CN215092736U

CN215092736U - Six abrasive band polishing equipment of multistation

Info

Publication number: CN215092736U
Application number: CN202121253874.XU
Authority: CN
Inventors: 蒋学军
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-06-05
Filing date: 2021-06-05
Publication date: 2021-12-10
Anticipated expiration: 2031-06-05

Abstract

The utility model provides a six abrasive band polishing equipment of multistation, including work piece aversion unit and at least two abrasive band units, work piece aversion unit includes the support, the platform of portable installation in the support, be fixed in the work piece rotating assembly of platform, and work piece aversion servo motor, the platform is disc type or orthoscopic structure, work piece aversion servo motor is used for driving the platform and removes so that the work piece rotating assembly on the platform is in different stations in order to correspond different abrasive band units, install the abrasive band of different models on at least two abrasive band units respectively, work piece rotating assembly is used for fixing the work piece and drives the work piece and make and deflect and the rotation about; the abrasive belt unit comprises a base, an abrasive belt head assembly and a four-shaft driving mechanism fixed on the base, wherein the four-shaft driving mechanism is used for driving the abrasive belt head assembly to move in a three-shaft mode and to deflect up and down. The utility model discloses a combination of many abrasive band units + work piece aversion unit realizes high-efficient, high-quality production.

Description

Six abrasive band polishing equipment of multistation

Technical Field

The utility model relates to a grind and throw technical field, specifically a six abrasive band polishing equipment of multistation.

Background

In the existing grinding and polishing industry at home and abroad, the equipment for grinding products by using abrasive belts is mainly divided into two types: the first is the robot belt sander, and the second is the special belt sander.

The robot abrasive band machine has the following defects:

a. the purchase price of the robot is high.

At present, the robot which can be used for sanding belt mainly comprises a French robot and an ABB robot which are produced abroad, and the domestic robot can not meet the sanding performance requirement of the belt sander at present. However, foreign robots are expensive in selling price, the cost of the robot accounts for 50% of the whole equipment cost in the manufacturing cost of one robot abrasive belt machine set, and domestic robot abrasive belt machine equipment manufacturers do grafts for foreign robot manufacturers.

b. The efficiency of the robot belt sander is low.

The working mode of the robot abrasive band machine is as follows: the robot grasps the product, and polishes the surface of the product on a coarse abrasive belt, a medium-coarse abrasive belt, a fine abrasive belt, a superfine abrasive belt and the like in sequence, so that the action is repeated, and the efficiency is low.

The special abrasive belt machine has the following defects:

a. the special belt sander has stiff action, single motion track and very limited applicable product range. Because the grinding machine is special, the appearance type of the produced product is single, the flexible characteristic of six-axis linkage of the robot belt sander is not possessed, and the product with a complex curved surface appearance cannot be ground;

b. the precision of the special belt sander is not high, and high-quality products cannot be produced.

The fixed motion track of the special machine can not flexibly link the radian of the surface of the product, and the appearance quality of the produced product is limited.

c. The cost of the special plane is high, and the effective utilization rate of the equipment cannot be guaranteed.

When the products produced by the special machine have no orders for some reason, the special machine has no use value. The special machine has a complex structure, is limited by the quantity of product orders, diversifies product varieties, and is required to be diversified, so that the special machine cannot be produced in batches, the manufacturing cost of equipment cannot be reduced, and the price is high.

SUMMERY OF THE UTILITY MODEL

The above-mentioned defect to prior art exists, the utility model provides a six abrasive band polishing equipment of multistation has integrated the flexibility of robot abrasive band machine, the advantage that the precision is high, and has integrated the efficient advantage of special abrasive band machine, can enlarge the variety classification of production product, promotes the product quality, but this equipment batch production in addition, can reduce the manufacturing cost of equipment, improves user's rate of equipment utilization.

A multi-station six-axis abrasive belt polishing device comprises a workpiece shifting unit and at least two abrasive belt units, wherein the workpiece shifting unit comprises a support, a platform movably mounted on the support, a workpiece rotating assembly fixed on the platform and a workpiece shifting servo motor, the platform is of a disc type or linear structure, the workpiece shifting servo motor is used for driving the platform to move so that the workpiece rotating assembly on the platform is located at different stations to correspond to different abrasive belt units, abrasive belts of different models are respectively mounted on the at least two abrasive belt units, and the workpiece rotating assembly is used for fixing a workpiece and driving the workpiece to deflect left and right and rotate; the abrasive belt unit comprises a base, an abrasive belt head assembly and a four-axis driving mechanism fixed on the base, wherein the four-axis driving mechanism is used for driving the abrasive belt head assembly to move in a three-axis mode and to deflect up and down.

Further, the workpiece rotating assembly comprises a rotating body, a rotating chuck and a corner main body, the rotating body is mounted on the side face of the corner main body, the corner main body is provided with a rotating motor, the rotating motor is connected with the rotating body through an output shaft perpendicular to the side face of the corner main body, and the rotating motor rotates clockwise and anticlockwise to drive the corner main body to deflect left and right; the rotary chuck is arranged at the top of the rotary body and used for fixing a workpiece, and the rotary chuck is driven by the rotary body to rotate around a rotating shaft vertical to the top surface of the rotary body so as to drive the workpiece to rotate.

Furthermore, the abrasive belt head assembly comprises an abrasive belt power motor, an abrasive belt driving rubber wheel, an abrasive belt auxiliary wheel, an abrasive belt deviation adjusting wheel and an abrasive belt deviation adjusting speed reducing motor, wherein the abrasive belt driving rubber wheel, the abrasive belt auxiliary wheel and the abrasive belt deviation adjusting wheel are arranged in a triangular shape to form three-point support, an abrasive belt is wound on the abrasive belt driving rubber wheel, the abrasive belt auxiliary wheel and the abrasive belt deviation adjusting wheel, the abrasive belt driving rubber wheel is driven to rotate by the abrasive belt power motor, the abrasive belt auxiliary wheel is located on one side of the abrasive belt driving rubber wheel, and the abrasive belt deviation adjusting wheel realizes deviation adjusting action on the abrasive belt through a joint linkage mechanism by the abrasive belt deviation adjusting speed reducing motor.

Further, four-axis actuating mechanism includes X axle drive assembly, Y axle drive assembly, Z axle drive assembly and A axle drive assembly, X axle drive assembly is used for driving the abrasive band head subassembly and realizes the horizontal rotation gesture motion to realize X axial motion, Y axle drive assembly is used for driving the removal that the abrasive band head subassembly realized the Y axle direction, Z axle drive assembly is used for driving the removal that the abrasive band head subassembly realized the Z direction, A axle drive assembly is used for the abrasive band head subassembly to carry out deflection motion from top to bottom.

Furthermore, the Z-axis driving assembly comprises a Z-axis servo motor, a Z-axis screw rod, a Z-axis sliding block, a Z-axis guide rail, a machine head connecting plate and a Z-axis fixing frame; the Z-axis servo motor is fixed at the top of the Z-axis fixing frame, the Z-axis guide rail is vertically and fixedly installed on the Z-axis fixing frame and is parallel to the Z-axis guide rail, an output shaft of the Z-axis servo motor is connected with one end of a Z-axis screw rod, the Z-axis screw rod is screwed on a screw nut on a machine head connecting plate, the A-axis driving assembly is fixed on the machine head connecting plate, and an output shaft of the A-axis driving assembly is fixedly connected with an abrasive belt fixing frame of an abrasive belt head assembly.

Furthermore, the A-axis driving assembly comprises an A-axis servo motor, the A-axis servo motor is fixed on the machine head connecting plate, and the A-axis servo motor drives the belt sander head assembly to perform vertical deflection motion through the output shaft during working.

Furthermore, the X-axis driving assembly comprises an X-axis servo motor, a small helical gear disc and a large helical gear disc, an output shaft of the X-axis servo motor is in driving connection with the small helical gear disc, the small helical gear disc is fixed with a disc seat located at the bottom of the Z-axis fixing frame through a fixing plate, the large helical gear disc is fixed on a bottom plate of the large helical gear disc, the disc seat is in relative rotating connection with the large helical gear disc, and the small helical gear disc is in meshing connection with the large helical gear disc.

Furthermore, the Y-axis driving assembly comprises a Y-axis servo motor, a Y-axis lead screw, a Y-axis guide rail and a Y-axis sliding block, the Y-axis lead screw is horizontally arranged and is perpendicular to the Z-axis lead screw, the Y-axis guide rail is arranged in parallel with the Y-axis lead screw, an output shaft of the Y-axis servo motor is connected with one end of the Y-axis lead screw, the Y-axis lead screw is in threaded connection with a lead screw nut on the large helical gear disc bottom plate, and the Y-axis sliding block in sliding connection with the Y-axis guide rail is arranged on the large helical gear disc bottom plate.

The utility model discloses a many abrasive band unit + combination of work piece aversion unit, the abrasive band unit is the four-axis linkage, work piece aversion unit is the diaxon linkage, six axis linkages altogether, the abrasive material of the different models of 2 mountable of a plurality of abrasive band units, for example, thick abrasive band, well thick abrasive band, thin abrasive band, superfine abrasive band, the work piece is with the form of assembly line like this, through carousel or sharp unit in proper order by thick abrasive band polish, well thick abrasive band polish, thin abrasive band polish, superfine abrasive band polish, the work piece is every rotatory or the straight line moves a station, can produce a finished product work piece promptly, a new work piece will be put into simultaneously, so circulate, can realize high-efficient, the production of high quality, the product of processing can transposing automatically, the product of multistation carries out the abrasive band cutting motion of polishing in step, make things convenient for the upper and lower of material simultaneously.

Drawings

Fig. 1 is a schematic perspective view of one embodiment of the present invention;

FIG. 2 is a schematic view of a three-dimensional structure of the workpiece shifting unit in one direction according to the present invention;

FIG. 3 is a schematic perspective view of the workpiece shifting unit according to another direction of the present invention;

FIG. 4 is a front view of the workpiece shifting unit of the present invention;

fig. 5 is a schematic perspective view of a belt sander of the present invention in one direction;

fig. 6 is a schematic perspective view of the belt sander of the present invention in another direction;

fig. 7 is a schematic perspective view of the belt sander of the present invention in another direction;

fig. 8 is a schematic view of an exploded structure of a middle abrasive belt machine set according to the present invention.

The reference numerals in the figures are as follows: 1-workpiece shifting unit, 2-abrasive belt unit, 3-workpiece, 4-abrasive belt, 11-bracket, 12-platform, 13-workpiece shifting servo motor, 14-rotating body, 15-rotating chuck, 16-corner body, 21-base, 22-X axis servo motor, 221-bevel pinion disk, 222-bevel pinion disk, 23-abrasive belt head assembly, 231-abrasive belt power motor, 232-abrasive belt driving rubber wheel, 233-auxiliary wheel bracket, 234-abrasive belt auxiliary wheel, 235-abrasive belt deflection adjusting wheel, 236-abrasive belt deflection adjusting speed reducing motor, 237-abrasive belt fixing frame, 24-Y axis servo motor, 241-Y axis screw rod, 242-Y axis guide rail, 243-Y axis slide block, 243-bevel pinion disk base plate, 25-A axis servo motor, 251-buffer cylinder assembly, 26-Z axis servo motor, 261-Z axis screw rod, 262-Z axis slide block, 263-Z axis guide rail, 264-head plate, 265-fixed mount, 266-disc seat.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1-4, an embodiment of the multi-station six-axis belt polishing apparatus of the present invention includes a workpiece moving unit 1 and at least two belt units 2. The workpiece shifting unit 1 can be designed into a disc type or a linear type structure, the workpiece shifting unit 1 shown in fig. 1-4 is designed into a disc type, three abrasive belt units 2 annularly surround the workpiece shifting unit 1 at certain intervals, and when the workpiece shifting unit 1 is designed into a linear type structure, a plurality of abrasive belt units 2 are arranged at intervals along the workpiece shifting unit 1.

The workpiece shifting unit 1 comprises a support 11, a platform 12 movably mounted on the support 1, a workpiece rotating assembly fixed on the platform 12, and a workpiece shifting servo motor 13, wherein the workpiece shifting servo motor 13 provides accurate motion power for the platform 12 and is used for driving the platform 12 to move so that the workpiece rotating assembly on the platform 12 is positioned at different stations to correspond to different abrasive belt units 2.

The workpiece rotating assembly is used for fixing the workpiece 3 and driving the workpiece 3 to do two-axis movement of left-right deflection and autorotation, the workpiece rotating assembly comprises a rotating body 14, a rotating chuck 15 and a corner main body 16, the rotating body 14 is installed on the side surface of the corner main body 16, the corner main body 16 is provided with a rotating motor, the rotating motor is connected with the rotating body 14 through an output shaft perpendicular to the side surface of the corner main body 16, and the rotating motor can drive the corner main body 16 to deflect left and right through clockwise and anticlockwise rotation; the rotating chuck 15 is installed on the top of the rotating body 14, the rotating chuck 15 is used for fixing the workpiece 3, the rotating chuck 15 can be designed to be a telescopic clamping piece suitable for different workpieces, and the rotating chuck 15 is driven by the rotating body 14 to rotate around a rotating shaft perpendicular to the top surface of the rotating body 14, so that the workpiece 3 is driven to rotate.

In this embodiment, the workpiece shifting unit 1 takes a disc type as an example, the platform 12 is a disc structure, and is connected to an output shaft of a workpiece shifting servo motor 13 located below the platform 12 through a middle rotating shaft component, the workpiece shifting servo motor 13 drives the platform 12 of the disc structure to rotate when operating, so that a plurality of workpiece rotating assemblies circumferentially arranged on the platform 12 are located at different positions along with the rotation of the platform 12, and the workpiece shifting servo motor 13 controls and stops at the abrasive belt unit 2 arranged around the platform 12, so as to polish the workpiece 3 mounted on the workpiece rotating assemblies.

Referring to fig. 5-7, the belt sander 2 includes a base 21, a belt sander head assembly 23, and a four-axis driving mechanism fixed to the base 21, wherein the four-axis driving mechanism is used for driving the belt sander head assembly 23 to perform three-axis movement and up-and-down deflection movement, so as to cooperate with the workpiece shifting unit 1 to polish the workpiece 3.

Referring to fig. 8, the belt head assembly 23 includes a belt power motor 231, a belt driving rubber wheel 232, an auxiliary wheel bracket 233, a belt auxiliary wheel 234, a belt deviation-adjusting wheel 235, a belt deviation-adjusting deceleration motor 236, and a belt fixing bracket 237, wherein the belt power motor 231, the auxiliary wheel bracket 233, and the belt deviation-adjusting deceleration motor 236 are mounted on the belt fixing bracket 237.

The abrasive belt driving rubber wheel 232, the abrasive belt auxiliary wheel 234 and the abrasive belt deviation adjusting wheel 235 are arranged in a triangular shape to form three-point support, the abrasive belt 4 is wound on the abrasive belt driving rubber wheel 232, the abrasive belt auxiliary wheel 234 and the abrasive belt deviation adjusting wheel 235, so that the grinding and polishing modes of the abrasive belt 4 are diversified, and the multi-style grinding and polishing of a large rubber wheel surface, a small rubber wheel surface and a suspended abrasive belt (hanging belt) is formed, namely, a large surface can be directly ground, the abrasive belt is powerful and efficient, a small surface can be used for drawing corners, no dead angle can be used for grinding and polishing a product, the hanging belt can be used for grinding and polishing, and the radian of the surface of the product is smoother and more flexible.

The auxiliary wheel 234 is fixed on one side of the driving rubber wheel 232 by the auxiliary wheel bracket 233, and the belt deviation-adjusting wheel 235 is located on the rear side of the driving rubber wheel 232 and the auxiliary wheel 234. The abrasive belt driving rubber wheel 232 is driven by an abrasive belt power motor 231 to rotate so as to drive the abrasive belt 4 to move, and the abrasive belt power motor 231 can adopt a 380V three-phase power motor to provide cutting power for the abrasive belt 4. The belt deviation adjusting wheel 235 realizes the deviation adjusting action of the belt 4 through a joint linkage mechanism by a belt deviation adjusting speed reducing motor 236.

The four-axis driving mechanism comprises an X-axis driving assembly, a Y-axis driving assembly, a Z-axis driving assembly and an A-axis driving assembly.

The Z-axis driving component comprises a Z-axis servo motor 26, a Z-axis lead screw 261, a Z-axis sliding block 262, a Z-axis guide rail 263, a machine head connecting plate 264 and a Z-axis fixing frame 265.

The Z-axis servo motor 26 is fixed on the top of the Z-axis fixing frame 265, the Z-axis guide rail 263 is vertically and fixedly installed on the Z-axis fixing frame 265 and is parallel to the Z-axis guide rail 263, an output shaft of the Z-axis servo motor 26 is connected with one end of a Z-axis screw 261, the Z-axis screw 261 is screwed on a screw nut on the head coupling plate 264, and a Z-axis slider 262 which is connected with the Z-axis guide rail 263 in a sliding mode is arranged on the head coupling plate 264. The a-axis driving component is fixed on the head coupling plate 264, and the output shaft of the a-axis driving component is fixedly connected with the belt fixing frame 237 of the belt sander head component 23. The Z-axis servomotor 26 drives the Z-axis screw 261 to rotate, and then drives the Z-axis slider 262 to move along the Z-axis guide rail 263, and further drives the abrasive belt head assembly 23 to move in the vertical direction (Z-axis direction) through the head coupling plate 264.

The X-axis driving assembly comprises an X-axis servo motor 22, a small helical gear disk 221 and a large helical gear disk 222, an output shaft of the X-axis servo motor 22 is in driving connection with the small helical gear disk 221, the small helical gear disk 221 is fixed with a disk seat 266 located at the bottom of a Z-axis fixing frame 265 through a fixing plate, the large helical gear disk 222 is fixed on a large helical gear disk bottom plate 244, the disk seat 266 is in relative rotating connection with the large helical gear disk 222, and the small helical gear disk 221 is in meshing connection with the large helical gear disk 222. The X-axis servo motor 22 drives the bevel pinion disk 221 to rotate, the bevel pinion disk 222 is fixed (as a stator), the bevel pinion disk 221 (as a rotor) rotates around the bevel pinion disk 222 under the driving of the X-axis servo motor 22, and the bevel pinion disk 221 is fixed with the disk seat 266 through the fixing plate and further drives the Z-axis driving assembly and the belt sander head assembly 23 on the Z-axis driving assembly to realize horizontal rotation posture movement, so that X-axis movement is realized.

The Y-axis driving assembly comprises a Y-axis servo motor 24, a Y-axis lead screw 241, a Y-axis guide rail 242 and a Y-axis sliding block 243, the Y-axis lead screw 241 is horizontally arranged and is perpendicular to the Z-axis lead screw 261, the Y-axis guide rail 242 is arranged in parallel with the Y-axis lead screw 241, an output shaft of the Y-axis servo motor 24 is connected with one end of the Y-axis lead screw 241, the Y-axis lead screw 241 is in threaded connection with a lead screw nut on a large bevel gear disc base plate 244, and the Y-axis sliding block 243 in sliding connection with the Y-axis guide rail 242 is arranged on the large bevel gear disc base plate 244. The Y-axis servo motor 24 drives the Y-axis lead screw 241 to rotate, and further drives the Y-axis slider 243 to move along the Y-axis guide rail 242, and further drives the belt sander head assembly 23 to move in the Y-axis direction through the large bevel gear plate base plate 244.

The A-axis driving assembly comprises an A-axis servo motor 25 and a buffer air cylinder assembly 251, the A-axis servo motor 25 is fixed on the head connecting plate 264, an output shaft of the A-axis servo motor 25 is fixedly connected with an abrasive belt fixing frame 237 of the abrasive belt head assembly 23, and the A-axis servo motor 25 drives the abrasive belt head assembly 23 to perform vertical deflection movement through the output shaft when working. The buffer cylinder assembly 251 is used to buffer the operation of the a-axis servomotor 25 and prevent the backlash of the vertical deflection of the belt sander head assembly 23.

The utility model discloses the theory of operation:

1. the workpiece shifting unit 1 is responsible for exchanging the position of a product, and meanwhile, a plurality of workpiece rotating assemblies on the workpiece shifting unit 1 can synchronously change the posture of the product in two directions (two-axis movement of left-right deflection and autorotation);

2. the abrasive belt unit 2 is responsible for controlling the rotation of the abrasive belt 4, the abrasive belt 4 can change postures in four directions (an X axis, a Y axis, a Z axis and an A axis), and the contact surface between the abrasive belt 4 and the workpiece 3 can be on the surfaces of large and small rubber wheels (an abrasive belt driving rubber wheel 232 and an abrasive belt auxiliary wheel 234) or on the surface of a suspended abrasive belt 4 (commonly called as sling grinding).

The utility model discloses a many abrasive band unit + combination of work piece aversion unit, the abrasive band unit is the four-axis linkage, work piece aversion unit is the diaxon linkage, six axis linkages altogether, the abrasive material of the different models of 2 mountable of a plurality of abrasive band units, for example, thick abrasive band, well thick abrasive band, thin abrasive band, superfine abrasive band, the work piece is with the form of assembly line like this, through carousel or sharp unit in proper order by thick abrasive band polish, well thick abrasive band polish, thin abrasive band polish, superfine abrasive band polish, the work piece is every rotatory or the straight line moves a station, can produce a finished product work piece promptly, a new work piece will be put into simultaneously, so circulate, can realize high-efficient, the production of high quality, the product of processing can transposing automatically, the product of multistation carries out the abrasive band cutting motion of polishing in step, make things convenient for the upper and lower of material simultaneously. The product that current burnishing device ground mainly is cell-phone shell class isoplanar object, can only throw five at most, and sixth can not throw, and the utility model discloses can realize the polishing of six faces, realize the burnishing and polishing of three-dimensional work piece promptly, have more application scenes.

The above description is only the specific implementation manner of the present invention, but the protection scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention are all covered by the protection scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims

1. A six abrasive band polishing equipment of multistation which characterized in that: the abrasive belt grinding machine comprises a workpiece shifting unit and at least two abrasive belt units, wherein the workpiece shifting unit comprises a support, a platform movably arranged on the support, a workpiece rotating assembly fixed on the platform and a workpiece shifting servo motor, the platform is of a disc type or linear structure, the workpiece shifting servo motor is used for driving the platform to move so that the workpiece rotating assembly on the platform is positioned at different stations to correspond to different abrasive belt units, abrasive belts of different types are respectively arranged on the at least two abrasive belt units, and the workpiece rotating assembly is used for fixing a workpiece and driving the workpiece to deflect left and right and rotate; the abrasive belt unit comprises a base, an abrasive belt head assembly and a four-axis driving mechanism fixed on the base, wherein the four-axis driving mechanism is used for driving the abrasive belt head assembly to move in a three-axis mode and to deflect up and down.

2. A multi-station six-axis belt sander apparatus as set forth in claim 1, wherein: the workpiece rotating assembly comprises a rotating body, a rotating chuck and a corner main body, the rotating body is arranged on the side face of the corner main body, the corner main body is provided with a rotating motor, the rotating motor is connected with the rotating body through an output shaft perpendicular to the side face of the corner main body, and the rotating motor rotates clockwise and anticlockwise to drive the corner main body to deflect left and right; the rotary chuck is arranged at the top of the rotary body and used for fixing a workpiece, and the rotary chuck is driven by the rotary body to rotate around a rotating shaft vertical to the top surface of the rotary body so as to drive the workpiece to rotate.

3. A multi-station six-axis belt sander apparatus as set forth in claim 1, wherein: the abrasive belt head component comprises an abrasive belt power motor, an abrasive belt driving rubber wheel, an abrasive belt auxiliary wheel, an abrasive belt deviation adjusting wheel and an abrasive belt deviation adjusting speed reducing motor, wherein the abrasive belt driving rubber wheel, the abrasive belt auxiliary wheel and the abrasive belt deviation adjusting wheel are arranged in a triangular mode to form three-point support, an abrasive belt is wound on the abrasive belt driving rubber wheel, the abrasive belt auxiliary wheel and the abrasive belt deviation adjusting wheel, the abrasive belt driving rubber wheel is driven to rotate by the abrasive belt power motor, the abrasive belt auxiliary wheel is located on one side of the abrasive belt driving rubber wheel, and the abrasive belt deviation adjusting wheel realizes deviation adjustment action on the abrasive belt through a joint linkage mechanism by the abrasive belt deviation adjusting speed reducing motor.

4. A multi-station six-axis belt sander apparatus as set forth in claim 3, wherein: four-axis actuating mechanism includes X axle drive assembly, Y axle drive assembly, Z axle drive assembly and A axle drive assembly, X axle drive assembly is used for driving the abrasive band head subassembly and realizes the horizontal rotation gesture motion to realize X axial motion, Y axle drive assembly is used for driving the removal that the abrasive band head subassembly realized the Y axle direction, Z axle drive assembly is used for driving the removal that the abrasive band head subassembly realized the Z direction, A axle drive assembly is used for the abrasive band head subassembly to carry out deflection motion from top to bottom.

5. A multi-station six-axis belt sander as set forth in claim 4, wherein: the Z-axis driving assembly comprises a Z-axis servo motor, a Z-axis lead screw, a Z-axis sliding block, a Z-axis guide rail, a machine head connecting plate and a Z-axis fixing frame; the Z-axis servo motor is fixed at the top of the Z-axis fixing frame, the Z-axis guide rail is vertically and fixedly installed on the Z-axis fixing frame and is parallel to the Z-axis guide rail, an output shaft of the Z-axis servo motor is connected with one end of a Z-axis screw rod, the Z-axis screw rod is screwed on a screw nut on a machine head connecting plate, the A-axis driving assembly is fixed on the machine head connecting plate, and an output shaft of the A-axis driving assembly is fixedly connected with an abrasive belt fixing frame of an abrasive belt head assembly.

6. A multi-station six-axis belt sander as set forth in claim 5, wherein: the A-axis driving assembly comprises an A-axis servo motor, the A-axis servo motor is fixed on the machine head connecting plate, and the A-axis servo motor drives the abrasive belt machine head assembly to perform vertical deflection motion through the output shaft during working.

7. A multi-station six-axis belt sander as set forth in claim 5, wherein: the X-axis driving assembly comprises an X-axis servo motor, a small helical gear disc and a large helical gear disc, an output shaft of the X-axis servo motor is in driving connection with the small helical gear disc, the small helical gear disc is fixed with a disc seat located at the bottom of the Z-axis fixing frame through a fixing plate, the large helical gear disc is fixed on a large helical gear disc base plate, the disc seat is in relative rotating connection with the large helical gear disc, and the small helical gear disc is in meshing connection with the large helical gear disc.

8. A multi-station six-axis belt sander apparatus as set forth in claim 7, wherein: the Y-axis driving assembly comprises a Y-axis servo motor, a Y-axis lead screw, a Y-axis guide rail and a Y-axis sliding block, the Y-axis lead screw is horizontally arranged and is perpendicular to the Z-axis lead screw, the Y-axis guide rail is parallel to the Y-axis lead screw, an output shaft of the Y-axis servo motor is connected with one end of the Y-axis lead screw, the Y-axis lead screw is screwed on a lead screw nut on a large helical gear plate bottom plate, and the Y-axis sliding block which is connected with the Y-axis guide rail in a sliding mode is arranged on the large helical gear plate bottom plate.