CN112828415B - Auxiliary soldering device for high-frequency transformer - Google Patents

Abstract

The invention relates to a soldering device, in particular to an auxiliary soldering device for a high-frequency transformer. The invention provides a high-frequency transformer auxiliary soldering device which does not need manual soldering and can solder a plurality of transformers simultaneously. The invention provides an auxiliary soldering device of a high-frequency transformer, which comprises the following components: the bottom plate is provided with a first frame body; the cleaning mechanisms are arranged on two sides of the first frame body; the cleaning mechanism is provided with a clamping mechanism; and the driving mechanism is arranged on one side of the first frame body. The transformer is clamped through the clamping mechanism, and then the cleaning mechanism is driven to move downwards through the driving mechanism to clean the film heated by the tin in the first frame body back to move, and the cleaning mechanism is driven to move downwards through the back to move so that the transformer is contacted with the tin to carry out tin feeding.

Description

Auxiliary soldering device for high-frequency transformer

Technical Field

The invention relates to a soldering device, in particular to an auxiliary soldering device for a high-frequency transformer.

Background

The high-frequency transformer consists of an iron core and a coil, wherein the coil comprises two or more E-shaped windings. When the high-frequency transformer is manufactured, links such as winding on the spool, tape wrapping, wiring, soldering tin, assembly, inductance test, copper tape wrapping, detection, pin correction, packaging and the like are mainly included.

At present, a clamp is used for clamping a high-frequency transformer, pins are inserted into a tin furnace, the temperature of the tin furnace is adjusted to 450-500 ℃ in advance, the pins are inserted into the tin furnace for continuous soldering for 2-4 s, and then the pins are taken out. However, the efficiency is extremely low because the clips are used for soldering tin only singly at a time, and because the temperature of the tin liquid is very high, when soldering tin is carried out, the hands of the staff are closer to the tin furnace, the hands of the staff are easy to scald due to carelessness, and potential safety hazards are easy to bring.

Therefore, there is a need to design a high-frequency transformer auxiliary soldering device capable of soldering a plurality of transformers at the same time without manually soldering.

Disclosure of Invention

In order to overcome the defects that the use of a clip can only singly carry out soldering tin each time, and because the temperature of tin liquid is very high, when soldering tin, hands of workers are close to a tin furnace, hands of the workers are easy to scald due to carelessness, and potential safety hazards are easy to bring, the invention solves the technical problems that: provided is a high-frequency transformer auxiliary soldering device which does not need manual soldering and can solder a plurality of transformers at the same time.

The technical scheme of the invention is as follows: the auxiliary soldering tin device for the high-frequency transformer comprises a bottom plate, a first frame body and a cleaning mechanism, wherein the first frame body is arranged on the bottom plate; the cleaning mechanisms are arranged on two sides of the first frame body; the cleaning mechanism is provided with a clamping mechanism; and the driving mechanism is arranged on one side of the first frame body.

Optionally, the cleaning mechanism comprises: the first fixing blocks are symmetrically arranged on two sides of the first frame body; the four first fixed blocks are respectively provided with a straight type chute plate; the first sliding bars are arranged in the four straight chute plates in a sliding manner; the scraping plates are arranged between one opposite sides of each two first sliding rods; the connecting rods are rotatably arranged on one back side of the four first sliding rods; and a second fixed block is arranged between the other ends of the two similar connecting rods.

Optionally, the chucking mechanism includes: the first fixing rod is arranged between two sides of the two second fixing blocks; the middle part of the first fixing rod at one side of the first bearing seat is provided with the first bearing seat; the first rotating shaft is rotatably arranged on the first bearing seat; the rotating block is arranged on the first rotating shaft; the pressing block is arranged on the rotating block; the first elastic piece is arranged between one side of the first bearing seat and one side of the rotating block.

Optionally, the drive mechanism comprises: the bottom of the second fixed block on one side is provided with a third fixed block; the first frame body on the same side is provided with a bracket; the cylinder is arranged on the support, a telescopic rod is arranged in the cylinder in a sliding mode, and the other end of the telescopic rod is connected with the third fixed block.

Optionally, the method further comprises: a sliding plate is arranged between the two first fixing rods in a sliding manner, and round holes are uniformly spaced on the sliding plate; the middle parts of the two second fixing blocks are respectively provided with a guide sleeve; the second slide bar is arranged on both guide sleeves in a sliding manner; and second elastic pieces are arranged between one sides of the two guide sleeves and one sides of the two second sliding rods.

Optionally, the method further comprises: the second bearing seat is provided with second bearings at the bottoms of the two first fixing blocks far away from one side of the air cylinder; the second rotating shaft is rotatably arranged between the two second shafts; the wedge-shaped blocks are symmetrically arranged on the second rotating shaft; a third elastic piece is arranged between one side of the two wedge blocks and one side of the two second bearings; a limiting rod is arranged between the tops of the two second bearings; the second fixing rod is arranged at one end of the second sliding rod far away from one side of the air cylinder; and the bottom end of the second fixing rod is provided with a third fixing rod.

Optionally, the method further comprises: the other two sides of the first frame body are symmetrically provided with two third bearing seats; the third rotating shafts are rotatably arranged in the four third bearing seats; the second frame body is arranged between the two third rotating shafts on the same side; the swing rods are arranged at one back end of the four third rotating shafts; the two first sliding rods close to one side of the air cylinder are respectively provided with a fourth fixed rod, the two first fixed blocks on the same side are respectively internally provided with a sliding groove, and the two fourth fixed rods are positioned in the sliding grooves; the ejector rods are arranged at the end parts of the two fourth fixing rods.

Optionally, the third elastic members are torsion springs.

The invention has the following advantages: 1. the transformer is clamped through the clamping mechanism, and then the cleaning mechanism is driven to move downwards through the driving mechanism to clean the film heated by the tin in the first frame body back to move, and the cleaning mechanism is driven to move downwards through the back to move so that the transformer is contacted with the tin to carry out tin feeding.

2. The transformer can be clamped by downward rotation of the pressing block, so that the transformer is prevented from shaking and falling when tin is added.

3. The third dead lever can rock the slide with wedge inclined plane contact for the transformer tin-plating is more even.

4. The second frame body can collect the film heated by the tin in the first frame body.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of a cleaning mechanism according to the present invention.

Fig. 3 is a schematic perspective view of the clamping mechanism of the present invention.

Fig. 4 is a schematic perspective view of a first part of the present invention.

Fig. 5 is a schematic perspective view of a second part of the present invention.

Fig. 6 is a schematic perspective view of a third portion of the present invention.

In the above figures: the device comprises a bottom plate 1 …, a first frame body 2 …, a cleaning mechanism 3 …, a first fixed block 31 …, a straight sliding groove plate 32 …, a first sliding rod 33 …, a second scraping plate 34 …, a connecting rod 35 …, a second fixed block 36 …, a clamping mechanism 4 …, a first fixed rod 41 …, a first bearing seat 42 …, a first rotating shaft 43 …, a rotating block 44 …, a pressing block 45 …, a first elastic member 46 …, a driving mechanism 5 …, a third fixed block 51 …, a bracket 52 …, a cylinder 53 …, a sliding plate 6 …, a guide sleeve 7 …, a second sliding rod 8 …, a second elastic member 9 …, a second bearing seat 10 …, a second rotating shaft 11 …, a wedge block 12 …, a third elastic member 13 …, a limit rod 14 …, a second fixed rod 15 …, a third fixed rod 16 …, a third bearing seat 17 …, a third frame body 18 …, a second frame body 19 …, a swing rod 21, a fourth rotating shaft … and a fixed rod 22.

Detailed Description

The invention will be further described with reference to specific examples, illustrative examples and illustrations of which are provided herein to illustrate the invention, but are not to be construed as limiting the invention.

Example 1

As shown in fig. 1, a high-frequency transformer auxiliary soldering device comprises a base plate 1, a first frame body 2, a cleaning mechanism 3, a clamping mechanism 4 and a driving mechanism 5, wherein the first frame body 2 is arranged on the base plate 1, the cleaning mechanism 3 is arranged on the left side and the right side of the first frame body 2, the clamping mechanism 4 is arranged on the cleaning mechanism 3, and the driving mechanism 5 is arranged on the left side of the first frame body 2.

When the transformer needs to be soldered, a certain amount of tin is added into the first frame body 2 by a worker, the clamping mechanism 4 is pushed upwards by the worker, then the transformer is placed on the clamping mechanism 4 by another worker, at this time, the clamping mechanism 4 is released by the worker, the transformer is clamped by the lower rotating reset, the driving mechanism 5 is controlled by the worker, the cleaning mechanism 3 is driven by the downward movement to clean a film heated by the tin in the first frame body 2, the tin is contacted by the transformer, the tin is applied by the cleaning mechanism 3 is driven by the downward movement, the driving mechanism 5 is controlled by the worker, the cleaning mechanism 3 is driven by the upward movement to reset the opposite movement of the cleaning mechanism 3, the clamping mechanism 4 is driven by the opposite movement of the cleaning mechanism 4, the transformer is not applied by the tin any more, at this time, the transformer is pushed upwards by the worker, the transformer which is finished by the tin is removed by the other worker, at this time, the clamping mechanism 4 is released by the worker, and the welding mechanism 4 is reset by the downward rotating reset. The device has simple structure and is convenient to operate.

Example 2

As shown in fig. 2 and 3, on the basis of embodiment 1, the cleaning mechanism 3 includes a first fixing block 31, a straight-shaped sliding groove plate 32, a first sliding rod 33, a scraping plate 34, a connecting rod 35 and a second fixing block 36, the first fixing block 31 is symmetrically arranged on the left side and the right side of the first frame 2, the straight-shaped sliding groove plate 32 is arranged on the four first fixing blocks 31, the first sliding rod 33 is arranged in the four straight-shaped sliding groove plates 32 in a sliding manner, the scraping plate 34 is arranged between opposite sides of each two first sliding rods 33, the connecting rod 35 is arranged on one side of each of the four first sliding rods 33 in a rotating manner, and the second fixing block 36 is arranged between the other ends of the two similar connecting rods 35.

When the transformer is required to be soldered, a worker firstly adds a certain amount of tin into the first frame body 2, then another worker pushes the clamping mechanism 4 upwards, the worker releases the clamping mechanism 4, after the transformer is completely soldered, the worker controls the driving mechanism 5, the driving mechanism 5 moves downwards to drive the second fixing block 36 to move downwards, the second fixing block 36 moves downwards to drive the first sliding rod 33 to slide back in the straight sliding groove plate 32 through the connecting rod 35, the first sliding rod 33 slides back to drive the scraping plate 34 to move back to clean a film heated by the tin in the first frame body 2, the second fixing block 36 moves downwards to drive the clamping mechanism 4 to enable the transformer to be in contact with the tin, after the transformer is completely soldered, the worker controls the driving mechanism 5, the driving mechanism 5 moves upwards to drive the second fixing block 36 to move upwards, the second fixing block 36 moves upwards to drive the first sliding rod 33 to slide back in the straight sliding groove plate 32 through the connecting rod 35, at this time, the first sliding rod 33 moves back to drive the scraping plate 34 to move back to enable the second fixing block 36 to move upwards, and then the worker does not touch the other worker to move back to the tin, and the welding mechanism 4 is not to be in contact with the tin, and then the welding mechanism 4 is released. The device has a simple structure, and can clean the film heated by the tin in the first frame body 2.

The clamping mechanism 4 comprises a first fixing rod 41, a first bearing seat 42, a first rotating shaft 43, a rotating block 44, a pressing block 45 and a first elastic piece 46, wherein the first fixing rod 41 is arranged between two sides of the two second fixing blocks 36, the middle part of the first fixing rod 41 at the rear side is provided with the first bearing seat 42, the first rotating shaft 43 is rotatably arranged on the first bearing seat 42, the rotating block 44 is arranged on the first rotating shaft 43, the pressing block 45 is arranged on the rotating block 44, and the first elastic piece 46 is arranged between one side of the first bearing seat 42 and one side of the rotating block 44.

After a worker firstly adds a certain amount of tin into the first frame body 2, the worker pushes the rotating block 44 upwards, the rotating block 44 rotates upwards on the first rotating shaft 43, the first elastic piece 46 deforms, the rotating block 44 rotates upwards to drive the pressing block 45 to rotate upwards, at the moment, another worker places the transformer between the two first fixing rods 41, then the worker releases the rotating block 44, the first elastic piece 46 resets to drive the rotating block 44 to rotate downwards on the first rotating shaft 43, the rotating block 44 rotates downwards to drive the pressing block 45 to rotate downwards to clamp the transformer, the worker controls the driving mechanism 5, the driving mechanism 5 moves downwards to drive the second fixing block 36 to move downwards, the second fixing block 36 moves downwards to drive the first fixing rod 41 to move downwards, so that the transformer contacts tin to perform tin feeding, after the tin feeding of the transformer is completed, a worker controls the driving mechanism 5, the driving mechanism 5 moves upwards to drive the second fixed block 36 to move upwards, the second fixed block 36 moves upwards to drive the first fixed rod 41 to move upwards, the transformer is not contacted with the tin any more, the worker pushes the rotating block 44 upwards, the rotating block 44 rotates upwards on the first rotating shaft 43, the first elastic piece 46 is deformed, the rotating block 44 rotates upwards to drive the pressing block 45 to rotate upwards to not clamp the transformer any more, the other worker takes out the transformer after the tin feeding is completed, the worker releases the rotating block 44, the first elastic piece 46 resets to drive the rotating block 44 to rotate downwards on the first rotating shaft 43, and the rotating block 44 rotates downwards to drive the pressing block 45 to rotate downwards to reset. The device has a simple structure, and can clamp the transformer, so that the transformer is prevented from shaking and falling when being tinned.

The driving mechanism 5 comprises a third fixed block 51, a bracket 52 and a cylinder 53, the bottom of the second fixed block 36 on the left side is provided with the third fixed block 51, the first frame body 2 on the left side is provided with the bracket 52, the bracket 52 is provided with the cylinder 53, the cylinder 53 is internally provided with a telescopic rod in a sliding manner, and the other end of the telescopic rod is connected with the third fixed block 51.

When the transformer is clamped, the working personnel control air cylinder 53, the telescopic rod of the air cylinder 53 contracts to drive the second fixing rod 36 to move downwards, the second fixing rod 36 moves downwards to drive the first fixing rod 41 to move downwards, and then the transformer is contacted with tin for tin feeding, after the transformer is tin fed, the working personnel control air cylinder 53, the telescopic rod of the air cylinder 53 extends to drive the second fixing rod 36 to move upwards, the second fixing rod 36 moves upwards to drive the first fixing rod 41 to move upwards, and then the transformer is separated from tin contact and tin feeding is not carried out any more. The device has a simple structure, and can lead the transformer on the first fixing rod 41 to be contacted with tin for tin plating.

Example 3

As shown in fig. 4, 5 and 6, the sliding plate 6, the guide sleeves 7, the second sliding rods 8 and the second elastic pieces 9 are further included, the sliding plate 6 is slidably arranged between the two first fixing rods 41, round holes are uniformly spaced on the sliding plate 6, the guide sleeves 7 are respectively arranged in the middle of the two second fixing blocks 36, the second sliding rods 8 are respectively slidably arranged on the two guide sleeves 7, and the second elastic pieces 9 are respectively arranged between one side of the two guide sleeves 7 and one side of the two second sliding rods 8.

The rotating block 44 rotates upwards to drive the pressing block 45 to rotate upwards, at the moment, another worker pushes the second sliding rod 8 back to slide back in the guide sleeve 7, the second elastic piece 9 is compressed, then the worker takes out the sliding plate 6 to place the transformer on the sliding plate 6, then the sliding plate 6 is put back between the first fixing rods 41, the worker releases the second sliding rod 8, the second elastic piece 9 resets to drive the second sliding rod 8 to slide back in the guide sleeve 7, and the second sliding rod 8 slides back to clamp the sliding plate 6. The device has a simple structure and can place the transformer on the slide plate 6.

The novel sliding rod fixing device is characterized by further comprising a second bearing seat 10, a second rotating shaft 11, wedge blocks 12, a third elastic piece 13, a limiting rod 14, a second fixing rod 15 and a third fixing rod 16, wherein the second bearing seat 10 is arranged at the bottom of each of the two first fixing blocks 31 on the right side, the second rotating shaft 11 is rotatably arranged between the two second bearing seats 10, the wedge blocks 12 are symmetrically arranged on the second rotating shaft 11, the third elastic piece 13 is arranged between one side of each of the two wedge blocks 12 and one side of each of the two second bearing seats 10, the limiting rod 14 is arranged between the tops of the two second bearing seats 10, the second fixing rod 15 is arranged at one end of the second sliding rod 8 on the right side, and the third fixing rod 16 is arranged at the bottom end of the second fixing rod 15.

The second fixing block 36 moves downwards to drive the third fixing rod 16 to contact with the wedge block 12 through the second fixing rod 15, and presses the wedge block 12 downwards, the wedge block 12 rotates downwards on the second rotating shaft 11 to contact with the limiting rod 14, the third elastic piece 13 deforms, when the third fixing rod 16 is not pressing the wedge block 12, the third elastic piece 13 resets with the wedge block 12, the third fixing rod 16 moves leftwards to drive the left second sliding rod 8 to slide leftwards in the guide sleeve 7 through the second fixing rod 15, the left second elastic piece 9 is stretched, the left second sliding rod 8 slides leftwards to drive the sliding plate 6 to slide leftwards on the first fixing rod 41, the sliding plate 6 slides leftwards to drive the right second sliding rod 8 to slide leftwards in the guide sleeve 7, the right second elastic piece 9 is compressed, the second fixing block 36 moves upwards to drive the third fixing rod 16 to move upwards to be out of contact with the wedge block 12 through the second fixing rod 15, the left second elastic piece 9 resets to drive the second sliding rod 8 to slide rightwards in the guide sleeve 7, the right second sliding rod 9 resets to drive the right second sliding rod 8 to slide rightwards in the guide sleeve 7, and the right elastic piece 9 resets to drive the right second sliding rod 8 to slide rightwards in the guide sleeve 8. The device has a simple structure, and can shake the sliding plate 6, so that the tin coating of the transformer is more uniform.

The novel lifting device is characterized by further comprising a third bearing seat 17, third rotating shafts 18, second frame bodies 19, swinging rods 20, fourth fixing rods 21 and ejector rods 22, wherein two third bearing seats 17 are symmetrically arranged on the front side and the rear side of the first frame body 2, the third rotating shafts 18 are all arranged in the four third bearing seats 17 in a rotating mode, the second frame bodies 19 are all arranged between the two third rotating shafts 18 on the same side, the swinging rods 20 are all arranged at one back end of the four third rotating shafts 18, the fourth fixing rods 21 are all arranged on the two first sliding rods 33 on the left side, sliding grooves are all formed in the two first fixing blocks 31 on the same side, the two fourth fixing rods 21 are located in the sliding grooves, and the ejector rods 22 are all arranged at the end parts of the two fourth fixing rods 21.

The first slide bar 33 slides back to back and drives the ejector rod 22 to move back through the fourth fixed rod 21, the ejector rod 22 moves back to press the swinging rod 20, the swinging rod 20 rotates upwards to drive the third rotating shaft 18 to rotate, the third rotating shaft 18 rotates to drive the second frame 19 to rotate upwards, the scraping plate 34 moves back to scrape a film heated by tin in the first frame 2 into the second frame 19, the first slide bar 33 slides back to back and drives the ejector rod 22 to move in opposite directions through the fourth fixed rod 21, the ejector rod 22 moves in opposite directions to not press the swinging rod 20 any more, the swinging rod 20 rotates downwards on the third rotating shaft 18 to reset under the action of gravity of the second frame 19, and the third rotating shaft 18 rotates to drive the swinging rod 20 to rotate downwards. The device has a simple structure, and can scrape the film heated by the tin in the first frame body 2 into the second frame body 19 for collection.

The foregoing examples have shown only the preferred embodiments of the invention, which are described in more detail and are not to be construed as limiting the scope of the invention. It should be noted that modifications, improvements and substitutions can be made by those skilled in the art 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 (2)

1. An auxiliary soldering device for a high-frequency transformer, which is characterized by comprising:

a base plate (1), wherein a first frame body (2) is arranged on the base plate (1);

the cleaning mechanism (3) is arranged on two sides of the first frame body (2);

the cleaning mechanism (3) is provided with the clamping mechanism (4);

a driving mechanism (5), wherein the driving mechanism (5) is arranged at one side of the first frame body (2);

the cleaning mechanism (3) comprises:

the first fixing blocks (31) are symmetrically arranged on two sides of the first frame body (2);

the straight type chute plates (32) are arranged on the four first fixing blocks (31);

the first sliding rods (33) are arranged in the four straight chute plates (32) in a sliding manner;

the scraping plates (34) are arranged between one opposite sides of each two first sliding rods (33);

the connecting rods (35) are rotatably arranged on one side, opposite to the back, of the four first sliding rods (33);

the second fixed block (36) is arranged between the other ends of the two connecting rods (35) which are close to each other;

the chucking mechanism (4) includes:

a first fixed rod (41) is arranged between two sides of the two second fixed blocks (36);

the middle part of the first fixing rod (41) at one side of the first bearing seat (42) is provided with the first bearing seat (42);

the first rotating shaft (43) is rotatably arranged on the first bearing seat (42);

a rotating block (44), wherein the rotating block (44) is arranged on the first rotating shaft (43);

a pressing block (45), wherein the pressing block (45) is arranged on the rotating block (44);

a first elastic piece (46), wherein the first elastic piece (46) is arranged between one side of the first bearing seat (42) and one side of the rotating block (44);

the drive mechanism (5) comprises:

a third fixed block (51), wherein the bottom of the second fixed block (36) at one side is provided with the third fixed block (51);

a bracket (52) is arranged on the first frame body (2) at the same side;

the air cylinder (53) is arranged on the bracket (52), a telescopic rod is arranged in the air cylinder (53) in a sliding manner, and the other end of the telescopic rod is connected with the third fixed block (51);

further comprises:

a sliding plate (6) is arranged between the two first fixing rods (41) in a sliding manner, and round holes are uniformly formed in the sliding plate (6) at intervals;

the guide sleeves (7) are arranged in the middle of the two second fixing blocks (36);

the second slide bar (8) is arranged on the two guide sleeves (7) in a sliding manner, and the second slide bar (8) is arranged on the two guide sleeves (7);

the second elastic piece (9) is arranged between one side of the two guide sleeves (7) and one side of the two second sliding rods (8); further comprises:

the bottoms of the two first fixing blocks (31) at the side far away from the air cylinder (53) are respectively provided with a second bearing (10);

a second rotating shaft (11), wherein the second rotating shaft (11) is rotatably arranged between the two second bearings (10);

the wedge-shaped blocks (12) are symmetrically arranged on the second rotating shaft (11);

a third elastic piece (13) is arranged between one side of the two wedge blocks (12) and one side of the two second bearing seats (10);

a limiting rod (14) is arranged between the tops of the two second bearings (10);

a second fixed rod (15) is arranged at one end of the second sliding rod (8) far away from one side of the air cylinder (53);

the bottom end of the second fixed rod (15) is provided with a third fixed rod (16);

further comprises:

the third bearing seat (17) is symmetrically arranged on the other two sides of the first frame body (2);

the third rotating shafts (18) are rotatably arranged in the four third bearing seats (17);

the second frame body (19) is arranged between the two third rotating shafts (18) on the same side;

the swing rods (20) are arranged at the back ends of the four third rotating shafts (18);

the fourth fixed rod (21) is arranged on the two first sliding rods (33) close to one side of the air cylinder (53), sliding grooves are formed in the two first fixed blocks (31) on the same side, and the two fourth fixed rods (21) are positioned in the sliding grooves;

ejector rods (22) are arranged at the end parts of the two fourth fixing rods (21).

2. The auxiliary soldering device for a high frequency transformer according to claim 1, wherein the third elastic members (13) are torsion springs.