KR101206716B1 - Camera module with function of autofocus - Google Patents

Abstract

It relates to a camera module having an autofocus function. The camera module includes a lens portion, a coil portion, at least a pair of magnets, yokes, a head, and a base. The lens unit includes at least one lens. The coil portion is coupled around the lens portion. The magnets are arranged to face each other in pairs with the coil portion therebetween. Yokes are attached to each outer side of the magnets. The head has head incision grooves for respectively inserting magnets, and alignment supports for aligning and supporting each side of the magnets in each of the head incision grooves. The base has base cutting grooves each defining the yoke insertion holes together with the head cutting grooves so that the yokes are inserted in the engaged state.

Description

Camera module with function of autofocus

The present invention relates to a camera module, and more particularly, to a camera module mounted on a terminal or the like and having a function of automatically focusing toward a subject.

In general, a camera module mounted in a small terminal such as a digital camera or a mobile phone employs an image sensor such as a charge coupled device (CCD) or a complementary metal oxide semiconductor (CMOS) to convert an optical signal into an electrical signal. Implement

When the camera module has an autofocus function for automatically focusing on a subject, the camera module includes an autofocus driver that can vary the position of the lens with respect to the image sensor, for example, an autofocus driver of a voice coil motor (VCM) system.

The VCM-type autofocus driver is a magnet that generates a magnetic field so as to face a coil supplied with a current, thereby changing the position of the lens by a Lorentz force generated perpendicular to the magnetic field and the current. Here, the coil may be installed to move together with the lens in the camera module, and the magnet may be installed to be fixed in the camera module.

The above-described camera module is installed with many components including magnets, coils, and the like installed therein. In order to improve productivity, the assembly process needs to be easy and simple.

An object of the present invention is to provide a camera module having an autofocus function of the structure that the assembly process can be easy and simple.

Camera module having an autofocus function according to the present invention for achieving the above object, the lens unit having at least one lens; A coil unit coupled around the lens unit; At least one pair of magnets disposed to face each other in pairs with the coil unit therebetween; Yokes attached to each outer surface of the magnets; A head having head cutting grooves for respectively inserting the magnets, and alignment supports for aligning and supporting both sides of the magnets in each of the head cutting grooves; And a base having base cutting grooves respectively defining the yoke insertion holes together with the head cutting grooves so that the yokes are inserted while being coupled to the head.

The camera module according to the present invention has a structure in which the assembly and bonding process between the head, the magnet, the yoke, and the base can be made easily and simply, and thus may have an advantageous effect on productivity improvement.

1 is a side cross-sectional view of a camera module having an autofocus function according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view showing a part of the camera module shown in FIG.
3 is a perspective view showing the inside of the head in FIG.
4 is a partial bottom view of a state in which the magnets are aligned and supported by the head of FIG. 3;
5 is a partial side cross-sectional view of the portion of the head and the base in FIG.
FIG. 6 is an exploded perspective view illustrating a state before the lower end of the head and the upper end of the base are joined in the region A of FIG. 6;
FIG. 7 is a perspective view illustrating a process of inserting a yoke into the yoke insertion groove of FIG. 1. FIG.
FIG. 8 is a partial side cross-sectional view of the yoke of FIG. 7 showing a state in which the yoke is spaced apart from the extension jaws.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a side cross-sectional view of a camera module having an autofocus function according to an embodiment of the present invention. FIG. 2 is an exploded perspective view showing a part of the camera module shown in FIG.

1 and 2, the camera module includes a lens unit 110, a coil unit 120, at least one pair of magnets 130, yokes 140, a head 150, and And base 160.

The lens unit 110 includes at least one lens 111. The lens 111 forms an optical image of the subject. The lens unit 110 may include a barrel 112 for receiving the lens 111. The upper portion of the barrel 112 is opened so that light enters the lens 111. The lower part of the barrel 112 is opened so that light passing through the lens 111 can be transmitted to the image sensor 101 side installed below the lens 111.

Here, the image sensor 101 converts an optical image formed by the lens 111 into an electrical signal, and may be configured as a CCD, a CMOS, or the like. The image sensor 101 may be installed on the printed circuit board 102. The printed circuit board 102 supplies a control current for adjusting the focus of the lens 111 to the coil unit 120, and the printed circuit board 102 may be installed in the lower opening of the base 160.

The coil unit 120 is coupled around the lens unit 110. The coil unit 120 may include a bobbin 121 having a hollow and a coil 122 wound around the bobbin 121. The bobbin 121 may be screwed with the barrel 112. The barrel 112 may linearly move in the optical axis direction as it rotates forward and reverse in a state in which the barrel 112 is screwed to the bobbin 121. In this process, fine focus adjustment for zero adjustment of the lens 111 can be performed.

When the control current is supplied to the coil unit 120 from the printed circuit board 102, the coil unit 120 in the magnetic field of the magnet 130 moves linearly in the optical axis direction by the Lorentz force, and thus the coil unit 120 The lens unit 110 coupled to the linear movement in the optical axis direction. Accordingly, the position of the lens 111 is varied with respect to the image sensor 101, so that the focus can be automatically adjusted.

The coil unit 120 may be elastically supported with respect to the head 150 and the base 160. For example, an upper spring 103 may be installed between the coil unit 120 and the head 150, and a lower spring 104 may be installed between the coil unit 120 and the base 160. When a force is applied to the coil part 120 and the coil part 120 moves in the optical axis direction, the upper and lower springs 103 and 104 are elastically deformed. When the force applied to the coil unit 120 is removed, a restoring force is generated on the upper and lower springs 103 and 104 to return the coil unit 120 to the original position by the restoring force. The upper and lower springs 103 and 104 may be configured in the form of a leaf spring.

The magnets 130 generate at least one pair by generating a magnetic field. The magnets 130 are arranged to face each other in pairs with the coil part 120 interposed therebetween, such that a magnetic field is applied to the coil part 120. The magnets 130 are illustrated as being composed of two pairs, but are not limited thereto. The magnets 130 may be formed in a flat plate shape, respectively. The magnets 130 are disposed perpendicular to each other, and each of the opposite polarities is set to the same polarity. For example, if each inside of the magnets 130 is set to the N pole, each outside of the magnets 130 may be set to the S pole.

Yokes 140 are attached to each outer surface of the magnets 130. Each yoke 140 may have a flat plate shape having a larger area than the magnet 130. The yoke 140 allows the magnetic flux generated from the magnet 130 to be concentrated and guided to the coil unit 120.

The head 150 has head cutting grooves 151 for inserting the magnets 130, respectively. When four magnets 130 are included, the head 150 may have a structure in which one head cutting groove 151 is formed at each of four sides in an hexahedral shape having an inner space and an upper and lower portions thereof. The head cutting groove 151 is formed by cutting from the lower opening of the head 150, so that the head 150 has a structure having head protrusions 152 protruding downward in four corners, respectively. The lens unit 110 may be inserted through the upper opening of the head 150 to be coupled to the coil unit 120.

Alignment support portions 153 are formed in each of the head cutting grooves 151. The alignment support 153 allows the magnet 130 to be aligned and supported when the magnet 130 is inserted into the head incision groove 151. For example, if the magnets 130 are placed in the center space of the head 150 and the magnets 130 correspond to the head incision grooves 151, respectively, the magnets 130 try to move toward the magnetic body by magnetic force. . In this case, the magnets 130 may be easily and conveniently aligned by the alignment support 153, respectively. In this state, the magnets 130 may be fixed to the head 150 by an adhesive or the like.

The base 160 has a base cutting groove 161 which defines the yoke insertion holes 171 (see FIG. 7) together with the head cutting grooves 151 so that the yokes 140 are inserted in the state in which the base 160 is coupled to the head 150. Have them. When the head 150 has the above-described structure, the base 160 may have a structure in which one base cutting groove 161 is formed at every four sides in an hexahedral shape having an inner space and an upper and lower portions thereof. The base cut groove 161 is formed by cutting from the upper opening of the base 160, so that the base 160 has a structure having base protrusions 162 protruding upwards at four corners, respectively. The base protrusions 162 correspond to the head protrusions 152 and are coupled to each other. The printed circuit board 102 may be fixed to the lower opening of the base 160.

When the yoke 140 is placed to correspond to the yoke insertion hole 171 defined by the head cutting groove 151 and the base cutting groove 161, the yoke 140 is pulled by the magnetic force of the magnet 130 and the yoke insertion hole is provided. After being inserted through 171, the magnet 130 may be attached to an outer surface of the magnet 130. At this time, the assembly of the yoke 140 can be made easily and simply. In this state, the yoke 140 may be fixed to the head 150 and the base 160 by an adhesive or the like.

Meanwhile, as shown in FIGS. 3 and 4, the alignment support 153 may include reference surfaces 154 and support surfaces 155. The reference planes 154 protrude from the magnets 130 to the planes toward the coil unit 120 from the inside of the head incision grooves 151 to allow the magnets 130 to be aligned. The reference faces 154 provide a reference position at which the magnet 130 is aligned with respect to the head 150.

That is, in a state in which the magnetic body is placed in the central space of the head 150, the magnet 130 may be aligned with the reference surfaces 154 while the surface facing the coil unit 120 moves toward the magnetic body by magnetic force. have. Based on the drawings, if the surface facing the coil unit 120 in the magnet 130 is called the inner surface, the reference surface 154 may be formed to abut each of the left and right edge inner surface of the magnet 130. As another example, the reference surfaces 154 may be formed to abut each of the inner surfaces of the upper and lower edges of the magnet 130, and thus are not limited to the illustrated example. On the other hand, if the yoke 140 is attached to the outer surface of the magnet 130 with the magnet 130 aligned by the reference planes 154, the yoke 140 is also aligned by the reference planes 154. Can be.

The support surfaces 155 protrude from the inner side of the head incision groove 151 to the sides of the magnet 130 so as to support the magnet 130. Based on the drawings, the support surfaces 155 may protrude from the left and right sides of the magnet 130 to contact the left and right sides of the magnet 130 to support the magnet 130. As another example, the reference surfaces 154 may protrude to the upper and lower sides of the magnet 130 so as to be in contact with the upper and lower sides of the magnet 130, but are not limited to the illustrated example.

In addition, a magnet bonding groove 156 may be formed between the reference surface 154 and the support surface 155 to inject an adhesive for bonding the magnet 130 to the head 150. The magnet bonding groove 156 has a shape recessed between the reference surface 154 and the support surface 155 from the lower side of the head 150. An inclined surface may be included around the inlet of the magnet bonding groove 156, such as a protruding portion of the reference surface 154 to allow the adhesive to flow smoothly into the magnet bonding groove 156.

The process of attaching the magnet 130 to the head 150 may be performed as follows. The magnets 130 are aligned and supported in the head incision grooves 151, respectively, with the lower side of the head 150 facing upward. In this state, when the adhesive is injected through each inlet of the magnet bonding grooves 156 and then cured, the magnets 130 may be bonded to and fixed to the head 150, respectively.

Referring to FIGS. 5 and 6 together with FIG. 3, the lower edge of the head 150 and the upper end of the base 160 are in contact with each other, and the adhesive is formed in the gap G1 spaced apart from each other by the inner parts. It can be formed to be filled. For example, the upper surface of the base protrusion 162 has a concave shape of the inner portion and a convex shape of the outer portion. The lower surface of the head protrusion 152 has a convex shape with an inner portion corresponding to the concave portion of the base protrusion 162 and a concave shape with an outer portion corresponding to the convex portion of the base protrusion 162. The convex portion of the base protrusion 162 contacts the concave portion of the head protrusion 152, and the concave portion of the base protrusion 162 is spaced apart from the convex portion of the head protrusion 152. The head protrusion 152 and the base protrusion 162 of the above-described structure may facilitate alignment between the head 150 and the base 160.

The process of bonding the head 150 and the base 160 to each other may be performed as follows. After applying the adhesive to the concave inner portion of the base protrusion 162, the head 150 is positioned so that the head protrusion 152 is placed on the base protrusion 162. In this state, the outer portion of the base protrusion 162 is supported in contact with the outer portion of the head protrusion 152. In addition, since the inner portion of the base protrusion 162 is spaced apart from the inner portion of the head protrusion 152, the adhesive may be filled in the spaced gap G1. Thereafter, when the adhesive is cured, the head 150 and the base 160 may be adhered to each other.

As shown in FIGS. 7 and 8, an extension jaw 172 may be formed in each of the head cutting groove 151 and the base cutting groove 161. The extension jaws 172 are formed to surround the circumference of the magnet 130 along the inner circumference of the yoke insertion hole 171.

In addition, the extension jaws 172 are formed to be spaced apart from the front face of the edge of the yoke 140. That is, the extension jaws 172 form a gap G2 between the yoke 140 and the extension jaw 172. The gap G2 allows the yoke 140 to be attached in close contact with the outer surface of the magnet 130, thereby allowing the yoke 140 to be aligned with respect to the reference surfaces 154. The gap G2 also allows adhesive to be injected between the yoke 140 and the extending jaws 172.

Adhesive injection grooves 173 may be formed in the yoke insertion hole 171. The adhesive injection grooves 173 are incised across the head 150 and the base 160 on both sides of the yoke insertion hole 171 so that the adhesive is injected into the gap G2 between the yoke 140 and the extension jaw 172. It is formed. When the adhesive is supplied through the adhesive injection groove 173, the adhesive flows into the spaced gap G2 between the yoke 140 and the extension jaw 172, and then cures, such that the yoke 140 is the head 150 and the base 160. In addition to being fixed to the, it is possible to more secure the fixing between the head 150 and the base 160. The adhesive injection groove 173 may be formed in various shapes in a range capable of performing the above-described functions in addition to the illustrated shape.

Yoke cutting grooves 141 may be formed at both sides of the yoke 140, respectively. The yoke cut groove 141 is cut to have an inlet facing the inlet of the adhesive injection groove 173. The yoke cut groove 141 allows the adhesive to flow more easily into the spaced gap G2 of the yoke 140 and the extension jaw 172. The yoke cutting groove 141 may be formed in various shapes in a category capable of performing the above-described functions in addition to the illustrated shape.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

110. Lens part 120. Coil part
130. Magnet 140. York
150 head 153 alignment support
154. reference surface 155. support surface
156 .. Magnet bonding groove 160 .. Base
171 yoke insert hole 173 adhesive injection groove

Claims (6)

delete A lens unit having at least one lens;
A coil unit coupled around the lens unit;
At least one pair of magnets disposed to face each other in pairs with the coil unit therebetween;
Yokes attached to each outer surface of the magnets;
A head having head cutting grooves for respectively inserting the magnets, and alignment supports for respectively aligning and supporting the magnets inside each of the head cutting grooves; And
And a base having base cutting grooves respectively defining the yoke insertion holes together with the head cutting grooves so that the yokes are inserted while being coupled to the head.
Each of the alignment support,
And a reference surface protruding from the magnet toward the coil portion and aligning the magnets, and supporting surfaces protruding from the side surfaces of the magnet to support the magnet, respectively. Camera module. The method of claim 2,
Between the reference surface and the support surface,
A camera module having an autofocus function, characterized in that a groove for attaching a magnet into which an adhesive for adhering the magnet to the head is injected is formed. The method of claim 2,
The lower end of the head and the upper end of the base,
The outer edge portion is in contact with each other, the inner portion of the camera module having an autofocus function, characterized in that formed so that the adhesive is filled in the gap spaced apart from each other. The method of claim 2,
Extension jaws formed around the inner circumference of the yoke insertion hole in the head and the base and spaced apart from each other in a state facing the front edge of the yoke;
And an adhesive injection groove formed by cutting across the head and the base to both sides of the yoke insertion hole so that adhesive is injected into the gap between the yoke and the extended jaw. The method of claim 5,
On both sides of the yoke,
A camera module having an autofocus function, characterized in that each of the yoke incision grooves formed to have inlets facing each inlet of the adhesive injection grooves are formed.

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