KR101036291B1 - fatigue tester - Google Patents

Abstract

The present invention relates to a fatigue tester, and a fatigue tester for measuring the fatigue failure point of the solder joint of the IC mounted on the substrate, the housing having a plurality of fixed anvil is installed so that each of the plurality of substrates on the upper surface; ; An elevating plate mounted on an upper portion of the housing and provided with a plurality of pressing anvils to press the substrate; It is installed on the lower portion of the housing for driving the lifting plate; characterized in that it comprises a, it is possible to test a plurality of specimens at a time to improve workability, shorten the measurement time, accurate and reliable measurement results Can be derived.

4 points, bending, fatigue, fatigue tester, board, cam, guide

Description

Fatigue Tester

The present invention relates to a fatigue tester, and more particularly to a four-point bending fatigue tester for the life evaluation of the solder joint of the IC mounted on the substrate.

In general, a board on which various chips are mounted (hereinafter referred to as a "substrate") may be warped during use or may be bent under artificial mechanical load. Particularly, a substrate to be loaded may be a conventional substrate (a substrate subjected to pressure generated by pressing a keypad) embedded in a mobile phone. The bending phenomenon of the substrate caused by the load may be caused by breakage of the substrate or solder. This can cause breakage of the solder, breakage of the chip connections or the chip itself.

Therefore, in order to confirm the breakdown point of the substrate, a method of obtaining and measuring the number of repetitions until the substrate reaches failure by applying a stress having a constant amplitude to the substrate has been proposed.

However, such a conventional fatigue strength measuring device is simply formed by pressing the upper surface of the substrate as an anvil while supporting both sides of the lower surface of the substrate, which takes a lot of time because only one substrate (sample) can be tested at a time. There was a disadvantage.

Accordingly, the present invention has been made to solve the problems of the prior art as described above, as a four-point support form not only can test a number of specimens at a time, but also acts on the substrate by varying the displacement of the lifting and lowering pressure and bill The purpose is to provide a fatigue tester that can improve the accuracy and reliability of the measurement results by measuring the bending displacement in various ways.

The above object is a fatigue tester for measuring a fatigue breakdown point of a substrate, comprising: a housing provided with a plurality of fixed anvils so as to mount a plurality of substrates on an upper surface thereof; An elevating plate mounted on an upper portion of the housing and provided with a plurality of pressing anvils to press the substrate; It is achieved by a fatigue tester comprising a; is installed in the lower portion of the housing for driving the lifting plate.

The drive unit may include: a motor having a drive gear installed in the housing and driven to rotate; A rotating shaft rotatably installed in the housing and fixed with a driven gear engaged with the driving gear of the motor; And a pair of cams fixedly installed at both ends of the rotary shaft and configured to lift by varying the movement displacement of the elevating plate.

And, the drive unit, the lifting shaft and fixed to the lifting plate; It is preferably configured to further include; a guide which is fixed to the lifting shaft while being installed to surround the pair of cams and selectively contact with the pair of cams that are rotated to lift the lifting shaft and the lifting plate.

The driving unit includes a rotating plate installed on the rotating shaft to rotate together with the rotating shaft and having a sensing groove formed at one side thereof; It is preferably configured to further include a sensor or limit switch for detecting the number of revolutions by detecting the sensing groove of the rotating rotating plate.

According to the fatigue tester of the present invention, by operating the elevating plate in a state where four specimens are installed on the upper surface of the housing, it is possible to test a plurality of specimens at once, thereby improving workability and reducing measurement time.

In the present invention, the bending displacement of the substrate may be variously measured by adjusting the displacement of the pressing anvil which presses the substrate, thereby improving accuracy and reliability of the measurement result.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 6 are diagrams illustrating a fatigue tester according to the present invention.

The fatigue tester 10 of the present invention is a four-point bending fatigue tester for measuring the fatigue breakdown point of the substrate 1, as shown in Figs. 1 and 2, the housing 100 and the pressing unit 200 largely The drive unit 300 is roughly configured.

The housing 100 is formed in a box shape with its lower surface opened, a pressing portion 200 is formed at an upper portion thereof, and a driving portion 300 is formed at a lower portion thereof.

A plurality of fixed anvils 110 are vertically installed on the upper surface of the housing 100, and a plurality of fixed anvils 110 installed in this way are installed in total of four as two sets, and a plurality of substrates 1 That is, four substrates 1 can be measured at a time.

In addition, a plurality of support shafts 120 are vertically installed at a higher length than the fixed anvil 110 at the outside of the fixed anvil 110 installed as described above, and the substrate 1 seated on the fixed anvil 110. By supporting the outer circumferential surface of the substrate), the detachment of the substrate 1 is prevented.

The pressurizing part 200 includes a rectangular lifting plate 210 installed on the upper part of the housing 100 to be elevated.

Four shafts of the elevating plate 210 as the elevating plate 210 is elevated as the elevating state penetrating through the housing 100, the guide shaft 230 for guiding the lifting operation of the elevating plate 210 is bolted It is detachably installed, and the elevating plate 210 is lifted by the cams 340 and 350 of the driving unit 300 to be described later in a state penetrating the housing 100 to one side side central portion of the elevating plate 210. The lifting shaft 220 for raising and lowering is fixedly installed. Therefore, the elevating plate 210 is lifted and operated integrally like the elevating shaft 220 and separated from the elevating shaft 220 to replace the substrate 1.

In addition, a plurality of pressing anvils 211 for pressing the substrate 1 seated on the fixing anvil 110 of the housing 100 are installed at the center of the lower surface of the elevating plate 210. The pressure anvil 211 is installed so that two pressure anvils 211 are disposed on one substrate 1. Accordingly, the substrate 1 has two fixed anvils 110 on its lower surface and two pressing anvils 211 on its upper surface in a four-point support form.

The driving unit 300 is configured under the housing 100 to elevate the elevating plate 210 on the upper portion of the housing 100 up and down.

As shown in FIGS. 3 and 4, the driving unit 300 includes a motor 310 provided with a drive gear 312, a rotation shaft 320 provided with a driven gear 321, and a pair of cams having different diameters. 340, 350, guide 360, and the like.

The motor 310 is installed to be fixed to the lower surface of the housing 100 and the drive gear 312 that is rotationally driven as power is supplied to the end thereof is installed. In addition, a speed reducer 311 is provided between the motor 310 and the drive gear 312 to reduce the rotation rpm of the motor 310 and transmit the result to the drive gear 312 to decelerate and rotate the drive gear 312.

3 and 4, the rotation shaft 320 is disposed in one direction of the housing 100 in a rotatable state through a bearing 323 inside the housing 100 adjacent to the motor 310. It is installed, and the driven gear 321 engaged with the drive gear 312 of the motor 310 is fixed to be rotated like the rotation shaft 320.

In addition, one side of the rotating shaft 320 is fixed to the rotating plate 322 integrally driven to rotate like a rotating shaft 320, one side of the rotating plate 322 is cut detection groove (as shown in Figure 4) ( 322a) is formed.

In addition, a sensor 330 is installed in the housing 100 adjacent to the rotating plate 322 to detect or detect the sensing groove 322a of the rotating plate 322 to detect the rotational speed of the rotating plate 322.

In this case, the sensor 330 may also be configured as a limit switch. When the sensor 330 is configured as a limit switch, the limit switch is in contact with the rotating plate 322 and is in a contact on state. The contact of the limit switch is off (off) can be configured to detect the number of revolutions of the rotating plate 322.

On the other hand, since the one rotational speed of the rotating plate 322 detected as described above corresponds to the one-time lifting operation of the elevating plate 210 configured in the pressing unit 200, the number of rotations is the number of times the substrate 1 is pressed. Becomes the same as

In addition, the pair of cams 340 and 350 are two cams 340 and 350 having different diameters at both ends of the rotating shaft 320 are detachably coupled as fixing bolts 342 and 352. The elevating width of the elevating plate 210, that is, the elevating plate 210 may be elevated while varying the displacement of the elevating plate 210.

In this case, the pair of cams 340 and 350 installed on the rotation shaft 320 may be installed such that the protrusions (eccentric portions) of the cams 340 and 350 are positioned in the same direction.

In addition, bearings 341 and 351 which facilitate rotation of the cams 340 and 350 are respectively installed on the outer surfaces of the cams 340 and 350, and the pair of cams 340 and 350 are It is preferable that the length including the cams 340 and 350 and the bearings 341 and 351 is formed to have a height difference of 2 mm.

Accordingly, when the inner cam (2 mm displacement cam) 340 of the pair of cams 340 and 350 is rotated, the lifting plate 210 is elevated at intervals of 2 mm, and the outer cam (4 mm displacement cam) When the 350 is rotated, the lifting plate 210 is elevated at intervals of 4 mm.

This is because, in accordance with the international standard for fatigue testing, the amplitude applied to the substrate 1 is basically 2 mm, and is provided to provide an amplitude between 2 and 4 mm as an option. Therefore, the fatigue tester 10 of the present invention has its limitation. It is configured to test all the values as one device.

At this time, the pair of cams 340 and 350 are coupled to this to elevate the lifting shaft 220 through the bearings 341 and 351 rotated eccentrically, the lifting shaft 220 therein A guide 360 which is configured to receive the bearings 341 and 351 to be raised and lowered integrally with the lifting shaft 220 is configured.

The guide 360 has a top plate 361 coupled as a fastening bolt 361a to the lifting shaft 220 passing through the center portion thereof, as shown in FIGS. 5A to 6B, and bolts at both ends of the top plate 361. Both side plates 362 coupled to each other and vertically coupled, and the lower plate 363 coupled as a bolt to the lower end of the side plate 362, the cams 340, 350 and bearings 341 and 351 therein. Accept and wrap it.

As described above, the bearings 341 and 351 of the cams 340 and 350 installed inside the guide 360 are installed in contact with the lifting shaft 220 and the lower plate 363 of the guide 360. The guide 360 and the lifting shaft 220 and the lifting plate 210 are raised and lowered integrally while being rotated in an eccentric state by the rotation of the 340 and 350.

At this time, the left and right width inside the guide 360 is formed to have a width larger than the diameter of the bearings 341 and 351 including the cams 340 and 350, and the bearings 341 rotated by the cams 340 and 350. Contact with 351 is blocked.

Meanwhile, the cams 340 and 350 and the bearings 341 and 351 accommodated in the guide 360 as described above are rotated around the cams 340 and 350, as shown in FIGS. 5A to 6B. When the fixing bolts 342 and 352 fixed to the 320 are released, the cams 340 and 350 are freely moved on the rotation shaft 320, thereby guiding a desired cam from the pair of cams 340 and 350. ), And the bearings 341 and 351 are installed on the outer surfaces of the cams 340 and 350, so that the bearings 341 and 351 are also guided like the cams 340 and 350. 360 is moved and installed inside.

At this time, when the cams 340 and 350 are replaced as described above or when the substrate 1 is replaced, the cams 340 and 350 are disposed so that the protrusions (eccentric portions) of the cams 340 and 350 face the lifting shaft 220. In particular, the lifting shaft 220 due to the position of the cams 340 and 350 is positioned at the top dead center as shown in FIGS. 5A and 6A while being supported by the bearings 341 and 351. Therefore, the substrate 1 can be easily replaced.

Accordingly, the cams 340 and 350 and the bearings 341 and 351 moved in the guide 360 as described above have upper and lower portions of the bearings 341 and 351 and the lower surface of the lifting shaft 220 and the guide ( It is installed in contact with the upper surface of the lower plate 363 of 360, respectively, the bearings 341 and 351 are eccentric between the lifting shaft 220 and the lower plate 363 by the rotation of the cam 340, 350 Is rotated.

Hereinafter, the operation of the fatigue tester 10 of the present invention configured as described above.

In the state where the protrusions (eccentric portions) of the cams 340 and 350 are positioned toward the lifting shaft 220, the bolts of the lifting plate 210 and the lifting shaft 220 are released to lift the lifting plate 210. After the separation from the 220, the substrate 1 to be measured on the fixed anvil 110 on the upper surface of the housing 100, respectively, and the lifting plate 210 is bolted to the lifting shaft 220 to be coupled again. . Then, the pressing anvil 211 of the elevating plate 210 is located on the upper surface of each substrate (1).

In this state, the lower plate 363 of the guide 360 is detached from the side plate 362, and the fastening bolt 361a of the upper plate 361 is released to fix the upper plate 361 from the lifting shaft 220. Release it.

Thereafter, as shown in FIGS. 5A and 5B, the fixing bolts 342 and 352 fixing the cams 340 and 350 are released to move the inner cam 340 and the bearing 341 into the guide 360. After the movement, the cams 340 and 350 are fixed again by fixing bolts 342 and 352, and the lower plate 363, which has been separated, is again bonded to the lower surface of the side plate 362 to fix the lower plate 363. The upper surface of the upper plate 361a is fastened to the lifting shaft 220 as shown in FIG. 5A by refastening the fastening bolt 361a of the upper plate 361 while the upper surface of the inner cam 340 is in contact with the bearing 341. .

Then, the upper and lower portions of the bearing 341 of the inner cam 340 are in contact with the lower surface of the lifting shaft 220 and the upper surface of the lower plate 363 of the guide 360, respectively. When power is supplied to the motor 310, the drive gear 312 of the motor 310 is driven to rotate, and the driven gear 321 engaged thereto is rotated integrally with the rotation shaft 320, and the rotation of the rotation shaft 320 is performed. The cams 340 and 350 are also integrally rotated together.

Accordingly, as the bearing 341 is rotated in an eccentric state in the guide 360 by the inner cam 340 rotated as described above, the protrusion 360 of the cam 340 is guide 360 as shown in FIG. 5A. When it comes in contact with the upper plate (361) of the elevating plate 210 is raised to reach the top dead center, and when the protrusion of the cam 340 is in contact with the lower plate (363) of the guide 360 as shown in Figure 5b As 210 is lowered and reaches the bottom dead center, the lifting operation is repeated.

Due to the elevating operation of the elevating plate 210, the press-and-ville 211 descends at intervals of 2 mm while pressing the substrate 1 to apply fatigue to the solder joint of the substrate 1, causing breakage and increasing resistance. The data measured at the time of measurement and complete rupture are not only stored through the PC, but the overall operation of the fatigue tester 10 is controlled by the PC.

On the other hand, the rotating plate 322, which is rotated together with the rotating shaft 320, the sensing groove 322a of one side is continuously sensed by the sensor 330, so that the rotation speed of the rotating plate 322 is detected and stored in the PC, the number of times of pressing And the resulting resistance value of the substrate 1 are accumulated in the PC to be data.

Subsequently, after the measurement by the inner cam 340, the measurement by the outer cam 350, as described above, so that the protrusions of the cam 340, 350 toward the lifting shaft 220. After positioning, the lower plate 363 of the guide 360 is removed, and the fastening bolt 361a of the upper plate 361 fixed to the lifting shaft 220 is released to release the fixed state of the upper plate 361.

After unfastening the fixing bolts 342 and 352 of the cams 340 and 350 in such a state, the outer cam 350 is moved into the guide 360 as shown in FIGS. 6A and 6B to fix the fixing bolts. Fixed again as 352, the inner cam 340 is moved to the outside of the guide 360 to avoid interference with the guide 360 and then fixed as a fixing bolt 342.

Subsequently, the lower plate 363, which was separated, is again coupled to the lower surface of the side plate 362 and fixed, and the upper plate 363 of the upper plate 363 is brought into contact with the bearing 351 of the outer cam 350. The upper plate 361 is fixed to the lifting shaft 220 by fastening the fastening bolts 361a. Then, the upper plate 361 is installed in a state of rising about 2 mm to the upper portion of the lifting shaft 220 as shown in Figure 6a.

When the driving unit 300 is operated again in this state, the lifting plate 210 and the pressure anvil 211 move up and down at intervals of 4 mm while reciprocating the top dead center and the bottom dead center as shown in FIGS. 6A and 6B. By pressing the substrate 1, fatigue can be applied to the substrate 1 as described above.

1 is a perspective view showing a fatigue tester according to the present invention.

Figure 2 is a perspective view showing the lifting plate separated in the fatigue tester of FIG.

3 is a cross-sectional view taken along the line A-A of FIG.

Figure 4 is a perspective view showing a drive unit configured in the fatigue tester of the present invention.

5 is a view showing the state of the inner cam (2mm displacement cam) of the driving unit of the present invention, Figure 5a is a state where the lifting plate is located at the top dead center, Figure 5b is the lifting plate is located at the bottom dead center. It is a state.

Figure 6 is a view showing the state of the outer cam (4mm displacement cam) of the drive of the present invention when driving, Figure 6a is a state in which the lifting plate is located at the top dead center, Figure 6b is the lifting plate is located at the bottom dead center. It is a state.

<Description of the symbols for the main parts of the drawings>

1 substrate 10 fatigue tester

100: housing 110: fixed anvil (anvil)

120: support shaft 200: pressing portion

210: lifting plate 211: pressurized and ville

220: lifting shaft 230: guide shaft

300: driving unit 310: motor

311: reducer 312: drive gear

320: rotating shaft 321: driven gear

322: rotating plate 322a: detection groove

323: Bearing 330: Sensor

340,350: Cam 341,351: Bearing

342,352: Fixed bolt 360: Guide

361: top plate 361a: fastening bolt

362: side plate 363: lower plate

Claims (4)

In the fatigue tester for measuring the fatigue failure point of the substrate, A housing provided with a plurality of fixed anvils so as to mount a plurality of substrates on the upper surface, respectively; An elevating plate mounted on an upper portion of the housing and provided with a plurality of pressing anvils to press the substrate; Is installed in the lower portion of the housing including a drive for lifting the lifting plate, The driving unit includes: A motor having a drive gear installed in the housing and driven to rotate; A rotating shaft rotatably installed in the housing and fixed with a driven gear engaged with the driving gear of the motor; A pair of cams fixedly installed at both ends of the rotating shaft and configured to move up and down by different movement displacements of the lifting plate; A lifting shaft fixed to the lifting plate; And a guide fixed to the elevating shaft and installed to surround the pair of cams, the guide selectively contacting the pair of cams being rotated. delete delete The method of claim 1, The driving unit, the rotating plate is installed to be rotated on the rotating shaft, such as a rotating shaft and the sensing groove is formed on one side; And a sensor or limit switch for detecting a rotation speed by detecting a sensing groove of the rotating plate to be rotated.

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