the lens storage unit; It is preferable to adhere the lens to the lens housing portion with an adhesive that fills a gap with the inner side surface of the lens housing portion.
Moreover, it is preferable that the adhesive fixing part of the pedestal mount is formed from a silicone-based adhesive.
Furthermore, the barrel storage part of the pedestal mount preferably has a quadrangular inner cross-sectional shape.

  Next, according to the present invention, a lens unit having a lens and a cylindrical barrel that houses the lens, an image sensor that converts light imaged by the lens into an electrical signal, the image sensor is housed, and the lens A pedestal mount to which the unit is attached, and the pedestal mount has a barrel storage portion that houses the cylindrical barrel of the lens unit, and has an inner cross-sectional shape forming a polygon. A camera module is provided that includes a fixing rib at a portion where the barrel contacts.

  Furthermore, according to the present invention, a lens unit having a lens and a cylindrical barrel that stores the lens, an image sensor that converts incident light imaged by the lens unit into an electrical signal, and an image sensor are stored. A pedestal mount to which the lens unit is attached, and the side wall portion of the pedestal mount has an outer diameter of the barrel so that a substantially lower half of the barrel in the height direction abuts when the cylindrical barrel of the lens unit is accommodated. When the barrel is stored, a clearance is formed between the substantially upper half of the barrel and the inner side surface of the side wall, and the outer diameter when the barrel is thermally expanded. A clearance forming portion having the same inner diameter, and the upper half of the barrel and the inner side surface of the clearance forming portion on the side wall portion are bonded by at least three bonding portions. The camera module is provided.

Here, the side wall portion of the pedestal mount preferably has a tapered shape so that the inner diameter of the side wall portion continuously increases from the clearance forming portion to the contact portion.
Moreover, it is preferable to adhere | attach the substantially upper half of a barrel and the inner side surface of the clearance formation part of a side wall part by four adhesion parts.

  According to the present invention, the optical axis shift due to the heat treatment at the time of manufacturing the camera module is prevented.

  Hereinafter, embodiments of the present invention will be described in detail. The present invention is not limited to the following embodiments, and various modifications can be made within the scope of the invention. The drawings used are for explaining the present embodiment and do not represent the actual size.

(First embodiment)
FIG. 1 is a diagram illustrating a camera module 1 to which the present embodiment is applied. As shown in FIG. 1, the camera module 1 includes a cylindrical lens unit 2 that holds a plurality of lenses (described later) and a pedestal mount 3 to which the lens unit 2 is attached. The pedestal mount 3 includes a cylindrical portion 3a to which the lens unit 2 is attached and a rectangular portion 3b that is configured integrally with the cylindrical portion 3a.
As shown in FIG. 1, the cylindrical part 3a of the pedestal mount 3 to which the lens unit 2 is attached is formed with a barrel housing part 3c whose inner cross-sectional shape is a quadrangle. An adhesive fixing portion 2d filled with an adhesive is formed in a gap (clearance) between the lens unit 2 and the inner side surface of the barrel housing portion 3c. The adhesive fixing part 2d will be described later. In addition, the part which attached the lens unit 2 to the base mount 3 may be called a lens-barrel.

  FIG. 2 is an exploded perspective view of the camera module 1 shown in FIG. As shown in FIG. 2, the camera module 1 includes a lens unit 2 and a pedestal mount 3. Furthermore, the filter 15 that removes a specific frequency component of incident light incident on the lens unit 2, the sensor (imaging device) 16 that converts incident light into an electrical signal, and the filter 15 and the sensor 16 are disposed. A square glass cover 17 is provided. Furthermore, it has the board | substrate 21 with which the sensor 16 is attached.

The lens unit 2 includes a cylindrical barrel (lens barrel) 2a constituting the lens unit 2 main body, and a first lens 4 and a second lens 6 held by the barrel 2a. Further, an intermediate ring 5 is disposed between the first lens 4 and the second lens 6.
The first lens 4 and the second lens 6 housed in the cylindrical barrel 2a are optical elements that transmit external light and form an image on a light receiving area (imaging area) of the sensor 16. That is, the first lens 4 and the second lens 6 form a predetermined optical system so that light incident from the opening 2 b forms an image on the sensor 16.
The intermediate ring 5 has a diaphragm function that limits the amount of incident light that passes through the opening 2b. An opening 2b through which light enters is provided on the end surface of the barrel 2a, and the outer peripheral surface of the barrel 2a constitutes a side wall 2c having a thread groove (male thread).

The pedestal mount 3 is configured such that the cylindrical portion 3a and the rectangular portion 3b are integrally formed, and the internal space of the cylindrical portion 3a and the internal space of the rectangular portion 3b are continuous.
As shown in FIG. 2, inside the cylindrical portion 3a, a cylindrical barrel 2a of the lens unit 2 is accommodated, and a barrel accommodating portion 3c having an inner cross-sectional shape of a quadrangle is formed. As will be described later, the lens unit 2 is bonded after screwing a screw groove (female screw) formed inside the barrel housing part 3c of the cylindrical part 3a and a screw groove (male screw) formed in the side wall part 2c. It is attached with adhesive. Thereby, focusing of the lens unit 2 is realized.

  The filter 15 is a thin plate member that removes a specific frequency component of external light. In the present embodiment, an infrared filter (IRCF: Infrared Cut Filter) is used. The filter 15 is disposed in the vicinity of the sensor 16, thereby suppressing the influence of irregular reflection.

The glass cover 17 is accommodated inside a region formed by the rectangular portion 3b of the base mount 3 surrounded by the side wall portion 3e.
The glass cover 17 is disposed between the filter 15 and the sensor 16, and the sensor 16 is fixed to the glass cover 17. The sensor 16 is an image sensor (imaging device) such as a CCD (Charge Coupled Device) or a CMOS (Complementary Metal Oxide Semiconductor), and converts incident light imaged by the lens unit 2 into an electrical signal. In this embodiment, a sensor having a CSP (Chip Scale Package) structure is used. The sensor 16 generates and outputs an electrical signal in accordance with the light imaged on the light receiving region via the lens unit 2.

Although not shown, a wiring pattern is provided in advance on the emission surface (lower surface) side of the glass cover 17, and a plurality of solder bumps are provided so that the wiring pattern and the sensor 16 are electrically and physically connected. It has been. The sensor 16 is physically fixed (bonded) to the glass cover 17 and electrically connected to the wiring pattern of the glass cover 17 by solder bumps attached to the wiring pattern.
Moreover, the electrical connection between the glass cover 17 and the circuit board (not shown) is ensured by the solder bumps arranged at different positions on the wiring pattern on the light emission surface side of the glass cover 17. The solder bumps are also used as spacers for separating the sensor 16 fixed to the glass cover 17 and the circuit board from each other.

Next, the materials of the lens unit 2 and the pedestal mount 3 constituting the camera module 1 will be described.
In the present embodiment, the barrel 2a and the pedestal mount 3 of the lens unit 2 are made of a synthetic resin having a light shielding property and having a heat resistance capable of withstanding a reflow temperature during heat treatment in a reflow furnace described later. The Here, the reflow furnace is, for example, an apparatus for supplying solder to a location where an electronic component or the like is connected on a mounting substrate such as a printed wiring board and placing the electronic component therein and then heating the reflow soldering It is.
Here, the heat resistant temperature is usually 200 ° C. or higher, preferably 260 to 300 ° C.

Examples of such heat-resistant synthetic resins include polycondensates of ethylene terephthalate and parahydroxybenzoic acid, polycondensates of phenol and phthalic acid and parahydroxybenzoic acid, and 2,6-hydroxynaphthoic acid. Examples thereof include liquid crystal polymers such as polycondensates with parahydroxybenzoic acid; thermoplastic resins such as polyphthalamide resin, polyether ether ketone resin (PEEK), and thermoplastic polyimide.
Moreover, as a material which comprises the 1st lens 4 and the 2nd lens 6, synthetic resins, such as silicone resin; Glass etc. are mentioned.

  In addition, the adhesive fixing | fixed part 2d (refer FIG. 1) is similarly formed with the heat resistant adhesive which has the heat resistance which can endure the heat processing in a reflow furnace. Examples of such heat-resistant adhesives include silicone adhesives; organic adhesives such as epoxy resin adhesives; and inorganic adhesives such as silicate adhesives and phosphate adhesives. Can be mentioned. Among these, a silicone-based adhesive is preferable. In addition, when using a heat resistant adhesive, a black thing is preferable for antireflection.

Next, the fitting state of the lens unit 2 and the pedestal mount 3 will be described.
FIG. 3 is a plan view for explaining a fitting state between the barrel 2 a of the lens unit 2 and the barrel storage portion 3 c of the pedestal mount 3. As shown in FIG. 3A, the cylindrical barrel 2a of the lens unit 2 is accommodated such that the side wall of the barrel 2a is inscribed in the inner side surface of the barrel accommodating portion 3c having an inner sectional shape of a quadrangle. ing. As described above, the barrel housing portion 3c is formed inside the cylindrical portion 3a that is integrally formed with the rectangular portion 3b. Further, by accommodating the cylindrical barrel 2a, the gaps formed at the four corners of the barrel accommodating portion 3c whose inner cross-sectional shape is a quadrangle are filled with an adhesive fixing portion 2d made of an adhesive. The barrel 2a is bonded to the inner side surface of the barrel storage portion 3c by the adhesive fixing portion 2d.

Next, when the heat treatment is performed in the reflow furnace in a state where the cylindrical barrel 2a is housed in the barrel housing portion 3c, the outer diameter of the barrel 2a increases due to expansion, as shown in FIG. The inner side surface of the barrel housing part 3c is compressed and deformed.
Subsequently, the barrel 2a contracts to the original outer diameter by the subsequent cooling process, but the inner diameter does not return to the original even if the inner side surface of the deformed barrel storage portion 3c contracts. Therefore, as shown in FIG. 3 (c), it occurs new clearance 3c ₀ between the inner side surface of the barrel 2a and the barrel housing portion 3c. However, at this time, the barrel 2a is adhesively fixed to the inner side surface of the barrel storage portion 3c while maintaining the adhesive strength by the adhesive fixing portion 2d formed of a heat-resistant adhesive. For this reason, the position of the barrel 2a does not change, and the optical axis does not shift.

FIG. 4 is a diagram for explaining another embodiment of the barrel storage unit. 4 (a) is formed inside of the rectangular portion 3b and the cylindrical portion 3a ₁ which is formed integrally of the base mount is a diagram inner cross section illustrating the barrel housing portion 3c ₁ is a hexagon ( (1) in FIG. As shown in (2) in FIG. 4 (a), the cylindrical barrel 2a is the side wall of the barrel 2a is housed to be inscribed on the inner side surface of the barrel housing portion 3c ₁ is an inner cross-sectional shape is hexagonal Is done. Further, by accommodating a cylindrical barrel 2a, the gap inside cross section occurs at six positions in the hexagonal barrel housing portion 3c _1, the adhesive fixing portion 2d ₁ consisting of an adhesive is filled, the barrel 2a is It is bonded to the inner side surface of the barrel housing portion 3c _1.

FIG. 4B is a diagram for explaining the barrel storage portion 3c ₂ formed so that the inner cross-sectional shape of the cylindrical portion 3a ₂ has a shape in which the four concave portions 3c ₃ and the curved surface are combined. Yes ((1) in FIG. 4B). As shown in (2) of FIG. 4 (b), the cylindrical barrel 2a is the side wall of the barrel 2a is housed in contact with the portion having the curved surface of the inner side surface of the barrel housing portion 3c _2. Further, by accommodating a cylindrical barrel 2a, the gap between the recess 3c ₃ formed in four places of the barrel accommodating portion 3c ₂ has adhesive fixing portion 2d ₂ consisting of an adhesive is filled, the barrel 2a barrel It is bonded to the inner side surface of the housing portion 3c _2.

(Second Embodiment)
Next, a second embodiment of the camera module will be described.
FIG. 5 is a diagram for explaining a second embodiment of the camera module. The same reference numerals are used for the same configurations as those in the first embodiment, and the description thereof is omitted. FIG. 5A is a perspective view of the pedestal mount 3 according to the second embodiment. As shown in FIG. 5A, the pedestal mount 3 is configured integrally with a cylindrical portion 3a to which the lens unit 2 (see FIG. 2) is attached and the cylindrical portion 3a, as in the first embodiment. And a rectangular portion 3b. The cylindrical portion 3a of the pedestal mount 3 accommodates the cylindrical barrel 2a (see FIG. 2) of the lens unit 2, and has a barrel accommodating portion 3c whose inner cross-sectional shape is a quadrangle. In the present embodiment, a fixing rib 3d for fixing the barrel 2a is provided on a portion of the inner side surface of the barrel housing portion 3c where the barrel 2a is inscribed. A screw groove is formed inside the fixed rib 3d.

FIG. 5B is a diagram showing a state where the cylindrical barrel 2a is stored in the barrel storage portion 3c of the pedestal mount 3 shown in FIG. As shown in FIG. 5B, the cylindrical barrel 2a is stored such that the side wall portion of the barrel 2a is inscribed in the four fixed ribs 3d provided inside the barrel storage portion 3c. By providing the fixing rib 3d, it is easy to obtain accuracy for the surface formation.
Further, by providing the fixing rib 3d and fixing the position of the barrel 2a, gaps generated at the four corners of the barrel housing portion 3c whose inner cross-sectional shape is quadrangular are increased, and for example, insertion of a dispenser needle is facilitated. Improved workability.

(Third embodiment)
Next, a third embodiment of the camera module will be described.
FIG. 6 is a diagram for explaining a third embodiment of the camera module. The same reference numerals are used for the same configurations as those in the first embodiment, and the description thereof is omitted. 6A is a view showing a state where the cylindrical barrel 2a is stored in the barrel storage portion 3c of the pedestal mount 3 (see FIG. 2). As shown in (1) of FIG. 6 (a), the cylindrical barrel 2a is the side wall of the barrel 2a is housed in a barrel housing portion 3c formed on the inner side of the cylindrical portion 3a _3, the barrel accommodating portion 3c Are bonded and fixed by four adhesive fixing portions 2d ₃ provided inside. At this time, since the inner diameter of the upper portion of the barrel storage portion 3c is larger than the outer diameter of the cylindrical barrel 2a, a clearance is generated between the upper portion of the cylindrical barrel 2a and the upper portion of the barrel storage portion 3c.

6A is a cross-sectional view taken along line xx ′ in FIG. 6A. As shown in (2) of FIG. 6 (a), the side wall portion of the cylindrical portion 3a ₃ of the barrel accommodating portion 3c is formed, at the time of accommodating a cylindrical barrel 2a, barrel 2a in the height direction An abutting portion 3f having an inner diameter (L ₁ ) approximately the same as the outer diameter of the barrel 2a so that the substantially lower half (height H ₁ ) abuts, and when the barrel 2a is stored, A clearance forming portion 3g that forms a clearance between the half (height H ₂ ) and the inner side surface of the side wall portion and has an inner diameter (L ₂ ) that is substantially the same as the outer diameter when the barrel 2a is thermally expanded; It is composed of A thread groove is formed in the lower portion of the barrel 2a and the contact portion 3f so as to be screwed together.
Then, as shown in (2) of FIG. 6 (a), and the substantially upper half and the side wall portion inner side surface of the clearance forming portions 3g of the barrel 2a, is bonded and fixed by an adhesive fixing portion 2d ₃ of at least 4 points Yes. Further, the side wall portion of the cylindrical portion 3a ₃ is formed in a tapered shape so that the inner diameter of the side wall increases continuously toward the abutment portion 3f from the clearance forming portions 3g.

Next, (1) and (2) of FIG. 6 (b) are views showing the state of the barrel storage portion 3c and the barrel 2a in the heat treatment state. As shown in (1) of FIG. 6B, when the heat treatment is performed in the reflow furnace with the cylindrical barrel 2a stored in the barrel storage portion 3c, the outer diameter of the barrel 2a increases due to expansion. The inner side surface of the barrel housing part 3c is compressed and deformed. At this time, as shown in (2) of FIG. 6B, the inner diameter (L ₁ ) of the abutting portion 3f constituting the substantially lower half (height H ₁ ) of the side wall portion of the cylindrical portion 3a ₃ is expanded. The barrel 2a is expanded and enlarged.

Subsequently, (1) and (2) in FIG. 6 (c) are views showing the state of the barrel housing part 3c and the barrel 2a after the cooling process. As shown in (1) of FIG. 6C, the barrel 2a contracts to the original outer diameter by the cooling process after the heat process. At this time, as shown in (2) of FIG. 6C, the inner side surface of the contact portion 3f constituting the substantially lower half (height H ₁ ) of the deformed cylindrical portion 3a ₃ Will not return. For this reason, a new clearance 3a ₄ is generated between the barrel 2a and the inner side surface of the contact portion 3f. However, this time, the barrel 2a is adhesively fixed portion 2d ₃ constituted by heat-resistant adhesive, is bonded and fixed to the inner side of the left barrel housing portion 3c retaining the adhesive strength. For this reason, the position of the barrel 2a does not change and the optical axis is not displaced.

(Fourth embodiment)
Next, a fourth embodiment of the camera module will be described.
In the present embodiment, the configuration has been described in which the cylindrical barrel 2a of the lens unit 2 is stored in the barrel storage portion 3c formed on the inner side of the pedestal mount 3 and having a quadrangular inner cross-sectional shape. Such a technique can be applied to a circular lens and a barrel 2a that houses the lens.
FIG. 7 is a diagram for explaining a fourth embodiment of the camera module. The same reference numerals are used for the same configurations as those in the first embodiment, and the description thereof is omitted. As shown in FIG. 7, the camera module is configured integrally with a lens unit 2 including a lens 10 and a cylindrical barrel 2a that houses the lens 10, and a cylindrical portion 3a and a cylindrical portion 3a to which the lens unit 2 is attached. And a pedestal mount 3 composed of a rectangular portion 3b.
As shown in FIG. 7, inside the cylindrical barrel 2a of the lens unit 2, a lens storage portion 2e that stores the lens 10 and has a quadrangular inner cross-sectional shape is provided. As in the first embodiment, by storing the circular lens 10 in the lens storage portion 2e, the gaps generated at the four corners of the lens storage portion 2e having the inner cross-sectional shape of a quadrangle are filled with an adhesive, With this adhesive, the lens 10 is bonded and fixed to the lens housing portion 2e. A screw groove is formed on the outer side of the barrel 2a, and is screwed with a screw groove (not shown) formed on the inner side of the cylindrical portion 3a.
At this time, the lens 10 is adhesively fixed to the inner side surface of the barrel 2a while maintaining the adhesive strength by an adhesive fixing portion formed of a heat resistant adhesive. For this reason, even if it passes through the heat processing process by a reflow furnace, the position of the lens 10 does not change and the shift | offset | difference of an optical axis does not arise.

Next, a method for manufacturing an imaging device having the camera module 1 and the circuit board to which the present embodiment is applied will be described.
In the camera module 1, first, the lens unit 2 is temporarily screwed into the cylindrical portion 3 a of the pedestal mount 3, and the filter 15 is attached to a flange portion (not shown) of the pedestal mount 3. At this time, the sensor 16 is bonded and fixed to the glass cover 17 in advance with a plurality of solder bumps in a state where a light receiving region (not shown) faces the glass cover 17.
Next, the glass cover 17 bonded to the sensor 16 is fitted into a region formed by being surrounded by the side wall 3 e of the pedestal mount 3.

  Thereafter, an adhesive is poured into the gap between the side end face of the fitted glass cover 17 and the side wall 3e of the pedestal mount 3, and the glass cover 17 and the pedestal mount 3 are bonded. In this case, before the glass cover 17 to which the sensor 16 is bonded is fitted, an adhesive may be poured into the pedestal mount 3 in advance. When the glass cover 17 is fitted into the pedestal mount 3, the light receiving area of the sensor 16 is optically positioned in the imaging areas of the first lens 4 and the second lens 6, and the vertical and horizontal optical axes are adjusted. Thereafter, after image adjustment is performed, the lens unit 2 is fixed to the base mount 3 with an adhesive, and the assembly of the camera module 1 is completed.

Next, a process in which the camera module 1 assembled as described above is mounted on a circuit board (not shown) by an automatic mounting machine (mounter) will be described below.
The assembled camera module 1 is mounted on a reel. Then, the mounting process starts when the reel on which the camera module 1 is mounted is set in the mounter and the mounter is operated. The mounter picks up the camera module 1 from the reel and mounts it at a predetermined position on the circuit board (mounting process). Solder paste is printed in advance on the circuit board where the camera module 1 is mounted. When the mounter mounts the camera module 1 at a predetermined position, the camera module 1 is temporarily fixed. Subsequently, the mounter mounts other electronic components on the circuit board to complete the mounting operation. The camera module 1 may be picked up from a tray instead of from a reel.

  Next, the circuit board on which the camera module 1 is mounted is transferred to a reflow furnace. In the reflow furnace, the circuit board is heated for several tens of seconds at a temperature at which the solder melts (for example, 260 ° C. or higher), and soldering is performed (heating process). At this time, the solder bumps arranged on the wiring pattern (not shown) of the glass cover 17 of the camera module 1 are melted and soldered to terminals (not shown) formed in advance on the circuit board. Thereby, the sensor 16 in the camera module 1 and the signal processing unit on the circuit board are electrically connected.

  The camera module 1 described in the present embodiment is a mobile phone as an example of a mobile device in which the camera module 1 is mounted. For example, a camera mounted on a personal computer or a PDA (Personal Digital Assistant), a camera mounted on an automobile, or a monitor. It can be applied to a camera or the like.

It is a figure explaining the camera module to which this Embodiment is applied. It is a disassembled perspective view of the camera module shown in FIG. It is a top view explaining the fitting state of the barrel of a lens unit and the barrel storage part of a base mount. It is a figure explaining other embodiment of a barrel storage part. It is a figure explaining 2nd Embodiment of a camera module. It is a figure explaining 3rd Embodiment of a camera module. It is a figure explaining 4th Embodiment of a camera module. It is a figure explaining the conventional camera module. It is a top view explaining the fitting state of the conventional lens unit and a base mount.

Explanation of symbols

1 ... camera module, 2 ... lens unit, 2a ... barrel, _2d, 2d 1, _2d 2, 2d 3 _... adhesive fixing portion, 2e ... lens housing portion, 3 ... pedestal mount, 3c, _3c 1, 3c 2 _... barrel housing Part, 3d ... fixing rib, 3e ... side wall part, 3f ... contact part, 3g ... clearance forming part, 16 ... sensor (imaging device)

Claims (8)

A lens unit having a lens and a cylindrical barrel for housing the lens;
An image sensor that converts light imaged by the lens into an electrical signal;
A pedestal mount that houses the imaging device and to which the lens unit is attached;
The pedestal mount is
A barrel housing portion that houses the cylindrical barrel of the lens unit, and an inner cross-sectional shape forms a polygon;
A camera module, comprising: an adhesive fixing portion that fills a gap between the barrel stored in the barrel storage portion and an inner side surface of the barrel storage portion and bonds the barrel to the barrel storage portion.   The cylindrical barrel of the lens unit includes a lens storage unit that stores the lens and has a polygonal inner cross-sectional shape, and the lens stored in the lens storage unit and the inner side surface of the lens storage unit The camera module according to claim 1, wherein the lens is bonded to the lens housing portion with an adhesive that fills a gap between the lens and the lens housing.   The camera module according to claim 1, wherein the adhesive fixing portion of the pedestal mount is formed of a silicone-based adhesive.   The camera module according to claim 1, wherein the barrel housing portion of the pedestal mount has a quadrangular inner cross-sectional shape. A lens unit having a lens and a cylindrical barrel for housing the lens;
An image sensor that converts light imaged by the lens into an electrical signal;
A pedestal mount that houses the imaging device and to which the lens unit is attached;
The pedestal mount is
The cylindrical barrel of the lens unit is accommodated, a barrel accommodating portion whose inner cross-sectional shape forms a polygon is provided, and a fixing rib is provided at a portion of the inner side surface of the barrel accommodating portion that comes into contact with the barrel. A camera module characterized by A lens unit having a lens and a cylindrical barrel for housing the lens;
An image sensor that converts incident light imaged by the lens unit into an electrical signal;
A pedestal mount that houses the imaging device and to which the lens unit is attached;
The side wall of the pedestal mount is
When storing the cylindrical barrel of the lens unit, a contact portion having an inner diameter substantially the same as the outer diameter of the barrel so that the substantially lower half of the barrel in the height direction contacts,
When storing the barrel, a clearance is formed between a substantially upper half of the barrel and an inner side surface of the side wall, and a clearance forming portion having an inner diameter substantially equal to an outer diameter when the barrel is thermally expanded. And having
The camera module, wherein the substantially upper half of the barrel and the inner side surface of the clearance forming portion of the side wall portion are bonded by at least three bonding portions.   The camera module according to claim 6, wherein the side wall portion of the pedestal mount has a tapered shape so that the inner diameter of the side wall portion continuously increases from the clearance forming portion to the contact portion. .   The camera module according to claim 6, wherein the substantially upper half of the barrel and the inner side surface of the clearance forming portion of the side wall portion are bonded by the four bonding portions.

Images