CN116374513A

CN116374513A - Feeding device and method for processing aluminum electrolytic container workpiece

Info

Publication number: CN116374513A
Application number: CN202310353383.XA
Authority: CN
Inventors: 曹迎春; 李建兵; 尹龙
Original assignee: Yiyang Dongzi Electronics Co ltd
Current assignee: Yiyang Dongzi Electronics Co ltd
Priority date: 2023-04-04
Filing date: 2023-04-04
Publication date: 2023-07-04

Abstract

The utility model relates to a feeding device for processing an aluminum electrolytic container workpiece, and belongs to the technical field of electrolytic capacitor processing. The automatic feeding device comprises a workbench and a vibration feeding disc, wherein the top of the workbench is fixedly connected with a first slideway, one end of the first slideway is connected with a feeding port of the vibration feeding disc, the bottom of the workbench is fixedly connected with a motor, an output shaft of the motor extends to the top of the workbench and is fixedly connected with a rotating table, the rotating table penetrates through the first slideway, the rotating table can be driven to rotate and a supporting rod to move by a starting motor, and the stroke of the supporting rod can be increased by a first rack, a second gear and a third rack so as to facilitate pushing an inverted shell in a guiding port into the second slideway, and meanwhile, a sliding plate can be driven to move a clamping shell and drive the shell to rotate 180 degrees, so that the shell can be turned and adjusted, and subsequent processing and use are facilitated.

Description

Feeding device and method for processing aluminum electrolytic container workpiece

Technical Field

The utility model belongs to the technical field of electrolytic capacitor machining, and relates to a feeding device and method for machining an aluminum electrolytic container workpiece.

Background

With the development of society and the continuous progress of technology, in recent years, as the world electronic complete machine industry such as computers is growing at a high speed and the transmission industry such as the pedal industry is also steadily growing, the demands on aluminum electrolytic capacitors in the market are increasing, and in order to meet the demands of enterprise productivity, many large-scale manufacturing enterprises purchase aluminum electrolytic capacitor assembling machines to improve the production efficiency of the aluminum electrolytic capacitors.

After searching, the utility model with the bulletin number of CN214254151U is a material conveying device for an aluminum electrolytic capacitor assembly machine, and the technical scheme is characterized in that: including the conveying mechanism who is used for carrying the aluminum hull to the assemblage machine, conveying mechanism is including connecting the defeated material pole that is used for carrying the aluminum hull to the assemblage machine between vibration dish and assemblage machine, and defeated material pole is provided with the defeated silo that supplies the material to remove and is used for sieving the sieve material hole of aluminum hull, and defeated silo is linked together with vibration dish, assemblage machine respectively, and the sieve material hole is linked together with defeated silo, and defeated material pole includes the bottom plate that links to each other general being used for supporting the aluminum hull with sieve material hole. The aluminum shell screening device has the technical effect of screening out aluminum shells with wrong conveying states.

The device also has the following disadvantages when in use: when the device is used, the sleeping shell can be filtered through the airing hole, but the shell is in a barrel shape, the bottom of the shell is closed, and the opening orientation is inconsistent easily caused during conveying, so that the subsequent processing is not facilitated; the filtered shell needs manual treatment in the recycling box when the filtered shell is too much to be used, so that the feeding device for processing the aluminum electrolytic container workpiece and the simulation method thereof are provided for solving the problems.

Disclosure of Invention

In view of the above, the utility model aims to solve the problem that the shell is closed at the barrel-shaped bottom, and the opening orientation is inconsistent easily during conveying, which is not beneficial to subsequent processing; the filtered shell is in the recovery box, and when the filtered shell is too much contained, the filtered shell needs to be manually treated and is inconvenient to use, and the feeding device and the feeding method for processing the aluminum electrolytic container workpiece are provided.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the utility model provides a loading attachment that aluminium electroloysis container work piece processing was used, includes workstation and vibration feeding tray, the top fixedly connected with first slide of workstation, the one end of first slide is connected with the delivery port of vibration feeding tray, the bottom fixedly connected with motor of workstation, the output shaft of motor extends to the top of workstation and fixedly connected with revolving stage, the revolving stage runs through first slide, the guiding hole for spacing to the shell has been seted up at the top of revolving stage, the top fixedly connected with mounting panel of first slide, the bottom fixedly connected with of mounting panel is used for detecting the positive and negative infrared range finder of shell;

the top of the workbench is fixedly connected with a second slide way, the second slide way is positioned on one side of the first slide way, rectangular openings corresponding to the guide openings are formed in one sides of the first slide way and the second slide way, which are close to each other, openings are formed in one sides of the first slide way and the second slide way, and a blocking plate for guiding the shell is fixedly connected to the inner wall of the opening;

the pushing mechanism is arranged at the top of the workbench and used for pushing the shell in the first sliding rod into the second slideway, so that the manual selection time is saved;

the turnover mechanism is arranged at the top of the workbench and used for turning over the selected shell, so that the follow-up continuous use is facilitated.

Further, pushing mechanism includes the first backup pad of fixed connection at the workstation top, one side sliding connection of first backup pad has first rack, the outer wall fixed cover of motor is equipped with the first gear with first rack looks meshing, the one end fixedly connected with head rod of first rack, the inner wall rotation of head rod is connected with the second gear, the top fixedly connected with of workstation and second gear engaged with second rack, one side sliding connection of first backup pad has the third rack with second gear engaged, the one end of third rack is equipped with the bracing piece that is used for pushing the shell.

Further, tilting mechanism is including rotating the spliced pole in first slide one side, the outside fixed cover of spliced pole is equipped with the fixed plate, the outer wall slip cap of spliced pole is equipped with the sliding plate, the outer wall cover of spliced pole is equipped with the third spring, the both ends of third spring respectively with one side fixed connection that fixed plate and sliding plate are close to each other, the spout has been seted up to the outer wall of spliced pole, the outer wall cover of spliced pole is equipped with the slip ring, the inner wall slip of spout is equipped with the sliding block, sliding block fixed connection is in the slip ring, the outer wall cover of spliced pole is equipped with the fourth spring, the both ends of fourth spring are close to one side fixed connection each other with sliding plate and slip ring respectively.

Further, one end of the third rack penetrates through the third sliding rod in a sliding manner, one end of the third sliding rod is fixedly connected with the connecting plate, the first sliding rod is fixedly connected to the top of the workbench, one side of the first sliding rod penetrates through the supporting rod in a sliding manner, one end of the supporting rod is fixedly connected with the connecting plate, a second spring is sleeved on the outer wall of the third sliding rod, and two ends of the second spring are respectively fixedly connected with the connecting plate and one side, close to each other, of the third rack.

Further, the top fixedly connected with second backup pad of workstation, one side sliding connection of second backup pad has the fourth rack with first gear engaged with, fixedly connected with same second connecting rod between fourth rack and the slip ring.

Further, the inner wall sliding connection of second slide has the conflict board, the one end fixedly connected with second slide bar of conflict board, second slide bar runs through sliding connection with the second slide, the outer wall cover of second slide bar is equipped with first spring, the both ends of first spring are close to one side fixed connection each other with conflict board and second slide respectively.

Further, one side fixedly connected with axis of rotation of second slide, the outer wall of axis of rotation rotates the cover and is equipped with first connecting rod, the one end of first connecting rod runs through fixedly connected with driving lever, the outer wall cover of axis of rotation is equipped with the torsional spring, the both ends of torsional spring are close to one side fixed connection each other with first connecting rod and second slide respectively, one side fixedly connected with of sliding plate and the lug of driving lever cooperation use.

Further, a limiting block which is in contact with the first connecting rod is fixedly connected to one side of the second slide way.

Further, the sliding groove consists of a moving groove and a spiral groove.

The application method of the feeding device for processing the aluminum electrolytic container workpiece comprises the following steps:

s1, firstly pouring a shell into a vibration feeding disc, starting the vibration feeding disc to sequentially convey the shell onto a first slideway, detecting through an infrared range finder when an opening part of the first slideway moves into a guide opening, judging the positive and negative of the shell by detecting the distance of the bottom of the first slideway through the infrared range finder, wherein the detection distance is small, the bottom is upward, the detection distance is large, and the bottom is downward;

s2, when the bottom of the shell is detected to be upward, the motor is started to rotate, the motor can drive the rotating table to rotate, the opening of the guide opening faces the second slideway, the guide opening can abut against the abutting plate to move rightwards when rotating, meanwhile, the motor can drive the first gear to rotate, the first gear drives the first rack to move, the first rack can drive the second gear to rotate on the second rack, the second gear can drive the third rack to move when rotating, the supporting rod is in contact with the outer wall of the rotating table, the second spring is compressed, when the supporting rod is not in contact with the outer wall of the rotating table, the second spring can drive the connecting plate and the supporting rod to move, the shell in the guide opening is driven to abut against the second slideway, and the motor continues to rotate until the shell is completely pushed into the second slideway;

s3, the rotating table and the first rack are driven to reset by the reverse rotation of the starting motor, the first rack can drive the third rack to reset and move by the reset movement of the first rack, the supporting rod can be driven to move from the guide opening, meanwhile, the supporting plate is reset under the acting force of the first spring, the shell is pushed to move, the detection is continued, and the shells in the second slideway are automatically stacked in sequence until the first shell moves between the fixed plate and the sliding plate;

s4, when the shell with the bottom upwards is detected again, the motor is started, the motor drives the rotating table to rotate the supporting rod to move so as to push the shell into the second slideway, meanwhile, the first gear can drive the fourth rack to move, the fourth rack can drive the sliding block to slide in the spiral groove when the sliding ring moves through the second connecting rod, the fourth spring props against the sliding plate to move so as to clamp the shell, the sliding block can slide in the moving groove after continuing to move, and therefore the rotating column can be driven to rotate so as to drive the clamped shell to rotate;

s5, when the convex block abuts against the deflector rod, the deflector rod can be driven to rotate continuously until the deflector rod is leveled with the convex block, the shell rotates for 180 degrees, the clamped shell falls on one side of the deflector rod, the motor is started to rotate reversely, the fourth rack is driven to move outwards, the sliding ring is driven to move, the sliding plate moves outwards under the acting force of the fourth spring and the third spring, meanwhile, the sliding ring moves to drive the rotating column to rotate reversely, conveying is carried out sequentially, when the convex block is far away from the deflector rod, the deflector rod is automatically reset under the acting force of the torsion spring, the shell is driven to move forwards, and the shell abuts against the shell, so that the shell can enter the first slideway through the blocking plate and the opening to continue to be used.

The utility model has the beneficial effects that:

1. according to the feeding device for processing the aluminum electrolytic container workpiece, disclosed by the utility model, the shell can be sequentially conveyed onto the first slide way by starting the vibration feeding disc, when the opening part of the first slide way moves into the guide opening, the shell is detected by the infrared range finder, the front and back of the shell can be judged by detecting the distance of the bottom of the first slide way by the infrared range finder, the detection distance is small, the bottom is upward, the detection distance is large, and the bottom is downward;

2. according to the feeding device for processing the aluminum electrolytic container workpiece, the motor is started to rotate, the motor can drive the rotating table to rotate, so that the opening of the guide opening faces the second slideway, the guide opening can abut against the abutting plate to move rightwards when rotating, meanwhile, the motor can drive the first gear to rotate, the first gear drives the first rack to move, the first rack can drive the second gear to rotate on the second rack, the second gear can drive the third rack to move, the supporting rod is enabled to contact with the outer wall of the rotating table, the second spring is compressed, when the supporting rod is enabled not to contact with the outer wall of the rotating table, the second spring can drive the connecting plate and the supporting rod to move, the shell in the guide opening is driven to abut against the second slideway, and the motor continues to rotate until the shell is completely pushed into the second slideway;

3. according to the feeding device for processing the aluminum electrolytic container workpiece, the rotating table and the first rack can be driven to reset by starting the motor to rotate reversely, the first rack can be driven to reset and move to drive the third rack to reset and move, the supporting rod can be driven to move out of the guide opening, meanwhile, the supporting plate resets under the acting force of the first spring, the shell is pushed to move, the detection is continued, and the shells in the second slideway are automatically stacked in sequence until the first shell moves between the fixed plate and the sliding plate;

4. according to the feeding device for processing the aluminum electrolytic container workpiece, the motor is started to drive the rotating table to rotate the supporting rod to move so as to push the shell into the second slideway, meanwhile, the first gear can drive the fourth rack to move, the fourth rack can drive the sliding block to slide in the spiral groove when the sliding ring moves through the second connecting rod, the sliding block is pushed by the fourth spring to move against the sliding plate to clamp the shell, the sliding block can slide in the moving groove after continuing to move, so that the rotating column can be driven to rotate, and the clamped shell is driven to rotate;

5. according to the feeding device for processing the aluminum electrolytic container workpiece, when the lug abuts against the deflector rod, the deflector rod can be driven to rotate continuously until the deflector rod is leveled with the lug, the shell rotates 180 degrees, the clamped shell falls on one side of the deflector rod, the motor is started to rotate reversely to drive the fourth rack to move outwards to drive the sliding ring to move, the sliding plate moves outwards under the acting force of the fourth spring and the third spring, meanwhile, the sliding ring can drive the rotating column to rotate reversely to sequentially carry out conveying, when the lug is far away from the deflector rod, the deflector rod is automatically reset under the acting force of the torsion spring and drives the shell to move forwards, and the shell abuts against the shell to enable the shell to enter the first slideway through the blocking plate and the opening to continue to use.

According to the utility model, the rotating table can be driven to rotate and the supporting rod can be driven to move by the starting motor, the stroke of the supporting rod can be increased by the first rack, the second gear and the third rack, so that the inverted shell in the guide opening can be conveniently pushed into the second slideway, meanwhile, the sliding plate can be driven to move to clamp the shell and drive the shell to rotate 180 degrees, the shell can be turned over and adjusted, and the subsequent processing and use are facilitated.

Additional advantages, objects, and features of the utility model will be set forth in part in the description which follows and in part will become apparent to those having ordinary skill in the art upon examination of the following or may be learned from practice of the utility model. The objects and other advantages of the utility model may be realized and obtained by means of the instrumentalities and combinations particularly pointed out in the specification.

Drawings

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, the present utility model will be described in the following preferred detail with reference to the accompanying drawings, in which:

FIG. 1 is a schematic three-dimensional structure of a feeding device for processing an aluminum electrolytic container workpiece;

FIG. 2 is a schematic view of a three-dimensional structure of another view of a feeding device for processing an aluminum electrolytic container workpiece according to the present utility model;

FIG. 3 is a schematic top view of a feeding device for processing aluminum electrolytic container workpieces;

FIG. 4 is a schematic diagram of a pushing mechanism of a feeding device for processing aluminum electrolytic container workpieces;

FIG. 5 is a schematic diagram of the turnover mechanism of the feeding device for processing the aluminum electrolytic container workpiece;

FIG. 6 is a schematic diagram of a rotary column of a feeding device for processing aluminum electrolytic container workpieces;

FIG. 7 is a schematic diagram of a chute structure of a feeding device for processing an aluminum electrolytic container workpiece according to the present utility model;

FIG. 8 is a schematic drawing of a deflector rod structure of a loading device for processing aluminum electrolytic container workpieces.

Reference numerals: 1. a work table; 2. vibrating the feeding tray; 3. a first slideway; 4. a second slideway; 5. a mounting plate; 6. a rotating table; 7. a support rod; 8. a first slide bar; 9. a connecting plate; 10. a contact plate; 11. a second slide bar; 12. a first spring; 14. a first link; 15. an opening; 16. a closure plate; 17. an infrared range finder; 18. a guide opening; 19. a motor; 20. a first gear; 21. a first support plate; 22. a first rack; 23. a second rack; 24. a first connecting rod; 25. a second gear; 26. a third rack; 27. a third slide bar; 28. a second spring; 29. a second support plate; 30. a fourth rack; 31. a second connecting rod; 32. a slip ring; 33. rotating the column; 34. a fixing plate; 35. a third spring; 36. a sliding plate; 37. a bump; 38. a fourth spring; 39. a sliding block; 40. a chute; 41. a moving groove; 42. a spiral groove; 43. a rotating shaft; 44. a torsion spring; 45. a limiting block; 46. a deflector rod.

Detailed Description

Other advantages and effects of the present utility model will become apparent to those skilled in the art from the following disclosure, which describes the embodiments of the present utility model with reference to specific examples. The utility model may be practiced or carried out in other embodiments that depart from the specific details, and the details of the present description may be modified or varied from the spirit and scope of the present utility model. It should be noted that the illustrations provided in the following embodiments merely illustrate the basic idea of the present utility model by way of illustration, and the following embodiments and features in the embodiments may be combined with each other without conflict.

Wherein the drawings are for illustrative purposes only and are shown in schematic, non-physical, and not intended to limit the utility model; for the purpose of better illustrating embodiments of the utility model, certain elements of the drawings may be omitted, enlarged or reduced and do not represent the size of the actual product; it will be appreciated by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

The same or similar reference numbers in the drawings of embodiments of the utility model correspond to the same or similar components; in the description of the present utility model, it should be understood that, if there are terms such as "upper", "lower", "left", "right", "front", "rear", etc., that indicate an azimuth or a positional relationship based on the azimuth or the positional relationship shown in the drawings, it is only for convenience of describing the present utility model and simplifying the description, but not for indicating or suggesting that the referred device or element must have a specific azimuth, be constructed and operated in a specific azimuth, so that the terms describing the positional relationship in the drawings are merely for exemplary illustration and should not be construed as limiting the present utility model, and that the specific meaning of the above terms may be understood by those of ordinary skill in the art according to the specific circumstances.

Example 1

As shown in fig. 1-4, a feeding device for processing an aluminum electrolytic container workpiece comprises a workbench 1 and a vibration feeding disc 2, wherein the top of the workbench 1 is fixedly connected with a first slideway 3, one end of the first slideway 3 is connected with a material conveying port of the vibration feeding disc 2, the bottom of the workbench 1 is fixedly connected with a motor 19, an output shaft of the motor 19 extends to the top of the workbench 1 and is fixedly connected with a rotating table 6, the rotating table 6 penetrates through the first slideway 3, a guide port 18 for limiting a shell is formed in the top of the rotating table 6, the top of the first slideway 3 is fixedly connected with a mounting plate 5, and the bottom of the mounting plate 5 is fixedly connected with an infrared range finder 17 for detecting the positive and negative directions of the shell;

the top of the workbench 1 is fixedly connected with a second slide way 4, the second slide way 4 is positioned on one side of the first slide way 3, rectangular openings corresponding to the guide openings 18 are formed in the sides, close to each other, of the first slide way 3 and the second slide way 4, openings 15 are formed in the sides, close to each other, of the first slide way 3 and the second slide way 4, and a blocking plate 16 used for guiding the outer shell is fixedly connected to the inner wall of the opening 15;

the pushing mechanism is arranged at the top of the workbench 1 and used for pushing the shell in the first sliding rod 8 into the second slideway 4, so that the manual selection time is saved;

the turnover mechanism is arranged at the top of the workbench 1 and used for turnover of the selected shell, so that the shell can be used continuously and conveniently; the distance is long, then shell bottom is down, and the starter motor 19 drives when the bottom up and rotates platform 6 and rotates the opening 15 of guiding hole 18 and second slide 4 corresponding, drives pushing mechanism and carries out the propelling movement, and the bottom of shell is down when can driving tilting mechanism upset shell simultaneously, and the follow-up continuous processing of being convenient for uses, and vibration feeding tray 2 is the same with the use in the patent literature is CN 214254151U.

Referring to fig. 4, the pushing mechanism includes a first support plate 21 fixedly connected to the top of the workbench 1, a first rack 22 is slidably connected to one side of the first support plate 21, a first gear 20 meshed with the first rack 22 is fixedly sleeved on the outer wall of the motor 19, a first connecting rod 24 is fixedly connected to one end of the first rack 22, a second gear 25 is rotatably connected to the inner wall of the first connecting rod 24, a second rack 23 meshed with the second gear 25 is fixedly connected to the top of the workbench 1, a third rack 26 meshed with the second gear 25 is slidably connected to one side of the first support plate 21, a supporting rod 7 for pushing the shell is arranged at one end of the third rack 26, and in the above technical scheme, the first rack 20 is driven to rotate by the starting motor 19, the second rack 25 is driven to rotate on the second rack 23, so that a third rack 26 is driven to move, and the moving stroke of the supporting rod 7 can be increased by the second rack 23, the second rack 25 and the third rack 26.

Referring to fig. 5-7, the turnover mechanism includes a rotating column 33 rotatably connected to one side of the first slideway 3, a fixed plate 34 is fixedly sleeved outside the rotating column 33, a sliding plate 36 is sleeved on the outer wall of the rotating column 33, a third spring 35 is sleeved on the outer wall of the rotating column 33, two ends of the third spring 35 are fixedly connected to one side, close to each other, of the fixed plate 34 and the sliding plate 36 respectively, a sliding groove 40 is formed in the outer wall of the rotating column 33, a sliding ring 32 is sleeved on the outer wall of the rotating column 33, a sliding block 39 is slidably arranged on the inner wall of the sliding groove 40, the sliding block 39 is fixedly connected in the sliding ring 32, a fourth spring 38 is sleeved on the outer wall of the rotating column 33, two ends of the fourth spring 38 are fixedly connected to one side, close to each other, of the sliding plate 36 and the sliding ring 32 can be driven by the fourth spring 38 to move inwards to clamp the shell, and the sliding ring 32 can be driven to rotate by the sliding block 39 and the sliding groove 40, so that the shell can be driven to rotate 180 ° to change positions, and the bottom of the shell can be downward.

Example two

Referring to fig. 1-4, the utility model provides a new technical scheme, a feeding device for processing aluminum electrolytic container workpieces, which comprises a workbench 1 and a vibration feeding disc 2, wherein the top of the workbench 1 is fixedly connected with a first slideway 3, one end of the first slideway 3 is connected with a material conveying port of the vibration feeding disc 2, the bottom of the workbench 1 is fixedly connected with a motor 19, an output shaft of the motor 19 extends to the top of the workbench 1 and is fixedly connected with a rotating table 6, the rotating table 6 penetrates through the first slideway 3, the top of the rotating table 6 is provided with a guide port 18 for limiting a shell, the top of the first slideway 3 is fixedly connected with a mounting plate 5, and the bottom of the mounting plate 5 is fixedly connected with an infrared range finder 17 for detecting the positive and negative directions of the shell;

Referring to fig. 4, one end of the third rack 26 is connected with a third sliding rod 27 in a penetrating and sliding manner, one end of the third sliding rod 27 is fixedly connected with a connecting plate 9, the top of the workbench 1 is fixedly connected with a first sliding rod 8, one side of the first sliding rod 8 is connected with a supporting rod 7 in a penetrating and sliding manner, one end of the supporting rod 7 is fixedly connected with the connecting plate 9, the outer wall of the third sliding rod 27 is sleeved with a second spring 28, two ends of the second spring 28 are respectively connected with the connecting plate 9 and one side, close to each other, of the third rack 26, and the supporting rod 7 can stretch and retract through setting of the second spring 28 to prevent the supporting rod 7 and the guide opening 18 from being blocked mutually.

Referring to fig. 5, the top of the workbench 1 is fixedly connected with a second support plate 29, one side of the second support plate 29 is slidably connected with a fourth rack 30 meshed with the first gear 20, the fourth rack 30 is fixedly connected with the same second connecting rod 31 with the sliding ring 32, and in the above technical scheme, the sliding ring 32 can be driven to move simultaneously when the motor 19 is started through setting of the fourth rack 30 and the second connecting rod 31, so that the power source is saved.

Referring to fig. 3, an inner wall of the second slideway 4 is slidably connected with an abutting plate 10, one end of the abutting plate 10 is fixedly connected with a second sliding rod 11, the second sliding rod 11 is in penetrating sliding connection with the second slideway 4, a first spring 12 is sleeved on the outer wall of the second sliding rod 11, two ends of the first spring 12 are respectively fixedly connected with one side, close to each other, of the abutting plate 10 and the second slideway 4, in the technical scheme, the rotating table 6 rotates to drive the abutting plate 10 to move through a guide opening 18, and when the guide opening 18 is far away from the abutting plate 10, the abutting plate 10 can move under the acting force of the first spring 12 to drive a shell to push the sliding plate 36.

Referring to fig. 5 and 8, a rotating shaft 43 is fixedly connected to one side of the second slide 4, a first connecting rod 14 is sleeved on the outer wall of the rotating shaft 43 in a rotating manner, one end of the first connecting rod 14 is fixedly connected with a deflector rod 46 in a penetrating manner, a torsion spring 44 is sleeved on the outer wall of the rotating shaft 43, two ends of the torsion spring 44 are respectively and fixedly connected with one side, close to the first connecting rod 14 and the second slide 4, of the second slide 4, a protruding block 37 matched with the deflector rod 46 is fixedly connected to one side of the sliding plate 36, the deflector rod 46 can be driven to rotate through the protruding block 37 when the sliding plate 36 rotates, the deflector rod 46 is located below the sliding plate 36 when the sliding plate is turned over, and the deflector rod 46 is reset under the acting force of the torsion spring 44 to drive the turned shell to move so as to push the shell to move from the second slide 4 to the first slide 3.

Referring to fig. 8, a limiting block 45 that is in contact with the first link 14 is fixedly connected to one side of the second slide 4, and in the above technical solution, the limiting of the first link 14 can be facilitated by setting the limiting block 45, so as to prevent the rotation angle of the first link 14 from being too large.

Referring to fig. 7, the sliding chute 40 is composed of a moving chute 41 and a spiral chute 42, in the above technical solution, the sliding block 39 slides in the spiral chute 42 to drive the sliding plate 36 to move to clamp the shell, and the sliding block 39 can drive the rotating column 33 to rotate 180 ° when sliding in the moving chute 41, so that it is convenient to drive the sliding plate 36 to clamp the shell and drive the shell to rotate.

s1, firstly pouring a shell into a vibration feeding disc 2, starting the vibration feeding disc 2 to sequentially convey the shell onto a first slideway 3, detecting through an infrared distance meter 17 when an opening 15 part of the first slideway 3 moves into a guide opening 18, judging the front and back of the shell by detecting the distance of the bottom of the first slideway 3 through the infrared distance meter 17, wherein the detection distance is small, the bottom is upward, the detection distance is large, and the bottom is downward;

s2, when the bottom of the shell is detected to be upward, the motor 19 is started to rotate, the motor 19 can drive the rotating table 6 to rotate, the opening 15 of the guide opening 18 faces the second slideway 4, the guide opening 18 can abut against the abutting plate 10 to move rightward when rotating, meanwhile, the motor 19 can drive the first gear 20 to rotate, the first gear 20 drives the first rack 22 to move, the first rack 22 can drive the second gear 25 to rotate on the second rack 23, the second gear 25 can drive the third rack 26 to move, the supporting rod 7 contacts the outer wall of the rotating table 6 and compresses the second spring 28, when the supporting rod 7 does not contact the outer wall of the rotating table 6, the second spring 28 can drive the connecting plate 9 and the supporting rod 7 to move, the shell in the guide opening 18 is driven to abut against the second slideway 4, and the motor 19 continues to rotate until the shell is completely pushed into the second slideway 4;

s3, the starting motor 19 is reversed to drive the rotating table 6 and the first rack 22 to reset, the first rack 22 can drive the third rack 26 to reset and move, the supporting rod 7 can be driven to move out of the guide opening 18, meanwhile, the supporting plate 10 resets under the acting force of the first spring 12, the shell is pushed to move towards 13 to continue to detect, and the shells in the second slideway 4 are automatically stacked in sequence until the first shell moves between the fixed plate 34 and the sliding plate 36;

s4, when the shell with the bottom upwards is detected again, the motor 19 is started, the motor 19 drives the rotating table 6 to rotate the supporting rod 7 to move so as to push the shell into the second slideway 4, meanwhile, the first gear 20 can drive the fourth rack 30 to move, the fourth rack 30 can drive the sliding ring 32 to move through the second connecting rod 31, the sliding block 39 slides in the spiral groove 42, the fourth spring 38 props against the sliding plate 36 to clamp the shell, the sliding block 39 can slide in the moving groove 41 after continuous movement, so that the rotating column 33 can be driven to rotate, and the clamped shell is driven to rotate;

s5, when the protruding block 37 abuts against the deflector rod 46, the deflector rod 46 can be driven to rotate continuously until the deflector rod 46 is leveled with the protruding block 37, the shell rotates 180 degrees, the clamped shell falls on one side of the deflector rod 46, the starting motor 19 is turned back to drive the fourth rack 30 to move outwards, the sliding ring 32 is driven to move, the sliding plate 36 moves outwards under the acting force of the fourth spring 38 and the third spring 35, meanwhile, the sliding ring 32 moves to drive the rotating column 33 to rotate reversely to sequentially carry out conveying, when the protruding block 37 is far away from the deflector rod 46, the deflector rod 46 is automatically reset under the acting force of the torsion spring 44 and drives the shell to move forwards, and the shell abuts against the shell, so that the shell can enter the first slideway 3 through the blocking plate 16 and the opening 15 to continue to be used.

However, as well known to those skilled in the art, the working principles and wiring methods of the vibration feeding tray 2 and the motor 19 are common, which are all conventional means or common general knowledge, and are not described herein in detail, and any choice can be made by those skilled in the art according to their needs or convenience.

Finally, it is noted that the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the present utility model, which is intended to be covered by the claims of the present utility model.

Claims

1. The utility model provides a loading attachment that aluminium electrolysis container work piece processing was used, includes workstation (1) and vibration feeding tray (2), its characterized in that, the top fixedly connected with first slide (3) of workstation (1), the one end of first slide (3) is connected with the delivery port of vibration feeding tray (2), the bottom fixedly connected with motor (19) of workstation (1), the output shaft of motor (19) extends to the top of workstation (1) and fixedly connected with rotating table (6), rotating table (6) run through first slide (3), guiding hole (18) for spacing to the shell have been seted up at the top of rotating table (6), the top fixedly connected with mounting panel (5) of first slide (3), the bottom fixedly connected with of mounting panel (5) is used for detecting infrared range finder (17) of shell positive and negative.

The top of the workbench (1) is fixedly connected with a second slide way (4), the second slide way (4) is positioned on one side of the first slide way (3), rectangular openings corresponding to the guide openings (18) are formed in one sides, close to each other, of the first slide way (3) and the second slide way (4), openings (15) are formed in one sides, close to each other, of the first slide way (3) and the second slide way (4), and a blocking plate (16) used for guiding the shell is fixedly connected to the inner wall of the opening (15);

the pushing mechanism is arranged at the top of the workbench (1) and used for pushing the shell in the first sliding rod (8) into the second slideway (4), so that the manual selection time is saved;

the turnover mechanism is arranged at the top of the workbench (1) and used for turning over the selected shell, so that the follow-up continuous use is facilitated.

2. The feeding device for processing the aluminum electrolysis container workpiece according to claim 1, wherein the pushing mechanism comprises a first supporting plate (21) fixedly connected to the top of the workbench (1), one side of the first supporting plate (21) is slidably connected with a first rack (22), the outer wall of the motor (19) is fixedly sleeved with a first gear (20) meshed with the first rack (22), one end of the first rack (22) is fixedly connected with a first connecting rod (24), the inner wall of the first connecting rod (24) is rotatably connected with a second gear (25), the top of the workbench (1) is fixedly connected with a second rack (23) meshed with the second gear (25), one side of the first supporting plate (21) is slidably connected with a third rack (26) meshed with the second gear (25), and one end of the third rack (26) is provided with a supporting rod (7) for pushing the shell.

3. The feeding device for processing the aluminum electrolytic container workpiece according to claim 2, wherein the turnover mechanism comprises a rotating column (33) rotatably connected to one side of the first slideway (3), a fixed plate (34) is fixedly sleeved on the outer side of the rotating column (33), a sliding plate (36) is sleeved on the outer wall of the rotating column (33), a third spring (35) is sleeved on the outer wall of the rotating column (33), two ends of the third spring (35) are fixedly connected with one side, close to the sliding plate (36), of the fixed plate (34) respectively, a sliding groove (40) is formed in the outer wall of the rotating column (33), a sliding ring (32) is sleeved on the outer wall of the rotating column (33), a sliding block (39) is slidably arranged on the inner wall of the sliding groove (40), a fourth spring (38) is fixedly connected in the sliding ring (32), and two ends of the fourth spring (38) are fixedly connected with the sliding plate (36) and one side, close to each other, of the sliding ring (32) respectively.

4. The feeding device for processing the aluminum electrolysis container workpiece according to claim 2, wherein one end of the third rack (26) is penetrated and slidably connected with a third sliding rod (27), one end of the third sliding rod (27) is fixedly connected with a connecting plate (9), the top of the workbench (1) is fixedly connected with a first sliding rod (8), one side of the first sliding rod (8) is penetrated and slidably connected with a supporting rod (7), one end of the supporting rod (7) is fixedly connected with the connecting plate (9), the outer wall of the third sliding rod (27) is sleeved with a second spring (28), and two ends of the second spring (28) are respectively fixedly connected with one side, close to each other, of the connecting plate (9) and the third rack (26).

5. A feeding device for processing an aluminum electrolysis container workpiece according to claim 3, wherein a second supporting plate (29) is fixedly connected to the top of the workbench (1), a fourth rack (30) meshed with the first gear (20) is slidably connected to one side of the second supporting plate (29), and the same second connecting rod (31) is fixedly connected between the fourth rack (30) and the sliding ring (32).

6. The feeding device for processing the aluminum electrolysis container workpiece according to claim 5, wherein an abutting plate (10) is slidably connected to the inner wall of the second slideway (4), one end of the abutting plate (10) is fixedly connected with a second sliding rod (11), the second sliding rod (11) is in penetrating sliding connection with the second slideway (4), a first spring (12) is sleeved on the outer wall of the second sliding rod (11), and two ends of the first spring (12) are fixedly connected with one side, close to the abutting plate (10) and the second slideway (4), of each other.

7. The feeding device for processing the aluminum electrolytic container workpiece according to claim 6, wherein one side of the second slideway (4) is fixedly connected with a rotating shaft (43), the outer wall of the rotating shaft (43) is rotatably sleeved with a first connecting rod (14), one end of the first connecting rod (14) penetrates through a fixed connection with a deflector rod (46), the outer wall of the rotating shaft (43) is sleeved with a torsion spring (44), two ends of the torsion spring (44) are respectively fixedly connected with one side, close to the first connecting rod (14) and the second slideway (4), of the second slideway, and one side of the sliding plate (36) is fixedly connected with a lug (37) matched with the deflector rod (46).

8. The feeding device for processing the aluminum electrolytic container workpiece according to claim 7, wherein a limiting block (45) which is in contact with the first connecting rod (14) is fixedly connected to one side of the second slideway (4).

9. A feeding device for processing an aluminum electrolytic container workpiece according to claim 3, wherein the chute (40) is composed of a moving groove (41) and a spiral groove (42).

10. The method of using a loading device for processing workpieces of aluminum electrolysis containers according to any one of claims 1 to 9, comprising the steps of:

s1, firstly pouring a shell into a vibration feeding disc (2), starting the vibration feeding disc (2) to sequentially convey the shell onto a first slide way (3), detecting through an infrared distance meter (17) when an opening (15) of the first slide way (3) moves into a guide opening (18), judging the front and back of the shell through detecting the distance of the bottom of the first slide way (3) by the infrared distance meter (17), wherein the detection distance is small, the bottom is upward, the detection distance is large, and the bottom is downward;

s2, when the bottom of the shell is detected to be upward, the motor (19) is started to rotate, the motor (19) can drive the rotating table (6) to rotate, the opening (15) of the guide opening (18) faces the second slideway (4), the guide opening (18) can abut against the abutting plate (10) to move rightwards when rotating, meanwhile, the motor (19) can drive the first gear (20) to rotate, the first gear (20) can drive the first rack (22) to move, the first gear (22) can drive the second gear (25) to rotate on the second rack (23), the second gear (25) can drive the third rack (26) to move, the supporting rod (7) is enabled to contact the outer wall of the rotating table (6) and compress the second spring (28), when the supporting rod (7) is enabled not to contact the outer wall of the rotating table (6), the second spring (28) can drive the connecting plate (9) and the supporting rod (7) to move, the shell in the guide opening (18) is enabled to abut against the second slideway (4), and the motor (19) continues to rotate until the shell is completely pushed into the second slideway (4);

s3, a starting motor (19) is reversed to drive the rotating table (6) and the first rack (22) to reset, the first rack (22) is reset to drive the third rack (26) to reset, the supporting rod (7) can be driven to move out of the guide opening (18), meanwhile, the supporting plate (10) is reset under the acting force of the first spring (12), the shell is pushed to move towards the shell (13) to continue to detect, and the shells in the second slideway (4) are automatically stacked in sequence until the first shell moves between the fixed plate (34) and the sliding plate (36);

s4, when the shell with the bottom upwards is detected again, a motor (19) is started, the motor (19) drives a rotating table (6) to rotate a supporting rod (7) to move so as to push the shell into a second slideway (4), meanwhile, a first gear (20) can drive a fourth rack (30) to move, the fourth rack (30) can drive a sliding ring (32) to move through a second connecting rod (31), a sliding block (39) slides in a spiral groove (42), and the sliding plate (36) is abutted to move through a fourth spring (38) so as to clamp the shell, the sliding block (39) can slide in a moving groove (41) continuously, so that a rotating column (33) can be driven to rotate, and the clamped shell is driven to rotate;

s5, when the protruding block (37) is abutted against the deflector rod (46), the deflector rod (46) can be driven to rotate continuously until the deflector rod (46) is leveled with the protruding block (37), the shell rotates 180 degrees, the clamped shell falls on one side of the deflector rod (46), the motor (19) is started to rotate reversely, the fourth rack (30) is driven to move outwards, the sliding ring (32) is driven to move, the sliding plate (36) is driven to move outwards under the acting force of the fourth spring (38) and the third spring (35), meanwhile, the sliding ring (32) can drive the rotating column (33) to rotate reversely and sequentially convey, when the protruding block (37) is far away from the deflector rod (46), the deflector rod (46) is automatically reset under the acting force of the torsion spring (44), the shell is driven to move forwards, and the shell is abutted against the shell, so that the shell can enter the first slideway (3) to continue to be used continuously through the blocking plate (16) and the opening (15).