CN115354256B - Auxiliary inserting equipment for diode pin tin-immersing rack - Google Patents

Abstract

The invention provides auxiliary material inserting equipment for a diode pin tin-immersing rack, which comprises a workbench, wherein the middle part of the workbench is provided with a tin-immersing rack supporting and placing jig, and material inserting components are correspondingly arranged on two opposite sides of the tin-immersing rack supporting and placing jig; the material inserting assembly comprises a first linear sliding table, a second linear sliding table, a T-shaped mounting plate and a clamping structure; the second linear sliding table is connected with the first linear sliding table through a first sliding block, and the second linear sliding table and the first linear sliding table form a vertical relationship; the T-shaped mounting plate is connected with the second linear sliding table through a second sliding block; the clamping structure is correspondingly arranged on the T-shaped mounting plate and corresponds to the tin-immersing rack bearing jig in position; a through hole is formed in the middle of the T-shaped mounting plate at a position corresponding to the clamping structure; the clamping structure comprises a first clamping part and a second clamping part which are oppositely matched. And the working efficiency is improved.

Description

Auxiliary inserting equipment for diode pin tin-immersing rack

Technical Field

The invention relates to the technical field of diode processing, in particular to auxiliary material inserting equipment for a diode pin tin-immersing frame.

Background

During diode processing, tin-immersing treatment is required to be carried out on pins of the strip-shaped material belt below the tube shell. The conventional operations in the prior art are: the material belt is orderly placed in the rectangular tin-immersing frame 10 by hands, the bottom of the material belt 11 is supported by the material supporting plate 13 in the rectangular tin-immersing frame 10, and then the top of the material belt is tightly pressed by the I-shaped pressing rod 15, so that tin-immersing treatment can be carried out on a plurality of material belts at one time. The operation efficiency of putting the material strip into the rectangular tin-immersed frame 10 by the human hand is very low, mainly because the material strip is basically bent when the rectangular tin-immersed frame 10 is inserted, so that the human hand is required to straighten the material on one hand and to align the yielding grooves 12 on two opposite sides of the rectangular tin-immersed frame 10 for insertion on the other hand, the human hand is required to concentrate in the processes of keeping the straightening action and calibrating the insertion action, thus being easy to fatigue, and being difficult to avoid the condition of shaking hands to influence the material insertion efficiency. In view of this, a solution is needed.

Disclosure of Invention

Based on the above, the invention aims to provide auxiliary material inserting equipment for the diode pin immersed tin frame, so that automatic material inserting is realized, and the working efficiency is improved.

The invention provides auxiliary material inserting equipment for a diode pin tin-immersing rack, which comprises a workbench, wherein the middle part of the workbench is provided with a tin-immersing rack supporting and placing jig, and material inserting components are correspondingly arranged on two opposite sides of the tin-immersing rack supporting and placing jig;

the material inserting assembly comprises a first linear sliding table, a second linear sliding table, a T-shaped mounting plate and a clamping structure;

the second linear sliding table is connected with the first linear sliding table through a first sliding block, and the second linear sliding table and the first linear sliding table form a vertical relationship; the T-shaped mounting plate is connected with the second linear sliding table through a second sliding block; the clamping structure is correspondingly arranged on the T-shaped mounting plate and corresponds to the tin-immersing rack bearing jig in position;

a through hole is formed in the middle of the T-shaped mounting plate at a position corresponding to the clamping structure;

the clamping structure comprises a first clamping part and a second clamping part which are oppositely matched, and the first clamping part and the second clamping part both comprise a push-pull driving motor and clamping jaws; the power output end of the push-pull driving motor is connected with the clamping jaw; the lower parts of the two clamping jaws penetrate through the through holes and extend to the lower surface of the T-shaped mounting plate.

Further, a third linear sliding table is arranged at a position, corresponding to the tin-immersing rack supporting and placing jig, on the workbench, and the third linear sliding table is connected with the tin-immersing rack supporting and placing jig through a third sliding block.

Further, the upper surface of the tin-immersing rack bearing jig is provided with a plurality of limit slots along the width direction.

Further, the clamping jaw is arranged in a vertical Z shape.

Further, two lateral surface of one clamping jaw on the material inserting assembly is provided with a lug, vertical threaded holes are formed in the lug, and fool-proof ejector pins are correspondingly connected with threads in the vertical threaded holes.

The beneficial effects of the invention are as follows: the staff is with the material area correspondingly placed in the clamping structure of both sides and is carried out the centre gripping by the clamping structure, then, the second straight line slip table makes T shape mounting panel to invading tin frame and hold the position that the tool corresponds to insert to accomplish and insert the material action, so repeatedly operate, effectively avoided the material area to influence the condition of efficiency because of the curved material, work efficiency is high, has saved the manpower greatly.

Drawings

Fig. 1 is a top view of a pin-immersed tin frame.

Fig. 2 is a bottom perspective view of the pin-immersed tin frame.

Fig. 3 is a perspective view of the present invention.

Fig. 4 is a partial view of the clamping structure of the present invention.

Fig. 5 is a partial view (another perspective) of the clamping structure of the present invention.

The reference numerals are: rectangular tin-immersing rack 10, material belt 11, abdication groove 12, material supporting plate 13, gap 14, I-shaped compression bar 15, T-shaped mounting plate 18, second sliding block 17, second linear sliding table 16, push-pull driving motor 20, clamping jaw 19, protruding block 21, fool-proof thimble 22, third linear sliding table 23, through hole 24, first clamping part 25, workbench 26, material inserting assembly 27, tin-immersing rack bearing jig 28, limit slot 29, first linear sliding table 30, second clamping part 31, clamping structure 32 and first sliding block 33.

Detailed Description

The invention will be further described in detail with reference to the following detailed description and the accompanying drawings, in order to further understand the features and technical means of the invention and the specific objects and functions achieved.

In the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and include, for example, either permanently connected, removably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

Referring to fig. 1-5, the invention provides auxiliary inserting equipment for a diode pin solder mask, which comprises a workbench 26, wherein a solder mask holding jig 28 is arranged in the middle of the workbench 26, and inserting components 27 are correspondingly arranged on two opposite sides of the solder mask holding jig 28.

The stock insertion assembly 27 includes a first linear slide 30, a second linear slide 16, a T-shaped mounting plate 18, and a clamping structure 32.

The second linear sliding table 16 is connected with the first linear sliding table 30 through a first sliding block 33, and the second linear sliding table 16 and the first linear sliding table 30 form a vertical relationship; the T-shaped mounting plate 18 is connected with the second linear sliding table 16 through a second sliding block 17; the clamping structure 32 is correspondingly mounted on the T-shaped mounting plate 18 and is positioned to correspond to the tin-plated fixture 28.

Through holes 24 are formed in the middle of the T-shaped mounting plate 18 at positions corresponding to the clamping structures 32.

The clamping structure 32 comprises a first clamping part 25 and a second clamping part 31 which are oppositely matched, and the first clamping part 25 and the second clamping part 31 comprise a push-pull driving motor 20 and clamping jaws 19; the power output end of the push-pull driving motor 20 is connected with the clamping jaw 19; the lower portions of the two clamping jaws 19 each extend through the through hole 24 and to the lower surface of the T-shaped mounting plate 18.

A third linear sliding table 23 is arranged on the workbench 26 at a position corresponding to the tin-immersing rack supporting and placing jig 28, and the third linear sliding table 23 is connected with the tin-immersing rack supporting and placing jig 28 through a third sliding block. The third linear sliding table 23 can drive the tin-immersing rack supporting and placing jig 28 to move back and forth along the length direction of the tin-immersing rack supporting and placing jig 28, so that a worker can conveniently place and take away the rectangular tin-immersing rack 10 on the tin-immersing rack supporting and placing jig 28.

The upper surface of the solder bump receiving jig 28 is formed with a plurality of stopper slots 29 along the width direction thereof.

The clamping jaw is arranged in a vertical Z shape, and through the arrangement, the push-pull stroke of the push-pull driving motor 20 is shortened, and the clamping speed is improved.

The outer side face of one clamping jaw on the two material inserting assemblies 27 is provided with a protruding block 21, the protruding block 21 is provided with a vertical threaded hole, and the vertical threaded hole is correspondingly in threaded connection with a foolproof thimble 22. Through setting up prevent slow-witted thimble 22, after the material area is inserted the suitable position in the groove 12 of stepping down, prevent slow-witted thimble 22 can with hold in the palm the upper surface contact of flitch 13 to avoid appearing the material area and excessively insert and damage the condition. The vertical extension distance of the fool-proof thimble 22 on the convex block 21 can be adjusted, so that the fool-proof thimble can be properly fine-tuned according to the abrasion condition, and the service life is too long.

The principle of operation of this embodiment is:

1. the rectangular tin-immersing rack 10 is placed on the tin-immersing rack bearing jig 28, and the material supporting plate 13 at the bottom of the rectangular tin-immersing rack is correspondingly embedded into the limiting slot 29 so as to realize stable placement;

2. the material taking belt is put at the positions of the clamping structures 32 on the two sides, and the two ends of the material belt are respectively clamped and fixed by the first clamping part 25 and the second clamping part 31 in a matched manner, so that the bending or the position deviation of the material belt is avoided;

3. the second linear sliding table 16 drives the T-shaped mounting plate 18 and the clamping structure 32 to move straight towards the direction of the tin-immersing rack supporting and placing jig 28 until the clamping jaws 19 drive the material belt to be inserted into the abdication groove 12, and at the moment, the two clamping jaws 19 are positioned at the gaps 14 between the abdication grooves 12 and the material supporting plates 13 on the two opposite sides of the rectangular tin-immersing rack 10, so that the material belt which is adjacently placed is prevented from touching;

4. then the second linear sliding table 16 drives the T-shaped mounting plate 18 and the clamping structure 32 to reset, and the first linear sliding table 30 drives the second linear sliding table 16, the T-shaped mounting plate 18 and the clamping structure 32 to displace for a set distance and then the above material inserting actions are continuously repeated.

The invention effectively avoids the condition that the efficiency of the material belt is affected by bending the material, has high working efficiency and greatly saves manpower.

The above examples illustrate only one embodiment of the invention, which is described in more detail and is not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (4)

1. The utility model provides a supplementary material equipment of inserting of diode pin invasion tin frame, includes workstation (26), its characterized in that: the middle part of the workbench (26) is provided with a tin-immersing rack supporting jig (28), and two opposite sides of the tin-immersing rack supporting jig (28) are correspondingly provided with material inserting components (27);

the material inserting assembly (27) comprises a first linear sliding table (30), a second linear sliding table (16), a T-shaped mounting plate (18) and a clamping structure (32);

the second linear sliding table (16) is connected with the first linear sliding table (30) through a first sliding block (33), and the second linear sliding table (16) and the first linear sliding table (30) form a vertical relationship; the T-shaped mounting plate (18) is connected with the second linear sliding table (16) through a second sliding block (17); the clamping structure (32) is correspondingly arranged on the T-shaped mounting plate (18) and is positioned corresponding to the tin-immersing rack bearing jig (28);

a through hole (24) is formed in the middle of the T-shaped mounting plate (18) and corresponds to the clamping structure (32);

the clamping structure (32) comprises a first clamping part (25) and a second clamping part (31) which are oppositely matched, and the first clamping part (25) and the second clamping part (31) comprise a push-pull driving motor (20) and clamping jaws (19); the power output end of the push-pull driving motor (20) is connected with the clamping jaw (19); the lower parts of the two clamping jaws (19) penetrate through the through holes (24) and extend to the lower surface of the T-shaped mounting plate (18); the outer side face of one clamping jaw on the two material inserting assemblies (27) is provided with a protruding block (21), the protruding block (21) is provided with a vertical threaded hole, and the vertical threaded hole is correspondingly connected with a foolproof thimble (22) in a threaded mode.

2. The diode pin penetration tin frame auxiliary inserting device according to claim 1, wherein: the tin-immersing rack is characterized in that a third linear sliding table (23) is arranged at a position, corresponding to the tin-immersing rack supporting and placing jig (28), on the workbench (26), and the third linear sliding table (23) is connected with the tin-immersing rack supporting and placing jig (28) through a third sliding block.

3. The diode pin penetration tin frame auxiliary inserting device according to claim 1, wherein: the upper surface of the tin-immersing rack bearing jig (28) is provided with a plurality of limit slots (29) along the width direction.

4. The diode pin penetration tin frame auxiliary inserting device according to claim 1, wherein: the clamping jaw is arranged in a vertical Z shape.