CN219074407U

CN219074407U - Numerical control cutter for improving stability for machining

Info

Publication number: CN219074407U
Application number: CN202223044233.0U
Authority: CN
Inventors: 吉宗建; 焦非; 陈晓刚
Original assignee: Changzhou Shanmg Precision Machinery Co ltd
Current assignee: Changzhou Shanmg Precision Machinery Co ltd
Priority date: 2022-11-16
Filing date: 2022-11-16
Publication date: 2023-05-26
Anticipated expiration: 2032-11-16

Abstract

The utility model discloses a numerical control cutter for improving stability for machining, which relates to the field of cutters for machining and comprises a cutter body, wherein the centers of the back surfaces of the left side and the right side of the cutter body are symmetrically and fixedly connected with an adapting block, the centers of the back surfaces of the cutter body are movably connected with a movable column, the back surfaces of the movable column are fixedly connected with a mounting column, the back surfaces of the cutter body are provided with mounting assemblies, the left side and the right side of the front surfaces of the mounting assemblies are symmetrically provided with cover plates, the centers of the front surfaces of inner cavities of the mounting assemblies are provided with mounting grooves, the left side and the right side of the inner cavities of the mounting grooves are symmetrically provided with buffer assemblies, the outer walls of the two buffer assemblies are symmetrically wound with springs, the back surfaces of the inner cavities of the mounting grooves are movably connected with threaded columns, and the back surfaces of the threaded columns are in threaded connection with connecting columns. The numerical control cutter for mechanical processing, which is disclosed by the utility model, has better stability and protection performance, and is convenient to maintain and replace.

Description

Numerical control cutter for improving stability for machining

Technical Field

The utility model relates to the field of cutters for machining, in particular to a numerical control cutter for improving stability for machining.

Background

Machining refers to a process of changing the external dimensions or properties of a workpiece by a mechanical device, and can be classified into cutting and pressing according to differences in machining modes.

In China, patent application number: the utility model discloses a numerical control cutter convenient to installation stability is high in CN202122914588.X, including the cutter main part, the lower extreme surface of cutter main part is provided with installation mechanism, the upper end surface of cutter main part is provided with the installation base, installation screw has been seted up to the inside of installation base, installation mechanism's lower extreme surface is provided with the guide arm, the outer wall of guide arm is provided with buffer gear, the lower extreme surface of pole is provided with the blade, and the use length of this cutter is fixed, can not adjust the length of cutter according to the user demand, and inner structure is comparatively complicated simultaneously, and manufacturing cost is higher.

Therefore, it is necessary to provide a numerical control tool for machining with improved stability to solve the above problems.

Disclosure of Invention

The utility model mainly aims to provide a numerical control cutter for improving stability for machining, which can effectively solve the problems in the background technology.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

the numerical control cutter for improving the stability of machining comprises a cutter body, wherein the centers of the back surfaces of the left side and the right side of the cutter body are symmetrically and fixedly connected with an adapter block, the centers of the back surfaces of the cutter body are movably connected with a movable column, and the back surfaces of the movable column are fixedly connected with a mounting column;

the back of cutter body is provided with the installation component, the apron is installed to the positive left and right sides symmetry of installation component, the mounting groove has been seted up in the positive centre of installation component inner chamber, the left and right sides symmetry of mounting groove inner chamber is provided with buffer assembly, two buffer assembly's outer wall symmetry winding has the spring, mounting groove inner chamber back swing joint has the screw thread post, the back threaded connection of screw thread post has the spliced pole, the back swing joint at installation component top has the second gear, the bottom of second gear is provided with first gear.

Preferably, the round grooves are symmetrically formed in the centers of the two adapting blocks, the front faces of the movable columns are movably connected to the back face of the inner cavity of the cutter body, the size of the installing columns is matched with that of the installing grooves, and the installing columns are inserted into the inner cavity of the installing grooves and are connected to the outer walls of the threaded columns in a threaded mode.

Preferably, the centre of mounting groove left and right sides has symmetrically seted up the adaptation groove, the size looks adaptation of adaptation piece and adaptation groove, the size looks adaptation of circular slot and buffer assembly, adaptation piece swing joint is in the inner chamber of adaptation groove and establishes at buffer assembly's outer wall through the circular slot cover.

Preferably, the bottoms of the two springs are symmetrically and fixedly connected to the back surfaces of the inner cavities of the two adapting grooves, the front surfaces of the two springs are symmetrically attached to the back surfaces of the two adapting blocks, the front surfaces of the two cover plates are symmetrically and threadedly connected with bolts, and the two cover plates are in threaded connection with the front surfaces of the two buffer assemblies through the bolts.

Preferably, the back thread of screw thread post outer wall is connected with the spliced pole, the back fixed connection of spliced pole is in the positive centre of first gear.

Preferably, the first gear is meshed with the second gear, the centers of the inner cavities of the first gear and the second gear are symmetrically and fixedly connected with rotating shafts, the back surfaces of the two rotating shafts are symmetrically and rotatably connected to the back surface of the inner cavity of the cutter body, a through groove is formed in the back surface of the top of the cutter body, and the second gear is movably connected in the inner cavity of the through groove.

Advantageous effects

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

1. this machining is with numerical control cutter that promotes stability, conveniently installs the cutter body through screw thread post, apron and the bolt that set up, through the erection column that sets up, can threaded connection at the outer wall of screw thread post to this can fix in the inner chamber of mounting groove, through setting up apron and bolt, can fix the adaptation piece in the inner chamber of adaptation groove, this structure is convenient for maintain and change the cutter body.

2. This numerical control cutter of stability is used in machining can drive the adaptation piece through the spring that sets up after the cutter body receives the impact and remove to the back, and the cutter body can remove to the back of activity post outer wall simultaneously to this drives the cutter body and carries out displacement effect, can be with spring contact this moment, with this cushioning effect, can also improve stability when playing the protection effect to the cutter body, can not produce great rocking phenomenon after receiving great impact when processing.

3. This machining is with numerical control cutter that promotes stability through rotating the second gear that sets up, can mesh with the first gear of bottom to this can drive the spliced pole and rotate, make the back of screw thread post can be in the inner chamber threaded connection of spliced pole, with this length that can adjust the cutter body, can adjust the cutter body according to the user demand this moment.

Drawings

FIG. 1 is a schematic view of the front face of the present utility model;

FIG. 2 is a schematic view of the structure of the mounting post of the present utility model;

FIG. 3 is a schematic view of the structure of the threaded post of the present utility model;

fig. 4 is a schematic structural view of the tool body of the present utility model.

In the figure: 1. a cutter body; 2. an adaptation block; 3. a circular groove; 4. a movable column; 5. a mounting column; 6. a cover plate; 7. a bolt; 8. a mounting assembly; 9. an adaptation groove; 10. a buffer assembly; 11. a spring; 12. a mounting groove; 13. a threaded column; 14. a connecting column; 15. a first gear; 16. a second gear; 17. a rotating shaft; 18. and (5) through grooves.

Detailed Description

The utility model is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the utility model easy to understand.

As shown in fig. 1-4, a numerical control cutter for improving stability for machining comprises a cutter body 1, wherein the centers of the back surfaces of the left side and the right side of the cutter body 1 are symmetrically and fixedly connected with an adapter block 2, the centers of the back surfaces of the cutter body 1 are movably connected with a movable column 4, the back surfaces of the movable column 4 are fixedly connected with a mounting column 5, the back surfaces of the cutter body 1 are provided with a mounting component 8, the left side and the right side of the front surface of the mounting component 8 are symmetrically provided with a cover plate 6, the center of the front surface of the inner cavity of the mounting component 8 is provided with a mounting groove 12, the left side and the right side of the inner cavity of the mounting groove 12 are symmetrically provided with buffer components 10, the outer walls of the two buffer components 10 are symmetrically wound with springs 11, the back surfaces of the inner cavity of the mounting groove 12 are movably connected with threaded columns 13, the back surfaces of the threaded columns 13 are connected with connecting columns 14, the back surfaces of the top of the mounting component 8 are movably connected with a second gear 16, the bottom of the second gear 16 is provided with a first gear 15, the centers of the two adapting blocks 2 are symmetrically provided with round grooves 3, the front faces of the movable columns 4 are movably connected to the back face of the inner cavity of the cutter body 1, the size of the installing columns 5 and the size of the installing grooves 12 are matched, the installing columns 5 are inserted into the inner cavity of the installing grooves 12 and are connected with the outer wall of the threaded columns 13 in a threaded manner, the centers of the left side and the right side of the installing grooves 12 are symmetrically provided with adapting grooves 9, the sizes of the adapting blocks 2 and the adapting grooves 9 are matched, the round grooves 3 and the buffer components 10 are matched in size, the adapting blocks 2 are movably connected into the inner cavity of the adapting grooves 9 and are sleeved on the outer wall of the buffer components 10 through the round grooves 3, the bottoms of the two springs 11 are symmetrically and fixedly connected to the back faces of the inner cavities of the two adapting grooves 9, the front faces of the two springs 11 are symmetrically attached to the back faces of the two adapting blocks 2, the front faces of the two cover plates 6 are symmetrically connected with bolts 7 in a threaded manner, the two cover plates 6 are connected with the front surfaces of the two buffer assemblies 10 through bolts 7 in a threaded manner, the back surfaces of the outer walls of the threaded columns 13 are connected with connecting columns 14 in a threaded manner, the back surfaces of the connecting columns 14 are fixedly connected with the front center of the first gear 15, the first gear 15 is meshed with the second gear 16, the centers of the inner cavities of the first gear 15 and the second gear 16 are symmetrically and fixedly connected with rotating shafts 17, the back surfaces of the two rotating shafts 17 are symmetrically and rotatably connected with the back surfaces of the inner cavity of the cutter body 1, through grooves 18 are formed in the back surfaces of the tops of the cutter body 1, the second gear 16 is movably connected in the inner cavity of the through grooves 18, the cutter body 1 is conveniently installed through the arranged threaded columns 13, the cover plates 6 and bolts 7, the rear surfaces of the connecting columns are in a threaded manner through the arranged mounting columns 5, the connecting columns can be fixedly arranged in the inner cavity of the mounting grooves 12, the structure is convenient for maintenance and replacement of the cutter body 1, the cutter body 1 can be driven to move backwards through the arranged spring 11 after being impacted by the cutter body 1, meanwhile, the cutter body 1 can move backwards to the outer wall of the movable column 4, so as to drive the cutter body 1 to carry out displacement effect, the cutter body can be contacted with the spring 11 at the moment, the buffer effect is achieved, the cutter body 1 can be protected, the stability can be improved, the cutter body can not generate larger shaking phenomenon after being impacted greatly during processing, the connecting column 14 can be driven to rotate through the first gear 15 arranged at the bottom by rotating the second gear 16, the back surface of the threaded column 13 can be in threaded connection in the inner cavity of the connecting column 14, the length of the cutter body 1 can be adjusted, the tool body 1 can be adjusted at this time according to the use requirements.

It should be noted that, the present utility model is a numerical control tool for improving stability for machining, when in use, the installation component 8 is connected with the numerical control device, so that the tool body 1 can be driven to work, after the tool body 1 is impacted, the tool body can move towards the back of the outer wall of the movable column 4, so as to drive the adapting block 2 to move on the outer wall of the buffer component 10, at the same time, the adapting block can be contacted with the spring 11, thereby playing a role of buffering, the second gear 16 is rotated, at the same time, the second gear 16 can be meshed with the first gear 15, at the same time, the first gear 15 can drive the connecting column 14 to rotate, so that the threaded column 13 can be in threaded connection in the inner cavity of the connecting column 14, at the same time, the length of the tool body 1 can be adjusted, when the tool body 1 needs to be maintained, the bolt 7 is taken out, the cover plate 6 is taken away, the second gear 16 is rotated, the threaded column 13 can be driven to retract into the inner cavity of the connecting column 14, at the same time, the front of the threaded column 13 can be separated from the inner cavity of the installation column 5, at the same time, and the tool body 1 can be taken out and replaced.

The foregoing has shown and described the basic principles and main features of the present utility model and the advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a numerical control cutter of stability is promoted for machining, includes cutter body (1), its characterized in that: the right and left sides of the cutter body (1) are symmetrically and fixedly connected with an adapter block (2) in the middle of the back surface, the middle of the back surface of the cutter body (1) is movably connected with a movable column (4), and the back surface of the movable column (4) is fixedly connected with a mounting column (5);

the novel cutting tool is characterized in that the back of the tool body (1) is provided with a mounting assembly (8), a cover plate (6) is symmetrically mounted on the right and left sides of the front of the mounting assembly (8), a mounting groove (12) is formed in the front center of an inner cavity of the mounting assembly (8), a buffer assembly (10) is symmetrically arranged on the right and left sides of the inner cavity of the mounting groove (12), springs (11) are symmetrically wound on the outer wall of the buffer assembly (10), a threaded column (13) is movably connected on the back of the inner cavity of the mounting groove (12), a connecting column (14) is connected with the back of the threaded column (13), a second gear (16) is movably connected on the back of the top of the mounting assembly (8), and a first gear (15) is arranged on the bottom of the second gear (16).

2. The numerical control tool for improving stability for machining according to claim 1, wherein: round grooves (3) are symmetrically formed in the centers of the two adapting blocks (2), the front faces of the movable columns (4) are movably connected to the back face of the inner cavity of the cutter body (1), the installing columns (5) are matched with the installing grooves (12) in size, and the installing columns (5) are inserted into the inner cavity of the installing grooves (12) and are connected to the outer walls of the threaded columns (13) in a threaded mode.

3. The numerical control tool for improving stability for machining according to claim 2, wherein: the right side of mounting groove (12) centre symmetry has seted up adaptation groove (9), the size looks adaptation of adaptation piece (2) and adaptation groove (9), the size looks adaptation of circular slot (3) and buffer assembly (10), adaptation piece (2) swing joint is in the inner chamber of adaptation groove (9) and establishes the outer wall at buffer assembly (10) through circular slot (3) cover.

4. The numerical control tool for improving stability for machining according to claim 1, wherein: the bottoms of the springs (11) are symmetrically and fixedly connected to the back surfaces of the inner cavities of the two adapting grooves (9), the front surfaces of the springs (11) are symmetrically attached to the back surfaces of the two adapting blocks (2), the front surfaces of the cover plates (6) are symmetrically and spirally connected with bolts (7), and the cover plates (6) are spirally connected to the front surfaces of the two buffer assemblies (10) through the bolts (7).

5. The numerical control tool for improving stability for machining according to claim 1, wherein: the back thread connection of screw thread post (13) outer wall has spliced pole (14), the back fixed connection of spliced pole (14) is in the positive centre of first gear (15).

6. The numerical control tool for improving stability for machining according to claim 5, wherein: the novel cutting tool is characterized in that the first gear (15) is meshed with the second gear (16), rotating shafts (17) are symmetrically and fixedly connected to the centers of the inner cavities of the first gear (15) and the second gear (16), the back surfaces of the two rotating shafts (17) are symmetrically and rotatably connected to the back surface of the inner cavity of the tool body (1), through grooves (18) are formed in the back surface of the top of the tool body (1), and the second gear (16) is movably connected to the inner cavity of each through groove (18).