KR20170119509A - Finger scan sensor test socket - Google Patents

Abstract

A fingerprint sensor test socket is initiated. A fingerprint recognition sensor test socket of the present invention comprises: a base on which a fingerprint recognition sensor is seated; A middle cover rotatably coupled to the base and restricting the flow of the fingerprint recognition sensor; A push member movably coupled to the middle cover and equipped with a conductive rubber for pressing the sensing portion of the fingerprint recognition sensor; A top cover rotatably coupled to the base; And a pressing member mounted on the top cover and coupled with a conductive rubber pressing the sensing part. According to the present invention, it is possible to provide a fingerprint sensor test socket in which only a certain pressure is transmitted to a sensing area of a sensing area even when the operator presses the sensing device with excessive force in the process of driving a program of the test equipment.

Description

{FINGER SCAN SENSOR TEST SOCKET}

The present invention relates to a fingerprint recognition sensor test socket, and more particularly, to a fingerprint recognition sensor test socket in which only a certain pressure is transmitted to a sensing area of a sensing unit even when an operator presses a program of the test equipment with excessive force Lt; / RTI >

The fingerprint sensor is an input image device for acquiring image information of a fingerprint, which is a characteristic difference of each person in the fingerprint recognition technology. The acquired fingerprint image is obtained by extracting characteristics of the fingerprint and then registering it in the database And compares them with the feature information of the user who has been registered.

Fingerprint images are obtained in a variety of ways including optical, capacitive sensing semiconductor devices, ultrasonic, thermal, noncontact, or combinations of these methods.

A fingerprint recognition sensor used in a semiconductor device system includes a plurality of sensing cells arranged in a matrix form. When a finger is brought into contact with a fingerprint recognition sensor, a response output from the sensing cells according to the capacitance formed between the sensing cells and the finger The signal is different. Using this characteristic, it is possible to determine whether the sensing cell touches the ridge or the valley of the fingerprint, and the fingerprint image is generated by synthesizing the response signals output from the sensing cells.

However, if there is an abnormality in some of the sensing cells, there is an error in the outputted fingerprint image, and the accuracy of the fingerprint authentication is lowered. Therefore, it is necessary to test the performance of the fingerprint recognition sensor before attaching the fingerprint recognition sensor to the fingerprint recognition device.

In the testing process of the fingerprint sensor, a test socket is used in which the base portion of the fingerprint sensor is connected to the test device in a circuit and the sensing portion of the fingerprint sensor is fixed to the test position. Conventional test sockets consist of a base on which a fingerprint sensor is placed and a simple structure of a cover that covers or opens the top of the base. The sensing part is exposed upward through the hole formed in the cover in the state of being mounted on the test socket.

The worker in the test process must first run the test equipment program before touching the finger on the sensing unit after mounting the fingerprint sensor in the test socket (to generate the fingerprint image). Even if the fingerprint recognition sensor is mounted on the test socket, the fingerprint image can not be generated even if a finger is touched to the sensing portion unless the program of the test equipment is driven.

Most of the fingerprint sensor test programs are programmed by tapping the sensing part with finger several times (about 3 times). That is, when the sensing unit senses that the sensing unit is tapped three times, the test equipment is set to start a program for generating a fingerprint image, and after the program is driven, a finger is again touched to the sensing unit so that the test equipment is output from the sensing cells A fingerprint image is generated by combining the response signals.

However, since the sensing part has to be pressed at a certain pressure or more to form a sufficient electrostatic capacity for generating a response signal, there is a problem that the program is not operated if the operator is pressed at a constant pressure or less even once in the process of pressing three times. If the program is not activated, it takes a long time for the test to be confirmed by pressing the sensing part again. This is a major factor in lowering production efficiency in test lines that need to test thousands of fingerprint sensors every day.

However, if the sensing part is pressed with excessive pressure several times in order to prevent this, an excessive impact is concentrated on some sensing cells, and the fingerprint recognition sensor may be damaged during the testing process.

On the other hand, the operator of the test process touches the finger or touches the sensing unit after the program operation of the test apparatus or generates a rubbed fingerprint image. However, the method of directly touching the sensing part by the operator has a problem that the reliability of the performance test is low because the pressure and angle of the finger are changed during each test even if the same operator does.

SUMMARY OF THE INVENTION An object of the present invention is to provide a fingerprint sensor test socket in which a constant pressure is transmitted to a sensing area of a sensing area even when the operator presses the sensing device with excessive force in the process of driving a program of the test equipment.

Also, it is an object of the present invention to provide a fingerprint recognition sensor test socket which can accurately and quickly test the fingerprint recognition sensor by keeping the pressing area, angle and pressure of the sensing part constant under the best setting conditions.

The above object is achieved according to the present invention by providing a fingerprint recognition apparatus comprising: a base on which a fingerprint recognition sensor is seated; A middle cover rotatably coupled to the base and restraining a flow of the fingerprint recognition sensor; A push member movably coupled to the middle cover, the push member being mounted with a conductive rubber pressing the sensing portion of the fingerprint recognition sensor; A top cover rotatably coupled to the base; And a pressing member mounted on the top cover and coupled with a conductive rubber pressing the sensing portion.

Wherein the middle cover is formed with a rail through which the push member slides and the push member is slid along the rail in a state in which the middle cover restrains the flow of the fingerprint recognition sensor, To enter or exit.

The push member includes: a body slidably moving along the rail; And a pusher mounted with the conductive rubber and pressed by the user toward the sensing portion from the body.

An elastic member may be interposed between the conductive rubber and the pusher, and the elastic member may be configured to absorb an impact applied to the sensing unit while being compressed when the conductive rubber is in contact with the sensing unit.

Wherein the pressing member is rotatably mounted on the top cover, and the pressing member is rotated by its own weight so that the conductive rubber and the sensing unit form parallel contact surfaces during rotation of the top cover toward the base, To rotate relatively.

The pressing member includes: a rotating portion rotatably coupled to the top cover; And a moving unit to which the conductive rubber is mounted and which is urged from the rotation unit toward the sensing unit by elastic means, and the elastic means compresses when the conductive rubber is in contact with the sensing unit, .

The rotating portion may be provided with a boundary means for restricting the moving distance of the moving portion by the compression of the elastic means so as to be adjustable and adjusting the compression amount of the conductive rubber by adjusting the boundary means.

The rotating portion may be formed with a through hole, and the boundary means may be screwed to the through hole to adjust a length of the protruding portion into a moving section of the moving portion.

According to the present invention, by pushing the push member with the conductive rubber movably in the middle cover, even if the operator presses with excessive force in the process of driving the program of the test equipment, only a certain pressure is transmitted to the sensing portion The present invention can provide a fingerprint sensor test socket.

Further, in the process of rotating the top cover toward the base, the pressing member relatively rotates with the top cover due to its own weight to form a contact surface in which the conductive rubber and the sensing portion are parallel to each other, so that the pressing area, angle and pressure of the sensing portion are constant And a fingerprint sensor test socket can be provided which is adapted to test the fingerprint recognition sensor accurately and quickly.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view showing a state in which a top cover of a fingerprint sensor test socket of the present invention is closed. Fig.
2 is a view showing a state in which the top cover and the middle cover of the fingerprint sensor test socket of FIG. 1 are opened.
3 is a view showing a state in which the middle cover of the fingerprint sensor test socket of FIG. 1 is closed.
4 is a view showing a state in which the push member of the fingerprint sensor test socket of FIG. 1 is moved along the rail of the middle cover.
Figs. 5 and 6 are views showing a use state of a push member of the fingerprint recognition sensor test socket of Fig. 1; Fig.
7 to 9 are views showing a state in which the top cover and the pressing member of the fingerprint sensor test socket of Fig. 1 are relatively rotated.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, the well-known functions or constructions are not described in order to simplify the gist of the present invention.

The fingerprint recognition sensor test socket of the present invention is configured so that even when the operator presses with excessive force in the course of driving the program of the test equipment, only a certain pressure is transmitted to the sensing portion in a predetermined area.

In addition, the fingerprint sensor test socket of the present invention is configured to accurately and quickly test the fingerprint recognition sensor while keeping the area, angle, and pressure of the sensing portion constant at the best setting conditions.

FIG. 1 is a view showing a state in which a top cover of a fingerprint sensor test socket of the present invention is closed. FIG. 2 is a view showing a state in which a top cover and a middle cover of a fingerprint sensor test socket of FIG. FIG. 4 is a view showing a state in which the push member of the fingerprint sensor test socket of FIG. 1 is moved along the rail of the middle cover, and FIGS. 5 and 6 are diagrams showing a state where the middle cover of the fingerprint sensor test socket of FIG. Fig. 7 is a view showing a state in which the push member of the fingerprint recognition sensor test socket of Fig. 1 is in use; Figs. 7 to 9 are views showing a state in which the presser member and the top cover of the fingerprint sensor test socket of Fig.

As shown in FIGS. 1 and 2, the fingerprint sensor test socket 10 of the present invention is configured such that even if the operator presses with excessive force in the process of driving the program of the test equipment, And includes a base 100, a middle cover 200, a push member 300, a top cover 400, and a pressing member 500.

In order to facilitate understanding, the upper and lower portions will be described below in the state shown in the drawings. In the description of the middle cover 200, the push member 300, the top cover 400, and the pressing member 500, the upper and lower sections are based on the closed state as shown in FIG.

As shown in Fig. 2, the base 100 has a configuration in which the fingerprint recognition sensor 1 is seated, and is formed in a rectangular parallelepiped block shape. A sensing guide unit 110 on which the sensing unit 2 is mounted and a substrate guide unit 120 on which the substrate unit 3 is mounted are installed on the upper surface of the base 100.

Although not shown, the base 100 is coupled to the upper surface of a testing device (not shown) through fastening means such as bolts. On the upper surface of the substrate guide part 120, terminals for forming electrical contacts with the substrate part 3 are provided. The base 100, when coupled to the top surface of the test apparatus, forms an electrical contact with the circuit board of the test apparatus through its bottom surface. Therefore, the substrate portion 3 is electrically connected to the circuit board of the test apparatus while being seated on the substrate guide portion 120.

As shown in FIGS. 2 and 3, the middle cover 200 is rotatably coupled to the base 100 as a configuration for restricting the flow of the fingerprint recognition sensor 1. The middle cover 200 and the base 100 are rotatably engaged by a pin (hereinafter referred to as a 'first cover pin 230'). The first cover pin 230 is fitted with a torsion spring. The middle cover 200 is maintained in the open state of FIG. 2 by the torsion spring.

The operator places the fingerprint recognition sensor 1 on the sensing guide unit 110 and the substrate guide unit 120 together with the middle cover 200 opening the upper portion of the base 100 as shown in FIG. Then, the operator rotates the middle cover 200 to close the upper portion of the base 100 as shown in FIG.

The base 100 is provided with a rotation lever 130. The rotation lever 130 is rotatably coupled to the base 100 by a pin (hereinafter referred to as a lever pin 131). A torsion spring (not shown) is mounted on the lever pin 131. The rotation lever 130 forms a rotational force in a direction to be caught by the first stopping jaw 240 of the middle cover 200 by the torsion spring. When the user presses the rotation lever 130 in the state of FIG. 3, the constraint between the rotation lever 130 and the first engagement protrusion 240 is released, and the middle cover 200 is rotated to the open state of FIG.

The middle cover 200 is formed with an exposure hole 201 for exposing the sensing unit 2 upward in a state where the upper portion of the base 100 is closed (see FIG. 3). The exposure hole 201 functions as a path for allowing the conductive rubber 530 to enter the sensing portion 2 in the process of closing the upper portion of the middle cover 200 by the top cover 400.

As shown in FIG. 2, the middle cover 200 is formed with a pressing portion 220 that pushes the base portion 3 downward while the upper portion of the base 100 is closed. When the pressing portion 220 pushes the substrate portion 3 toward the substrate guide portion 120 as the middle cover 200 closes the upper portion of the base 100, The electrical contact between the substrate portion 3 and the substrate guide portion 120 is closely contacted.

As shown in FIGS. 2 to 4, the middle cover 200 has a rail 210 on which the push member 300 slides. The rails 210 are provided in pairs and are provided on both sides of the exposure hole 201 in parallel with each other.

6, the push member 300 includes a body 310, a pusher 320, and a conductive rubber (not shown) for pressing the sensing unit 2 at a predetermined pressure in the process of driving a program of the test equipment. 330).

The body 310 is configured to slide along the rail 210, and is formed in a block shape. The body 310 is provided with a pair of mounting portions 311 mounted on the rail 210. As shown in FIGS. 3 and 4, when the user pushes the body 310 in the longitudinal direction of the rail 210, the body 310 slides along the rail 210 and slides.

2 and 5, the rail 210 is shown in the form of a circular bar, and the mounting portion 311 is shown as a circular rod inserted. However, the coupling structure between the rail 210 and the mounting portion 311 is not limited thereto, It is possible to change the structure to various structures that allow the body 310 to slide on the upper surface of the cover 200.

As shown in FIGS. 5 and 6, the body 310 has an insertion hole 313 through which the pusher 320 is vertically inserted. The pusher 320 is configured to be pushed by the user toward the sensing unit 2 from the body 310 and includes a pushing part 321 and an extension part 322.

The pushing portion 321 is pressed downward by the user's hand and the upper end thereof is exposed to the upper side of the body 310 through the insertion hole 313. An insertion groove 323 into which the conductive rubber 330 is inserted is formed in the lower portion of the pusher 320.

The extension portion 322 extends laterally from the lower end of the pushing portion 321 and the body 310 and the extension portion 322 form a coupling force by the bolts 325 and the compression spring 326. The lower end of the bolt 325 is screwed to the extended portion 322, and the head thereof is spaced upward from the body 310. The compression spring 326 is interposed between the head of the bolt 325 and the body 310 in a compressed state.

5, the extension portion 322 is pressed against the step portion 312 by the urging force of the resilient recovery force of the compression spring 326 in a state in which the user does not press the pressing portion 321.

6, when the user presses the pressing portion 321, the compression spring 326 is compressed and the expanding portion 322 is lowered until the lower end thereof contacts the middle cover 200. As shown in FIG. That is, the upper surfaces of the step portion 312 and the middle cover 200 form an interval in which the extending portion 322 moves in the vertical direction in the insertion hole 313. When the user then releases the pushing portion 321, the expanding portion 322 is raised by the elastic recovery force of the compression spring 326 and is brought into close contact with the step.

As shown in Fig. 5, the conductive rubber 330 is provided in the insertion groove 323 as a structure for forming capacitance with the sensing cells of the sensing unit 2. Fig. The conductive rubber 330 is made of conductive rubber. Conductive rubber is used as a rubber for dispersing powder of graphite, noble metal or the like in rubber to cause electric current to flow, and is used for switches and conductor parts which require both conductivity and elasticity. The conductive rubber is a known technique, and a detailed description thereof will be omitted.

As shown in FIG. 5, the conductive rubber 330 includes a contact portion 331 and an enlarged portion 332. The contact portion 331 is provided at a lower end portion of the conductive rubber 330 as a portion forming a contact surface with the sensing portion 2. [ The enlarged portion 332 extends laterally from the upper end of the contact portion 331 and a plurality of elastic members 333 (compression springs) are interposed between the enlarged portion 332 and the upper end of the insertion groove 323.

5, the normally enlarged portion 332 is pressed downward by the elastic restoring force of the elastic member 333, so that the edge is brought into close contact with the head of the locking bolt 324. The locking bolt 324 is coupled to the body 310 with its head protruding into the insertion groove 323 under the enlarged portion 332. The enlarged portion 332 is spaced apart from the upper end of the insertion groove 323 by a predetermined distance in a state of being closely attached to the head of the locking bolt 324 by the resilience of the elastic member 333.

6, when the user presses the pushing part 321, the extension part 322 descends until the lower end of the extension part 322 contacts the upper surface of the middle cover 200. In this process, (2). The elastic member 333 is compressed when the conductive rubber 330 is in contact with the sensing unit 2, thereby absorbing the shock applied to the sensing unit 2. [

Even if the user presses the pushing part 321 with an excessive force, the extension part 322 comes into contact with the upper surface of the middle cover 200 and the downward distance of the pusher 320 is kept constant, while the elastic member 333 The pressure applied to the sensing unit 2 is absorbed by the sensing unit 2, and only a predetermined pressure is transmitted to the sensing unit 2 over a predetermined area.

Most of the fingerprint sensor test programs are programmed by tapping the sensing part with finger several times (about 3 times). That is, when the sensing unit senses that the sensing unit is tapped three times, the test equipment is set to start a program for generating a fingerprint image, and after the program is driven, a finger is again touched to the sensing unit so that the test equipment is output from the sensing cells A fingerprint image is generated by combining the response signals.

However, since the sensing part has to be pressed at a certain pressure or more to form a sufficient electrostatic capacity for generating a response signal, there is a problem that the program is not operated if the operator is pressed at a constant pressure or less even once in the process of pressing three times. If the program is not activated, it takes a long time for the test to be confirmed by pressing the sensing part again. This is a major factor in lowering production efficiency in test lines that need to test thousands of fingerprint sensors every day.

However, if the sensing part is pressed with excessive pressure several times in order to prevent this, an excessive impact is concentrated on some sensing cells, and the fingerprint recognition sensor may be damaged during the testing process.

The fingerprint sensor test socket 10 of the present invention can solve the problems described above by attaching the push member 300 to the middle cover 200. [ That is, the fingerprint recognition sensor test socket 10 of the present invention is different from the conventional technique in which the operator manually touches the sensing unit a plurality of times to drive the program of the test apparatus, and the middle cover 200 moves the fingerprint sensor 1 The pushing member 300 is slid into the rotation section of the top cover 400 and the pusher 320 is pressed so that the contact portion 331 can be moved even if the force or angle that the user presses the pusher 320 varies, The area, angle, and pressure of the pressing portion 2 are kept constant, and the program can be accurately and quickly driven.

4, the user pushes the body 310 in the state shown in FIG. 3 to push the push member 300 out of the rotation section of the top cover 400 . The user then rotates the top cover 400 to close the top of the middle cover 200.

7 to 9, the top cover 400 is rotatably coupled to the base 100 as a structure for moving the pressing member 500. As shown in Fig. The top cover 400 and the base 100 are rotatably coupled by a pin (hereinafter referred to as 'second cover pin 410'). The second cover pin 410 is fitted with a torsion spring. The top cover 400 is kept in the open state of Fig. 3 by the torsion spring.

3, the operator rotates the top cover 400 to close the upper portion of the middle cover 200, as shown in FIG. 1, in a state where the push member 300 is separated from the rotation section of the top cover 400.

The top cover 400 is provided with a rotation lever 420. The rotation lever 420 is rotatably coupled to the top cover 400 by a pin (hereinafter referred to as a 'lever pin 421'). A torsion spring (not shown) is mounted on the lever pin 421. The rotation lever 420 forms a rotational force in a direction to be caught by the second engagement protrusion 101 of the base 100 by the torsion spring. When the user presses the rotation lever 420 in the state of FIG. 1, the constraint between the rotation lever 420 and the second locking jaw 101 is released, and the top cover 400 is rotated to the open state of FIG.

7 to 9, the top cover 400 is formed with an insertion portion 430 into which the pressing member 500 is inserted. The insertion portion 430 is provided in a groove shape in which the pressing member 500 is inserted from below.

The pressing member 500 is configured to interlock the rotation of the top cover 400 and the pressing of the sensing unit 2 and includes a rotating unit 510, a moving unit 520 and a conductive rubber 530.

The rotating part 510 is rotatably coupled to the top cover 400 in the inserting part 430 and forms a block shape together with the moving part 520. The rotation part 510 is rotatably coupled to the top cover 400 by the shaft pin 511. The axis pin 511 forms a rotation axis parallel to the second cover pin 410. Holes into which the shaft pins 511 are inserted are formed in the rotation part 510 and the top cover 400.

The shaft pin 511 rotatably connects the rotation part 510 and the top cover 400 to each other above the gravity direction from the entire gravity center of the pressing member 500. [ The lower end surface of the contact portion 531, which will be described later, forms a plane perpendicular to the extension line connecting the center of gravity of the pressing member 500 and the shaft pin 511.

As shown in FIG. 7, the rotation part 510 is formed with an insertion hole 512 into which the moving part 520 is inserted. A plurality of elastic means 521 (compression springs) are interposed between the upper end of the insertion hole 512 and the moving part 520.

8, the moving part 520 is pressed downward by the elastic recovery force of the elastic means 521 until the conductive rubber 530 presses the sensing part 2, so that the edge is caught on the head of the locking bolt 514 And maintains a close contact state. The locking bolt 514 is engaged with the rotation part 510 with its head protruding into the insertion hole 512. The moving part 520 is spaced apart from the upper end of the insertion hole 512 by a predetermined distance in a state of being closely attached to the head of the locking bolt 514 by the elastic recovery force of the elastic means 521. [

9, when the user rotates the top cover 400 to completely cover the upper portion of the middle cover 200, the elastic means 521 is moved in a direction in which the pressing portion 531 presses the sensing portion 2 And is compressed between the moving part 520 and the upper end of the insertion hole 512. The elastic means 521 is compressed until the moving part 520 comes into contact with the boundary means 513 to absorb the impact applied to the sensing part 2. [

As shown in FIGS. 7 to 9, the conductive rubber 530 is inserted into the groove of the moving part 520, and is configured to form an electrostatic capacity with the sensing cells of the sensing part 2. The conductive rubber 530 is made of conductive rubber.

The conductive rubber 530 includes a contact portion 531 and a coupling portion 532. The contact portion 531 is provided at the lower end of the conductive rubber 530 as a portion forming a contact surface with the sensing portion 2. The engaging portion 532 is a portion to be inserted into the groove of the moving portion 520. The engaging portion 532 partially absorbs an impact generated when the contacting portion 531 presses the sensing portion 2 by self elastic deformation.

The rotation unit 510 is formed with a through hole through which the boundary unit 513 is screwed. The through holes are not marked with reference numerals, but should be understood as a hole into which the boundary means 513 is inserted.

7 to 9, the boundary means 513 is configured to limit the moving distance of the moving part 520 by the compression of the elastic means 521 so as to be adjustable, and is provided with a tongue bolt or the like. The lower end of the boundary means 513 protrudes into the insertion hole 512 in a state where the boundary means 513 is screwed into the through hole.

9, when the user rotates the top cover 400 to completely cover the upper portion of the middle cover 200, the elastic means 521 is rotated in the direction in which the pressure of the pressing portion 531 (the pressing portion 531 against the sensing portion 2) The moving part 520 is lifted up until it is contacted with the boundary means 513.

A hole is formed in the top cover 400 to allow the tool to enter the boundary means 513. When the length of the boundary means 513 protruded into the moving section is adjusted using a tool such as a screwdriver or a wrench, the distance by which the moving section 520 ascends when the top cover 400 is closed can be adjusted, 400 can be easily closed by pressing the sensing portion 2 while the conductive rubber 530 is compressed.

7, when the top cover 400 is opened, the center of gravity of the pressing member 500 is positioned on the right side of the shaft cover 511, that is, on the middle cover 200 side in the illustrated state. Therefore, the pressing member 500 forms a clockwise rotational force due to gravity in the illustrated state. The rotating portion 510 can rotate about the axial pin 511 by the above-described rotational force, but the rotation center 510 can be rotated about the axial pin 511 by the interference by the inner surface of the insertion portion 430 (the center of gravity of the pressing member 500 is perpendicular to the axial pin 511 And is rotated about 1 degree in the clockwise direction).

The pressing member 500 is rotatably formed around the shaft pin 511 by its own weight so that the top cover 400 is rotated before the upper portion of the middle cover 200 is completely covered The center of gravity of the pressing member 500 is moved in a direction perpendicular to the axis pin 511 in a rotation section of about 1 degree (rotated in FIG. 9 in FIG. 8) The bottom surface of the contact portion 531 and the upper surface of the sensing portion 2 form a contact surface parallel to each other when the rotation lever 420 is engaged with the second stopping protrusion 101 as shown in FIG. do.

Conventional test sockets consist of a base on which a fingerprint sensor is placed and a simple structure of a cover that covers or opens the top of the base. The sensing part is exposed upward through the hole formed in the cover in the state of being mounted on the test socket.

The worker in the test process attaches the fingerprint sensor to the test socket, and then touches the finger or touches the sensing part or generates a rubbed fingerprint image. However, the method of directly touching the sensing part by the operator has a problem that the reliability of the performance test is low because the pressure and angle of the finger are changed during each test even if the same operator does.

The fingerprint recognition sensor test socket 10 of the present invention can solve the problem as described above by rotatably mounting the pressing member 500 on the top cover 400 by its own weight. That is, in the process of closing the top cover 400, the bottom surface of the contact portion 531 and the top surface of the sensing portion 2 are in close contact with each other while forming a contact surface parallel to each other in the process of closing the top cover 400, The area, angle, and pressure of the sensor 531 pressed against the sensing unit 2 are kept constant under the best setting conditions.

According to the present invention, by pushing the push member with the conductive rubber movably in the middle cover, even if the operator presses with excessive force in the process of driving the program of the test equipment, only a certain pressure is transmitted to the sensing portion The present invention can provide a fingerprint sensor test socket.

Further, in the process of rotating the top cover toward the base, the pressing member relatively rotates with the top cover due to its own weight to form a contact surface in which the conductive rubber and the sensing portion are parallel to each other, so that the pressing area, angle and pressure of the sensing portion are constant And a fingerprint sensor test socket can be provided which is adapted to test the fingerprint recognition sensor accurately and quickly.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have. Accordingly, it should be understood that such modifications or alterations should not be understood individually from the technical spirit and viewpoint of the present invention, and that modified embodiments fall within the scope of the claims of the present invention.

10: Test socket
100: base 300: push member
110: sensing guide unit 310: body
120: substrate guide portion 311:
130: rotation lever 312:
131: lever pin 313: insertion hole
101: second stop jaw 320: pusher
200: middle cover 321:
210: rail 322:
220: pressing portion 323: insertion groove
201: Exposure hole 324: Retaining bolt
230: first cover pin 325: bolt
240: first stop jaw 326: compression spring
500: pressing member 330: conductive rubber
510: rotating part 331:
511: Axial pin 332: Magnifying section
512: insertion hole 333: elastic member
513: boundary means 400: top cover
514: latching bolt 410: second cover pin
520: moving part 420: rotating lever
521: Elastic means 421: Lever pin
530: conductive rubber 430: inserting portion
531:
532:
1: Fingerprint sensor
2: sensing unit
3:

Claims (8)

A base on which the fingerprint recognition sensor is seated;
A middle cover rotatably coupled to the base and restraining a flow of the fingerprint recognition sensor;
A push member movably coupled to the middle cover, the push member being mounted with a conductive rubber pressing the sensing portion of the fingerprint recognition sensor;
A top cover rotatably coupled to the base; And
And a pressing member which is attached to the top cover and to which a conductive rubber pressing the sensing unit is coupled. The method according to claim 1,
A rail on which the push member slides is formed on the middle cover,
Wherein the push member slides along the rail while the middle cover restrains the flow of the fingerprint sensor and enters or leaves the rotation section of the top cover. 3. The method of claim 2,
The push member includes:
A body slidably moving along the rail; And
And a pusher mounted with the conductive rubber and pressed by the user toward the sensing portion from the body. The method of claim 3,
An elastic member is interposed between the conductive rubber and the pusher,
Wherein the elastic member absorbs an impact applied to the sensing unit while being compressed when the conductive rubber is in contact with the sensing unit. The method according to claim 1,
The pressing member is rotatably mounted on the top cover,
Wherein the pressing member is rotated relative to the top cover by its own weight so that the conductive rubber and the sensing unit form a contact surface parallel to each other during the rotation of the top cover toward the base. 6. The method of claim 5,
The pressing member
A rotating part rotatably coupled to the top cover; And
And a moving part to which the conductive rubber is coupled and which is urged from the rotating part toward the sensing part by elastic means,
Wherein the elastic means absorbs an impact applied to the sensing unit while being compressed when the conductive rubber is in contact with the sensing unit. The method according to claim 6,
Characterized in that the rotating portion is provided with a boundary means for restricting the movement interval of the moving portion by the compression of the elastic means in an adjustable manner and the compression amount of the conductive rubber is adjusted by the adjustment of the boundary means socket. 8. The method of claim 7,
A through hole is formed in the rotating portion,
Wherein the boundary means is screwed into the through hole to adjust the length of the finger protruding into the moving section of the moving part.

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