CN116079554A

CN116079554A - Processing device and processing method for hydrogen energy ultra-clean precise pipe

Info

Publication number: CN116079554A
Application number: CN202310321668.5A
Authority: CN
Inventors: 陈小义
Original assignee: Changzhou Youlong Precision Technology Co ltd
Current assignee: Changzhou Youlong Precision Technology Co ltd
Priority date: 2023-03-29
Filing date: 2023-03-29
Publication date: 2023-05-09

Abstract

The invention belongs to the technical field of precision tube processing equipment, in particular to a processing device and a processing method of a hydrogen energy ultra-clean precision tube, wherein the processing device comprises a bottom plate, and the bottom plate is provided with: the polishing device comprises a driving mechanism, a polishing mechanism, a sliding rail and a reciprocating mechanism; the slide rail is connected with a slide frame in a sliding way, the slide frame is symmetrically connected with a rotatable bracket, and the polishing mechanism is provided with a pair of polishing mechanisms and is respectively connected with the brackets in a rotating way; the polishing mechanism comprises a rotating frame which is rotatably connected to the bracket, a first tension spring is connected between the rotating frame and the bracket, and a polishing roller and a polishing motor for driving the polishing roller to rotate are connected to the rotating frame; according to the polishing device, the pair of polishing rollers are arranged, and the angle between the two polishing rollers and the precise tube can be adjusted, so that the device is provided with two polishing modes for polishing the surface and the end face of the precise tube, and the functionality of the polishing device is improved.

Description

Processing device and processing method for hydrogen energy ultra-clean precise pipe

Technical Field

The invention relates to the technical field of hydrogen energy precise tube processing, in particular to a processing device and a processing method of a hydrogen energy ultra-clean precise tube.

Background

The hydrogen energy precise stainless steel pipe is a high-precision and high-brightness seamless steel pipe produced by a cold drawing or cold rolling process, is safe, reliable, sanitary, environment-friendly, economical and applicable, has the advantages of thinner pipelines, irreplaceable other pipes, more and more engineering applications, more and more popularization in use and good prospect, and is developed successfully by a novel reliable, simple and convenient connecting method.

In the process of production and processing of precise stainless steel pipelines, the precise stainless steel pipelines are required to be cut, polished, cleaned and other processing programs, burrs are often left on the end faces of the pipelines after cutting, the use of the precise pipelines is affected, therefore, the burrs on the end faces of the pipelines are required to be polished and cleaned before use, the conventional pipeline surface polishing equipment is required to polish the surfaces of the pipelines, the functions are single, manual cooperation polishing is required, the polishing efficiency and polishing quality of the pipelines are affected by manual operation, and part of equipment can only polish the end faces of the pipelines, so that the burrs on the inner sides of the end faces cannot be removed.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a processing device and a processing method of a hydrogen energy ultra-clean precise tube, wherein a driving mechanism drives the precise tube to rotate, and simultaneously changes the angle between a polishing mechanism and the end face of the precise tube, and the polishing mechanism polishes and deburrs the end face of the precise tube, so as to solve the problems in the background art.

In order to achieve the technical purpose, the specific technical scheme of the invention is as follows, and the processing device of the hydrogen energy ultra-clean precision tube provided by the invention comprises: the bottom plate, be equipped with on the bottom plate: the driving mechanism is used for driving the precise tube to rotate; the polishing mechanism is used for polishing the surface and the end face of the precision tube; the polishing device comprises a sliding rail, a sliding frame, a polishing mechanism and a polishing mechanism, wherein the sliding rail is connected with the sliding frame in a sliding manner, rotatable brackets are symmetrically connected to the sliding frame, and the polishing mechanism is provided with a pair of polishing mechanisms and is respectively connected to the brackets in a rotating manner; the reciprocating mechanism is used for driving the sliding frame to slide back and forth along the sliding rail; the polishing mechanism comprises a rotating frame, the rotating frame is rotationally connected to the support, a first tension spring is connected between the rotating frame and the support, and a polishing roller and a polishing motor for driving the polishing roller to rotate are connected to the rotating frame.

As a preferable technical scheme of the invention, the driving mechanism comprises a fixed seat, a driving motor is arranged on the fixed seat, a rotating shaft is connected to the driving motor, and a driving roller for driving the precise tube to rotate is connected to the rotating shaft.

As a preferable technical scheme of the invention, the fixed seat is symmetrically connected with a pair of movable limiting frames, the limiting frames are connected with limiting wheels for limiting two sides of the precise tube, the fixed seat is connected with an adjusting screw, one end of the adjusting screw is connected with the limiting frames, and the fixed seat is connected with a pair of supporting wheels for supporting the precise tube.

As a preferable technical scheme of the invention, the reciprocating mechanism comprises a frame, a pair of spiral rollers are rotationally connected to the frame, driven gears meshed with each other are fixedly connected to one ends of the two spiral rollers, driving gears meshed with the driven gears are connected to the rotating shafts, a moving frame is connected to the frame in a sliding manner, the moving frame is fixedly connected with the sliding frame, and guide holes connected with the moving frame in a sliding manner are formed in the frame.

As a preferable technical scheme of the invention, the side surface of the movable frame is rotatably connected with a movable rod, the movable rod is arranged between two screw rolls, and the surface of the movable rod is fixedly connected with a pair of arc-shaped screw blocks correspondingly matched with the screw rolls; the movable frame surface is rotationally connected with a movable frame, a clamping groove is fixedly connected on the movable frame, the upper end face of the movable rod is fixedly connected with a shaft lever matched with the clamping groove, the movable frame surface is rotationally connected with a supporting rod, and a second tension spring is connected between the supporting rod and the movable frame.

As a preferable technical scheme of the invention, the movable frame is symmetrically and fixedly connected with a pair of stop rods for limiting the support rods, the frame is fixedly connected with a limiting rod for driving the support rods to rotate, and the movable frame is fixedly connected with a fixing rod fixedly connected with the sliding frame.

As a preferable technical scheme of the invention, a sliding rod is fixedly connected to the sliding frame, a sliding block is connected to the sliding rod in a sliding manner, a connecting rod is connected between the sliding block and the rotating frame, a pair of connecting plates are fixedly connected to two sides of the sliding rod, and a pair of limiting blocks for limiting and fixing the sliding block are fixedly connected between the two connecting plates.

As a preferable technical scheme of the invention, the bottom of the bracket is fixedly connected with a rotating seat, an arc-shaped connecting hole is formed in the rotating seat, a sliding seat which is in sliding connection with the sliding rail is fixedly connected onto the sliding frame, the rotating seat is connected onto the sliding seat, and a bolt rod fixedly connected with the connecting hole is arranged on the sliding seat.

The processing method of the ultra-clean precise hydrogen energy pipe adopts the processing device of the ultra-clean precise hydrogen energy pipe, and comprises the following steps:

polishing the end face of a precise pipe: the precise tube is arranged on the driving mechanism, the position of the precise tube is adjusted, so that the two polishing rollers are arranged in a splayed shape and are in contact with the end surface of the precise tube, the driving mechanism drives the precise tube to rotate, meanwhile, the reciprocating mechanism drives the sliding frame to reciprocate, the angle between the polishing rollers and the end surface of the precise tube is continuously changed when the sliding frame moves, and the inner side and the outer side of the end surface of the precise tube are polished and deburred;

polishing the surface of a precision tube: the position of the bracket is adjusted to enable the bracket to vertically face the precise tube, the position of the polishing mechanism is adjusted to enable the polishing roller to be parallel to the precise tube and contact with the surface of the precise tube, and the position of the polishing mechanism is fixed by limiting the sliding block through the limiting block; the driving mechanism drives the precise tube to rotate, and simultaneously drives the sliding frame to move back and forth through the back and forth mechanism, so that the polishing roller moves back and forth while rotating, and the surface of the precise tube is polished.

The beneficial effects of the invention are as follows:

1. according to the invention, the angle between the two grinding rollers and the precise tube can be adjusted by arranging the pair of grinding rollers, and when the two grinding rollers are arranged in a splayed shape, the end face of the precise tube is ground; when two polishing rollers are arranged in parallel with the precise tube, the surface of the precise tube is polished, so that the functionality of the polishing device is improved.

2. When the end face of the precise pipe is polished, the driving mechanism drives the precise pipe to rotate, and simultaneously drives the polishing mechanism to rotate back and forth through the back and forth mechanism, so that the angle between the polishing roller and the end face of the precise pipe is continuously changed, and burrs on the inner side and the outer side of the end face of the precise pipe are polished and removed.

Drawings

FIG. 1 is a schematic view of the polishing mechanism of the present invention for polishing burrs on the inner side of a precision pipe end surface.

Fig. 2 is a schematic diagram of the polishing mechanism of the present invention when polishing burrs on the outer side of a precision pipe end surface.

FIG. 3 is a schematic view of the polishing mechanism of the present invention polishing the surface of a precision tube.

Fig. 4 is a partial enlarged view at a in fig. 3.

Fig. 5 is a partial enlarged view at B in fig. 3.

Fig. 6 is a schematic structural view of the polishing mechanism of the present invention.

Fig. 7 is a schematic structural view of the driving mechanism of the present invention.

Fig. 8 is a schematic structural view of the round trip mechanism of the present invention.

Fig. 9 is a schematic structural view of the moving frame of the present invention.

In the figure: 1. a bottom plate; 2. a driving mechanism; 21. a driving motor; 22. a fixing seat; 23. a rotating shaft; 24. a driving roller; 25. a drive gear; 26. a limiting frame; 27. a limiting wheel; 28. adjusting a screw; 29. a support wheel; 3. a round trip mechanism; 31. a frame; 32. a moving rack; 321. a movable rod; 322. a screw block; 323. a movable frame; 324. a clamping groove; 325. a shaft lever; 326. a support rod; 327. a second tension spring; 328. a stop lever; 329. a fixed rod; 33. a guide hole; 34. a screw roller; 35. a driven gear; 36. a limit rod; 4. a bracket; 41. a rotating seat; 42. a connection hole; 5. a polishing mechanism; 51. a rotating frame; 52. a grinding roller; 53. polishing a motor; 6. a carriage; 61. a slide; 62. a bolt rod; 7. a slide rail; 8. a connecting rod; 9. a first tension spring; 10. a slide block; 11. a slide bar; 12. a connecting plate; 13. and a limiting block.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

Examples: as shown in fig. 1 to 9, the present invention is a processing apparatus for a hydrogen energy ultra-clean precision tube, comprising: the polishing device comprises a bottom plate 1, wherein a driving mechanism 2, a polishing mechanism 5, a pair of sliding rails 7 and a reciprocating mechanism 3 are arranged on the bottom plate 1, the driving mechanism 2 drives a precise tube to rotate, the polishing mechanism 5 polishes the surface and the end surface of the precise tube when the precise tube rotates, a sliding frame 6 is connected to the sliding rails 7 in a sliding manner, the reciprocating mechanism 3 drives the sliding frame 6 to reciprocate, rotatable supports 4 are symmetrically connected to the sliding frame 6, the supports 4 are of L-shaped structures, and the polishing mechanism 5 is provided with a pair and is respectively connected to the supports 4 in a rotating manner; the polishing mechanism 5 comprises a rotating frame 51, the rotating frame 51 is rotationally connected to the bracket 4, a first tension spring 9 is connected between the rotating frame 51 and the bracket 4, a polishing roller 52 and a polishing motor 53 for driving the polishing roller 52 to rotate are connected to the rotating frame 51, the polishing motor 53 and the polishing roller 52 are in gear engagement transmission, when the polishing roller 52 polishes the end face of a precision pipe, the two polishing rollers 52 are arranged in a splayed shape, the polishing roller 52 is tightly contacted with the end face of the precision pipe through the tension of the first tension spring 9, and when the sliding frame 6 moves back and forth, the angle between the two polishing rollers 52 is continuously changed due to the blocking of the precision pipe, and the contact angle between the polishing roller 52 and the precision pipe is continuously changed, so that burrs on the inner side and the outer side of the precision pipe end face are polished and removed; when the polishing roller 52 polishes the surface of the precision tube, the polishing roller 52 is disposed in parallel with the precision tube, and the polishing roller 52 is in contact with the surface of the precision tube.

As shown in fig. 4, a sliding rod 11 is fixedly connected to a sliding frame 6, a sliding block 10 is slidably connected to the sliding rod 11, a connecting rod 8 is connected between the sliding block 10 and a rotating frame 51, two sides of the sliding rod 11 are fixedly connected with a pair of connecting plates 12, a pair of limiting blocks 13 for limiting and fixing the sliding block 10 are fixedly connected between the two connecting plates 12, the limiting blocks 13 are of a U-shaped structure, strip-shaped holes are formed in the connecting plates 12, and the limiting blocks 13 are fixedly connected with the strip-shaped holes through bolt assemblies; when the polishing roller 52 polishes the surface of the precise tube, the sliding block 10 is required to be fixed through the limiting block 13, so that the polishing mechanism 5 is fixed, and the polishing roller 52 is always in contact with the surface of the precise tube; when the polishing roller 52 polishes the end face of the precision tube, the slider 10 does not need to be fixed.

As shown in fig. 5, the bottom of the bracket 4 is fixedly connected with a rotating seat 41, an arc-shaped connecting hole 42 is formed in the rotating seat 41, a sliding seat 61 slidably connected with the sliding rail 7 is fixedly connected to the sliding frame 6, the rotating seat 41 is connected to the sliding seat 61, a bolt rod 62 fixedly connected with the connecting hole 42 is arranged on the sliding seat 61, and a nut is connected to the bolt rod 62 to fix the rotating seat 41, so that the orientation of the bracket 4 is conveniently adjusted, and the polishing state of the polishing mechanism 5 is changed.

As shown in fig. 7, the driving mechanism 2 comprises a fixed seat 22, a driving motor 21 is mounted on the fixed seat 22, a rotating shaft 23 is connected to the driving motor 21, a driving roller 24 for driving the precision tube to rotate is connected to the rotating shaft 23, the driving roller 24 is in contact with the surface of the precision tube, and the driving roller 24 is made of rubber; the fixed seat 22 is symmetrically connected with a pair of movable limiting frames 26, the limiting frames 26 are arc-shaped, the fixed seat 22 is provided with sliding grooves which are in sliding connection with the limiting frames 26, the limiting frames 26 are connected with limiting wheels 27 which are used for limiting two sides of a precision tube, the limiting wheels 27 are arranged on the upper side of the precision tube, the fixed seat 22 is connected with an adjusting screw 28, one end of the adjusting screw 28 is rotationally connected with the limiting frames 26, the fixed seat 22 is connected with a pair of supporting wheels 29 which are used for supporting the precision tube, and the supporting wheels 29 are arranged on the lower side of the precision tube; the limiting frame 26 is driven to move through the adjusting screw 28, so that the limiting wheel 27 is tightly contacted with the surface of the precision tube, and the precision tube is tightly pressed.

As shown in fig. 8-9, the reciprocating mechanism 3 comprises a frame 31, a pair of screw rolls 34 are rotatably connected to the frame 31, a driven gear 35 meshed with each other is fixedly connected to one end of each screw roll 34, a driving gear 25 meshed with the driven gear 35 is connected to a rotating shaft 23, a driving motor 21 drives a precision tube to rotate and simultaneously drives the two screw rolls 34 to rotate, a movable frame 32 is slidably connected to the frame 31, the movable frame 32 is fixedly connected with the sliding frame 6, a guide hole 33 slidably connected with the movable frame 32 is formed in the frame 31, the guide hole 33 is in a strip shape, and the movable frame 32 moves back and forth along the guide hole 33; the movable rod 321 is rotatably connected to the side surface of the movable frame 32 and arranged between the two screw rolls 34, a pair of arc-shaped thread blocks 322 correspondingly matched with the screw rolls 34 are fixedly connected to the surface of the movable rod 321, the movable rod 321 rotates in different directions to enable the two thread blocks 322 to be respectively contacted with the different screw rolls 34, as the rotation directions of the two screw rolls 34 are opposite, when the different thread blocks 322 are contacted with the different screw rolls 34, the two screw rolls 34 respectively drive the movable frame 32 to move in different directions, the movable frame 323 is rotatably connected to the surface of the movable frame 32, a clamping groove 324 is fixedly connected to the movable frame 323, a shaft lever 325 matched with the clamping groove 324 is fixedly connected to the upper end surface of the movable rod 321, when the movable frame 323 rotates, the movable frame 323 is contacted with the shaft lever 324 through the clamping groove 324, the movable lever 321 is driven to rotate, a support rod 326 is rotatably connected to the surface of the movable frame 323, a second tension spring 327 is connected between the support rod 326 and the movable frame 323, and the second tension spring 327 plays a role of stabilizing the movable frame 323, so that the clamping groove 324 is contacted with the shaft lever 325 stably; a pair of stop rods 328 for limiting the support rods 326 are symmetrically and fixedly connected to the movable frame 32, a limiting rod 36 for driving the support rods 326 to rotate is fixedly connected to the frame 31, and a fixing rod 329 fixedly connected with the sliding frame 6 is fixedly connected to the movable frame 32; the operation mode of the round trip mechanism 3: when one of the screw rolls 34 drives the movable frame 32 to move, and the movable frame 32 moves to one end of the frame 31, the supporting rod 326 contacts with the limiting rod 36, the supporting rod 326 rotates to one side to the stop rod 328 due to the blocking of the limiting rod 36, the supporting rod 326 drives the movable frame 323 to rotate through the second tension spring 327, and the movable frame 323 drives the movable rod 321 to rotate to one side through the clamping groove 324 when rotating, so that the other screw block 322 contacts with the other screw roll 34, and the other screw roll 34 drives the movable frame 32 to move back due to the opposite rotation directions of the two screw rolls 34, so that the reciprocating movement of the movable frame 32 is realized, and the sliding frame 6 is driven to slide back and forth.

The embodiment also discloses a processing method of the hydrogen energy ultra-clean precise pipe processing device, which comprises the following two modes:

polishing the end face of a precise pipe: as shown in fig. 1-2, the precise tube is mounted on a driving mechanism 2, the position of the precise tube is adjusted so that two polishing rollers 52 are arranged in a splayed shape and are in contact with the end surface of the precise tube, the driving mechanism 2 drives the precise tube to rotate, meanwhile, a sliding frame 6 is driven to reciprocate by a reciprocating mechanism 3, the angle between the polishing rollers 52 and the end surface of the precise tube is continuously changed when the sliding frame 6 moves, and the inner side and the outer side of the end surface of the precise tube are polished and deburred;

polishing the surface of a precision tube: as shown in fig. 3, the position of the bracket 4 is adjusted to be vertically oriented to the precision tube, and the position of the polishing mechanism 5 is adjusted to enable the polishing roller 52 to be parallel to the precision tube and contact with the surface of the precision tube, and the position of the polishing mechanism 5 is fixed by limiting and fixing the sliding block 10 through the limiting block 13; the driving mechanism 2 drives the precise tube to rotate, and simultaneously drives the sliding frame 6 to reciprocate through the reciprocating mechanism 3, so that the polishing roller 52 rotates and reciprocates simultaneously to polish the surface of the precise tube.

Finally, it should be noted that: in the description of the present invention, it should be noted that the azimuth or positional relationship indicated by the terms "vertical", "upper", "lower", "horizontal", etc. are based on the azimuth or positional relationship shown in the drawings, and are merely for convenience of describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and thus should not be construed as limiting the present invention.

The foregoing description is only a preferred embodiment of the present invention, and the present invention is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present invention has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The utility model provides a processingequipment of ultra-clean precision tube of hydrogen energy which characterized in that includes:

the bottom plate (1), be equipped with on bottom plate (1):

the driving mechanism (2) is used for driving the precise tube to rotate;

the polishing mechanism (5) is used for polishing the surface and the end face of the precise tube;

the polishing device comprises a sliding rail (7), wherein the sliding rail (7) is connected with a sliding frame (6) in a sliding manner, rotatable brackets (4) are symmetrically connected to the sliding frame (6), and the polishing mechanism (5) is provided with a pair of polishing mechanisms which are respectively connected to the brackets (4) in a rotating manner;

the reciprocating mechanism (3) is used for driving the sliding frame (6) to slide back and forth along the sliding rail (7);

the polishing mechanism (5) comprises a rotating frame (51), the rotating frame (51) is rotationally connected to the support (4), a first tension spring (9) is connected between the rotating frame (51) and the support (4), and a polishing roller (52) and a polishing motor (53) for driving the polishing roller (52) to rotate are connected to the rotating frame (51).

2. The processing device of the hydrogen energy ultra-clean precision tube according to claim 1, wherein the driving mechanism (2) comprises a fixed seat (22), a driving motor (21) is installed on the fixed seat (22), a rotating shaft (23) is connected to the driving motor (21), and a driving roller (24) for driving the precision tube to rotate is connected to the rotating shaft (23).

3. The processing device for the ultra-clean precise tube of the hydrogen energy source according to claim 2, wherein a pair of movable limiting frames (26) are symmetrically connected to the fixed seat (22), limiting wheels (27) used for limiting two sides of the precise tube are connected to the limiting frames (26), an adjusting screw (28) is connected to the fixed seat (22), one end of the adjusting screw (28) is connected to the limiting frames (26), and a pair of supporting wheels (29) used for supporting the precise tube are connected to the fixed seat (22).

4. A processing device for a hydrogen energy ultra-clean precision tube according to claim 3, characterized in that the reciprocating mechanism (3) comprises a frame (31), a pair of screw rolls (34) are rotationally connected to the frame (31), one end of each screw roll (34) is fixedly connected with a driven gear (35) meshed with each other, a driving gear (25) meshed with the driven gear (35) is connected to the rotating shaft (23), a moving frame (32) is slidingly connected to the frame (31), the moving frame (32) is fixedly connected with the sliding frame (6), and a guide hole (33) slidingly connected with the moving frame (32) is formed in the frame (31).

5. The processing device of the hydrogen energy ultra-clean precision tube according to claim 4, wherein a movable rod (321) is rotatably connected to the side surface of the movable frame (32), the movable rod (321) is arranged between the two screw rolls (34), and a pair of arc-shaped thread blocks (322) correspondingly matched with the screw rolls (34) are fixedly connected to the surface of the movable rod (321); the movable frame (32) surface rotation is connected with movable frame (323), fixedly connected with draw-in groove (324) on movable frame (323), movable rod (321) up end fixedly connected with draw-in groove (324) complex axostylus axostyle (325), just movable frame (323) surface rotation is connected with branch (326), branch (326) with be connected with second extension spring (327) between movable frame (323).

6. The processing device for the ultra-clean precise hydrogen energy tube according to claim 5, wherein a pair of stop rods (328) for limiting the supporting rods (326) are symmetrically and fixedly connected to the movable frame (32), a limiting rod (36) for driving the supporting rods (326) to rotate is fixedly connected to the frame (31), and a fixing rod (329) fixedly connected to the sliding frame (6) is fixedly connected to the movable frame (32).

7. The processing device for the hydrogen energy ultra-clean precise tube according to claim 6, wherein a sliding rod (11) is fixedly connected to the sliding frame (6), a sliding block (10) is slidably connected to the sliding rod (11), a connecting rod (8) is connected between the sliding block (10) and the rotating frame (51), a pair of connecting plates (12) are fixedly connected to two sides of the sliding rod (11), and a pair of limiting blocks (13) for limiting and fixing the sliding block (10) are fixedly connected between the two connecting plates (12).

8. The processing device of the hydrogen energy ultra-clean precision tube according to claim 7, wherein a rotating seat (41) is fixedly connected to the bottom of the support (4), an arc-shaped connecting hole (42) is formed in the rotating seat (41), a sliding seat (61) which is in sliding connection with the sliding rail (7) is fixedly connected to the sliding frame (6), the rotating seat (41) is connected to the sliding seat (61), and a bolt rod (62) fixedly connected with the connecting hole (42) is arranged on the sliding seat (61).

9. A method for processing a hydrogen-source ultra-clean precision tube, using the apparatus for processing a hydrogen-source ultra-clean precision tube according to claim 8, comprising:

polishing the end face of a precise pipe: the precise tube is arranged on the driving mechanism (2), the position of the precise tube is adjusted, so that two polishing rollers (52) are arranged in a splayed shape and are in contact with the end surface of the precise tube, the driving mechanism (2) drives the precise tube to rotate, meanwhile, the sliding frame (6) is driven to reciprocate through the reciprocating mechanism (3), the angle between the polishing rollers (52) and the end surface of the precise tube is continuously changed when the sliding frame (6) moves, and the inner side and the outer side of the end surface of the precise tube are polished and deburred;

polishing the surface of a precision tube: the position of the bracket (4) is adjusted to enable the bracket to vertically face the precise tube, the position of the polishing mechanism (5) is adjusted to enable the polishing roller (52) to be parallel to the precise tube and contact with the surface of the precise tube, and the sliding block (10) is limited and fixed through the limiting block (13), so that the position of the polishing mechanism (5) is fixed; the driving mechanism (2) drives the precise tube to rotate, and meanwhile, the reciprocating mechanism (3) drives the sliding frame (6) to reciprocate, so that the polishing roller (52) rotates and reciprocates simultaneously to polish the surface of the precise tube.