CN110836819A

CN110836819A - Pneumatic transmission auxiliary device for measuring pull-out load and welding spot shearing performance of welding column in CGA column planting process

Info

Publication number: CN110836819A
Application number: CN201911162640.1A
Authority: CN
Inventors: 赵智力; 王迪; 肖凯; 曹荣楠; 张海洋
Original assignee: Harbin University of Science and Technology
Current assignee: Harbin University of Science and Technology
Priority date: 2019-11-25
Filing date: 2019-11-25
Publication date: 2020-02-25
Anticipated expiration: 2039-11-25
Also published as: CN110836819B

Abstract

The utility model provides a pneumatic transmission auxiliary device for measuring CGA post planting technology post draws off load and solder joint shearing property, it relates to an atmospheric transmission device who utilizes the cylinder, concretely relates to a pneumatic transmission auxiliary device for measuring post draws off load and solder joint shearing property. The invention aims to solve the problems that the existing drawing test PCB is uneven in clamping, welding columns are easy to be damaged mechanically, the welding columns cannot be pulled out vertically upwards at a constant speed and uniform force, and welding points with larger diameters cannot be tested. The device comprises an object stage assembly, a positioning plate assembly, a positioning hanger assembly, a push-pull force meter assembly, a fixture body assembly, a push-type broach assembly, a bottom plate and top plate assembly and a vertical plate assembly, wherein the positioning hanger assembly is arranged in a square groove hole slot of the top plate assembly, and the object stage assembly is arranged in the positioning plate assembly and realizes vertical and uniform upward and downward movement by means of a power device (air cylinder). The invention belongs to the field of electronic products.

Description

Pneumatic transmission auxiliary device for measuring pull-out load and welding spot shearing performance of welding column in CGA column planting process

Technical Field

The invention relates to a pneumatic transmission device utilizing an air cylinder, in particular to an auxiliary device for measuring pull-off load and welding spot shearing performance of a welding column, and belongs to the field of electronic products.

Background

CGA interconnection means that solder pillars are implanted in solder balls by associated pillar-implanting devices. The interconnection form is characterized in that the solder columns are used for replacing 10Sn90Pb high Pb solder columns, so that the pollution to the environment is reduced to a certain extent; in addition, the CGA interconnection is beneficial to improving the packaging density, and the mechanical property, the heat dissipation performance and the electrical property are better, and part of stress can be released through the deformation of the welding columns in the service process, so that the CGA interconnection is widely applied to the field of microelectronic packaging.

When a precise micro bench drill is used for the CGA column planting process, the connection strength of the brazing filler metal and the welding column is of great importance; the method directly determines the mechanical property of the CGA interconnection and indirectly reflects the condition of an interface layer to a certain extent, so that the connection strength of the CGA interconnection and the interface layer is necessary to be measured; the method comprises the following specific operations that the bench vice is fixed on a table top, the two side surfaces of a PCB are clamped by the jaw of the bench vice, the jaw clamp of the push-pull force meter is fixed on the push-pull force meter through threaded connection, the welding column is clamped by the jaw clamp of the push-pull force meter, and then the welding column is drawn vertically upwards; the shearing strength of the welding spot is measured by using a special shearing tester in a laboratory, the corresponding push broach displacement, the push broach speed and the push broach height are set according to the diameter of the welding spot, and the shearing strength is displayed on a screen of the shearing tester after shearing is finished. The following problems exist with the current devices of this type:

(1) clamping the side surface of the PCB with the thickness of about 2.0mm by using a vice jaw, and clamping the PCB to incline possibly to prevent the welding column from being pulled out vertically;

(2) the welding column is soft, the clamping surface of the jaw clamp is rough, and the welding column can be seriously damaged when being clamped;

(3) the clamping force for clamping the welding column by using the related jaw clamp is limited, and the maximum clamping force is about 126N through the verification of related experiments, so that the drawing test with high connection strength cannot be tested, and the clamping welding column can shake;

(4) the push-pull dynamometer jaw clamp is used for clamping the welding column, the welding column is likely to be touched or the influence of clamping force on a welding column/brazing filler metal interface is large, the drawing test process is operated manually, the welding column is difficult to be pulled out of a welding spot by uniform force and vertical force, and the drawing strength of the welding column is greatly influenced.

(5) Measuring the shearing strength of a welding spot, wherein the shearing instrument for the experiment is not suitable for shearing a slightly larger welding spot aiming at the welding spot with the diameter not more than 1.0mm, otherwise, the shearing instrument exceeds the measuring range to damage the push broach; most of shearing instruments used in laboratories are special, the principle is that the back-and-forth movement of the push broach is controlled through computer programming, and non-pneumatic hydraulic transmission is adopted, so that the device is single in function, and the device can also be used for measuring the shearing displacement of welding points.

Disclosure of Invention

The invention provides a method for measuring pull-off load, shear strength and shear displacement of CGA/solder welding spots by using air cylinders, and aims to solve the fatal defects that the existing equipment such as a small bench vice, a push-pull force meter jaw clamp, a special shearing instrument and the like is utilized to measure the pull-off load and shear strength of the welding spots, the PCB is not horizontal, so that the welding spots cannot be pulled out vertically and upwards, uniform force is difficult to ensure to pull out the welding spots, welding spots with higher and larger connection strength cannot be measured, mechanical damage to the welding spots and welding column/solder interfaces and micro-shaking of the clamped welding columns occur.

The technical scheme adopted by the invention for solving the problems is as follows: the device mainly comprises a bottom plate assembly, vertical plates at two sides, two power devices 36 and 37 (cylinders), a positioning plate, an object stage (comprising a drawing device side and a shearing strength side), a fixture body, a sleeve, a push-pull dynamometer and a fixing part thereof, a push broach, a positioning hanging frame, a top plate assembly and the like, wherein the power devices (cylinders) are respectively arranged at the upper part of a top plate and the upper part of a base, and the power device 36 (cylinder 36) on the top plate is positioned at the centers of the two plates of the positioning hanging frame; when the device is used for testing the shearing strength of a welding spot, firstly, the hanging frame is fixed and positioned by utilizing bolts at two sides, the power device 36 does not work, the hook on the push-pull dynamometer is detached, the push-pull broach device is replaced, the power device 37 (air cylinder 37) is installed on the base, the positions of the shearing side of the objective table and the power device 37 are adjusted, the push-pull dynamometer is provided with a force-displacement sensor, the objective table is driven by the power device 2 to vertically move upwards at a constant speed, the welding spot is contacted with a clamping groove of the push-pull broach, and the shearing force and the shearing displacement are conveniently read; the upper surfaces of the base and the top plate close to the grooves of the pneumatic cylinder part are convenient to install an air supply and exhaust pipe for providing power.

When the device is used for testing the pull-out load, the objective table and the positioning plate are fixed by utilizing bolt connection; positioning action is realized by placing CGA/brazing filler metal welding spots on the drawing side of the vertical plate objective table; the positioning and clamping actions of the welding column are realized by utilizing the special fixture body and the sleeve; the positioning action of the push-pull dynamometer container is realized through threaded holes and bolts at two sides of the positioning hanging frame; the push-pull dynamometer is fixed by the push-pull dynamometer container; the push-pull dynamometer is used for measuring the instantaneous pull-off load action; measuring the shearing force and the shearing displacement action of the welding spot by using a push-pull dynamometer; a power device 36 (an air cylinder 36) is arranged below the top plate, the air inlet and supply pipe is used for balancing the air cylinder, and finally the internal piston plate is jacked up, so that a power rod connected with the piston plate moves upwards vertically at a constant speed and drives a positioning hanging rack to move together, and the action of drawing the welding column is realized; the circular slot is used for connecting the objective table with a piston rod of a power device 37 (an air cylinder 37); positioning action is realized by placing CGA/brazing filler metal welding spots on a shearing side of a vertical plate objective table; the bolt connection is utilized to realize the fixing action of the push broach and the screw rod on the push-pull dynamometer; the fixing action of the top plate and the two side plates of the positioning hanging rack is realized through the bolt connection; the cylinder motion of the power device 37 (cylinder 37) is used for driving the objective table to realize the action of vertical upward and uniform motion; the push broach with the circular arc structure is just tangent to the spherical crown welding point moving vertically upwards so as to realize shearing action.

The invention has the beneficial effects that:

first, the pneumatic transmission device of the present invention measures pull-off load and shear strength, and besides the values of the two, the two are measured on almost the same device, which is beneficial to improving efficiency.

Secondly, the welding column can be clamped through the thread clamping and elastic deformation mechanism, the centering precision is high, the clamping force is high, the welding column can be positioned in the center of the clamp and can be clamped, and the problems that the welding column cannot be pulled out vertically, the welding column is not perpendicular to a jaw face when being clamped, mechanical damage is caused in the pulling process of the welding column and the like are solved or reduced; compared with the existing jaw clamp utilizing the WJJ-01 push-pull dynamometer, the inner side surface of the elastic centering tool of the device is also in a deep cylindrical shape, so that the mechanical damage to a welding column during pull-off load measurement can be reduced.

Thirdly, the power devices 36 and 37 (the air cylinders 36 and 37) adopt double-acting single-piston air cylinders, namely, air cavities on two sides of the piston can compress air to realize bidirectional movement; the cylinder operates stably, the power rod is guaranteed to do uniform and vertical motion, the cylinder piston is stressed uniformly, and the problems that force is not uniform, uniform and the welding column cannot be pulled out vertically in the manual welding column drawing process are solved.

Fourthly, the push-pull force meter fixing part and the push-pull force meter are connected with the two side plates of the positioning hanging rack through bolts, so that the positioning hanging rack is convenient to disassemble and convenient to measure pull-off load and welding spot shearing strength; the vertical plate and the bearing plate are connected by using a bolt when measuring the pulling-off load, and the power device 37 (the air cylinder 37) does not work; when the shearing strength is measured, the lower end of the vertical plate is vertically connected with a power rod of a power device 37 (an air cylinder 37), and the vertical plate is not connected with a bearing plate bolt; compared with the prior art, the operation is flexible and convenient; meanwhile, the verticality of the welding column, the push-pull dynamometer and the push knife and the levelness of the PCB are guaranteed, and the measuring result is more accurate.

Fifthly, the invention is especially suitable for measuring the pull-out load of the welding column with larger connection strength and the shear strength of the welding spot with larger diameter.

Sixthly, the force-displacement sensor is arranged on the push-pull dynamometer, so that the shearing force and the shearing displacement can be conveniently read through curve change.

Drawings

FIG. 1 is a view showing the construction of a drawing apparatus according to the present invention;

FIG. 2 is a partial enlarged view of a drawing spot;

FIG. 3 is an enlarged view of a portion of the push-pull dynamometer fastening mechanism;

FIG. 4 is a block diagram of the shearing module of the present invention;

FIG. 5 is a partial enlarged view of a shear weld;

FIG. 6 is a partial enlarged view of the stage and the alignment plate;

FIG. 7 is a schematic view of a stage with CGA solder joints;

FIG. 8 is a schematic view of the positioning plate assembly;

FIG. 9 is a schematic structural view of a riser assembly;

FIG. 10 is a schematic view of a positioning hanger assembly;

FIG. 11 is a schematic view of a push-pull force gauge assembly;

FIG. 12 is a schematic view of the top plate assembly;

FIG. 13 is a schematic view of the assembly of the chuck body;

FIG. 14 is a schematic view of the clamp assembly and sleeve assembly;

FIG. 15 is a schematic view of a push-type broach assembly;

fig. 16 is a schematic structural view of a base plate assembly.

Detailed Description

The first embodiment is as follows:

the embodiment is described with reference to fig. 1 to 16, and the pneumatic transmission auxiliary device for measuring the pull-out load and the welding spot shearing performance of the welding column in the CGA column planting process in the embodiment includes an object stage and object stage positioning plate mechanism, a positioning hanger assembly, a push-pull dynamometer assembly, a clamp body assembly, a push-pull broach assembly, a power device assembly, a top plate and a bottom plate assembly, and the like, wherein the clamp body assembly and the pull-force measurement assembly are mounted on the positioning hanger mechanism, the positioning hanger is mounted on the top plate assembly, the clamp body assembly is located above the object stage assembly, and the power device 36 is mounted above the top plate; the centering action of the welding column and the drill chuck component is realized through the movement of the objective table component and the power device 37; the clamp body assembly is used for realizing vertical connection and clamping actions with the CGA welding spot welding column; the power device 1 realizes the vertical uniform upward movement of the positioning hanger component and the vertical uniform upward movement of the drill chuck component.

The second embodiment is as follows:

the present embodiment is described with reference to fig. 6 to 9, and the objective table, the positioning plate assembly and the vertical plate assembly of the pneumatic transmission auxiliary device for measuring the pulling-out load and the welding spot shearing performance of the welding column in the CGA column planting process in the present embodiment include an objective table pulling-out side 1, a CGA/brazing filler metal welding spot and a PCB plate 2, an objective table main body 3, an objective table shearing side 4, an objective table bottom circular groove 5, a groove 6, a vertical plate main body 42, a sliding fastening bolt 43, a vertical plate bolt sliding groove 44, a positioning bolt 7, a square through hole 8, a positioning plate 9 and a screw hole 10, the CGA/brazing filler metal welding spot and the PCB plate 2 are connected to the objective table pulling-out side 1 or the objective table shearing side 4 through the groove 6, the objective table main body 3 and the objective table shearing side 4 are symmetrically welded to the objective table main body 3 in a certain manner, the objective table main body 3 is fixedly mounted on the objective, the object stage positioning plate 9 is fixed on the two side vertical plates 42 through two side sliding fastening bolts 43, the sliding fastening bolts and the vertical plate bolt sliding grooves 44 are positioned on the vertical plate main body 42, and the lower end of the object stage main body 3 is connected with a piston rod of the power device 37 through riveting. Other components and connections are the same as those in the first embodiment.

The object stage drawing side 1 and the object stage shearing side 4 are fixed with the PCB 2 through the groove 6, the object stage main body 3 is fixed with the object stage positioning plate 9 through the positioning bolt 7, the sliding fastening bolt 43 slides on the vertical plate main body 42 through the vertical plate bolt sliding groove 44, and the object stage positioning plate 9 is fixed with the vertical plate 42 through the sliding fastening bolt 43.

The third concrete implementation mode:

the positioning hanger assembly, the push-pull force meter assembly and the top plate assembly of the pneumatic transmission auxiliary device for measuring the pulling-out load and the welding spot shearing performance of the welding column in the CGA column planting process according to the embodiment are described with reference to FIGS. 10 to 12, and the positioning hanger assembly, the push-pull force meter assembly and the top plate assembly according to the embodiment comprise positioning hanger double-side bolt holes 14, a positioning hanger main body 11, positioning bolts 12, bolt holes 13, positioning hanger bolt holes 14, circular groove holes 15, fastening bolts 16, a push-pull force meter 17, a push-pull force meter container 18, a fixing bolt 19, a push-pull force meter fastening mechanism 20, threaded holes 21, threaded holes 22, a push-pull force meter hook nut 23, a push-pull force meter hook 24, an air guide pipe opening 31, a power device 37, a threaded hole 38, a top plate assembly square groove 39, a top plate 40, a fastening bolt 41 and a square hole, wherein the push-, the push-pull dynamometer 17 is placed in the push-pull dynamometer container 18 and is fastened and positioned by a push-pull dynamometer fastening mechanism 20, a fixing bolt 19 and a threaded hole 21, and the push-pull dynamometer container 18 is fixed with the positioning hanger main body 11 through a double-side threaded hole 22; the positioning hanger main body 11 is connected with a top plate 40 through a top plate assembly square groove hole 39, the power device 37 is connected with the top plate assembly 40 through a square groove hole 42, the power device 37 is fixed on the top plate assembly 40 through a fastening bolt 41, the push-pull force gauge container 18 is fixedly installed below the top plate assembly 40, and the positioning hanger main body 11 is in bolt fastening connection with the top plate assembly 40 at a bolt hole 14 through a fastening bolt 16 during a shear test.

The push-pull dynamometer hook 24 is in bolted connection with the push-pull dynamometer 17 through the push-pull dynamometer hook nut 23, the push-pull dynamometer 17 is clamped and positioned in the push-pull dynamometer container 18 through the push-pull dynamometer fastening mechanism 20, the fixing bolt 19 and the threaded hole 21, the push-pull dynamometer container 18 is connected with the positioning hanger main body 11 through the positioning bolt 12 and the threaded hole 22, the positioning hanger main body 11 is connected with the top plate assembly 40 through the top plate assembly square groove hole 39, and the positioning hanger main body 11 drives the push-pull dynamometer 17 to vertically move upwards at a constant speed through the power device 37; through the above operations, the positioning hanger main body and the push-pull dynamometer 17 can move upwards at a constant speed in the Z direction; other components and connections are the same as those in the first embodiment.

The fourth concrete implementation mode:

referring to fig. 13-15, fig. 9 illustrates the present embodiment, in which the push-type broach assembly and the vertical plate assembly include a clamp hook 25, a clamp body 26, an open-type structure and semicircular slot 27, a sleeve 28, a push-type broach body 29, a push-type broach top threaded hole 30, a push-type broach arc groove 31, a vertical plate body 42, a sliding fastening bolt 43 and a vertical plate bolt sliding groove 44, the CGA welding point and the welding column in the PCB 2 are tightly bolted with the semicircular slot 27, the sleeve 28 and the clamp body 26 through the open-type structure, the clamp body hook 25 is connected with a push-pull force meter hook 24, the welding column drawing action is completed by the uniform vertical upward movement of the push-pull force meter 17 and the positioning hanger main body 11 under the drive of the power device 37; the push broach main body 29 is fixedly connected with a screw rod at the lower end of a push-pull dynamometer 17 through a push broach top threaded hole 30, the fastening bolt 16 is fixedly connected with a top plate assembly 40 through the positioning hanger double-side bolt hole 14, the positioning bolt 7 is dismounted, and the CGA/brazing filler metal welding point 2 on the objective table shearing side 4 is matched with the arc surface of the welding point of the push broach main body 29 through the sliding fastening bolt 43, the vertical plate bolt sliding groove 44, the bottom plate fastening bolt 34 and the power device 36; the upward movement of the piston rod in the power device 36 drives the welding spot 2 on the shearing side 4 of the objective table to vertically move upward at a constant speed, the brazing filler metal welding spot 2 on the shearing side 4 of the objective table is pushed away by the push broach main body 29, and the shearing force and the shearing displacement are read by moving a force-displacement sensor on the push pull dynamometer 17; other components and connection relationships are the same as those in the second embodiment.

The fifth concrete implementation mode:

the embodiment is described with reference to fig. 12 and 16, and the bottom plate and top plate assembly of the pneumatic transmission auxiliary device for measuring the pull-off load and the welding spot shearing performance of the welding column in the CGA column planting process according to the embodiment includes a bottom plate-to-air duct opening 31, an air duct opening 32, a bottom plate 33, a fastening bolt 34, a bottom plate square groove 35, a power device 36 (an air cylinder 36), a power device 37 (an air cylinder 37), a threaded hole 38, a top plate assembly square groove hole 39, a top plate 40, a fastening bolt 41 and a square groove hole 42, in a shearing test, the bolt hole 38 is connected with the positioning hanger double-side bolt holes 14 to fix the positioning hanger main body 11, the fastening bolt 41 fixes the power device 37, the square groove hole 42 is connected with the power device 37, the positioning hanger square groove hole 39 is connected with the positioning hanger main body 11, the bottom plate assembly air duct opening, The air ports of the power device 36 are connected, the square groove 35 of the bottom plate is connected with the power device 36 to realize the installation and the X-direction movement of the power device 36, the fastening bolt 34 of the bottom plate realizes the fixation of the power device 37, and the power device 37 is driven to work by inputting compressed air; in a pulling-out load measurement test, the positioning bolt 7 fastens the objective table main body 3, the sliding fastening bolt 43 fixes the objective table positioning plate 9 and enables the CGA/brazing filler metal welding point 2 to be vertically aligned with the clamp body main body 26, and the clamp body main body 26 and the sleeve 28 clamp the CGA/brazing filler metal welding point 2 to finish pulling under the driving of the power device 37.

The power device 36 is placed in the bottom plate square groove 35; the power device 36 is fastened in the bottom plate square groove 35 by the bottom plate fastening bolt 34; the power device 37 is put into the square groove hole 42 and fixed in the square groove hole 42 by the fastening bolt 41; the positioning hanger main body 11 is inserted into the top plate assembly square groove hole 39; in the shear test, the bolt holes 38 and the positioning hanger double-side bolt holes 14 are tightly connected through the positioning hanger double-side fixing bolts 16, so that the fixing action of the positioning hanger main body 11 is realized; the

power devices

36 and 37 are driven to complete work by inputting compressed air; the other components and the connection relationship are the same as those of the second, third and fifth embodiments.

The sixth specific implementation mode:

the present embodiment is described with reference to fig. 1 to 16, and the material of the PCB pad of the pneumatic transmission auxiliary device for measuring the pulling-out load and the shearing performance of the solder joint of the CGA post-implantation process may be any one of Cu, Au, Ag, and Ni, or a multi-layer metal film pad formed by combining Cu, Au, Ag, and Ni; other components and connection relations are the same as those of the first to fifth embodiments.

The seventh embodiment:

the embodiment is described with reference to fig. 1 to 16, and the CGA weld column material of the pneumatic transmission auxiliary device for measuring the pulling-out load and the weld spot shearing performance of the CGA column planting process may be any one of Cu, brass, iron-nickel alloy and solder weld column; other components and connection relationships are the same as those in the first to sixth embodiments.

The specific implementation mode is eight:

the embodiment is described with reference to fig. 1 to 16, and the CGA solder joint of the pneumatic transmission auxiliary device for measuring the pulling-off load and the shear property of the solder joint in the CGA column planting process according to the embodiment may be any one of 63Sn37Pb, sn3.0ag0.5cu, sn0.3ag0.7cu, Sn58Bi and sn0.7cu, or may be formed by combining 63Sn37Pb, sn3.0ag0.5cu, sn0.3ag0.7cu, Sn58Bi and sn0.7cu; other components and connection relationships are the same as those in the first to seventh embodiments.

The specific implementation method nine:

the embodiment is described with reference to fig. 1 to 16, and the diameter of the solder column or solder column of the pneumatic transmission auxiliary device for measuring the pulling-off load and the shearing performance of the solder column in the CGA column planting process according to the embodiment may be any one of 300 μm, 400 μm, 500 μm, 600 μm and 700 μm; other components and connection relationships are the same as those in the first to eighth embodiments.

The detailed implementation mode is ten:

the embodiment is described with reference to fig. 1 to 16, the diameter of the welding spot of the pneumatic transmission auxiliary device for measuring the pulling-off load and the shearing performance of the welding spot in the CGA column-planting process according to the embodiment may be any one of 300 μm, 400 μm, 500 μm, 600 μm, 700 μm, 800 μm, 1000 μm, 1200 μm and 1500 μm; other components and connection relationships are the same as those in the first to ninth embodiments.

Examples

Example 1:

the invention relates to an air pressure transmission auxiliary device for measuring pulling-out load and welding spot shearing performance of a welding column in a CGA column planting process, which comprises the following steps:

step one, placing a 63Sn37Pb welding spot with the diameter to be measured being 1000 microns, the welding pad being a Cu welding pad and the welding column being Cu (the diameter being 400 microns) into a drawing side groove of an objective table:

the CuCGA/63Sn37Pb welding spot which is completed by column planting in the new mode is connected with a groove on the drawing side of a carrier in a PCB, and a carrier main body is fastened on a positioning plate by a bolt to prevent the carrier main body from moving;

step two, installing and positioning the hanger assembly:

vertically inserting the positioning hanging rack into square groove holes on two sides of a top plate assembly in the device, wherein the size of each square groove hole is completely the same as that of two side plates of the positioning hanging rack, a circular groove is formed in the top of the positioning hanging rack and used for connecting a piston rod of an air cylinder, and finally, the positioning hanging rack and the top plate are fastened through two bolts to prevent the positioning hanging rack from moving;

step three, installing a push-pull force gauge assembly and a clamp body assembly:

fixing the push-pull dynamometer in the push-pull dynamometer container through a bolt and a push-pull dynamometer fastening mechanism, opening a switch of the push-pull dynamometer and pressing a 'SET' button to record pull-off load, fastening the push-pull dynamometer on a positioning hanger body through bolts at two sides, screwing a push-pull dynamometer hook on a bolt rod below the push-pull dynamometer and screwing the bolt rod with a nut; the clamp body adopts a rotary clamping and elastic deformation mechanism, a slotted hole of the clamp body adopts a cylindrical shape to reduce the mechanical damage to the Cu column, and the clamp body and the sleeve are hung on a push-pull dynamometer hook through a hook;

adjusting the positions of the center of the fixture body, the Cu column, the positioning plate and the cylinder:

the Cu column is clamped by the clamp body in a rotating mode, the fastening bolt capable of sliding on the vertical plate is adjusted, the air cylinder on the bottom plate is adjusted, the air cylinder can move in the square groove of the bottom plate, finally, the center of the clamp body is perpendicular to the axial direction of the Cu column and is on a horizontal line, the object stage and the axial direction of a piston rod of the air cylinder are also on a horizontal line, and the sliding fastening bolt on the vertical plate and the fixing bolt on the bottom plate are screwed to prevent the positioning plate and the air cylinder from moving;

step five, opening the positioning hanging rack bolt, operating the device and recording numerical values:

the fastening bolts on the two sides of the positioning hanger are opened, compressed air is introduced into the air guide tube of the air cylinder, when the air inlet pressure and the air outlet pressure reach balance, the gravity of the positioning hanger, the clamp body, the push-pull dynamometer mechanism and the like is overcome to do work, the piston rod of the air cylinder can vertically move upwards at a constant speed to drive the positioning hanger, the push-pull dynamometer mechanism and the clamp body to move upwards at a constant speed, and the Cu column is pulled out of a CuCGA/63Sn37Pb welding spot; the pull-out load (unit: N) at the moment of pulling out the Cu column was recorded by a push-pull dynamometer.

Example 2:

step one, placing a 63Sn37Pb welding point with the diameter to be measured being 1000 microns, the welding pad being a Cu welding pad and the welding column being Cu (the diameter being 400 microns):

the CuCGA/63Sn37Pb welding spot which is completed by column planting in the new mode is connected with a groove on the shearing side of a carrying table in the PCB, and a fastening bolt on a positioning plate is opened;

step two, installing and positioning the hanger assembly:

step three, installing a push-pull force meter assembly and a push-pull tool assembly:

fixing the push-pull dynamometer in the push-pull dynamometer container through a bolt and a push-pull dynamometer fastening mechanism, opening a switch of the push-pull dynamometer and pressing a 'SET' button to record shearing force and shearing displacement, fastening the push-pull dynamometer on the positioning hanger main body through bolts at two sides, and screwing a push broach device on a bolt rod below the push-pull dynamometer; the lower part of the push broach is provided with an arc-shaped groove for matching with a spherical CuCGA/63Sn37Pb welding point;

fourthly, adjusting the positions of the push broach, the spherical crown CuCGA/63Sn37Pb welding spot, the positioning plate and the cylinder:

the push broach groove is used for fitting the spherical crown CuCGA/63Sn37Pb welding spot, the fastening bolt which can slide on the vertical plate is adjusted, the air cylinder on the bottom plate is adjusted, the air cylinder can move in the square groove of the bottom plate, finally, the push broach groove is fitted with the spherical crown CuCGA/63Sn37Pb welding spot and is vertical to the vertical line, the object stage and the axial direction of the piston rod of the air cylinder are also on the same horizontal line, and the sliding fastening bolt on the vertical plate and the fixing bolt on the bottom plate are screwed to prevent the positioning plate and the air cylinder from moving;

step five, introducing compressed air into the air cylinder, operating the device and recording numerical values:

tightening fastening bolts at two sides of the positioning hanging rack, introducing compressed air into an air guide pipe of an air cylinder on the air bottom plate, overcoming the gravity of an object stage and the like to do work after air inlet and exhaust pressure is balanced, enabling a piston rod of the air cylinder to vertically move upwards at a constant speed, driving the object stage main body and a CuCGA/63Sn37Pb welding point to move upwards at a constant speed, and enabling the arc surface of the push broach to be matched with the spherical crown-shaped welding point to finish shearing action; a force-displacement sensor is arranged in the push-pull dynamometer and used for recording the change of the shearing displacement along with the shearing load, and the shearing displacement and the peak value (unit: N) of the shearing force at the moment are recorded when the shearing force is sharply reduced.

Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims

1. The utility model provides a pneumatic transmission auxiliary device for measuring CGA post planting technology weld column pulls out load and solder joint shearing property which characterized in that: the pneumatic transmission auxiliary device for measuring the pulling-out load and the welding spot shearing performance of the welding column in the CGA column planting process comprises an object stage, an object stage positioning plate mechanism, a positioning hanger assembly, a tension measuring assembly, a fixture body assembly, a push broach assembly, a power device assembly, a top plate assembly, a bottom plate assembly and the like, wherein the fixture body assembly and the tension measuring assembly are installed on the positioning hanger mechanism, a positioning hanger is installed on the top plate assembly, the fixture body assembly is located above the object stage assembly, and a power device (36) is installed above the top plate; the centering action of the welding column and the clamp body assembly is realized through the movement of the objective table assembly and the power device (37); the clamp body assembly is used for realizing vertical connection and clamping actions with the CGA/brazing filler metal welding spot welding column; the vertical uniform upward movement of the positioning hanger component and the vertical uniform upward movement of the fixture body component are realized through a power device (37).

2. The pneumatic transmission auxiliary device for measuring the pulling-out load and the shearing performance of the welding point of the welding column in the CGA column planting process according to claim 1, is characterized in that: the objective table, the positioning plate assembly and the vertical plate assembly of the pneumatic transmission auxiliary device for measuring the pulling-out load and the welding spot shearing performance of the welding column in the CGA column planting process comprise an objective table pulling side (1), a CGA welding spot and a PCB (2), an objective table main body (3), an objective table shearing test (4), an objective table bottom circular groove (5), a groove (6), a vertical plate main body (42), a sliding fastening bolt (43), a vertical plate bolt sliding groove (44), a positioning bolt (7), a square through hole (8), a positioning plate (9) and a screw hole (10), wherein the CGA/brazing filler metal welding spot and the PCB (2) are connected to the objective table pulling side (1) or the objective table shearing side (4) through the groove (6), the objective table main body (3) and the objective table shearing test (4) are symmetrically welded on the objective table main body (3) pulling side (1) in a certain mode, the object stage main body (3) is fixedly arranged on the object stage positioning plate (9) through a positioning bolt (7), the object stage positioning plate (9) is fixed on vertical plates (42) on two sides through sliding fastening bolts (43) on two sides, the sliding fastening bolts and vertical plate bolt sliding grooves (44) are positioned on the vertical plate main body (42), and the lower end of the object stage main body (3) is connected with a piston rod of the power device (37) through riveting.

3. The pneumatic transmission auxiliary device for measuring the pulling-out load and the shearing performance of the welding point of the welding column in the CGA column planting process according to claim 1, is characterized in that: the positioning hanger assembly, the push-pull dynamometer assembly and the top plate assembly of the pneumatic transmission auxiliary device for measuring the pulling-out load and the welding spot shearing performance of the welding column in the CGA column planting process comprise positioning hanger double-side bolt holes (14), a positioning hanger main body (11), positioning bolts (12), bolt holes (13), positioning hanger bolt holes (14), circular slotted holes (15), fastening bolts (16), a push-pull dynamometer (17), a push-pull dynamometer container (18), fixing bolts (19), a push-pull dynamometer fastening mechanism (20), threaded holes (21), threaded holes (22), push-pull dynamometer hook nuts (23), a push-pull dynamometer hook (24), an air duct opening (31), a power device (37), threaded holes (38), a top plate assembly square groove hole (39), a top plate (40), fastening bolts (41) and square groove holes (42), wherein the push-pull dynamometer hook nuts (23) are sleeved on the push-pull dynamometer hook (24) and are in cooperation with the push-pull dynamometer (17) bolt holes (17) The connection is carried out, a push-pull dynamometer (17) is placed in a push-pull dynamometer container (18) and is fastened and positioned by a push-pull dynamometer fastening mechanism (20), a fixing bolt (19) and a threaded hole (21), and the push-pull dynamometer container (18) is fixed with the positioning hanger main body (11) through a bilateral threaded hole (22); the positioning hanger main body (11) is connected with a top plate (40) through a square groove hole (39) of the top plate assembly, a power device (37) is connected with the top plate assembly (40) through a square groove hole (42), the power device (37) is fixed on the top plate assembly (40) through a fastening bolt (41), a push-pull dynamometer container (18) is fixedly installed below the top plate assembly (40), and the positioning hanger main body (11) is in bolt fastening connection with the top plate assembly (40) at a bolt hole (14) through a fastening bolt (16) during a shearing test.

4. The pneumatic transmission auxiliary device for measuring the pulling-out load and the shearing performance of the welding point of the welding column in the CGA column planting process according to claim 2, is characterized in that: the spiral clamping and elastic deformation clamp body device of the pneumatic transmission auxiliary device for measuring the pulling-out load and the welding spot shearing performance of the welding column in the CGA column planting process comprises a clamp body hook (25), a clamp body main body (26), an open type structure, a semicircular groove hole (27), a sleeve (28), a push broach main body (29), a push broach top threaded hole (30), a push broach arc groove (31), a vertical plate main body (42), a sliding fastening bolt (43) and a vertical plate bolt sliding groove (44), wherein a CGA welding spot and a welding column in a PCB (2) are tightly connected with the semicircular groove hole (27), the sleeve (28) and the clamp body main body (26) through the open type structure, the clamp body hook (25) is connected with a push-pull force meter hook (24), the welding column drawing action is completed by the uniform vertical upward movement of the push-pull force meter (17) and the positioning hanger main body (11) under the drive of a power device (37); the push broach main body (29) is fixedly connected with a screw rod at the lower end of a push-pull dynamometer (17) through a push broach top threaded hole (30), the fastening bolt (16) is fixedly connected with a top plate assembly (40) through a positioning hanger bilateral bolt hole (14), the positioning bolt (7) is dismounted, and the CGA/brazing filler metal welding spot (2) on the shearing side (4) of the objective table is matched with the arc surface of the welding spot of the push broach main body (29) through the sliding fastening bolt (43), a vertical plate bolt sliding groove (44), a bottom plate fastening bolt (34) and a power device (36); the welding point (2) on the shearing side (4) of the objective table is driven to vertically move upwards at a constant speed by the upward movement of a piston rod in the power device (36), the welding point (2) on the shearing side (4) of the objective table is pushed away by the push-type broach main body (29), and the shearing force and the shearing displacement are read by a force-displacement sensor on the push-pull dynamometer (17).

5. The pneumatic transmission auxiliary device for measuring the pulling-out load and the shearing performance of the welding point of the welding column in the CGA column planting process according to claim 3, wherein the pneumatic transmission auxiliary device comprises: the bottom plate and top plate assembly of the pneumatic transmission auxiliary device for measuring the pulling-out load and the welding spot shearing performance of the welding column in the CGA column planting process comprises a bottom plate to air guide pipe orifice (31), an air guide pipe orifice (32), a bottom plate (33), a fastening bolt (34), a bottom plate square groove (35), a power device (36), a power device (37), a threaded hole (38), a top plate assembly square groove hole (39), a top plate (40), a fastening bolt (41) and a square groove hole (42), wherein the bolt hole (38) is connected with the positioning hanger double-side bolt holes (14) to fix the positioning hanger main body (11) in a shearing test, the fastening bolt (41) is used for fixing the power device (37), the square groove hole (42) is connected with the power device (37), the positioning hanger square groove hole (39) is connected with the positioning hanger main body (11), and the air guide pipe orifice (31) and the power device (36) of, 37) The air ports are connected, the square groove (35) of the bottom plate is connected with the power device (36) to realize the installation and X-direction movement of the power device (36), the fastening bolt (34) of the bottom plate realizes the fixation of the power device (37), and the power device (37) is driven to work by inputting compressed air; in a pull-out load measurement test, the object stage main body (3) is fastened by the positioning bolt (7), the object stage positioning plate (9) is fixed by the fastening bolt (43) in a sliding mode, the CGA/brazing filler metal welding points (2) are vertically centered with the clamp body main body (26), and the CGA/brazing filler metal welding points (2) are clamped by the clamp body main body (26) and the sleeve (28) and are pulled under the driving of the power device (37).

6. The pneumatic transmission auxiliary device for measuring the pulling-out load and the shearing performance of the welding point of the welding column in the CGA column planting process according to claim 4, wherein the pneumatic transmission auxiliary device comprises: the PCB bonding pad material of the pneumatic transmission auxiliary device for measuring the pulling-off load and the welding spot shearing performance of the welding column in the CGA column planting process can be any one of Cu, Au, Ag and Ni, or a multilayer metal film bonding pad formed by matching and combining Cu, Au, Ag and Ni.

7. The CGA welding column material of the pneumatic transmission auxiliary device for measuring the pulling-off load and the welding spot shearing performance of the CGA column planting process according to claim 5, wherein the material can be any one of Cu, brass, iron-nickel alloy and brazing filler metal welding columns.

8. The CGA solder joint solder for the air pressure transmission auxiliary device for measuring the pulling-off load and the shear performance of the solder joint in the CGA column planting process of claim 6, wherein the solder joint solder can be any one of 63Sn37Pb, Sn3.0Ag0.5Cu, Sn0.3Ag0.7Cu, Sn58Bi and Sn0.7Cu, or the solder joint solder is formed by matching and combining 63Sn37Pb, Sn3.0Ag0.5Cu, Sn0.3Ag0.7Cu, Sn58Bi and Sn0.7Cu.

9. The solder column diameter size of the pneumatic transmission auxiliary device for measuring the pulling-off load and the shearing performance of the welding spot of the CGA column planting process welding column according to claim 7 can be any one of 300 μm, 400 μm, 500 μm, 600 μm and 700 μm.

10. The welding spot diameter size of the pneumatic transmission auxiliary device for measuring the pulling-off load and the shearing performance of the welding spot of the welding column in the CGA column planting process according to claim 8, wherein the diameter size of the brazing filler metal welding column can be any one of 300 μm, 400 μm, 500 μm, 600 μm, 700 μm, 800 μm, 1000 μm, 1200 μm and 1500 μm.