CN217776227U - Machining equipment capable of effectively reducing machining vibration - Google Patents

Abstract

The utility model provides a can effectively reduce processing equipment of processing vibrations. The machining process solves the problem that when the cutting force changes in the existing machining process, the machining effect is greatly influenced due to the fact that the change caused by the gap and the elastic deformation is vibration. The utility model discloses when cutting the work piece, adjust the position of cutter through cutting the first screw rod of power direction vertically with work piece owner, remove to the work piece direction through the first wedge of second wedge drive, make the direction of first screw rod perpendicular with the direction of main cutting power, can not cut the power conflict with main when adjusting second wedge position, can comparatively relax adjusts.

Description

Machining equipment capable of effectively reducing machining vibration

Technical Field

The utility model relates to a lathe technical field, in particular to can effectively reduce processing equipment of processing vibrations.

Background

The guide rail moves to drive the cutter and the workpiece to move relatively to process the workpiece, the guide rail has gaps due to manufacturing and assembling, when the guide rail is stressed, the related gaps can be compressed, when the cutting force is increased, the guide rail can generate elastic deformation, when the cutting force is changed, the machining effect is greatly influenced due to the fact that the change caused by the gaps and the elastic deformation is vibration, and the prior art has the improved part.

Disclosure of Invention

The utility model provides a processing device which can effectively reduce processing vibration aiming at the existing situation;

the machining equipment capable of effectively reducing machining vibration comprises a machine tool, a workpiece and a cutter, wherein the workpiece is movably arranged on the machine tool, the cutter is used for cutting the workpiece, a first driving mechanism used for driving the cutter and the workpiece to be close to each other is movably arranged on the machine tool, the cutter exerts main cutting force on the workpiece, the direction of the main cutting force is the first direction, the first driving mechanism can drive the cutter or the workpiece to move along the first direction, the first driving mechanism comprises a first wedge-shaped block and a second wedge-shaped block, a first inclined surface and a second inclined surface which are attached to each other are respectively arranged on the first wedge-shaped block and the second wedge-shaped block, the first inclined surface and the second inclined surface are intersected with and not perpendicular to the first direction, a first screw rod driving the second wedge-shaped block to move is movably arranged on the second wedge-shaped block through threaded connection, the first screw rod penetrates through the second wedge-shaped block, the length direction of the first screw rod is perpendicular to the first direction, a first motor used for driving the first screw rod to rotate is arranged at one end of the first screw rod, the second screw rod can drive the first screw rod to move along the length direction of the first wedge-shaped block, and the first wedge-shaped block or the second wedge-shaped block can drive the cutter to move along the lower direction of the workpiece, and the first wedge-shaped block can move along the length direction of the first wedge-shaped block.

Preferably, the machine tool is provided with a second driving mechanism for driving the first driving mechanism to move, and the first driving mechanism is driven by the second driving mechanism to move along the longitudinal direction of the first screw, and the moving direction of the first driving mechanism is perpendicular to the first direction.

Preferably, a fixing member for pressing the first wedge against the second wedge is disposed on the first wedge, a cross beam is fixedly disposed at one end of the fixing member away from the second wedge, an extruding mechanism is disposed on the cross beam, the second driving mechanism includes a first bottom plate disposed below the first wedge and the second wedge, two first guide rails extending along the first direction are fixedly disposed on the first bottom plate, a first sliding groove extending along the first direction is formed in the first wedge, the first guide rail is inserted into the first sliding groove, a fixing plate is disposed on the first bottom plate, two second guide rails are fixedly disposed on the fixing plate, the length direction of the second guide rails is parallel to the length direction of the first screw, a second sliding groove is formed in the first bottom plate, the second guide rail is inserted into the second sliding groove, a second screw rod for driving the first bottom plate to move along the length direction of the second guide rail is movably disposed on the first bottom plate through a threaded connection, a second screw rod for driving the second screw rod to rotate is disposed on the fixing plate, a second fixing top plate is disposed on one side of the fixing plate, and a side of the fixing plate away from the second wedge is disposed on the fixing plate.

Preferably, a plurality of needle rollers are movably arranged on the first inclined surface, the needle rollers are fully distributed on the first inclined surface, and the second inclined surface on the second wedge-shaped block is attached to the plurality of needle rollers.

Preferably, the workpiece is movably arranged on the machine tool, the tool is fixedly arranged on a first wedge-shaped block, the first wedge-shaped block and a second wedge-shaped block are located on the same plane, and a mounting plate extending in the vertical direction is fixedly arranged on one side, away from the workpiece, of the fixing plate.

Preferably, the fixing plate is disposed on a side wall of the first base plate on a side away from the workpiece, the fixing plate extends in a vertical direction, and the second guide rail is fixedly disposed on an end surface of the fixing plate on a side facing the first base plate.

Preferably, the tool is disposed on a machine tool, the workpiece is movably disposed on a first wedge block, a second wedge block is located below the first wedge block, a third driving mechanism for driving the first driving mechanism and the second driving mechanism to move is disposed on the machine tool, the third driving mechanism includes a supporting plate disposed below a fixing plate, two third guide rails are fixedly disposed on the supporting plate, a length direction of the third guide rails is perpendicular to a length direction of the second screw rod, a third screw rod for driving the fixing plate to move in a horizontal direction is disposed on the supporting plate, a length direction of the third screw rod is parallel to the length direction of the third guide rails, a plane where the third screw rod is located is parallel to a plane where the second screw rod is located, and a third motor for driving the third screw rod to rotate is disposed on the supporting plate.

Preferably, the extrusion mechanism comprises a first force application assembly fixedly arranged on the beam and used for applying a pulling force to the first wedge block to enable the first wedge block to be pressed against the second wedge block all the time, and the first force application assembly is fixedly connected with a first sliding assembly; first slip subassembly includes the mount pad, the mount pad include with first application of force subassembly fixed connection's second bottom plate, the equal vertical riser that is provided with in second bottom plate both sides, two it is connected with the pivot to rotate between the riser, the external fixation cover of pivot is equipped with the gyro wheel.

Preferably, the first force application assembly comprises a first sleeve vertically arranged on the cross beam, a first compression spring is sleeved outside the first sleeve, the height of the first compression spring is greater than that of the first sleeve, and the top end of the first compression spring is fixedly connected with the first sliding assembly; a first sliding rod is inserted in the first sleeve in a sliding mode, the outer diameter of the first sliding rod is matched with the inner diameter of the first sleeve, and the top end of the first sliding rod is fixedly connected with the first sliding assembly.

Preferably, the first force application assembly is a first air cylinder, the first air cylinder is arranged on the cross beam, and a piston rod of the first air cylinder is fixedly connected with the first sliding assembly.

Preferably, the extrusion mechanism is including seting up in on the steady piece and link up the mounting groove of steady piece, the bottom of mounting groove is provided with and is used for applying the second application of force subassembly that pulling force made first wedge press on the second wedge all the time to first wedge, second application of force subassembly fixedly connected with second slip subassembly, second slip subassembly including wear to locate perpendicularly in the mounting groove and with mounting groove sliding fit's connecting rod, the both ends of connecting rod all are provided with sliding fit's bearing.

Preferably, the second force application assembly comprises a second sleeve arranged at the bottom of the mounting groove, a second compression spring is sleeved outside the second sleeve, the height of the second compression spring is greater than that of the second sleeve, and the top end of the second compression spring is fixedly connected with the second sliding assembly; and a second slide bar is inserted in the second sleeve in a sliding manner, the inner diameter of the second slide bar is matched with that of the second sleeve, and the top end of the second slide bar is fixedly connected with a second sliding assembly.

Preferably, the second force application assembly is a second air cylinder, the second air cylinder is arranged at the bottom of the mounting groove, and a piston rod of the second air cylinder is fixedly connected with the second sliding assembly.

Compared with the prior art, the utility model discloses following beneficial effect has: when a workpiece is cut, the position of the cutter is adjusted through the first screw rod perpendicular to the main cutting force direction of the workpiece, the first wedge block is driven to move towards the workpiece through the second wedge block, the direction of the first screw rod is perpendicular to the main cutting force direction, the position of the second wedge block cannot conflict with the main cutting force when being adjusted, and the adjustment can be carried out easily.

Drawings

FIG. 1 is an overall structural view of embodiment 1;

FIG. 2 is a schematic structural view of the right side of embodiment 1;

FIG. 3 is a schematic view of the structure of embodiment 7;

FIG. 4 is a schematic structural view of example 8;

FIG. 5 is a schematic structural view of an extruding mechanism in embodiment 1;

FIG. 6 is a schematic view of the structure of an extruding mechanism in embodiment 2;

FIG. 7 is a schematic view of a structure of an extruding mechanism in embodiment 3

FIG. 8 is a schematic view of a structure of an extruding mechanism in embodiment 4;

FIG. 9 is a schematic view of the structure of an extrusion mechanism in embodiment 5;

fig. 10 is a schematic structural view of an extrusion mechanism in embodiment 6.

The labels in the figure are: 1. a workpiece; 2. a cutter; 3. a first drive mechanism; 4. a first wedge block; 5. a second wedge block; 6. a first inclined plane; 7. a second inclined plane; 8. a first screw; 9. a first motor; 10. a second drive mechanism; 11. a first base plate; 12. a first guide rail; 13. a first chute; 14. a fixing plate; 15. a second guide rail; 16. a second chute; 17. a second screw; 18. a second motor; 19. rolling needles; 20. mounting a plate; 21. A third drive mechanism; 22. a support plate; 23. a third guide rail; 24. a third screw; 25. a third motor; 26. a stabilizing member; 27. a cross beam; 61. a first sleeve; 62. a first slide bar; 28. a first compression spring; 81. A second base plate; 82. a vertical plate; 29. a rotating shaft; 30. a roller; 31. a first cylinder; 32. a magnetic block; 33. a magnetic strip; 34. mounting grooves; 151. a second sleeve; 152. a second slide bar; 35. a second compression spring; 36. a second cylinder; 37. a connecting rod; 38. a bearing; 39. an extrusion mechanism; 40. a top plate.

Detailed Description

The invention will be further described with reference to the embodiments shown in the drawings to which:

example 1

As shown in fig. 1-2 and fig. 5, a machining apparatus capable of effectively reducing machining vibrations includes a machine tool, a workpiece 1 movably disposed on the machine tool, and a tool 2 cutting the workpiece 1, wherein the machine tool is movably provided with a first driving mechanism 3 for driving the tool 2 and the workpiece 1 to approach each other, the tool 2 applies a main cutting force to the workpiece 1, the main cutting force has a first direction, the first driving mechanism 3 can drive the tool 2 and the workpiece 1 to move along the first direction, the first driving mechanism 3 includes a first wedge block 4 and a second wedge block 5, the first wedge block 4 and the second wedge block 5 are respectively provided with a first inclined surface 6 and a second inclined surface 7 attached to each other, the first inclined surface 6 and the second inclined surface 7 intersect with the first direction and are not perpendicular to the first direction, the second wedge block 5 is movably provided with a first screw rod 8 for driving the second wedge block 5 to move through a threaded connection, the first screw rod 8 penetrates through the second wedge block 5, the first screw rod 8 drives the first wedge block 8 to move along a length direction of the first screw rod 8, and the first screw rod 8 is disposed on the second wedge block 5 and is capable of driving the first screw rod 8 to move along a direction perpendicular to the first direction or to the first direction of the first screw rod 9, and the first screw rod 8, the first screw rod 8 is disposed below the first screw rod for driving the first wedge block 5, and the first screw rod 8 is disposed below the first screw rod for driving the first wedge block 5. The machine tool is provided with a second driving mechanism 10 for driving the first driving mechanism 3 to move, the first driving mechanism 3 can move along the length direction of the first screw 8 under the driving of the second driving mechanism 10, the moving direction is perpendicular to the first direction, the first wedge block 4 is provided with a fixing member 26 for pressing the first wedge block 4 against the second wedge block 5, one end of the fixing member 26, which is far away from the second wedge block 5, is fixedly provided with a cross beam 27, the cross beam 27 is provided with an extrusion mechanism 39, when the workpiece 1 is cut, the position of the cutter 2 is adjusted through the first screw 8, which is perpendicular to the main cutting force direction of the workpiece 1, the first wedge block 4 is driven to move towards the workpiece 1 through the second wedge block 5, the direction of the first screw 8 is perpendicular to the main cutting force direction, when the position of the second wedge block 5 is adjusted, the cutter can be adjusted easily, the fixing plate 11 is fixedly provided with a top plate 40, one side of the second wedge block 5, which is far away from the first screw 8, is perpendicular to the main cutting force, the second wedge block 5 does not collide with the main cutting force when the position of the second wedge block 5, the top plate 40 is pressed against the bottom plate 40, and the first wedge block 5, and the second wedge block 5 presses the first wedge block 5 against the bottom plate, and supports the first wedge block 5 against the bottom plate 40.

The second driving mechanism 10 includes a first bottom plate 11 disposed below the first wedge-shaped block 4 and the second wedge-shaped block 5, two first guide rails 12 extending along the first direction are fixedly disposed on the first bottom plate 11, a first sliding groove 13 extending along the first direction is disposed on the first wedge-shaped block 4, the first guide rail 12 is inserted into the first sliding groove 13, a fixing plate 14 is disposed on the first bottom plate 11, two second guide rails 15 are fixedly disposed on the fixing plate 14, a length direction of the second guide rail 15 is parallel to a length direction of the first screw 8, a second sliding groove 16 is disposed on the first bottom plate 11, the second guide rail 15 is inserted into the allowing sliding groove, a second screw 17 driving the first bottom plate 11 to move along the length direction of the second guide rail 15 is movably disposed on the first bottom plate 11 through a threaded connection, and a second motor 18 for driving the second screw 17 to rotate is disposed on the fixing plate 14. The transverse displacement of the tool 2 is effected by means of the second drive 10.

The first inclined surface 6 is movably provided with a plurality of roller pins 19, the roller pins 19 are fully distributed on the first inclined surface 6, and the second inclined surface 7 on the second wedge-shaped block 5 is abutted on the plurality of roller pins 19. The workpiece 1 is movably arranged on a machine tool, the cutter 2 is fixedly arranged on a first wedge-shaped block 4, the first wedge-shaped block 4 and a second wedge-shaped block 5 are located on the same plane, and one side, far away from the workpiece 1, of the fixing plate 14 is fixedly provided with an installation plate 20 extending along the vertical direction. The entire apparatus is mounted on the side wall in the vertical direction by the mounting plate 20, and the entire resistance when the tool cuts is supported.

The two ends of the steady member 26 are respectively arranged on the first wedge-shaped block 4 and the mounting plate 20, the extrusion mechanism 39 comprises a first force application component which is fixedly arranged on the cross beam 27 and is used for applying a pulling force to the first wedge-shaped block 4 so as to enable the first wedge-shaped block 4 to be always pressed on the second wedge-shaped block 5, and the first force application component is fixedly connected with a first sliding component; first slip subassembly includes the mount pad, the mount pad include with first application of force subassembly fixed connection's second bottom plate 81, the equal vertical riser 82 that is provided with in second bottom plate 81 both sides, two it is connected with pivot 29 to rotate between the riser 82, the outside fixed cover of pivot 29 is equipped with gyro wheel 30, paste through gyro wheel 30 and lean on mounting panel 20 and press first wedge 4 on second wedge 5 all the time, make the inseparable joint of first wedge 4 on first guide rail 12, and provide a pretightning force that sets up with above-mentioned first direction is relative to the guide rail of installing on first wedge 4, the guide rail has certain resistance when the cutting, the deformation volume of guide rail reduces along with the increase of resistance gradually, through the pretightning force that provides, make the resistance of guide rail be in a great value all the time, the fluctuation range of guide rail deformation volume is less, the vibrations that the guide rail produced are littleer in the course of working, the plane after the processing is more smooth, and through setting up the firm piece 26 on first wedge 4 and mounting panel 20 respectively, make first wedge 4, second wedge 5, roof 40, first wedge 11, first mounting panel 14 compress tightly upwards at first fixing plate 20.

Example 2

The difference from the embodiment 1 is that: as shown in fig. 1-2 and fig. 6, the first force application assembly has a specific structure of the first cylinder 31, that is, the first cylinder 31 is disposed on the cross beam 27, a piston rod of the first cylinder 31 is fixedly connected to the mounting seat of the first sliding assembly, and specifically, the piston rod of the first cylinder 31 is fixedly connected to the second bottom plate 81 of the mounting seat. During machining, the cross beam 27 is pulled in a direction away from the first wedge block 4 by the first cylinder 31.

Example 3

The difference from the embodiment 1 is that: as shown in fig. 1-2 and 7, stabilizing member 26 is provided with: stabilizing members 26 are two in number, two stabilizing members 26 are vertically disposed on both sides of first wedge block 4 and extend to mounting plate 20, and stabilizing members 26 move along with first wedge block 4.

Example 4

The difference from the embodiment 3 is that: as shown in fig. 1-2 and fig. 8, the first force application assembly is specifically configured as a first air cylinder 31, that is, the first air cylinder 31 is disposed on the cross beam 27, a piston rod of the first air cylinder 31 is fixedly connected with the mounting seat of the first sliding assembly, specifically, the piston rod of the first air cylinder 31 is fixedly connected with a second bottom plate 81 of the mounting seat, and a pulling force in a direction away from the first wedge block 4 is applied to the cross beam 27 through the first air cylinder.

Example 5

The difference from example 1 is that: as shown in fig. 1-2 and 9, a mounting groove 34 penetrating through the steady member 26 is formed in the steady member 26 in a direction perpendicular to the steady member 26, a second force application assembly for applying a downward pulling force to the mounting plate 20 to make the first wedge block 4 always abut against the second wedge block 5 is arranged at the bottom of the mounting groove 34, the second force application assembly includes a second sleeve 151 arranged at the bottom of the mounting groove 34, a second compression spring 35 is sleeved outside the second sleeve 151, the height of the second compression spring 35 is greater than that of the second sleeve 151, a second sliding assembly in sliding fit with the bottom surface of the mounting plate 20 is fixedly connected to the top end of the second compression spring 35, a second slide bar 152 is slidably inserted into the second sleeve 151, the outer diameter of the second slide bar 152 is adapted to the inner diameter of the second sleeve 151, and the top end of the second slide bar 152 is fixedly connected to the second sliding assembly. The arrangement of the second sleeve 151 and the second sliding rod 152 can facilitate the second compression spring 35 to perform a telescopic motion, and can improve the stability of the sliding fit between the second sliding component and the bottom of the mounting plate 20. The second sliding assembly has the specific structure that: the second sliding component comprises a connecting rod 37 vertically penetrating through the mounting groove 34 and sliding-fit with the mounting groove 34, and bearings 38 contacting and sliding-fit with the bottom surface of the mounting plate 20 are arranged at two ends of the connecting rod 37.

Example 6

The difference from example 5 is that: as shown in fig. 1-2 and 10, the second force application component is a second cylinder 36, the second cylinder 36 is disposed at the bottom of the mounting groove 34, a piston rod of the second cylinder 36 is fixedly connected with the second sliding component, and specifically, the piston rod of the second cylinder 36 is fixedly connected with a connecting rod 37 of the second sliding component.

Example 7

The difference from embodiment 1 is that, as shown in fig. 3, the fixing plate 14 is provided on the side wall of the first bottom plate 11 on the side away from the workpiece 1, the fixing plate 14 extends in the vertical direction, and the second guide rail 15 is fixedly provided on the end surface of the fixing plate 14 on the side facing the first bottom plate 11. By arranging the second guide rail 15 on the vertical fixing plate 14 for counteracting the resistance generated when cutting the workpiece 1, the two ends of the steady member 26 are respectively arranged on the first wedge block 4 and the fixing plate 14, and the pressing mechanism 39 is as described in the above embodiments 1-6.

Example 8

The difference from embodiment 1 is that, as shown in fig. 4, the tool 2 is provided on a machine tool, the workpiece 1 is mounted on a first wedge-shaped block 4, the second wedge-shaped block 5 is located below the first wedge-shaped block 4, a third driving mechanism for driving the first driving mechanism 3 and the second driving mechanism 10 to move is provided on the machine tool, the third driving mechanism includes a support plate 22 provided below a fixing plate 14, two third guide rails 23 are fixedly provided on the support plate 22, a length direction of the third guide rails 23 is perpendicular to a length direction of the second screw 17, a third screw 24 for driving the fixing plate 14 to move in a horizontal direction is provided on the support plate 22, a length direction of the third screw 24 is parallel to the length direction of the third guide rails 23, a plane of the third screw 24 is parallel to a plane where the second screw 17 is located, and a third motor 25 for driving the third screw 24 to rotate is provided on the support plate 22. The steady member 26, the cross member 27 and the pressing mechanism 39 disposed on the cross member 27 are provided in two sets, respectively disposed between the first wedge block 4 and the fixing plate 14 and between the fixing plate 14 and the mounting plate 20, the two sets are not located on the same plane and the moving paths of the two sets are perpendicular to each other, and the pressing mechanism 39 is as described in the above embodiments 1 to 6.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications or additions may be made to the described embodiments or alternatives may be employed by those skilled in the art without departing from the spirit or ambit of the invention as defined in the appended claims.

Claims (7)

1. A machining device capable of effectively reducing machining vibration comprises a machine tool, a workpiece (1) movably arranged on the machine tool and a cutter (2) for cutting the workpiece (1), and is characterized in that a first driving mechanism (3) for driving the cutter (2) and the workpiece (1) to be close to each other is movably arranged in the machine tool, the cutter (2) applies a main cutting force to the workpiece (1), the direction of the main cutting force is a first direction, the first driving mechanism (3) can drive the cutter (2) or the workpiece (1) to move along the first direction, the first driving mechanism (3) comprises a first wedge block (4) and a second wedge block (5), a first inclined surface (6) and a second inclined surface (7) which are attached to each other are respectively arranged on the first wedge block (4) and the second wedge block (5), the first inclined surface (6) and the second inclined surface (7) are intersected with the first direction and not perpendicular to the first direction, a first screw (8) for driving a first screw (5) to move is movably connected with a second wedge block (5) through a screw (8), and a first screw (8) is arranged on the second wedge block (5) and used for driving a first screw (8) to rotate towards the first screw (8) and be perpendicular to the first screw (8), the second wedge block (5) can move along the length direction of the first screw rod (8) under the driving of the first screw rod (8), the cutter or the workpiece is arranged on the first wedge block (4), and the first wedge block (4) can move along the first direction under the driving of the second wedge block (5).

2. A processing apparatus capable of effectively reducing processing vibration according to claim 1, wherein the machine tool is provided with a second driving mechanism (10) for driving the first driving mechanism (3) to move, the first driving mechanism (3) can move along the length direction of the first screw (8) under the driving of the second driving mechanism (10), and the moving direction is perpendicular to the first direction.

3. The processing apparatus capable of effectively reducing processing vibration according to claim 2, wherein the second driving mechanism (10) comprises a first bottom plate (11) disposed below the first wedge-shaped block (4) and the second wedge-shaped block (5), the first bottom plate (11) is fixedly provided with two first guide rails (12) extending along the first direction, the first wedge-shaped block (4) is provided with a first sliding slot (13) extending along the first direction, the first guide rails (12) are inserted into the first sliding slot (13), the first bottom plate (11) is provided with a fixing plate (14), the fixing plate (14) is fixedly provided with two second guide rails (15), the length direction of the second guide rail (15) is parallel to the length direction of the first screw (8), a second sliding groove (16) is formed in the first bottom plate (11), the second guide rail (15) is inserted into the allowing sliding groove, a second screw (17) which drives the first bottom plate (11) to move along the length direction of the second guide rail (15) is movably arranged on the first bottom plate (11) through threaded connection, a second motor (18) which is used for driving the second screw (17) to rotate is arranged on the fixing plate (14), a top plate (40) is fixedly arranged on the fixing plate, and the end face, far away from one side of the first wedge block (4), of the second wedge block (5) is attached to the top plate (4) 40).

4. A machining apparatus effective for reducing machining vibrations according to claim 3, characterized in that a plurality of needles (19) are movably arranged on said first inclined surface (6), said needles (19) are distributed over said first inclined surface (6), and said second inclined surface (7) of said second wedge block (5) abuts against said plurality of needles (19).

5. A machining apparatus for reducing machining vibrations effectively as claimed in claim 4, characterized in that said workpiece (1) is movably mounted on a machine tool, said tool (2) is fixedly mounted on a first wedge (4), said first wedge (4) and said second wedge (5) are located on the same plane, and a mounting plate (20) extending in a vertical direction is fixedly mounted on a side of said mounting plate (14) remote from said workpiece (1).

6. A processing apparatus capable of effectively reducing processing vibration according to claim 5, wherein the fixing plate (14) is provided on a side wall of the first base plate (11) on a side away from the workpiece (1), the fixing plate (14) extends in a vertical direction, and the second guide rail (15) is fixedly provided on an end surface of the fixing plate (14) on a side facing the first base plate (11).

7. A processing apparatus capable of effectively reducing processing vibration according to claim 4, wherein the tool (2) is disposed on a machine tool, the workpiece (1) is movably disposed on a first wedge block (4), the second wedge block (5) is disposed below the first wedge block (4), a third driving mechanism for driving the first driving mechanism (3) and the second driving mechanism (10) to move is disposed in the machine tool, the third driving mechanism comprises a supporting plate (22) disposed below a fixing plate (14), two third guide rails (23) are fixedly disposed on the supporting plate (22), the length direction of the third guide rails (23) is perpendicular to the length direction of the second screw (17), a third screw (24) for driving the fixing plate (14) to move in the horizontal direction is disposed on the supporting plate (22), the length direction of the third screw (24) is parallel to the length direction of the third guide rails (23), and the plane where the third screw (24) is disposed is parallel to the plane where the second screw (17) is disposed, and a third motor (25) for driving the third screw (24) to rotate is disposed on the supporting plate (22).

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