JP2020201327A - Lens unit and camera module - Google Patents

Abstract

To provide a lens unit and a camera module that can melt snow and the like adhering to the surface of an object side without heating a lens.SOLUTION: A lens unit 100 comprises: a lens tube 10 formed in a cylindrical shape; a plurality of lenses 1 to 5 aligned inside the lens tube along an axial direction of the lens tube; a sealing member 30 arranged in a diameter reduction part formed on an end of the lens tube at an object side; a cover glass 50, arranged on the object side of the sealing member 30, in which a heater part 60 is formed on the surface at an image side; and a lid member 40 mounted to the end of the lens tube at the object side while holding an outer periphery of the cover glass. The heater part 60 has a transparent conductive film 61, and a pair of electrode parts 26 formed on the transparent conductive film.SELECTED DRAWING: Figure 2

Description

The present invention relates to a lens unit and a camera module.

Cameras installed outdoors, such as surveillance cameras and in-vehicle cameras, are known. In such a camera installed outdoors, ice and snow may adhere to the front surface of the lens when it snows. In addition, when the outside air temperature falls below freezing, the front surface of the lens may freeze and frost may adhere. In that case, the captured image becomes unclear due to the deposits on the front surface of the lens, and the imaging performance of the camera deteriorates.

In recent years, a camera (vehicle-mounted camera) has been mounted on a vehicle, and the image captured by the vehicle-mounted camera is used for functions such as an automatic braking function and an automatic driving function. These functions are functions for controlling the running of the vehicle, and deterioration of the imaging function of the in-vehicle camera may lead to the occurrence of an accident or the like. Therefore, there is a demand for the development of a camera having a snow melting function that melts the deposits adhering to the front surface of the lens. As an example of a camera having a snow melting function, for example, there is one disclosed in Patent Document 1.

Japanese Unexamined Patent Publication No. 2004-325603

By the way, in the camera disclosed in Patent Document 1, a film-shaped heater is provided on the image-side surface of the flange portion of the first lens located closest to the object side. As described above, when the lens is directly heated, there is a possibility that the lens becomes hot and deformed, and the optical performance of the lens unit deteriorates due to a change in the refractive index and a change in the dimensions due to the temperature rise.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a lens unit and a camera module capable of melting snow or the like without directly heating the lens.

In order to solve the above problems, the lens unit of the present invention is used.
The lens barrel formed in a cylindrical shape and
A plurality of lenses arranged side by side along the axial direction of the lens barrel inside the lens barrel,
A seal member arranged in a reduced diameter portion formed at the end of the lens barrel on the object side, and
A cover glass arranged on the object side of the sealing member and having a heater portion formed on the image side surface.
A lid member attached to the end of the lens barrel on the object side while holding the outer peripheral portion of the cover glass is provided.
The heater portion is characterized by having a transparent conductive film and a pair of electrode portions formed on the transparent conductive film.

Further, the lens unit of the present invention is
The lens barrel formed in a cylindrical shape and
A plurality of lenses arranged side by side along the axial direction of the lens barrel inside the lens barrel,
A cylindrical holder attached to the end of the lens barrel on the object side,
A seal member arranged in a reduced diameter portion formed at the end of the holder on the object side,
A cover glass arranged on the object side of the sealing member and having a heater portion formed on the image side surface.
A lid member attached to the end of the holder on the object side while holding the outer peripheral portion of the cover glass is provided.
The heater portion is characterized by having a transparent conductive film and a pair of electrode portions formed on the transparent conductive film.

According to such a configuration, a heater portion composed of a transparent conductive film and a pair of electrode portions formed on the transparent conductive film is formed on the image side surface of the cover glass located on the object side of the lens. Therefore, it is possible to melt the snow or the like adhering to the surface of the cover glass. As a result, the snow melting function can be realized without heating the lens, and it is possible to prevent deterioration of the optical performance of the lens unit due to deformation of the lens at high temperature, change in refractive index due to temperature rise, dimensional change, and the like.

Further, in the configuration of the present invention, the transparent conductive film is formed in a circular shape, and the pair of electrode portions are formed point-symmetrically with the center of the transparent conductive film as a symmetrical center. And.

Further, in the configuration of the present invention, the transparent conductive film has a notch portion formed in a circular shape and the transparent conductive film is not formed on a part on the outer peripheral side, and the pair of electrode portions are formed. A portion in which one electrode portion is formed on the transparent conductive film, the other electrode portion is formed so as to straddle the notch portion and the transparent conductive film, and is formed on the transparent conductive film. The electrode portion of the above is formed point-symmetrically with the center of the transparent conductive film as the center of symmetry.

Further, in the configuration of the present invention, the transparent conductive film is formed in a square shape, and one of the electrode portions of the pair of electrode portions is formed on a predetermined side of the transparent conductive film, and the other electrode portion is formed. The portion is formed on the side of the transparent conductive film facing the predetermined side.

Further, in the configuration of the present invention, the transparent conductive film is formed in a square shape, and one of the electrode portions of the pair of electrode portions is formed on a predetermined side of the transparent conductive film, and the other electrode portion is formed. The portion is formed so as to straddle the outside of the side orthogonal to the predetermined side of the transparent conductive film and the top of the side of the transparent conductive film facing the predetermined side.

According to such a configuration, since the pair of electrode portions are formed symmetrically on the transparent conductive film, a current flows uniformly through the transparent conductive film, and the transparent conductive film generates heat uniformly. Can be done. As a result, it is possible to eliminate the temperature unevenness of heating the cover glass, and it is possible to suppress the deterioration of the optical performance of the lens unit that occurs when the temperature unevenness occurs.

Further, in the configuration of the present invention, the lens barrel includes a wiring portion connected to the pair of electrode portions of the heater portion, the lens barrel has a through hole formed along the axial direction, and the wiring portion has a through hole. , It is characterized in that it is pulled out to the image side through the through hole.

According to such a configuration, since the wiring portion is pulled out to the image side through the through hole of the lens barrel provided along the axial direction, the wiring portion is moved to the image side through the outer peripheral side of the lens barrel. It is possible to prevent the problem of deterioration of the sealing property of the sealing member that occurs when the material is pulled out.

Further, in the configuration of the present invention, the wiring portion is characterized by two lead wires, and the through holes are circular through holes formed at two locations. According to such a configuration, the lens barrel may be provided with two circular through holes, so that the processing can be facilitated.

Further, in the configuration of the present invention, the wiring portion is a flexible printed circuit board, and the through hole is an arc-shaped through hole formed at one place. According to such a configuration, one FPC may be inserted through one through hole, so that workability is improved.

Further, in the configuration of the present invention, the flexible printed circuit board is further provided with a thermistor having a self-temperature control function. According to such a configuration, the thermistor has a self-temperature control function, that is, a function in which the resistance value increases when the temperature rises and reaches a predetermined temperature, so that ON / OFF is not controlled. A constant temperature can be maintained.

Further, in the configuration of the present invention, the heater portion is characterized in that the transparent conductive film and the protective film covering the electrode portion are formed. According to such a configuration, since the transparent conductive film and the protective film covering the electrode portion are formed, the insulating property of the heater portion can be ensured and the heater portion can be prevented from being damaged.

The camera module of the present invention is characterized by including a lens unit having the above configuration and an image pickup element that captures an image formed by the lens unit. According to such a configuration, the camera module can have the same effect as the lens unit of the present invention described above.

According to the present invention, since snow and the like can be melted without heating the lens, it is possible to prevent deterioration of the optical performance of the lens unit due to deformation of the lens at a high temperature.

It is an axial sectional view of the camera module which concerns on 1st Embodiment of this invention. The same is an axial sectional view of the lens unit. The cover glass is viewed from the image side, and is an explanatory view of the heater portion. The cover glass is viewed from the image side, and is an explanatory view showing a modified example (No. 1) of the heater portion. The cover glass is viewed from the image side, and is an explanatory view showing a modified example (No. 2) of the heater portion. The cover glass is viewed from the image side, and is an explanatory view showing a modified example (No. 3) of the heater portion. The same is a view of the cover glass viewed from the image side, and is a view of the cover glass in a state where a lead wire as a wiring portion is connected, as viewed from the side surface. The same shows a part of the lens barrel seen from the object side, and is a diagram for explaining a through hole for passing a lead wire. It is the figure which looked at the cover glass in the state which FPC as a wiring part was connected from the side. The same shows a part of the lens barrel seen from the object side, and is a diagram for explaining a through hole for passing the FPC. It is an axial sectional view of the camera module which concerns on 2nd Embodiment of this invention. The same is an axial sectional view of the lens unit.

(First Embodiment)
Hereinafter, the first embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is an axial sectional view of the camera module 500 according to the first embodiment. Note that in FIG. 1, some hatching indicating that the cross section is used is omitted.
The camera module 500 includes a lens unit 100, an upper camera case 310, a lower camera case 320, a seal member 330, an image sensor 340, a substrate 350, and the like.

In the lens unit 100, an optical filter 8 is provided at the end of the image side (imaging side) where the first lens 1, the second lens 2, the third lens 3, the fourth lens 4, and the fifth lens 5 form an image. It is arranged. Further, an image sensor 340 is arranged on the image side of the lens unit 100 at a position facing the optical filter 8, and the image sensor 340 is an image formed by the first lens 1 to the fifth lens 5. To image.
Further, the lens unit 100 is arranged so that the end portion on the side opposite to the image side, that is, the end portion on the object side faces the image pickup target. The camera module 500 including the lens unit 100 forms an image of an object on the image side, and is used, for example, in an in-vehicle camera mounted on an automobile. The in-vehicle camera includes, for example, a rear view camera mounted on a side mirror of the vehicle to take an image of the rear of the vehicle.

FIG. 2 is an axial sectional view of the lens unit 100. In FIG. 2, some hatching indicating that the cross section is used is omitted. The lens unit 100 includes a lens barrel 10, a first lens 1, a second lens 2, a third lens 3, a fourth lens 4, a fifth lens 5, a plurality of spacers 6, a plurality of apertures 7, an optical filter 8, and a sealing member. 9. The lid member 19, the seal member 30, the lid member 40, the cover glass 50, the heater portion 60, the wiring portion 70, and the like are provided.

The lens barrel 10 is a cylindrical member and is made of a metal such as stainless steel or an aluminum alloy. The first lens 1 is a glass lens having a substantially circular shape, and the second lens 2 to the fifth lens 5 are glass or resin lenses having a substantially circular shape. The first lens 1 to the fifth lens 5 are arranged inside the lens barrel 10 with their optical axes aligned with each other. The first lens 1 to the fifth lens 5 are positioned in a direction orthogonal to the optical axis direction by abutting the outer peripheral surface thereof with the inner peripheral surface of the lens barrel 10.
The diaphragm 7 is an annular member, and is made of, for example, metal. The diaphragm 7 is arranged between the lenses inside the lens barrel 10. The diaphragm 7 includes an aperture diaphragm that limits the amount of transmitted light and determines an F value that is an index of brightness, or a light-shielding diaphragm that blocks light rays that cause ghosts and light rays that cause aberrations.
The spacer 6 is an annular member, and is made of, for example, metal. The spacer 6 is arranged between the lenses inside the lens barrel 10. The inner peripheral surface of the spacer 6 is formed in a screw shape, whereby the processing speed of time-consuming cutting can be increased, productivity can be improved, and ghosting can be effectively prevented. ..
The optical filter 8 is, for example, an infrared cut filter formed in a circular shape. The optical filter 8 is arranged for the purpose of removing a specific frequency component. The optical filter 8 is fixed to the end surface of the lens barrel 10 on the image side in a recess formed so as to be recessed toward the object side, for example, by adhesion. As the adhesive, an ultraviolet curable resin or the like is used.

The lens barrel 10 is provided with a small-diameter tube portion 11 for holding the first lens 1 to the fifth lens 5, etc., and a hakama-shaped object extending outward in the radial direction and toward the object side of the small-diameter tube portion 11. It is provided with a large-diameter tubular portion 12 for holding a cover glass 50 arranged on the side.
The inner peripheral surface of the small-diameter tubular portion 11 on the most image side is provided with a support portion 11a that protrudes inward in the radial direction and is annular when viewed from the axial direction. The image-side surface of the outer peripheral portion of the fifth lens 5 is in contact with the support portion 11a. The outer peripheral portion of the lens is a portion (flange portion) formed on the outer peripheral side of the effective diameter of the lens.
Further, a male screw portion 11b is provided on the outer peripheral surface of the small diameter tubular portion 11 on the most object side.
The large-diameter tubular portion 12 is formed so as to extend from the outer peripheral surface (substantially central portion) of the small-diameter tubular portion 11 on the object side in a hakama shape toward the outer side in the radial direction and the object side. The tip of the large-diameter tubular portion 12 (the end on the object side) protrudes toward the object from the end of the small-diameter tubular portion 11 on the object side and the surface of the first lens 1 on the object side. A male screw portion 12a is formed on the outer peripheral surface of the large-diameter tubular portion 12 on the most object side. Further, a flange-shaped flange portion 13 projecting outward in the radial direction is formed on the outer peripheral surface of the large-diameter tubular portion 12 on the most image side.

The lid member 19 is a lid-shaped member formed in a cylindrical shape, and is made of a metal such as an aluminum alloy. The inner peripheral surface of the lid member 19 on the most object side is provided with a first lens holding portion 19b that projects inward in the radial direction and has an inner diameter smaller than that of the inner peripheral surface on the image side. The inner diameter of the first lens holding portion 19b is smaller than the outer diameter of the first lens 1. Further, on the inner peripheral surface of the lid member 19 on the image side, a female screw portion 19a that can be screwed with the male screw portion 11b is provided. The lid member 19 is attached to the end of the lens barrel 10 (small diameter cylinder portion 11) on the object side by screwing, and the end on the inner peripheral side of the first lens holding portion 19b hits the outer peripheral portion of the first lens 1. It is designed to come into contact. As a result, the parts housed inside the lens barrel 10 (small diameter cylinder portion 11) are sandwiched between the lid member 19 and the support portion 11a so that no gap is formed between the parts. It has become.

The image-side outer peripheral surface of the first lens 1 is provided with a diameter-reduced portion 1a having an outer diameter smaller than that of the object-side outer peripheral surface (formed by narrowing the diameter). An O-ring as a seal member 9 is arranged between the reduced diameter portion 1a and the inner peripheral surface of the lens barrel 10 (small diameter cylinder portion 11) on the object side. The seal member 9 is formed of, for example, elastically deformable rubber, and is arranged in a compressed (pressed) state between the lens barrel 10 and the first lens 1. As a result, the end portion of the lens barrel 10 (small diameter cylinder portion 11) on the object side is sealed.

The lid member 40 is a lid-shaped member formed in a cylindrical shape, and is made of a metal such as aluminum. The inner peripheral surface of the lid member 40 on the most object side is provided with a cover glass holding portion 40b that projects inward in the radial direction and has an inner diameter smaller than that of the inner peripheral surface on the image side. The inner diameter of the cover glass holding portion 40b is smaller than the outer diameter of the cover glass 50. Further, on the inner peripheral surface of the lid member 40 on the image side, a female screw portion 40a that can be screwed with the male screw portion 12a is provided. The lid member 40 is attached to the end of the lens barrel 10 (large diameter cylinder portion 12) on the object side by screwing, and the image-side surface of the cover glass holding portion 40b abuts on the outer peripheral portion of the cover glass 50 (cover). It holds the outer peripheral portion of the glass 50). The cover glass 50 is sandwiched and held between the lid member 40 and the end of the lens barrel 10 (large diameter cylinder portion 12) on the object side.

The outermost peripheral surface of the large-diameter tubular portion 12 on the most object side is provided with a reduced diameter portion 12b having an outer diameter smaller than that of the outer peripheral surface on the image side (formed by narrowing the diameter). The reduced diameter portion 12b opens outward in the radial direction and toward the object side. An O-ring as a seal member 30 is arranged on the reduced diameter portion 12b. The seal member 30 is formed of, for example, elastically deformable rubber, and is arranged in a compressed (pressed) state between the cover glass 50, the lid member 40, and the lens barrel 10 (large diameter cylinder portion 12). .. As a result, the end portion of the lens barrel 10 (large diameter tube portion 12) on the object side is sealed so that water, dust, and the like do not enter the inside of the lens barrel 10.

The cover glass 50 is a circular transparent glass arranged on the object side of the lens unit 100. As the material of the cover glass 50, a white plate glass (transparent) such as borosilicate glass having a stable refractive index and excellent acid resistance, alkali resistance, water resistance and the like is preferable. The thickness of the cover glass 50 is preferably 0.2 mm or more and 1.2 mm or less. If the thickness is thinner than 0.2 mm, cracks or the like may occur when the surface is strongly pressed. Further, if the thickness is thicker than 1.2 mm, aberration may occur in the camera image, and the peripheral image may be blurred.

Next, the heater portion 60 formed on the image-side surface of the cover glass 50 will be described with reference to FIG. The heater portion 60 is provided to heat the cover glass 50. The heater unit 60 includes a transparent conductive film 61 and a pair of electrode units 62.

The transparent conductive film 61 is formed on the image-side surface of the cover glass 50 so as to have a uniform circular shape. The transparent conductive film 61 has conductivity and generates heat when energized. In other words, the transparent conductive film 61 has a heater function. As the transparent conductive film 61, an ITO film, that is, an ITO (In ₂ O ₃ : Sn) having an In ₂ O ₃ diameter is preferable. Incidentally, as the transparent conductive film 61, the ZnO diameter AZO (ZnO: Al), GZO (ZnO: Ga), SnO 2 based _{ATO (SnO 2: Sb),} FTO (SnO 2: F) or the like may be used .. That is, it may be a transparent and conductive film. By forming the transparent conductive film 61 by thin-film deposition or sputtering, a highly reliable and strong film can be imparted to the cover glass 50.

The electrode portion 62 is formed on the transparent conductive film 61 in a linear shape with a predetermined width, and is provided so as to have an arc shape (approximately 1/4 circle), for example. As the material of the electrode portion 62, Ni, Cu, Au or the like having low electric resistance is preferable. As a method for forming the electrode portion 62, there is screen printing using a paste electrode material in addition to thin film deposition or sputtering. The electrode portion 62 is provided at a location outside the range through which the light beam passes, that is, at a location that does not affect the optical performance of the lens unit 100. The electrode portions 62 are provided at two locations, one electrode portion 62 is for the positive electrode and the other electrode portion 62 is for the negative electrode. A connecting portion 62a having a circular pattern is provided at the end of each electrode portion 62. A wiring unit 70, which will be described later, is connected to the connection unit 62a, and power is supplied to the electrode unit 62 via the wiring unit 70. The relationship between the electrode portion 62 and the transparent conductive film 61 is such that when power is supplied to the electrode portion 62, a current flows uniformly (uniformly) through the transparent conductive film 61. In the above embodiment, the pair of electrode portions 62 are provided so as to be point-symmetrical with the center O of the circular transparent conductive film 61 as the center of symmetry. Since the electrode portion 62 is formed point-symmetrically, when electric power is supplied to the electrode portion 62, a current flows uniformly through the transparent conductive film 61, and the transparent conductive film 61 generates heat uniformly. .. That is, the temperature unevenness does not occur when the transparent conductive film 61 generates heat. When the transparent conductive film 61 generates heat, the cover glass 50 is heated, and snow, frost, ice, etc. adhering to the surface of the cover glass 50, that is, the surface on the object side and exposed to the outside, melts. There is. If the heat generated by the transparent conductive film 61 is uneven in temperature, the optical performance of the lens unit 100 may deteriorate due to the uneven snow melting range and snow melting time of the cover glass 50.

Further, a protective film (not shown) may be further formed on the transparent conductive film 61 for the purpose of ensuring insulation and preventing scratches. As the protective film, for example, a SiO ₂ film or the like is used. At that time, the connection portion 62a (the feeding portion in the electrode portion 62) to which the wiring portion 70 must be connected is masked, and a protective film is formed by vapor deposition or sputtering. As the protective film, an AR film (antireflection film) for the purpose of antireflection may be used.

Next, a modified example (No. 1) of the heater unit 60 will be described with reference to FIG.
The transparent conductive film 61 is provided with a shape in which a part of the outer peripheral side of the circular shape is cut out over about 1/4 yen, that is, a cutout portion in which the transparent conductive film 61 is not formed. Two connecting portions 62a of the electrode portion 62 are formed so as to be adjacent to each other along the circumferential direction on one side within the range of the notched portion.
One electrode portion 62 is formed on the transparent conductive film 61 so as to form an arc shape having a length of about 1/4 circle counterclockwise from the one connecting portion 62a.
The other electrode portion 62 is formed so as to form an arc shape having a length of about a semicircle clockwise from the other connecting portion 62a. At this time, the arc of about half of the other electrode portion 62 on the connecting portion 62a side is located within the range of the notch portion, and the electrode is placed on the transparent conductive film 61 in about half of the side far from the connecting portion 62a. A portion 62 is formed. In other words, the other electrode portion 62 is formed so as to straddle the notch portion of the transparent conductive film 61 and the top of the transparent conductive film 61. Even in this case, the relationship between the electrode portions 62 provided on the transparent conductive film 61 is point-symmetrical. That is, the electrode portion 62 of the portion formed on the transparent conductive film 61 is provided so as to be point-symmetrical with the center O of the transparent conductive film 61 as the center of symmetry. It can also be said that the symmetrical electrode portion 62 is formed by making the forming range of the transparent conductive film 61 different from that of the asymmetric electrode portion 62.
As a result, when electric power is supplied to the electrode portion 62, a current flows uniformly through the transparent conductive film 61, and the transparent conductive film 61 generates heat uniformly. With such a configuration, it is possible to uniformly pass an electric current through the transparent conductive film 61 while bringing the two connecting portions 62a close to each other. By bringing the two connecting portions 62a close to each other (providing them adjacent to each other), it is possible to obtain an effect that, for example, the work of connecting the wiring portions 70 becomes easier.

Next, a modified example (No. 2) of the heater unit 60 will be described with reference to FIG.
The transparent conductive film 61 is uniformly formed in a quadrangular shape on the image-side surface of the cover glass 50. The electrode portion 62 is formed on a pair of opposite sides of the transparent conductive film 61. That is, one electrode portion 62 is formed on a predetermined side of the transparent conductive film 61, and the other electrode portion 62 is formed on a side of the transparent conductive film 61 facing the predetermined side. Further, the connecting portion 62a is formed at an end portion on the same side of the electrode portion 62. The pair of electrode portions 62 are formed so as to be symmetrical (line symmetric) with respect to the center line X of the transparent conductive film 61. Even with such a configuration, a current flows uniformly through the transparent conductive film 61, and the transparent conductive film 61 generates heat uniformly.

Next, a modified example (No. 3) of the heater unit 60 will be described with reference to FIG.
The transparent conductive film 61 is uniformly formed in a quadrangular shape on the image-side surface of the cover glass 50. Further, two connecting portions 62a of the electrode portion 62 are formed so as to be adjacent to each other in the vicinity of a predetermined corner of the transparent conductive film 61.
One electrode portion 62 is formed from one connection portion 62a on a predetermined side of the rectangular transparent conductive film 61.
The other electrode portion 62 is formed from the other connecting portion 62a so as to straddle the outside of the side orthogonal to the predetermined side of the transparent conductive film 61 and the top of the side facing the predetermined side. That is, the other electrode portion 62 is formed so that the two straight portions are orthogonal to each other, one straight portion is formed outside the transparent conductive film 61 along one side of the transparent conductive film 61, and the other straight portion is formed. Is formed on one side of the transparent conductive film 61. Even in this case, the relationship between the electrode portions 62 provided on the transparent conductive film 61 is symmetrical. That is, the electrode portion 62 of the portion formed on the transparent conductive film 61 is symmetrical (line symmetric) with respect to the center line X of the transparent conductive film 61.
As a result, when electric power is supplied to the electrode portion 62, a current flows uniformly through the transparent conductive film 61, and the transparent conductive film 61 generates heat uniformly. With such a configuration, it is possible to uniformly pass an electric current through the transparent conductive film 61 while bringing the two connecting portions 62a close to each other.

As the wiring portion 70, a lead wire (lead wire) or an FPC (flexible printed circuit board) is used. The wiring unit 70 is provided to supply electric power from the outside to the heater unit 60. The wiring unit 70 can also be said to be a power supply means to the heater unit 60 (connection unit 62a).
FIG. 7 is a diagram showing a state in which two conducting wires as wiring portions 70 are connected to the heater portion 60 of the cover glass 50. One lead wire is connected to one connecting portion 62a, and the other lead wire is connected to the other connecting portion 62a by soldering or the like. The conducting wire is a metal wire for passing an electric current, and is coated with, for example, PVC (polyvinyl chloride).
FIG. 8 is a diagram showing a part of the lens barrel 10 seen from the object side. The lens barrel 10 is provided with through holes 14 for guiding the two lead wires as the wiring portions 70 toward the image side in parallel with the axial direction. When a conducting wire is used as the wiring portion 70, the through holes 14 are formed in a circular shape (round hole) at two locations corresponding to the two conducting wires and having a diameter corresponding to the diameter of the conducting wires. As shown in FIG. 2, the through hole 14 is provided at a position on the lens barrel 10 that is radially outside the small diameter cylinder portion 11 and is radially inside the large diameter cylinder portion 12. One end of the lead wire as the wiring portion 70 is connected to the heater portion 60, and the other end is drawn out to the image side of the lens barrel 10 (lens unit 100) through the through hole 14, and is provided with a power supply circuit. It is connected to 350 (see FIG. 1). According to such a configuration, it is possible to prevent the problem of deterioration of the sealing property of the sealing member 30 that occurs when the wiring portion 70 is pulled out to the image side through the outer peripheral side of the lens barrel 10.

FIG. 9 is a diagram showing a state in which FPCs (Flexible printed circuits) as wiring portions 70 are connected to the heater portion 60 of the cover glass 50. The material of the FPC is, for example, a PET film or a polyimide film, and an electric circuit is wired in the film. The FPC is connected to, for example, an ACF (Anisotropic Conductive Film) to the connecting portion 62a of the heater portion 60. In the ACF connection, crimping and heating are applied.
FIG. 10 is a diagram showing a part of the lens barrel 10 seen from the object side. When the FPC is used as the wiring portion 70, the through hole 14 is formed in an arc shape at one place in a size corresponding to the width and thickness of the FPC. One end of the FPC as the wiring portion 70 is connected to the heater portion 60, and the other end is pulled out to the image side of the lens barrel 10 (lens unit 100) through the through hole 14, and the substrate is provided with a power supply circuit. It is connected to 350 (see FIG. 1). A connector is connected to the other end of the FPC.

When an FPC is used as the wiring portion 70, a thermistor may be mounted (arranged) on the FPC. The thermistor is provided, for example, on the FPC near the connection portion with the heater portion 60. This thermistor has a PTC (Positive Temperature Coefficient) function (PTC characteristic), that is, a self-temperature control function, and can keep the heating temperature of the heater unit 60 constant. The thermistor is an electronic component having a PTC function, and exhibits a substantially constant resistance value near room temperature, but the resistance value rises sharply when a predetermined temperature is exceeded. Generally, a chip type thermistor is often used, and the PTC property is generally obtained by adding a trace amount of rare earth element to barium titanate. This thermistor has the property of detecting the ambient temperature, and when it reaches a specific temperature (detection temperature), the resistance rapidly increases and the flowing current is reduced. A thermistor having this characteristic can be used for a constant temperature heating element, a heater, etc., and can maintain a constant temperature without controlling ON / OFF. By arranging the thermistor, the flowing current can be controlled without providing a control circuit.
Further, for example, by inserting a thermistor in series in the lead wire, the current flowing through the heater unit 60 can be controlled without the need for a control circuit.
As another method, the voltage of the thermista is monitored by a monitor circuit, and the output of the monitor circuit is A / D converted by the control circuit and input to the internal microcomputer to control the voltage to be applied to the heater unit 60. It is also possible to do this. As a result, highly accurate temperature control can be performed. It should be noted that the control circuit may be configured by an analog circuit instead of a digital circuit.

As shown in FIG. 1, the upper camera case 310 has a shape that covers the periphery of the lens unit 100 together with the lower camera case 320 while exposing a part of the lens unit 100 to the object side through a circular opening. Have. An O-ring as a sealing member 330 is arranged between the upper camera case 310 and the flange portion 13 of the lens barrel 10, whereby the inside of the camera case is ensured to be airtight. The image sensor 340 and the substrate 350 are arranged inside the lower camera case 320 at positions facing the image side of the lens unit 100.

The image-side opening of the through hole 14 is provided at a position on the image side of the seal portion formed by the upper camera case 310 and the seal member 330 in the axial direction of the lens barrel 10. Since the inside of the camera case is airtight, water does not enter the inside of the lens barrel 10 through the through hole 14. As a result, it is not necessary to insulate the heater unit 60. Further, since it is not necessary to insulate the heater portion 60, cost reduction can be realized.

The camera module 500 may include a signal processing circuit, a flexible wiring sheet, a connector, and the like, in addition to the lens unit 100, the upper camera case 310, the lower camera case 320, the seal member 330, the image sensor 340, and the substrate 350. The camera module 500 includes at least a lens unit 100 and an image sensor 340.

The camera module 500 operates as follows. The light incident from the object side is incident on the image sensor 340 via the lens group of the lens unit 100. The image sensor 340 converts the incident image into an electric signal. The signal processing circuit performs signal processing (A / D conversion, image correction processing, etc.) on the electric signal from the image sensor 340. The electric signal output from the signal processing circuit is connected to an external electronic device via a flexible wiring sheet and a connector.

In the lens unit 100 (camera module 500) according to the present embodiment, the snow melting function can be realized without heating the lens, and the optical performance of the lens unit 100 deteriorates due to deformation of the lens at a high temperature or the like. Can be prevented.

Further, since the captured image is not blurred due to the adhesion of snow or the like to the cover glass 50, it is possible to prevent deterioration of the imaging performance of the lens unit 100. Therefore, for example, when the lens unit 100 is used for an in-vehicle camera, snow or the like adhering to the surface of the cover glass 50 (the surface on the object side) affects the automatic braking function, the automatic driving function, and the like of the vehicle. Can be prevented. As a result, it is possible to provide the driver with comfortable driving and ensure the safety of the occupants.

The angle of view of the camera module 500 as a camera is preferably 110 ° or less. If the angle of view exceeds 110 °, the cover glass 50 becomes extremely large, which is not practical. In addition, there is a problem that aberration occurs in the camera image and the image is blurred in the peripheral portion.

(Second Embodiment)
Next, a second embodiment of the present invention will be described.
FIG. 11 is an axial sectional view of the camera module 600 according to the second embodiment. Note that in FIG. 11, some hatching indicating that the cross section is used is omitted. Further, FIG. 12 is an axial sectional view of the lens unit 100 in the camera module 600. Note that in FIG. 12, some hatching indicating that the cross section is used is omitted.
Hereinafter, configurations having the same or equivalent functions as those described in the first embodiment and the second embodiment are designated by the same reference numerals, and the description thereof will be omitted or simplified.
The camera module 600 includes a lens unit 100, an upper camera case 310, a lower camera case 320, a seal member 330, an image sensor 340, a substrate 350, and the like.

The lens unit 100 includes a lens barrel 10, a holder 20, a first lens 1, a second lens 2, a third lens 3, a fourth lens 4, a fifth lens 5, a plurality of spacers 6, a plurality of apertures 7, and an optical filter 8. , A seal member 9, a lid member 19, a seal member 30, a lid member 40, a cover glass 50, a heater portion 60, a wiring portion 70, and the like.
In the first embodiment, as shown in FIG. 2, the lens barrel 10 is composed of a small diameter cylinder portion 11 and a large diameter cylinder portion 12. In the second embodiment, the lens barrel 10 is composed of only a portion corresponding to the small diameter cylinder portion 11, and the portion corresponding to the large diameter cylinder portion 12 is a holder 20 of a separate member. Further, a flange-shaped flange portion 18 projecting outward in the radial direction is formed on the outer peripheral surface of the lens barrel 10 on the object side.

The holder 20 is a cylindrical member and is made of metal. The holder 20 is provided so that the cover glass 50 can be arranged on the object side of the lens unit 100.
The holder 20 is formed inside with an inner diameter capable of accommodating a portion of the lens barrel 10 on the object side. The end of the holder 20 on the object side protrudes toward the object from the end of the lens barrel 10 on the object side and the surface of the first lens 1 on the object side. Further, the image-side end of the holder 20 is in contact with the flange portion 18 of the lens barrel 10.

Further, a male screw portion 21 is formed on the outer peripheral surface of the holder 20 on the most object side. The male screw portion 21 can be screwed with the female screw portion 40a of the lid member 40.
Further, a flange-shaped flange portion 22 that projects outward in the radial direction is formed on the outer peripheral surface of the holder 20 on the most image side. A seal member 330 is arranged between the flange portion 22 and the upper camera case 310 to form a seal portion.

Further, the outer peripheral surface of the holder 20 on the most object side is provided with a reduced diameter portion 23 having an outer diameter smaller than that of the outer peripheral surface on the image side (formed by reducing the diameter). The reduced diameter portion 23 is open toward the outside in the radial direction and toward the object side. An O-ring as a seal member 30 is arranged on the reduced diameter portion 23. The seal member 30 is formed of, for example, elastically deformable rubber, and is arranged in a compressed (pressed) state between the cover glass 50, the lid member 40, and the holder 20. As a result, the end portion of the holder 20 on the object side is sealed so that water, dust, or the like does not enter the space inside the cover glass 50.

The lens unit 100 (camera module 600) according to the present embodiment has the following effects in addition to the effects of the first embodiment. That is, when the lens barrel 10 and the holder 20 are made into separate parts, the shape of the parts is not complicated as in the case where they are integrally formed, the processing becomes easier, and the productivity is improved.

In the present invention, within the scope of the invention, it is possible to freely combine each embodiment, modify any component of each embodiment, or omit any component in each embodiment. ..

1, 2, 3, 4, 5 Lens 10 Lens barrel 12b Reduced diameter part 14 Through hole 20 Holder 23 Reduced diameter part 30 Seal member 40 Lid member 50 Cover glass 60 Heater part 61 Transparent conductive film 62 Electrode part 70 Wiring part 500, 600 camera module

Claims (12)

The lens barrel formed in a cylindrical shape and
A plurality of lenses arranged side by side along the axial direction of the lens barrel inside the lens barrel,
A seal member arranged in a reduced diameter portion formed at the end of the lens barrel on the object side, and
A cover glass arranged on the object side of the sealing member and having a heater portion formed on the image side surface.
A lid member attached to the end of the lens barrel on the object side while holding the outer peripheral portion of the cover glass is provided.
The lens unit is characterized by having a transparent conductive film and a pair of electrode portions formed on the transparent conductive film. The lens barrel formed in a cylindrical shape and
A plurality of lenses arranged side by side along the axial direction of the lens barrel inside the lens barrel,
A cylindrical holder attached to the end of the lens barrel on the object side,
A seal member arranged in a reduced diameter portion formed at the end of the holder on the object side,
A cover glass arranged on the object side of the sealing member and having a heater portion formed on the image side surface.
A lid member attached to the end of the holder on the object side while holding the outer peripheral portion of the cover glass is provided.
The lens unit is characterized by having a transparent conductive film and a pair of electrode portions formed on the transparent conductive film. The transparent conductive film is formed in a circular shape.
The lens unit according to claim 1 or 2, wherein the pair of electrode portions are formed point-symmetrically with the center of the transparent conductive film as a symmetrical center. The transparent conductive film is formed in a circular shape, and has a notch portion on the outer peripheral side where the transparent conductive film is not formed.
In the pair of electrode portions, one electrode portion is formed on the transparent conductive film, and the other electrode portion is formed so as to straddle the notch portion and the transparent conductive film. The lens unit according to claim 1 or 2, wherein the electrode portion of the portion formed above is formed point-symmetrically with the center of the transparent conductive film as the center of symmetry. The transparent conductive film is formed in a quadrangular shape.
In the pair of electrode portions, one electrode portion is formed on a predetermined side of the transparent conductive film, and the other electrode portion is formed on a side of the transparent conductive film facing the predetermined side. The lens unit according to claim 1 or 2, wherein the lens unit is provided. The transparent conductive film is formed in a quadrangular shape.
In the pair of electrode portions, one electrode portion is formed on a predetermined side of the transparent conductive film, and the other electrode portion is outside the side orthogonal to the predetermined side of the transparent conductive film and the transparent. The lens unit according to claim 1 or 2, wherein the conductive film is formed so as to straddle the side facing the predetermined side of the conductive film. A wiring portion connected to the pair of electrodes of the heater portion is provided.
The lens barrel has a through hole formed along the axial direction.
The lens unit according to any one of claims 1 to 6, wherein the wiring portion is pulled out to the image side through the through hole. The wiring part is two conducting wires.
The lens unit according to claim 7, wherein the through holes are circular through holes formed at two locations. The wiring portion is a flexible printed circuit board.
The lens unit according to claim 7, wherein the through hole is an arc-shaped through hole formed at one location. The lens unit according to claim 9, wherein a thermistor having a self-temperature control function is further arranged on the flexible printed circuit board. The lens unit according to any one of claims 1 to 10, wherein a transparent conductive film and a protective film covering the electrode portion are formed on the heater portion. A camera module comprising the lens unit according to any one of claims 1 to 11 and an image pickup element for capturing an image formed by the lens unit.

Images