CN115096896A

CN115096896A - Stainless steel pipe surface quality detection process

Info

Publication number: CN115096896A
Application number: CN202210702402.0A
Authority: CN
Inventors: 范淑月
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-03-03
Filing date: 2021-03-03
Publication date: 2022-09-23
Also published as: CN113029057A; CN113029057B

Abstract

The invention discloses a stainless steel pipe surface quality detection process, and belongs to the technical field of stainless steel pipe surface quality. A stainless steel pipe surface quality detection process comprises a feeding table, a separation mechanism, a detection mechanism and a clamping mechanism, wherein the separation mechanism is fixedly connected to one side of the feeding table, a detection roller is arranged, a working gear is pushed to rotate to drive a lead screw to rotate, the lead screw rotates to drive a material pushing ejector post to move through a material pushing slider, a stainless steel pipe drives a lifting inclined block to slide along a detection support through the clamping mechanism, the inclination angle of the lifting inclined block is 45 degrees, the lifting operation of the lifting inclined block is facilitated, the damage of the stainless steel pipe to the lifting inclined block is reduced, a depth gauge connected with a lifting post is driven to move through the rolling of the detection roller along the outer wall of the stainless steel pipe, the bottom end of the detection roller is equal to the central axis of the clamping mechanism in height, and the accurate detection operation of the surface quality of the stainless steel pipe is achieved.

Description

Stainless steel pipe surface quality detection process

Technical Field

The invention relates to the technical field of surface quality of stainless steel pipes, in particular to a system and a process for detecting the surface quality of a stainless steel pipe.

Background

The surface of the stainless steel pipe is not allowed to have delamination, cracks, folding, heavy skin, distortion, over-pickling and scale, the detection is carried out by a visual inspection method, the residual wall thickness at the cleaning part is not less than the minimum value allowed by the wall thickness, slight scratch, indentation and pock with the depth not exceeding the negative deviation of the wall thickness are allowed to exist, the defects such as welding seam misalignment, undercut, bulge, depression and the like are not more than the allowable deviation of the wall thickness, a professional detection device is used for carrying out size detection on the stainless steel pipe, the welding seam defect is allowed to be repaired, but the heat treatment is carried out again after the steel pipe delivered in a heat treatment state is repaired.

The weld reinforcement should meet the following specifications:

A. the outer diameter of the steel pipe is less than 133mm, and the residual height of the inner side of a welding seam is not more than 10% S;

B. a steel pipe with an outer diameter not less than 133mm but not more than 325mm, and the residual height of the inner side of a welding seam is not more than 15% S;

C. the outer diameter of the steel pipe is larger than 325mm, and the residual height of the inner side of a welding seam is not more than 20% S; but a maximum of 3 mm.

The steel pipe manufactured by adopting the double-sided automatic welding method has the advantages that the residual height of any side of the inner welding seam and the outer welding seam is flush with the base metal and is in smooth transition, or the uniform residual height is not more than 2 mm.

Through retrieval, the invention discloses a device for automatically detecting the surface quality and classification of steel pipes, which belongs to the technical field of stainless steel pipe surface quality and comprises a conveying mechanism, a clamping mechanism, a detection mechanism and a screening mechanism, wherein the detection mechanism is a Chinese patent with the application number of CN 202010650504.3; conveying mechanism includes first support and slides and sets up fixed block on the first support, the fixed block includes connecting portion and sets up the portion of placing at connecting portion both ends, set up the V type groove that is used for placing the steel pipe in the portion of placing, clamping mechanism is located the both sides of first support, clamping mechanism be used for with on the fixed block the steel pipe centre gripping is fixed, detection mechanism be used for with clamping mechanism is fixed the steel pipe detects, screening mechanism is used for detecting the completion the steel pipe is sorted. According to the invention, the laser sensor or the linear camera is arranged to move along the direction parallel to the steel pipe, so that the straightness and the like of the steel pipe are measured, and after the measurement is finished, the steel pipe is conveyed to the screening mechanism by the conveying mechanism, so that the labor intensity of personnel is reduced, the speed is high, and the operation is convenient.

The problem that the diameters of all parts of the stainless steel pipe cannot be detected occurs in the device for automatically detecting the surface quality and classification of the steel pipe in the patent, so that the detection efficiency of the surface quality of the stainless steel pipe is low, the requirements of people cannot be met, and therefore a system and a detection process for detecting the surface quality of the stainless steel pipe are needed.

Disclosure of Invention

The invention aims to solve the problem that the diameter of each part of a stainless steel pipe cannot be detected in the prior art, and provides a system and a process for detecting the surface quality of the stainless steel pipe.

In order to achieve the purpose, the invention adopts the following technical scheme:

a stainless steel pipe surface quality detection system comprises a feeding table, a separating mechanism, a detection mechanism and a clamping mechanism, wherein one side of the feeding table is fixedly connected with the separating mechanism, one end of the separating mechanism, far away from the feeding table, is fixedly connected with the detection mechanism, the inner wall of the detection mechanism is fixedly connected with an electric push rod, the output end of the electric push rod is fixedly connected with a push plate, one end of the push plate, far away from the electric push rod, is movably connected with a swing orifice plate screwed with the inner wall of the detection mechanism, a swing chute is formed at the connecting part of the swing orifice plate and the push plate, one end of the swing orifice plate, far away from the inner wall of the detection mechanism, is movably connected with a sliding deflector rod which is slidably connected with the inner wall of the detection mechanism, a sliding chute is formed at the connecting part of the sliding deflector rod and the swing orifice plate, one end, far away from the sliding chute, is movably and fixedly connected with a guide cylinder penetrates through the interior of the guide cylinder, a rotating main shaft penetrates through the switching cylinder barrel, a servo motor fixedly connected with the inner wall of the detection mechanism is arranged at one end of the rotating main shaft, a separating gear is fixedly connected with the outer wall of the rotating main shaft, a separating sliding gear fixedly connected with the switching cylinder barrel is arranged outside the separating gear, a separating working gear in screwed connection with the inner wall of the detection mechanism is arranged on the meshing surface of the separating sliding gear, a clamping gear is fixedly connected with one end of the rotating main shaft far away from the separating gear, a clamping sliding gear fixedly connected with the switching cylinder barrel is meshed with the outside of the clamping gear, a clamping working gear in screwed connection with the inner wall of the detection mechanism is arranged on the meshing surface of the clamping sliding gear, a clamping mechanism is arranged on the meshing surface of the clamping working gear, and a pushing gear is fixedly connected between the separating gear and the clamping gear on the middle outer wall of the rotating main shaft, a pushing sliding gear fixedly connected with the switching cylinder is meshed with the outer part of the pushing gear, a pushing working gear screwed with the inner wall of the detection mechanism is arranged on the meshing surface of the pushing sliding gear, a lead screw penetrates through the inner part of the pushing working gear, a pushing sliding block slidably connected with the detection mechanism is connected with the outer wall of the top end of the pushing sliding block, a pushing ejection post is fixedly connected with the outer wall of the top end of the pushing ejection post, a pushing plate fixedly connected with the pushing sliding block is fixedly connected below the clamping mechanism below the pushing ejection post, one end of the pushing plate, far away from the pushing ejection post, extends to the outer part of the detection mechanism, a blanking table is arranged above the blanking table and is fixedly connected with a detection bracket on the outer wall of the clamping mechanism, a lifting column penetrates through the inner part of the detection bracket, a depth gauge is arranged above the lifting column, and a compression spring is arranged below the detection bracket on the outer wall of the lifting column, and the lower part of the compression spring is fixedly connected with a lifting inclined block which is connected with the outer wall of the detection support in a sliding manner, and the bottom end of the lifting inclined block is screwed with a detection roller.

Preferably, the swing pore plate forms a swing structure with the detection mechanism through the push plate and the swing sliding chute, the swing angle of the swing pore plate is 60 degrees, the sliding deflector rod forms a sliding structure with the detection mechanism through the swing pore plate and the sliding chute, and the sliding length of the sliding deflector rod is twice of the thickness of the separation gear.

Preferably, the axis of guide cylinder coincides with the axis of switching cylinder, and the inner wall of guide cylinder laminates with the outer wall of switching cylinder mutually, the axis of switching cylinder coincides with the axis of rotating the main shaft mutually, and the inner wall of switching cylinder laminates with the outer wall of rotating the main shaft mutually.

Preferably, the inner wall of the separating sliding gear is provided with teeth which are matched with the separating gear, the inner wall of the clamping sliding gear is provided with teeth which are matched with the clamping gear, the distance from the clamping sliding gear to the clamping gear is equal to twice the thickness of the clamping gear, the inner wall of the pushing sliding gear is provided with teeth which are matched with the pushing gear, the distance from the pushing sliding gear to the pushing gear is equal to the thickness of the pushing gear, and the thickness of the separating gear, the thickness of the separating sliding gear, the thickness of the clamping sliding gear, the thickness of the pushing gear and the thickness of the pushing sliding gear are equal.

Preferably, the lifting oblique block is provided with an inclined plane with an inclination angle of 45 degrees, the side face of the detection roller is provided with an inclined plane tangent to the inclined plane of the lifting oblique block, the lifting oblique block and the compression spring form a lifting structure with the detection support through the lifting column, and the bottom end of the detection roller is equal to the central axis of the clamping mechanism in height.

Preferably, the separating mechanism comprises a separating rotating shaft, a threaded rod, a threaded slider, a rotating bent plate, a rotating chute, a flat moving plate, a separating plate, a flat moving pore plate, a supporting rod, a connecting rod and a sector gear, the separating rotating shaft penetrating through the separating working gear is arranged outside the separating mechanism, the threaded rod is arranged at one end of the separating rotating shaft, the threaded slider in sliding connection with the inner wall of the separating mechanism is in threaded connection with the outer wall of the threaded rod, the rotating bent plate in screwed connection with the inner wall of the separating mechanism is movably connected with the side wall of the threaded slider, the rotating chute is arranged at the connecting part of the rotating bent plate and the threaded slider, the flat moving plate is screwed at one end of the rotating bent plate far away from the rotating chute, the separating plate in sliding connection with the inner wall of the separating mechanism is in sliding connection with the side wall of the flat moving plate, the connecting part of the separating plate and the flat moving plate is provided with a flat moving, and the supporting rod is screwed at one end of the flat moving pore plate far away from the rotating bent plate, and the connecting rod is screwed at the connecting part of one end of the supporting rod far away from the translational plate and the rotating bent plate, and the sector gear is fixedly connected on the outer wall of the supporting rod close to the connecting rod.

Preferably, the threaded rods are provided with two groups, the position relationship of the two groups of threaded rods is symmetrical about the partition plate, the rotating bent plate forms a rotating structure through the threaded sliding blocks and the rotating sliding chutes, the rotating angle of the rotating bent plate is 90 degrees, the partition plate forms a lifting structure through the translation plate and the translation pore plate and the partition mechanism, the lifting height of the partition plate is 1.4 times that of the support rod, the two groups of partition plates are provided, and the position relationship of the two groups of partition plates is symmetrical about the sector gear.

Preferably, the clamping mechanism comprises a transmission gear, a reduction gear, a rotating cylinder, a clamping rod, a clamping chute and a clamping roller, the transmission gear meshed with the meshing surface of the clamping working gear is arranged inside the clamping mechanism, the reduction gear is meshed with one end, away from the clamping working gear, of the transmission gear, the rotating gear is meshed with one end, away from the transmission gear, of the reduction gear, the rotating cylinder is fixedly connected to the inner wall of the rotating gear and slidably connected with the inner wall of the clamping mechanism, the clamping rod movably connected with the inner wall of the clamping mechanism is screwed on the inner wall of the rotating cylinder, the clamping chute is formed in the connecting position of the clamping rod and the clamping mechanism, and the clamping roller is screwed on one end, away from the rotating cylinder, of the clamping rod.

Preferably, the central axis of the rotating gear coincides with the central axis of the rotating cylinder, six groups of clamping rods are arranged, the position relation of the six groups of clamping rods is distributed in an equiangular circumference mode about the central axis of the clamping mechanism, and the clamping rollers form a rotary clamping structure with the clamping rods and the clamping mechanism through the rotating cylinder.

The scheme also provides a detection process of the stainless steel pipe surface quality detection system, and the method comprises the following steps:

s1, when the device is used, firstly, orderly feeding operation of stainless steel pipes is carried out, workers place the stainless steel pipes on a feeding table, a separating mechanism works to drive a separating plate to move, a servo motor works to drive a rotating main shaft to rotate, the rotating main shaft rotates to drive a separating gear to rotate, the separating gear drives a separating working gear to rotate by being meshed with a separating sliding gear, the separating working gear rotates to drive a threaded rod to rotate through a separating rotating shaft, the threaded rod drives a threaded slider to move, the threaded slider drives a rotating bent plate to rotate through a rotating chute, the rotating bent plate drives a flat movable plate to move through a supporting rod, the flat movable plate drives the separating plate to move up and down through a flat movable hole plate, and a sector gear on the supporting rod drives two groups of separating plates to move up and down relatively to finish the orderly feeding operation of the stainless steel pipes;

s2, carrying out switching operation of transmission of the rotating main shaft, wherein in the detection mechanism, an electric push rod works to drive a push plate to move and drive a swing orifice plate to swing through a swing sliding groove, the swing orifice plate drives a sliding deflector rod to move through a sliding groove, and the sliding deflector rod drives a switching cylinder barrel to move through a guide cylinder, so that the switching operation of transmission of the rotating main shaft is completed;

s3, performing the pushing operation of the stainless steel pipe, switching the cylinder motion to enable the pushing sliding gear to be meshed with the pushing gear, pushing the sliding gear to rotate to drive the pushing working gear to rotate, pushing the working gear to rotate to drive the pushing sliding block to move through the lead screw, driving the pushing ejection column on the pushing plate to move through the movement of the pushing sliding block, and driving the stainless steel pipe to pass through the inside of the clamping mechanism through the pushing ejection column;

s4, centering, clamping and rotating the stainless steel pipe, switching cylinder barrel movement to enable a clamping sliding gear to be meshed with a clamping gear to drive a clamping working gear to rotate, driving a reduction gear to rotate through a transmission gear, driving a rotating gear to rotate through the reduction gear, driving a rotating cylinder barrel to rotate through the rotating gear, driving six groups of clamping rods to move through a clamping sliding groove, driving six groups of clamping rods to rotate to drive a clamping roller to move, completing centering and clamping operation on the stainless steel pipe through the six groups of clamping rollers, and driving the stainless steel pipe to rotate through the rotating gear after clamping;

and S5, finally, performing surface quality detection operation on the stainless steel pipe, wherein the stainless steel pipe moves to drive the lifting inclined block to slide along the detection support, the stainless steel pipe is clamped and rotated by the clamping mechanism, the detection roller rolls along the outer wall of the stainless steel pipe to drive the lifting column to move, the lifting amount of the lifting column is detected by the depth gauge to detect the surface quality of the stainless steel pipe, the surface quality operation on the stainless steel pipe is completed, and after the detection is finished, the stainless steel pipe is placed on the blanking table.

Compared with the prior art, the invention provides a stainless steel pipe surface quality detection system and a detection process, which have the following beneficial effects:

1. the stainless steel pipe surface quality detection system and the detection process have the advantages that the rotating bent plates are arranged, the separating rotating shaft is rotated to drive the threaded rods to rotate in the separating mechanism, the threaded rods are provided with two groups, the threaded rods rotate to drive the threaded sliders to slide along the inner walls of the separating mechanism, the threaded sliders slide to drive the rotating bent plates to rotate through the rotating chutes, the rotating angles of the rotating bent plates are 90 degrees, the rotating bent plates rotate to drive the translation plates to move, the translation plates enable the translation plates to stably move through the supporting rods, the translation plates drive the partition plates to move through sliding along the inner walls of the translation hole plates, the lifting heights of the partition plates are 1.4 times of the supporting rods, the two groups of partition plates are driven by the supporting rods through the sector gears to move, and ordered feeding operation of the stainless steel pipes is achieved;

2. according to the stainless steel pipe surface quality detection system and the detection process, the switching cylinder barrel is arranged, in the detection mechanism, the electric push rod works to drive the push plate to move, the push plate moves to drive the swing orifice plate to swing through the swing chute, the swing angle of the swing orifice plate is 60 degrees, the swing orifice plate drives the sliding deflector rod to move through the sliding chute, the sliding length of the sliding deflector rod is twice of the thickness of the separation gear, the sliding deflector rod drives the switching cylinder barrel through the guide barrel, the switching operation of transmission of the rotating main shaft is realized, and the switching of detection operation on the diameter of each part of the stainless steel pipe is convenient to realize;

3. according to the stainless steel pipe surface quality detection system and the detection process, a clamping rod is arranged, a transmission gear rotates to drive a reduction gear to rotate in a clamping mechanism, the reduction gear rotates to drive a rotating gear, the transmission ratio of the gear is changed, the rotating gear rotates to drive a rotating cylinder to rotate, the rotating cylinder rotates to drive the clamping rod to move through a clamping chute, six groups of clamping rods are arranged, the clamping rods rotate to drive clamping rollers to move, the clamping operation on a stainless steel pipe is completed through the movement of the six groups of clamping rollers, and the rotating gear rotates to drive the stainless steel pipe to rotate after clamping, so that the diameter detection operation on each part of the stainless steel pipe is realized;

4. according to the stainless steel pipe surface quality detection system and the detection process, the detection roller wheel is arranged, the working gear is pushed to rotate to drive the lead screw to rotate, the lead screw rotates to drive the pushing ejector pin to move through the pushing sliding block, the stainless steel pipe drives the lifting inclined block to slide along the detection support through the clamping mechanism, the inclination angle of the lifting inclined block is 45 degrees, the lifting operation of the lifting inclined block is facilitated, the damage of the stainless steel pipe to the lifting inclined block is reduced, the detection roller wheel rolls along the outer wall of the stainless steel pipe to drive the depth gauge connected with the lifting column to move, the bottom end of the detection roller wheel is equal to the central axis of the clamping mechanism in height, and the accurate detection operation of the surface quality of the stainless steel pipe is achieved.

Drawings

FIG. 1 is a schematic view of the overall external structure of a stainless steel pipe surface quality detection system and detection process according to the present invention;

FIG. 2 is a schematic view of an overall internal first view structure of a stainless steel pipe surface quality detection system and detection process according to the present invention;

FIG. 3 is a schematic view of a second view structure of the whole interior of the stainless steel pipe surface quality detection system and detection process according to the present invention;

FIG. 4 is a schematic view of the internal structure of a partition mechanism of the stainless steel pipe surface quality detection system and detection process according to the present invention;

FIG. 5 is a schematic diagram of the external connection structure of the switching cylinder of the stainless steel pipe surface quality detection system and detection process provided by the present invention;

FIG. 6 is a schematic view of the internal connection structure of the switching cylinder of the stainless steel pipe surface quality detection system and detection process provided by the present invention;

FIG. 7 is a schematic view of the internal structure of a clamping mechanism of the stainless steel pipe surface quality detection system and detection process provided by the present invention;

FIG. 8 is a schematic side view of a clamping mechanism of the stainless steel pipe surface quality detection system and detection process according to the present invention;

fig. 9 is a schematic view of a connection structure of a detection bracket of the stainless steel pipe surface quality detection system and detection process provided by the invention.

In the figure: 1. a feeding table; 2. a separation mechanism; 201. a partition rotating shaft; 202. a threaded rod; 203. a threaded slider; 204. rotating the bent plate; 205. rotating the chute; 206. a translation plate; 207. a partition plate; 208. a translational pore plate; 209. a support bar; 210. a connecting rod; 211. a sector gear; 3. a detection mechanism; 4. an electric push rod; 5. pushing the plate; 6. oscillating the orifice plate; 7. a swing chute; 8. a sliding deflector rod; 9. a sliding chute; 10. a guide cylinder; 11. switching the cylinder barrel; 12. rotating the main shaft; 13. a servo motor; 14. a partition gear; 15. a divided sliding gear; 16. separating the working gears; 17. clamping the gear; 18. clamping the sliding gear; 19. clamping the working gear; 20. a clamping mechanism; 2001. a transmission gear; 2002. a reduction gear; 2003. a rotating gear; 2004. rotating the cylinder barrel; 2005. a clamping lever; 2006. clamping the chute; 2007. clamping the roller; 21. a push gear; 22. pushing the sliding gear; 23. pushing the working gear; 24. a screw rod; 25. a material pushing slide block; 26. pushing a material top column; 27. a material pushing plate; 28. a blanking table; 29. detecting the bracket; 30. a lifting column; 31. a depth gauge; 32. a compression spring; 33. a lifting inclined block; 34. and detecting the roller.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1-9, a stainless steel pipe surface quality detection system comprises a feeding table 1, a separating mechanism 2, a detection mechanism 3 and a clamping mechanism 20, wherein one side of the feeding table 1 is fixedly connected with the separating mechanism 2, one end of the separating mechanism 2 far away from the feeding table 1 is fixedly connected with the detection mechanism 3, the inner wall of the detection mechanism 3 is fixedly connected with an electric push rod 4, the output end of the electric push rod 4 is fixedly connected with a push plate 5, one end of the push plate 5 far away from the electric push rod 4 is movably connected with a swing orifice plate 6 screwed with the inner wall of the detection mechanism 3, a swing chute 7 is arranged at the connecting part of the swing orifice plate 6 and the push plate 5, one end of the swing orifice plate 6 far away from the inner wall of the detection mechanism 3 is movably connected with a sliding deflector rod 8 connected with the inner wall of the detection mechanism 3, and a sliding chute 9 is arranged at the connecting part of the sliding deflector rod 8 and the swing orifice plate 6, a guide cylinder 10 is movably and fixedly connected with one end of the sliding deflector rod 8 far away from the sliding chute 9, a switching cylinder barrel 11 penetrates through the interior of the guide cylinder 10, a rotating main shaft 12 penetrates through the interior of the switching cylinder barrel 11, a servo motor 13 fixedly connected with the inner wall of the detection mechanism 3 is arranged at one end of the rotating main shaft 12, a separation gear 14 is fixedly connected with the outer wall of the rotating main shaft 12, a separation sliding gear 15 fixedly connected with the switching cylinder barrel 11 is arranged outside the separation gear 14, a separation working gear 16 screwed with the inner wall of the detection mechanism 3 is arranged on the meshing surface of the separation sliding gear 15, a clamping gear 17 is fixedly connected with one end of the rotating main shaft 12 far away from the separation gear 14, a clamping sliding gear 18 fixedly connected with the switching cylinder barrel 11 is meshed with the exterior of the clamping gear 17, a clamping working gear 19 screwed with the inner wall of the detection mechanism 3 is arranged on the meshing surface of the clamping sliding gear 18, a clamping mechanism 20 is arranged on the meshing surface of the clamping working gear 19, a pushing gear 21 is fixedly connected between the separating gear 14 and the clamping gear 17 on the outer wall of the middle of the rotating main shaft 12, a pushing sliding gear 22 fixedly connected with the switching cylinder 11 is meshed on the outer portion of the pushing gear 21, a pushing working gear 23 in screwed connection with the inner wall of the detection mechanism 3 is arranged on the meshing surface of the pushing sliding gear 22, a lead screw 24 penetrates through the pushing working gear 23, a pushing sliding block 25 in sliding connection with the detection mechanism 3 is connected to the outer wall of the lead screw 24, a pushing ejection column 26 is fixedly connected to the outer wall of the top end of the pushing sliding block 25, a pushing plate 27 fixedly connected with the pushing sliding block 25 is fixedly connected below the clamping mechanism 20 below the pushing ejection column 26, and a blanking table 28 is arranged on the outer portion of the detection mechanism 3, wherein one end of the pushing plate 27, far away from the pushing ejection column 26, and the upper side of the blanking table 28 is fixedly connected with a detection support 29 on the outer wall of the clamping mechanism 20, a lifting column 30 penetrates through the detection support 29, a depth gauge 31 is arranged on the top end of the lifting column 30 above the detection support 29, a compression spring 32 is arranged on the outer wall of the lifting column 30 below the detection support 29, a lifting oblique block 33 which is connected with the outer wall of the detection support 29 in a sliding manner is fixedly connected on the top end of the lifting column 30 below the compression spring 32, and a detection roller 34 is screwed on the bottom end of the lifting oblique block 33.

Furthermore, the swing pore plate 6 forms a swing structure with the detection mechanism 3 through the push plate 5 and the swing chute 7, the swing angle of the swing pore plate 6 is 60 degrees, the sliding deflector rod 8 forms a sliding structure with the detection mechanism 3 through the swing pore plate 6 and the sliding chute 9, the sliding length of the sliding deflector rod 8 is twice of the thickness of the separation gear 14, the push plate 5 moves to drive the swing pore plate 6 to swing through the swing chute 7, the swing pore plate 6 swings to drive the guide cylinder 10 on the sliding deflector rod 8 to move through the sliding chute 9, and the guide cylinder 10 drives the switching cylinder barrel 11 to slide along the rotating main shaft 12, so that the switching operation of the switching cylinder barrel 11 is facilitated, and the switching control operation of the transmission of the rotating main shaft 12 is realized;

further, the central axis of the guide cylinder 10 coincides with the central axis of the switching cylinder 11, the inner wall of the guide cylinder 10 is attached to the outer wall of the switching cylinder 11, the central axis of the switching cylinder 11 coincides with the central axis of the rotating main shaft 12, the inner wall of the switching cylinder 11 is attached to the outer wall of the rotating main shaft 12, and the guide cylinder 10 drives the switching cylinder 11 to stably slide along the rotating main shaft 12, so that stable switching operation of the switching cylinder 11 is facilitated, and stable switching control operation of transmission of the rotating main shaft 12 is realized;

furthermore, the inner wall of the separating sliding gear 15 is provided with teeth which are matched with the separating gear 14, the inner wall of the clamping sliding gear 18 is provided with teeth which are matched with the clamping gear 17, the distance from the clamping sliding gear 18 to the clamping gear 17 is equal to twice the thickness of the clamping gear 17, the inner wall of the pushing sliding gear 22 is provided with teeth which are matched with the pushing gear 21, the distance from the pushing sliding gear 22 to the pushing gear 21 is equal to the thickness of the pushing gear 21, the thickness of the separating gear 14, the thickness of the separating sliding gear 15, the thickness of the clamping gear 17, the thickness of the clamping sliding gear 18, the thickness of the pushing gear 21 and the thickness of the pushing sliding gear 22 are equal, the switching cylinder 11 moves to drive the separating sliding gear 15, the clamping sliding gear 18 and the pushing sliding gear 22 to move, the separating sliding gear 15 is meshed with the separating gear 14 to drive the separating working gear 16 to rotate, the separation operation of the separation mechanism 2 is realized, the clamping sliding gear 18 is meshed with the clamping gear 17 to drive the clamping working gear 19, the clamping operation of the clamping mechanism 20 is realized, and the pushing sliding gear 22 is meshed with the pushing gear 21 to realize the transmission operation of the pushing working gear 23 driving the screw rod 24;

furthermore, the inclined plane with an inclination angle of 45 degrees is arranged on the lifting inclined block 33, the inclined plane tangent to the inclined plane of the lifting inclined block 33 is arranged on the side surface of the detection roller 34, the lifting inclined block 33 forms a lifting structure with the detection support 29 through the lifting column 30 and the compression spring 32, the bottom end of the detection roller 34 is equal to the central axis of the clamping mechanism 20 in height, the stainless steel pipe drives the lifting inclined block 33 to slide along the detection support 29 through the material pushing slider 25, and the depth gauge 31 realizes the detection operation of the surface quality of the stainless steel pipe through the lifting operation of the lifting inclined block 33;

further, the separating mechanism 2 comprises a separating rotating shaft 201, a threaded rod 202, a threaded slider 203, a rotating bent plate 204, a rotating chute 205, a flat moving plate 206, a separating plate 207, a flat moving orifice plate 208, a support rod 209, a connecting rod 210 and a sector gear 211, the separating rotating shaft 201 penetrating through the separating working gear 16 is arranged outside the separating mechanism 2, one end of the separating rotating shaft 201 is provided with the threaded rod 202, the outer wall of the threaded rod 202 is in threaded connection with the threaded slider 203 in sliding connection with the inner wall of the separating mechanism 2, the side wall of the threaded slider 203 is movably connected with the rotating bent plate 204 screwed with the inner wall of the separating mechanism 2, the connecting part of the rotating bent plate 204 and the threaded slider 203 is provided with the rotating chute 205, one end of the rotating bent plate 204 far away from the rotating chute 205 is screwed with the flat moving plate 206, and the side wall of the flat moving plate 206 is in sliding connection with the separating plate 207 in sliding connection with the inner wall of the separating mechanism 2, a translational pore plate 208 is arranged at the connecting part of the separation plate 207 and the translational plate 206, a support rod 209 is screwed at one end of the translational pore plate 208 far away from the rotating bent plate 204, a connecting rod 210 is screwed at the connecting part of one end of the support rod 209 far away from the translational plate 206 and the rotating bent plate 204, a sector gear 211 is fixedly connected to the outer wall of the support rod 209 close to the connecting rod 210, a threaded rod 202 is driven to rotate by rotating a separation rotating shaft 201, the threaded rod 202 rotates to drive the rotating bent plate 204 to rotate through a threaded sliding block 203 and a rotating sliding groove 205, the rotating bent plate 204 drives the translational plate 206 to move through the support rod 209, the translational plate 206 drives the separation plate 207 to move through the translational pore plate 208, and the ordered feeding operation of the stainless steel pipes is realized through the lifting movement of the separation plate 207;

furthermore, two sets of threaded rods 202 are arranged, the position relationship of the two sets of threaded rods 202 is symmetrical about the separation plate 207, the rotating bent plate 204 forms a rotating structure with the separation mechanism 2 through the threaded sliding block 203 and the rotating chute 205, the rotating angle of the rotating bent plate 204 is 90 degrees, the separation plate 207 forms a lifting structure with the separation mechanism 2 through the translation plate 206 and the translation orifice plate 208, the lifting height of the separation plate 207 is 1.4 times of that of the support rod 209, the two sets of separation plates 207 are arranged, the position relationship of the two sets of separation plates 207 is symmetrical about the sector gear 211, the two sets of threaded rods 202 are driven to rotate through the rotation of the separation rotating shaft 201, the two sets of threaded rods 202 rotate to drive the rotating bent plate 204 to rotate through the threaded sliding block 203 and the rotating chute 205, the rotating bent plate 204 drives the translation plate 206 to move through the support rod 209, the support rod 209 drives the two sets of translation plates 206 to move through the sector gear 211, the two groups of translation plates 206 drive the two-component partition plates 207 to move through the translation pore plates 208, and the ordered feeding operation of the stainless steel pipes is realized through the lifting motion of the two-component partition plates 207;

further, the clamping mechanism 20 comprises a transmission gear 2001, a reduction gear 2002, a rotation gear 2003, a rotation cylinder 2004, a clamping rod 2005, a clamping sliding groove 2006 and a clamping roller 2007, a transmission gear 2001 meshed with the meshing surface of the clamping working gear 19 is arranged inside the clamping mechanism 20, one end of the transmission gear 2001 far away from the clamping working gear 19 is meshed with the reduction gear 2002, one end of the reduction gear 2002 far away from the transmission gear 2001 is meshed with the rotation gear 2003, the inner wall of the rotation gear 2003 is fixedly connected with the rotation cylinder 2004 in sliding connection with the inner wall of the clamping mechanism 20, the inner wall of the rotation cylinder 2004 is screwed with the clamping rod 2005 movably connected with the inner wall of the clamping mechanism 20, the connecting part of the clamping rod 2005 and the clamping mechanism 20 is provided with the clamping sliding groove 2006, one end of the clamping rod 2005 far away from the rotation cylinder 2004 is screwed with the clamping roller 2007, the clamping working gear 19 rotates to drive the transmission gear 2001 to rotate, the transmission gear 2001 rotates to drive the rotating gear 2003 to rotate through the reduction gear 2002, the rotating gear 2003 rotates to drive the clamping rod 2005 to move through the rotating cylinder barrel 2004, the clamping rod 2005 drives the clamping roller 2007 to move through the clamping sliding groove 2006, the clamping roller 2007 moves to realize clamping operation on the stainless steel pipe, and after clamping is performed, the rotating gear 2003 rotates to drive the stainless steel pipe to realize rotating operation, so that surface quality detection operation on the stainless steel pipe is realized;

further, the central axis of the rotating gear 2003 coincides with the central axis of the rotating cylinder 2004, six groups of clamping rods 2005 are arranged, the positional relationship of the six groups of clamping rods 2005 is distributed in an equiangular circumference with respect to the central axis of the clamping mechanism 20, a rotary clamping structure is formed by the clamping rollers 2007 and the clamping rods 2005 through the rotating cylinder 2004 and the clamping mechanism 20, the rotating gear 2003 rotates to drive the clamping rods 2005 to move through the rotating cylinder 2004, the clamping rods 2005 drive the clamping rollers 2007 to move through the clamping chutes 2006, the clamping rollers 2007 move, and centering clamping operation on the stainless steel pipe is achieved;

the embodiment also provides a use scheme of the stainless steel pipe surface quality detection system, and the device is adopted, and the method comprises the following steps:

s1, when the device is used, firstly, orderly feeding operation of stainless steel pipes is carried out, a worker places the stainless steel pipes on a feeding table 1, a separating mechanism 2 works to drive a separating plate 207 to move, a servo motor 13 works to drive a rotating main shaft 12 to rotate, the rotating main shaft 12 rotates to drive a separating gear 14 to rotate, the separating gear 14 drives a separating working gear 16 to rotate by being meshed with a separating sliding gear 15, the separating working gear 16 rotates to drive a threaded rod 202 to rotate by rotating a separating rotating shaft 201, the threaded rod 202 drives a threaded slider 203 to move, the threaded slider 203 drives a rotating bent plate 204 to rotate by a rotating chute 205, the rotating bent plate 204 drives a flat movable plate 206 to move by a supporting rod 209, the flat movable plate 206 drives the separating plate 207 to do lifting motion by a flat hole plate 208, and drives two component separating plates 207 to do relative lifting motion by a sector gear 211 on the supporting rod 209, finishing the ordered feeding operation of the stainless steel pipe;

s2, carrying out switching operation of transmission of the rotating main shaft 12, in the detection mechanism 3, enabling the electric push rod 4 to work to drive the push plate 5 to move to drive the swing orifice plate 6 to swing through the swing chute 7, enabling the swing orifice plate 6 to drive the sliding deflector rod 8 to move through the sliding chute 9, and enabling the sliding deflector rod 8 to drive the switching cylinder barrel 11 to move through the guide barrel 10, so that switching operation of transmission of the rotating main shaft 12 is completed;

s3, performing the pushing operation of the stainless steel pipe, switching the movement of the cylinder 11 to enable the pushing sliding gear 22 to be meshed with the pushing gear 21, pushing the sliding gear 22 to rotate to drive the pushing working gear 23 to rotate, pushing the working gear 23 to rotate to drive the pushing slider 25 to move through the screw rod 24, driving the pushing plunger 25 to move to drive the pushing plunger 26 on the pushing plate 27 to move, and driving the stainless steel pipe to pass through the inside of the clamping mechanism 20 through the pushing plunger 26;

s4, centering, clamping and rotating the stainless steel pipe, switching the movement of the cylinder barrel 11 to enable the clamping sliding gear 18 to be meshed with the clamping gear 17 to drive the clamping working gear 19 to rotate, driving the reduction gear 2002 to rotate through the transmission gear 2001, driving the rotation gear 2003 to rotate through the rotation of the reduction gear 2002, driving the rotation of the rotation cylinder barrel 2004 to rotate, driving six groups of clamping rods 2005 to move through the rotation of the clamping chute 2006, driving the clamping rollers 2007 to move through the rotation of the six groups of clamping rollers 2005, completing the centering and clamping operation on the stainless steel pipe, and driving the stainless steel pipe to rotate through the rotation of the rotation gear 2003 after clamping;

and S5, finally, performing surface quality detection operation on the stainless steel pipe, wherein the stainless steel pipe moves to drive the lifting inclined block 33 to slide along the detection bracket 29, the stainless steel pipe is clamped and rotated by the clamping mechanism 20, the detection roller 34 rolls along the outer wall of the stainless steel pipe to drive the lifting column 30 to move, the lifting amount of the lifting column 30 detected by the depth gauge 31 detects the surface quality of the stainless steel pipe, the surface quality operation on the stainless steel pipe is completed, and the stainless steel pipe is placed on the blanking table 28 after the detection is completed.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered as the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims

1. The utility model provides a stainless steel pipe surface quality detecting system, includes material loading platform (1), separating mechanism (2), detection mechanism (3) and clamping mechanism (20), its characterized in that: one side of the feeding table (1) is fixedly connected with a separating mechanism (2), one end of the separating mechanism (2) far away from the feeding table (1) is fixedly connected with a detection mechanism (3), the inner wall of the detection mechanism (3) is fixedly connected with an electric push rod (4), the output end of the electric push rod (4) is fixedly connected with a push plate (5), one end of the push plate (5) far away from the electric push rod (4) is movably connected with a swing orifice plate (6) screwed with the inner wall of the detection mechanism (3), the connecting part of the swing orifice plate (6) and the push plate (5) is provided with a swing chute (7), one end of the swing orifice plate (6) far away from the inner wall of the detection mechanism (3) is movably connected with a sliding shift lever (8) slidably connected with the inner wall of the detection mechanism (3), and the connecting part of the sliding shift lever (8) and the swing orifice plate (6) is provided with a sliding chute (9), the device is characterized in that a guide cylinder (10) is movably and fixedly connected to one end, far away from a sliding chute (9), of the sliding shifting rod (8), a switching cylinder (11) penetrates through the guide cylinder (10), a rotating main shaft (12) penetrates through the switching cylinder (11), a servo motor (13) fixedly connected with the inner wall of the detection mechanism (3) is arranged at one end of the rotating main shaft (12), a separating gear (14) is fixedly connected to the outer wall of the rotating main shaft (12), a separating sliding gear (15) fixedly connected with the switching cylinder (11) is arranged outside the separating gear (14), a separating working gear (16) connected with the inner wall of the detection mechanism (3) in a screwed mode is arranged on the meshing surface of the separating sliding gear (15), a clamping gear (17) is fixedly connected to one end, far away from the separating gear (14), of the rotating main shaft (12), of the clamping gear (17), and a clamping sliding gear (18) fixedly connected with the switching cylinder (11) is meshed with the outer portion of the clamping gear (17) ) A clamping working gear (19) which is screwed with the inner wall of the detection mechanism (3) is arranged on the meshing surface of the clamping sliding gear (18), a clamping mechanism (20) is arranged on the meshing surface of the clamping working gear (19), a pushing gear (21) is fixedly connected between the separating gear (14) and the clamping gear (17) on the outer wall of the middle of the rotating main shaft (12), a pushing sliding gear (22) which is fixedly connected with the switching cylinder barrel (11) is meshed with the outer portion of the pushing gear (21), a pushing working gear (23) which is screwed with the inner wall of the detection mechanism (3) is arranged on the meshing surface of the pushing sliding gear (22), a lead screw (24) penetrates through the inner portion of the pushing working gear (23), a material pushing sliding block (25) which is connected with the detection mechanism (3) in a sliding mode is connected to the outer wall of the lead screw (24), and a material pushing ejection column (26) is fixedly connected to the outer wall of the top end of the material pushing sliding block (25), a material pushing plate (27) fixedly connected with a material pushing slider (25) is fixedly connected below the clamping mechanism (20) below the material pushing ejection column (26), one end, far away from the material pushing ejection column (26), of the material pushing plate (27) extends to the outside of the detection mechanism (3) and is provided with a blanking table (28), a detection support (29) is fixedly connected on the outer wall of the clamping mechanism (20) above the blanking table (28), a lifting column (30) penetrates through the inside of the detection support (29), a depth gauge (31) is arranged above the detection support (29) at the top end of the lifting column (30), a compression spring (32) is arranged below the detection support (29) on the outer wall of the lifting column (30), and a lifting inclined block (33) in sliding connection with the outer wall of the detection support (29) is fixedly connected at the top end of the lifting column (30) below the compression spring (3), the bottom end of the lifting inclined block (33) is screwed with a detection roller (34);

the swing pore plate (6) and the detection mechanism (3) form a swing structure through the push plate (5) and the swing sliding chute (7), the swing angle of the swing pore plate (6) is 60 degrees, the sliding deflector rod (8) and the detection mechanism (3) form a sliding structure through the swing pore plate (6) and the sliding chute (9), and the sliding length of the sliding deflector rod (8) is twice of the thickness of the separation gear (14);

the central axis of the guide cylinder (10) coincides with the central axis of the switching cylinder barrel (11), the inner wall of the guide cylinder (10) is attached to the outer wall of the switching cylinder barrel (11), the central axis of the switching cylinder barrel (11) coincides with the central axis of the rotating main shaft (12), and the inner wall of the switching cylinder barrel (11) is attached to the outer wall of the rotating main shaft (12);

the separation mechanism (2) comprises a separation rotating shaft (201), a threaded rod (202), a threaded sliding block (203), a rotating bent plate (204), a rotating chute (205), a translation plate (206), a separation plate (207), a translation pore plate (208), a support rod (209), a connection rod (210) and a sector gear (211), the separation rotating shaft (201) penetrating through the separation working gear (16) is arranged outside the separation mechanism (2), the threaded rod (202) is arranged at one end of the separation rotating shaft (201), the threaded sliding block (203) which is in sliding connection with the inner wall of the separation mechanism (2) is in threaded connection with the outer wall of the threaded rod (202), the rotating bent plate (204) which is in screwed connection with the inner wall of the separation mechanism (2) is movably connected with the side wall of the threaded sliding block (203), and the rotating chute (205) is formed at the connection part of the rotating bent plate (204) and the threaded sliding block (203), one end, far away from the rotating chute (205), of the rotating bent plate (204) is rotatably connected with a translation plate (206), the side wall of the translation plate (206) is connected with a separation plate (207) in a sliding manner, the separation plate is connected with the inner wall of the separation mechanism (2) in a sliding manner, a translation pore plate (208) is arranged at the connecting part of the separation plate (207) and the translation plate (206), one end, far away from the rotating bent plate (204), of the translation pore plate (208) is rotatably connected with a support rod (209), a connecting rod (210) is rotatably connected with the connecting part of the rotation bent plate (204) and one end, far away from the translation plate (206), of the support rod (209), and the outer wall, close to the connecting rod (210), of the support rod (211) is fixedly connected with a sector gear;

the lifting inclined block (33) is provided with an inclined plane with an inclination angle of 45 degrees, the side surface of the detection roller (34) is provided with an inclined plane tangent to the inclined plane of the lifting inclined block (33), the lifting inclined block (33) forms a lifting structure with the detection support (29) through a lifting column (30) and a compression spring (32), and the bottom end of the detection roller (34) is equal to the central axis of the clamping mechanism (20) in height;

the threaded rods (202) are provided with two groups, the position relation of the two groups of threaded rods (202) is symmetrical about the separation plate (207), the rotating bending plate (204) forms a rotating structure with the separation mechanism (2) through the threaded sliding block (203) and the rotating sliding groove (205), the rotating angle of the rotating bending plate (204) is 90 degrees, the separation plate (207) forms a lifting structure with the separation mechanism (2) through the translation plate (206) and the translation pore plate (208), the lifting height of the separation plate (207) is 1.4 times that of the support rod (209), the separation plate (207) is provided with two groups, and the position relation of the two groups of separation plates (207) is symmetrical about the sector gear (211).

2. The stainless steel pipe surface quality detection system according to claim 1, wherein: the inner wall of the separation sliding gear (15) is provided with teeth matched with the separation gear (14), the inner wall of the clamping sliding gear (18) is provided with teeth matched with the clamping gear (17), the distance from the clamping sliding gear (18) to the clamping gear (17) is twice as large as the thickness of the clamping gear (17), the inner wall of the pushing sliding gear (22) is provided with teeth matched with the pushing gear (21), the distance from the pushing sliding gear (22) to the pushing gear (21) is equal to the thickness of the pushing gear (21), and the thickness of the separation gear (14), the thickness of the separation sliding gear (15), the thickness of the clamping gear (17), the thickness of the clamping sliding gear (18), the thickness of the pushing gear (21) and the thickness of the pushing sliding gear (22) are equal.

3. The stainless steel pipe surface quality detection system of claim 2, wherein: the clamping mechanism (20) comprises a transmission gear (2001), a reduction gear (2002), a rotating gear (2003), a rotating cylinder (2004), a clamping rod (2005), a clamping sliding groove (2006) and a clamping roller (2007), the transmission gear (2001) meshed with the meshing surface of the clamping working gear (19) is arranged inside the clamping mechanism (20), the reduction gear (2002) is meshed at one end, far away from the clamping working gear (19), of the transmission gear (2001), the rotating gear (2003) is meshed at one end, far away from the transmission gear (2001), of the reduction gear (2002), the rotating cylinder (2004) connected with the inner wall of the clamping mechanism (20) in a sliding mode is fixedly connected to the inner wall of the rotating gear (2003), the clamping rod (2005) movably connected with the inner wall of the clamping mechanism (20) is screwed on the inner wall of the rotating gear (2004), and the clamping sliding groove (2006) is formed in the connecting position of the clamping rod (2005) and the clamping mechanism (20), and one end of the clamping rod (2005) far away from the rotating cylinder barrel (2004) is screwed with a clamping roller (2007).

4. The stainless steel pipe surface quality detection system of claim 3, wherein: the central axis of the rotating gear (2003) coincides with the central axis of the rotating cylinder (2004), six groups of clamping rods (2005) are arranged, the position relation of the six groups of clamping rods (2005) is distributed in an equiangular circumference mode relative to the central axis of the clamping mechanism (20), and the clamping roller (2007) forms a rotating clamping structure with the clamping mechanism (20) through the rotating cylinder (2004) and the clamping rods (2005).

5. The detection process of the stainless steel pipe surface quality detection system according to claim 4, characterized by comprising the following steps:

s1, when the device is used, firstly, ordered feeding operation of stainless steel pipes is carried out, a worker places the stainless steel pipes on a feeding table (1), a separation mechanism (2) works to drive a separation plate (207) to move, a servo motor (13) works to drive a rotary main shaft (12) to rotate, the rotary main shaft (12) rotates to drive a separation gear (14) to rotate, the separation gear (14) is meshed with a separation sliding gear (15) to drive a separation working gear (16) to rotate, the separation working gear (16) rotates to drive a threaded rod (202) to rotate through a separation rotating shaft (201), the threaded rod (202) drives a threaded slider (203) to move, the threaded slider (203) drives a rotary bent plate (204) to rotate through a rotary sliding groove (205), the rotary bent plate (204) drives a flat plate (206) to move through a support rod (209), the flat plate (206) drives the separation plate (207) to move up and down through a flat hole plate (208), the sector gear (211) on the supporting rod (209) drives the two-component partition plate (207) to do relative lifting movement, and the ordered feeding operation of the stainless steel pipe is completed;

s2, carrying out transmission switching operation of the rotating main shaft (12), in the detection mechanism (3), enabling an electric push rod (4) to work to drive a push plate (5) to move and drive a swing pore plate (6) to swing through a swing chute (7), enabling the swing pore plate (6) to drive a sliding deflector rod (8) to move through a sliding chute (9), and enabling the sliding deflector rod (8) to drive a switching cylinder barrel (11) to move through a guide cylinder (10) so as to complete transmission switching operation of the rotating main shaft (12);

s3, carrying out the pushing operation of the stainless steel pipe, switching the movement of the cylinder barrel (11) to enable the pushing sliding gear (22) to be meshed with the pushing gear (21), pushing the sliding gear (22) to rotate to drive the pushing working gear (23) to rotate, pushing the working gear (23) to rotate to drive the pushing sliding block (25) to move through the lead screw (24), driving the pushing top pillar (26) on the pushing plate (27) to move through the movement of the pushing sliding block (25), and driving the stainless steel pipe to pass through the inside of the clamping mechanism (20) through the pushing top pillar (26);

s4, centering and clamping the stainless steel pipe, switching the movement of the cylinder barrel (11) to enable the clamping sliding gear (18) to be meshed with the clamping gear (17) to drive the clamping working gear (19) to rotate, driving the reduction gear (2002) to rotate through the transmission gear (2001), driving the rotation gear (2003) to rotate through the reduction gear (2002), driving the rotation cylinder barrel (2004) to rotate through the rotation gear (2003), driving six groups of clamping rods (2005) to move through the clamping sliding grooves (2006), driving the clamping rollers (2007) to move through the rotation of six groups of clamping rollers (2007), completing the centering and clamping operation on the stainless steel pipe through the movement of the six groups of clamping rollers (2007), and driving the stainless steel pipe to rotate through the rotation gear (2003) after clamping;

s5, finally, carrying out surface quality detection operation on the stainless steel pipe, enabling the stainless steel pipe to move to drive the lifting inclined block (33) to slide along the detection support (29), enabling the stainless steel pipe to be clamped and rotated through the clamping mechanism (20), enabling the detection roller (34) to roll along the outer wall of the stainless steel pipe to drive the lifting column (30) to move, detecting the surface quality of the stainless steel pipe through the lifting amount of the lifting column (30) detected through the depth gauge (31), completing the surface quality operation on the stainless steel pipe, and placing the stainless steel pipe on the blanking table (28) after the detection is finished.