CN220806283U

CN220806283U - Turnover mechanism for machining

Info

Publication number: CN220806283U
Application number: CN202322674383.8U
Authority: CN
Inventors: 姜永超; 耿立军; 王婷; 贾喜圣; 梁贤辉
Original assignee: Dalian Zhenyi Precision Parts Co ltd
Current assignee: Dalian Zhenyi Precision Parts Co ltd
Priority date: 2023-10-07
Filing date: 2023-10-07
Publication date: 2024-04-19
Anticipated expiration: 2033-10-07

Abstract

The utility model discloses a turnover mechanism for machining, which comprises a bottom plate and two groups of supporting blocks, wherein the side surfaces of the two groups of supporting blocks are respectively bolted with a first rotating motor and a second rotating motor, the corresponding surfaces of the two groups of supporting blocks are rotatably provided with a first rotating column, the outer cambered surface of the first rotating column is fixedly sleeved with a driving gear, the side surfaces of the driving gear are meshed with a transmission gear, the corresponding surfaces of the two groups of supporting blocks are respectively provided with a connecting block, and the upper parts of the connecting blocks are commonly connected with a rotating seat; the second rotating electrical machines drive through the connecting rod and rotate the seat and rotate, and then drive electronic vacuum chuck and upper portion work piece upset, rethread first rotating electrical machines rotate and drive the driving gear and rotate to drive the drive gear and rotate, drive electronic vacuum chuck and upper portion work piece and rotate, and then reach and carry out the angle rotation when overturning the work piece, make the work piece that needs the upset promptly and need rotatory can rotate simultaneously, with this increase work efficiency, reduce artifical use cost.

Description

Turnover mechanism for machining

Technical Field

The utility model relates to the technical field of machining, in particular to a turnover mechanism for machining.

Background

The machining refers to the process of changing the external dimension or performance of a workpiece through mechanical equipment, the machining mode difference can be divided into cutting machining and pressure machining, the production process of a machine refers to the whole process of manufacturing a product from raw materials (or semi-finished products), the production process of the machine comprises the steps of transporting and storing raw materials, preparing production, manufacturing blanks, processing and heat treatment of parts, assembling and debugging products, painting and packaging and the like, in the process of conveying the workpiece, the workpiece needs to be turned over, and the machining treatment of different surfaces of the workpiece in the next project is realized, but the conventional turning over needs to be realized manually, has complicated manual operation and easy fatigue, reduces the efficiency, and increases the engineering cost by manual operation, so that the requirement of machining is difficult to be met; the existing turnover mechanism can only simply turn over the workpiece and cannot rotate at the same time of turning over; therefore, we need to propose a turnover mechanism for machining.

Disclosure of utility model

The utility model aims to provide a turnover mechanism for machining, which drives a second connecting block to rotate through a second rotating motor, and drives a rotating seat to rotate through a connecting rod, so that an electric vacuum chuck and an upper workpiece are driven to turn over, and drives a rotating column to rotate through a first rotating motor, so that a driving gear is driven to rotate, and the driving gear is meshed with a transmission gear, so that the transmission gear is driven to rotate, and the electric vacuum chuck and the upper workpiece are driven to rotate, so that the problems in the background art are solved.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a tilting mechanism for machining, includes bottom plate and two sets of supporting shoe, two sets of the supporting shoe side is bolted respectively has first rotating electrical machines and second rotating electrical machines, two sets of the supporting shoe corresponds the face and rotates and be provided with first rotation post, first rotation post extrados is fixed to be cup jointed the driving gear, driving gear side meshing is provided with drive gear, drive gear top fixedly connected with second rotation post, two sets of the supporting shoe corresponds the face and is provided with first connecting block and second connecting block respectively, first connecting block and second connecting block upper portion are connected with the rotation seat jointly, second rotation post one end runs through the rotation seat and is provided with electronic vacuum chuck.

Preferably, one end of the first rotating column penetrates through the supporting block to be connected with the output end of the first rotating motor in a key mode, the first rotating column is connected with the first connecting block and the second connecting block in a rotating mode, connecting rods are fixedly connected to the upper surfaces of the first connecting block and the second connecting block, and the two groups of connecting rods are connected to two sides of the rotating seat respectively.

Preferably, the output end of the second rotating motor is fixedly connected with the second connecting block through a coupler, and the second rotating motor is not connected with the first rotating column.

Preferably, the bottom plate upper surface fixed is provided with the ejection of compact platform, just the ejection of compact platform is located electronic vacuum chuck lower part, the bottom plate upper surface has the feeding platform through support column fixed mounting, just the feeding platform is located electronic vacuum chuck upper portion, the feeding platform is inside to be seted up the extracting groove that corresponds with electronic vacuum chuck.

Preferably, the upper surface of the bottom plate is slidably provided with two groups of sliding tables, the upper surfaces of the two groups of sliding tables are fixedly provided with electric push rods, and the two groups of supporting blocks are respectively connected to the top ends of the two groups of electric push rods.

Preferably, the sliding table bottom end fixing is provided with the sliding block, the sliding tray that corresponds with the sliding block has been seted up to the bottom plate upper surface, and the sliding block side runs through and is provided with the reference column, the bottom plate has all been seted up in a plurality of groups of locating holes that correspond with the reference column with the sliding tray side.

Preferably, the internal thread is arranged in the positioning hole, the external thread corresponding to the positioning hole is arranged on the outer cambered surface of the positioning column, and a manual rotary table is fixedly arranged at one end of the positioning column.

Compared with the prior art, the utility model has the beneficial effects that:

According to the utility model, the second connecting block is driven to rotate by the second rotating motor, the rotating seat is driven to rotate by the connecting rod, the electric vacuum chuck and the upper workpiece are driven to turn over by the connecting rod, the rotating column is driven to rotate by the first rotating motor, the driving gear is driven to rotate by the rotating column, the driving gear is meshed with the transmission gear, so that the transmission gear is driven to rotate, the electric vacuum chuck and the upper workpiece are driven to rotate, and the workpiece can be turned over and rotated at the same time, so that the working efficiency is increased, and the manual use cost is reduced.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

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

FIG. 3 is a schematic view of a rotating assembly according to the present utility model;

fig. 4 is a front view of the overall structure of the present utility model.

In the figure: 1. a bottom plate; 2. a discharging table; 3. a sliding table; 4. a support block; 5. an electric push rod; 6. a first rotating electric machine; 7. a feed table; 8. a sliding groove; 9. positioning holes; 10. positioning columns; 11. a sliding block; 12. a second rotating electric machine; 13. a first rotating column; 14. a drive gear; 15. a transmission gear; 16. an electric vacuum chuck; 17. a first connection block; 18. a connecting rod; 19. a second rotating column; 20. a rotating seat; 21. and a second connecting block.

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.

The present utility model provides: the turnover mechanism for machining comprises a base plate 1 and two groups of supporting blocks 4, wherein the side surfaces of the two groups of supporting blocks 4 are respectively bolted with a first rotating motor 6 and a second rotating motor 12, the corresponding surfaces of the two groups of supporting blocks 4 are rotatably provided with a first rotating column 13, the outer cambered surface of the first rotating column 13 is fixedly sleeved with a driving gear 14, the side surfaces of the driving gear 14 are meshed with a transmission gear 15, the top end of the transmission gear 15 is fixedly connected with a second rotating column 19, the corresponding surfaces of the two groups of supporting blocks 4 are respectively provided with a first connecting block 17 and a second connecting block 21, the upper parts of the first connecting block 17 and the second connecting block 21 are jointly connected with a rotating seat 20, one end of the second rotating column 19 penetrates through the rotating seat 20 to be provided with an electric vacuum chuck 16, when the first rotating motor 6 drives the rotating column 13 to rotate, the driving gear 14 is driven to rotate, the driving gear 14 is meshed with the transmission gear 15, and the transmission gear 15 is driven to rotate, and then the electric vacuum chuck 16 and an upper workpiece are driven to rotate through the transmission column 19.

As a preferred way, one end of the first rotating column 13 penetrates through the supporting block 4 to be connected with the output end of the first rotating motor 6 in a key way, the first rotating column 13 is rotationally connected with the first connecting block 17 and the second connecting block 21, connecting rods 18 are fixedly connected to the upper surfaces of the first connecting block 17 and the second connecting block 21, two groups of connecting rods 18 are respectively connected to two sides of the rotating seat 20, the first rotating motor 6 is connected with the rotating column 13 in a key way, the first rotating motor 6 starts to drive the rotating column 13 to rotate, the first connecting block 17 and the second connecting block 21 cannot rotate along with the rotating, and when the workpiece is required to rotate in an angle, the rotating seat 20 cannot be driven to rotate, so that the workpiece cannot be driven to turn over during rotation.

It is worth to say that, the output end of the second rotating motor 12 is fixedly connected with the second connecting block 21 through a coupler, the second rotating motor 12 is not connected with the first rotating column 13, the second rotating motor 12 is started to drive the second connecting block 21 to rotate, then the rotating seat 20 is driven to rotate through the connecting rod 18, the rotating seat 20 drives the electric vacuum chuck 16 and the upper part to adsorb the workpiece to overturn through the transmission column 19, the second rotating motor 12 is not connected with the rotating column 13, and the workpiece is prevented from being driven to rotate when the workpiece is overturned.

Further, the fixed discharging table 2 that is provided with of upper surface of bottom plate 1, and discharging table 2 is located electronic vacuum chuck 16 lower part, bottom plate 1 upper surface is through support column fixed mounting having feeding platform 7, and feeding platform 7 is located electronic vacuum chuck 16 upper portion, feeding platform 7 inside has offered the material taking groove that corresponds with electronic vacuum chuck 16, adsorb the work piece on feeding platform 7 upper portion through electronic vacuum chuck 16, then drive electronic vacuum chuck 16 upset to discharging table 2 upper portion through second rotating electrical machines 12, place the work piece on discharging table 2 upper portion again, thereby make whole upset and rotatory process accomplish by mechanical automation, avoid needing artifical the participation, thereby reduce artifical use cost.

Still further, the upper surface of the bottom plate 1 is slidably provided with two groups of sliding tables 3, the upper surfaces of the two groups of sliding tables 3 are fixedly provided with electric push rods 5, two groups of supporting blocks 4 are respectively connected to the top ends of the two groups of electric push rods 5, when the workpiece inside the feeding table 7 needs to be adsorbed, the electric push rods 5 push the supporting blocks 4 to move upwards, then drive the electric vacuum chuck 16 to move upwards, adsorb the workpiece and lift the workpiece at the same time, overturn and rotate again, and then the side wall of the workpiece can be prevented from colliding with the side wall of the feeding table 7, so that the workpiece is prevented from being collided with the side wall of the feeding table 7, and the workpiece is damaged.

In addition, sliding block 11 is provided with to the fixed bottom of sliding table 3, and sliding groove 8 that corresponds with sliding block 11 has been seted up to bottom plate 1 upper surface, and sliding block 11 side runs through and is provided with reference column 10, and bottom plate 1 and sliding groove 8 side all link up and have seted up a plurality of groups and reference column 10 corresponding locating hole 9, when the inside work piece size of feeding platform 7 changes, through sliding table 3 in sliding groove 8 to drive upset subassembly and electronic vacuum chuck 16 and remove to the work piece under, in order to guarantee that electronic vacuum chuck 16 can steadily adsorb the work piece.

Specifically, the internal thread has been seted up inside the locating hole 9, and the external screw thread that corresponds with locating hole 9 has been seted up to the spliced pole 10 extrados, and spliced pole 10 one end fixed mounting has manual carousel, and after sliding table 3 along sliding tray 8 to required position, through rotating manual carousel, inside the spliced pole 10 screw in corresponding locating hole 9, make spliced pole 10 run through slider 11 and sliding tray 8 with sliding table 3 fixed.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a tilting mechanism for machining which characterized in that: including bottom plate (1) and two sets of supporting shoe (4), two sets of supporting shoe (4) side is bolted respectively has first rotating electrical machines (6) and second rotating electrical machines (12), two sets of supporting shoe (4) are provided with first rotation post (13) corresponding surface rotation, first rotation post (13) extrados has fixedly cup jointed driving gear (14), driving gear (14) side meshing is provided with drive gear (15), drive gear (15) top fixedly connected with second rotation post (19), two sets of supporting shoe (4) are provided with first connecting block (17) and second connecting block (21) respectively corresponding surface, first connecting block (17) and second connecting block (21) upper portion are connected with rotation seat (20) jointly, second rotation post (19) one end runs through rotation seat (20) and is provided with electronic vacuum chuck (16).

2. The turnover mechanism for machining of claim 1, wherein: the utility model discloses a rotary seat, including supporting shoe (4), first rotating electrical machines (6), first pivoted post (13) one end runs through supporting shoe (4) and first rotating electrical machines (6) output key connection, just first pivoted post (13) all rotate with first connecting block (17) and second connecting block (21) and be connected, just equal fixedly connected with connecting rod (18) of first connecting block (17) and second connecting block (21) upper surface, two sets of connecting rod (18) are connected in rotation seat (20) both sides respectively.

3. A turnover mechanism for machining according to claim 2, wherein: the output end of the second rotating motor (12) is fixedly connected with the second connecting block (21) through a coupler, and the second rotating motor (12) is not connected with the first rotating column (13).

4. The turnover mechanism for machining of claim 1, wherein: the feeding device is characterized in that a discharging table (2) is fixedly arranged on the upper surface of the bottom plate (1), the discharging table (2) is located at the lower portion of the electric vacuum chuck (16), a feeding table (7) is fixedly arranged on the upper surface of the bottom plate (1) through a supporting column, the feeding table (7) is located at the upper portion of the electric vacuum chuck (16), and a material taking groove corresponding to the electric vacuum chuck (16) is formed in the feeding table (7).

5. The turnover mechanism for machining of claim 4, wherein: the sliding table is characterized in that two groups of sliding tables (3) are slidably arranged on the upper surface of the bottom plate (1), electric push rods (5) are fixedly arranged on the upper surfaces of the two groups of sliding tables (3), and the two groups of supporting blocks (4) are respectively connected to the top ends of the two groups of electric push rods (5).

6. The turnover mechanism for machining of claim 5, wherein: the sliding table is characterized in that a sliding block (11) is fixedly arranged at the bottom end of the sliding table (3), a sliding groove (8) corresponding to the sliding block (11) is formed in the upper surface of the bottom plate (1), positioning columns (10) are arranged on the side surfaces of the sliding block (11) in a penetrating mode, and a plurality of groups of positioning holes (9) corresponding to the positioning columns (10) are formed in the side surfaces of the bottom plate (1) and the sliding groove (8) in a penetrating mode.

7. The turnover mechanism for machining of claim 6, wherein: the positioning device is characterized in that an internal thread is arranged in the positioning hole (9), an external thread corresponding to the positioning hole (9) is arranged on the outer cambered surface of the positioning column (10), and a manual rotary table is fixedly arranged at one end of the positioning column (10).