KR100939119B1 - Camera module with function of autofocus - Google Patents

Abstract

PURPOSE: A camera module with an auto focus function is provided to conveniently connect a coil unit with a PCB without respect to the locations of extracting parts of wire terminals of the coil unit, thereby conveniently connecting the coil unit with the PCB. CONSTITUTION: A coil unit(120) is fixed to a lens unit. A magnet unit(130) is connected to one among wire terminals of the coil unit. A holder(141) is fixed to a printed circuit board. Legs of a spring member(151) is protruded toward the holder. The first connection terminal(161) is touched with the magnet unit. The second connection terminal is touched with at least one of the legs of the spring member.

Description

Camera module with function of autofocus

The present invention relates to a camera module, and more particularly to a camera module having an autofocus function.

Camera modules mounted on small electronic devices such as digital cameras and mobile phones employ image sensors such as a charge coupled device (CCD) or a complementary metal oxide semiconductor (CMOS) to convert an optical signal into an electrical signal to implement an image.

A camera module having a function of automatically focusing on a subject, a so-called autofocus function, is provided with an autofocus adjusting device capable of varying the position of the lens with respect to the image sensor.

The conventional autofocus control device is configured to linearly move the lens in the optical axis direction by using a converter mechanism such as a gear to rotate the motor. However, the automatic focusing apparatus of the above-described configuration has a limitation in finely adjusting the focus by using a gear, and has a limitation in miniaturization due to the space occupied by the motor and the gear.

Accordingly, an auto focusing device of a voice coil motor (VCM) system has been proposed. The VCM-type autofocus controller is a method in which a permanent magnet generating magnetic force is disposed opposite to a coil receiving a current, and the position of the lens is changed by a Lorentz force perpendicular to the magnetic field and the current.

In the VCM type auto focusing device, it is necessary to connect the coil to the printed circuit board so that the current can be supplied to the coil. For this purpose, the wiring terminals of the coil are directly soldered to the connecting terminals of the printed circuit board.

However, in the above-described case, the wiring terminals of the coil should be long enough to be connected to the connection terminals of the printed circuit board even where the drawn portion is located. For example, when the lens is rotated with respect to the printed circuit board to finely adjust the focus while the coil is fixed to the lens unit, the position of the portion where the wiring terminals are drawn out of the coil may be changed according to the rotational position of the lens unit.

Then, the distance between the wiring terminal of the coil and the connection terminal of the printed circuit board may be changed. In such a case, in order for the wiring terminal of the coil to connect with the connection terminal of the printed circuit board, the wiring terminal must be made sufficiently long. However, after the wiring terminals of the coil are connected to the connection terminals of the printed circuit board, when the length of the wiring terminals remains unnecessarily, there is a need to neatly process the wiring of the coil.

An object of the present invention is to solve the above problems, to provide a camera module having an autofocus function that can be connected to the coil portion more conveniently to the printed circuit board.

Camera module having an autofocus function according to the present invention for achieving the above object, the lens unit; A coil part surrounding the lens part and fixed to the lens part; A magnet part disposed to act on the coil part, connected to one of the wiring terminals of the coil part, and supported by a base; A holder screwed to the base and fixed on a printed circuit board for fine focus adjustment of the lens unit; A spring member interposed between the lens portion and the base, connected to another one of the wiring terminals of the coil portion, and having a plurality of legs protruding toward the holder; A first connection terminal connected to one of the connection terminals of the printed circuit board, the first connection terminal being in contact with the magnet unit while the base is assembled with the holder; Connected to another one of the connection terminals of the printed circuit board, and in contact with at least one of the legs of the spring member irrespective of the positional change of the portion where the wiring terminals are drawn out while the base is assembled with the holder. And a second connection terminal formed.

Camera module having an autofocus function according to the present invention, the lens unit; A coil part surrounding the lens part and fixed to the lens part; A magnetic part disposed to act on the coil part and supported by a base; A holder screwed to the base and fixed on a printed circuit board for fine focus adjustment of the lens unit; And a length extending from both ends of the coil of the coil part, the length of which can be wound in a receiving groove formed on the side of the base and can be released, and the base is drawn out from both ends of the coil in an assembled state with the holder. And wiring terminals that may be connected to connection terminals of the printed circuit board, regardless of variation.

According to the present invention, it is possible to conveniently connect the coil unit to the printed circuit board wherever the lead portions of the wiring terminals of the coil unit are positioned while the base is screwed to the holder and finely adjusted.

According to the present invention, when the wiring terminals of the coil unit are connected to the magnet unit and the spring member, respectively, and the magnet unit and the spring member are energized to the first and second connection terminals in the process of screwing the base and the holder, The coil portion can be conveniently connected to the printed circuit board. In addition, since the wiring terminals of the coil part may be easily connected to the magnet part and the spring member with the shortest length, the wiring process of the coil part may be neatly performed.

According to the present invention, when the wiring terminals of the coil unit are formed to have a length that can be unwound while being wound on the side of the base, the wiring terminals can be unwound and used only as necessary for the connection, so that the coil part is located where the lead portions of the wiring terminals are located. Can be conveniently connected to a printed circuit board. Then, the wiring terminals can be loosened only as necessary for the connection and the rest can be wound around the base, so that the wiring processing can be performed neatly. In addition, since the wiring terminals of the coil portion do not need to be soldered to the outer yoke and the spring member, contamination of the surroundings in the soldering process can be prevented.

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

1 is a perspective view of a camera module having an autofocus function according to an embodiment of the present invention, FIG. 2 is an exploded perspective view of FIG. 1, and FIG. 3 is a sectional view of FIG. 1.

1 to 3, the camera module 100 includes a lens unit 110, a coil unit 120, a magnet unit 130, a holder 141, a spring member 151, and a It comprises a 1,2 connection terminals (161,162).

The lens unit 110 may include at least one lens (not shown) for forming an optical image of a subject, and a barrel 111 for receiving and supporting the lens. The barrel 111 may have an exposed hole formed on an upper surface of the barrel 111 to receive light into the lens, and may have an opening structure in which the light passing through the lens may be transferred toward the image sensor 148.

The coil unit 120 wraps around the lens unit 110 and is fixed to the lens unit 110. When the coil unit 120 receives current from the magnetic field generated by the magnet unit 130, the coil unit 120 moves linearly by Lorentz force, thereby allowing the lens unit 110 to linearly move in the optical axis direction. Accordingly, the position of the lens is variable with respect to the image sensor 148 to operate to automatically adjust the focus.

The coil unit 120 may include a coil 121 and a coil ring 122. The coil 121 may have a structure wound in a ring shape in a state spaced apart from the outer surface of the barrel 111. The coil 121 may be provided with wiring terminals 121a and 121b at both ends thereof so as to receive a current from the printed circuit board 146. The coil ring 122 is fixed to the coil 121 and the barrel 111 so that the coil 121 can be supported in a state spaced apart from the outer surface of the barrel 111.

The magnet part 130 is disposed so that a magnetic field acts on the coil part 120. The magnet part 130 is connected to one of the wiring terminals 121a and 121b of the coil part 120. This is to allow the coil unit 120 and the first connection terminal 161 to be electrically connected through the magnet unit 130.

The magnet part 130 and the wiring terminal 121a of the coil part 120 may be soldered and connected to each other. The magnet part 130 is supported by the base 136. The base 136 has a ring shape and has a structure in which a screw portion for screwing with the holder 141 is formed. The magnet part 130 and the base 136 may be coupled to each other by a coupling ring 137.

Holder 141 is made of a structure that can be screwed with the base 136. This is because when the base 136 constitutes the lens assembly together with the magnet part 130, the lens part 110, and the coil part 120, the base part 136 rotates with respect to the holder 141 while the lens part 110 is rotated. To fine tune the focus.

As such, the base 136 constitutes the lens assembly together with the lens unit 110, and the force is applied to the base 136 in the process of fine focusing of the lens unit 110, but no force is applied to the lens unit 110. You may not. Accordingly, as will be described later, when the lens unit 110 is elastically supported by the spring members 151 and 152 to be described later in the lens assembly, since the lens unit 110 may maintain the focus adjusted state after the fine focus adjustment, Fine focus adjustment can be made conveniently. In addition, since no force is applied to the spring members 151 and 152 in the fine focusing process, damage to the spring members 151 and 152 may be prevented.

The holder 141 is fixed on the printed circuit board 146. Here, since the image sensor 148 is mounted on the printed circuit board 146, the holder 141 may have a structure in which a center thereof is opened to expose the top surface of the image sensor 148. In this case, the holder 141 may have an edge fixed to the edge of the printed circuit board 146.

The printed circuit board 146 allows a current to be supplied to the coil unit 120. For example, the printed circuit board 146 may receive a control current for adjusting the focus and transfer it to the coil unit 120. The image sensor 148 is disposed below the lens unit 110. The image sensor 148 may receive an optical image formed by the lens and convert the optical image into an electrical signal. As the image sensor 148, a CCD image sensor or a CMOS image sensor may be used.

The spring member 151 is interposed between the lens unit 110 and the base 136 to allow the lens unit 110 to elastically support the base 136. That is, the spring member 151 is elastically deformed when a force is applied to the lens unit 110 and the lens unit 110 linearly moves in the optical axis direction, and when the force applied to the lens unit 110 is removed, the lens unit is restored by a restoring force. Allow 110 to return to its original state. The spring member 151 may be a leaf spring.

Another spring member 152 may be further provided on the upper side of the lens unit 110. In this case, the upper spring member 152 is interposed between the head 156 fixed to the upper end of the magnet portion 130 and the lens unit 110 to elastically support the lens unit 110 with respect to the head 156. Can be.

The spring member 151 positioned below the lens unit 110 is connected to the other one 121b of the wiring terminals 121a and 121b of the coil unit 120. This is to allow the coil unit 120 and the second connection terminal 162 to be electrically connected through the spring member 151. The spring member 151 and the wiring terminal 121b of the coil unit 120 may be soldered and connected to each other.

The spring member 151 protrudes from the plurality of legs 151a toward the holder 141. The legs 151a are for connection with the second connection terminal 162. The legs 151a may be bent and protruded toward the holder 141 through grooves formed in the outer side of the base 136. Each leg 151a may be formed in two branches. Here, the leg 151a is elastic to maintain the state of being connected to the second connection terminal 162 during the process in which the base 136 is screwed to the holder 141 and rotated to finely adjust the lens unit 110. It can be modified.

The first connection terminal 161 is connected to one of the connection terminals 147 of the printed circuit board 146, and the base 136 is in contact with the magnet part 130 while the holder 141 is screwed. It is formed to be energized. Accordingly, one of the connection terminals 147 of the printed circuit board 146 may be electrically connected to the coil unit 120 via the first connection terminal 161 and the magnet unit 130.

The second connection terminal 162 is connected to the other one of the connection terminals 147 of the printed circuit board 146, and the leg of the spring member 151 with the base 136 screwed to the holder 141. It is formed to be in electrical contact with at least one of the (151a). Accordingly, the other one of the connection terminals 147 of the printed circuit board 146 may be electrically connected to the coil unit 120 via the second connection terminal 162 and the spring member 151.

As described above, in the process in which the base 136 is screwed to the holder 141, the magnet part 130 and the spring member 151 are energized to the first and second connection terminals 161 and 162. Can be conveniently connected to the printed circuit board 146. Accordingly, the coil unit 120 is conveniently mounted on the printed circuit board 146 where the lead portions of the wiring terminals 121a and 121b are positioned while the base 136 is screwed to the holder 141 and finely adjusted. Can be connected. In addition, since the wiring terminals 121a and 121b of the coil unit 120 may be easily connected to the magnet unit 130 and the spring member 151 with the shortest possible length, even when located, the wiring of the coil unit 120 Processing can be done neatly.

On the other hand, the holder 141 may be configured to include a holder body 142 and the holder support portion 143. The holder body 142 has a threaded portion to be screwed with the base 136. The holder support part 143 may protect the lens assembly including the magnet part 130 or the magnet part 130 from external impact, thereby preventing the lens part, the coil part, etc. constituting the lens assembly from being separated.

The holder support part 143 is provided in plurality, and protrudes from the holder body 142 so as to support the outside of the magnet part 130. The holder supports 143 may be arranged at equal intervals. For example, four holder supports 143 may be provided and arranged at 90 degree intervals on the holder body 142. The holder support part 143 may have an inner side in close contact with an outer side of the magnet 130. In addition, the holder support part 143 may be fixed to the magnet part 130 with an adhesive or the like.

As described above, when the holder 141 is provided with four holder support parts 143 and arranged at intervals of 90 degrees, the legs 151a of the spring member 151 are soldered to the second connection terminal 162, or the like. Legs 151a may be provided in two, and may be spaced apart from each other at 120 degree intervals to fix them.

Correspondingly, the second connection terminal 162 may be bent in a circle in a range of 240 degrees to be supported by the holder 141 in contact with at least one of the legs 151a of the spring member 151. That is, the second connection terminal 162 may be formed in a band shape in which a contact portion with the spring member 151 is bent in a circle in a range of 240 degrees, and may be supported on the upper surface of the holder 141.

Accordingly, even if one of the legs 151a of the spring member 151 is hidden by the holder support 143 and difficult to solder to the second connection terminal 162, the other one is located between the holder supports 143. It may be conveniently soldered to the second connection terminal 162.

As shown in FIG. 4, the first and second connection terminals 161 and 162 may be connected to the connection terminals 147 of the printed circuit board 146 between the holder support parts 143 and the holder body 142. It is preferred to be fixed to each. This is to facilitate the connection between the first and second connection terminals 161 and 162 and the printed circuit board 146. Fixing protrusions are formed in the holder main body 142 so that the first and second connecting terminals 161 and 162 can be fixed to the holder body 142, and fixing holes into which the fixing protrusions are fitted into the first and second connecting terminals 161 and 162. This can be formed.

The magnet unit 130 may include a permanent magnet 131, an outer yoke 132, and an inner yoke 133. The permanent magnet 131 is formed in a ring shape surrounding the lens unit 110. The permanent magnet 131 is disposed so that the upper and lower ends have different poles.

The outer yoke 132 and the inner yoke 133 are made of magnetic material and allow the coil 121 to be placed in the magnetic field. That is, the outer yoke 132 and the inner yoke 133 is a horizontal flow of the magnetic force line is formed to induce the flow of the magnetic force line so that the coil 121 passes.

The outer yoke 132 is fixed to the upper end of the permanent magnet 131 to have the same pole as the upper end of the permanent magnet 131. The outer yoke 132 is preferably fixed to the top of the permanent magnet 131 over a large area as possible. Accordingly, the outer yoke 132 may be more firmly fixed to the permanent magnet 131, and may receive more magnetic force of the permanent magnet 131.

The outer yoke 132 is bent to face the outer side of the coil part 120 while surrounding the outer side of the permanent magnet 131, and the lower end is fixed to the base 136. Accordingly, the outer yoke 132 may cover the outer shell of the camera module 100 to prevent foreign matter from entering, and thus may serve as a housing that is usually provided to surround the outer shell of the camera module. Therefore, it may be advantageous to reduce the overall size of the camera module 100 to be miniaturized.

The inner yoke 133 is fixed to the lower end of the permanent magnet 131 to have the same pole as the lower end of the permanent magnet 131. The inner yoke 133 is preferably fixed to the lower end of the permanent magnet 131 over a large area as possible. Accordingly, the inner yoke 133 may be more firmly fixed to the permanent magnet 131, and may receive more magnetic force from the permanent magnet 131.

However, if the part of the inner yoke 133 fixed to the permanent magnet 131 is too close to the outer yoke 132, there may be a loss of the magnetic force line, the interval with the outer yoke 132 is set in the category to minimize this This is preferred. The inner yoke 133 may be formed to be bent to face the inner side of the coil part 120, and may face the outer yoke 132 with the coil part 120 interposed therebetween.

5 is a cross-sectional view of a camera module having an autofocus function according to another exemplary embodiment of the present invention, and FIG. 6 is an exploded perspective view showing a state in which a wiring terminal of a coil unit is accommodated in a base in FIG. 5. Like reference numerals in the drawings indicate the same elements having the same functions. In this embodiment, the difference from the above-described embodiment will be described in detail.

5 and 6, the camera module 200 of this embodiment has a structure in which the first and second connection terminals 161 and 162 of the above-described embodiment are omitted. Instead, the wiring terminals 221a and 221b of the coil unit 120 extend from both ends of the coil 121 so that the coil unit 120 can be connected to the printed circuit board 146, and the base 236 Each of the receiving grooves 236a is wound to a length that can be unwound.

The receiving groove 236a may be formed recessed in the side of the base 236. The accommodation grooves 236a may be formed to accommodate the wiring terminals 221a and 221b together, but may be formed in two to accommodate the wiring terminals 221a and 221b, respectively. The accommodating grooves 236a are preferably made of a size that can maintain the wound state in which the wiring terminals 221a and 221b are inserted. In addition, the wiring terminals 221a and 221b may be drawn out through the base 236 from the coil part 120 and may be accommodated in the accommodation groove 236a.

As described above, since the wiring terminals 221a and 221b are formed to have a length that can be wound around the receiving grooves 236a of the base 236, respectively, where the lead portions of the wiring terminals 221a and 221b are located. Whether it is possible to conveniently connect the coil unit 120 to the printed circuit board 146. That is, where the lead portions of the wiring terminals 221a and 221b are positioned while the base 136 is screwed to the holder 141 and finely adjusted, the wiring terminals 221a and 221b may be connected to the printed circuit board. It can be loosened enough to be connected to the connection terminals 147 of 146 and connected to the connection terminals.

Since the wiring terminals 221a and 221b are loosened only as necessary for the connection with the printed circuit board 146 and the remainder is wound in the receiving groove 236a of the base 236, the wiring process can be neatly performed. The wiring terminals 221a and 221b may be fixed to the base 236 with an adhesive or the like so that the wiring terminals 221a and 221b may be wound around the receiving grooves 236a after the wiring process.

In addition, since the wiring terminals 221a and 221b of the coil unit 120 may extend from both ends of the coil 121 to be directly connected to the connection terminals 147 of the printed circuit board 146, the coil unit It is not necessary to solder the wiring terminals 221a and 221b of the 120 to the outer yoke 132 and the spring member 151. Therefore, the contamination of the surroundings by the generation of flux or the like in the soldering process can be prevented.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Could be. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

1 is a perspective view of a camera module having an autofocus function according to an embodiment of the present invention.

2 is an exploded perspective view of FIG. 1.

3 is a cross-sectional view of FIG. 1.

4 is a perspective view showing a state in which the first and second connection terminals are mounted to the holder in FIG.

5 is a cross-sectional view of a camera module having an autofocus function according to another embodiment of the present invention.

FIG. 6 is an exploded perspective view showing a state in which a wiring terminal of a coil unit is accommodated in a base in FIG. 5; FIG.

<Brief description of the major symbols in the drawings>

110. Lens part 120. Coil part

121. Coil 122. Coil Ring

121a, 121b, 221a, 221b..Wiring terminal 130..Magnetic part

Permanent Magnet 132. Outer York

133..Inner yoke 136,236..Base

141 holder. 142 holder body

143. Holder support 146 Printed circuit board

147. Connection terminal 148. Image sensor

151..Spring member 151a..leg

161 .. 1st connection terminal 162. 2nd connection terminal

236a..Acceptance groove

Claims (8)

A lens unit; A coil part surrounding the lens part and fixed to the lens part; A magnet part disposed to act on the coil part, connected to one of the wiring terminals of the coil part, and supported by a base; A holder fixed to a printed circuit board, the base being screwed and rotatable for fine focus adjustment of the lens unit; A spring member interposed between the lens portion and the base, connected to another one of the wiring terminals of the coil portion, and having a plurality of legs protruding toward the holder; A first connection terminal connected to one of the connection terminals of the printed circuit board, the first connection terminal being in contact with the magnet unit while the base is assembled with the holder; It is connected to the other one of the connection terminals of the printed circuit board, while being formed in the shape of a band bent in a circular shape corresponding to the legs of the spring member is drawn out of the wiring terminals while the base is assembled with the holder A second connecting terminal in contact with at least one of the legs of the spring member irrespective of the positional variation of the portion; Camera module having an autofocus function comprising a. The method of claim 1, The holder is: A holder body screwed to the base, And a plurality of holder support portions each protruding from the holder body to support the outside of the magnet portion and arranged at intervals of 90 degrees. The method of claim 2, The legs of the spring member are provided in two and arranged spaced apart from each other at 120 degree intervals; And the second connection terminal is bent in a circle in a range of 240 degrees to be in contact with at least one of the legs of the spring member and supported by the holder body. The method according to claim 2 or 3, The first and second connection terminals are camera modules having an autofocus function, wherein portions connected to the connection terminals of the printed circuit board are respectively fixed to the holder body between the holder support portions. The method of claim 1, The magnet part: A ring-shaped permanent magnet surrounding the lens unit, An outer yoke fixed to an upper end of the permanent magnet and bent to face the outer side of the coil while being wrapped around the outer side of the permanent magnet, and fixed to the base; Camera module having an autofocus function, characterized in that the inner yoke is fixed to the lower end of the permanent magnet and formed to bend to face the inner side of the coil portion. A lens unit; A coil part surrounding the lens part and fixed to the lens part; A magnetic part disposed to act on the coil part and supported by a base; A holder fixed to a printed circuit board, the base being screwed and rotatable for fine focus adjustment of the lens unit; And The printed circuit, which extends from both ends of the coil of the coil part and is wound in the receiving groove formed on the side surface of the base, and is pulled out from both ends of the coil in a state where the base is assembled with the holder. Wiring terminals formed to be loosened to a length respectively connected to the connection terminals of the substrate; Camera module having an autofocus function comprising a. The method of claim 6, The holder is: A holder body screwed to the base, A camera module having an autofocus function, characterized in that it comprises a plurality of holder support portions each protruding from the holder body to support the outside of the magnet portion. The method according to claim 6 or 7, The magnet part: A ring-shaped permanent magnet surrounding the lens unit, An outer yoke fixed to an upper end of the permanent magnet and bent to face the outer side of the coil while being wrapped around the outer side of the permanent magnet, and fixed to the base; Camera module having an autofocus function, characterized in that the inner yoke is fixed to the lower end of the permanent magnet and formed to bend to face the inner side of the coil portion.

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