JP2008148020A - CAMERA MODULE, CAMERA MODULE MANUFACTURING METHOD, AND IMAGING DEVICE - Google Patents

Abstract

An object of the present invention is to provide a camera module or the like that eliminates the need for sealing a vent hole and can reduce costs.
A camera module includes a mount, a lens unit, a filter, and an image sensor. The mount 10 has a communication hole 15 </ b> A that communicates the internal space 17 with the outside. The communication hole 15 </ b> A is formed in a crank shape that allows external air to enter the internal space 17 and allows air to flow.
[Selection] Figure 3

Description

  The present invention relates to a camera module mounted on, for example, a mobile phone or a personal computer.

In recent years, camera systems have been installed in mobile phones and personal computers. In such a camera system, a camera module that forms an image of a subject on an image sensor (image sensor) using a lens is widely used. These camera modules are also used for in-vehicle cameras, surveillance cameras, etc., in addition to mobile phones and personal computers.
As such a camera module, a configuration as disclosed in Patent Document 1 is known.
In the camera module disclosed in Patent Document 1, a lens barrel supporting a lens is fixed on a surface of a wiring board having a window portion, and incident light is converted into an electrical signal on a surface of the wiring board opposite to the lens barrel. The image sensor chip to be converted is fixed with its sensor portion positioned at the window portion of the wiring board. In this configuration, the lens barrel and the image sensor chip are separately mounted on the wiring board.

Some camera modules have a configuration in which a lens and an image sensor are integrated with a holding member. In addition to this, a filter (for example, an infrared cut filter) that adjusts the wavelength distribution of electromagnetic waves incident on the image sensor (transmits or absorbs electromagnetic waves in a specific wavelength range) may be provided.
In the camera module having such a configuration, the holding member covers the periphery of the lens and the image sensor in a light-shielded state so that external light does not enter the image sensor and cause image defects such as flare and fog. Constructed and inevitably a nearly airtight structure.
An adhesive is used for fixing the lens, the image sensor, the filter, and the like to the holding member. The adhesive generates a gas when it is solidified, but if this gas stays inside the holding member, there is a risk of causing problems such as clouding of the lens. For this reason, the holding member is formed with a vent hole communicating the inside and the outside, and the gas generated from the adhesive is discharged to the outside through the vent hole.

Further, such a vent hole also acts to equalize the pressure inside and outside the holding member.
For example, each component of the camera module is formed of a heat-resistant material, so that it can be mounted on a circuit board using the camera module simultaneously with other electronic components by a reflow process. In such a configuration, when the internal pressure of the holding member is increased by heat applied during reflow, focus shift or breakage due to position variation of the lens and the image sensor is caused. The vent hole formed in the holding member also functions to prevent such a problem by eliminating the pressure difference between the inside and outside of the holding member.

JP 2003-51973 A

Here, in the camera module in which the vent hole is formed in the holding member as described above, external light may enter the inside of the holding member through the vent hole and cause image defects such as flare and fog. For this reason, the operation | work which seals a vent hole is required. For example, a ball-shaped plug (plug) is fitted into the vent hole and bonded with an adhesive.
The operation of sealing the air vent hole is performed after the function of the air vent hole has become unnecessary, that is, after the adhesive is solidified and no gas is generated. Further, when the camera module is mounted on the circuit board by reflow, it must be performed after the temperature of the camera module is stabilized after mounting.
For this reason, there is a problem that a member (plug) for sealing the vent hole is required and the operation is troublesome, which causes a cost increase.

  An object of the present invention is to provide a camera module or the like that does not require the work of sealing a vent hole and can reduce costs.

  For this purpose, the camera module according to the present invention includes an imaging element that converts incident light into an electrical signal, an optical element that collects incident light on the imaging element, and a connecting member that connects the optical element and the imaging element. And the connecting member is formed with a communication path that communicates the internal space and the outside of the connecting member without allowing light to directly enter the internal space from outside. To do.

  Further, the camera module according to the present invention viewed from another viewpoint connects an imaging element that converts incident light into an electrical signal, an optical element that collects incident light on the imaging element, and the optical element and the imaging element. A connecting member, and the connecting member includes an inner surface opening that opens into the inner space of the connecting member and an outer surface opening that opens to the outside of the connecting member, so that air does not directly enter the inner space from the outside. Is characterized in that a communication passage communicating with a possible bent path is formed.

Here, the communication path may be formed by a gap formed by cutting from the end of the connection member in a direction intersecting with the direction in which the internal space of the connection member communicates with the outside.
Further, the connecting member may be formed integrally with the optical element.
The image sensor further includes a cover member that transmits incident light to the image sensor, the image sensor and the cover member are integrated to form an image member, and the image member is coupled to the connecting member via the cover member. Can be characterized.
Further, a plurality of communication paths may be formed.

  In the method for manufacturing a camera module of the present invention, an imaging element that converts incident light into an electrical signal and an optical element that condenses incident light on the imaging element are connected by a connecting member, and the internal space of the connecting member is connected to the connecting member. Is a method of manufacturing a camera module in which a communication path is formed so that air can communicate without allowing light to directly enter the outside, and the connecting member is bent so that light does not directly enter the internal space from the outside. It includes a step of forming a gap having a cross-sectional shape from the end surface of the connecting member to a position reaching the internal space, and a step of coupling the connecting member and the imaging member.

  An imaging device of the present invention is connected to an imaging device that converts incident light into an electrical signal, an optical element that focuses incident light on the imaging device, a connecting member that connects the optical element and the imaging device, and the imaging device. The connecting member is formed with a communication path that allows the internal space and the outside of the connecting member to communicate with each other without allowing light to directly enter the internal space from the outside. It is characterized by.

  According to the present invention, the communication path communicates the internal space and the outside of the connecting member between the external space and the air without allowing light to directly enter the internal space. Is no longer necessary. Thereby, the productivity of the camera module and the like can be improved, and the cost can be reduced.

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings.
FIG. 1 is an external perspective view of a camera module 1 according to the present embodiment, and FIG. 2 is an exploded perspective view thereof. 3 is a longitudinal sectional view of the camera module 1 mounted on the circuit board 80, FIG. 4 is a bottom view of the camera module 1, and FIG. 5 is a sectional view taken along line AA of FIG. FIG. 6 is an enlarged view of the communication hole 15A.
A camera module 1 shown in FIG. 1 is used for, for example, a camera (imaging device) built in a mobile phone.

  The camera module 1 includes a mount 10 as a connecting member, a lens unit 20, a filter 30 as a filter member, and an image sensor 40 as an imaging member. Further, a connecting flexible substrate 50 as shown by a two-dot chain line in FIG. 1 is connected to the image sensor 40, and the flexible substrate 50 may be referred to as the camera module 1. The flexible substrate 50 is formed by forming an electric circuit on a polyester (PET) film, and includes a connector 51 for connecting the camera module 1 and a circuit substrate of a device (for example, a mobile phone) (not shown) using the camera module 1. Prepare.

Here, the mount 10 and the barrel 21 are formed of a heat-resistant engineering resin such as an epoxy resin having a light shielding property. The imaging lens 22 is made of an optically transparent heat-resistant optical resin material such as silicon resin, epoxy resin, or polysulfone resin.
The camera module 1 configured as described above is mounted on a flexible substrate 50 indicated by a two-dot chain line in FIG. 1 via solder bumps 70, and a mobile phone or the like using the camera module 1 as shown in FIG. It is mounted (mounted) directly on the circuit board 80 via the solder bumps 70.
When the camera module 1 is mounted on a circuit board 80 such as a cellular phone, each component of the camera module 1 is made of a heat-resistant material as described above. It can be mounted simultaneously in a batch soldering process such as reflow. That is, it can be directly mounted on a circuit board 80 of a device using the camera module 1. This eliminates the need for a structure to be connected to a circuit board such as a mobile phone via a flexible board 50 as shown by a two-dot chain line in FIG. It can contribute.

Hereinafter, the configuration of each part of the camera module 1 will be described in detail.
The mount 10 is formed by integrally forming a cylindrical lens holding portion 12 on the upper side of a rectangular parallelepiped base portion 11. In the present embodiment, the planar shape of the base portion 11 is a square, and the length of the side and the diameter of the lens holding portion 12 are set equal. The base 11 and the lens holding part 12 are formed hollow by a wall plate having a predetermined thickness, the bottom of the base 11 is opened downward, and the upper end of the lens holding part 12 is opened upward.
In four places around the mount 10, slits 15 are formed as gaps at a predetermined height from the lower end edge of the base 11. The slit 15 forms a communication hole 15A as a communication path communicating with the internal space 17 of the mount 10 which will be described in detail later and the outside.

A filter 30 and an image sensor 40 are mounted inside the base 11.
The base 11 has a rectangular parallelepiped shape that opens downward in FIG. 3, and its top surface is positioned so as to partition the interior of the mount 10 in the vertical direction, which supports the filter 30 and the image sensor 40. It has become.
The support plate 13 is a plate having a predetermined thickness, and a rectangular light-transmitting opening 14 corresponding to the light receiving area (light receiving surface 41A) of the image sensor 40 is formed at the center.
An accommodation recess 16 for accommodating the filter 30 is formed on the lower surface of the support plate portion 13 (the surface opposite to the lens holding portion 12).
The housing recess 16 is formed in a planar shape and depth that can accommodate a rectangular filter 30 larger than the light-transmitting opening 14, with its center coinciding with the light-transmitting opening 14.

The filter 30 is formed by coating a surface of a glass substrate having a predetermined thickness to adjust the wavelength of an electromagnetic wave to be transmitted. In this embodiment, an infrared filter (IRCF: Infrared Cut Filter) that absorbs electromagnetic waves in the infrared region.
The planar shape is a rectangle larger than the imaging range at the installation position, and both front and rear surfaces thereof are smooth and formed with parallelism with a predetermined accuracy.
Then, the support plate portion 13 is accommodated in the accommodation recess 16 of the support plate portion 13 of the mount 10 and filled with a thermosetting adhesive or the like (adhesion portion 31) filled between the side peripheral edge and the inner wall of the accommodation recess 16. (Mount 10).

The image sensor 40 is configured by mounting a transparent cover 42 as a cover member on the front surface (the light receiving surface 41 </ b> A side) of a sensor unit 41 as an imaging element.
The sensor unit 41 is a light receiving element such as a CCD (Charge Coupled Device) or a CMOS (Complementary Metal Oxide Semiconductor), and generates and outputs an electrical signal corresponding to light incident on the light receiving surface 41A (see FIG. 2).
The transparent cover 42 is a transparent glass plate having a predetermined thickness, and both front and rear surfaces thereof are smooth and formed with parallelism with a predetermined accuracy. Further, a wiring circuit 42A is formed on the back surface side (the surface side facing the sensor unit 41), and the inner end of the wiring circuit 42A is connected to the electrode of the sensor unit 41 by a solder bump 43. The connection by the solder bumps 43 serves both as electrical continuity and bonding between the sensor unit 41 and the transparent cover 42. The positions of the transparent cover 42 and the sensor unit 41 are set to a predetermined accuracy.

Further, the outer end of the wiring circuit 42A is connected to the flexible substrate 50 indicated by a two-dot chain line in FIG. 1 or the circuit substrate 80 shown in FIG. That is, the transparent cover 42 has a function of preventing breakage of the sensor unit 41 and adhesion of dust to the sensor unit 41 and a function of an output terminal circuit of the sensor unit 41.
The image sensor 40 having such a configuration has the side surface of the transparent cover 42 in a state where the upper surface of the transparent cover 42 is in contact with the lower surface of the support plate 13 and the center of the light receiving surface 41A is aligned with the optical axis. It is fixed to the support plate part 13 (mount 10) by a thermosetting adhesive or the like (adhesive part 44) filled between the surface and the side wall of the base part 11.

The lens holding portion 12 has a female screw formed on the inner periphery, and the lens unit 20 is screwed and attached thereto.
The lens unit 20 is configured by assembling an imaging lens 22 as an optical element at a predetermined position inside a cylindrical barrel 21.
The barrel 21 is formed with a small-diameter objective opening 21A in the center on the upper end side, and is open in a cylindrical shape on the lower end side. Further, a male screw that is screwed into the female screw of the lens holding portion 12 is formed on the outer periphery thereof.
The imaging lens 22 includes a single lens or a plurality of lens groups, and forms an optical system that forms an image of incident light from the objective aperture 21A on the light receiving surface 41A of the image sensor 40 (sensor unit 41). .
The lens unit 20 configured as described above is screwed into the lens holding unit 12 and is adjusted so that the image formation position of the image formation lens 22 is the light receiving surface 41A of the image sensor 40, and then the thermosetting adhesive. It is fixed to the lens holding part 12 so as not to move with an agent.

  In the camera module 1 configured as described above, the filter 30 and the image sensor 40 mounted on the base 11 (support plate 13) and the lens unit 20 (lens 22) mounted on the lens holding unit 12 are disposed. A substantially airtight internal space 17 is formed. A slit 15 (communication hole 15 </ b> A) formed in the mount 10 communicates the internal space 17 and the outside without allowing external light to directly enter the internal space 17.

Next, the slit 15 formed in the mount 10 and the communication hole 15A formed by the slit 15 will be described in detail.
As described above, the slits 15 are formed in the wall plate of the mount 10 at four locations around the mount 10 at a predetermined height from the lower end surface of the base 11. That is, the slit 15 is open to the lower surface side of the mount 10.

As shown in FIG. 6A, which is an enlarged view, the shape of the slit 15 in the thickness direction of the wall plate is an outer surface opening 15a that opens on the outer surface of the wall plate, and a circumferential direction with respect to the outer surface opening 15a. The inner surface opening portion 15b that opens to the inner surface of the wall plate by a predetermined amount is connected through a path bent in a crank shape.
That is, from the outer surface side slit portion 15c formed substantially at right angles to the outer surface from the outer surface opening portion 15a that opens to the outer surface of the wall plate to the center in the thickness direction of the wall plate, and from the inner surface opening portion 15b that opens to the inner surface of the wall plate. The inner surface side slit portion 15d formed substantially at right angles to the inner surface up to substantially the center in the thickness direction of the wall plate is connected by a connecting slit portion 15e substantially parallel to the inner and outer surfaces. The width of the outer surface opening 15a and the inner surface opening 15b and the length of the connecting slit portion 15e are such that external light (indicated by an arrow in the figure) incident on the outer surface opening 15a enters the inner space 17 from the inner surface opening 15b. It is set so that it does not occur (so that it cannot pass linearly from the outer surface opening 15a to the inner surface opening 15b).

The formation position of the slit 15 in the circumferential direction of the mount 10 is set so that the outer surface opening 15a is the center of the side of the base 11 (that is, the position where the outer surface of the base 11 and the outer peripheral surface of the lens holding portion 12 coincide). Since the slit 15 has a crank shape as described above, the inner surface opening 15b is shifted from the center of the side of the base 11.
On the other hand, as shown in FIGS. 1 to 3, the height of the slit 15 is set so as to reach a predetermined amount from the upper surface of the base 11 toward the lens holding unit 12 (a predetermined amount above the upper surface of the support plate 13). Yes.

Due to the setting of the slit 15, the inner surface opening 15 b opens into the internal space 17 above the support plate 13, and communicates with the crank-shaped communication hole 15 </ b> A when the internal space 17 and the outside are viewed in plan. It has become.
That is, the crank-shaped communication hole 15 </ b> A is formed by the slit 15 having a crank-shaped cross section and opening to the lower surface side of the base 11. In other words, the slit 15 extends in a direction orthogonal to the internal and external communication directions by the communication hole 15A. As a result, the communication hole 15A can be easily formed (the forming will be described in detail later).

The communication hole 15A as described above allows the gas generated when the adhesive for fixing the lens unit 20, the image sensor 40, the filter 30 and the like is solidified to escape from the internal space 17 to the outside, and the image forming lens 22 is clouded by the gas. Prevent the occurrence of problems. Further, the pressure difference between the internal space 17 and the outside is eliminated, and problems due to an increase in internal pressure are prevented. For example, if the internal pressure of the internal space 17 is increased by heat applied during reflow, there may be a focus shift or damage due to position fluctuations of the imaging lens 22 and the image sensor 40, but this is not the case.
Further, since the communication hole 15A allows air to flow without allowing light to directly enter the inner surface opening 15b from the outer surface opening 15a, it is not necessary to seal the communication hole after the function becomes unnecessary as described above. For this reason, the member and operation | work for sealing become unnecessary, and a cost reduction is attained. Since the communication hole 15A has a crank shape, it is difficult for dust or the like to enter even if it remains open.

In this embodiment, the four communication holes 15A are formed in the circumferential direction of the mount 10, but the number of the communication holes 15A is not limited to this, and even if it is less (for example, one), It may be more than that. However, since the communication hole 15A may be blocked for some reason, it is more preferable to provide a plurality of communication holes 15A. The size of the opening portion (outer surface opening portion 15a) of the communication hole 15A is preferably a size that can be formed within a range that does not affect the image even if dust or the like enters, but is not limited thereto.
Further, the shape of the communication hole 15A is not limited to the crank shape, and may be any shape that allows air to flow without causing light to directly enter the inner surface opening 15b from the outer surface opening 15a. For example, as shown in FIG. 6 (b), it may be a "" shape "" bent at one place, or an arc shape as shown in FIG. 6 (c).
Furthermore, the bending direction of the communication hole 15A is not limited to the circumferential direction, and may be configured to bend in a direction intersecting the circumferential direction (for example, the optical axis direction).
Furthermore, the communication hole 15 </ b> A may be configured to open to a surface (for example, the upper surface) other than the side surface of the mount 10.

Next, a manufacturing method of the camera module 1 in which the communication hole 15A (slit 15) as described above is formed will be described.
FIG. 7 is an explanatory diagram of the manufacturing process of the camera module 1. In the following description, the reference numerals of the parts not described in FIG. 7 are the same as those in FIGS.
First, the mount 10 of the camera module 1 is formed by injection molding using a resin such as thermoplastic resin. That is, the mount 10 is formed by press-fusing molten resin into a cavity 93 having a corresponding shape formed in the mold 90 (the fixed-side mold 91 and the movable-side mold 92) shown in FIG. .

In the illustrated mold 90, a split surface between the fixed mold 91 and the movable mold 92 is set at the boundary between the base 11 and the lens holding section 12.
The fixed-side mold 91 includes a crank-shaped template 91A corresponding to the slit 15, and as the mount 10 is formed, the mount 10 is opened to the lower end surface of the base 11 as shown in FIG. A slit 15 having a predetermined height is formed.
That is, in this case, the molding process of the mount 10 is also a process of forming the slit 15 at the same time. In this configuration, the slit 15 (crank-shaped communication hole 15A) having a crank-shaped cross section is set in the moving direction of the movable-side mold 92 (ie, the mold-release direction), thereby enabling easy formation in this way. It is what has become.
The mount 10 in which the slits 15 are formed in this manner is turned upside down as shown in FIG. 7C from the normal top-and-bottom state as shown in FIG. 2, and the bottom of the base 11 is opened upward. And Thereby, the accommodation recessed part 16 formed in the support plate part 13 opens to the upper side.

Next, as shown in FIG. 7 (d), the filter 30 is placed inside the housing recess 16 from above the base 11, and an adhesive is filled between the side edge and the inner wall of the housing recess 16 (adhesion). Part 31) and the filter 30 are bonded and fixed to the support plate part 13 (mount 10).
Thereafter, as shown in FIG. 7E, the image sensor 40 is placed on the upper side of the support plate portion 13 corresponding to the housing recess 16 (filter 30) in a posture in which the image sensor 40 faces downward (the transparent cover 42 is on the lower side). . Then, an adhesive is filled between the side end surface of the transparent cover 42 and the inner wall of the base portion 11 of the mount 10 (adhesive portion 44), and the image sensor 40 is bonded and fixed to the mount 10.
Thereby, the filter 30 and the image sensor 40 are attached to the mount 10 so as not to be detached.

Thereafter, although not shown, the lens unit 20 is screwed into the lens holding portion 12, and the position is adjusted so that an image is formed on the light receiving surface 41A of the image sensor 40 by adjusting the screwing amount, and then fixed with an adhesive or the like. Thereby, the camera module 1 is completed.
Then, such a camera module 1 is mounted on the circuit board 80. As a result, as shown in FIG. 3, an imaging apparatus in which the camera module 1 is mounted on the circuit board 80 is configured. The mounting of the camera module 1 on the circuit board 80 can be performed simultaneously with the other electronic components by performing a reflow process in a state where the camera module 1 is mounted at a predetermined position on the circuit board 80 together with the other electronic components. it can.

  As described above, in the camera module 1 configured as described above, the communication hole 15A formed in the mount 10 so as to communicate the internal space 17 with the outside allows the external light to directly enter the internal space 17. The air can be circulated. For this reason, it is not necessary to seal after the function becomes unnecessary. As a result, the member and work for sealing become unnecessary, productivity improves, and a cost reduction is attained.

  In addition, this invention is not limited to the said embodiment, It can change suitably. For example, in the above-described embodiment, the image sensor 40 is configured such that the transparent cover 42 is integrally attached to the front surface of the sensor unit 41. However, the image sensor 40 may be configured without the transparent cover 42. The transparent cover 42 may be separately mounted on the mount 10. Furthermore, it may be configured to be connected to a circuit board of a device (for example, a mobile phone) via an interposer board or the like.

Further, the structure of the camera module to which the present invention is applied is not limited to the structure of the above embodiment.
FIG. 8 is a cross-sectional view of the camera module 2 having a different configuration from the above embodiment.
In the illustrated camera module 2, the imaging lens 22 (lens unit 20) and the member corresponding to the mount 10 in the above embodiment are integrally formed by resin molding. That is, the lens (lens portion 201) and the cylindrical holder portion 202 are formed as an integral lens barrel 200.
The lens barrel 200 has a light shielding layer 203 formed on the inner and outer surfaces of the holder portion 202 so that external light is not incident. The light shielding layer 203 is formed by masking the lens portion 201 and applying a light shielding paint.
The lower end edge of the lens barrel 200 (the lower end edge of the holder portion 202) is coupled to the upper surface of the image sensor 400 by an adhesive (adhesive portion 204), whereby the lens barrel 200 and the image sensor 400 are integrated. The camera module 2 is configured. In this configuration, the lower open portion of the lens barrel 200 is closed by the image sensor 400 and is in an almost airtight state, and the interior of the lens barrel 200 is the internal space 17.

A slit 19 is formed at a predetermined height near the lower end of the lens barrel 200 (holder portion 202), and the slit 19 communicates the internal space 17 of the lens barrel with the outside.
The shape of the slit 19 viewed from the plane side is formed in, for example, a crank shape similar to that of the above-described embodiment, and air can be circulated without light being directly incident on the internal space 17 from the outside. Yes. In the above-described embodiment, a part of the slit 15 forms the communication hole 15A (see FIG. 3 and the like) as the communication path. However, in this configuration, the entire slit 19 forms the communication path as it is.
Although the image sensor 400 of this embodiment does not include a transparent cover, the image sensor 40 in which the transparent cover 42 is integrally attached to the sensor unit 41 as in the above-described embodiment (see FIG. 3) is used. The transparent cover 42 and the lens barrel 200 may be bonded to each other.

It is an external appearance perspective view of the camera module which concerns on this Embodiment. It is a disassembled perspective view of a camera module. It is a longitudinal cross-sectional view of a state where the camera module is mounted on a circuit board. It is a bottom view of a camera module. It is AA sectional drawing of FIG. It is an enlarged view of a communicating hole. It is explanatory drawing of the manufacturing process of a camera module. It is a longitudinal cross-sectional view of the camera module of a different structure.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 2 ... Camera module 10 ... Mount 10 (connection member), 13 ... Support plate part (filter support part), 15 ... Slit (gap), 15A ... Communication hole (communication path), 15a ... External surface opening part, 15b ... inner surface opening part, 19 ... slit (communication path), 22 ... imaging lens (optical element), 30 ... filter (filter member), 40, 400 ... image sensor (imaging member), 41 ... sensor part (imaging element) 42 ... Transparent cover (cover member)

Claims (8)

An image sensor that converts incident light into an electrical signal;
An optical element that focuses incident light on the imaging element;
A connecting member that connects the optical element and the imaging element;
With
The connection member is formed with a communication path that allows the internal space and the outside of the connection member to communicate with each other without allowing light to directly enter the internal space from the outside. The camera module. An image sensor that converts incident light into an electrical signal;
An optical element that focuses incident light on the imaging element;
A connecting member that connects the optical element and the imaging element;
With
The connection member has an inner surface opening that opens into the internal space of the connection member and an outer surface opening that opens to the outside of the connection member, so that air can flow without direct incidence of light from the outside into the internal space. A camera module characterized in that a communication path communicating with a possible bent path is formed.   2. The communication path is formed by a gap formed by cutting from an end of the connection member in a direction intersecting with a direction in which the internal space of the connection member communicates with the outside. Or the camera module in any one of 2.   The camera module according to claim 1, wherein the connecting member is formed integrally with the optical element. A cover member that transmits incident light to the image sensor;
The imaging element and the cover member are integrated to form an imaging member,
The camera module according to claim 1, wherein the imaging member is coupled to the connection member via the cover member.   The camera module according to claim 1, wherein a plurality of the communication paths are formed. An imaging element that converts incident light into an electrical signal and an optical element that condenses incident light on the imaging element are connected by a connecting member, and light is directly connected to the internal space and the outside of the connecting member to the connecting member. A method of manufacturing a camera module comprising a communication path that allows air to flow without being incident,
Forming a bent cross-sectional gap in which light is not directly incident on the internal space from the outside to the connection member to a position reaching the internal space from an end surface of the connection member;
Combining the connecting member and the imaging member;
A method for manufacturing a camera module. An image sensor that converts incident light into an electrical signal;
An optical element that focuses incident light on the imaging element;
A connecting member that connects the optical element and the imaging element;
A circuit board connected to the image sensor;
With
The connection member is formed with a communication path that allows the internal space and the outside of the connection member to communicate with each other without allowing light to directly enter the internal space from the outside. Imaging device.

Images