CN111156953B

CN111156953B - Surface smoothness detection device for intelligent bearing manufacturing

Info

Publication number: CN111156953B
Application number: CN202010197343.7A
Authority: CN
Inventors: 吕莹; 梅芳; 冯金龙
Original assignee: Lingnan Normal University
Current assignee: Lingnan Normal University
Priority date: 2020-03-19
Filing date: 2020-03-19
Publication date: 2021-05-28
Anticipated expiration: 2040-03-19
Also published as: CN111156953A

Abstract

The invention discloses a surface smoothness detection device for intelligent bearing manufacturing, which comprises a base plate, an operation plate, a side bolt, an electric telescopic rod and a detection probe body, wherein a vertical plate and a fixing plate are fixedly welded on the base plate, a limiting groove is formed in the upper end face of the base plate, a horizontal bolt is fixedly welded on the operation plate, the side bolt penetrates through the side of a positioning plate, the tail end of the side bolt is mutually connected with a clamping plate through a bearing, the inner side of the limiting groove is attached to the bottom end of the vertical bolt, the electric telescopic rod is installed on an installation plate, and the detection probe body is fixedly arranged at the top of the electric telescopic rod. This surface smoothness detection device is used in processing is made to bearing intelligence adopts neotype structural design for this device can carry out stable location to the bearing ring of different diameters fixedly, and regulation swivel bearing ring that moreover can be convenient makes the outside surface to the bearing ring that test probe can be quick carry out continuous detection operation, has improved detection efficiency greatly.

Description

Surface smoothness detection device for intelligent bearing manufacturing

Technical Field

The invention relates to the technical field of intelligent manufacturing, in particular to a surface smoothness detection device for intelligent manufacturing and processing of a bearing.

Background

Intelligent manufacturing, i.e. man-machine integrated intelligent system, which can perform intelligent activities such as analysis, reasoning, judgment, conception and decision making during the manufacturing process, and by the cooperation of man and intelligent machine, to expand, extend and partially replace the mental labor of human experts in the manufacturing process, and which updates the concept of manufacturing automation, extending to flexibility, intelligence and high integration, the intelligent manufacturing equipment has wide application in many fields, especially the mechanical manufacturing field, because of the large amount of repeated labor in the mechanical manufacturing process, such as the production of bearing rings.

With the continuous use of intelligent manufacturing equipment for producing bearing rings, the following problems are found in the actual production process:

no matter the bearing ring that artificial manufacturing or intelligent manufacturing equipment produced, its surface smoothness all can influence the quality and the life etc. of bearing, and in the in-process discovery that detects bearing ring surface smoothness, traditional artifical detection speed is slow, and the mounting fixture simple structure who uses, and unable convenient fixes a position the bearing ring of different diameters, leads to the efficiency of detecting lower.

Therefore, the surface smoothness detection device for intelligent bearing manufacturing needs to be designed aiming at the problems.

Disclosure of Invention

The invention aims to provide a surface smoothness detection device for intelligent bearing manufacturing, which aims to solve the problems that the traditional manual detection speed is low, and a used fixing clamp is simple in structure and cannot conveniently and quickly position and fix bearing rings with different diameters, so that the detection efficiency is low.

In order to achieve the purpose, the invention provides the following technical scheme: a surface smoothness detection device for intelligent bearing manufacturing comprises a base plate, an operation plate, a side bolt, an electric telescopic rod and a detection probe body, wherein a vertical disc and a fixed plate are welded and fixed on the base plate, a limit groove is formed in the upper end face of the base plate, a horizontal bolt is welded and fixed on the operation plate, the tail end of the horizontal bolt is attached to a track groove, the track groove is formed in the fixed plate, the center of the operation plate is welded and fixed with the tail end of a control rod, the control rod is welded and fixed with inner rings of a first connecting bearing and a second connecting bearing, outer rings of the first connecting bearing and the second connecting bearing are respectively welded and fixed on the fixed plate and the vertical disc, a function plate is welded and fixed on the control rod, the function plate is attached to a side contact pulley, the contact pulley is installed at one end of the movable rod, the movable rod is attached to the inner wall of a stable hole, and the stable hole is formed, and the movable rod other end and locating plate welded fastening, welded fastening has reset spring on the locating plate, and reset spring and perpendicular dish welded fastening to the locating plate avris with accomodate the laminating of inslot wall, accomodate the groove simultaneously and set up at perpendicular dish avris, the inboard bottom bonding of locating plate is fixed with interior backup pad, and interior backup pad bonding is fixed with the work pulley, the side bolt runs through the locating plate avris, and the side bolt end is through bearing and clamp plate interconnect, spacing inslot side and the laminating of perpendicular bolt bottom, and perpendicular bolt top installs the top nut to perpendicular bolt runs through the mounting panel, install electric telescopic handle on the mounting panel, and the electric telescopic handle top is fixed with the test probe body.

Preferably, the horizontal bolt is provided with a pressing nut, the pressing nut is attached to the fixing plate, and the horizontal bolt is symmetrically distributed around the center of the operating panel.

Preferably, the horizontal bolt is connected with the track groove in a sliding mode, the track groove is arc-shaped, the central angle of the arc-shaped edge of the track groove is 60 degrees, and the track groove is distributed in a centrosymmetric mode around the center of the operating panel.

Preferably, the control rod forms a rotating mechanism with the fixed plate and the vertical disc through a first connecting bearing and a second connecting bearing respectively, the control rod and the function plate are vertically distributed, the function plate is of a triangular plate structure made of high-speed steel, and the vertex angle of the function plate is provided with a chamfer angle.

Preferably, the movable rod uses the control rod as the center and has 3 equiangular distributions, and the movable rod is sliding connection with the stabilization hole.

Preferably, the front section of the positioning plate is shaped like U, the front section of the positioning plate is arc-shaped, and the positioning plate is in sliding connection with the receiving groove.

Preferably, the inner cushion plate and the clamping plate are made of cork wood, and working pulleys are densely distributed on the inner cushion plate at equal intervals.

Preferably, the side bolt is in threaded connection with a hole formed in the side of the positioning plate, the side bolt and the clamping plate form a rotating mechanism through a bearing mounted at the tail end of the side bolt, the clamping plate is symmetrically distributed relative to the inner backing plate, and 3 side bolts are mounted on the side of 1 clamping plate.

Preferably, the vertical bolt is in sliding connection with the limiting groove, the limiting groove is symmetrically distributed around the mounting plate, and the bottom surface of the mounting plate is attached to the surface of the substrate.

Compared with the prior art, the invention has the beneficial effects that: the surface smoothness detection device for the intelligent manufacturing and processing of the bearing adopts a novel structural design, so that the device can stably position and fix bearing rings with different diameters, and can conveniently adjust and rotate the bearing rings, so that a detection probe can rapidly and continuously detect the outer side surface of the bearing rings, and the detection efficiency is greatly improved;

1. the structure consisting of the operating panel, the horizontal bolt, the extrusion nut, the track groove, the control rod, the first connecting bearing and the second connecting bearing can conveniently control the functional board to rotate and fix, and is convenient for the functional board to extrude and push the contact pulley and the movable rod;

2. the structure consisting of the positioning plate, the accommodating groove, the inner backing plate, the working pulley, the side bolt and the clamping plate can position and fix the bearing rings with different diameters, and the bearing rings can stably rotate, so that the continuous and stable detection operation of the bearing rings by the detection probe body is facilitated;

3. the structure that spacing groove, perpendicular bolt, top nut, mounting panel and electric telescopic handle are constituteed, the position of the fixed test probe body of regulation that can be convenient, the installation of the bearing ring of not only being convenient for can adjust the test probe body to suitable detection position moreover.

Drawings

FIG. 1 is a schematic front sectional view of the present invention;

FIG. 2 is an enlarged schematic view of the structure A shown in FIG. 1 according to the present invention;

FIG. 3 is a schematic top view of a spacing groove of the present invention;

FIG. 4 is a schematic diagram of a track groove side view structure according to the present invention;

FIG. 5 is a schematic side view of a cross-sectional structure of the vertical disk of the present invention;

FIG. 6 is a schematic side sectional view of the positioning plate of the present invention.

In the figure: 1. a substrate; 2. a vertical tray; 3. a fixing plate; 4. an operation panel; 5. a horizontal bolt; 501. extruding the nut; 6. a track groove; 7. a control lever; 8. a first connecting bearing; 9. a second connecting bearing; 10. a function board; 11. a contact pulley; 12. a movable rod; 13. a stabilization well; 14. positioning a plate; 15. a return spring; 16. a receiving groove; 17. an inner liner plate; 18. a working pulley; 19. a side bolt; 20. a clamping plate; 21. a limiting groove; 22. a vertical bolt; 23. a top nut; 24. mounting a plate; 25. an electric telescopic rod; 26. and detecting the probe body.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, the present invention provides a technical solution: a surface smoothness detection device for intelligent bearing manufacturing comprises a base plate 1, a vertical plate 2, a fixing plate 3, an operation plate 4, a horizontal bolt 5, an extrusion nut 501, a track groove 6, a control rod 7, a first connecting bearing 8, a second connecting bearing 9, a function plate 10, a contact pulley 11, a movable rod 12, a stable hole 13, a positioning plate 14, a reset spring 15, a containing groove 16, an inner backing plate 17, a working pulley 18, a side bolt 19, a clamping plate 20, a limiting groove 21, a vertical bolt 22, a top nut 23, a mounting plate 24, an electric telescopic rod 25 and a detection probe body 26, wherein the vertical plate 2 and the fixing plate 3 are fixedly welded on the base plate 1, the limiting groove 21 is formed in the upper end face of the base plate 1, the horizontal bolt 5 is fixedly welded on the operation plate 4, the tail end of the horizontal bolt 5 is attached to the track groove 6, the track groove 6 is formed in the fixing plate 3, the center of the operation plate 4 is fixedly welded to the tail end of the control rod 7, and the control rod 7 is welded and fixed with the inner rings of the first connecting bearing 8 and the second connecting bearing 9, and the outer rings of the first connecting bearing 8 and the second connecting bearing 9 are welded and fixed on the fixing plate 3 and the vertical disc 2 respectively, the control rod 7 is welded and fixed with the function plate 10, and the side of the function plate 10 is jointed with the contact pulley 11, and the contact pulley 11 is installed at one end of the movable rod 12, the movable rod 12 is jointed with the inner wall of the stable hole 13, and the stable hole 13 is arranged in the vertical disc 2, and the other end of the movable rod 12 is welded and fixed with the positioning plate 14, the positioning plate 14 is welded and fixed with the reset spring 15, and the reset spring 15 is welded and fixed with the vertical disc 2, and the side of the positioning plate 14 is jointed with the inner wall of the accommodating groove 16, and the accommodating groove 16 is arranged at the side of the vertical disc 2, the bottom of the inner side of the positioning plate 14 is bonded and, side bolt 19 runs through 14 avris of locating plate, and 19 terminal bearing and the pinch-off blades 20 interconnect of passing through of side bolt, and the laminating of spacing groove 21 inboard and perpendicular bolt 22 bottom, and perpendicular bolt 22 top is installed top nut 23 to perpendicular bolt 22 runs through mounting panel 24, installs electric telescopic handle 25 on the mounting panel 24, and electric telescopic handle 25 top is fixed with test probe body 26.

In this example, the horizontal bolt 5 is provided with the pressing nut 501, the pressing nut 501 is attached to the fixing plate 3, and the horizontal bolts 5 are symmetrically distributed about the center of the operating panel 4, and the above structural design enables the pressing nut 501 to fix the positions of the horizontal bolt 5 and the operating panel 4 by pressing the fixing plate 3;

the horizontal bolt 5 is connected with the track groove 6 in a sliding mode, the track groove 6 is arc-shaped, the central angle of the arc-shaped edge of the track groove 6 is 60 degrees, meanwhile, the track groove 6 is distributed in a central symmetry mode relative to the center of the operating panel 4, the operating panel 4 can drive the horizontal bolt 5 to stably slide and move along the track groove 6 through the structural design, and the control rod 7 can drive the function board 10 to rotate for a sufficient angle;

the control rod 7 forms a rotating mechanism with the fixed plate 3 and the vertical disc 2 through a first connecting bearing 8 and a second connecting bearing 9 respectively, the control rod 7 and the function plate 10 are distributed vertically, the function plate 10 is of a triangular plate structure made of high-speed steel, and the vertex angle of the function plate 10 is provided with a chamfer angle, so that the control rod 7 can extrude and push 3 movable rods 12 through the side of the function plate 10 when rotating;

3 movable rods 12 are distributed at equal angles by taking the control rod 7 as the center, and the movable rods 12 are in sliding connection with the stabilizing holes 13, so that the movable rods 12 can slide along the stabilizing holes 13 at the same speed and amplitude under the extrusion of the function board 10;

the front section of the positioning plate 14 is U-shaped, the front section of the positioning plate 14 is arc-shaped, the positioning plate 14 is in sliding connection with the receiving groove 16, and the structural design enables the positioning plate 14 to stably receive the bearing ring from the inner side;

the inner backing plate 17 and the clamping plate 20 are made of cork wood, the working pulleys 18 are densely distributed on the inner backing plate 17 at equal intervals, the inner backing plate 17 made of cork wood and the clamping plate 20 have large surface friction and certain elasticity and can be tightly attached to a ferrule, and the working pulleys 18 are designed to facilitate the adjustment of the rotation of the bearing ferrule;

the side bolts 19 are in threaded connection with holes formed in the side of the positioning plate 14, the side bolts 19 and the clamping plates 20 form a rotating mechanism through bearings mounted at the tail ends of the side bolts 19, the clamping plates 20 are symmetrically distributed relative to the

inner backing plate

17, and 3 side bolts 19 are mounted on the sides of 1 clamping plate 20;

the vertical bolts 22 are slidably connected with the limiting grooves 21, the limiting grooves 21 are symmetrically distributed about the mounting plate 24, the bottom surface of the mounting plate 24 is attached to the surface of the substrate 1, and the mounting plate 24 can perform stable displacement motion along the track of the limiting grooves 21 due to the structural design.

The working principle is as follows: when the device is used, firstly, a bearing ring to be detected is taken out and sleeved on the outer side of the positioning plate 14 in the figure 5, the center of the bearing ring and the center of the positioning plate 14 in the figure 2 are positioned on the same vertical plane, then the extrusion nut 501 in the figure 1 is unscrewed, the extrusion nut 501 does not extrude the side of the fixing plate 3 any more, the operation plate 4 is rotated, the operation plate 4 drives the horizontal bolt 5 to stably slide in the track groove 6 in the figure 4, the operation plate 4 drives the function plate 10 in the figure 5 to rotate through the control rod 7, the function plate 10 simultaneously extrudes and pushes the contact pulleys 11 arranged at the tail ends of 3 movable rods 12 by using the side of the function plate 10 when the function plate rotates, the movable rods 12 slide in the direction far away from the control rod 7, the movable rods 12 drive the positioning plate 14 to slide out of the accommodating grooves 16 and stretch the return spring 15, until the working pulley 18 arranged on the inner backing plate 17 on the inner side of, the inner cushion plate 17 made of cork is extruded to slightly sink and deform, the operation panel 4 stops rotating, the extrusion nut 501 is screwed, the positions of the control rod 7, the function plate 10, the contact pulley 11, the movable rod 12 and the positioning plate 14 are fixed, and the bearing ring is extruded and positioned by the working pulleys 18 on the inner sides of the 3 positioning plates 14;

then, the symmetrically distributed side bolts 19 in fig. 2 are rotated simultaneously, the side bolts 19 are screwed in towards the center of the positioning plate 14, namely the side of the bearing ring, the symmetrically distributed side bolts 19 push the symmetrically distributed clamping plates 20 to be in contact with the two sides of the bearing ring, the position of the bearing ring in the horizontal direction is limited, and the side bolts 19 are rotated until the clamping plates 20 are attached to the two sides of the bearing ring without excessive clamping;

then, the mounting plate 24 in fig. 1 is pushed to drive the vertical bolt 22 to slide rightwards along the track of the limiting groove 21, the detection probe body 26 at the top of the mounting plate 24 moves to the position under the bearing ring positioned by the positioning plate 14 and stops, the top nut 23 is screwed, the top nut 23 extrudes the mounting plate 24 to be fixed, the electric telescopic rod 25 is controlled to extend, the detection probe body 26 is jacked up until the distance between the detection probe body 26 and the outer surface of the fixed bearing ring is enough, the detection probe body 26 can be started to carry out smoothness detection, during detection, the side bolt 19 can be slightly unscrewed, the clamping plate 20 is slightly far away from the side of the bearing ring, the bearing ring is pushed to rotate under the action of the working pulley 18 contacted with the inner side, the position aligned with the detection probe body 26 is changed, and the bearing ring is continuously rotated, so that the detection probe body 26 can continuously perform continuous detection operation on the outer surface of the bearing ring.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a bearing intelligent manufacture processing is with surface smoothness detection device, includes base plate (1), operation board (4), side bolt (19), electric telescopic handle (25) and test probe body (26), its characterized in that: the device is characterized in that a vertical disc (2) and a fixing plate (3) are welded and fixed on the substrate (1), a limiting groove (21) is formed in the upper end face of the substrate (1), a horizontal bolt (5) is welded and fixed on the operating disc (4), the tail end of the horizontal bolt (5) is attached to a track groove (6), the track groove (6) is formed in the fixing plate (3), the center of the operating disc (4) is welded and fixed with the tail end of a control rod (7), the control rod (7) is welded and fixed with inner rings of a first connecting bearing (8) and a second connecting bearing (9), outer rings of the first connecting bearing (8) and the second connecting bearing (9) are welded and fixed on the fixing plate (3) and the vertical disc (2) respectively, a function plate (10) is welded and fixed on the control rod (7), the side of the function plate (10) is attached to a contact pulley (11), and the contact pulley (11) is installed at one end of a movable rod (12), the utility model discloses a fixing device for a fixing device of a vertical disc, including a movable rod (12), a stable hole (13), a vertical disc (2), a locating plate (14), a locating plate (12), the other end of the movable rod (12), a locating plate (14), a reset spring (15), an inner backing plate (17), a working pulley (18), a side bolt (19), a bearing, a clamping plate (20) and a top nut (23) are installed at the top of the vertical bolt (22), wherein the locating plate (14) is welded and fixed with the inner wall of the vertical disc (2), the locating plate (14) is welded and fixed with the reset spring (15), the inner side of the locating plate (14) is adhered and fixed with the inner backing plate (17), the inner backing plate (17) is adhered and fixed with the working pulley (18), the side bolt (19) runs through the side of the locating plate (14), the end of the side bolt (19) is connected with the clamping plate (20) through the bearing, and vertical bolt (22) run through mounting panel (24), install electric telescopic handle (25) on mounting panel (24), and electric telescopic handle (25) top is fixed with test probe body (26).

2. The device for detecting the surface smoothness for the intelligent manufacturing and processing of the bearing according to claim 1, wherein: install on horizontal bolt (5) and extrude nut (501), and extrude nut (501) and fixed plate (3) laminating to horizontal bolt (5) are around operation panel (4) central symmetry distribution.

3. The device for detecting the surface smoothness for the intelligent manufacturing and processing of the bearing according to claim 1, wherein: horizontal bolt (5) are sliding connection with orbit groove (6), and orbit groove (6) set up to the arc to orbit groove (6) arc limit is 60 to the central angle, and orbit groove (6) are central symmetry distribution about operation board (4) center simultaneously.

4. The device for detecting the surface smoothness for the intelligent manufacturing and processing of the bearing according to claim 1, wherein: the control rod (7) forms a rotating mechanism with the fixed plate (3) and the vertical disc (2) through the first connecting bearing (8) and the second connecting bearing (9), the control rod (7) and the function plate (10) are vertically distributed, the function plate (10) is of a triangular plate-shaped structure made of high-speed steel materials, and meanwhile, the vertex angle of the function plate (10) is provided with a chamfer.

5. The device for detecting the surface smoothness for the intelligent manufacturing and processing of the bearing according to claim 1, wherein: the movable rods (12) are distributed at equal angles by taking the control rod (7) as the center, and the movable rods (12) are in sliding connection with the stabilizing holes (13).

6. The device for detecting the surface smoothness for the intelligent manufacturing and processing of the bearing according to claim 1, wherein: the front section of the positioning plate (14) is shaped like U, the front section of the positioning plate (14) is arc-shaped, and the positioning plate (14) is in sliding connection with the receiving groove (16).

7. The device for detecting the surface smoothness for the intelligent manufacturing and processing of the bearing according to claim 1, wherein: the inner backing plate (17) and the clamping plate (20) are both made of cork wood, and working pulleys (18) are densely distributed on the inner backing plate (17) at equal intervals.

8. The device for detecting the surface smoothness for the intelligent manufacturing and processing of the bearing according to claim 1, wherein: the side bolt (19) is in threaded connection with a hole formed in the edge side of the positioning plate (14), the side bolt (19) and the clamping plate (20) form a rotating mechanism through a bearing mounted at the tail end of the side bolt, the clamping plate (20) is symmetrically distributed relative to the inner backing plate (17), and 3 side bolts (19) are mounted on the edge side of 1 clamping plate (20).

9. The device for detecting the surface smoothness for the intelligent manufacturing and processing of the bearing according to claim 1, wherein: the vertical bolt (22) is in sliding connection with the limiting groove (21), the limiting groove (21) is symmetrically distributed relative to the mounting plate (24), and the bottom surface of the mounting plate (24) is attached to the surface of the substrate (1).