KR101442035B1 - Apparatus for testing camera module - Google Patents

Abstract

An apparatus for testing a camera module according to the present invention comprises a base body including a pin block formed with a plurality of POGO pins; a module block disposed on the base body and to raise up and down the camera module; a guide block disposed on both sides of the module block and to raise up and down the module block while linearly reciprocating; a top plate to be pivoted to the base body and formed with a connection terminal block disposed to face the terminal of the camera module; and a lever plate to be pivoted to the base body and to interconnect or separate the terminal and the connection terminal block by linearly reciprocating the guide block.

Description

[0001] APPARATUS FOR TESTING CAMERA MODULE [0002]

The present invention relates to a test apparatus for testing a camera module.

Generally, a camera module is mounted on a mobile phone, a small game machine, a camera, and the like to take a digital image or a moving picture.

The camera module includes a voice coil motor (VCM) having autofocusing or image stabilization function, an image sensor mounted on the voice coil motor, and an image sensor and a terminal portion connected to the voice coil motor.

Generally, a terminal portion connected to a camera module is formed in a direction toward a rear surface opposite to a front surface of an image sensor with respect to a front surface of the image sensor. However, in recent years, a terminal portion mounted on a camera module has been formed in a direction Is being developed.

In recent years, development of a camera module in which a terminal portion faces upward has been developed, as well as a test device for testing a camera module in which a terminal portion faces upward.

A test apparatus for testing a camera module having a terminal portion facing upward includes a lower body for fixing a camera module having a terminal portion and an upper body having a connection terminal connected to the terminal portion by being folded in a folding manner with respect to the lower body.

However, when the terminal portion of the camera module and the connection terminal of the test apparatus are rotated to contact each other by the folding method, the connection terminals of the camera module may be bent during the contact of the connection terminals of the test apparatus, The terminals are not correctly contacted, and so forth.

The cause of such a problem is caused by contacting the terminal portion of the camera module and the connection terminal of the test apparatus in a folding manner.

Korean Registered Patent No. 10-1199018 (2012.11.01) Test socket for camera module

The present invention reduces the time required for testing, and is a pivoting method in which a camera module can be stably placed at a designated position, thereby testing the camera module. And a camera module test apparatus in which defects of contacts and defective contacts are eliminated.

In one embodiment, a camera module testing apparatus includes a base body including a pin block having a plurality of pogo pins formed therein; A module block disposed on the base body for up-downing the camera module; A guide block disposed on both sides of the module block and linearly reciprocating to up-down the module block; A top plate rotatable with respect to the base body and having a connection terminal block disposed to face a terminal of the camera module; And a lever plate pivoted to the base body and reciprocating the guide block to connect or disconnect the terminal and the connection terminal block.

The module module of the camera module testing device has a receiving groove for receiving the camera module and the terminal on the upper surface of the module block.

Wherein the guide block facing the side surface of the module block of the camera module testing device is formed with a first up-down portion formed with a first inclined surface and a first flat surface connected to the first inclined surface, And a second up-down portion having a second inclined surface in contact with the first inclined surface and a second flat surface connected to the second inclined surface are formed.

A stopper plate formed parallel to the upper surface of the module block is coupled to the base body of the camera module testing device and an elastic member pressing the module block is interposed between the stopper plate and the module block.

Wherein the base body, the top plate and the lever plate of the camera module testing device are coupled by a hinge shaft, and a guide pusher pin for linearly reciprocating the guide block is provided on the top plate and the lever plate adjacent to the hinge shaft And the guide block is formed with a guide block transfer groove for linearly reciprocating the guide block by the rotation of the guide pusher pin.

A tension spring is disposed on the hinge shaft of the camera module testing device. One end of the tension spring is in contact with the base body and the other end opposite to the one end of the tension spring is disposed on the top plate.

The thickness of a portion of the guide block of the camera module testing device where the guide block transfer groove is formed is formed thinner than a portion of the guide block where the guide block transfer groove is not formed to form a step.

A clamping device for simultaneously clamping the top plate and the lever plate is formed on the base body of the camera module testing device, and clamping parts to be clamped to the clamper are formed on the top plate and the lever plate, respectively.

A gap of 0.3 mm to 1.0 mm is formed between the terminal and the connection terminal in a state in which the top plate of the camera module testing device is arranged in parallel with the base body and the lever plate is arranged not parallel to the base plate do.

The camera module testing apparatus according to the present invention shortens the time required for testing, and has a merit of being able to test and arrange the camera module at a designated position stably. It is possible to eliminate warpage of the connection terminals and contact defects which are generated when the connection terminals are connected.

1 is a perspective view of a camera module testing apparatus according to an embodiment of the present invention.
2 is an exploded perspective view of FIG.
3 is a rear exploded perspective view showing the module block and the guide block of FIG.
FIGS. 4 and 5 are cross-sectional views illustrating a testing process of a camera module testing apparatus according to an exemplary embodiment of the present invention.

In the following description, only parts necessary for understanding the embodiments of the present invention will be described, and the description of other parts will be omitted so as not to obscure the gist of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor is not limited to the meaning of the terms in order to describe his invention in the best way. It should be interpreted as meaning and concept consistent with the technical idea of the present invention. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely preferred embodiments of the present invention, and are not intended to represent all of the technical ideas of the present invention, so that various equivalents And variations are possible.

1 is a perspective view of a camera module testing apparatus according to an embodiment of the present invention. 2 is an exploded perspective view of FIG. 3 is a rear exploded perspective view showing the module block and the guide block of FIG. FIGS. 4 and 5 are cross-sectional views illustrating a testing process of a camera module testing apparatus according to an exemplary embodiment of the present invention.

Referring to FIG. 1, a camera module testing apparatus 700 includes a base body 100, a module block 200, a guide block 300, a top plate 400, and a lever plate 500.

2, the base body 100 is formed in a plate shape. The base body 100 includes a hinge structure 105, a pin block 110, a module block 200, a guide block 300, (600), the clamper (650), and the like.

The base body 100 may be formed by processing a synthetic resin or a metal material.

A hinge structure 105 having a shaft hole into which a hinge shaft 410 for rotating the top plate 400 and the lever plate 500 to be described later is inserted is formed at one side of the upper surface of the base body 100.

A top plate 400 and a clamper 650 for clamping the lever plate 500 are formed on the other side opposite to the one side of the upper surface of the base body 100.

The clamper 650 is pivotally coupled to the base body 100 by a clamper pin 660.

A pin block 110 is formed at the center of the upper surface of the base body 100. The pin block 110 has a plurality of pogo pins 115 disposed in a matrix form and disposed perpendicular to the upper surface of the base body 100.

Test signals for testing the camera module 10 are externally provided to each of the pogo pins 115 of the pin block 110 so that the pin block 110 penetrates the upper and lower surfaces of the base body 100 .

Referring to FIGS. 2 and 3, the module block 200 is disposed on the upper surface of the base body 100. For example, the module block 200 is disposed between the pin block 110 and the clamper 650 when viewed in plan.

The module block 200 is formed in a rectangular parallelepiped plate shape and the camera module 10 and the terminals 15 of the camera module 10 are stored in a predetermined position on the upper surface of the module block 200, A receiving groove 210 for fixing the terminal 10 and the terminal 15 is formed.

In an embodiment of the present invention, the module block 200 may be formed of a synthetic resin material.

The module block 200 up-down the camera module 10 and the terminal 15 in the defined Z-axis direction by the guide block 300 to be described later.

Meanwhile, stopper plates 600 and elastic members 610 are disposed on both sides of the upper surface of the module block 200 of the base body 100.

The stopper plates 600 are disposed at both side ends of the upper surface of the module block 200 in the shape of a rectangular plate. The stopper plate 600 is formed, for example, in a bar shape and in the X-axis direction in parallel with the guide block 300. The stopper plate 600 is fixed to both sides of the upper surface of the base body 100 by fastening screws or the like.

One end of the elastic member 610 is coupled to the stopper plate 600 and the other end of the elastic member 610 is disposed on the upper surface of the module block 200. The elastic member 610 applies elastic force to the module block 200 Click.

The up-down method and structure of the module block 200 by the guide block 300 will be described after explaining the guide block 300 for the sake of explanation.

2 and 3, the guide blocks 300 are disposed on both sides of the module block 200, respectively. The guide block 300 is formed in a rod shape, and the guide block 300 is arranged in a direction parallel to the X axis direction.

At least two through holes 310 are formed in the guide block 300 so as to penetrate the outer surface of the guide block 300 and the inner surface opposite to the outer surface of the guide block 300. The through holes 310 are formed in the X- And is formed in an oblong hole shape.

The guide block 300 is not separated from the base body 100 by the fastening member 320 coupled to the base body 100 through the through hole 310 and the guide block 300 is inserted through the through- The holes 310 do not move in the Z-axis direction and the Y-axis direction but move only in the X-axis direction.

The lower surface of the guide block 300 contacts the upper surface of the base body 100 and the guide rail 115 is formed on the upper surface of the base body 100 so that the guide block 300 can be moved only in the X- The guide block 300 is formed with a guide portion 301 coupled to the guide rail 115.

Referring to FIG. 3, a first up-down portion 360 including a first inclined surface 340 and a first flat surface 350 is formed on an inner surface of the guide block 300, For example, two portions 360 are formed on the inner surface of the guide block 300 intermittently.

The first inclined surface 340 is connected to the first flat surface 350 and the height of the first flat surface 350 and the lower surface of the guide block 300 may be about 0.3 mm to about 1.0 mm.

The second up-down portion 240 including the second inclined surface 220 and the second flat surface 230 is formed on the side of the module block 200 described above, and the second up- The second inclined surface 220 of the guide block 300 contacts the first inclined surface 240 of the guide block 300 and is formed in parallel with the first inclined surface 240.

As the guide block 300 is moved toward the X axis direction, the first inclined surface 340 of the guide block 300 pushes up the second inclined surface 220 of the module block 300 in the Z axis direction, The lower surface of the block 200 is disposed on the first flat surface 350 of the guide block 300.

That is, the camera module 10 and the terminal 15 mounted on the module block 200 and the module block 200 are moved from the designated position by a height of about 0.3 mm to about 1.0 mm by the linear motion of the guide block 300 Z-axis direction.

When the module block 200 is lifted in the Z axis direction by the linear motion of the guide block 300, the elastic member 610 coupled to the stopper plate 600 presses the upper surface of the module block 200 .

At the end of the guide block 300 adjacent to the hinge structure 105, a guide block transfer groove 330 is formed. The guide block transfer grooves 330 may be grooves or through holes formed concavely in the direction from the upper surface of the guide block 300 toward the lower surface. The guide block transfer grooves 330 are formed in the shape of a long hole when viewed in a plan view.

The guide block 300 is formed with a thickness smaller than the entire thickness of the guide block 300. That is, a step 335 is formed at a portion where the guide block transfer groove 330 is formed.

A step 335 is formed at a portion where the guide block transfer groove 330 is formed so that the lever plate 500 to be described later is rotated in the reverse direction to return the guide block 300 to the designated position, The raised module block 200 is lowered by the compressive force of the elastic member 610 connected to the stopper plate 600.

1 and 2, the top plate 400 is hinged by the hinge structure 105 of the base body 100 so that the top plate 400 is rotated relative to the base body 100.

A hinge pin 410 is coupled to the shaft hole of the hinge structure 105 of the base body 100 and a top plate 400 is coupled to the hinge pin 410 to rotate the top plate 400 relative to the base body 100 And is pivotally coupled.

The top plate 400 and the base body 100 are coupled to the hinge pin 410 so that the top plate 400 is pivoted to the top surface of the base body 100. As a result, As shown in FIG.

The top plate 400 has a flat area smaller than the flat area of the base body 100.

The circuit board 420 disposed on the inner surface of the top plate 400 is rotated in a state in which the top plate 400 is rotated so as to be parallel to the base body 100, A connection terminal block 450 is disposed.

The connection terminal block 450 and the terminals 15 of the camera module 10 are not connected to each other in a state where the top plate 400 is rotated so that the top plate 400 and the base body 100 are arranged in parallel, The lever plate 500 is rotated in parallel with the base body 100 so that the guide block 300 is moved and electrically connected to each other.

A drive signal for testing the camera module 10 from the outside is applied to the terminal of the circuit board 420 through the pogo pin 115 of the pin block 110 and a test signal applied to the terminal is applied to the circuit board 420 To the terminal 15 of the camera module 10 through the connection terminal block 450 so that the camera module 10 is tested.

A module pusher 430 is disposed on the circuit board 420. The module pusher 430 may provide a constant elastic force in a direction toward the base body 100 and the module pusher 430 may include a spring to generate an elastic force.

The camera module 10 is not pressed by the top plate 400 when the height of the camera module 10 is lower than the predetermined height within the range of about 0.5 mm. The module pusher 430 is placed on the circuit board 420 The camera module 10 is pressed onto the top plate 400 by the module pusher 430 to be accurately fixed at the designated position even if the height of the camera module 10 is lower than the designated height by about 0.5 mm. Therefore, the connection terminal block 450 and the terminal 15 of the camera module 10 are also correctly connected.

Meanwhile, a clamper 650 formed on the base body 100 and a clamper 460 clamped are formed on the top plate 400.

The top plate 400, the base body 100, and the hinge shaft 410 are rotated in order to rotate and return the top plate 400 when the clamper unit 460 is engaged with the clamper 650 The tension spring 470 is engaged as shown in FIG.

One end of the tension spring 470 is fixed to the top plate 400 and the other end of the tension spring 470 opposite to the one end of the tension spring 470 is fixed to the base body 440. The tension spring 470 is inserted into the hinge shaft 410, (Not shown).

The lever plate 500 is coupled to a hinge pin 410 that rotates the top plate 400 relative to the base body 100 such that the lever plate 500 is coupled to the base body 100 together with the top plate 400. [ As shown in Fig.

The lever plate 500 is formed in a structure suitable for rotating the top plate 400 in parallel with the base body 100 after the top plate 400 is rotated in parallel with the base body 100. The lever plate 500 has a clamper 620, The clamping portion 520 is formed.

The clamping portion 520 formed on the lever plate 500 may be used to clamp the top plate 400 already coupled to the clamper 650 when the clamping portion 520 is coupled to the clamper 650. In this case, The clamping part 520 formed on the lever plate 500 has a structure for pressing the clamping part 460 formed on the top plate 400 so that the part 460 is not separated from the clamper 650, Protrusions, and the like.

The lever plate 500 is formed in a shape similar to an L shape and a part of the lever plate 500 is rotatably supported by the top plate 400 and the top plate 400 so that when the lever plate 500 is rotated, Respectively.

The lever plate 500 is rotated in conjunction with the top plate 400 and the lever plate 500 is rotated along the top plate 400 after the top plate 400 is rotated about 12 to about 20 degrees, Convenience and test time can be further shortened.

A first guide pusher pin 512 is formed at a position corresponding to the guide block feed groove 330 of the other guide block 300 of the lever plate 500 and the first guide pusher pin 512 A second guide pusher pin 514 is formed at a position corresponding to the guide block transfer groove 330.

The first guide pusher pin 512 protrudes from one side of the lever plate 500 and is rotated and inserted into the guide block feed groove 330 of the one guide block 300 to feed the guide block 300 in the X axis direction .

The second guide pusher pin 514 protrudes to the other side opposite to the one side of the lever plate 500 and the second guide pusher pin 514 is rotated to move the guide block conveyance groove 330 of the other guide block 300, And guides the guide block 300 in the X-axis direction.

In one embodiment of the present invention, the first and second guide pusher pins 512 and 514 simultaneously operate the pair of guide blocks 300 by the rotation of the lever plate 500, so that the pair of guide blocks 300 And simultaneously transported in the X-axis direction.

The lever plate 500 is rotated so that the first guide pusher pin 512 and the second guide pusher pin 514 retract the guide block 300 in the X axis direction at the same time so that the module block 200 is raised, The terminal 15 of the camera module 10 mounted on the base plate 200 is connected to the connection terminal block 450 and the terminal formed on the substrate 420 of the top plate 400 is connected to the pogo pin (Not shown).

Hereinafter, a test procedure of a camera module testing apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1, 4, and 5. FIG.

FIGS. 4 and 5 are cross-sectional views illustrating a testing process of a camera module testing apparatus according to an exemplary embodiment of the present invention.

1 and 4, the camera module 10 to be tested and the terminal (not shown) connected to the camera module 10 are connected to the base body 100 in a state in which the top plate 400 and the lever plate 500 are rotated with respect to the base body 100 15 are disposed in the receiving groove 210 of the module block 200 of the opened base body 100.

The top plate 400 is first rotated in order to test the camera module 10 and the top plate 400 is rotated in parallel with the base body 100 and then the clamping portion 460 of the top plate 400 is rotated, Is coupled to a clamper (650) formed on the substrate (100).

The terminal 15 of the camera module 10 disposed on the base body 100 and the connection terminal block 450 formed on the top plate 400 in the state where the top plate 400 is rotated in parallel with the base body 100, Are also spaced apart and are not electrically connected.

The top plate 400 is rotated so that the terminal 15 and the connection terminal block 450 of the camera module 10 are spaced apart from each other while the top plate 400 is disposed in parallel with the base body 100 This is because when the terminal 15 and the connection terminal block 450 of the camera module 10 are connected while the top plate 400 is rotated, the connection terminal block 450 is damaged and connection failure occurs.

5, when the lever plate 500 is rotated in a state in which the top plate 400 is disposed in parallel with the base body 100, the lever plate 500 is rotated to be formed on the lever plate 500 The first and second guide block pusher pins 512 and 514 move back the guide block 300 so that the module block 200 rises and the terminal 15 and the connection terminal block 450 of the camera module 10 And are electrically connected to each other.

After the terminal 15 and the connection terminal block 450 of the camera module 10 are electrically connected to each other, a test signal is applied through the pogo pin 115 so that the camera module 10 is tested.

After the clamping portions 460 and 520 of the top plate 400 and the lever plate 500 coupled to the clamper 650 are separated from the clamper 650, the tested camera module 10 is ejected and the camera module 10 are again coupled to the module block 100.

In an embodiment of the present invention, the operator manually rotates the lever plate 500 to perform the test of the camera module 10, or the automatic operation of the camera module 10 by an automated process using a linear reciprocating motion mechanism or a rotating motion mechanism. Tests can be performed.

As described above in detail, the time required for the test is small, and the camera module is tested by the rotation method while testing the camera module by the rotation method having an advantage that the camera module can be stably placed at the designated position. It is possible to eliminate warpage of the connection terminals and contact defects which are generated when the connection terminals are connected.

It should be noted that the embodiments disclosed in the drawings are merely examples of specific examples for the purpose of understanding, and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

100 ... base body 200 ... module block
300 ... Guide block 400 ... Top plate
500 ... lever plate 600 ... stopper plate

Claims (10)

A base body including a pin block having a plurality of pogo pins formed therein;
A module block disposed on the base body for up-downing the camera module;
A guide block disposed on both sides of the module block and linearly reciprocating to up-down the module block;
A top plate rotatable with respect to the base body and having a connection terminal block disposed to face a terminal of the camera module; And
And a lever plate that is rotated with respect to the base body and linearly reciprocates the guide block to interconnect or separate the terminal and the connection terminal block. The method according to claim 1,
Wherein the camera module and the terminal are formed on a top surface of the module block. The method according to claim 1,
A first up-down portion having a first inclined surface and a first flat surface connected to the first inclined surface is formed in the guide block facing the side surface of the module block, and a first up-down portion formed parallel to the first inclined surface And a second up-down portion formed with a second flat surface connected to the second inclined surface. The method according to claim 1,
Wherein a stopper plate formed parallel to an upper surface of the module block is coupled to the base body and an elastic member pressing the module block is interposed between the stopper plate and the module block. The method according to claim 1,
Wherein the base body, the top plate, and the lever plate are coupled by a hinge shaft, and the top plate and the lever plate are rotated in an interlocking manner at an angle of 12 to 20,
A guide pusher pin for linearly reciprocating the guide block is respectively coupled to the top plate and the lever plate adjacent to the hinge shaft, and a guide block for guiding the guide block linearly reciprocates by the rotation of the guide pusher pin, Camera module test device with block transfer grooves. 6. The method of claim 5,
Wherein a tension spring is disposed on the hinge shaft and one end of the tension spring is in contact with the base body and the other end opposite to the one end of the tension spring is disposed in the top plate. 6. The method of claim 5,
Wherein a thickness of a portion of the guide block where the guide block transport groove is formed is thinner than a portion of the guide block where the guide block transport groove is not formed, so that a step is formed. The method according to claim 1,
Wherein the base body is formed with a clamper for clamping the top plate and the lever plate at the same time, and the clamping unit is clamped to the clamper on the top plate and the lever plate, respectively. The method according to claim 1,
Wherein a gap of 0.3 mm to 1.0 mm is formed between the terminal and the connection terminal in a state in which the top plate is disposed parallel to the base body and the lever plate is disposed not parallel to the base plate. The method according to claim 1,
Wherein the module pusher includes a spring for pressing the upper surface of the camera module regardless of a height deviation of the camera module, Test device.

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