CN210499235U - High-precision mold machining center - Google Patents

Abstract

The utility model discloses a high accuracy mould machining center, the on-line screen storage device comprises a base, the first driving motor of fixedly connected with on the lateral wall of base one side, the first bevel gear of shaft coupling fixedly connected with is passed through to first driving motor's output, two symmetrical fixed plates of fixedly connected with of two correspondences edges of base upper surface, the last fixed surface of fixed plate is connected with two symmetrical clamp splices, the utility model discloses the beneficial effect who reaches is: the utility model relates to a high accuracy mould machining center adds man-hour to the part when using machining center, and at the in-process of work, real-time first driving motor and second driving motor are removed to open according to the required angle of parts machining, and real-time position to the slider is adjusted for the swing cutter can reach its required position, carries out the processing of high accuracy, accomplishes all processings behind the disposable clamping, satisfies the actual demand of high accuracy mould.

Description

High-precision mold machining center

Technical Field

The utility model relates to a mould machining center, in particular to high accuracy mould machining center belongs to machining technical field.

Background

In the field of modern machining, a machining center is used as a high-precision automatic machining device, and is increasingly applied to machining of high-precision parts due to the characteristics of concentrated procedures and high machining precision. Particularly, for small-batch parts with complex shapes and high precision requirements, the machining mode of the parts is often completed by selecting a high-precision machining center. The machining process of the existing die machining center is that a main shaft rotates to drive a cutter to machine parts, all machining is basically difficult to complete after one-time clamping, and the actual requirements of a high-precision die are difficult to meet, so that the high-precision die machining center is necessary to solve the problems.

SUMMERY OF THE UTILITY MODEL

The utility model discloses its course of working of mould machining center who solves often is that a main shaft rotates and drives a cutter and process spare part, hardly accomplishes all processing after realizing clamping basically, hardly satisfies the problem of the actual demand of high accuracy mould, provides a high accuracy mould machining center.

In order to solve the technical problem, the utility model provides a following technical scheme:

the utility model relates to a high-precision mold machining center, which comprises a base, a first driving motor is fixedly connected on the side wall of one side of the base, the output end of the first driving motor is fixedly connected with a first bevel gear through a coupler, two symmetrical fixed plates are fixedly connected at two corresponding edges of the upper surface of the base, two symmetrical clamping blocks are fixedly connected on the upper surface of the fixed plates, a first lead screw is rotatably connected between the two clamping blocks through a first bearing, one end of the first lead screw penetrates through the corresponding clamping block and extends outwards, a second bevel gear is fixedly connected, the first bevel gear is rotatably connected with a second bevel gear through a transmission device, a first lead screw nut matched with the first lead screw is sleeved on the rod wall of the first lead screw between the two clamping blocks, a sliding block is sleeved on the outer fixed part of the first lead screw nut, the upper surfaces of the two fixed plates corresponding to the position of the sliding block are provided with sliding grooves, the lower ends of the sliding blocks are connected in the sliding grooves in a sliding manner, the upper ends of the two sliding blocks are fixedly connected with clamping blocks, a second screw rod is rotatably connected between the two clamping blocks through a second bearing, the upper surface of one clamping block is fixedly connected with a second driving motor, the output end of the second driving motor is fixedly connected with a driving gear through a coupler, one end of the second screw rod penetrates through the corresponding clamping block and extends outwards, and is fixedly connected with a driven gear meshed with the driving gear, a second screw rod nut matched with the second screw rod is sleeved on the rod wall of the second screw rod between the two clamping blocks, a sliding block is fixedly sleeved outside the second screw rod nut, and a fixed rod is fixedly connected on two corresponding side walls at the position below the second screw rod between the two clamping blocks, the sliding block is sleeved on the rod wall of the fixed rod between the two clamping blocks, and the lower end of the sliding block is fixedly connected with a swinging cutter.

As a preferred technical proposal of the utility model, the transmission device comprises two symmetrical first fixed blocks, the two first fixed blocks are symmetrically and fixedly connected on the side wall of one side of the base, a first rotating rod is rotatably connected between the two first fixed blocks through a third bearing, two ends of the first rotating rod penetrate through the corresponding first fixed blocks and extend outwards, and a third bevel gear is fixedly sleeved and connected, one end of the first rotating rod penetrates through the corresponding third bevel gear and extends outwards, and is fixedly sleeved with a fourth bevel gear meshed with the first bevel gear, the side walls of one side of the two fixed plates are fixedly connected with second fixed blocks, the second fixed block is rotatably connected with a second rotating rod through a fourth bearing, two ends of the second rotating rod penetrate through the second fixed block and extend towards the two ends, and the two ends of the connecting rod are fixedly connected with a fifth bevel gear meshed with the second bevel gear and the third bevel gear respectively.

As a preferred technical scheme of the utility model, the sliding block is located two symmetrical stoppers of one end fixedly connected with of sliding tray, two rotate through first pivot between the stopper and be connected with the runner.

As an optimal technical scheme of the utility model, the equal fixedly connected with support column in four corners department of base lower surface.

As a preferred technical scheme of the utility model, the lower extreme of support column is rotated through the second pivot and is connected with the support, the support is rotated through the third pivot and is connected with the wheel.

The utility model discloses the beneficial effect who reaches is: the utility model relates to a high accuracy mould machining center adds man-hour to the part when using machining center, and at the in-process of work, real-time first driving motor and second driving motor are removed to open according to the required angle of parts machining, and real-time position to the slider is adjusted for the swing cutter can reach its required position, carries out the processing of high accuracy, accomplishes all processings behind the disposable clamping, satisfies the actual demand of high accuracy mould.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a schematic structural diagram of the present invention;

fig. 3 is an enlarged view of a portion a in fig. 1.

In the figure: 1. a base; 2. a first drive motor; 3. a first bevel gear; 4. a fixing plate; 5. a clamping block; 6. a first lead screw; 7. a second bevel gear; 8. a transmission device; 9. a first lead screw nut; 10. a slider; 11. a sliding groove; 12. a clamping block; 13. a second lead screw; 14. a second drive motor; 15. a driving gear; 16. a driven gear; 17. a second feed screw nut; 18. a slider; 19. fixing the rod; 20. a first fixed block; 21. a first rotating lever; 22. a third bevel gear; 23. a fourth bevel gear; 24. a second fixed block; 25. a second rotating lever; 26. a fifth bevel gear; 27. a limiting block; 28. a rotating wheel; 29. a support pillar; 30. a support; 31. a wheel; 32. and (5) swinging the cutter.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are presented herein only to illustrate and explain the present invention, and not to limit the present invention.

Examples

As shown in fig. 1-3, the utility model provides a high precision mold machining center, which comprises a base 1, a first driving motor 2 is fixedly connected on the side wall of one side of the base 1, the output end of the first driving motor 2 is fixedly connected with a first bevel gear 3 through a shaft coupling, two symmetrical fixed plates 4 are fixedly connected at two corresponding edges of the upper surface of the base 1, two symmetrical clamping blocks 5 are fixedly connected on the upper surface of the fixed plate 4, a first lead screw 6 is rotatably connected between the two clamping blocks 5 through a first bearing, one end of the first lead screw 6 penetrates through the corresponding clamping block 5 and extends outwards, a second bevel gear 7 is fixedly connected, the first bevel gear 3 is rotatably connected with the second bevel gear 7 through a transmission device 8, a first lead screw nut 9 matched with the first lead screw is sleeved on the rod wall of the first lead screw 6 between the two clamping blocks 5, a sliding block 10 is fixedly sleeved outside the first screw nut 9, a sliding groove 11 is arranged on the upper surface of the two fixing plates 4 corresponding to the position of the sliding block 10, the lower end of the sliding block 10 is connected in the sliding groove 11 in a sliding manner, the upper ends of the two sliding blocks 10 are fixedly connected with clamping blocks 12, a second screw 13 is rotatably connected between the two clamping blocks 12 through a second bearing, the upper surface of one clamping block 12 is fixedly connected with a second driving motor 14, the output end of the second driving motor 14 is fixedly connected with a driving gear 15 through a coupler, one end of the second screw 13 penetrates through the corresponding clamping block 12 and extends outwards, and is fixedly connected with a driven gear 16 engaged with the driving gear 15, a second screw nut 17 matched with the second screw nut is sleeved on the rod wall of the second screw 13 between the two clamping blocks 12, a sliding block 18 is fixedly sleeved outside the second screw nut 17, and a fixing rod 19 is fixedly connected on two corresponding side walls at the position below the second screw 13 between the, the sliding block 18 is sleeved on the rod wall of the fixed rod 19 between the two clamping blocks 12, and the lower end of the sliding block 18 is fixedly connected with a swinging cutter 32.

The transmission device 8 comprises two symmetrical first fixed blocks 20, the two symmetrical first fixed blocks 20 are fixedly connected to the side wall of one side of the base 1, a first rotating rod 21 is rotatably connected between the two first fixed blocks 20 through a third bearing, two ends of the first rotating rod 21 penetrate through the corresponding first fixed blocks 20 and extend outwards, and are fixedly sleeved with a third bevel gear 22, one end of the first rotating rod 21 penetrates through the corresponding third bevel gear 22 and extends outwards, and is fixedly sleeved with a fourth bevel gear 23 engaged with the first bevel gear 3, the side wall of one side of the two fixed plates 4 is fixedly connected with a second fixed block 24, the second fixed block 24 is rotatably connected with a second rotating rod 25 through a fourth bearing, two ends of the second rotating rod 25 penetrate through the second fixed blocks 24 and extend towards two ends, and two ends are respectively and fixedly connected with a fifth bevel gear 26 engaged with the second bevel gear 7 and the third bevel gear 22, the rotation of the first bevel gear 3 is transmitted to the two second bevel gears 7, so that the two sliding blocks 10 keep advancing or retreating synchronously.

The one end fixedly connected with two symmetrical stopper 27 of sliding block 10 in sliding tray 11, rotate through first pivot between two stopper 27 and be connected with runner 28, supplementary sliding block 10's slip reduces its resistance.

The equal fixedly connected with support column 29 in four corners department of base 1 lower surface supports base 1.

The lower extreme of support column 29 is rotated through the second pivot and is connected with support 30, and support 30 rotates through the third pivot and is connected with wheel 31, and supplementary machining center removes.

Specifically, when the utility model is used, according to the position of the part, the first driving motor 2 is started in real time, the first driving motor 2 drives the second bevel gear 7 to rotate through the transmission device 8, the second bevel gear 7 drives the first lead screw 6 to rotate, through the matching of the first lead screw 6 and the first lead screw nut 9, the two sliding blocks 10 advance or retreat and drive the swing cutter 32 in the center to advance or retreat, meanwhile, the second driving motor 14 is started in real time according to the position of the part, the second driving motor 14 drives the second lead screw 13 to rotate through the matching of the driving gear 15 and the driven gear 16, through the matching of the second lead screw 13 and the second lead screw nut 17, the sliding block 18 can move to both sides and drive the swing cutter 32 in the center to do synchronous motion, so that the swing cutter 32 can reach the required position, and high-precision processing is carried out, all processing is finished after one-time clamping, and the actual requirements of the high-precision die are met.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (5)

1. A high-precision mold machining center comprises a base (1) and is characterized in that a first driving motor (2) is fixedly connected to the side wall of one side of the base (1), the output end of the first driving motor (2) is fixedly connected with a first bevel gear (3) through a coupler, two symmetrical fixing plates (4) are fixedly connected to two corresponding edges of the upper surface of the base (1), two symmetrical clamping blocks (5) are fixedly connected to the upper surface of the fixing plates (4), a first lead screw (6) is rotatably connected between the two clamping blocks (5) through a first bearing, one end of the first lead screw (6) penetrates through the corresponding clamping block (5) and extends outwards, a second bevel gear (7) is fixedly connected to the first bevel gear (3), and a second bevel gear (7) is rotatably connected to the first bevel gear (3) through a transmission device (8), a first screw rod nut (9) matched with the first screw rod (6) is sleeved on the rod wall of the first screw rod (6) between the two clamping blocks (5), a sliding block (10) is fixedly sleeved outside the first screw rod nut (9), a sliding groove (11) is formed in the upper surface of the two fixing plates (4) corresponding to the position of the sliding block (10), the lower end of the sliding block (10) is connected in the sliding groove (11) in a sliding manner, clamping blocks (12) are fixedly connected to the upper ends of the two sliding blocks (10), a second screw rod (13) is rotatably connected between the two clamping blocks (12) through a second bearing, a second driving motor (14) is fixedly connected to the upper surface of one clamping block (12), the output end of the second driving motor (14) is fixedly connected with a driving gear (15) through a coupler, one end of the second screw rod (13) penetrates through the corresponding clamping block (12) and extends outwards, and fixedly connected with and driving gear (15) engaged with driven gear (16), be located two cup joint rather than assorted second screw-nut (17) on the pole wall of second lead screw (13) between fixture block (12), second screw-nut (17) external fixation cover has connect slider (18), is located two fixedly connected with a dead lever (19) on two corresponding lateral walls of second lead screw (13) below position between fixture block (12), slider (18) cup joint on dead lever (19) are located the pole wall between two fixture blocks (12), the lower extreme fixedly connected with swing cutter (32) of slider (18).

2. The high-precision mold machining center according to claim 1, wherein the transmission device (8) comprises two symmetrical first fixed blocks (20), the two symmetrical first fixed blocks (20) are fixedly connected to the side wall of one side of the base (1), a first rotating rod (21) is rotatably connected between the two first fixed blocks (20) through a third bearing, two ends of the first rotating rod (21) penetrate through the corresponding first fixed blocks (20) and extend outwards, a third bevel gear (22) is fixedly sleeved on the first rotating rod, one end of the first rotating rod (21) penetrates through the corresponding third bevel gear (22) and extends outwards, a fourth bevel gear (23) meshed with the first bevel gear (3) is fixedly sleeved on the first rotating rod, and a second fixed block (24) is fixedly connected to the side wall of one side of the two fixed plates (4), the second fixed block (24) is connected with a second rotating rod (25) through a fourth bearing in a rotating mode, the two ends of the second rotating rod (25) penetrate through the second fixed block (24) and extend towards the two ends, and the two ends of the second rotating rod are respectively fixedly connected with a fifth bevel gear (26) meshed with the second bevel gear (7) and the third bevel gear (22).

3. A high precision mold processing center according to claim 1, wherein two symmetrical limit blocks (27) are fixedly connected to one end of the sliding block (10) located in the sliding groove (11), and a rotating wheel (28) is rotatably connected between the two limit blocks (27) through a first rotating shaft.

4. A high precision mold processing center according to claim 1, characterized in that a support column (29) is fixedly connected to each of four corners of the lower surface of the base (1).

5. A high accuracy mould machining center according to claim 4, characterized in that, the lower end of the support column (29) is rotatably connected with a bracket (30) through a second rotating shaft, and the bracket (30) is rotatably connected with a wheel (31) through a third rotating shaft.

Images