KR200289985Y1 - Device for testing durability of key pad - Google Patents

Abstract

An apparatus for testing the durability of a keypad is disclosed. In such keypad durability test apparatus, a pair of vertical frames are formed to protrude upward from both sides of the base, and the pair of vertical frames are connected to each other by a horizontal frame, and are mounted on the horizontal frame to reciprocate in the X-axis direction. 3, consisting of a moving X-axis feeder, a Y-axis feeder mounted on the X-axis feeder to reciprocate in the Y-axis direction, and a Z-axis feeder that is movably mounted on the upper surface of the base and moves the keypad in the X-axis direction. An axis control robot and a Y-axis transfer unit, which is capable of vertically reciprocating movement, and a test unit capable of testing durability of the keypad by a constant pressing force by repeatedly pressing the keypad to measure pressing force, and the Z axis A seating part mounted on a conveying part, for seating the keypad and transferring the keypad to the test part; and And a group 3 festival robot control, the test unit, the control unit mounted to the control.

Description

Keypad durability test device {DEVICE FOR TESTING DURABILITY OF KEY PAD}

The present invention relates to a durability test apparatus of a keypad, and more particularly, a push pull gauge displaying force on a three-axis control robot, and pressing the push pull gauge to the keypad to easily measure the magnitude of the pressurized force. In addition, the present invention relates to a keypad durability test apparatus that can test the durability of the keypad by repeatedly pressing the keypad with the same force by inputting the same force as the measured pressing force.

Recently, due to the development of information and communication, communication media such as mobile phones and terminals have been widely distributed. In addition, such a mobile phone and a terminal are generally equipped with a keypad in which numbers, letters, etc. are input to input information, and a mobile phone user inputs corresponding information such as inputting a telephone number by operating a keypad.

Therefore, the user continuously presses the keypad using a finger or the like, and in this process, the keypad receives a repeated load. In addition, since the keypad accumulates fatigue due to such repeated load, the keypad may be broken or a malfunction may occur.

Thus, the keypad must have adequate durability to withstand such repeated loads, and this durability can be determined by a durability test in the manufacturing process.

However, at present, there is no standardized method for testing the durability of the keypad, and each has to be tested manually.

Therefore, the present invention is designed to solve the above problems, and the object of the present invention is to mount the push-pull gauge displaying the magnitude of the force on the 3-axis control robot to press the keypad repeatedly to increase the durability of the keypad against repeated loads. To provide a test apparatus that can measure.

Further, another object of the present invention is to provide a test device that can test the durability by setting the size of the various repetitive load by inputting the target pressing force by recognizing such pressing force, because the pressing force is displayed on the push-pull gauge. .

1 is a front view of the keypad durability test apparatus according to a preferred embodiment of the present invention.

2 is a side view of the keypad durability test apparatus shown in FIG.

3 is a plan view of the keypad durability test apparatus shown in FIG.

Figure 4 is an operating state of the keypad durability test apparatus according to a preferred embodiment of the present invention.

In order to realize the object of the present invention as described above, the present invention is a pair of vertical frames are projected respectively formed upward from both sides of the base, the pair of vertical frames are connected to each other by a horizontal frame, An X-axis feeder mounted on a horizontal frame to reciprocate in the X-axis direction, a Y-axis feeder mounted to the X-axis feeder and reciprocated in the Y-axis direction, and mounted on the upper surface of the base so as to be movable, A three-axis control robot made of a Z-axis feeder moving in a direction;

A test unit mounted on the Y-axis feeder and capable of vertically reciprocating movement, and capable of testing durability of the keypad by a constant pressing force by repeatedly pressing the keypad to measure pressing force;

A seating unit mounted on the Z-axis transfer unit and seating the keypad to transfer the keypad to the test unit; And

It provides a keypad durability test apparatus including a control unit for controlling the three-axis control robot, test unit, seating unit.

Hereinafter, with reference to the accompanying drawings will be described in detail a keypad durability test apparatus according to a preferred embodiment of the present invention.

1 to 3, a keypad durability test apparatus according to an embodiment of the present invention includes a three-axis control robot 1 having an X, Y, and Z axes, and a Y-axis feeder of the three-axis control robot 1. A test unit (3) mounted on (17) for testing the durability of the keypad (2), a seating unit (5) mounted on the Z-axis transfer unit (19) and capable of transferring the keypad (2) in the Z-axis direction; , A control unit 7 for controlling the control robot 1, the test unit 3, and the seating unit 5.

In the keypad durability test apparatus having the above structure, the three-axis control robot is provided with a base (9), a pair of vertical frame (11) is mounted on both sides of the base (9), the pair Between the vertical frame 11 of the horizontal frame 13 is mounted. In addition, an X-axis feeder 15 is vertically mounted on the horizontal frame 13 so that the X-axis feeder 15 may be transferred in the X-axis direction, and a Y-axis feeder 17 may be mounted on the X-axis feeder 15 to reciprocate up and down. do. In addition, on the base 9, the Z-axis feeder 19 reciprocates in the Z-axis direction to transfer the keypad 2 to the working position.

The three-axis control robot 1 has a stepping motor, a belt (not shown), and the like therein, and drives the stepping motor by the control signal of the control unit 7 so that the X, Y, Z axis transfer unit 15 is provided. It may be a robot having the same or similar structure as the three-axis control robot of the general structure to properly move the 17,19) to proceed with the scheduled work.

The test unit 3 is mounted on the lower portion of the Y-axis feeder 17, and when the Y-axis feeder 17 reciprocates up and down, the load is repeatedly applied to the keypad 2 to display the magnitude of the pressing force. do.

The test unit 3 includes at least one push-pull gauge 21 capable of measuring an external pressure. The push-pull gauge 21 displays a force acting on the keypad 2 by mounting a load cell therein so that the user can easily recognize the pressing force.

The push pull gauge 21 senses pressure by contacting the keypad 2 with the sensing pin 23 protruding from the lower part thereof, and the upper part thereof is connected to the connecting rod 25 fixed to the Y axis.

The push-pull gauge 21 may have a Wheatstone bridge circuit therein, and may indicate a magnitude of a force acting by measuring a change in voltage value according to a change in resistance value. The operation principle of the Wheatstone bridge circuit is that when the input value flows, the resistance value is changed, and the magnitude of the force is displayed by converting it into a change amount of the voltage value.

According to this principle, when describing the operation of the push-pull gauge, when the sensing pin 23 is in contact with the upper surface of the keypad 2 with a predetermined pressing force, the sensing pin 23 is connected to the keypad (2) It is pushed upwards by contact. At this time, the resistance value of the Wheatstone Bridge inside the case changes according to the flow of the sensing pin 23, and the amount of change in the resistance value is detected and converted into a voltage value. The converted data is displayed on the display window 26 formed on the front surface of the push-pull gauge 21 in a digital manner. Thus, the user can know the magnitude of the force acting on the keypad 2 by recognizing this number.

In addition, the user can recognize the target value by the magnitude of the force displayed on the display window 26, and then store the value by inputting the value to the control unit 7. The controller 7 may repeatedly apply a uniform load to the keypad 2 by reciprocating the Y-axis feeder 17 with a constant force up and down according to the stored value. Thus, the push-pull gauge 21 can measure the durability of the keypad 2 to a certain pressing force.

On the other hand, the push-pull gauge 21 is fixed to the connecting table 25 by the fastening screw 27, respectively. The position of the push pull gauge 21 can be adjusted by fastening / releasing the fastening screw 27.

This tether 25 is equipped with at least one push-pull gauge 21, preferably four push-pull gauges. Therefore, the durability test can be performed with respect to four keypads 2 simultaneously.

On the other hand, the seating portion 5 is mounted on the Z-axis feeder 19 is to move forward and backward reciprocating in the Z-axis direction, that is, the test section (3) direction.

The Z-axis feeder 19 is mounted on the rail 39 protruding from the upper surface of the base 9, and the lower portion thereof is connected to a belt driven by a motor mounted inside the base 9. Therefore, when the motor is driven, the belt is rotated, the work table 29 connected to the belt is moved. The moving distance is controlled by the control unit 7.

The seating portion 5 is a work table 29 mounted on the Z-axis feeder 19, a jig 30 mounted on the work table 29, the keypad 2 is seated, and the jig 30 It includes a guide frame (35) for horizontally moving in the horizontal direction and a fastening screw (37) for fixing the keypad (2) seated on the jig (30).

In addition, the jig 30 is at least one fixed jig 31 fixedly mounted on the upper surface of the work table 29, the fixing jig 31 is disposed to face and move along the guide frame 35 At least one moving jig 33 is made up.

The fixing jig 31 is positioned apart from each other by a predetermined interval on the upper surface of the work table 29, the guide frame 35 to fix the plurality of fixing jig (31). At the same time, the guide frame 35 passes through the plurality of moving jigs 33. Therefore, when an external force acts on the moving jig 33, the moving jig 33 is movable along the guide frame 35 from side to side.

In addition, the fastening screw 37 fixes the moving jig 33 to the guide frame 35. Therefore, when the moving jig 33 moves along the guide frame 35 to reach a predetermined position, the user fixes the moving jig 33 by tightening the fastening screw 37. At this time, the distance between the moving jig 33 and the fixing jig 31 is a distance that the keypad 2 is seated and can be fixed. Therefore, the keypad 2 of various sizes can be seated by adjusting the distance.

In addition, the fixing jig 31 and the moving jig 33 each have a “b” shape to prevent the left and right flows when the keypad 2 is mounted, thereby stably fixing the keypad 2 even during the durability test. have.

Hereinafter, with reference to the accompanying drawings will be described in more detail the operation of the keypad durability test apparatus according to a preferred embodiment of the present invention.

1 to 4, when the durability of the keypad 2 is tested using the keypad durability test apparatus, the keypad 2 is first placed on the seating portion 5.

That is, by releasing the fastening screw 37 of the seating portion 5 to move the moving jig 33 in the direction of the fixed jig 31 by a proper distance to maintain the interval that the keypad (2) can be placed. In this state, the keypad 2 is seated on the fixing jig 31 and the moving jig 33, and the moving jig 33 is pushed in the direction of the fixing jig 31 to press the side of the keypad 2. The keypad 2 can be fixed to the seating part 5 by fastening the fastening screw 37.

In the case of seating a plurality of keypads 2, by repeating this process, each keypad 2 can be fixed to the seating portion (5).

As described above, after the plurality of keypads 2 are fixed to the seating portion 5, the control unit 7 is operated to transfer the Z-axis feeder 19 in the working position, that is, in the direction of the Y-axis feeder 17. Thus, the keypad 2 seated on the Z-axis feeder 19 is transferred to the working position.

After the keypad 2 is moved to the working position, the control unit 7 lowers the Y-axis feeder 17 downward so that the sensing pin 23 of the push-pull gauge 21 contacts the upper surface of the keypad 2. Be sure to

When the sensing pin 23 is in contact with the keypad 2, the sensing pin 23 flows upward by a predetermined distance to operate the load cell so that the measured pressing force is displayed on the display window 26. Thus, the user can easily recognize the magnitude of the force currently being pressed.

At this time, the user lowers the Y-axis feeder 17 until the magnitude of the target force is displayed. When the target value is displayed on the display window 26, the lowering of the Y-axis feeder 17 is stopped, and the value is input to the controller 7.

The control unit 7 stores the input data, and repeatedly lowers and raises the Y-axis transfer unit 17 using this data as a target value. Therefore, the durability test can be performed by the detection pin 23 continuously contacting and releasing the upper surface of the keypad 2 by a constant force.

As such, the keypad durability test apparatus according to the preferred embodiment of the present invention has the following advantages.

First, it is possible to easily measure the magnitude of the pressurized force by measuring the pressing force acting on the keypad by the push-pull gauge on which the force is displayed, and also repeatedly inputting the keypad with the same pressing force by inputting the same force as the measured pressing force. Pressing may test the durability of the keypad.

Second, by mounting multiple push-pull gauges, you can run durability tests on multiple keypads at the same time.

Third, durability tests can be automated by mounting a push-pull gauge on a three-axis control robot.

In the above, a preferred embodiment of the present invention has been described for the purpose of illustration, but is not limited thereto. It is also possible to carry out various modifications within the scope of the utility model registration claims and the detailed description of the invention and the accompanying drawings.

Claims (5)

A pair of vertical frames are formed to protrude upward from both sides of the base, and the pair of vertical frames are connected to each other by a horizontal frame, and are mounted on the horizontal frame and reciprocated in the X-axis direction; A three-axis control robot comprising a Y-axis feeder mounted on the X-axis feeder and reciprocally moved in the Y-axis direction, and a Z-axis feeder mounted on the upper surface of the base to move the keypad in the X-axis direction; A test unit mounted on the Y-axis feeder and capable of vertically reciprocating movement, and capable of testing durability of the keypad by a constant pressing force by repeatedly pressing the keypad to measure pressing force; A seating unit mounted on the Z-axis transfer unit and seating the keypad to transfer the keypad to the test unit; And Keypad durability test apparatus including a control unit for controlling the three-axis control robot, test unit, seating. According to claim 1, wherein the test part is a sensing pin protrudes in the lower portion to contact the keypad to detect the pressing force, the upper portion is connected to the connecting rod protruding to the lower end of the Y-axis transfer portion, the load cell is mounted therein The keypad durability test apparatus comprising a push-pull gauge for displaying the pressing force by the operation of the Wheatstone bridge circuit when the sensing pin flows. The keypad durability test apparatus of claim 2, wherein the control unit receives the pressing force data measured by the test unit and vertically reciprocates the Y-axis feeder to press the keypad with a force corresponding to the input pressing force data. According to claim 1, wherein the mounting portion is a work table mounted on the Z-axis transfer portion, a jig mounted on the work table, the keypad is seated, a guide frame for horizontally moving the jig in the horizontal direction, and the seating portion Keypad durability test apparatus comprising a fastening screw for fixing the keypad. The keypad durability test apparatus according to claim 4, wherein the jig includes a fixed jig fixedly mounted on the work table and a movable jig movable horizontally to the work table.