KR101850937B1 - Camera module automatic test socket - Google Patents

Abstract

The present invention relates to an automatic test socket for a camera module, and more particularly, to an automatic test socket for a camera module, which comprises a base 100 on which a guide bracket 130 having a guide groove 131 is installed; A cylinder block 200 in which a piston rod 210 is fixed to the base 100 and an elevation induction bracket 240 is installed on both sides of the guide groove 131 and connected to the connecting shaft; An elevation guide block 300 slidable by the rail in the base 100; And a top plate 400 installed at the top of the lifting guide block 300 and guided to the guide groove 131 by the roller shaft 250 to be moved forward and backward and upward and downward.

Description

A camera module automatic test socket for a camera module,

The present invention relates to a test socket for a camera module, and more particularly, to a test socket for checking whether an operation circuit board included in a CCD camera module built in a mobile phone or a digital camera operates or not. And an automatic test socket for a camera module in which a stable test operation can be performed.

Generally, a camera module, which is mounted on a mobile phone or a digital camera and is composed of a camera installed to capture and store moving images and images, and a PCB connected to the camera, is mounted in a relatively limited space of a mobile phone. And the connector printed on the PCB is formed relatively finely.

Therefore, it is very difficult to measure the electrical connection state after manufacturing and assembling the PCB connected to the lens as described above.

In order to determine whether or not the connection state of the small lens and the connector is defective, a socket having a measuring pin is used. Such a conventional socket has a base frame and a cover frame coupled to the base frame so as to be rotatable by a hinge .

That is, the base on which the camera module is mounted and the cover plate provided with the measurement pin are pivotably coupled to each other by a hinge to form a socket, and the socket includes a test pin block and a connection pin block, After the cover plate is closed, it is connected to the main board and tested.

However, in the conventional socket, the cover plate provided with a plurality of measurement pins is coupled to the base while rotating around the hinge. In this process, the measurement pins of the cover plate are not simultaneously contacted to the circuit pattern, There is a problem in that the measuring pin is tilted and the pressure applied to each measuring pin is different from each other due to contact with the measuring pin so that the end of the measuring pin is uneven or damaged. There is a problem that the circuit pattern of the contacting camera module may be damaged.

Accordingly, a technique has been studied in which a pin block having a measurement pin connected to a camera module can be vertically connected, and a registered patent of the prior art document shows an example of such prior art.

Patent Document 1 discloses a structure in which a pneumatic cylinder, a piston, and a cam are installed, and the sliding block and the cover plate are automatically moved by the action of a pneumatic cylinder. When the pin block is moved up and down by a cam action, Respectively.

Patent Document 2 discloses a camera module of a camera module groove provided at one end of a base with a sliding block and a cover mounted on the upper side of the base and the sliding block and the cover including a pin block and a printed circuit board, And these horizontal and vertical movements are made manually.

In Patent Document 1, although the efficiency of the operation by the automation can be improved, there is a problem that the arrangement of the cam and the pneumatic cylinder and the associated equipment thereof can not be efficiently arranged and operated. In Patent Document 2, There is a problem that the efficiency of the work is very low.

In addition, in Patent Documents 1 and 2, the camera module is mounted in the module groove in common, and the upper cover is horizontally and vertically moved so that the pin block is connected to the camera module. However, It can be finely flowed due to vibration or impact caused by the operation of the device and can not be precisely connected due to momentary contact with the pin block approaching from the upper side and irregular There is a problem that unstable connection occurs due to contact.

Therefore, in the related art, it is possible to reduce the manufacturing cost with a relatively simple structure, and to perform an automatic operation by an effective coupling operation, and to provide a stable fixed state of the camera module, A camera module test socket is required, and Applicant has filed a patent application 10-2015-0129359 as a technique for solving the problem.

In the above-mentioned patent application, two guide brackets are provided on both sides, and a guide groove is formed in the guide bracket so that the roller shaft is guided. One cylinder is installed at the center to advance the roller shaft by pneumatic pressure, The top plate and the like are horizontally and vertically moved according to the orbit of the groove to be combined with the camera module and tested.

This patent application has a simpler structure and enables automatic operation and stable installation and testing of the camera module.

However, the above-mentioned prior application discloses that foreign substances are easily caught in the rail grooves of the guide brackets installed on both sides, and the operation of the apparatus is influenced. Since the guide is guided to the rail grooves on both sides, And there is a problem that the configuration of the device for fixing the camera module without shaking is too complicated, which is against the intention to reduce the cost.

1. Korean Patent No. 10-1308741. 2. Korean Patent No. 10-1387418.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a camera module in which measurement pins connected to a camera module are vertically and uniformly connected to prevent uneven wear and breakage of a camera module and a measurement pin, To provide an automated test socket.

It is another object of the present invention to provide an automatic test socket for a camera module in which measurement pins connected to a camera module are vertically and uniformly connected while horizontal and vertical movements of a device for testing the camera module are automatically performed .

It is a further object of the present invention to provide a camera module that is mounted in a module groove and is automatically and firmly fixed and supported along with the operation of the device so that stable contact and test So that it is possible to realize the automatic test socket for a camera module.

It is another object of the present invention to provide a camera module which can automatically and horizontally and vertically move a device for testing a camera module, can firmly support the camera module in the module groove, The present invention provides an automatic test socket for a camera module which can be connected uniformly to a camera module so that accurate testing can be performed and the overall configuration of the device can be simplified to reduce the manufacturing cost, .

It is still another object of the present invention to provide an automatic test socket for a camera module which enhances the strength of a cylinder and improves precision by unitizing a guide bracket guiding movement of the device.

In order to achieve the above object, the present invention provides a camera module comprising a top plate having a pin block connected to the camera module and a printed circuit board, The automatic test socket for a camera module according to any one of claims 1 to 3, further comprising: a base mounted on one end of the module guide and connected to a pneumatic line so that the camera module can be fixed by suction; A guide bracket fixedly installed in the middle of the upper surface of the base, the guide bracket being provided with guide grooves formed on both sides thereof with a horizontal section and a vertical section formed continuously; A cylinder block that is installed movably in accordance with the supply of air pressure by connecting ends of the pair of piston rods to the base on both sides of the guide bracket; An elevating guide block coupled to the upper side of the cylinder block and installed at both lower ends of the base to move together with the cylinder block on an upper surface of the base and having vertically raised and recessed grooves and spring grooves formed on the upper surface thereof; A pair of lifting and guiding brackets disposed on both sides of the guide bracket and connected to the cylinder block by a connecting shaft so as to be moved together with the cylinder block and having sloped grooves penetrating to both sides in the middle; A slide shaft disposed between the lift brackets and having a slot for holding the guide bracket therebetween and an upper end fixed to a bottom surface of the top plate; A roller shaft provided so as to pass through the inclined grooves of the lift-up guide bracket, the side surfaces of the roller shaft holder, and the guide grooves of the guide bracket at the same time, the roller being inserted into the guide grooves and the inclined grooves; A plurality of elevating shafts are provided on the bottom of the elevating guide block and vertically guided by the elevating grooves of the elevating guide block and elastically upwardly biased by a spring provided in a spring groove of the elevating guide block, The top plate being guided by the lifting guide bracket and the roller shaft holder so that the lifting and lowering can be performed; And the like.

In another aspect of the present invention, the guide groove of the guide bracket is formed with a horizontal section from the upper end of the front vertical section to the rear, and the inclined section is formed downwardly behind the horizontal section.

As a result, the final height after operation of the apparatus can be reduced, thereby avoiding interference with other apparatuses and enhancing the usability of the space.

In another aspect of the present invention, a recess for allowing the guide bracket to pass therethrough is formed at the lower center of the elevating guide block, and a support portion closely contacting the rear end of the elevating guide block is formed at the rear of the cylinder block .

In another aspect of the present invention, the connecting shaft of the elevating guide bracket is integrally assembled by operating the elevating guide block through the elevating guide block and its rear end connected to the cylinder block to operate together, thereby achieving more precise operation.

In another aspect of the present invention, a stopper is provided at a rear end of the base, and a protrusion is formed at an inner lower end of the cylinder block to contact the stopper.

The present invention can accurately and automatically move the top plate accommodating the test pin block in the horizontal and vertical directions and securely fix the camera module by pneumatic pressure in connection with the conveyance, And provides a high-quality test.

The present invention provides an effect that the operation of the device is automatically performed, the camera module is firmly fixed and tested, and the configuration of the device is simplified to reduce the manufacturing cost.

The present invention also provides an effect of increasing the overall space utilization of the device by allowing the top plate to move downward even when moving backward.

The present invention further improves the contact force by bifurcating the cylinder, and the precision of the guide bracket can be further improved by unifying the guide bracket as one unit at the center, and since the guide bracket is disposed at the center, the guide groove is not exposed to the outside, It also provides a possible effect.

1 is a perspective view showing an example of a test socket according to the present invention;
2 is a rear perspective view of the above-mentioned FIG. 1;
3 is an exploded perspective view of a test socket according to the present invention.
4 is a partial perspective view showing an assembly state of a base and a guide bracket in the present invention.
5 is a bottom perspective view of a cylinder block according to the present invention.
6 is an assembled perspective view of a cylinder block and a lifting guide bracket according to the present invention.
7 is a perspective view of an elevation guide block according to the present invention.
8 is a bottom perspective view of the elevation guide block according to the present invention.
9 is a bottom perspective view of a top plate according to the present invention.
10 is a plan view showing a state in which the top plate is moved backward in the present invention.
11 and 12 are sectional views showing the state of the guide bracket portion and the elevation induction bracket portion, respectively, in a state in which the top plate is moved rearward.
FIG. 13 is an image showing the sectional state of FIG. 12; FIG.
Fig. 14 is a plan view of a state in which the top plate is moved forward in the present invention. Fig.
15 is a perspective view of the present invention in a state in which the top plate is moved forward;
16 is a rear perspective view of the top plate in a state in which the top plate is moved forward in the present invention.
17 and 18 are sectional views showing the state of the guide bracket portion and the elevation induction bracket portion in a state in which the top plate is moved forward;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

In the drawings, the same reference numerals are applied to the same names.

FIG. 1 is a perspective view showing an example of a test socket according to the present invention, FIG. 2 is a rear perspective view of FIG. 1, and FIG. 3 is an exploded perspective view of a test socket according to the present invention, The test socket for module (hereinafter referred to as 'socket') is roughly divided into a base 100, a cylinder block 200, an elevation guide block 300 and a top plate 400.

The cylinder block 200 and the elevation guide block 300 are installed so as to be movable forward and backward from the upper surface of the base 100. The top plate 400 is vertically lifted from the upper side of the elevation guide block 300, .

First, the main base 100 is connected to a main PCB, and a module guide 110 is provided at the front center of the upper surface of the base 100, and a module groove 111 in which a camera module is mounted is formed on the upper surface. The module guide portion having the groove 111 may be separately manufactured and assembled detachably to the base 100. The module guide portion may be integrally formed with the base 100. Further, As shown in FIG.

A pneumatic line 112 connected to the front of the module guide 110 is formed at a lower side of the module groove 111 so that the camera module can be firmly fixed by the air pressure when the camera module is seated in the module groove 111 .

A stopper 120 for restricting the backward movement of the cylinder block 200 is provided at the rear of the upper surface of the base 100. The stopper 120 may be a pin or a bolt to adjust the distance in the stopper holder 121 Respectively.

Therefore, the rear limit line of the cylinder block 200 can be adjusted, and in the case of a stopper made of pins, a separate fixing means can be added.

4, a guide bracket 130 is installed in the center of the upper surface of the base 100. The guide bracket 130 is installed in a raised state and has guide grooves 131 having both open sides, Respectively.

The guide groove 131 includes a horizontal section 132 and a vertical section 133. The horizontal section 132 is formed in the forward and backward directions of the base 100, (Not shown).

Therefore, the guide groove 131 is formed in a " - "shape, and the trajectory of the movement of the top plate 400 is shown intact.

The inclined section 134 is further downwardly formed at the rear of the guide groove 131. This means that the top plate 400 which is moved backward is also moved downward from the rear side.

The cylinder block 200 is a pneumatic cylinder, which is installed at the center rear of the base 100 and is pneumatically connected, and is capable of moving forward and backward by itself.

That is, a pair of cylinders of the cylinder block 200 are formed on both sides, and a pair of piston rods 210 to be coupled thereto are positioned on both sides of the guide bracket 130 as shown in FIG. 4, The cylinder block 200 is fixed to the upper surface of the base 100 by means of the piston rod fastener 211. The cylinder block 200 is installed on the piston rod 210 in a state where the cylinder block 200 is not fixed, The cylinder block 200 itself moves.

As shown in FIG. 5, a protrusion 201 is formed at one end of the lower side of the cylinder block 200 to contact the stopper 120. The shape of the cylinder block may be arbitrarily changed .

A pair of lifting and guiding brackets 240 are installed on both sides of the guide bracket 130. The lifting and guiding brackets 240 are connected to the connecting shaft 242 in a rearward direction, 200).

7 and 8, the connecting shaft 242 passes through the elevating guide block 300 before being assembled with the cylinder block 200. For this purpose, A pair of connection holes 302 through which the shaft 242 is passed is formed and the connection shaft 242 is movably fitted in the connection hole 302 so that it is not fixed to the elevation guide block 300 So that the elevating guide block 300 firmly supports the horizontal movement of the connecting shaft 242. [

Therefore, the elevation induction bracket 240 moves together with the cylinder block 200 while being supported by the elevation guide block 300, and an inclined groove 241 having both sides opened is formed therein.

The inclined grooves 241 serve to raise and lower the top plate 400 in cooperation with the guide grooves 131 of the guide bracket 130. The inclined grooves 241 preferably have an inclination angle of 45 degrees.

A roller shaft holder 410 is positioned between the guide rails 240. The roller shaft holder 410 is located inside the guide rails 240 on both sides of the guide bracket 240, And an upper end of the slot 411 is fixed to the bottom surface of the top plate 400 as shown in FIG.

A roller shaft 250 is provided so as to pass through the guide groove 131 of the guide bracket 130 and the side surface of the roller shaft holder 410 and the inclined grooves 241 of the guide bracket 240, The rollers 251 are fitted on the roller shaft 250 in the interval between the guide grooves 131 and the inclined grooves 241 so as to smoothly perform the rolling action according to the movement.

The roller 251 and the roller shaft 250 move along the guide groove 131 of the guide bracket 130 to induce the movement of the top plate 400. The horizontal section of the guide groove 131 The vertical section 133 of the guide groove 131 becomes the vertical stroke distance of the top plate 400 and the inclination section of the guide groove 131 134 becomes the inclined stroke distance of the top plate 400. [

On the other hand, the elevation guide block 300 is installed on the upper side of the cylinder block 200. The elevation guide block 300 is installed to cover the cylinder block 200 as a whole and the lower ends of both sides are connected to the base 100 .

The rail is composed of a fixed rail 310 fixed on the upper surface of the base 100 in the moving direction of the cylinder block and the top plate and the movable rail 311 installed on both sides of the elevating guide block 300 So that the fixed rail 310 and the movable rail 311 are engaged with each other to ensure accurate and firm sliding.

The lifting guide block 300 is installed so as to surround the upper side of the cylinder block 200 and the supporting portion 202 protruding upwardly is formed at the rear end of the cylinder block 200. The supporting portion 202 is supported by the lifting and lowering guide block 300).

The connecting shaft 242 of the lifting guide bracket 240 is assembled to the cylinder block 200 through the connecting hole 302 of the lifting and lowering guide block 300, The guide block 300 is assembled together.

The elevating guide block 300 is connected to the connecting shaft 242 and linearly moves in the same direction as the cylinder block 200 and the elevation guiding bracket 240 but does not operate integrally.

An adjusting screw 203 is provided on the supporting portion 202 to adjust the distance between the rear end of the elevating guide block 300 and the rear supporting portion 202 of the cylinder block 200, And a concave portion 301 is formed on the bottom surface thereof to avoid interference with the guide bracket 130.

A plurality of elevating grooves 320 and spring grooves 330 are formed on the upper surface of the elevating guide block 300. An elevating shaft 420 installed on the bottom surface of the top plate 400 is attached to each of the elevating grooves 320 And a spring 331 for upwardly biasing the top plate 400 is installed in the spring groove 330. As shown in FIG.

The top plate 400 is installed to be able to move up and down from the upper part of the elevation guide block 300. To this end, the upper end of each elevation shaft 420, which is vertically installed in the elevation guide block 300, The upper plate 400 is maintained to be upwardly curved with respect to the elevation guide block 300 by the spring 331. [

The top plate 400 is provided with a top PCB 430 and a pin block 440 and a lens push block 450 are installed in the middle of the top plate 400. The lens push block 450 prevents the top plate 400 from being moved forward The camera module M that is seated in the module groove 111 of the module guide unit 110 is stably pressed.

The pin block 440 is electrically connected to the top PCB 430. The pin block 440 is connected to the camera module M by the movement of the top plate 400 and is tested by circuit connection.

The roller shaft holder 410 is installed on the bottom surface of the top plate 400 and is connected to the roller shaft 250 so that the roller shaft 250 is operated together with the front and back movement and the up and down movement of the roller shaft 250 have.

This is achieved by moving the roller shaft 250 by the movement of the cylinder block 200 and the guide bracket 240 and by moving the roller shaft 250 in accordance with the height of the guide groove 131, Is activated.

A sensor housing 500 is installed at one side of the base 100 to sense the movement of the elevation guide block 300 or the top plate 400 to control the overall operation.

That is, a magnet is installed on the side surface of the elevation guide block 300 or the top plate 400, and the magnet housing is sensed by the sensor housing 500 to control the operation of the cylinder or the like.

In the figure, reference numeral 150 denotes a connector for pneumatic connection.

Hereinafter, the operation of the present invention will be described.

FIG. 10 is a plan view of the top plate 400 in a state in which the top plate 400 is moved rearward in the present invention. As shown in FIGS. 1 and 2, 111 are exposed, and in this state, the middle of the socket 1 of the present invention is shown in cross section in Figs. 11 to 13. Fig.

11 shows the state of the guide bracket 130 located at the center of the socket 1. It can be seen that the roller shaft 250 is located at the rear end of the guide groove 131, 130 and the connecting shaft 242 and the top plate 400 including the inclined grooves 241 are located rearwardly of the elevating guide bracket 240. As shown in FIG.

FIG. 13 is an image of the cross-sectional state of FIG. 12, which shows the coupling relationship between the roller shaft 250, the lifting guide bracket 240, and the roller shaft holder 410.

Here, the inclined grooves 241 of the lifting guide bracket 240 are inclined by themselves, but the overall height covers the entire height of the guide grooves 131.

When the camera module M is inserted into the exposed module groove 111, the camera module M is pressed and fixed to the module groove 111 by the air pressure action through the pneumatic line 112.

When the pneumatic cylinder block 200 is operated in this state, the cylinder block 200, the elevation guide block 300, the elevation induction bracket 240, and the top plate 400 are moved forward together.

That is, when air pressure acts on the cylinder block 200, the cylinder block 200 moves directly because the piston rod 210 is fixed. At this time, the cylinder block 200 is moved up and down by the connecting shaft 242, (240).

At this time, the roller shaft 250, which is simultaneously inserted into the guide groove 131 and the inclined groove 241, is pushed by the inclined grooves 241 of the elevation induction bracket 240 and moves together.

The top plate 400 is also moved by the roller shaft holder 410 connected to the roller shaft 250 and the elevation guide 420 connected to the lower side of the top plate 400 by the elevating shaft 420 The block 300 moves together.

Here, the cylinder block 200, the elevation guide block 300, and the elevation induction bracket 240 are guided by the piston rod 210 and the rails 310 and 311 to perform linear motion, 410 are connected to the roller shaft 250 so that the roller shaft 250 moves up and down according to the height of the guide groove 131 through which the roller shaft 250 moves.

That is, as the roller 251 and the roller shaft 250 move past the inclined section 134 of the guide groove 131, the top plate 400 is gradually moved upward while advancing forward When the roller shaft 250 or the like passes through the horizontal section 132 of the guide groove 131, the top plate 400 also moves horizontally.

The top plate 400 is maintained in a state in which the top plate 400 is elastically upwardly raised with respect to the elevation guide block 300 by the spring 331 so that the roller shaft 250 is also moved upwards in the guide groove 131 and the inclined groove 241 The elastic force is applied.

The elevation guide block 300 is accurately slid by the engagement of the movable rail 311 provided at the lower ends of both sides of the elevation guide block 300 with the fixed rail 310 provided at the base 100, The elevation guide block 300 stably supports the top plate 400 to maintain the accurate position.

A roller 251 is provided on the roller shaft in a section between the guide groove 131 and the inclined groove 241 so that the roller 251 is in contact with the inner surface of the guide groove 131 and the inclined groove 241, .

The cylinder block 200 and the elevation guide block 300 and the elevation induction bracket 240 and the top plate 400 continue to move forward and the roller shaft 250 terminates the horizontal section 132 of the guide groove 131 The roller shaft 250 can no longer move forward and the top plate 400 and the elevation guide block 300 connected by the roller shaft 250 and the roller shaft holder 410 are stopped from advancing.

The pin block 430 and the lens push block 440 of the top plate 400 are positioned at the vertical upper end of the camera module M inserted into the module groove 111.

The inclined grooves 241 of the lifting guide bracket 240 push the roller shaft 250 downward and the roller shaft 250 Is moved downward through the vertical section 133 of the guide groove 131.

That is, even during the horizontal movement, the inclined groove 241 continuously moves the roller shaft 250 while pushing it forward and downward, and the roller shaft 250, which is no longer moved horizontally, moves downward to the vertical section 133 This is due to the combined action of the inclined grooves 241 of 45 DEG and the guide grooves 131 continuing in the horizontal and vertical sections.

The roller shaft 250 and the roller shaft holder 410 are lowered while the cylinder block 200 and the lifting guide bracket 240 are continuously moved horizontally and the top plate 400) is also lowered.

Here, the top plate 400 is accurately guided and descended by the lifting shaft 420 while resisting elasticity of the spring 331, so that the lifting guide block 300 is in a stopped state at this time.

As a result, the entire horizontal movement of the cylinder block 200 and the vertical movement of the top plate 400 are smoothly connected to each other by one operation, .

Fig. 14 is a plan view of the present invention in which the top plate is moved forward; Fig. 15 is a perspective view of the present invention in which the top plate is moved forward; 17 and 18 are sectional views showing the state of the guide bracket part and the lifting guide bracket part in a state in which the top plate is moved forward and the roller shaft 250 is in the vertical section of the guide groove 131 133) from the bottom to the bottom.

When the top plate 400 is vertically lowered as the roller shaft 250 descends, the lens block 440 of the top plate 400 presses the camera module M, Is connected to the circuit pattern of the module (M).

In this state, the test is performed by an electrical signal. When the test is completed, the cylinder block 200 is retreated back by the operation of the cylinder block 200 and the top plate 400 and the roller shaft holder 410 And then the top plate 400, the elevation guide block 300, the elevation guide bracket 240, etc. are horizontally moved rearward and returned to the original position.

Since the top plate 400 is always upwardly biased by the spring 331, when the cylinder block 200 is retracted, the inclined groove 241 pushes up the roller shaft 250, So that it is more smoothly moved upward.

The roller shaft 250 is further moved downward along the inclined section 134 through the horizontal section 132 to move backward, and the top plate 400 also moves downward and returns.

In this state, the height of the top plate 400 is lowered, thereby reducing the overall height of the device, thereby enhancing the space efficiency with other devices.

When the cylinder block 200 is continuously moved backward, the roller shaft 250 may be caught by the rear end of the guide groove 131 to limit the backward movement of the cylinder block 200. Before the stopper 120 contacts the protrusion 201 So that the backward movement is limited so that the operation of the devices is not impaired, and the limit line can be adjusted by the adjustment of the stopper 120.

A magnet is embedded in a side surface of the elevation guide block 300 or the top plate 400 so that sensing of the magnet by the movement of the cylinder block 200 or the like is performed by the sensor housing 500, The operation of the cylinder block 200 and the like can be controlled.

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 illustration, Embodiments incorporating replaceable components as equivalents in the components of the claims may be included within the scope of the present invention. For example, the guide bracket, the cylinder block, the elevation guide block, and the like may be arbitrarily changed depending on the relationship with other devices.

100; A base 110; Module guide portion
111; Module groove 112; Pneumatic line
120; Stopper 121; Stopper holder
130; Guide bracket 131; Guide groove
132; Horizontal section 133; Vertical section
134; A slope section 150; Connector
200; A cylinder block 201; projection part
202; A support 203; Adjusting screw
210; A piston rod 211; Piston rod fastener
240; A lifting guide bracket 241; Oblique groove
242; Connection axis 250; Roller shaft
251; Roller 300; Lift guide block
301; A recess 302; Connecting hole
310; Fixed rail 311; Movable rail
320; A lifting groove 330; Spring groove
331; Spring 400; Top plate
410; Roller shaft holder 411; slot
420; Lifting shaft 430; Top PCB
440; Pin block 450; Lens push block
500; Sensor housing

Claims (5)

A top plate having a pin block connected to the camera module and a printed circuit board having a module guide unit on which the camera module is seated and connecting and testing the camera module while moving the top plate, An automatic test socket for a camera module,
A base mounted on a front end of the module guide portion and connected to a pneumatic line so that the camera module can be fixedly attached thereto;
A guide bracket fixedly installed in the middle of the upper surface of the base, the guide bracket being provided with guide grooves formed on both sides thereof with a horizontal section and a vertical section formed continuously;
A cylinder block that is installed movably in accordance with the supply of air pressure by connecting ends of the pair of piston rods to the base on both sides of the guide bracket;
An elevating guide block coupled to the upper side of the cylinder block and installed at both lower ends of the base to move together with the cylinder block on an upper surface of the base and having vertically raised and recessed grooves and spring grooves formed on the upper surface thereof;
A pair of lifting and guiding brackets disposed on both sides of the guide bracket and connected to the cylinder block by a connecting shaft so as to be moved together with the cylinder block and having sloped grooves penetrating to both sides in the middle;
A slide shaft disposed between the lift brackets and having a slot for holding the guide bracket therebetween and an upper end fixed to a bottom surface of the top plate;
A roller shaft provided so as to pass through the inclined grooves of the lift-up guide bracket, the side surfaces of the roller shaft holder, and the guide grooves of the guide bracket at the same time, the roller being inserted into the guide grooves and the inclined grooves;
A plurality of lifting shafts are provided on a bottom surface of the lifting guide block and are vertically guided by the lifting grooves of the lifting guide block and are upwardly biased by a spring provided in a spring groove of the lifting guide block, The top plate being guided by the lifting guide bracket and the roller shaft holder so that the lifting and lowering can be performed;
Wherein the first and second test terminals are electrically connected to each other.
The method according to claim 1,
Wherein the guide groove of the guide bracket is formed with a horizontal section from the upper end of the front vertical section to the rear side and an inclined section is formed downwardly behind the horizontal section.
The method according to claim 1,
Wherein a guide portion for passing the guide bracket is formed at a lower center of the elevation guide block and a support portion which is in close contact with a rear end portion of the elevation guide block is formed at the rear of the cylinder block. Test socket.
The method according to claim 1,
Wherein the connection shaft of the lift-up guide bracket passes through an elevation guide block, and a rear end thereof is connected to the cylinder block.
The method according to claim 1,
Wherein a stopper is provided at a rear end of the base, and a protrusion is formed at an inner lower end of the cylinder block to contact the stopper.

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