CN117054213A - Cement pole detects auxiliary device - Google Patents

Abstract

The utility model relates to the field of electric pole quality detection, in particular to a cement electric pole detection auxiliary device, which comprises two jacks, wherein the upper parts of the two jacks are provided with supporting parts, the upper parts of the supporting parts are inserted with guide rods, the outer sides of the guide rods are provided with intermittently-moving electric sliding blocks, the lower parts of the guide rods are provided with detection parts in a sliding manner at equal intervals, the detection parts comprise moving rings, the left sides of the moving rings are rotatably provided with detection rings, and guide assemblies are arranged inside the detection rings in a sliding manner at equal intervals along the inner and outer sides of the circumferential surfaces of the detection rings; and the outer side surface of the cement electric pole can be comprehensively detected by adopting surrounding detection, so that detection data can more reflect the actual strength condition of the concrete of the cement electric pole.

Description

Cement pole detects auxiliary device

Technical Field

The utility model relates to the field of electric pole quality detection, in particular to an auxiliary device for detecting a cement electric pole.

Background

The cement electric pole is mainly applied to agricultural nets and mountain areas and is an important facility for erecting electric network lines. The cement electric pole is of a column structure, the diameter of one end of the cement electric pole buried in the ground is slightly larger than that of the other end of the cement electric pole, and one end of the cement electric pole buried in the ground is of a hollow structure. The cement electric pole needs to be internally processed with steel bars in the concrete during manufacturing, so that the toughness of the cement electric pole is improved, and the service life of the cement electric pole is ensured. The concrete protection layer of the cement electric pole bears the important responsibility of enabling enough adhesive force to exist between stressed steel bars and bond coat coagulation, ensuring the coordination work of concrete and steel bars and protecting the steel bars from being affected and damaged by external harmful media, so that the concrete strength of the cement electric pole needs to be detected, and the quality of the cement electric pole is ensured to be qualified.

The existing method for detecting the strength of the concrete layer of the cement electric pole generally adopts a rebound method, wherein the rebound method is a detection method for estimating the strength of the concrete of the cement electric pole by using a heavy hammer driven by a spring on a strength detector, bouncing the surface of the concrete by a bouncing rod dowel bar, measuring the rebound distance of the heavy hammer and taking the ratio of the rebound distance of a rebound value to the initial length of the spring as an index related to the strength.

In the actual detection operation to the concrete strength of cement pole, generally adopt the workman to climb to the top of the cement pole of stacking up the upper strata, then handheld intensity detector detects the cement pole, and this kind of detection mode detects the time spent longer cement pole for detection efficiency is low.

Aiming at the problems, the Chinese patent publication No. CN215727332U provides a device for detecting the mechanical properties of a wireless communication concrete pole, and the device is connected with a computer controller through a first displacement detector, a second displacement detector, a third displacement detector, an electric push rod and a tension sensor, so that the acquisition, real-time display and control of the electric push rod of a plurality of detection data are realized, and the detection data can be displayed in a real-time diagrammatical manner.

However, the above patent only can detect the strength of the concrete pole at a specific position, so that the detection data is not comprehensive; meanwhile, when the cement electric pole is detected, the strength detector can vibrate to a large extent, so that the strength detector cannot be ensured to be in a stable state during detection in the literature; in addition, the electric pole cannot be locked in an accurate position, so that the axle center of the electric pole is inclined, and the distance between the test end of the strength detector and the outer side surface of the electric pole is deviated after the test end of the strength detector moves in position, so that the strength detection of the electric pole is inaccurate; when the pole carries out quality testing, debris outside the pole can cause its intensity to detect the influence, needs the manual work to clear up debris outside the pole in advance.

Disclosure of Invention

The technical scheme is adopted to solve the technical problems, the cement electric pole detection auxiliary device comprises two jacks, wherein supporting parts for lifting and supporting the cement electric pole to a horizontal state are arranged at the upper parts of the two jacks, guide rods are inserted into the upper parts of the supporting parts, electric sliding blocks capable of intermittently moving are arranged on the outer sides of the guide rods, and detection parts for carrying out surrounding detection on the strength of concrete on each position of the cement electric pole are arranged at the lower parts of the guide rods in a sliding mode at equal intervals.

The detection part comprises a moving ring, and a moving arm is arranged at the upper part of the moving ring; the fixed pulley is rotatably arranged at the top of the movable arm, the fixed pulley is hung on the upper side face of the guide rod in a rolling manner, the movable pulley is arranged in the middle of the movable arm in a sliding manner up and down, the movable pulley is pushed upwards to be abutted against the lower side face of the guide rod and locked in position through a screw, the movable ring can slide left and right along the guide rod, the detection ring is rotatably arranged on the left side of the movable ring, the guide assembly for rotating the detection ring when the movable ring moves left and right is arranged inside the detection ring in an equidistant manner along the circumferential face of the detection ring in an inside and outside sliding manner, and the movable arm on the left side is fixedly connected with the electric sliding block.

The guiding component comprises a guiding sleeve which is arranged in an inner sliding mode and an outer sliding mode along the circumferential surface of the detecting ring at equal intervals, a guiding spring is arranged between one side, far away from the cement electric pole, of the guiding sleeve and the moving ring, a guiding wheel frame is arranged on the lower portion of the guiding sleeve in a rotating mode, an electric push rod is arranged on the inner side of the bottom of the guiding sleeve, a detector is fixedly connected to the right side of the middle of the guiding sleeve, a stable structure is arranged inside the guiding sleeve, and the stable structure is used for locking and fixing the position of the cement electric pole when the detector detects the cement electric pole.

The lower part of the movable ring is hinged with the upper end of the connecting rod, the lower end of the connecting rod is hinged with the lower end of the connecting rod at the connecting position, and the hinged part of the lower ends of the two connecting rods at the adjacent positions is provided with an adjusting structure for adjusting the maximum rotation angle of the two connecting rods connected together.

Preferably, the guide wheel frame is fixed in rotation angle through a positioning pin which is arranged in the upper side of the guide wheel frame and radially slides along the guide sleeve, and the lower part of the guide wheel frame is rotatably provided with a guide wheel.

Preferably, the stabilizing structure comprises a sliding locking piece which is arranged at the rear side inside the guide sleeve in a front-back sliding manner through a tension spring, the position of the detection ring corresponding to the sliding locking piece is provided with a fixed locking piece, the electric push rod moves upwards to the top of the guide sleeve when the guide wheel stops rotating, the sliding locking piece is pushed backwards to be inserted into the fixed locking piece, and the maximum displacement position of the outer side face of the sliding locking piece is flush with the outer side face of the guide sleeve.

Preferably, the sliding locking teeth with the upper part being a horizontal plane and the lower part being an inward inclined plane are arranged at equal intervals in the axial direction of the guide sleeve at the rear part of the sliding locking piece, and the fixed locking teeth with the upper part being an outward inclined plane and the lower part being a horizontal plane are arranged at equal intervals in the axial direction of the guide sleeve at the front part of the fixed locking piece.

Preferably, the stabilizing structure further comprises a pushing block which is arranged on the right side inside the guide sleeve in a left-right sliding manner, a friction locking piece is arranged on the right side inside the detection ring in a left-right sliding manner corresponding to the position of the pushing block, a restoring spring which pushes the friction locking piece leftwards is sleeved on the outer side of the friction locking piece, the right side of the pushing block can be pushed rightwards to drive the friction locking piece to abut against the left side surface of the moving ring when the electric push rod acts, and the maximum displacement position of the outer side surface of the pushing block is flush with the outer side surface of the guide sleeve.

Preferably, the right part of the guide wheel frame is rotatably provided with a rolling broom, a shaking spring is arranged between the right side of the rolling broom and the guide wheel frame, the left side surface of the rolling broom is provided with an inclined surface block for pushing the rolling broom to the right, and the rear part of the guide wheel frame is provided with a transmission structure in linkage with the guide wheel, and the transmission structure is used for driving the rolling broom to rotate.

Preferably, the supporting component comprises a left supporting frame and a right supporting frame which are respectively arranged at the top parts of the left jack and the right jack, the upper parts of the left supporting frame and the right supporting frame are respectively hinged with angle rings, the two angle rings are respectively sleeved on the left side and the right side of the guide rod and are connected with the guide rod through locking screws, the right side of the left supporting frame is provided with left clamping blocks in an equidistant internal and external sliding manner along the circumferential surface of the left supporting frame, the left sliding sleeve is provided with clamping rings in a sliding manner on the outer side of the right part of the left supporting frame, the lower part of the left clamping ring is rotatably provided with left threaded rods, the right part of the left threaded rods is inserted in the left supporting frame and is in threaded fit with the left clamping blocks in an equidistant internal and external sliding manner along the circumferential surface of the right supporting frame, one side, which is close to each other, of the right clamping blocks is provided with inclined planes, the right threaded rods are inserted in the right supporting frame, and the left side of the right threaded rods is provided with conical blocks for ejecting the right clamping blocks towards the outer sides.

Preferably, the outer side of the right clamping block is provided with a top plate for jacking up the guide assembly in an initial state to be higher than the outer surface of the cement electric pole.

The utility model has the beneficial effects that:

1. according to the utility model, the intermittent moving electric slide block is adopted to drive the detection component to perform sectional type surrounding detection on the cement electric pole, so that the detection time is shortened, and the detection efficiency is accelerated; and the surrounding detection can comprehensively detect the outer side surface of the cement electric pole, so that the detection data are more real and effective, and the real strength condition of the concrete of the cement electric pole can be reflected more.

2. The guide assembly is adopted to drive the distance between the detector and the outer side surface of the cement pole to be consistent all the time; and make cement pole and the axis of detecting the ring be in parallel state through supporting part to carry out the accurate locking to the position of cement pole, guaranteed that the detector can be perpendicular to act on the check point of cement pole at the during operation, and the interval of the detection end of detector and pole remains unanimous throughout, has reduced detection error, has guaranteed that detection data is accurate.

3. The utility model adopts the stable structure to lock and stabilize the positions of the detection ring and the guide sleeve automatically when the detector detects, thereby ensuring that the detector can not change the upper and lower positions and the angle positions during detection, and further increasing the detection accuracy.

5. According to the utility model, the rolling broom which is linked with the guide wheel can be used for cleaning the surface of the detection point of the cement electric pole in real time, so that the soil and accumulated water adhered to the surface of the cement electric pole are removed, and the influence of sundries on the detection result is removed; and can make the roll sweep shake about pivoted in-process through the inclined plane piece to enlarge the clearance area, promote the clearance effect.

6. The utility model adopts the guide rod which is inserted and installed and the detection part which is arranged in a folding way, so that the utility model is convenient to assemble and disassemble, and has smaller volume after being disassembled and convenient carrying, thereby facilitating the field construction.

7. According to the utility model, the rotation speed of the detection ring can be changed by adjusting the initial angle of the guide wheel frame, so that when the movable ring stops, the stop angle positions of different detection rings are different, thereby ensuring that the detection points can be positioned at different positions of the outer ring surface of the electric pole, and further improving the reliability of detection data.

Drawings

The utility model will be further described with reference to the drawings and examples.

FIG. 1 is a schematic view of the overall fracture structure of the detecting member of the present utility model when folded together.

FIG. 2 is a schematic view of the overall structure of the detecting unit according to the present utility model after the detecting unit is unfolded.

Fig. 3 is a schematic view of the structure of the left half of the jack and the supporting member in the present utility model.

Fig. 4 is a schematic view of the structure of the right half of the jack and the supporting member in the present utility model.

Fig. 5 is a cross-sectional view of the right half of the support member of the present utility model.

Fig. 6 is a schematic structural view of a detecting member and a guide rod in the present utility model.

Fig. 7 is a partial enlarged view at a in fig. 6.

Fig. 8 is a partial semi-sectional view of the sensing ring, guide sleeve, slide lock and electric putter of the present utility model.

Fig. 9 is a partial enlarged view at B in fig. 8.

Fig. 10 is a partial semi-sectional view of the sensing ring, guide sleeve, push block, friction lock and electric putter of the present utility model.

FIG. 11 is a partial cross-sectional view of a sensing ring and stationary lock of the present utility model.

Fig. 12 is a schematic view of the structure of the friction lock according to the present utility model.

Fig. 13 is a partial semi-sectional view of the guide sleeve, the guide wheel frame and the electric putter of the present utility model.

Fig. 14 is a schematic view of the structure of the guide wheel frame, the guide wheel and the rolling broom in the present utility model.

FIG. 15 is a schematic view of the structure of the roll sweep and ramp block of the present utility model.

Fig. 16 is a partial semi-sectional view of two adjacent connecting rods of the present utility model.

Fig. 17 is a semi-sectional view of an adjustment member according to the present utility model.

In the figure: 1. a jack; 2. a support member; 3. a guide rod; 4. a detection section; 21. a left support frame; 22. a right support frame; 23. an angle ring; 31. an electric slide block; 41. a moving ring; 42. a detection ring; 43. a guide assembly; 44. a detector; 45. a connecting rod; 211. a left clamping block; 212. a clamping ring; 213. a left threaded rod; 221. a right clamping block; 222. a right threaded rod; 411. a moving arm; 412. a fixed pulley; 413. a moving pulley; 421. a fixed locking member; 422. friction locking piece; 431. a guide sleeve; 432. a guide wheel frame; 433. a guide wheel; 434. a slide lock; 435. a pushing block; 436. rolling and sweeping; 437. a bevel block; 438. a shaking spring; 439. an electric push rod; 451. an adjustment sleeve; 452. adjusting a tension spring; 453. a protrusion; 454. a track groove; 455. a key slot; 456. an adjusting member; 2211. and a top plate.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1 and 2, an auxiliary device for detecting a cement electric pole comprises two jacks 1, wherein a supporting part 2 for lifting and supporting the cement electric pole to a horizontal state is arranged at the upper parts of the two jacks 1, a guide rod 3 is inserted at the upper part of the supporting part 2, an intermittent moving electric sliding block 31 is arranged at the outer side of the guide rod 3, and a detecting part 4 for carrying out surrounding detection on the strength of concrete at each position on the cement electric pole is arranged at the lower part of the guide rod 3 in a sliding manner at equal intervals; specifically, when the cement electric pole stacked on the upper layer needs to be detected, the cement electric pole to be detected is supported and lifted through the supporting component 2, then the electric sliding block 31 is controlled to drive the detecting component 4 to carry out surrounding detection on the cement electric pole, the electric sliding block 31 moves leftwards to drive all the detecting components 4 to the outer side of the cement electric pole and then stops, the detecting component 4 detects the strength of the electric pole, then the electric sliding block 31 starts to move leftwards again, and each time the electric sliding block 31 moves for different distances, so that the detecting component 4 can detect the concrete strength of the cement electric pole in a segmented and comprehensive mode, and accuracy of detection data is guaranteed.

Referring to fig. 1 to 4, the supporting part 2 includes a left supporting frame 21 and a right supporting frame 22 respectively installed at the upper parts of the left and right jacks 1, the upper parts of the left supporting frame 21 and the right supporting frame 22 are respectively hinged with an angle ring 23, the two angle rings 23 are respectively sleeved at the left and right sides of the guide rod 3 and are connected with the guide rod 3 through locking screws, the detecting part 4 includes a moving ring 41, and the upper part of the moving ring 41 is provided with a moving arm 411; the top of the movable arm 411 is rotatably provided with a fixed pulley 412, the fixed pulley 412 is suspended on the upper side surface of the guide rod 3 in a rolling way, the middle part of the movable arm 411 is provided with a movable pulley 413 in a sliding way up and down, and the movable pulley 413 is pushed upwards to abut against the lower side surface of the guide rod 3 and then locked in position through a screw, so that the movable ring 41 can slide left and right along the guide rod 3; in the actual installation process, firstly, the left jack 1 is moved to the top position of the cement pole, the right jack 1 is moved to the bottom position of the cement pole, then the guide rod 3 is inserted into the left angle ring 23 from the right angle ring 23, the position of the guide rod 3 is locked by screwing the locking screw, and then the fixed pulley 412 is hung on the upper side surface of the guide rod 3, and the movable pulley 413 is pushed upwards to be abutted against the lower side surface of the guide rod 3, so that the movable ring 41 is quickly and slidably installed on the lower part of the guide rod 3.

Referring to fig. 1 and 2, in this embodiment, the guide rod 3 is a hexagonal column, and the fixed pulley 412 and the movable pulley 413 have shapes corresponding to the hexagonal columns, so that the movable ring 41 will not swing left and right when sliding left and right, and accurate detection is ensured.

Referring to fig. 1-5, a left clamping block 211 is slidably arranged on the right side of the left support frame 21 at equal intervals along the circumferential surface of the left support frame, a clamping ring 212 is sleeved on the outer side of the right part of the left support frame 21 in a left-right sliding manner, a left threaded rod 213 is rotatably arranged on the lower part of the left clamping ring 212, the right part of the left threaded rod 213 is inserted into the left support frame 21 and is in threaded fit with the left threaded rod 213, a right clamping block 221 is slidably arranged on the left side of the right support frame 22 at equal intervals along the circumferential surface of the right support frame 22, inclined surfaces are arranged on the sides, close to each other, of the right clamping block 221, a right threaded rod 222 is inserted into the right support frame 22, the right threaded rod 222 is in threaded fit with the right support frame 22, and a conical block for ejecting the right clamping block 221 towards the outer side of the right threaded rod 222 is arranged on the left side of the right threaded rod 222; the left support frame 21 is moved rightward to be sleeved on the outer side of the top of the cement pole, the right support frame 22 is moved leftward to be inserted into the bottom position of the cement pole, then the left threaded rod 213 and the right threaded rod 222 are simultaneously rotated, the left threaded rod 213 pushes the clamping ring 212 rightward, and the clamping ring 212 and the left clamping block 211 are matched with each other in an inclined plane to push the clamping ring to the direction of the cement pole, so that the clamping ring is clamped on the outer side of the top of the cement pole; the right threaded rod 222 drives the conical block to the left to be in inclined plane fit with the right clamping block 221, so that the right clamping block 221 is pushed to the outside to be tightly abutted against the bottom inner wall of the cement electric pole; the heights of the top and the bottom of the cement electric pole after clamping are equal to the heights of the left side and the right side of the guide rod 3 respectively, so that the axis of the cement electric pole and the axis of the guide rod 3 are in a parallel state, and then the jacks 1 on the left side and the right side are lifted at the same time, so that the cement electric pole is lifted, and the bottom of the cement electric pole is detected conveniently; and guarantee to remove ring 41 and cement pole and be in coaxial arrangement for detection part 4 can carry out vertical detection to cement pole, guarantees to detect accurately.

Referring to fig. 1, 2 and 6, a detection ring 42 is rotatably arranged at the left side of a moving ring 41, a guide assembly 43 for rotating the detection ring 42 when the moving ring 41 moves left and right is arranged inside the detection ring 42 in an equidistant and inner-outer sliding manner along the circumferential surface of the detection ring, a moving arm 411 positioned at the left side of a guide rod 3 is fixedly connected with an electric sliding block 31, the lower part of the moving ring 41 is hinged with the upper end of a connecting rod 45, the lower end of the connecting rod 45 is hinged with the lower end of the connecting rod 45 at an adjacent position, and an adjusting structure for adjusting the maximum rotation angle between the two connecting rods 45 is arranged at the hinged position of the lower ends of the two connecting rods 45 at the adjacent position; through the maximum distance between two adjacent movable rings 41 of regulation structure regulation, the electric slide block 31 drives the left movable ring 41 to move to the outside of cement pole left, and the connecting rod 45 of its lower part is driven to gradually rotate to the biggest angle that opens and shuts when the movable ring 41 of left moves, and afterwards connecting rod 45 drives the movable ring 41 of right side and moves to the outside of cement pole apart from left movable ring 41 a certain distance, and movable ring 41 drives guide assembly 43 through driving detection ring 42 and moves to on the lateral surface of cement pole.

Referring to fig. 1, 2, 16 and 17, in this embodiment, the adjusting structure includes an adjusting sleeve 451 fixedly installed at the lower end of the left connecting rod 45 of the two adjacent connecting rods 45, an adjusting member 456 is rotatably disposed inside the adjusting sleeve 451 through an adjusting tension spring 452, the adjusting member 456 is inserted into the front portion of the right connecting rod 45, a protrusion 453 is disposed at the front portion of the adjusting member 456, track grooves 454 are disposed at positions of the right connecting rod 45 corresponding to the protrusions 453 of the two adjacent connecting rods 45, key grooves 455 are disposed at equal intervals along the circumferential surface of the adjusting member 456 inside the adjusting sleeve 451, keys are disposed in the adjusting sleeve 451 corresponding to the key grooves 455, during specific adjustment, the adjusting member 456 is pulled out into the adjusting sleeve 451, then the adjusting member 456 is rotated to drive the protrusions 453 to rotate to corresponding positions, then the adjusting member 456 is inserted into the adjusting sleeve 451 again to fix the position of the adjusting member 456, when the connecting rod 45 rotates, the protrusions 453 slide inside the track grooves 454, and when the protrusions 453 slide to the end of the track grooves 454, the maximum rotation angle of the two connecting rods 45 is achieved, thereby realizing the function of adjusting the distance between the moving rings 41 at the upper ends of the connecting rods 45.

Referring to fig. 1, 4 and 7, the outer side of the right clamping block 221 is provided with a top plate 2211 for lifting the guide assembly 43 in an initial state to be higher than the outer surface of the concrete pole; when the right clamping block 221 locks the right end of the electric pole, the top plate 2211 pushes the guide assembly 43 to expand outwards along with the right clamping block 221, so that the guide assembly 43 is higher than the outer surface of the cement electric pole, and the guide assembly 43 cannot be clamped at the bottom of the cement electric pole when the movable ring 41 moves to the outer side of the cement electric pole.

Specifically, the jacks 1 at the left side and the right side lift up the cement electric pole; the maximum distance between two adjacent movable rings 41 is regulated through the regulating structure, the electric sliding block 31 is started to drive the left movable ring 41 to move rightwards to the outer side of the cement electric pole, the left movable ring 41 drives the right movable ring 41 to move a certain distance away from the left movable ring 41 to the outer side of the cement electric pole through the connecting rod 45, and the movable ring 41 drives the guide assembly 43 to move to the outer side surface of the cement electric pole through the driving of the detection ring 42.

It should be noted that, when the right clamping block 221 locks the right end of the electric pole, the top plate 2211 will push the guide assembly 43 to expand outwards along with the right clamping block 221, so that the guide assembly 43 is higher than the outer surface of the cement electric pole, and when the moving ring 41 moves to the outer side of the cement electric pole, the guide assembly 43 will not be clamped at the bottom of the cement electric pole.

Referring to fig. 6, 7 and 13, the guide assembly 43 includes a guide sleeve 431 slidably disposed at equal intervals inside and outside along a circumferential surface of the sensing ring 42, a guide spring is disposed between one side of the guide sleeve 431 away from the cement pole and the moving ring 41, a guide wheel frame 432 is rotatably disposed at a lower portion of the guide sleeve 431, the guide wheel frame 432 is angularly adjusted by a positioning pin disposed at an upper inner portion thereof to be radially slid along the guide sleeve 431, and a guide wheel 433 is rotatably disposed at a lower portion of the guide wheel frame 432; an electric push rod 439 is mounted on the inner side of the bottom of the guide sleeve 431, a detector 44 is fixedly connected to the right side of the middle of the guide sleeve 431, a stabilizing structure is arranged in the guide sleeve 431, and the stabilizing structure is used for locking and stabilizing the position of the cement electric pole when the detector 44 detects the cement electric pole; the angle of the guide wheel frame 432 is rotated in advance, so that the rotation direction of the guide wheel 433 is at a proper angle with the axis of the cement electric pole, then the position of the guide wheel frame 432 is locked through the positioning pin, when the moving ring 41 drives the guide assembly 43 to move to the outer side surface of the cement electric pole, the guide sleeve 431 moves downwards under the elastic force of the guide spring to drive the guide wheel 433 to be clung to the outer side surface of the cement electric pole, and the guide sleeve 431 drives the detector 44 to be always located at a fixed distance from the cement electric pole; when the guide component 43 moves left along the outer side surface of the cement pole, the guide wheel 433 rotates around the cement pole along the rotation direction of the guide wheel per se, so that the detector 44 is driven to rotate around the cement pole when moving left through the guide sleeve 431, the outer side surface of the cement pole is comprehensively detected, the electric push rod 439 is controlled to push out in the direction away from the cement pole when the moving ring 41 stops moving, the electric push rod 439 drives the stable structure to lock the guide sleeve 431 at the current position, and meanwhile, the detection ring 42 is locked at the current angle, so that the detector 44 is prevented from shaking during detection, and the detection quality is guaranteed.

Referring to fig. 6, 7, 14 and 15, a rolling broom 436 is rotatably provided at the right part of the guide wheel frame 432, a shaking spring 438 is provided between the right side of the rolling broom 436 and the guide wheel frame 432, a slant block 437 pushing the rolling broom 436 to the right is provided at the left side of the rolling broom 436, a transmission structure linked with the guide wheel 433 is provided at the rear part of the guide wheel frame 432, and the transmission structure is used for driving the rolling broom 436 to rotate; when the guide wheel 433 rotates, the rolling broom 436 is driven to rotate through the transmission structure, so that soil and accumulated water adhered to the outer side surface of the cement pole are swept, and the detection accuracy is ensured; when the roll brush 436 rotates until the inclined surface block 437 is inserted into the guide wheel frame 432, the roll brush 436 is pushed to the right side, meanwhile, the shaking springs 438 are compressed, and when the inclined surface block 437 rotates to be out of contact with the guide wheel frame 432, the shaking springs 438 push the roll brush 436 to bounce to the left side, so that the cleaning area is enlarged, and the cleaning effect is enhanced.

Referring to fig. 14, the driving structure in the present embodiment includes a driving bevel gear installed at the rear side of the guide wheel 433 and a driven bevel gear rotatably provided at the rear side of the guide wheel frame 432, the driving bevel gear being engaged with the driven bevel gear, the driven bevel gear transmitting torque to the rolling brush 436 through a belt.

Referring to fig. 8, 9 and 11, the stabilizing structure includes a sliding locking piece 434 slidably disposed at the rear side inside the guide sleeve 431 back and forth by a tension spring, a slope facing the outside of the guide sleeve 431 is disposed at the lower portion of the sliding locking piece 434 near the center side of the guide sleeve 431, a fixed locking piece 421 is mounted at the position of the detection ring 42 corresponding to the sliding locking piece 434, and an electric push rod 439 is pushed up to the top of the guide sleeve 431 when the guide wheel 433 stops rotating, so that the sliding locking piece 434 is pushed back to be inserted into the inside of the fixed locking piece 421, and the maximum displacement position of the outer side surface of the sliding locking piece 434 is flush with the outer side surface of the guide sleeve 431; when the push rod 439 is pushed upward, the slide lock 434 is pushed to move rearward to the inside of the insertion fixed lock 421, thereby locking the position of the guide sleeve 431.

Referring to fig. 8, 9 and 11, the rear part of the sliding locking piece 434 is equally spaced along the axial direction of the guide sleeve 431 with sliding locking teeth having an upper part being a horizontal plane and a lower part being an inward inclined plane, and the front part of the fixed locking piece 421 is equally spaced along the axial direction of the guide sleeve 431 with fixed locking teeth having an upper part being an outward inclined plane and a lower part being a horizontal plane; when the stop position of the guide sleeve 431 does not correspond to the position of the sliding locking tooth, the sliding locking piece 434 can be lifted up by a small distance by the fixed locking tooth, so that the fixed locking tooth corresponds to the position of the sliding locking tooth, the position of the guide sleeve 431 is fixed conveniently, and the situation that the guide sleeve 431 cannot be fixed or is blocked is avoided.

Referring to fig. 6, 10 and 12, the stabilizing structure further includes a pushing block 435 that is slidably disposed on the right side inside the guide sleeve 431, a slope that faces the outside of the guide sleeve 431 is disposed at the lower portion of the pushing block 435 near the center of the guide sleeve 431, a friction locking member 422 is slidably disposed on the right side inside the detection ring 42 in a position corresponding to the pushing block 435, a restoring spring that pushes the friction locking member 422 to the left is sleeved on the outer side of the friction locking member 422, and when the electric push rod 439 acts, the pushing block 435 can be pushed to the right to drive the right side of the friction locking member 422 to abut against the left side surface of the moving ring 41, and the maximum displacement position of the outer side surface of the pushing block 435 is flush with the outer side surface of the guide sleeve 431; when the electric push rod 439 is pushed upwards, the pushing block 435 can be pushed rightwards, and the pushing block 435 pushes the friction locking piece 422 rightwards, so that the right end of the friction locking piece 422 is abutted against the left side surface of the movable ring 41, and the rotation angle of the detection ring 42 is locked, so that accurate detection is facilitated.

Specifically, after the detection ring 42 moves leftwards to the outer side surface of the cement electric pole, the angle of the guide wheel frame 432 is adjusted, and then when the electric sliding block 31 drives the guide assembly 43 to move to the outer side surface of the cement electric pole through the moving ring 41, the guide sleeve 431 moves downwards under the action of the elasticity of the guide spring to drive the guide wheel 433 to be clung to the outer side surface of the cement electric pole, so that the guide sleeve 431 drives the detector 44 to be always located at a fixed distance of the cement electric pole; when the electric slide block 31 drives the guide component 43 to intermittently move leftwards along the outer side surface of the cement electric pole, the guide wheel 433 rotates around the cement electric pole along the rotation direction of the guide wheel, so that the guide sleeve 431 drives the detector 44 to rotate around the cement electric pole when moving leftwards, and the outer side surface of the cement electric pole is comprehensively detected; when the guide wheel 433 rotates, the rolling broom 436 is driven to rotate and shake left and right through the transmission structure, so that soil and accumulated water adhered to the outer side surface of the cement pole are swept, and accurate detection is ensured; when the moving ring 41 stops moving, the electric push rod 439 is controlled to push out in a direction away from the cement pole and push the sliding locking piece 434 to move backward to the inside of the insertion fixed locking piece 421, thereby locking the position of the guide sleeve 431; simultaneously pushing the pushing block 435 to the right, the pushing block 435 pushes the friction locking piece 422 to the right, so that the right end of the friction locking piece 422 is abutted against the left side surface of the moving ring 41, thereby locking the rotation angle of the detecting ring 42; thereby ensuring that the detector 44 does not shake during detection; finally, the quality of the cement electric pole meets the requirement or not by reading the detection data in the detector 44.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the spirit and scope of the utility model as defined by the appended claims and their equivalents.

Claims (8)

1. The utility model provides a cement pole detects auxiliary device, includes two jacks (1), and characterized in that, the supporting part (2) that lifts up cement pole and supports to the horizontality is installed to the upper portion of two jacks (1), and guide bar (3) are inserted to the upper portion of supporting part (2), and electric slider (31) of intermittent type removal are installed in guide bar (3) outside, and equidistant left and right sliding in guide bar (3) lower part is provided with detection part (4) that are used for encircleing the intensity of concrete everywhere on the cement pole;

the detection component (4) comprises a moving ring (41), and a moving arm (411) is arranged at the upper part of the moving ring (41); the top of the movable arm (411) is rotatably provided with a fixed pulley (412), the fixed pulley (412) is rotatably hung on the upper side surface of the guide rod (3), the middle part of the movable arm (411) is provided with a movable pulley (413) in a sliding manner up and down, the movable pulley (413) is pushed upwards to be abutted against the lower side surface of the guide rod (3) and then locked in position through a screw, the movable ring (41) can slide left and right along the guide rod (3), the left side of the movable ring (41) is rotatably provided with a detection ring (42), and a guide assembly (43) for rotating the detection ring (42) when the movable ring (41) moves left and right is arranged inside the detection ring (42) in an equidistant manner along the circumferential surface of the detection ring;

the guide assembly (43) comprises guide sleeves (431) which are arranged at equal intervals in an inner sliding manner along the circumferential surface of the detection ring (42), guide springs are arranged between one side, far away from the center of the movable ring (41), of the guide sleeves (431) and the movable ring (41), guide wheel frames (432) are rotatably arranged at the lower parts of the guide sleeves (431), electric push rods (439) are arranged at the inner sides of the bottoms of the guide sleeves (431), a detector (44) is fixedly connected to the right sides of the middle parts of the guide sleeves (431), a stable structure is arranged in the guide sleeves (431), and the stable structure is used for locking and fixing the positions of cement electric poles when the detector (44) detects the cement electric poles;

the lower part of the movable ring (41) is hinged with the upper end of the connecting rod (45), the lower end of the connecting rod (45) is hinged with the lower end of the connecting rod (45) at the connecting position, and the connecting rod (45) is used for connecting two detection components (4) at the adjacent positions together and keeping a certain distance during detection.

2. A cement pole inspection assistance device according to claim 1, wherein the guide wheel frame (432) is fixed in rotation angle by a positioning pin provided in an upper inner portion thereof so as to slide radially along the guide sleeve (431), and a guide wheel (433) is provided in rotation at a lower portion of the guide wheel frame (432).

3. A cement pole detection aid as claimed in claim 1, wherein the stabilizing structure comprises a sliding locking piece (434) slidably disposed in the rear side of the inside of the guide sleeve (431) back and forth by a tension spring, the detection ring (42) is provided with a fixed locking piece (421) corresponding to the position of the sliding locking piece (434), the electric push rod (439) moves upward to the top of the guide sleeve (431) when the guide wheel (433) stops rotating, so that the sliding locking piece (434) is pushed backward to be inserted into the inside of the fixed locking piece (421), and the maximum displacement position of the outer side face of the sliding locking piece (434) is flush with the outer side face of the guide sleeve (431).

4. A cement pole detection auxiliary device according to claim 3, wherein the sliding locking teeth with upper parts being horizontal planes and lower parts being inward inclined planes are equally spaced on the rear part of the sliding locking member (434) along the axial direction of the guide sleeve (431), and the fixed locking teeth with upper parts being outward inclined planes and lower parts being horizontal planes are equally spaced on the front part of the fixed locking member (421) along the axial direction of the guide sleeve (431).

5. The auxiliary device for detecting the cement electric pole according to claim 1, wherein the stabilizing structure further comprises a pushing block (435) which is arranged on the right side inside the guide sleeve (431) in a left-right sliding manner, a friction locking piece (422) is arranged on the right side inside the detection ring (42) in a left-right sliding manner corresponding to the position of the pushing block (435), a restoring spring which pushes the friction locking piece (422) leftwards is sleeved on the outer side of the friction locking piece (422), the pushing block (435) can be pushed rightwards to drive the right side of the friction locking piece (422) to abut against the left side surface of the movable ring (41) when the electric push rod (439) acts, and the maximum displacement position of the outer side surface of the pushing block (435) is flush with the outer side surface of the guide sleeve (431).

6. The auxiliary device for detecting the cement electric pole according to claim 1, wherein a rolling broom (436) is rotatably arranged at the right part of the guide wheel frame (432), a shaking spring (438) is arranged between the right side of the rolling broom (436) and the guide wheel frame (432), an inclined surface block (437) for pushing the rolling broom (436) rightwards is arranged at the left side surface of the rolling broom, a transmission structure which is linked with the guide wheel (433) is arranged at the rear part of the guide wheel frame (432), and the transmission structure is used for driving the rolling broom (436) to rotate.

7. The auxiliary device for detecting the cement pole according to claim 1, wherein the supporting component (2) comprises a left supporting frame (21) and a right supporting frame (22) which are respectively arranged at the upper parts of the left jack and the right jack (1), an angle ring (23) is respectively hinged at the upper parts of the left supporting frame (21) and the right supporting frame (22), the two angle rings (23) are respectively sleeved at the left side and the right side of the guide rod (3) and are connected with the guide rod (3) together through locking screws, a left clamping block (211) is arranged at the right side of the left supporting frame (21) in a sliding mode at equal intervals along the circumferential surface of the left supporting frame, a clamping ring (212) is arranged at the left side and the right side of the right supporting frame, a left threaded rod (213) is arranged at the lower part of the left clamping ring (212) in a rotating mode, the right part of the left threaded rod (213) is inserted into the left supporting frame (21) and is in threaded mode with the left supporting frame, a right clamping block (221) is arranged at the left side of the right supporting frame (22) in a sliding mode at equal intervals along the circumferential surface of the right side of the right supporting frame, an inclined surface is arranged at the right side, the right clamping block (221) is close to each other, the right clamping block (22) is inserted into the right threaded rod (222) is arranged at the right side of the threaded rod (222) in a conical shape, and the threaded rod (222) is arranged at the right side of the threaded rod (222) is matched with the left side.

8. A cement pole detection aid as claimed in claim 7, wherein the outer side of the right clamping block (221) is provided with a top plate (2211) for lifting the guide assembly (43) in an initial state above the outer surface of the cement pole.