KR101574053B1 - Connector inspection device - Google Patents

Abstract

The purpose of the present invention is to provide a connector test device capable of reducing the effort required in a test process by automatically performing operations to insert a connector into and separate it from a test groove, and increasing quantity to be tested. The present invention relates to the connector test device and comprises: a body (10) including the test groove (11) wherein a connector (C) to be tested is inserted, a plurality of test pins (12) installed inside the test groove (11); a holder (20) which forms a holder groove (21) wherein the front side of the connector (C) is placed to be protruded in the direction of the test groove (11); a guider (30) to support the holder (20) to be able to slide the body (10); a holder transfer unit (40) to move the holder (20) back and forth in the direction of the test groove (11) so the front side of the connector (C) is inserted into the test groove (11); and a connector fixture (50) is used to selectively fixate the connector placed in the holder groove (21) to hold it in position.

Description

Connector inspection device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a connector testing apparatus, and more particularly, to a connector testing apparatus capable of testing whether or not a connector of a connector cable connecting a component and another component is defective.

Generally, a large number of parts are installed in an automobile, an air conditioner, a refrigerator, a washing machine, etc., and complicated wiring circuits are employed to connect these parts to each other or to supply power. Since the wiring circuit is considerably complicated, it is effective to form a wiring circuit after installing a large number of components in advance. For this purpose, a connector cable implemented by connecting a connector and a wire cable is used in many cases.

Such a connector cable is formed by connecting a plurality of wires exposed by covering a plurality of wire cables with a plurality of terminals inserted into a connector housing, and is manufactured in various shapes according to the number of the terminals or the size of the connector housing.

However, in the case of a connector, a plurality of terminals and a plurality of cables are correctly connected, or a terminal connected to the cable must be inserted into the connector housing correctly. In a manufacturing process, if the terminal is not connected to a specific cable or the terminal is not inserted . In this case, the product using the connector cable did not work properly and was connected to a large defect. Therefore, after the connector cable is manufactured, a separate test process is performed to check whether a plurality of terminals and cables are correctly connected.

Typically, a connector test apparatus tests a connection state between a terminal and a cable by inserting a connector having a plurality of terminals in a test groove provided with a plurality of test pins, and checking whether the connector terminal and the test pin are energized. A connector inspection apparatus is disclosed in the Utility Model Registration No. 20-0393112 of the related art.

However, in the case of the conventional connector testing apparatus, since the operation of inserting and separating the connector into the test groove for testing has been dependent on the manual operation of the operator, a lot of efforts have been required in the repeated testing process, All.

After completing the test, pull the cable connected to the connector to disconnect the connector from the test groove. If the terminal and the cable are disconnected or the connection between the terminal and the cable is weakened, There was an issue that there was.

The present invention has been made in order to solve the above problems, and it is an object of the present invention to reduce the effort required in the test process by automatically performing the operation of inserting and separating the connector into the test groove, The present invention provides a connector test apparatus having a connector.

It is another object of the present invention to provide a connector for a connector which can automatically disconnect a connector in a test groove after completing a test of the connector so that the cable is not forcibly pulled for separation, And a connector test apparatus capable of preventing a binding force of a cable wire from being weakened.

In order to achieve the above object, a connector testing apparatus according to the present invention comprises:

A body 10 having a test groove 11 into which a connector C as an inspected object is inserted and a plurality of test pins 12 provided inside the test groove 11; A holder 20 having a holder groove 21 on which a front side of the connector C is seated so as to protrude in the direction of the test groove 11; A guider (30) slidably supporting the holder (20) with respect to the body (10); A holder transfer part 40 mounted on the body 10 and adapted to reciprocally transfer the holder 20 in the test groove 11 direction so that the front side of the connector C is inserted into the test groove 11; And a connector fixture (50) installed on the holder (20) and selectively fixing the connector (C) seated in the holder groove (21) so as not to move, and the guider (30) A linear motion bearing 31 mounted on the body 10 and a shaft 32 having one side fixed to the holder 20 and the other side inserted into the linear motion bearing 31 and linearly engaged with the linear motion bearing 31; .

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The holder transfer unit 40 includes a geared motor 41 installed in the body 10 and a rotary shaft connected to the rotary shaft of the geared motor 41 to rotate the holder 20 And a screw 42 screwed into the screw hole 20a.

In the present invention, the connector pitcher 50 is mounted on one side of the holder groove 21 and includes a first pressing terminal (not shown) which is in close contact with one side of the connector C that is seated in the holder groove 21 And a solenoid 52 installed on one side of the holder 20 and pushing or pulling the first pressing end 51 toward the connector C side.

The holder groove 21 is provided at the other side of the holder 20 and includes a holder groove varying part 60 for varying the width of the holder groove 21 so that a connector of a specific size can be seated in the holder groove 21 ). The holder groove changing part 60 includes a second pressing step 61 which is built in the other side of the holder groove 21 and is in close contact with the other side of the connector C that is seated in the holder groove 21, And a position variable bolt 62 provided on the other side of the holder 20 for finely moving the second pressing end 61 toward the connector C side.

In the present invention, the sensor unit 70 is pressed when the bottom of the connector C is completely attached to the bottom 21a of the holder groove to generate first and second pressing signals. And a controller 80 for operating the connector fixture 50 so that the connector C is positioned and fixed to the holder groove 21 when the first pressing signal and the second pressing signal are simultaneously generated in the sensor unit 70. [ ; ≪ / RTI > The sensor unit 70 includes a first sensor 71 and a second sensor 72. The first sensor 71 and the second sensor 71 are disposed at left and right sides of the center of the bottom 21a of the holder groove, 2 < / RTI >

According to the present invention, by adopting the holder transfer part, the connector placed in the holder groove can be automatically inserted into and detached from the body test groove, whereby the operator can perform repetitive operation It is possible to test a large number of connectors (C).

In addition, by adopting the connector pitcher, the connector can be automatically fixed in the state of being inserted into the holder groove. On the contrary, the position fixing can be canceled to disconnect the connector C from the holder groove without pulling the cable connected to the connector (C) So that the connector terminal and the cable can be separated from each other or the binding force between the terminal and the cable can be prevented from deteriorating.

And the first and second sensors provided on the bottom of the holder groove are used to fix the connector terminals so as to face the plurality of test pins fixed in the test groove accurately, It is effective.

1 is a perspective view of a connector testing apparatus according to the present invention,
2 is a side cross-sectional view of the connector test apparatus 1,
FIG. 3 is a view for explaining a holder transfer part, a connector picker, and a holder changing part provided in the body and the holder of FIG. 2;
FIG. 4 is a view for explaining a sensor unit installed in the holder of FIG. 2,
Fig. 5 is a diagram for explaining operation of the connector testing apparatus of Fig. 2; Fig.

Hereinafter, a connector testing apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of a connector testing apparatus according to the present invention, FIG. 2 is a side sectional view of the connector testing apparatus 1, FIG. 3 is a perspective view of a connector testing apparatus, FIG.

The connector test apparatus according to the present invention includes a test groove 11 into which a connector C as an inspected object is inserted and a body having a plurality of test pins 12 provided inside the test groove 11 (10); A holder 20 having a holder groove 21 on which a front side of the connector C is seated so as to protrude in the direction of the test groove 11; A guider (30) slidably supporting the holder (20) with respect to the body (10); A holder transfer part 40 provided on the body 10 and adapted to reciprocally transfer the holder 20 in the test groove 11 direction so that the front side of the connector C is inserted into the test groove 11; A connector fixture 50 which is provided at one side of the holder 20 and selectively fixes the connector C seated in the holder groove 21 so as not to move; A holder groove varying part 60 provided on the other side of the holder 20 for varying the width of the holder groove 21 so that connectors having various specific sizes can be seated in the holder groove 21; A sensor unit 70 for generating first and second pressing signals when the bottom of the connector C is completely attached to the bottom 21a of the holder groove; And a control unit 80 for operating the connector picker 50 so that the connector C is positioned and fixed to the holder groove 21 when the first pressing signal and the second pressing signal are simultaneously generated in the sensor unit 70 .

A test groove 11 into which a connector C as an inspected object is inserted is formed on the front surface of the body 10 and a plurality of test pins 12 are provided inside the test groove 11.

An inclined surface is formed at the upper end of the test groove 11 so that the connector C to be conveyed by the holder 20 to be described later is guided so as to be inserted into the test groove 11 accurately. As a result, the connector C can be prevented from being caught by the inlet of the test groove 11.

The test pin 12 is connected to the plurality of terminals C1 incorporated in the connector when the connector C is inserted into the test groove 11. The plurality of test pins 12 are connected to the device for generating the energization test signal so that the energization test is performed by connecting the plurality of terminals C1 when the connector C is inserted into the test groove 11 .

The test pin 12 should be firmly connected to the connector terminal C1. The test pin 12 is composed of a movable pin 12a to which a resilient force is applied to the connector C side and a fixed pin 12b which is fixed to the rear side of the body 10 and is electrically connected to the movable pin 12a do. Thus, when the connector C is inserted into the test groove 11, the movable pin 12a is firmly attached to the connector terminal C1 while being slightly pushed toward the fixing pin 12b.

The holder 20 conveys the connector C seated in the holder groove 21 in the direction in which the connector C is inserted into the test groove 11. At this time, in order to prevent the connector C from being pushed to the rear side of the holder groove 21, a latching jaw 22 is formed on the rear side of the holder groove 21 so that the rear edge of the connector C seated on the holder groove 21 is extended.

The front side of the connector C that is seated in the holder groove 21 protrudes from the holder 20 toward the test groove 11 side. Therefore, when the holder 20 is transferred to the body 10 side, the front side of the connector C is inserted into the test groove 11 as shown in Fig.

The guider (30) slidably supports the holder (20) toward the body (10) side. 3, the guider 30 includes a linear motion bearing 31 mounted on the body 10 and a linear motion bearing 31 fixed to one side of the holder 20 and the other side inserted into the linear motion bearing 31 And a shaft 32 that is coupled to move linearly. The guider 30 slidably supports the holder 20 in the horizontal direction while the shaft 32 moves in and out of the linear motion bearing 31.

2 and 3, the holder transfer portion 40 reciprocally transfers the holder 20 supported by the guider 30 to the body 10. [ To this end, the holder transfer section 40 is provided with a geared motor 41 mounted on the body 10, a screw shaft 20a connected to the rotary shaft of the geared motor 41 and screwed into a screw hole 20a passing through the holder 20 As shown in Fig. As the geared motor 41 causes the screw 42 to rotate in the forward and reverse directions by the holder transfer unit 40, the holder 20 is advanced or retracted toward the body 10 and the connector 20 C are inserted into or separated from the test groove 11.

Here, since the holder transfer part 40 composed of the geared motor 41 and the screw 42 is made of electricity, the size of the connector testing device of the present invention can be compactly realized.

In addition, since the rotation speed of the geared motor 41 can be controlled to smooth the conveying speed of the holder transfer section 40, it is possible to prevent the connector C from colliding with the test groove 11.

The connector picker 50 positions or releases the connector C that is seated in the holder groove 21 so as not to move. 3, the connector picker 50 is mounted on one side of the holder groove 21 and includes a first pressing terminal (not shown) which is in close contact with one side of the connector C that is seated in the holder groove 21, And a solenoid 52 provided on one side of the holder 20 and pushing or pulling the first pressing end 51 toward the connector C side.

The first pressing step 51 is formed with a first friction layer 51a made of a rubber material or a silicone rubber material for generating frictional force with a side surface of the connector C. Therefore, when the first pressing end 51 is brought into close contact with the side surface of the connector C, the connector C is fixed in position so as not to move by the first friction layer 51a.

The first pressing step 51 is transferred to the connector C side while the solenoid 52 is operated while the connector C is seated in the holder groove 21 by the connector fitting 50, (51a) is in close contact with one side surface of the connector. Then, the connector (C) is fixed in position in the holder groove (21).

The holder groove changing portion 60 is for securing versatility so that a connector having various specific sizes can be tested. As shown in Fig. 3, the holder groove changing portion 60 includes a second pressing portion (not shown) which is built in the other side of the holder groove 21 and is in close contact with the other side surface of the connector C that is seated in the holder groove 21 And a position variable bolt 62 provided on the other side of the holder 20 for finely moving the second pressing end 61 toward the connector C side.

The second pressing end 61 is formed with a second friction layer 61a made of rubber or silicon rubber for generating frictional force with the other side surface of the connector C. Therefore, when the second pressing end 61 is brought into close contact with the side surface of the connector C, the connector C is fixed in position so as not to move by the second friction layer 61.

When the size of the connector that is seated in the holder groove 21 is changed by the holder groove changing part 60, the position changing bold 62 is rotated in the normal and reverse directions to move the second pressing step 61 to a specific position So that the connector can be accurately positioned in the holder groove 21.

FIG. 4 is a view for explaining a sensor unit installed in the holder of FIG. 2. FIG.

The sensor unit 70 is pressed when the bottom of the connector C is completely attached to the bottom 21a of the holder groove to generate the first and second pressing signals. To this end, the sensor unit 70 includes a first sensor 71 and a second sensor 72 spaced from each other on the left and right sides of the center of the bottom 21a of the holder groove. When the first and second sensors 71 and 72 are pressed against the bottom of the connector, strictly speaking, the rear side of the connector C is in contact with the engagement groove 22 on the rear side of the holder groove, And simultaneously generates the first depression signal and the second depression signal when depressed. The first sensor 71 and the second sensor 72 may be implemented in various forms, for example, a piezoelectric sensor, a button, or the like.

The terminals C1 of the connector C that are seated in the holder groove 21 must be connected to the plurality of test pins 12 fixed in the test groove 11 in order to test the defectiveness of the connector C For this purpose, the connector C must be accurately positioned at a position set inside the holder groove 21.

However, since it is very difficult for a worker to know exactly when the connector terminal C1 and the test pin 12 are opposed to each other when the operator inserts the connector C into the holder groove 21, So that the sensor unit 70 can be inserted.

The first sensor 71 and the second sensor 72 can be simultaneously operated at the same time when the bottom of the connector is completely brought into close contact with the bottom of the holder groove 21 in a state in which the rear side of the connector C is in close contact with the engaging jaw 22, Thereby generating the first and second pressing signals. That is, the first and second pressing signals are generated when the connector is completely brought into close contact with the bottom of the latching groove in a state in which the connector is in tight contact with the latching jaw 22, and the connector terminals C1 and the test pins 12 It is in an opposed state. The first and second pressing signals are transmitted to the controller 80. The controller 80 generates an operation signal for operating the connector picker 50 so that the connector C is held in the holder groove 21 .

If the connector C is not in close contact with the latching jaw 22 or the bottom of the connector is not completely in contact with the bottom 21a of the holder groove, the first pressing signal and the second pressing signal are not generated at the same time. In this case, C is not set at the set position of the holder groove 21, and the connector picker 50 is not operated.

Next, the operation of the connector testing apparatus according to the present invention will be described.

In order to test whether or not the connector C is defective, the connector C is seated in the holder groove 21 as shown in Figs. At this time, the rear side of the connector C is hooked on the latching jaw 22 while the front side of the connector is projected toward the front side of the holder 20. In this state, the bottom of the connector C is connected to the bottom 21a of the holder groove, So that the first sensor 71 and the second sensor 72 are pressed. In this case, the first and second sensors 71 and 72 generate a first pressing signal and a second pressing signal and transmit the generated first pressing signal and the second pressing signal to the control unit 80.

The controller 80 generates an operation signal for activating the connector 50 when the first and second pressing signals are transmitted. The solenoid 52 of the connector picker 50 pushes the first pressing end 51 to fix the side surface of the connector C to the holder groove 21 so as not to move.

Next, the geared motor 41 of the holder transfer section 40 is activated to rotate the screw 42, whereby the holder 20 is transferred to the body 10 side. Then, the front side of the connector C is inserted into the test groove 11 of the body 10, and then the connector terminal C1 is connected to the test pin 12 provided in the test groove, so that the energization test is performed.

The holder transmitter 40 rotates the geared motor 41 in the forward and reverse directions to move the holder 20 backward and when the reverse operation is completed to the set point, the connector picker 50 is moved to the first pressing stage 51, From the surface of the connector (C). In this state, the connector C can be separated from the holder groove 21.

On the contrary, the result of the energization test is abnormal and a warning sound or a warning light is generated. In this state, the holder transfer portion 40 and the connector picker 50 are not operated. In this case, the operator manually operates the holder transfer portion 40 and the connector picker 50 to separate the connector C from each other.

As described above, according to the present invention, by employing the holder transfer portion 40, the connector C that is seated in the holder groove 21 can be automatically inserted into and detached from the test groove 11 of the body 10 . Accordingly, it is not necessary for the operator to repeatedly perform the operation of inserting and separating the connector into the test groove 11, and the inserting and separating operation is performed in a short time, so that a large number of connectors C can be tested.

In addition, by adopting the connector picker 50, the position of the connector C can be automatically fixed in the state of being inserted into the holder groove 21, and conversely, the position fixing can be canceled and the cable connected to the connector C can be fixed The connector C can be separated from the holder groove 21. As a result, the connector terminal C1 can be separated from the cable, or the binding force between the terminal C1 and the cable can be prevented from deteriorating.

By adopting the engagement protrusions 22 on the rear side of the holder groove 21 and the first and second sensors 71 and 72 provided on the bottom 21a of the holder groove, The test pins 12 can be accurately positioned so as to be opposed to each other.

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, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.

10 ... body 11 ... test home
12 ... test pin 12a ... movable pin
12b ... fixing pin 20 ... holder
21 ... holder groove 22 ... engaging jaw
30 ... guider 31 ... linear motion bearing
32 ... shaft 40 ... holder transmission
41 ... geared motor 42 ... screw
50 ... Connector picker 51 ... First pressing terminal
51a ... First friction layer 52 ... Solenoid
60 ... holder groove changing part 61 ... second pressing step
61a ... second friction layer 62 ... position variable bolt
70 ... Connector Connector of the picker 71, 72 ... 1st and 2nd sensors
80 ... control unit

Claims (7)

A body 10 having a test groove 11 into which a connector C as an inspected object is inserted and a plurality of test pins 12 provided inside the test groove 11;
A holder 20 having a holder groove 21 on which a front side of the connector C is seated so as to protrude in the direction of the test groove 11;
A guider (30) slidably supporting the holder (20) with respect to the body (10);
A holder transfer part 40 mounted on the body 10 and adapted to reciprocally transfer the holder 20 in the test groove 11 direction so that the front side of the connector C is inserted into the test groove 11; And
(50) provided in the holder (20) and selectively fixing the position of the connector (C) seated in the holder groove (21) so as not to move;
The guider 30 includes a linear motion bearing 31 mounted on the body 10 and a linear motion bearing 31 having one side fixed to the holder 20 and the other side inserted into the linear motion bearing 31, (32). ≪ / RTI > delete The portable terminal according to claim 1, wherein the holder transfer portion (40)
A screw 42 screwed to a screw hole 20a which is connected to the rotary shaft of the geared motor 41 and is rotated and passes through the holder 20, Wherein the connector testing device comprises: The connector according to claim 1, wherein the connector pitch (50)
A first pressing step 51 which is built in one side of the holder groove 21 and is in close contact with one side of the connector C that is seated in the holder groove 21, And a solenoid (52) for pushing or pulling the first pressing end (51) toward the connector (C) side. The method according to claim 1,
And a holder groove varying part 60 provided on the other side of the holder 20 for varying the width of the holder groove 21 so that a connector having a specific size can be seated in the holder groove 21 And the connector test apparatus. 6. The apparatus according to claim 5, wherein the holder groove changing portion (60)
A second pressing step 61 which is built in the other side of the holder groove 21 and is in close contact with the other side surface of the connector C that is seated in the holder groove 21, And a position variable bolt (62) for finely moving the second pressing end (61) toward the connector (C) side. The method according to claim 1,
A sensor unit 70 which is pressed when the bottom of the connector C is completely attached to the bottom 21a of the holder groove to generate first and second pressing signals; And a controller 80 for operating the connector fixture 50 so that the connector C is positioned and fixed to the holder groove 21 when the first pressing signal and the second pressing signal are simultaneously generated in the sensor unit 70. [ ; ≪ / RTI >
The sensor unit 70 includes a first sensor 71 and a second sensor 72. The first sensor 71 and the second sensor 71 are disposed at left and right sides of the center of the bottom 21a of the holder groove, 2 sensor (72).

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