CN210566984U

CN210566984U - Self-adaptive self-steering wheel type pipeline robot

Info

Publication number: CN210566984U
Application number: CN201921660658.XU
Authority: CN
Inventors: 张建华; 赵岩; 薛原; 徐立前; 李辉
Original assignee: Hebei University of Technology
Current assignee: Hebei University of Technology
Priority date: 2019-10-05
Filing date: 2019-10-05
Publication date: 2020-05-19
Anticipated expiration: 2029-10-05

Abstract

The utility model discloses a wheeled pipeline robot of self-adaptation autonomic steering, including box, elastic telescopic arm, first actuating mechanism, coupling mechanism, planetary gear train mechanism, worm gear mechanism, belt drive mechanism, second actuating mechanism, first stopper and second stopper. Through the rotation of the elastic telescopic arm around the vertical shaft and the roller b of the worm gear mechanism, power is transmitted to the belt transmission mechanism through the turbine, so that the roller b moves forwards along the pipe wall, the turning of the robot is realized, and the problem of autonomous steering of the pipeline robot is effectively solved. Through the synergism of elastic telescopic arm and belt drive mechanism in order to adapt to the change of pipe diameter, realize the flexible connection of box and planetary gear train mechanism through the universal joint fork, strengthened the adaptability of robot.

Description

Self-adaptive self-steering wheel type pipeline robot

Technical Field

The utility model relates to a pipeline robot field specifically is a wheeled pipeline robot of self-adaptation autonomic steering.

Background

At present, pipeline transportation is widely applied to the fields of urban drainage, oil transportation, natural gas transportation and the like as an important material transportation mode, along with the increase of the service life of pipelines, cracks and damages of the pipelines are easily caused under the influence of factors such as chemical corrosion, aging and the like, however, most of the pipelines are buried underground or in environments which are difficult to operate, and manual detection and maintenance are very difficult.

The document with application number 201721561809.7 discloses a multifunctional pipeline robot capable of self-adapting to spiral advancing with different pipe diameters, which can advance and retreat in a pipeline, but can not realize autonomous steering, can only advance in a reducing straight pipe, and can not be used in complex pipelines such as bent pipes.

SUMMERY OF THE UTILITY MODEL

The not enough to prior art, the utility model discloses the technical problem who plans to solve provides a wheeled pipeline robot of self-adaptation autonomic steering.

The technical solution of the present invention is to provide a self-adaptive self-steering wheel type pipeline robot, which is characterized in that the pipeline robot comprises a box body, an elastic telescopic arm, a first driving mechanism, a connecting mechanism, a planetary gear train mechanism, a worm gear mechanism, a belt transmission mechanism, a second driving mechanism, a first brake and a second brake;

the second driving mechanism comprises a main shaft, a second motor, a motor supporting seat, a spring b and a connecting column; the second motor is fixed on the motor supporting seat, and an output shaft of the second motor is connected with one end of the main shaft; one end of the connecting column is fixed on the motor supporting seat, and the other end of the connecting column is fixed on one end face of the supporting frame of the worm gear mechanism; a spring b is sleeved on the connecting column, and one end of the spring b is fixed on the connecting column;

the belt transmission mechanism comprises a connecting rod supporting seat and at least three belt transmission groups; the connecting rod supporting seat is nested on the connecting column and forms a moving pair with the connecting column; the other end of the spring b is fixedly connected with the connecting rod supporting seat; each belt transmission set comprises a first belt wheel, a synchronous belt, a second belt wheel, a shaft b, a long connecting rod, a short connecting rod, a roller b and a shaft a; the two long connecting rods are connected in parallel through a shaft a and a shaft b; the shaft a is rotatably arranged on the two long connecting rods and hinged on a support frame of the worm gear mechanism, and a first belt wheel is fixed at one end of the shaft a; the shaft b is rotatably arranged on the two long connecting rods, and a second belt wheel is arranged at one end of the shaft b, which is on the same side with the first belt wheel; the inner shaft surface of the second belt wheel is a ratchet wheel, a pawl is arranged on the shaft b, and the ratchet wheel and the pawl form a ratchet wheel mechanism; the first belt wheel and the second belt wheel are connected through a synchronous belt; the roller b is fixed on the shaft b and positioned between the two long connecting rods; one end of the short connecting rod is hinged on the connecting rod supporting seat, and the other end of the short connecting rod is hinged on the long connecting rod;

the worm and gear mechanism comprises a worm, a worm wheel, a long sleeve and a support frame; the worm is rotatably arranged on the outer side of the main shaft; the worm is rotatably arranged in the support frame; at least three turbines are uniformly distributed in the circumferential direction and are meshed with the worm, and each turbine is fixed on a respective shaft a and positioned between the two long connecting rods;

the planetary gear train mechanism comprises a planet carrier, a planet gear, an inner gear ring, a sun gear bracket, a sun gear, an output shaft, a bearing c, an elastic retainer ring b, a short column, a bearing d, a bearing e, a bearing f, an elastic retainer ring c and an end cover; the end cover is fixedly connected with a support frame of the worm gear mechanism; the sun wheel bracket is rotatably arranged at the outer side of the main shaft and is rotatably arranged in the support frame of the worm gear mechanism; one end of the sun wheel bracket is fixedly connected with the worm, and an inner gear ring is fixed on the inner side of the other end of the sun wheel bracket; the other end of the main shaft sequentially penetrates through a connecting rod supporting seat of the belt transmission mechanism, a worm of the worm gear mechanism and a sun gear bracket of the planetary gear train mechanism and is fixedly connected with a sun gear of the planetary gear train mechanism; the plurality of planet wheels are all meshed with the sun wheel and the inner gear ring; the short columns are fixed on the planet carrier; each planet wheel is rotatably arranged on the respective short column; the output shaft penetrates through the end cover to be rotatably connected with the end cover, and one end of the output shaft is fixedly connected with the planet carrier; the first brake is fixed on the output shaft; the second brake is fixed on the sun gear bracket;

the connecting mechanism is used for realizing flexible connection between the box body and the planetary gear train mechanism; the first driving mechanism is used for driving the elastic telescopic arm to rotate around a vertical shaft;

the elastic telescopic arm comprises an inner sliding column, an elastic arm shaft, a spring a, an outer sliding column and a roller a; two outer sliding columns are fixed at two ends of the rotating shaft; the inner sliding column is nested in the outer sliding column, and the inner sliding column and the outer sliding column form a sliding pair; one end of the spring a is fixedly connected with the inner sliding column, the other end of the spring a is fixedly connected with the outer sliding column, and the inner sliding column floats up and down in the outer sliding column due to the elasticity of the spring a; the roller a is rotatably mounted on the inner slide column through an elastic arm shaft and is in contact with the pipeline.

Compared with the prior art, the utility model discloses beneficial effect lies in:

1. through the rotation of the elastic telescopic arm around the vertical shaft and the roller b of the worm gear mechanism, power is transmitted to the belt transmission mechanism through the turbine, so that the roller b moves forwards along the pipe wall, the turning of the robot is realized, the problem of autonomous steering of the pipeline robot is effectively solved, and the robot can be carried out in complex pipelines such as bent pipes.

2. The change of the pipe diameter is adapted through the synergistic effect of the elastic telescopic arm and the belt transmission mechanism; when the pipe diameter changes, the elastic telescopic arm can float up and down in the pipeline under the extrusion of the pipe wall in the vertical direction, and meanwhile, the long connecting rod of the belt transmission mechanism rotates back and forth around the shaft a under the action of the extrusion of the pipe wall on the spring b to enable the long connecting rod to expand and contract so as to adapt to the change of the pipe diameter, and the self-adaptability of the robot is enhanced.

3. Through the matching use of the two brakes, the power of the second driving mechanism is switched to the corresponding parts of the worm gear mechanism so as to adapt to the running of the robot in the straight pipe and the bent pipe.

4. The flexible connection between the box body and the planetary gear train mechanism is realized through the universal joint fork, so that the position of the box body can be automatically adjusted in a complex pipeline environment by the robot, and the self-adaptability of the robot is further enhanced.

Drawings

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

FIG. 2 is a schematic perspective view of the internal structure of the case of the present invention;

fig. 3 is a left side sectional view of the elastic telescopic arm of the present invention;

fig. 4 is a schematic view of a first universal joint fork of the present invention;

fig. 5 is an installation cross-sectional view of the planetary gear train mechanism, the worm gear mechanism, the belt transmission mechanism and the second driving mechanism of the present invention;

fig. 6 is a schematic structural diagram of the planetary gear train mechanism of the present invention;

fig. 7 is a schematic view of the worm and gear mechanism and the belt transmission mechanism of the present invention;

fig. 8 is a schematic view of the belt transmission mechanism and the second driving mechanism according to the present invention;

fig. 9 is an explosion schematic diagram of part of the planetary gear train mechanism of the present invention;

in the figure, 1, a box body; 2. an elastic telescopic arm; 3. a first drive mechanism; 4. a connecting mechanism; 5. a planetary gear train mechanism; 6. a worm and gear mechanism; 7. a belt drive mechanism; 8. a second drive mechanism; 9. a first brake;

21. an inner strut; 22. a elastic retainer ring a; 23. an elastic arm shaft; 24. a short pin; 25. a spring a; 26. an outer strut; 27. a bearing a; 28. a roller a; 29. a connecting pin;

31. a rotating shaft; 32. a bearing b; 33. a bull gear; 34. a pinion gear; 35. a motor bracket; 36. a first motor;

41. a first universal joint fork; 42. a cross shaft; 43. a second yoke;

51. a planet carrier; 52. a planet wheel; 53. an inner gear ring; 54. a sun gear support; 55. a sun gear; 56. an output shaft; 57. a bearing c; 58. a circlip b; 59. a short column; 510. a bearing d; 511. a bearing e; 512. a bearing f; 513. a circlip c; 514. an end cap;

61. a worm; 62. a turbine; 63. a bearing g; 64. a long sleeve; 65. a bearing h; 66. a bearing i; 67. a support frame;

71. a first pulley; 72. a synchronous belt; 73. a second pulley; 74. a shaft b; 75. a long connecting rod; 76. a short connecting rod; 77. a connecting rod supporting seat; 78. a roller b; 79. a sleeve a; 710. a shaft a;

81. a main shaft; 82. a second motor; 83. a second coupling; 84. a motor supporting seat; 85. a spring b; 86. connecting columns.

Detailed Description

The present invention will be further explained with reference to the following embodiments and accompanying drawings. The specific embodiments are only used for further elaboration of the invention, and do not limit the scope of protection of the claims of the present application.

The utility model provides a self-adaptive self-steering wheel type pipeline robot (refer to the pipeline robot for short, see fig. 1-9), which is characterized in that the pipeline robot comprises a box body 1, an elastic telescopic arm 2, a first driving mechanism 3, a connecting mechanism 4, a planetary gear train mechanism 5, a worm and gear mechanism 6, a belt transmission mechanism 7, a second driving mechanism 8, a first brake 9 and a second brake (not shown in the figure);

the second driving mechanism 8 comprises a spindle 81, a second motor 82, a motor supporting seat 84, a spring b85 and a connecting column 86; the second motor 82 is fixed on a motor support seat 84, and an output shaft of the second motor is connected with one end of the main shaft 81 through a second coupler 83; at least three connecting columns 86 are uniformly distributed along the circumferential direction of the motor supporting seat 84, one end of each connecting column 86 is fixed on the motor supporting seat 84, and the other end of each connecting column 86 is fixed on one end face of the supporting frame 67 of the worm gear mechanism 6; the connecting column 86 is sleeved with a spring b85, and one end of a spring b85 is fixed on the connecting column 86;

the belt transmission mechanism 7 comprises a connecting rod supporting seat 77 and at least three belt transmission groups; the connecting rod supporting seat 77 is nested on the connecting column 86 and forms a moving pair with the connecting column 86; the other end of the spring b85 is fixedly connected with the connecting rod supporting seat 77, and the spring b85 stretches to enable each belt transmission set to float up and down to adapt to the change of the pipe diameter of the pipeline; each belt drive set comprises a first pulley 71, a timing belt 72, a second pulley 73, a shaft b74, a long link 75, a short link 76, a roller b78, a sleeve a79 and a shaft a 710; the two long links 75 are connected in parallel by the shaft a710 and the shaft b 74; the shaft a710 is rotatably arranged on the two long connecting rods 75 through bearings, the shaft a710 is hinged on the supporting frame 67 of the worm gear mechanism 6, and one end of the shaft a710 is fixed with a first belt pulley 71; the shaft b74 is rotatably arranged on the two long connecting rods 75 through bearings, and the second belt wheel 73 is arranged at one end of the shaft b74 on the same side as the first belt wheel 71; the inner axial surface of the second belt wheel 73 is a ratchet wheel, and a pawl is arranged on the shaft b74, so that a ratchet wheel mechanism is formed by the ratchet wheel and the shaft b 74; the first pulley 71 and the second pulley 73 are connected by a timing belt 72; the roller b78 is fixed on the shaft b74 and is positioned between the two long connecting rods 75; sleeves a79 are arranged on two sides of the roller b78 to limit the roller b 78; one end of the short connecting rod 76 is hinged on the connecting rod supporting seat 77, and the other end is hinged on the middle part of the long connecting rod 75;

another alternative is: the two long links 75 are connected in parallel by the shaft a710 and the shaft b 74; the shaft a710 is rotatably arranged on the two long connecting rods 75 through bearings, the shaft a710 is hinged on the supporting frame 67 of the worm gear mechanism 6, and one end of the shaft a710 is fixed with a first belt pulley 71; the shaft b74 is rotatably arranged on the two long connecting rods 75 through bearings, and a second belt wheel 73 is fixed at one end of the shaft b74 on the same side as the first belt wheel 71; the first pulley 71 and the second pulley 73 are connected by a timing belt 72; the roller b78 is arranged on the shaft b74 through a one-way bearing and is positioned between the two long connecting rods 75; sleeves a79 are arranged on two sides of the roller b78 to limit the roller b 78; one end of the short connecting rod 76 is hinged on the connecting rod supporting seat 77, and the other end is hinged on the middle part of the long connecting rod 75;

the worm gear mechanism 6 comprises a worm 61, a worm wheel 62, a bearing g63, a long sleeve 64, a bearing h65, a bearing i66 and a support frame 67; the worm 61 is rotatably arranged outside the main shaft 81 through a bearing g63 and a bearing h 65; the long sleeve 64 is positioned in the worm 61 and sleeved on the main shaft 81, one end of the long sleeve 64 is in contact with the end face of the bearing g63, and the other end of the long sleeve 64 is in contact with the end face of the bearing h65, so that the bearing g63 and the bearing h65 are positioned; the worm 61 is rotatably arranged in the support frame 67 through a bearing i66, and the worm 61 can rotate in the support frame 67; at least three worm wheels 62 are uniformly distributed in the circumferential direction and are all meshed with the worm 61, and each worm wheel 62 is respectively fixed on a respective shaft a710 and positioned between the two long connecting rods 75; the number of turbines 62 matches the number of belt drive sets;

the planetary gear train mechanism 5 comprises a planet carrier 51, a planet gear 52, an inner gear ring 53, a sun gear bracket 54, a sun gear 55, an output shaft 56, a bearing c57, a circlip b58, a short column 59, a bearing d510, a bearing e511, a bearing f512, a circlip c513 and an end cover 514; the end cover 514 is fixedly connected with a support frame 67 of the worm and gear mechanism 6 through bolts; the sun gear bracket 54 is rotatably arranged outside the main shaft 81 through a bearing e511 and is rotatably arranged inside the supporting frame 67 of the worm gear mechanism 6 through a bearing f512, so that the rotary motion of the main shaft 81 and the sun gear bracket 54 is ensured; one end of the sun gear bracket 54 is fixedly connected with the worm 61 through a screw, and the inner side of the other end is fixed with an inner gear ring 53 through a bolt; the other end of the main shaft 81 sequentially passes through the connecting rod supporting seat 77 of the belt transmission mechanism 7, the worm 61 of the worm gear mechanism 6 and the sun gear bracket 54 of the planetary gear train mechanism 5, and is fixedly connected with the sun gear 55 of the planetary gear train mechanism 5 through an elastic retainer c 513; circlip c513 serves to axially locate sun gear 55; a plurality of planet gears 52 (three in the embodiment, uniformly distributed in the circumferential direction) are all meshed with the sun gear 55 and the inner gear ring 53; a plurality of short columns 59 are fixed on the planet carrier 51 through bolts; each planet wheel 52 is rotatably mounted on a respective hollow stub 59 by a bearing d 510; a circlip b58 is arranged between the bearing d510 and the stub 59 to axially position the bearing d 510; the output shaft 56 passes through the end cover 514 and is rotatably connected with the end cover 514 through a bearing c57, and one end of the output shaft is fixedly connected with the planet carrier 51; the first brake 9 is fixed on the output shaft 56; the second brake is fixed on the sun gear bracket 54;

the connecting mechanism 4 adopts a universal coupling or a universal joint and comprises a first universal joint fork 41, a cross shaft 42 and a second universal joint fork 43; the shaft end of the second yoke 43 is fixedly connected with the other end of the output shaft 56 through a first coupling (not shown in the figure); the horizontal end of the cross shaft 42 is connected with the fork end of the second universal joint fork 43, and the vertical end is connected with the fork end of the first universal joint fork 41; the shaft end of the first universal joint fork 41 is fixed on the box body 1, and the box body 1 is flexibly connected with the planetary gear train mechanism 5 through the connecting mechanism 4;

the first driving mechanism 3 is used for driving the elastic telescopic arm 2 to do rotary motion around a vertical shaft, and comprises a rotary shaft 31, a bearing b32, a large gear 33, a small gear 34, a motor bracket 35 and a first motor 36; the rotating shaft 31 is rotatably mounted on two L-shaped supporting frames with through holes in the box body 1 through a bearing b32, and the L-shaped supporting frames limit the rotating shaft 31; a large gear 33 is fixed on the rotating shaft 31; the motor bracket 35 is fixed on the side wall of the box body 1 opposite to the L-shaped support frame; the first motor 36 is fixed on the motor bracket 35, and the output shaft of the first motor is fixed with a pinion 34 meshed with the gearwheel 33;

the elastic telescopic arm 2 comprises an inner sliding column 21, an elastic retainer ring a22, an elastic arm shaft 23, a short pin 24, a spring a25, an outer sliding column 26, a bearing a27, a roller a28 and a connecting pin 29; the two outer sliding columns 26 respectively penetrate through the box body 1 and are fixed at two ends of a rotating shaft 31 of the first driving mechanism 3 through screws; the inner sliding column 21 is nested in the outer sliding column 26, the inner sliding column 21 and the outer sliding column 26 form a sliding pair, and the inner sliding column 21 can slide along the outer sliding column 26; the spring a25 is positioned inside the inner sliding column 21, one end of the spring a25 is fixedly connected with the inner sliding column 21, the other end of the spring a25 is fixedly connected with the outer sliding column 26, the inner sliding column 21 floats up and down in the outer sliding column 26 under the action of the elastic force of the spring a25, when the pipe diameter is reduced, the elastic telescopic arm 2 is extruded in the vertical direction, the inner sliding column 21 moves towards the direction close to the outer sliding column 26, and the spring a25 is compressed; when the pipe diameter is increased, under the action of the elastic force of the spring a25, the elastic telescopic arm 2 extends along the vertical direction, and the inner sliding column 21 moves away from the outer sliding column 26; the elastic arm shaft 23 is fixed at the outer end part of the inner sliding column 21 through a connecting pin 29, and both ends of the elastic arm shaft 23 are rotatably provided with a roller a28 through a bearing a27 (the other proposal is that a roller a28 is rotatably arranged on the inner sliding column 21 through a bearing a27 and the elastic arm shaft 23 and is contacted with a pipeline); elastic check rings a22 are arranged between the inner ring of the bearing a27 and the elastic arm shaft 23 to axially limit the bearing a 27;

the outer sliding column 26 is a hollow cylinder with an opening at one end, a threaded hole is formed in the center of the bottom, and a protruding short pin 24 is fixed inside the outer sliding column; the inner sliding column 21 is a cylinder with a central hole, one side of the inner sliding column is provided with a notch matched with the short pin 24, and the short pin 24 can slide in the notch;

and a storage battery is arranged in the box body 1 and supplies power to the robot.

The utility model discloses a theory of operation and work flow are:

when the linear motion is performed, the second motor 82 is started first, and the spindle 81 starts to rotate; the rotation of the main shaft 81 rotates the sun gear 55 to rotate the three planetary gears 52. At this time, the first brake 9 does not work and the second brake works, the three planet wheels 52 rotate to enable the planet carrier 51 to rotate and the sun wheel bracket 54 not to rotate, so that the output shaft 56 is driven to rotate to enable the connecting mechanism 4, the box body 1, the elastic telescopic arm 2 and the first driving mechanism 3 to rotate around the horizontal shaft (similar to a propeller), and at this time, the roller b78 freely rotates along the pipe wall, so that the robot is driven to linearly advance in the pipeline.

When the robot turns, under the condition of keeping the second motor 82 started, the first brake 9 and the first motor 36 work, and the second brake does not work; the first brake 9 stops the rotation of the planet carrier 51, and at this time, the connecting mechanism 4, the box body 1, the elastic telescopic arm 2 and the first driving mechanism 3 stop the rotation movement around the horizontal shaft; the sun gear 55 transmits power to the inner gear ring 53 through the three planet gears 52, so that the sun gear bracket 54 rotates, and the worm 61 is driven to rotate; the worm 61 transmits the power to the three belt transmission sets of the belt transmission mechanism 7 through the three worm wheels 62 to rotate the three rollers b78, so as to move forward along the pipe wall; at the same time, the first motor 36 rotates the pinion 34 to rotate the bull gear 33; the large gear 33 drives the rotating shaft 31 to rotate, so that the elastic telescopic arm 2 rotates around the vertical shaft to push the robot to turn;

when the pipe diameter changes, the inner sliding column 21 is extruded or loosened by the pipe wall in the vertical direction, and the inner sliding column 21 slides up and down in the outer sliding column 26 under the action of the spring a25, so that the elastic telescopic arm 2 floats up and down in the pipeline; meanwhile, the roller b78 is squeezed or loosened by the pipe wall in the vertical direction, and drives the long link 75 to rotate around the shaft a710, so that the short link 76 rotates around the hinge part of the link support seat 77 to push the link support seat 77 to move on the connecting column 86, and the spring b85 extends or shortens to adapt to the pipe diameter change.

The utility model discloses the nothing is mentioned the part and is applicable to prior art.

Claims

1. A self-adaptive self-steering wheel type pipeline robot is characterized by comprising a box body, an elastic telescopic arm, a first driving mechanism, a connecting mechanism, a planetary gear train mechanism, a worm and gear mechanism, a belt transmission mechanism, a second driving mechanism, a first brake and a second brake;

2. The adaptive autonomous steering wheeled pipeline robot of claim 1, characterized in that at least three connecting columns are evenly distributed along the circumference of the motor supporting base.

3. The adaptive autonomous steering wheeled pipeline robot of claim 1, characterized by the belt drive set alternatives being: each belt transmission set comprises a first belt wheel, a synchronous belt, a second belt wheel, a shaft b, a long connecting rod, a short connecting rod, a roller b and a shaft a; the two long connecting rods are connected in parallel through a shaft a and a shaft b; the shaft a is rotatably arranged on the two long connecting rods and hinged on a support frame of the worm gear mechanism, and a first belt wheel is fixed at one end of the shaft a; the shaft b is rotatably arranged on the two long connecting rods, and a second belt wheel is fixed at one end of the shaft b, which is on the same side with the first belt wheel; the first belt wheel and the second belt wheel are connected through a synchronous belt; the roller b is arranged on the shaft b through a one-way bearing and is positioned between the two long connecting rods; one end of the short connecting rod is hinged on the connecting rod supporting seat, and the other end of the short connecting rod is hinged on the long connecting rod.

4. The adaptive autonomous steering wheeled pipeline robot according to claim 1 or 3, characterized in that the belt drive train further comprises a sleeve a; sleeves a are arranged on two sides of the roller b to limit the roller b; the number of turbines matches the number of belt drive sets.

5. The adaptive self-steering wheeled pipeline robot of claim 1, wherein said worm gear mechanism further comprises a long sleeve; the worm is rotatably arranged on the outer side of the main shaft through a bearing g and a bearing h; the long sleeve is positioned in the worm and sleeved on the main shaft, one end of the long sleeve is in contact with the end face of the bearing g, the other end of the long sleeve is in contact with the end face of the bearing h, and the bearing g and the bearing h are positioned.

6. The adaptive self-steering wheeled pipeline robot according to claim 1, wherein said planetary gear train mechanism further comprises a circlip b and a circlip c; the elastic retainer ring c is used for axially positioning the sun gear; each planet wheel is rotatably arranged on the respective short column through a bearing d; and an elastic retainer ring b is arranged between the bearing d and the short column to axially position the bearing d.

7. The adaptive self-steering wheeled pipeline robot according to claim 1, wherein the connecting mechanism is a universal joint or a universal joint, and comprises a first universal joint fork, a cross shaft and a second universal joint fork; the shaft end of the second universal joint fork is fixedly connected with the other end of the output shaft; the horizontal end of the cross shaft is connected with the fork end of the second universal joint fork, and the vertical end of the cross shaft is connected with the fork end of the first universal joint fork; the shaft end of the first universal joint fork is fixed on the box body.

8. The adaptive self-steering wheeled pipeline robot of claim 1, wherein said first drive mechanism comprises a rotating shaft, a gearwheel, a pinion, a motor mount and a first motor; the rotating shaft is rotatably arranged in the box body; a bull gear is fixed on the rotating shaft; the motor bracket is fixed inside the box body; the first motor is fixed on the motor bracket, and the output shaft of the first motor is fixed with a pinion which is meshed with the gearwheel.

9. The adaptive self-steering wheeled pipeline robot according to claim 1, wherein said elastically telescopic arm further comprises a circlip a, a bearing a and a connecting pin; the elastic arm shaft is fixed on the inner sliding column through a connecting pin, and both ends of the elastic arm shaft are rotatably provided with rollers a through bearings a; and an elastic retainer ring a is arranged between the inner ring of the bearing a and the elastic arm shaft to axially limit the bearing a.

10. The adaptive self-steering wheeled pipeline robot according to claim 1, wherein the outer sliding column is a hollow cylinder with an opening at one end, a threaded hole is formed at the center of the bottom, and a protruding short pin is fixed inside the hollow cylinder; the inner sliding column is a cylinder with a central hole, the spring a is positioned in the inner sliding column, one side of the inner sliding column is provided with a notch matched with the short pin, and the short pin can slide in the notch.