CN113695697A

CN113695697A - Coil dip soldering device

Info

Publication number: CN113695697A
Application number: CN202111056351.0A
Authority: CN
Inventors: 李加林; 时文静; 陈忠源; 胡秋原
Original assignee: Suzhou Inspur Intelligent Technology Co Ltd
Current assignee: Suzhou Inspur Intelligent Technology Co Ltd
Priority date: 2021-09-09
Filing date: 2021-09-09
Publication date: 2021-11-26

Abstract

The invention discloses a coil tin immersion welding device.A positioning column of a coil jig is inserted with a positioning coil, so that each limit position is limited at a specific grabbing position; after the coil is placed in place, the vertical movement driver and the horizontal movement driver of the transfer assembly are matched with each other to adjust the position of the clamping assembly; the clamping assembly drives the clamping block to move in an opening and closing mode through the clamping driver so as to clamp or release the coil, when tin immersion is needed, the coil is taken down from the positioning column, the vertical moving driver and the transverse moving driver are matched with each other, the coil is immersed into the tin immersion assembly, and the tin immersion welding operation is completed; the mechanical control is adopted to control the tin immersion process, the tin immersion degree and time are kept consistent every time, the uniform tin immersion effect can be achieved, and the quality of coil tin immersion welding is ensured.

Description

Coil dip soldering device

Technical Field

The invention relates to the field of soldering processing, in particular to a coil soldering device.

Background

An SMD (Surface Mounted device) coil is one of important component parts in a server, and solder dipping is a key process of a server SMD coil finished product, and the reliability of solder dipping is related to the quality of the server product.

Fig. 1 is a schematic structural diagram of an SMD coil, and when soldering, it is necessary to solder and fix a coil 01 and a metal fixing member 02 by immersion soldering. The tin immersion welding process of SMD coils in the current industry all adopts manual operation, and in the tin immersion welding process, the complete tin immersion welding is difficult to accomplish, and the result that causes is coil quality unstable, and the product quality of server also is very difficult to guarantee.

For those skilled in the art, how to ensure the quality of the coil solder dipping is a technical problem to be solved at present.

Disclosure of Invention

The invention provides a coil wicking welding device, which utilizes a mechanical structure to automatically complete a wicking process and realizes uniform wicking welding effect, and the specific scheme is as follows:

a coil wicking soldering apparatus comprising:

the coil jig comprises a base and a positioning column, wherein the positioning column is columnar and is used for inserting and positioning a coil;

the clamping assembly comprises a clamping driver and a clamping block, wherein the clamping driver drives the clamping block to move in an opening and closing mode to clamp or release the coil;

the transfer assembly comprises a supporting block, a vertical movement driver and a transverse movement driver, the clamping assembly is mounted on the supporting block, and the vertical movement driver drives the supporting block to move vertically; the transverse moving driver drives the vertical moving driver to move transversely;

and the wicking component is used for containing liquid tin, and the vertical movement driver drives the coil to translate between the coil jig and the wicking component.

Optionally, the supporting block is provided with a shaking assembly, the shaking assembly comprises a rocker and a swinging driver, the clamping assembly is arranged on the rocker, and the swinging driver can drive the rocker to swing in a reciprocating manner.

Optionally, the shake-up assembly further comprises a drive rod fixed to the output shaft of the swing driver; the two ends of the driving rod are respectively provided with a driving wheel, the rocker is correspondingly provided with a driven wheel, and the driving wheel and the driven wheel are in transmission through a chain, a belt or a gear.

Optionally, the base is provided with at least three positioning columns in linear arrangement.

Optionally, the coil fixture is placed on a support table, and the support table is provided with a track for guiding the coil fixture.

Optionally, the track that the brace table set up includes material loading slide, diversion slide, unloading slide, the material loading slide with the unloading slide is parallel to each other and not collinear, diversion slide perpendicular to the material loading slide with the unloading slide, and both ends dock respectively in the material loading slide with the unloading slide.

Optionally, the support table is provided with a turning driver, and the driving direction of the turning driver is parallel to the turning slideway, and the turning driver is used for enabling the coil jig to translate along the turning slideway and move from a position right opposite to the feeding slideway to a position right opposite to the discharging slideway.

Optionally, the output end of the turning driver is connected with a pulling rod, the pulling rod can be driven to translate, the pulling rod is bent upwards to form a protrusion, a pulling stop block is arranged, and when the pulling rod translates, the pulling stop block drives the coil jig to translate.

Optionally, the wicking assembly includes the lateral wall of two parallels, the wicking assembly corresponds sets up the scum board, the scum board is by scraping sediment driver drive translation, and the translation direction is parallel the lateral wall of two parallels of wicking assembly, two edges that the scum board is relative respectively with the laminating of the lateral wall of two parallels of wicking assembly is used for scraping the adnexed tin sediment of wicking assembly inner wall.

The invention provides a coil tin-dipping welding device.A positioning column of a coil jig is inserted with a positioning coil, so that each limit position is limited at a specific grabbing position; after the coil is placed in place, the vertical movement driver and the horizontal movement driver of the transfer assembly are matched with each other to adjust the position of the clamping assembly; the clamping assembly drives the clamping block to move in an opening and closing mode through the clamping driver so as to clamp or release the coil, when tin immersion is needed, the coil is taken down from the positioning column, the vertical moving driver and the transverse moving driver are matched with each other, the coil is immersed into the tin immersion assembly, and the tin immersion welding operation is completed; the mechanical control is adopted to control the tin immersion process, the tin immersion degree and time are kept consistent every time, the uniform tin immersion effect can be achieved, and the quality of coil tin immersion welding is ensured.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic diagram of an SMD coil;

FIG. 2A is an isometric view of a coil wicking welding apparatus of the present invention;

FIG. 2B is an enlarged partial view of the dashed circle in FIG. 2A;

FIG. 3A is a schematic axial view of another angle of the wicking soldering apparatus of the present invention;

FIG. 3B is an enlarged partial view of the dashed circle portion of FIG. 3A;

fig. 4 is a schematic structural diagram of a coil jig.

The figure includes:

the device comprises a coil 01, a metal fixing part 02, a coil jig 1, a base 11, a positioning column 12, a clamping assembly 2, a clamping driver 21, a clamping block 22, a transfer assembly 3, a supporting block 31, a vertical moving driver 32, a transverse moving driver 33, a tin immersion assembly 4, a slag scraping plate 41, a slag scraping driver 42, a shaking assembly 5, a rocker 51, a swinging driver 52, a driving rod 53, a driving wheel 54, a driven wheel 55, a supporting table 6, a feeding slideway 61, a direction-changing slideway 62, a discharging slideway 63 and a direction-changing driver 64.

Detailed Description

The core of the invention is to provide a coil tin immersion welding device, which utilizes a mechanical structure to automatically complete a tin immersion process and realize uniform and consistent tin immersion welding effect.

In order to make those skilled in the art better understand the technical solution of the present invention, the coil wicking welding apparatus of the present invention will be described in detail with reference to the accompanying drawings and the specific embodiments.

The coil tin immersion welding device comprises a coil jig 1, a clamping assembly 2, a transfer assembly 3, a tin immersion assembly 4 and the like. Fig. 2A and fig. 3A are schematic axial views of the coil wicking welding device of the present invention at two different angles.

Fig. 4 is a schematic structural diagram of the coil fixture 1; the coil jig 1 comprises a base 11 and a positioning column 12, wherein the base 11 is a supporting base structure, the positioning column 12 is columnar, the bottom of the positioning column 12 is fixed on the base 11, the positioning column 12 protrudes upwards, and the positioning column 12 is used for inserting and positioning a coil; the coil is the loop configuration who coils formation, and the appearance of reference column 12 is the same with the shape of coil, and the coil can overlap in the periphery of reference column 12, and the back is emboliaed to the coil, and the bottom and the base 11 contact of coil are supported by base 11 provides, are injectd the circumferential position of coil by reference column 12, and the coil can't transversely take place the displacement.

Referring to FIG. 2B, a partial enlarged view of the dashed circle in FIG. 2A is shown; the clamping assembly 2 comprises a clamping driver 21 and a clamping block 22, the clamping block 22 comprises two mutually independent modules which are mutually separated and closed, and the clamping driver 21 drives the clamping block 22 to open and close to clamp or release the coil; the clamping actuator 21 may employ an air cylinder to clamp the coil when the two modules of the clamping block 22 are close to each other and to release the coil when they are separated from each other. As shown in fig. 2A and 3A, the opening and closing direction of the holding block 22 is substantially along the X-axis direction.

The transfer component 3 comprises a supporting block 31, a vertical movement driver 32 and a transverse movement driver 33, the clamping component 2 is arranged on the supporting block 31, and the whole clamping component 2 is synchronously displaced along with the supporting block 31. The vertical movement driver 32 drives the supporting block 31 to move vertically, and correspondingly, a guide structure is arranged in parallel with the vertical movement driver 32, and the supporting block 31 moves vertically along the vertical guide structure; the traverse actuator 33 drives the vertical actuator 32 to move laterally, and accordingly, a guide structure is provided in parallel with the traverse actuator 33, along which the whole formed by the vertical actuator 32 and the support block 31 moves laterally. As shown in fig. 2A and 3A in combination, the driving direction of the vertical movement driver 32 is along the Z-axis direction, and the driving direction of the lateral movement driver 33 is along the X-axis direction.

Referring to FIG. 3B, a partial enlarged view of the dotted circle in FIG. 3A is shown; the wicking component 4 holds liquid tin, and wicking component 4 is a container, and the top is not sealed, and the coil can be from the liquid tin liquid that holds in the downward immersion wicking component 4 of follow, and the continuous heating makes tin keep liquid. The vertical movement driver 32 drives the coil to translate between the coil fixture 1 and the wicking component 4, namely in the X-axis direction in the figure.

When the coil clamping device is used, a coil is placed on the positioning column 12 of the coil jig 1, the coil jig 1 is positioned, the vertical movement driver 32 and the transverse movement driver 33 are matched with each other, the position of the supporting block 31 is adjusted, the clamping component 2 on the supporting block 31 is positioned right above the coil jig 1, the vertical movement driver 32 drives the supporting block 31 downwards, the clamping blocks 22 are kept in a separated state, and when the clamping blocks 22 reach the position of the coil, the clamping driver 21 drives the clamping blocks 22 to be close to clamp the coil; then the vertical driver 32 drives the supporting block 31 and the clamping component 2 to move upwards, and the horizontal driver 33 drives the vertical driver 32, the supporting block 31 and the clamping component 2 to form a whole, so that the clamping component 2 reaches the position right above the tin immersion component 4; the clamping assembly 2 is driven by the vertical movement driver 32 to move downwards again, and the coil is immersed in the liquid tin; taking out the coil after tin immersion; and putting the coil on the positioning column 12 of the coil jig 1 again according to the reverse sequence to finish the whole tin immersion process.

The coil tin immersion welding device disclosed by the invention adopts a mechanical control tin immersion process, the tin immersion degree and the tin immersion time are kept consistent every time, the uniform and consistent tin immersion effect can be achieved, and the quality of coil tin immersion welding is ensured.

On the basis of the scheme, the supporting block 31 of the invention is provided with the shaking assembly 5, and all parts of the shaking assembly 5 are arranged on the supporting block 31. Shake even subassembly 5 and include rocker 51 and swing driver 52, rocker 51 rotates to be connected in supporting shoe 31, presss from both sides and gets subassembly 2 and install in rocker 51, presss from both sides and gets subassembly 2 and rocker 51 and keep relatively fixed, combines to show in fig. 2B, presss from both sides the length direction of getting subassembly 2 and follows the Y axle direction, and two rockers 51 are fixed in respectively and press from both sides the both ends of getting subassembly 2, press from both sides the pivot reciprocating swing that gets subassembly 2 and can surround the Y axle direction.

The swing driver 52 can drive the rocker 51 to swing back and forth, and a motor is usually selected as a main power part of the swing driver 52, and the rocker 51 is driven to rotate back and forth by the swing driver 52, so that the clamping assembly 2 can swing.

Specifically, the shake-up assembly 5 of the present invention further includes a driving rod 53, the driving rod 53 is fixed to an output shaft of the swing driver 52, the driving rod 53 is rotatably mounted on the supporting block 31, the swing driver 52 directly drives the driving rod 53 to rotate, and the driving rod 53 further drives the rocker 51.

Two ends of the driving rod 53 are respectively provided with a driving wheel 54, the two rockers 51 are respectively and correspondingly provided with a driven wheel 55, and the driving wheel 54 and the driven wheel 55 are in transmission through a chain, a belt or a gear; the driving wheel 54 and the driven wheel 55 shown in the drawings of the present invention are both externally toothed wheels, driven by toothed belts. Drive lever 53 and rocker 51 all extend along the Y-axis direction, and drive lever 53 is located the top, and rocker 51 is located the below.

After the immersion tin is finished, the coil is shaken back and forth by the shaking-up component 5 when the coil is taken out, so that the liquid tin which is not solidified is distributed more uniformly, and the tin layer at each position is kept uniform.

Referring to fig. 4, the base 11 of the present invention is provided with at least three positioning pillars 12 arranged in a straight line, and the positioning pillars 12 have the same shape; correspondingly, the clamping block 22 of the clamping component 2 is in a long strip shape, all coils can be clamped simultaneously, the tin immersion process of the coils is completed at one time, and the production efficiency is improved.

On the basis of any one of the above technical schemes and the mutual combination thereof, the coil jig 1 is placed on the support table 6, the support table 6 is provided with a track for guiding the coil jig 1, and the coil jig 1 moves along the track for feeding and discharging.

Furthermore, the track arranged on the support table 6 comprises a feeding slide way 61, a direction-changing slide way 62 and a discharging slide way 63, wherein the feeding slide way 61 and the discharging slide way 63 are parallel to each other and are not collinear, the direction-changing slide way 62 is perpendicular to the feeding slide way 61 and the discharging slide way 63, two ends of the direction-changing slide way 62 are respectively butted with the feeding slide way 61 and the discharging slide way 63, the feeding slide way 61 is butted with the direction-changing slide way 62, the direction-changing slide way 62 is butted with the discharging slide way 63, and as shown in a combined figure 2B, an arrow (i) and an arrow (iii) are along the Y-axis direction, and an arrow (ii) is along the X-axis direction; during production, the coil jig 1 moves in the feeding slide way 61 along the direction shown by the arrow (r), the coil jig 1 moves in the turning slide way 62 along the direction shown by the arrow (r), and the coil jig 1 moves in the discharging slide way 63 along the direction shown by the arrow (c).

The coil jig 1 is translated along the arrow direction and pushed against the side wall of the turning slideway 62 when reaching the tail end, the coil jig 1 is stopped at the position, the coil jig 1 is positioned, a coil is taken and placed at the position, and the coil jig 1 is positioned through the bent part between the feeding slideway 61 and the turning slideway 62.

Furthermore, the present invention provides a direction-changing actuator 64 on the support base 6, and the direction-changing actuator 64 may be in the form of an air cylinder or the like. The driving direction of the direction-changing driver 64 is parallel to the direction-changing slide way 62, and is used for translating the coil jig 1 along the direction-changing slide way 62, moving the coil jig 1 from a position right opposite to the feeding slide way 61 to a position right opposite to the discharging slide way 63, and automatically completing the transfer of the coil jig 1.

Specifically, the output end of the direction-changing driver 64 is connected with the pulling rod, the output end of the direction-changing driver 64 drives the pulling rod to translate, the length direction of the pulling rod is along the X axis, and the output end of the direction-changing driver 64 reciprocates in the X axis direction; the pulling rod is upwards bent and protrudes to be provided with a pulling stop dog used for hooking the coil jig 1, the pulling stop dog protrudes out of the outer surface of the pulling rod, the protruding direction is upward along the Z axis, the pulling rod is fixed at the telescopic output end of the turning driver 64, when the telescopic output end of the turning driver 64 translates, the pulling stop dog contacts with the side wall of the coil jig 1, and the coil jig 1 is driven to translate along the turning slideway 62 through the pulling stop dog.

As shown in fig. 3B, the wicking component 4 includes two parallel side walls, the wicking component 4 is correspondingly provided with a scraping plate 41, the scraping plate 41 is driven by a scraping driver 42 to translate, the translation direction of the scraping plate 41 is parallel to the two parallel side walls of the wicking component, as shown in fig. 3A, wherein the two parallel side walls of the wicking component 4 are along the Y-axis direction, two opposite edges of the scraping plate 41 are respectively close to and attached to the two parallel side walls of the wicking component 4, as shown in fig. 3B, the scraping plate 41 is a flat plate, the length direction is along the X-axis, and two vertical edges at two ends of the X-axis are respectively close to and attached to the inner surfaces of the two parallel side walls of the wicking component 4; the moving direction of the scraping plate 41 is parallel to two parallel side walls of the tin immersion assembly 4, the two-way arrow in fig. 3B indicates the moving direction of the scraping plate 41 and the driving direction of the scraping driver 42, and the scraping plate 41 is circularly and reciprocally translated along the Y-axis direction. The slag scraping driver 42 adopts a cylinder structure and the like, drives the slag scraping plate 41 to move in a reciprocating manner, and is used for scraping tin slag attached to the inner wall of the tin immersion assembly 4 and keeping the tin immersion assembly 4 clean.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. A coil wicking welding device, characterized by includes:

the coil jig (1) comprises a base (11) and a positioning column (12), wherein the positioning column (12) is columnar and is used for inserting and positioning a coil;

the clamping assembly (2) comprises a clamping driver (21) and a clamping block (22), wherein the clamping driver (21) drives the clamping block (22) to move in an opening and closing mode to clamp or release the coil;

the transfer assembly (3) comprises a supporting block (31), a vertical movement driver (32) and a transverse movement driver (33), the clamping assembly (2) is installed on the supporting block (31), and the vertical movement driver (32) drives the supporting block (31) to move vertically; the transverse moving driver (33) drives the vertical moving driver (32) to move transversely;

and the tin immersion component (4) is used for containing liquid tin, and the vertical movement driver (32) drives the coil to translate between the coil jig (1) and the tin immersion component (4).

2. The coil wicking welding device according to claim 1, characterized in that the supporting block (31) is provided with a shaking assembly (5), the shaking assembly (5) comprises a rocking bar (51) and a rocking driver (52), the clamping assembly (2) is mounted on the rocking bar (51), and the rocking driver (52) can drive the rocking bar (51) to rock back and forth.

3. The coil wicking welding device of claim 2, wherein the swing assembly (5) further comprises a drive rod (53), the drive rod (53) being fixed to an output shaft of the swing driver (52); two ends of the driving rod (53) are respectively provided with a driving wheel (54), the rocker (51) is correspondingly provided with a driven wheel (55), and the driving wheel (54) and the driven wheel (55) are in transmission through a chain, a belt or a gear.

4. The coil wicking soldering apparatus according to claim 1, wherein the base (11) is provided with at least three positioning posts (12) arranged in a straight line.

5. The coil wicking soldering apparatus according to any one of claims 1 to 4, wherein the coil fixture (1) is placed on a support table (6), and the support table (6) is provided with a rail for guiding the coil fixture (1).

6. The coil wicking welding device of claim 5, characterized in that the track that the brace table (6) set up includes material loading slide (61), diversion slide (62), unloading slide (63), material loading slide (61) and unloading slide (63) are parallel to each other and not collinear, diversion slide (62) be perpendicular to material loading slide (61) and unloading slide (63), and both ends dock respectively in material loading slide (61) and unloading slide (63).

7. The coil wicking welding device according to claim 6, characterized in that the supporting platform (6) is provided with a direction-changing driver (64), and the driving direction of the direction-changing driver (64) is parallel to the direction-changing slideway (62), and is used for translating the coil jig (1) along the direction-changing slideway (62) and moving the coil jig from a position facing the feeding slideway (61) to a position facing the discharging slideway (63).

8. The coil wicking welding device of claim 7, characterized in that the output end of the direction-changing driver (64) is connected with a pulling rod, the pulling rod can be driven to translate, the pulling rod is bent upwards to form a pulling block, and when the pulling rod translates, the pulling block drives the coil jig (1) to translate.

9. The coil wicking welding device according to claim 5, wherein the wicking assembly (4) includes two parallel side walls, the wicking assembly (4) is correspondingly provided with a slag scraping plate (41), the slag scraping plate (41) is driven by a slag scraping driver (42) to translate, the translation direction is parallel to the two parallel side walls of the wicking assembly (4), and two opposite edges of the slag scraping plate (41) are respectively attached to the two parallel side walls of the wicking assembly (4) for scraping off tin slag attached to the inner wall of the wicking assembly (4).