CN217316146U - Novel numerical control cutting device for automobile parts - Google Patents

Abstract

The utility model discloses a novel automobile parts numerical control cutting device, which comprises a base, flexible positioning mechanism is installed to the base both sides, flexible positioning mechanism and base sliding connection, elevating system is installed to the base both sides, elevating system removes the end and installs moving mechanism, install translation mechanism between two moving mechanism, translation mechanism removes the end and is fixed with cutting tool, the utility model discloses when using, improve cutter flexibility and precision through elevating system, translation mechanism and moving mechanism, carry out the centre gripping through flexible fixture to arbitrary shape article, the fixed processing of the automobile parts of the different specifications of being convenient for.

Description

Novel numerical control cutting device for automobile parts

Technical Field

The utility model relates to an automobile parts processing technology field specifically is a novel automobile parts numerical control cutting device.

Background

Automobile parts supports the basis of auto industry development, carries out cutting process according to the drawing to spare part in cutting process, and it is often irregular shape to be unfavorable for the centre gripping fixed in the course of working, has influenced machining efficiency.

Therefore, a novel numerical control cutting device for automobile parts is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a novel automobile parts numerical control cutting device to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a novel automobile parts numerical control cutting device, includes the base, flexible positioning mechanism is installed to the base both sides, flexible positioning mechanism and base sliding connection, elevating system is installed to the base both sides, elevating system removes the end and installs moving mechanism, install translation mechanism between two moving mechanism, translation mechanism removes the end and is fixed with cutting tool, and flexible positioning mechanism is fixed to the part, and rethread elevating system, moving mechanism and translation mechanism carry out accurate location to the cutter, are convenient for improve the processing qualification rate.

Preferably, the flexible positioning mechanism comprises a positioning groove, a positioning shell, a driving groove, a spring, a positioning column, a first chute, a first bidirectional threaded rod, a first threaded sleeve, a first clamping plate and a first motor, the positioning groove is formed in the upper surface of the base, the positioning shell slides on two sides of the positioning groove, the first chute is formed in the upper surface and the lower surface of the positioning shell, the spring is fixed on the inner wall of the positioning shell in an equidistant manner, the positioning column is fixed at the other end of the spring, the driving groove is formed in the base and located below the positioning groove, the first motor is fixed on the inner wall of the driving groove, the first bidirectional threaded rod is rotatably connected with the inner wall of the driving groove, the output end of the first motor is fixedly connected with the first bidirectional threaded rod, the first bidirectional threaded rod is in threaded connection with the first threaded sleeve, and the first clamping plate is fixed on the upper surface of the first threaded sleeve, first splint and first spout sliding connection, first splint and location shell outside reference column fixed connection are convenient for carry out the centre gripping to arbitrary shape object and fix.

Preferably, the base is located flexible positioning mechanism both sides and has seted up the second spout, drive inslot wall is located first bidirectional threaded rod below and rotates and be connected with the second bidirectional threaded rod drive inslot wall is fixed with the second motor, second motor output and second bidirectional threaded rod fixed connection, second bidirectional threaded rod threaded connection has second threaded sleeve, second threaded sleeve both sides are fixed with the second splint, second splint and second spout sliding connection, second splint and location shell both sides fixed connection, the object of being convenient for carries out more nimble centre gripping.

Preferably, elevating system includes first drive shell, first threaded rod, third motor and third threaded sleeve, the base is located flexible positioning mechanism both sides and is fixed with first drive shell, first drive shell inner wall rotates and is connected with first threaded rod, first drive shell inner wall is fixed with the third motor, third motor output and first threaded rod fixed connection, first threaded rod threaded connection has third threaded sleeve, third threaded sleeve and first drive shell one side sliding connection are convenient for improve the precision that the cutter removed in vertical direction.

Preferably, moving mechanism includes second drive shell, second threaded rod, fourth motor and fourth threaded sleeve, one side that first drive shell was kept away from to third threaded sleeve is fixed with second drive shell, second drive shell inner wall rotates and is connected with the second threaded rod, second drive shell inner wall is fixed with the fourth motor, fourth motor output and second threaded rod fixed connection, second threaded rod threaded connection has fourth threaded sleeve, fourth threaded sleeve and second drive shell one side sliding connection are convenient for improve the removal precision of cutter at the horizontal direction.

Preferably, translation mechanism includes third drive shell, third threaded rod, fifth motor and fifth threaded sleeve, fourth threaded sleeve keeps away from second drive shell one side and is fixed with the third drive shell, third drive shell inner wall moves to be connected with the third threaded rod, and third drive shell inner wall is fixed with the fifth motor, fifth motor output and third threaded rod fixed connection, third threaded rod threaded connection has the fifth threaded sleeve, fifth threaded sleeve and third drive shell one side sliding connection, third drive shell and cutting tool fixed connection are convenient for improve the cutter moving as a whole precision.

Preferably, rubber is fixed on the contact surface of the positioning column, so that the clamping force of the article and the protection of the surface of the article are improved conveniently.

Preferably, the third motor, the fourth motor and the fifth motor are speed reducing motors, so that the moving speed of the cutter can be conveniently adjusted.

Compared with the prior art, the beneficial effects of the utility model are that: the flexibility and the precision of the cutter are improved through the lifting mechanism, the translation mechanism and the moving mechanism, and articles in any shape are clamped through the flexible clamping mechanism, so that the fixed processing of automobile parts in different specifications is facilitated.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the flexible positioning mechanism of the present invention;

fig. 3 is a second schematic structural view of the flexible positioning mechanism of the present invention;

fig. 4 is a third schematic structural view of the flexible positioning mechanism of the present invention;

fig. 5 is a schematic structural view of the lifting mechanism of the present invention;

fig. 6 is a schematic structural view of the moving mechanism of the present invention;

fig. 7 is a schematic structural view of the translation mechanism of the present invention.

In the figure: 1. a base; 2. a flexible positioning mechanism; 3. a lifting mechanism; 4. a moving mechanism; 5. a translation mechanism; 6. cutting a cutter; 7. a positioning groove; 8. a positioning shell; 9. a drive slot; 10. a spring; 11. a positioning column; 12. a first chute; 13. a first bi-directional threaded rod; 14. a first threaded sleeve; 15. a first splint; 16. a first motor; 17. a second chute; 18. a second bidirectional threaded rod; 19. a second motor; 20. a second threaded sleeve; 21. a second splint; 22. a first drive case; 23. a first threaded rod; 24. A third motor; 25. a third threaded sleeve; 26. a second drive case; 27. a second threaded rod; 28. a fourth motor; 29. a fourth threaded sleeve; 30. a third drive case; 31. a third threaded rod; 32. a fifth motor; 33. a fifth threaded sleeve; 34. rubber.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying 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 present invention provides a technical solution: the utility model provides a novel automobile parts numerical control cutting device, includes base 1, flexible positioning mechanism 2 is installed to 1 both sides of base, flexible positioning mechanism 2 and 1 sliding connection of base, elevating system 3 is installed to 1 both sides of base, 3 removal ends of elevating system install moving mechanism 4, install translation mechanism 5 between two moving mechanism 4, 5 moving ends of translation mechanism are fixed with cutting tool 6, improve cutter flexibility and precision through elevating system 3, translation mechanism 5 and moving mechanism 4, and flexible positioning mechanism 2 provides more effectual fixed action to the spare part.

Referring to fig. 2 and fig. 3, the flexible positioning mechanism 2 includes a positioning groove 7, a positioning housing 8, a driving groove 9, a spring 10, a positioning column 11, a first sliding groove 12, a first bidirectional threaded rod 13, a first threaded sleeve 14, a first clamping plate 15 and a first motor 16, the positioning groove 7 is formed on the upper surface of the base 1, the positioning housing 8 is slid on both sides of the positioning groove 7, the first sliding groove 12 is formed on the upper and lower surfaces of the positioning housing 8, the spring 10 is fixed on the inner wall of the positioning housing 8 at equal intervals, the other end of the spring 10 is fixed with the positioning column 11, the contact surface of the positioning column 11 is fixed with rubber 34, the driving groove 9 is formed below the positioning groove 7 inside the base 1, the first motor 16 is fixed on the inner wall of the driving groove 9, the first bidirectional threaded rod 13 is rotatably connected on the inner wall of the driving groove 9, the output end of the first motor 16 is fixedly connected with the first bidirectional threaded rod 13, first double-direction threaded rod 13 threaded connection has first threaded sleeve 14, first threaded sleeve 14 upper surface is fixed with first splint 15, first splint 15 and first spout 12 sliding connection, first splint 15 and location shell 8 outside reference column 11 fixed connection, reference column 11 pass through the height that different reference columns 11 were adjusted to spring 10 according to the shape of centre gripping spare part, make its identical spare part appearance, and first motor 16 drives first double-direction threaded rod 13 and rotates, and the rotation of first double-direction threaded rod 13 drives first threaded sleeve 14 and removes to the middle part, drives first splint 15 and makes the space between a plurality of reference column 11 in the location shell 8 closed in order to fix through the extrusion to outside reference column 11.

Referring to fig. 4, second sliding grooves 17 are formed in the two sides of the flexible positioning mechanism 2 of the base 1, the inner wall of the driving groove 9 is located below the first bidirectional threaded rod 13 and is rotatably connected with a second bidirectional threaded rod 18, a second motor 19 is fixed on the inner wall of the driving groove 9, the output end of the second motor 19 is fixedly connected with the second bidirectional threaded rod 18, the second bidirectional threaded rod 18 is in threaded connection with a second threaded sleeve 20, second clamping plates 21 are fixed on the two sides of the second threaded sleeve 20, the second clamping plates 21 are slidably connected with the second sliding grooves 17, the second clamping plates 21 are fixedly connected with the two sides of the positioning shell 8, the second motor 19 drives the second bidirectional threaded rod 18 to rotate, and the second bidirectional threaded rod 18 drives the second threaded sleeves 20 on the two sides to drive the positioning shell 8 to move through the second clamping plates 21.

Referring to fig. 5, the lifting mechanism 3 includes a first driving shell 22, a first threaded rod 23, a third motor 24 and a third threaded sleeve 25, the first driving shell 22 is fixed on two sides of the flexible positioning mechanism 2 of the base 1, the inner wall of the first driving shell 22 is rotatably connected to the first threaded rod 23, the third motor 24 is fixed on the inner wall of the first driving shell 22, the output end of the third motor 24 is fixedly connected to the first threaded rod 23, the first threaded rod 23 is in threaded connection with the third threaded sleeve 25, the third threaded sleeve 25 is slidably connected to one side of the first driving shell 22, the third motor 24 drives the first threaded rod 23 to rotate, and the third threaded sleeve 25 which is in threaded connection with the first threaded rod 23 moves along with the rotation of the first threaded rod 23 and drives the moving mechanism 4 to lift.

Referring to fig. 6, the moving mechanism 4 includes a second driving shell 26, a second threaded rod 27, a fourth motor 28, and a fourth threaded sleeve 29, the second driving shell 26 is fixed on a side of the third threaded sleeve 25 away from the first driving shell 22, the second threaded rod 27 is rotatably connected to an inner wall of the second driving shell 26, the fourth motor 28 is fixed on an inner wall of the second driving shell 26, an output end of the fourth motor 28 is fixedly connected to the second threaded rod 27, the second threaded rod 27 is threadedly connected to the fourth threaded sleeve 29, the fourth threaded sleeve 29 is slidably connected to one side of the second driving shell 26, the fourth motor 28 drives the second threaded rod 27 to rotate, and the fourth threaded sleeve 29 moves by the rotation of the second threaded rod 27 to drive the horizontal movement of the translating mechanism 5.

Referring to fig. 7, the translation mechanism 5 includes a third driving shell 30, a third threaded rod 31, a fifth motor 32 and a fifth threaded sleeve 33, the third driving shell 30 is fixed on a side of the fourth threaded sleeve 29 away from the second driving shell 26, the third threaded rod 31 is rotatably connected to an inner wall of the third driving shell 30, the fifth motor 32 is fixed on an inner wall of the third driving shell 30, the third motor 24, the fourth motor 28 and the fifth motor 32 are speed reduction motors, an output end of the fifth motor 32 is fixedly connected to the third threaded rod 31, the third threaded rod 31 is threadedly connected to a fifth threaded sleeve 33, the fifth threaded sleeve 33 is slidably connected to a side of the third driving shell 30, the third driving shell 30 is fixedly connected to the cutting tool 6, the fifth motor 32 drives the third threaded rod 31 to rotate, the fifth threaded sleeve 33 moves by rotation of the third threaded rod 31, driving the cutting tool 6 to move.

The working principle is as follows: an article is placed on the positioning groove 7, the second motor 19 drives the second bidirectional threaded rod 18 to rotate, the second bidirectional threaded rod 18 drives the second threaded sleeves 20 at two sides to drive the positioning shell 8 to move through the second clamping plate 21, the positioning columns 11 adjust the heights of different positioning columns 11 through the springs 10 according to the shapes of the clamped parts so that the positioning columns are matched with the shapes of the parts, the first motor 16 drives the first bidirectional threaded rod 13 to rotate, the first bidirectional threaded rod 13 rotates to drive the first threaded sleeve 14 to move towards the middle part, the first clamping plate 15 is driven to close gaps among the positioning columns 11 in the positioning shell 8 through extrusion on the positioning columns 11 at the outer side so as to be fixed, the third motor 24 drives the first threaded rod 23 to rotate, the third threaded sleeve 25 in threaded connection with the first threaded rod 23 moves along with the rotation of the first threaded rod 23 and drives the moving mechanism 4 to move, the lifting mechanism 3, the moving mechanism 4 and the translation mechanism 5 are identical in structure, and the cutting tool 6 is positioned through three-axis movement.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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

Claims (8)

1. The utility model provides a novel automobile parts numerical control cutting device, includes base (1), its characterized in that: flexible positioning mechanism (2) are installed to base (1) both sides, flexible positioning mechanism (2) and base (1) sliding connection, elevating system (3) are installed to base (1) both sides, moving mechanism (4) are installed to elevating system (3) removal end, install translation mechanism (5) between two moving mechanism (4), translation mechanism (5) moving end is fixed with cutting tool (6).

2. The novel numerical control cutting device for the automobile parts, according to claim 1, is characterized in that: the flexible positioning mechanism (2) comprises a positioning groove (7), a positioning shell (8), a driving groove (9), a spring (10), a positioning column (11), a first sliding groove (12), a first bidirectional threaded rod (13), a first threaded sleeve (14), a first clamping plate (15) and a first motor (16), wherein the positioning groove (7) is formed in the upper surface of the base (1), the positioning shell (8) is arranged on two sides of the positioning groove (7) in a sliding mode, the first sliding groove (12) is formed in the upper surface and the lower surface of the positioning shell (8), the spring (10) is fixed on the inner wall of the positioning shell (8) in an equidistant mode, the positioning column (11) is fixed to the other end of the spring (10), the driving groove (9) is formed in the base (1) and is located below the positioning groove (7), the first motor (16) is fixed to the inner wall of the driving groove (9), the first bidirectional threaded rod (13) is connected to the inner wall of the driving groove (9) in a rotating mode, first motor (16) output and first double-direction threaded rod (13) fixed connection, first double-direction threaded rod (13) threaded connection has first threaded sleeve (14), first threaded sleeve (14) upper surface is fixed with first splint (15), first splint (15) and first spout (12) sliding connection, first splint (15) and location shell (8) outside reference column (11) fixed connection.

3. The novel numerical control cutting device for the automobile parts as claimed in claim 2, characterized in that: base (1) is located flexible positioning mechanism (2) both sides and has seted up second spout (17), drive groove (9) inner wall is located first bidirectional threaded rod (13) below and rotates and be connected with second bidirectional threaded rod (18) drive groove (9) inner wall is fixed with second motor (19), second motor (19) output and second bidirectional threaded rod (18) fixed connection, second bidirectional threaded rod (18) threaded connection has second threaded sleeve (20), second threaded sleeve (20) both sides are fixed with second splint (21), second splint (21) and second spout (17) sliding connection, second splint (21) and location shell (8) both sides fixed connection.

4. The novel numerical control cutting device for the automobile parts, according to claim 1, is characterized in that: elevating system (3) are including first drive shell (22), first threaded rod (23), third motor (24) and third threaded sleeve (25), base (1) is located flexible positioning mechanism (2) both sides and is fixed with first drive shell (22), first drive shell (22) inner wall rotates and is connected with first threaded rod (23), first drive shell (22) inner wall is fixed with third motor (24), third motor (24) output and first threaded rod (23) fixed connection, first threaded rod (23) threaded connection has third threaded sleeve (25), third threaded sleeve (25) and first drive shell (22) one side sliding connection.

5. The novel numerical control cutting device for the automobile parts as claimed in claim 4, characterized in that: moving mechanism (4) include second drive shell (26), second threaded rod (27), fourth motor (28) and fourth threaded sleeve (29), one side that first drive shell (22) was kept away from in third threaded sleeve (25) is fixed with second drive shell (26), second drive shell (26) inner wall rotates and is connected with second threaded rod (27), second drive shell (26) inner wall is fixed with fourth motor (28), fourth motor (28) output and second threaded rod (27) fixed connection, second threaded rod (27) threaded connection has fourth threaded sleeve (29), fourth threaded sleeve (29) and second drive shell (26) one side sliding connection.

6. The novel numerical control cutting device for the automobile parts as claimed in claim 5, characterized in that: translation mechanism (5) include third drive shell (30), third threaded rod (31), fifth motor (32) and fifth threaded sleeve (33), second drive shell (26) one side is kept away from in fourth threaded sleeve (29) is fixed with third drive shell (30), third drive shell (30) inner wall is moved and is changeed and be connected with third threaded rod (31), and third drive shell (30) inner wall is fixed with fifth motor (32), fifth motor (32) output and third threaded rod (31) fixed connection, third threaded rod (31) threaded connection has fifth threaded sleeve (33), fifth threaded sleeve (33) and third drive shell (30) one side sliding connection, third drive shell (30) and cutting tool (6) fixed connection.

7. The novel numerical control cutting device for the automobile parts as claimed in claim 2, characterized in that: and rubber (34) is fixed on the contact surface of the positioning column (11).

8. The novel numerical control cutting device for the automobile parts as claimed in claim 6, characterized in that: the third motor (24), the fourth motor (28) and the fifth motor (32) are speed reducing motors.

Images