CN217596075U - High-speed vertical numerical control relieving machine - Google Patents

Abstract

The utility model discloses a high-speed vertical numerical control tooth forming machine relates to tooth forming machine technical field, including first frame subassembly and second frame subassembly, the top of first frame subassembly is equipped with X axle drive assembly, the front end of second frame subassembly is equipped with Z axle drive assembly, X axle drive assembly's removal end top is connected with the workstation, and second frame subassembly is located the extension line of workstation removal trajectory, and when the workstation carries the work piece and removes towards the spiller module, the pressure based on the pressure of spiller module finally acts on the pressure on second draw runner, second slider and top frame is positive pressure, receives this pressure effect for a long time, and the second draw runner, second slider and top frame are difficult for appearing wearing and tearing and deformation, and in addition, the spiller module is split type structure, comprises a plurality of spiller combination, when the cutting edge of one of them spiller takes place the turn-up, the correspondence change can, need not to change whole spiller module, and is simple and practical.

Description

High-speed vertical numerical control gear-shoveling machine

Technical Field

The utility model relates to a forming relieved machine technical field specifically is a high-speed vertical numerical control forming relieved machine.

Background

Through retrieval, the Chinese patent discloses a numerical control gear shoveling machine (publication No. CN 211331635U), wherein the content of the patent mainly comprises a base, an upright post, a shoveling mechanism, a first guide mechanism, a first power mechanism, a workbench, a second guide mechanism and a second power mechanism, the shoveling mechanism comprises a shoveling cutter connected to the upright post through the first guide mechanism, the guide direction of the first guide mechanism is the same as the height direction of the upright post, the first power mechanism of the shoveling mechanism comprises a first motor and a first transmission piece, and the first transmission piece is connected with the shoveling mechanism to drive the shoveling mechanism to move; the guide direction of the second guide mechanism is the same as the length direction of the base, the workbench is connected to the base through the second guide mechanism, the second power mechanism comprises a second motor and a second transmission piece connected with the second motor, and the second transmission piece is connected with the shoveling mechanism to drive the shoveling mechanism to move. The problems that in the prior art, the hydraulic drive positioning precision of the gear shoveling machine is poor, the gear shoveling machine is influenced by temperature, the safety is low and the like are solved;

the above patents have the disadvantages that: the stand that is responsible for indirect nature support relieved serrated knife, its mounted position is not located the removal orbit of workstation, carry the work piece when the workstation and remove, relieved serrated knife is after the atress, the final power that is used in on stand and linear guide rail is the yawing force, stand the effect of side pressure for a long time, different degrees wearing and tearing all can appear in stand and linear guide rail, deformation, in addition, relieved serrated knife sets up to a whole, when the hem appears in the cutting edge part of relieved serrated knife, need the whole change, it is extravagant to cause unnecessary.

SUMMERY OF THE UTILITY MODEL

The utility model provides a not enough to prior art, the utility model provides a high-speed vertical numerical control forming relieved tooth machine has solved the problem of proposing in the above-mentioned background art.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: a high-speed vertical numerical control relieving machine comprises a first machine base component and a second machine base component, wherein an X-axis driving component is arranged at the top of the first machine base component, a Z-axis driving component is arranged at the front end of the second machine base component, a workbench is connected to the top of the moving end of the X-axis driving component, a supporting frame is connected to the moving end of the Z-axis driving component, a stepped groove is formed in the bottom of the front end of the supporting frame, a relieving tool module is connected to the inside of the stepped groove,

the second base assembly is positioned on an extension line of a moving track line of the workbench;

the scraper knife module is of a split structure and is formed by combining a plurality of scraper knives, and each scraper knife is fixed with the support frame through a bolt.

As a further technical scheme of the utility model, the outside of first frame subassembly and second frame subassembly is "L" style of calligraphy structure jointly, X axle drive assembly is the same with Z axle drive assembly's structure, a plurality of groups T type groove have been seted up at the top of workstation.

As a further technical scheme of the utility model, first frame subassembly includes the bottom frame, first recess has been seted up at the top of bottom frame, the both ends of first recess all are equipped with two sets of first lugs, the top of bottom frame is connected with two sets of first draw slivers, every group the equal sliding connection in top of first draw slivers has first slider, the guiding gutter has been seted up to the edge of bottom frame, the exit end of guiding gutter is equipped with the inclined plane, every group the top of first draw slivers all links to each other with the bottom of workstation.

As a further technical scheme of the utility model, the second frame subassembly includes the top frame, the second recess has been seted up to the front end of top frame, the medial surface top and the bottom of second recess all are equipped with two sets of second lugs, the leading flank of top frame is connected with two sets of second draw slips, every group the equal sliding connection in outside of second draw slip has the second slider, every group the leading flank of second slider all links to each other with the trailing flank of support frame.

As a further technical scheme of the utility model, X axle drive assembly includes the threaded rod, the both ends of threaded rod all are equipped with the bearing frame, and are a set of the side-mounting of bearing frame has servo motor, servo motor's output and the one end of threaded rod link to each other, the outside of threaded rod is rotated the wheel and is connected with a screw thread section of thick bamboo, the external connection of a screw thread section of thick bamboo has the connecting block.

As a further technical scheme of the utility model, the threaded rod is located the inside of first recess, every group the bearing frame edge is located the top of two sets of first lugs respectively and links to each other.

Advantageous effects

The utility model provides a high-speed vertical numerical control relieving machine. Compared with the prior art, the method has the following beneficial effects:

the utility model provides a high-speed vertical numerical control forming relieved tooth machine, second frame subassembly is located the extension line of workstation removal trajectory, when the workstation carries the work piece and moves towards the spiller module, the pressure final action on the second draw runner based on the spiller module, the pressure on second slider and the top frame is positive pressure, receive this pressure effect for a long time, the second draw runner, wearing and tearing and deformation are difficult for appearing in second slider and top frame, in addition, the spiller module is split type structure, constitute by a plurality of spiller combinations, when the turn-up takes place for the cutting edge of one of them spiller, the correspondence is changed can, need not to change whole spiller module, and is simple and practical.

Drawings

FIG. 1 is a schematic structural view of a high-speed vertical numerically controlled gear-cutting machine;

FIG. 2 is a schematic view of a first housing assembly of a high speed vertical numerically controlled gear cutting machine;

FIG. 3 is a schematic view of a second housing assembly of a high speed vertical, numerically controlled gear-cutting machine;

FIG. 4 is a schematic diagram of an X-axis drive assembly of a high-speed vertical numerically controlled gear-cutting machine.

In the figure: 1. a first chassis assembly; 11. a bottom chassis; 12. a first groove; 13. a first bump; 14. a first slide bar; 15. a first slider; 16. a diversion trench; 17. a bevel; 2. a second foundation assembly; 21. a top frame; 22. a second groove; 23. a second bump; 24. a second slide bar; 25. a second slider; 3. an X-axis drive assembly; 31. a threaded rod; 32. a bearing seat; 33. a servo motor; 34. a threaded barrel; 35. connecting blocks; 4. a Z-axis drive assembly; 5. a work table; 6. a T-shaped groove; 7. a support frame; 8. a scraper knife module.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, the utility model provides a technical solution of a high-speed vertical numerical control gear-shaping machine: a high-speed vertical numerical control relieving machine comprises a first machine base component 1 and a second machine base component 2, wherein an X-axis driving component 3 is arranged at the top of the first machine base component 1, a Z-axis driving component 4 is arranged at the front end of the second machine base component 2, the top of the moving end of the X-axis driving component 3 is connected with a workbench 5, the moving end of the Z-axis driving component 4 is connected with a supporting frame 7, the bottom of the front end of the supporting frame 7 is provided with a stepped groove, a relieving tool module 8 is connected in the stepped groove, and the second machine base component 2 is positioned on an extension line of a moving track line of the workbench 5; the spiller module 8 is split type structure, comprises a plurality of spiller combinations, all through the bolt fastening between every spiller and the support frame 7, and the outside of first frame subassembly 1 and second frame subassembly 2 is "L" style of calligraphy structure jointly, and X axle drive assembly 3 is the same with Z axle drive assembly 4's structure, and a plurality of groups T type groove 6 have been seted up at the top of workstation 5.

Referring to fig. 2, the first housing assembly 1 includes a bottom housing 11, a first groove 12 is formed in the top of the bottom housing 11, two sets of first protrusions 13 are respectively disposed at two ends of the first groove 12, two sets of first slides 14 are connected to the top of the bottom housing 11, a first slider 15 is slidably connected to the top of each first slide 14, a guide groove 16 is formed in an edge of the bottom housing 11, an inclined surface 17 is disposed at an outlet end of the guide groove 16, and the top of each first slide 14 is connected to the bottom of the workbench 5.

Referring to fig. 3, the second base assembly 2 includes a top base 21, a second groove 22 is formed in the front end of the top base 21, two sets of second protrusions 23 are respectively disposed on the top and the bottom of the inner side of the second groove 22, two sets of second sliding strips 24 are connected to the front side of the top base 21, a second sliding block 25 is slidably connected to the outside of each set of second sliding strips 24, and the front side of each set of second sliding blocks 25 is connected to the rear side of the supporting frame 7.

Referring to fig. 4, the x-axis driving assembly 3 includes a threaded rod 31, bearing seats 32 are disposed at two ends of the threaded rod 31, a servo motor 33 is installed on a side surface of one group of the bearing seats 32, an output end of the servo motor 33 is connected with one end of the threaded rod 31, an external rotating wheel of the threaded rod 31 is connected with a threaded cylinder 34, an external part of the threaded cylinder 34 is connected with a connecting block 35, the threaded rod 31 is located inside the first groove 12, and edges of each group of the bearing seats 32 are respectively located at top ends of two groups of the first protrusions 13 and connected with each other.

In practical use, the X-axis driving assembly 3 drives the threaded rod 31 to rotate clockwise or counterclockwise through the servo motor 33, and the connecting block 35 moves forward or backward under the action of the threaded cylinder 34.

The utility model discloses a theory of operation: when the device is used, firstly, raw materials are installed on a workpiece, the workpiece and the workbench 5 are fixed through bolts, and the supporting frame 7 and the scraper knife module 8 are driven by the Z-axis driving component 4 to move downwards so that the scraper knife module 8 is attached to the raw materials;

then the X-axis driving component 3 drives the connecting block 35 to move towards the rear end, the scraper knife module 8 scrapes the surface of the raw material by extrusion, when the workbench 5 carries a workpiece to move towards the scraper knife module 8, the pressure of the scraper knife module 8 finally acts on the second slide bar 24, the second slide block 25 and the top base 21 in front, the scraper knife module 8 of the Z-axis driving component 4 performs lifting motion, the position of the raw material to be scraped is in a vertical state, the scraper knife module 8 is attached to the raw material again, then the X-axis driving component 3 drives the connecting block 35 to move towards the front end, and thus, the operations are repeated to process the raw material;

when the blade module 8 is used for a long time, if the edge of one or more blades is curled, the blade module can be replaced correspondingly.

Claims (6)

1. A high-speed vertical numerical control relieving machine comprises a first machine base component (1) and a second machine base component (2), wherein an X-axis driving component (3) is arranged at the top of the first machine base component (1), a Z-axis driving component (4) is arranged at the front end of the second machine base component (2), the top of the moving end of the X-axis driving component (3) is connected with a workbench (5), a plurality of groups of T-shaped grooves (6) are formed in the top of the workbench (5), the moving end of the Z-axis driving component (4) is connected with a supporting frame (7), a stepped groove is formed in the bottom of the front end of the supporting frame (7), a relieving tool module (8) is connected inside the stepped groove, and the relieving machine is characterized in that,

the second base assembly (2) is positioned on an extension line of a moving track line of the workbench (5);

the scraper knife module (8) is of a split structure and is formed by combining a plurality of scraper knives, and each scraper knife is fixed with the support frame (7) through bolts.

2. The high-speed vertical numerical control gear-cutting machine according to claim 1, characterized in that the first frame assembly (1) and the second frame assembly (2) are externally and jointly in an L-shaped structure, and the X-axis driving assembly (3) and the Z-axis driving assembly (4) are structurally identical.

3. The high-speed vertical numerical control gear-shoveling machine according to claim 2, wherein the first machine base assembly (1) comprises a bottom machine base (11), a first groove (12) is formed in the top of the bottom machine base (11), two sets of first protruding blocks (13) are arranged at two ends of the first groove (12), two sets of first sliding strips (14) are connected to the top end of the bottom machine base (11), a first sliding block (15) is connected to the top of each set of first sliding strips (14) in a sliding manner, a diversion trench (16) is formed in the edge of the bottom machine base (11), an inclined surface (17) is arranged at the outlet end of the diversion trench (16), and the top end of each set of first sliding strips (14) is connected to the bottom end of the workbench (5).

4. The high-speed vertical numerical control gear-shoveling machine according to claim 2, wherein the second machine base assembly (2) comprises a top machine base (21), a second groove (22) is formed in the front end of the top machine base (21), two groups of second protruding blocks (23) are arranged at the top and the bottom of the inner side surface of the second groove (22), two groups of second sliding strips (24) are connected to the front side surface of the top machine base (21), a second sliding block (25) is connected to the outer portion of each group of second sliding strips (24) in a sliding mode, and the front side surface of each group of second sliding blocks (25) is connected with the rear side surface of the support frame (7).

5. The high-speed vertical numerical control gear-shoveling machine according to claim 2, wherein the X-axis driving assembly (3) comprises a threaded rod (31), bearing seats (32) are arranged at both ends of the threaded rod (31), a servo motor (33) is installed on one group of side faces of the bearing seats (32), the output end of the servo motor (33) is connected with one end of the threaded rod (31), a threaded cylinder (34) is connected with an external rotating wheel of the threaded rod (31), and a connecting block (35) is connected with the external rotating wheel of the threaded cylinder (34).

6. The vertical numerically controlled high-speed gear-shaping machine according to claim 5, characterized in that the threaded bar (31) is located inside the first groove (12), and the edges of each set of bearing blocks (32) are respectively located at the top ends of the two sets of first projections (13).

Images