CN220265920U

CN220265920U - Electroplating processing suspension device

Info

Publication number: CN220265920U
Application number: CN202321756403.XU
Authority: CN
Inventors: 陈芹华; 周增有; 徐孟武
Original assignee: Wenzhou Grete Electroplating Co ltd
Current assignee: Wenzhou Grete Electroplating Co ltd
Priority date: 2023-07-06
Filing date: 2023-07-06
Publication date: 2023-12-29
Anticipated expiration: 2033-07-06

Abstract

The utility model discloses an electroplating suspension device, which relates to the technical field of electroplating processing and comprises a bottom plate, a rotating structure and a fixing structure, wherein an input conveyor belt is arranged on one side of the top end of the bottom plate, an electroplating pool is arranged at the front end of the top end of the bottom plate, an input conveyor belt is arranged on one side of the top end of the bottom plate far away from the input conveyor belt, a back plate is arranged at the rear end of the top end of the bottom plate, a top plate is arranged at the top end of the back plate, an annular chute is arranged at the bottom end of the top plate, a plurality of sliding blocks are arranged in the annular chute, and a rotating plate is arranged at the bottom end of each sliding block. According to the utility model, the driven rotating rod is driven to rotate through the driven gear, so that the driven rotating rod drives the rotating plate to rotate, the rotating plate drives the sliding block to make the sliding block do circular motion in the annular sliding groove, and the workpiece can be driven to rotate through the rotating plate.

Description

Electroplating processing suspension device

Technical Field

The utility model relates to the technical field of electroplating processing, in particular to an electroplating processing suspension device.

Background

Electroplating is a process of plating a thin layer of other metals or alloys on the surface of some metals by utilizing the electrolysis principle, and is a process of adhering a metal film on the surface of a metal or other material workpiece by utilizing the electrolysis effect, so that the effects of preventing the metal from oxidizing, improving the wear resistance, conductivity, reflectivity, corrosion resistance, improving the attractiveness and the like are achieved, and the electroplating processing hanging device is a device for fixing and conveying a workpiece to be electroplated.

Through the search, chinese patent grant publication No. CN212610972U, publication day 2021, 2 and 26, discloses a hanging workpiece conveying device for electroplating processing, and it is proposed that "the workpiece is manually fixed by a workpiece clamping device, the conveying motor operates to drive the workpiece to be conveyed to an electroplating processing area" and the workpiece is required to be manually clamped and fixed, automatic cycle processing electroplating cannot be performed, and the working efficiency is low.

Disclosure of Invention

The utility model aims to provide an electroplating processing suspension device, which solves the problems that automatic cycle processing electroplating cannot be performed and the working efficiency is low in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the electroplating processing suspension device comprises a bottom plate, a rotating structure and a fixing structure;

an input conveyor belt is arranged on one side of the top end of the bottom plate, an electroplating pool is arranged at the front end of the top end of the bottom plate, the input conveyor belt is arranged on one side of the top end of the bottom plate far away from the input conveyor belt, a back plate is arranged at the rear end of the top end of the bottom plate, a top plate is arranged at the top end of the back plate, an annular sliding groove is arranged at the bottom end of the top plate, a plurality of sliding blocks are arranged in the annular sliding groove, a rotating plate is arranged at the bottom end of the sliding block, pneumatic telescopic rods are arranged at the two sides of the bottom end of the rotating plate and at the front end and the rear end of the rotating plate, and a fixing structure is arranged at the bottom end of each pneumatic telescopic rod;

the rotating structure is positioned at the top end of the top plate;

the rotary structure comprises a mounting groove, the mounting groove is mounted at the middle position of the top end of the top plate, a first servo motor is mounted at the top end of the top plate on one side of the mounting groove, a driving rod is mounted at the output end of the first servo motor, a driving gear is mounted at one end of the driving rod, a driven rotating rod is mounted at the top end of the inner portion of the mounting groove through a rotating shaft, and a driven gear is mounted on the outer wall of the driven rotating rod.

Preferably, one end of the driving rod passes through the mounting groove, and one end of the driving rod extends to the inside of the mounting groove.

Preferably, the bottom of the driven rotating rod sequentially penetrates through the mounting groove and the top plate to extend to the top end of the rotating plate, and the driven rotating rod is mounted on the top end of the rotating plate.

Preferably, the driven gear is located below the driving gear, and the driven gear is meshed with the driving gear.

Preferably, the fixed knot constructs including splint, rotation groove, two-way threaded rod, screw thread piece and miniature servo motor, the rotation groove is all installed in pneumatic telescopic link's bottom, and the miniature servo motor is all installed to one side of rotation groove, two-way threaded rod is all installed to miniature servo motor's output, and two-way threaded rod's outer wall all has two screw thread pieces through threaded connection, splint are all installed to screw thread piece's bottom.

Preferably, one end of the bidirectional threaded rod penetrates through the rotating groove to extend to one side of the inner portion of the rotating groove, and the bidirectional threaded rod is mounted on one side of the inner portion of the rotating groove through the rotating shaft.

Preferably, the bottom ends of the clamping plates all penetrate through the rotating grooves, and the bottom ends of the clamping plates all extend to the lower parts of the rotating grooves.

Compared with the prior art, the utility model has the beneficial effects that: can drive driven gear through driving gear and rotate, it is rotatory to drive driven bull stick through driven gear, make driven bull stick drive the revolving board rotatory, make the revolving board drive the slider, make the slider be circular motion in the inside of annular spout, then can drive the work piece through the revolving board and rotate, make it remove to electroplating directly over the pond, make pneumatic telescopic link extension, and make miniature servo motor drive two-way threaded rod counter-rotating, place the inside of electroplating the pond with the work piece and electroplate, after electroplating, get the work piece clamp through the extension of pneumatic telescopic link and splint again, the revolving board rotates once more, make the work piece remove to the top of output conveyer belt, carry it to next step process through the output conveyer belt, through the rotation of revolving board and under a plurality of pneumatic telescopic links and fixed knot constructs, make the process form the circulation, this structure has realized the automatic cycle to electroplating each process, the efficiency of work has been improved.

Drawings

FIG. 1 is a schematic view of a front cross-sectional structure of the present utility model;

FIG. 2 is a schematic side view of the present utility model;

FIG. 3 is a schematic top cross-sectional view of the annular chute of the present utility model;

FIG. 4 is an enlarged schematic view of the structure of FIG. 1A according to the present utility model;

fig. 5 is an enlarged schematic view of the structure of fig. 1B according to the present utility model.

In the figure: 1. a lifting mechanism; 101. a guide rod; 102. a screw rod; 103. a crank; 104. a moving plate; 2. a housing; 3. a control panel; 4. an anti-slip pad; 5. a weighing mechanism; 501. a chute; 502. a pressure sensor; 503. a sliding plate; 504. a buffer spring; 505. a magnetic base; 6. a gear; 7. a first limit groove; 8. a rack; 9. a first slider; 10. a first transmission rod; 11. clamping blocks; 12. a main rod; 13. a rotating rod; 14. a second slider; 15. the second limit groove; 16. a third slider; 17. a second transmission rod; 18. a third limit groove; 19. and a motor.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1: referring to fig. 1 to 5, an input conveyor belt 12 is installed on one side of the top end of a bottom plate 1, an electroplating pool 2 is installed at the front end of the top end of the bottom plate 1, the input conveyor belt 12 is installed on one side of the top end of the bottom plate 1 far away from the input conveyor belt 12, a back plate 4 is installed at the rear end of the top end of the bottom plate 1, a top plate 11 is installed at the top end of the back plate 4, an annular chute 6 is installed at the bottom end of the top plate 11, a plurality of sliding blocks 10 are arranged in the annular chute 6, a rotating plate 7 is installed at the bottom end of the sliding blocks 10, pneumatic telescopic rods 5 are installed at two sides, front and rear ends of the bottom end of the rotating plate 7, and fixing structures 9 are located at the bottom ends of the pneumatic telescopic rods 5;

the rotating structure is positioned at the top end of the top plate 11;

referring to fig. 1-5, an electroplating suspension device further includes a rotating structure, the rotating structure includes a mounting groove 13, the mounting groove 13 is mounted at a top middle position of the top plate 11, a first servo motor 8 is mounted at a top end of the top plate 11 at one side of the mounting groove 13, a driving rod 17 is mounted at an output end of the first servo motor 8, a driving gear 16 is mounted at one end of the driving rod 17, a driven rotating rod 14 is mounted at a top end inside the mounting groove 13 through a rotating shaft, and a driven gear 15 is mounted at an outer wall of the driven rotating rod 14;

one end of the driving rod 17 passes through the mounting groove 13, and one end of the driving rod 17 extends to the inside of the mounting groove 13;

the bottom end of the driven rotating rod 14 sequentially passes through the mounting groove 13 and the top plate 11 to extend to the top end of the rotating plate 7, and the driven rotating rod 14 is mounted on the top end of the rotating plate 7;

the driven gear 15 is positioned below the driving gear 16, and the driven gear 15 is meshed with the driving gear 16;

specifically, as shown in fig. 1, 2, 3 and 4, when the mechanism is used, the driving rod 17 is driven to rotate by the first servo motor 8, the driving gear 16 is driven to rotate by the driving rod 17, the driven gear 15 can be driven to rotate by the driving gear 16 due to the mutual engagement of the driving gear 16 and the driven gear 15, the driven rotating rod 14 is driven to rotate by the driven gear 15, the driven rotating rod 14 drives the rotating plate 7 to rotate, the rotating plate 7 drives the sliding block 10, the sliding block 10 performs circular motion in the annular sliding groove 6, and the workpiece can be driven to rotate by the rotating plate 7.

Example 2: the fixed structure 9 comprises a clamping plate 901, a rotating groove 902, a bidirectional threaded rod 903, threaded blocks 904 and a miniature servo motor 905, wherein the rotating groove 902 is arranged at the bottom end of the pneumatic telescopic rod 5, the miniature servo motor 905 is arranged at one side of the rotating groove 902, the bidirectional threaded rod 903 is arranged at the output end of the miniature servo motor 905, the outer wall of the bidirectional threaded rod 903 is connected with two threaded blocks 904 through threads, and the clamping plate 901 is arranged at the bottom end of each threaded block 904;

one end of the bidirectional threaded rod 903 extends to one side inside the rotary groove 902 through the rotary groove 902, and the bidirectional threaded rod 903 is mounted on one side inside the rotary groove 902 through a rotating shaft;

the bottom ends of the clamping plates 901 all penetrate through the rotating grooves 902, and the bottom ends of the clamping plates 901 all extend to the lower parts of the rotating grooves 902;

specifically, as shown in fig. 1, 2 and 5, when the mechanism is used, the rotation direction of the bidirectional threaded rod 903 is adjusted by the micro-servo motor 905, so that the threaded blocks 904 move in the directions approaching each other, the clamping plates 901 are driven by the threaded blocks 904, the clamping plates 901 approach each other, and the workpiece can be clamped by the clamping plates 901.

Working principle: the work piece that the staff needs to electroplate is carried through the input conveyer belt 12, and move to the below of pneumatic telescopic link 5, at this moment, pneumatic telescopic link 5 above the input conveyer belt 12 will lengthen, and miniature servo motor 905 starts, drive the rotation of the two-way threaded rod 903 through miniature servo motor 905, because two-way threaded rod 903 is connected with threaded block 904 through the screw thread, and threaded block 904 is located two parts that the outer wall screw thread of two-way threaded rod 903 is opposite respectively, so in the course that two-way threaded rod 903 rotates, threaded block 904 can set up the screw thread and move at the outer wall of two-way threaded rod 903, and the direction of moving is opposite, adjust the direction of rotation of two-way threaded rod 903 through miniature servo motor 905, make threaded block 904 move to the direction that is close to each other, drive splint 901 through threaded block 904, make splint 901 close to each other, can carry out the centre gripping with the work piece through splint;

subsequently, the pneumatic telescopic rod 5 is contracted, the first servo motor 8 is started, the driving rod 17 is driven to rotate through the first servo motor 8, the driving gear 16 is driven to rotate through the driving rod 17, the driving gear 16 and the driven gear 15 are meshed with each other, the driven gear 15 can be driven to rotate through the driving gear 16, the driven rotating rod 14 is driven to rotate through the driven gear 15, the driven rotating rod 14 drives the rotating plate 7 to rotate, the rotating plate 7 drives the sliding block 10, the sliding block 10 circularly moves in the annular sliding groove 6, the workpiece can be driven to rotate through the rotating plate 7, the workpiece can be moved to the position right above the electroplating pool 2, the pneumatic telescopic rod 5 is extended, the micro servo motor 905 drives the bidirectional threaded rod to reversely rotate, the workpiece is placed in the electroplating pool 2 to be electroplated, after electroplating is completed, the workpiece is clamped through the extension of the pneumatic telescopic rod 5 and the clamping plate 901, the workpiece is moved to the upper portion of the output conveyor belt 3, the workpiece is conveyed to the next step through the output conveyor belt 3, and the circulating process is formed through the rotation of the rotating plate 7 and the cooperation of the plurality of pneumatic telescopic rods 5 and the fixing structures 9.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. Electroplating processing linkage, including bottom plate (1), its characterized in that: the device also comprises a rotating structure and a fixing structure (9);

an input conveyor belt (12) is arranged on one side of the top end of the bottom plate (1), an electroplating pool (2) is arranged at the front end of the top end of the bottom plate (1), the input conveyor belt (12) is arranged on one side of the top end of the bottom plate (1) far away from the input conveyor belt (12), a back plate (4) is arranged at the rear end of the top end of the bottom plate (1), a top plate (11) is arranged at the top end of the back plate (4), an annular sliding groove (6) is arranged at the bottom end of the top plate (11), a plurality of sliding blocks (10) are arranged in the annular sliding groove (6), a rotating plate (7) is arranged at the bottom end of the sliding blocks (10), pneumatic telescopic rods (5) are arranged at two sides, front ends and rear ends of the bottom end of the rotating plate (7), and fixing structures (9) are all arranged at the bottom ends of the pneumatic telescopic rods (5);

the rotating structure is positioned at the top end of the top plate (11);

the rotary structure comprises a mounting groove (13), the mounting groove (13) is mounted at the middle position of the top end of the top plate (11), a first servo motor (8) is mounted at the top end of the top plate (11) on one side of the mounting groove (13), a driving rod (17) is mounted at the output end of the first servo motor (8), a driving gear (16) is mounted at one end of the driving rod (17), a driven rotating rod (14) is mounted at the top end of the inner portion of the mounting groove (13) through a rotating shaft, and a driven gear (15) is mounted on the outer wall of the driven rotating rod (14).

2. A plating suspension device according to claim 1, wherein: one end of the driving rod (17) passes through the mounting groove (13), and one end of the driving rod (17) extends to the inside of the mounting groove (13).

3. A plating suspension device according to claim 1, wherein: the bottom of the driven rotating rod (14) sequentially penetrates through the mounting groove (13) and the top plate (11) to extend to the top end of the rotating plate (7), and the driven rotating rod (14) is mounted on the top end of the rotating plate (7).

4. A plating suspension device according to claim 1, wherein: the driven gear (15) is positioned below the driving gear (16), and the driven gear (15) is meshed with the driving gear (16).

5. A plating suspension device according to claim 1, wherein: fixed knot constructs (9) including splint (901), rotation groove (902), two-way threaded rod (903), screw thread piece (904) and miniature servo motor (905), rotation groove (902) all install in the bottom of pneumatic telescopic link (5), and all install miniature servo motor (905) in one side of rotation groove (902), two-way threaded rod (903) are all installed to the output of miniature servo motor (905), and the outer wall of two-way threaded rod (903) all has two screw thread pieces (904) through threaded connection, splint (901) are all installed to the bottom of screw thread piece (904).

6. An electroplating process suspension according to claim 5, wherein: one end of each bidirectional threaded rod (903) penetrates through the rotating groove (902) to extend to one side of the inside of the rotating groove (902), and each bidirectional threaded rod (903) is installed on one side of the inside of the rotating groove (902) through a rotating shaft.

7. An electroplating process suspension according to claim 5, wherein: the bottom ends of the clamping plates (901) all penetrate through the rotating grooves (902), and the bottom ends of the clamping plates (901) all extend to the lower parts of the rotating grooves (902).