CN216731008U - Device for removing burrs after cutting of rotor dynamic balancing machine - Google Patents

Abstract

The utility model discloses a device for removing burrs of a rotor dynamic balancing machine after cutting. The workpiece is placed on the main body supporting structure, the burr removing structure is installed on two sides of the main body supporting structure, the workpiece rotation driving structure is further installed on one side of the main body supporting structure and drives the workpiece to rotate, the burr removing structure performs burr removing on the rotor in a rotation state, and the part of the burr collecting structure is located below the main body supporting structure and used for receiving burrs of the workpiece after cutting. According to the utility model, the rotor is fixed, and after the rotor is driven to rotate, the contact brush is used for removing cutting burrs or cutting chips, so that the rotor is effectively prevented from falling out during chip removal, the chip removal efficiency is improved, the splashing of waste chips is reduced, the stability and the reliability are realized, and the automation is realized.

Description

Device for removing burrs after cutting of rotor dynamic balancing machine

Technical Field

The utility model relates to a burr removing device, in particular to a device for removing burrs of a dynamic balancing machine of a rotor after cutting.

Background

In the dynamic balance process of the rotor, a milling cutter is needed to cut and remove the weight to achieve the purpose of dynamic balance. In the cutting process, burrs are easily generated at the cutting mark due to the abrasion of a cutter, the material of a rotor and the like, and particularly when the cutting material is plastic, the cutting process generates heat, so that the cut plastic chips are adhered to the cutting mark of the rotor after being melted. This has an influence on the subsequent steps of the rotor, and therefore, it is necessary to remove this.

For rotors with cutting burrs or chips stuck, the common method in practical production is to remove them by brushes. Through the brush rotation, drive the rotor rotation, when the brush was touched to burr or the sticky cutting bits, got rid of by the brush.

When the method is used for actual production, the rotor is not fixed, so that the rotor is easy to separate from a machine when the hairbrush rotates, a lost part is caused, and the deburring effect is not good. Meanwhile, the removed burrs and scraps splash everywhere, are not easy to collect, and interfere with the normal production process.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems in the prior art, the utility model provides a device for removing burrs after cutting of a rotor dynamic balancing machine.

The technical scheme of the utility model is as follows:

the device comprises a main body supporting structure, wherein two ends of a workpiece are arranged on the main body supporting structure in a supporting way;

the device comprises a workpiece rotation driving structure, wherein one side of a main body supporting structure is also provided with the workpiece rotation driving structure which drives a workpiece to rotate;

the deburring device comprises a deburring structure, wherein two sides of a main body supporting structure are respectively provided with a deburring structure, and the deburring structures are contacted with the surfaces near two ends of a rotor through a driving brush so as to perform deburring on the rotor in a rotating state; the brush can be contacted with the edge of the circumferential surface of the rotor close to the two ends.

The burr collecting structure is arranged below the main body supporting structure, and is used for receiving burrs of a workpiece after cutting, and the burr collecting structure wraps the periphery of the main body supporting structure to form a closed space to prevent the burrs from flying out.

The main body supporting structure comprises a bottom plate, supporting columns, a cross beam, a supporting block, a burr removing mechanism mounting seat and a rear supporting frame; a rear supporting frame is fixedly arranged on one side of the bottom plate; two support columns are vertically arranged on the other side of the bottom plate, horizontal cross beams are arranged on the two support columns, supporting blocks for supporting workpieces are arranged at the tail ends of the cross beams, the supporting blocks are provided with workpieces, the two ends of each workpiece are respectively supported by the supporting blocks on the two sides, and a burr removing mechanism mounting seat is fixedly arranged on one side of the bottom plate right below the supporting blocks on the two sides.

The workpiece rotation driving structure comprises a driving base, a moving plate, a belt tensioning structure, an air cylinder, a servo motor and a driving wheel; the driving base is fixedly arranged on the side surface of the main body supporting structure; the moving plate is horizontally movably arranged on the driving base through the first guide rail sliding block pair, the belt tensioning structure is arranged on the moving plate, the cylinder is arranged on the driving base below the moving plate in parallel with the first guide rail sliding block pair, and a piston rod of the cylinder is fixedly connected with the moving plate; the servo motor is fixed on the bottom surface of the movable plate, an output shaft of the servo motor is coaxially connected with the driving wheel, and the belt tensioning structure is in belt transmission connection with the driving wheel.

The belt tensioning structure comprises a mounting seat, a first driven wheel, an elastic piece, a second driven wheel and a belt; the movable plate is characterized in that a first driven wheel is rotatably mounted on one side of the movable plate, a mounting seat is horizontally and slidably mounted on the other side of the movable plate through a second guide rail slider pair, the second guide rail slider pair is arranged in parallel with the first guide rail slider pair, the mounting seat is connected with an elastic piece parallel to the second guide rail slider pair, so that the elastic piece enables the mounting seat to move along the second guide rail slider pair in a limited mode, a second driven wheel is rotatably mounted on the mounting seat, and the belt is sleeved on the driving wheel, the first driven wheel and the second driven wheel to form belt transmission.

The elastic part comprises two pairs of tension spring groups which are respectively arranged on two sides of the mounting seat, each pair of tension spring groups comprises two tension springs which are symmetrically arranged along the direction parallel to the second guide rail slide block pair, one end of each tension spring is hooked on the mounting seat, and the other end of each tension spring is hooked on a tension spring support which is fixed on the movable plate.

The burr removing structure comprises a burr base, a linear bearing mounting seat, a linear bearing assembly, a brush fixing frame and a brush; the burr base is fixedly arranged on the main body supporting structure; the bottom of the linear bearing mounting seat is horizontally slidably mounted on the burr base through a third guide rail slide block pair, the air cylinder is fixedly mounted on the burr base, and a piston rod of the air cylinder is fixedly connected with the linear bearing mounting seat through a connecting plate; the linear bearing mounting seat is provided with an upward protruding part, the protruding part is provided with a pair of linear bearing assemblies which are horizontally arranged, the brush fixing frame is connected to the tail end parts of the linear bearing assemblies, and the brush is arranged on the brush fixing frame.

The linear bearing assembly comprises a shaft and a linear bearing, the linear bearing is fixed on the protruding portion, the shaft is movably sleeved in the linear bearing and freely moves along the axial direction, the end portion of the shaft penetrating through the linear bearing is fixedly connected with a brush fixing seat, and a spring is sleeved on the shaft between the brush fixing seat and the linear bearing.

The hairbrush is arranged on the hairbrush fixing frame in a way of adjusting the angle facing the workpiece.

The burr collection structure include the funnel, the funnel is arranged in the middle of the main part bearing structure below.

A through groove is formed in the middle of a bottom plate of a main body supporting structure between the burr removing mechanism mounting seats on the two sides, a funnel of the burr collecting structure is positioned under the through groove and used for receiving burrs falling from the through groove into the funnel, the upper end of the funnel is connected with the through groove of the bottom plate, and the lower end of the funnel is connected with an inlet of a dust collector; therefore, the burrs fall and are collected in the funnel, and finally are discharged in a centralized way through the dust collector.

The utility model has the beneficial effects that:

according to the utility model, the rotor is fixed, and after the rotor is driven to rotate, the brush is contacted to remove cutting burrs or cutting scraps. Effectively prevent that the rotor from falling out when the clear bits, improve clear chip efficiency, reduce splashing of sweeps.

The utility model has better applicability and can effectively remove burrs of various rotors after cutting. Meanwhile, the removed burrs and scraps are collected in a centralized manner, and the normal production process is not interfered. Stable and reliable, and realizes automation.

Drawings

Fig. 1 is an exploded view of the overall structure of the present invention.

Fig. 2 is a schematic diagram of the general structure of the present invention.

Fig. 3 is an exploded view of the body support structure B0 of the present invention.

Fig. 4 is a schematic view of the subject support structure B0 of the present invention.

Fig. 5 is an exploded view of the workpiece rotation drive structure C0 of the present invention.

Fig. 6 is a schematic view of a workpiece rotation driving structure C0 according to the present invention.

Fig. 7 is an exploded view of the inventive deburring structure D0.

Fig. 8 is a schematic view of the inventive flash removal structure D0.

Fig. 9 is an exploded view of the flash collection mechanism E0 of the present invention.

Fig. 10 is a schematic view of the burr collection mechanism E0 of the present invention.

In the figure, the position of the first and second end faces,

a0: a workpiece;

b0: a body support structure; b1: a base plate; b2: a support pillar; b3: a burr removal mechanism mounting base; b4: a cross beam; b5: a support block; b6: a rear support frame;

c0: a workpiece rotation drive structure; c1: a base; c2: a servo motor; c3: a driving wheel; c4: a first guide rail sliding block pair; c5: moving the plate; c6: a cylinder; c7: a belt tensioning arrangement; c7.1: a first driven wheel; c7.2: a belt; c7.3: a first tension spring strut; c7.4: a tension spring; c7.5: a second tension spring strut; c7.6: a second guide rail sliding block pair; c7.7: a mounting base; c7.8: a second driven wheel;

d0: a burr removal structure; d1: a base; d2: a third guide rail slide block pair; d3: a connecting plate; d4: a cylinder; d5: a linear bearing mount; d6: a linear bearing assembly; d7: a brush holder; d8: a brush;

e0: a burr collection structure; E1-E5: a sheet metal part; e6: a funnel.

Detailed Description

The utility model is further described with reference to the accompanying drawings and the detailed description.

As shown in fig. 1 and 2, the main structure of the apparatus includes a workpiece a0, a main body supporting structure B0, a workpiece rotation driving structure C0, a burr removing structure D0 and a burr collecting structure E0; the workpiece A0 is supported and placed on the main body supporting structure B0, a burr removing structure D0 is installed on each of two sides of the main body supporting structure B0, a workpiece rotating driving structure C0 is further installed on one side of the main body supporting structure B0, the workpiece rotating driving structure C0 drives the workpiece A0 to rotate, the burr removing structure D0 performs burr removing on the rotor in a rotating state, and a part of the burr collecting structure E0 is located below the main body supporting structure B0 and used for receiving burrs cut by the workpiece A0.

When the workpiece reaches a certain rotating speed, the burr removing structure D0 removes burrs of the rotor. After removal, the burr enters the burr collection mechanism E0 and exits the entire mechanism through the vacuum cleaner.

As shown in fig. 3 and 4, with respect to the main body support structure B0, it includes a bottom plate B1, a support column B2, a cross beam B4, a pallet B5, a burr removal mechanism mount B3, and a rear support frame B6; a rear supporting frame B6 is fixedly arranged on one side of the bottom plate B1, and a rear supporting frame B6 is used for fixing a workpiece rotation driving structure C0; two supporting columns B2 are vertically installed on the other side of the bottom plate B1, horizontal cross beams B4 are installed on the two supporting columns B2, support blocks B5 for supporting a workpiece A0 are installed on the extending tail end of the cross beam B4, namely one end of the cross beam B4 is fixed on the supporting column B2, support blocks B5 are installed on the other end of the cross beam B4, a workpiece A0 is installed on the support blocks B5, two ends of the workpiece A0 are respectively supported and placed on the support blocks B5 connected with the two supporting columns B2 through the cross beam B4, the axial direction of the workpiece A0 is along the connecting line direction between the support blocks B5 on the two sides, burr removing mechanism installation seats B3 are fixedly installed on one side of the bottom plate B1 right below the support blocks B5 on the two sides, and the burr removing mechanism installation seats B3 on the two sides are used for fixing the burr removing structure D0.

The supporting column B2 is respectively provided with a plurality of mounting notches, the cross beam B4 can be adjustably mounted on different mounting notches and is used for independently adjusting the vertical height position of the supporting block B5 on the supporting columns B2 at two sides and further adjusting the placing height of two ends of the supporting block B5, so that the workpiece A0 can be easily kept horizontally placed on the supporting block B5.

A plurality of mounting notches are formed in burr removal mechanism mounting base B3, and burr removal structure D0 is adjustably mounted in the different mounting notches to enable the position of burr removal structure D0 to accommodate workpieces A0 of different axial lengths.

As shown in fig. 5 and 6, the workpiece rotation driving structure C0 includes a driving base C1, a moving plate C5, a belt tensioning structure C7, an air cylinder C6, a servo motor C2 and a driving wheel C3; the driving base C1 is fixedly arranged on the side surface of the rear supporting frame B7 of the main body supporting structure B0, and the driving base C1 and the rear supporting frame B7 are fixedly connected through screws; the moving plate C5 is horizontally movably mounted on the driving base C1 through a first guide rail slider pair C4, the belt tensioning structure C7 is mounted on the moving plate C5, the air cylinder C6 is arranged on the driving base C1 below the moving plate C5 in parallel with the first guide rail slider pair C4, and a piston rod of the air cylinder C6 is fixedly connected with the moving plate C5; the servo motor C2 is fixed on the bottom surface of the moving plate C5, the driving wheel C3 is rotatably supported and installed below the moving plate C5, the output shaft of the servo motor C2 is coaxially connected with the driving wheel C3, and the belt tensioning structure C7 is in belt transmission connection with the driving wheel C3.

The belt tensioning structure C7 comprises a mounting seat C7.7, a first driven wheel C7.1, an elastic piece, a second driven wheel C7.8 and a belt C7.2; a first driven wheel C7.1 is rotatably mounted on one side of the front portion of the moving plate C5, a mounting seat C7.7 is horizontally and slidably mounted on the other side of the rear portion of the moving plate C5 through a second guide rail slider pair C7.6, the second guide rail slider pair C7.6 is parallel to the first guide rail slider pair C4, the mounting seat C7.7 is connected with an elastic piece parallel to the second guide rail slider pair C7.6 to enable the second guide rail slider pair C7.6 to move along the direction of the second guide rail slider pair C7.6, a second driven wheel C7.8 is rotatably mounted at the front end of the mounting seat C7.7, a belt C7.2 is sleeved on the driving wheel C3, the first driven wheel C7.1 and the second driven wheel C7.8 to form belt transmission, and the belt C7.2 is kept to be automatically tensioned under the action of the elastic piece.

The elastic part comprises two pairs of tension spring groups which are respectively arranged on two sides of the mounting seat C7.7, each pair of tension spring groups comprises two tension springs C7.4 which are symmetrically arranged along the direction parallel to the second guide rail slider pair C7.6, one end of each tension spring C7.4 is hooked on the mounting seat C7.7, and the other end of each tension spring C7.4 is hooked on a tension spring support which is fixed on the moving plate C5.

One point in the middle of one side of the mounting seat C7.7 is connected to the first tension spring strut C7.3 and the second tension spring strut C7.5 through two tension springs C7.4, the first tension spring strut C7.3 and the second tension spring strut C7.5 are both fixed on the moving plate C5, and one point in the middle of the first tension spring strut C7.3, the second tension spring strut C7.5 and one side of the mounting seat C7.7 are located on the same straight line and parallel to the direction of the second guide rail slider pair C7.6. This allows the mounting block C7.7 to move along the second rail-slider pair C7.6, but the range of movement is limited to the elastic limit of the front and rear tension springs C7.4. The belt C7.2 is kept automatically tensioned by the tension spring C7.4.

The cylinder C6 pushes the moving plate C5 to move back and forth along the first rail slider pair C4, so as to drive the first driven wheel C7.1, the second driven wheel C7.8 and the belt C7.2 on the moving plate C5 to integrally move, so that the belt C7.2 on the driving belt tensioning structure C7 mechanism is contacted with the workpiece A0, and after the belt C7.2 is contacted with the rotor of the workpiece A0, the servo motor C2 rotates to drive the workpiece A0 to rotate through the belt C7.2.

As shown in fig. 7 and 8, with respect to the burr removing structure D0, it includes a burr seating D1, a linear bearing mount D5, a linear bearing assembly D6, a brush holder D7, and a brush D8; burr mount D1 is fixedly mounted on mechanism mount B3 of body support structure B0, securing burr removal structure D0 on body support structure B0; the bottom of the linear bearing mounting seat D5 is horizontally slidably mounted on the burr base D1 through a third guide rail slider pair D2, the third guide rail slider pair D2 is arranged perpendicular to a first guide rail slider pair C4 of the workpiece rotation driving structure C0, the air cylinder D4 is fixedly mounted on the burr base D1, a piston rod of the air cylinder D4 is fixedly connected with the linear bearing mounting seat D5 through a connecting plate D3, and the linear bearing mounting seat D5 is pushed by the air cylinder D4 to horizontally move along the third guide rail slider pair D2; the linear bearing mounting seat D5 is provided with an upward bulge, a pair of horizontally arranged linear bearing assemblies D6 is arranged on the bulge, a brush fixing frame D7 is connected to the tail end part of the linear bearing assembly D6, a brush D8 is arranged on a brush fixing frame D7, and the brush D8 is used for contacting the surface of a workpiece A0 to scrape burrs.

The linear bearing assembly D6 comprises a shaft and a linear bearing, the linear bearing is fixed on the bulge, the shaft is movably sleeved in the linear bearing and freely moves along the axial direction, the end part of the shaft penetrating through the linear bearing is fixedly connected with the brush fixing seat D7, and a spring is sleeved on the shaft between the brush fixing seat D7 and the linear bearing.

The brush D8 is adjustably mounted on the brush holder D7 toward the workpiece a 0. In the concrete implementation, set up arc waist groove on the brush mount D7, brush D8 passes through the connection of arc waist groove with the screw, and screw one end and brush D8 are connected, and the screw other end inlays into the arc waist groove, thereby can adjust the burr on the different work pieces of better laminating of D8's inclination through this arc waist groove like this. When the workpiece rotation driving structure C0 drives the workpiece A0 to rotate, the air cylinder D4 drives the brush fixing seat D7 and the brush D8 to be pushed out forwards, so that the brush D8 is attached to the burr position to remove the burrs.

As shown in fig. 9, flash collection structure E0 includes a funnel E6, funnel E6 being disposed below and intermediate body support structure B0, and workpiece a0 being above and intermediate body support structure B0.

In specific implementation, a through groove is formed in the middle of a bottom plate B1 of a main body supporting structure B0 between two side burr removing mechanism mounting seats B3, a funnel E6 of a burr collecting structure E0 is positioned right below the through groove and used for receiving the burr collecting structure E6 falling from the through groove, the upper end of the funnel E6 is connected with the through groove of the bottom plate B1, and the lower end of the funnel E6 is connected with an inlet of a dust collector; the burrs thus fall and are collected in the hopper E6, and finally are discharged intensively by the cleaner.

As shown in fig. 9 and 10, the burr collecting structure E0 further includes sheet metal parts E1-E5, a plurality of sheet metal parts E1-E5 surround the outer frame of the device, a main body supporting structure B0 is installed in the outer frame of the device, and parts of the workpiece rotation driving structure C0 and the burr removing structure D0 can be located in the outer frame of the device.

In specific implementation, the burr collecting mechanism E0 seals the whole structure of the rest part of the device through sheet metal parts E1-E5 to prevent the burrs from splashing.

In specific implementation, the burr collecting mechanism E0 is formed into a closed shell through sheet metal parts E1-E5, and the bottom of the shell is of a funnel structure and is used for collecting falling burrs; the left side and the right side of the shell are provided with hollowed-out notches for arranging a burr removing structure D0; a hollow notch is formed in the rear side of the shell and used for arranging a workpiece rotation driving structure C0; the top of the shell is provided with a hollow notch for arranging a workpiece A0.

Claims (10)

1. The utility model provides a device that burr was clear away after is used for rotor dynamic balancing machine to cut which characterized in that:

comprises a workpiece (A0), a main body supporting structure (B0), a workpiece rotating driving structure (C0), a burr removing structure (D0) and a burr collecting structure (E0); the workpiece (A0) is supported and placed on the main body supporting structure (B0), a burr removing structure (D0) is installed on each of two sides of the main body supporting structure (B0), a workpiece rotating driving structure (C0) is further installed on one side of the main body supporting structure (B0), the workpiece rotating driving structure (C0) drives the workpiece (A0) to rotate, the burr removing structure (D0) performs burr removing on the rotor in a rotating state, and the part of the burr collecting structure (E0) is located below the main body supporting structure (B0) and used for bearing burrs of the workpiece (A0) after cutting.

2. The device for deburring after cutting of the rotor dynamic balancing machine according to claim 1, wherein: the main body supporting structure (B0) comprises a bottom plate (B1), a supporting column (B2), a cross beam (B4), a supporting block (B5), a burr removing mechanism mounting seat (B3) and a rear supporting frame (B6); a rear supporting frame (B6) is fixedly arranged on one side of the bottom plate (B1); two support columns (B2) of perpendicular installation on bottom plate (B1) opposite side, all be equipped with horizontally crossbeam (B4) on two support columns (B2), the tray (B5) that is equipped with support work piece (A0) on crossbeam (B4) end, work piece (A0) is placed in the installation on tray (B5), work piece (A0) both ends are supported by tray (B5) of both sides respectively, fixed mounting burr removal mechanism mount pad (B3) on bottom plate (B1) one side under both sides tray (B5).

3. The device for deburring after cutting of the rotor dynamic balancing machine according to claim 1, wherein: the workpiece rotation driving structure (C0) comprises a first base (C1), a moving plate (C5), a belt tensioning structure (C7), a first air cylinder (C6), a servo motor (C2) and a driving wheel (C3); the first base (C1) is fixedly arranged on the side surface of the main body supporting structure (B0); the moving plate (C5) is horizontally movably mounted on the first base (C1) through a first guide rail slider pair (C4), the belt tensioning structure (C7) is mounted on the moving plate (C5), a first air cylinder (C6) is arranged on the first base (C1) below the moving plate (C5) in parallel to the first guide rail slider pair (C4), and a piston rod of the first air cylinder (C6) is fixedly connected with the moving plate (C5); the servo motor (C2) is fixed on the bottom surface of the moving plate (C5), the output shaft of the servo motor (C2) is coaxially connected with the driving wheel (C3), and the belt tensioning structure (C7) is in belt transmission connection with the driving wheel (C3).

4. The device for deburring after cutting of the rotor dynamic balancing machine according to claim 3, wherein: the belt tensioning structure (C7) comprises a mounting seat (C7.7), a first driven wheel (C7.1), an elastic piece, a second driven wheel (C7.8) and a belt (C7.2); a first driven wheel (C7.1) is rotatably mounted on one side of the moving plate (C5), a mounting seat (C7.7) is horizontally and slidably mounted on the other side of the moving plate (C5) through a second guide rail slider pair (C7.6), the second guide rail slider pair (C7.6) and the first guide rail slider pair (C4) are arranged in parallel, the mounting seat (C7.7) is connected with an elastic piece parallel to the second guide rail slider pair (C7.6) to enable the elastic piece to move along the second guide rail slider pair (C7.6) to be limited, a second driven wheel (C7.8) is rotatably mounted on the mounting seat (C7.7), and a belt (C7.2) is sleeved on the driving wheel (C3), the first driven wheel (C7.1) and the second driven wheel (C7.8) to form belt transmission.

5. The device for deburring after cutting of the rotor dynamic balancing machine according to claim 4, wherein: the elastic piece comprises two pairs of tension spring sets which are respectively arranged on two sides of the mounting seat (C7.7), each pair of tension spring sets comprises two tension springs (C7.4) which are symmetrically arranged along the direction parallel to the second guide rail slider pair (C7.6), one end of each tension spring (C7.4) is hooked on the mounting seat (C7.7), and the other end of each tension spring (C7.4) is hooked on a tension spring strut fixed on the moving plate (C5).

6. The device for deburring after cutting of the rotor dynamic balancing machine according to claim 1, wherein: the burr removing structure (D0) comprises a second base (D1), a linear bearing mounting seat (D5), a linear bearing assembly (D6), a brush fixing frame (D7) and a brush (D8); the second base (D1) is fixedly mounted on the main body supporting structure (B0); the bottom of the linear bearing mounting seat (D5) is horizontally slidably mounted on a second base (D1) through a third guide rail slider pair (D2), a second air cylinder (D4) is fixedly mounted on the second base (D1), and a piston rod of the second air cylinder (D4) is fixedly connected with the linear bearing mounting seat (D5) through a connecting plate (D3); the linear bearing mounting seat (D5) is provided with an upward protruding part, a pair of horizontally arranged linear bearing assemblies (D6) is arranged on the protruding part, the brush fixing frame (D7) is connected to the tail end part of the linear bearing assemblies (D6), and a brush (D8) is arranged on the brush fixing frame (D7).

7. The device for deburring after cutting of the rotor dynamic balancing machine according to claim 6, wherein: the linear bearing assembly (D6) comprises a shaft and a linear bearing, the linear bearing is fixed on the protruding part, the shaft is movably sleeved in the linear bearing and freely moves along the axial direction, the end part of the shaft penetrating through the linear bearing is fixedly connected with a brush fixing frame (D7), and a spring is sleeved on the shaft between the brush fixing frame (D7) and the linear bearing.

8. The device for deburring after cutting of the rotor dynamic balancing machine according to claim 7, wherein: the brush (D8) is mounted on the brush holder (D7) in an angle adjustable toward the workpiece (A0).

9. The device for removing burrs after cutting of the rotor dynamic balancing machine according to claim 1, wherein: the burr collecting structure (E0) comprises a funnel (E6), the funnel (E6) being arranged below the middle of the main body support structure (B0).

10. The device for deburring after cutting of the rotor dynamic balancing machine according to claim 1, wherein: a through groove is formed in the middle of a bottom plate (B1) of a main body supporting structure (B0) between two side burr removing mechanism mounting seats (B3), a funnel (E6) of a burr collecting structure (E0) is located under the through groove and used for receiving the dust falling into the funnel (E6) from the through groove, the upper end of the funnel (E6) is connected with the through groove of the bottom plate (B1), and the lower end of the funnel is connected with an inlet of a dust collector.

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