CN116427773A - Indexing unit of single-column steel pipe pole high-altitude unmanned auxiliary docking device - Google Patents

Abstract

The invention discloses an indexing unit of a single-column steel pipe pole high-altitude unmanned auxiliary docking device, which comprises a first driving piece, a second driving piece, a swing arm and a first friction wheel; the first driving piece is fixed on the outer side of the cylindrical section, one end of the swing arm is fixed with the output end of the first driving piece, the second driving piece is fixed on the other end of the swing arm, and the first friction wheel is fixed with the output end of the second driving piece; a window is arranged on the side wall of the cylindrical section; the first driving piece drives the swing arm to rotate, so that the first friction wheel passes through the window and contacts with the outer wall of the upper steel pipe rod; the second driving piece drives the first friction wheel to rotate, so that the upper steel pipe rod is driven to rotate circumferentially. The indexing unit drives the friction wheel through the driving piece, and the upper steel pipe rod is forced to circumferentially rotate under the action of friction force, so that the centering of the upper screw hole and the lower screw hole is adjusted, the swing arm adopts a two-section design, and is elastically connected, so that impact force can be absorbed when the friction wheel is in contact with the steel pipe rod, and the friction wheel is ensured to be tightly abutted with the steel pipe rod under the action of the pushing of the spring.

Description

Indexing unit of single-column steel pipe pole high-altitude unmanned auxiliary docking device

Technical Field

The invention relates to the technical field of installation of electric towers, in particular to an indexing unit of a single-column steel pipe pole high-altitude unmanned auxiliary docking device.

Background

Modern society is developing towards an intelligent age, the internet and the internet of things technology are rapidly advancing, and resource and information sharing is becoming the subject of the 21 st century, and all this needs huge and full-coverage wireless communication support. As a core hub for power transmission, the power iron tower is not only used for erecting a high-voltage line, but also used for transmitting communication stations, various communication signals, microwave station signals and the like. The adoption of the electric power iron tower to carry the communication base station can save public resources, improve the base station construction efficiency and greatly promote the development of communication industry, so that the electric power iron tower cannot substitute for the electric power transmission and communication industry of a national power grid and the importance of future intelligent life.

As a common electric power iron tower, the single-column steel pipe tower structure has technical and economic advantages, and compared with the traditional truss iron tower, the single-column steel pipe tower structure has the advantages of low manufacturing cost, small occupied area, attractive appearance, short construction period and the like, has good environmental adaptability to power transmission networks at the periphery of a city and the tail end of a power grid, and is widely applied in China.

The conventional single-column steel tube tower comprises a tower body and a cross arm, wherein the tower body at least comprises two sections, and the key point of the tower body is that: each two adjacent tower bodies, the outer diameter of one tower body is slightly smaller than the inner diameter of the other tower body, and all the tower bodies can be sleeved together; nail penetrating holes are formed in two ends of each section of tower body, the nail penetrating holes are staggered up and down in sequence, and all sections of the tower body are connected through bolts in a penetrating mode. When the single-column steel pipe tower is assembled, the steel nose at the top of each section of tower body is required to be pulled, each section of tower body is sequentially pulled out, the through-nail holes on two adjacent sections of tower bodies correspond to each other, the through-nails of the bolts respectively penetrate through the tower bodies, and the bolts are used for fastening. The single-column steel pipe tower is installed in high altitude, the installation process adopts a crane to hoist and assemble in sections, the coordination and coordination work between an installer and the crane is more in the operation process, the construction safety risk is high, and the high altitude labor intensity is high.

The electric power tower mounting equipment comprises a ring sleeve A, a gear ring, guide sleeves, guide rods, a ring sleeve B, an inner hexagonal sleeve, a one-way ring, a ring sleeve C, a deflector rod B, a ring sleeve D, a deflector rod C and a volute spring, wherein a plurality of guide sleeves which are in one-to-one correspondence with connecting holes of a butt flange on a steel pipe rod are uniformly arranged on two ring sleeves A which are in butt joint through bolts A and are nested at the edge of the butt flange of the steel pipe rod in the circumferential direction; according to the invention, only one person can complete effective installation and pre-tightening of all bolts on the flange on the thicker steel pipe pole ladder, the installation efficiency is high, the potential safety hazard of auxiliary personnel on a crane is avoided, and the construction is safe. Although the equipment can reduce personnel and operation difficulty, the screw hole butt joint of the upper steel pipe rod and the lower steel pipe rod still needs personnel to participate, and the degree of automation is not high

Disclosure of Invention

The invention aims to solve the technical problem of how to automatically center screw holes of upper and lower rods when the steel pipe rods are automatically butted.

The invention solves the technical problems by the following technical means:

the indexing unit of the single-column steel pipe pole high-altitude unmanned auxiliary docking device comprises a first driving piece (31), a second driving piece (32), a swing arm (33) and a first friction wheel (34); the first driving piece (31) is fixed on the outer side of the cylindrical section (22), one end of the swing arm (33) is fixed with the output end of the first driving piece (31), the second driving piece (32) is fixed on the other end of the swing arm (33), and the first friction wheel (34) is fixed with the output end of the second driving piece (32); a window (221) is formed in the side wall of the cylindrical section (22); the first driving piece (31) drives the swing arm (33) to rotate, so that the first friction wheel (34) passes through the window (221) to be in contact with the outer wall of the upper steel pipe rod; the second driving piece (32) drives the first friction wheel (34) to rotate, so that the upper steel pipe rod is driven to rotate circumferentially.

The indexing unit drives the friction wheel through the driving piece, and the upper steel pipe rod is forced to circumferentially rotate under the action of friction force, so that the centering of the upper screw hole and the lower screw hole is adjusted, the swing arm adopts a two-section design, and is elastically connected, so that impact force can be absorbed when the friction wheel is in contact with the steel pipe rod, and the friction wheel is ensured to be tightly abutted with the steel pipe rod under the action of the pushing of the spring.

Further, the device also comprises a monitoring unit (6); the monitoring unit (6) collects screw hole information of the upper steel pipe rod and the lower steel pipe rod and sends the screw hole information to the controller, and the controller controls the starting and stopping of the first driving piece (31) and the second driving piece (32) according to the centering condition.

The indexing unit drives the friction wheel through the driving piece, and the upper steel pipe rod is forced to circumferentially rotate under the action of friction force, so that the centering of the upper screw hole and the lower screw hole is adjusted, the swing arm adopts a two-section design, and is elastically connected, so that impact force can be absorbed when the friction wheel is in contact with the steel pipe rod, and the friction wheel is ensured to be tightly abutted with the steel pipe rod under the action of the pushing of the spring. The automatic centering control can be realized by matching with the monitoring unit.

Further, the swing arm (33) comprises a first swing arm section (331) and a second swing arm section (332); one side of the swing arm first section (331) and one side of the swing arm second section (332), which faces the window (221), are elastically connected through a spring (333), and one side of the swing arm second section, which faces away from the window (221), is connected through an elastic block (334).

Further, the monitoring unit (6) is a camera and is fixed on the swing arm section (331) through a bracket, and enters the window (221) along with the swing arm (33) to shoot the screw hole from top to bottom.

Further, the camera is fixed with a section (331) of the swing arm through a bracket, and horizontally extends to the window (221).

Further, the first swing arm section (331) and the second swing arm section (332) are made of C-shaped steel, and the spring (333) is fixed on the inner wall of the wing plate of the C-shaped steel.

Further, the elastic block is fixed on the outer wall of the C-shaped steel wing plate.

Further, when the first friction wheel (34) is not in contact with the steel pipe rod, the first swing arm section (331) and the second swing arm section (332) are in a linear shape under the action of the spring (333) and the elastic block (334).

The invention has the advantages that:

the indexing unit drives the friction wheel through the driving piece, and the upper steel pipe rod is forced to circumferentially rotate under the action of friction force, so that the centering of the upper screw hole and the lower screw hole is adjusted, the swing arm adopts a two-section design, and is elastically connected, so that impact force can be absorbed when the friction wheel is in contact with the steel pipe rod, and the friction wheel is ensured to be tightly abutted with the steel pipe rod under the action of the pushing of the spring.

The automatic centering control can be realized by matching with the monitoring unit.

The impact force of the friction wheel and the steel pipe rod can be absorbed through the design of the spring and the elastic block.

Drawings

FIG. 1 is a schematic view of a docking apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic view of another view of half of the docking mechanism according to an embodiment of the present invention;

FIG. 3 is a schematic view of a horn roller according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of a transfer unit according to an embodiment of the invention;

FIG. 5 is a schematic diagram of a monitoring unit according to an embodiment of the present invention;

fig. 6 is a schematic structural diagram of a nut and bolt pushing unit according to an embodiment of the present invention;

FIG. 7 is a schematic view of another view of a nut and bolt pushing unit according to an embodiment of the present invention;

FIG. 8 is a schematic view of a mounting structure of a proximity switch on a platen according to an embodiment of the present invention;

FIG. 9 is a schematic view of the integrated design of a nut cage and bolt cage in accordance with an embodiment of the present invention;

fig. 10 is an enlarged schematic view of the tightening unit in the embodiment of the present invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions in the embodiments of the present invention will be clearly and completely described in the following in conjunction with the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The embodiment discloses a single-column steel pipe pole high altitude unmanned auxiliary docking device's transposition unit, and when this docking device used, need not personnel operation of ascending a height, reduces the operation degree of difficulty and factor of safety. As shown in fig. 1, the docking device comprises a clamping section 1, a guiding section 2, an indexing unit 3, a nut and bolt pushing unit 4, a tightening unit 5 and a monitoring unit 6 which are coaxially communicated.

In this embodiment, the clamping section 1 is used for clamping and holding with the top of the lower steel pipe rod, the whole body is in a circular ring shape, and two semi-rings formed by bending steel plates are assembled into a whole ring. The end surfaces of the semi-rings are provided with assembly steps, and when the two semi-rings are assembled, the assembly steps are matched and then fixed through bolts, so that the purpose of holding the steel pipe rod tightly can be achieved.

As shown in fig. 1 and 2, the guiding section 2 includes a horn section 21, the small caliber end of the horn section 21 is located below and extends downwards to form a cylindrical section 22, and the clamping section 1 is connected with the cylindrical section 22 through a plurality of connecting rods, so that the overall weight of the device can be reduced.

The butt joint device is fixed at the top end of the lower steel pipe rod through the clamping section 1, and the bottom end of the upper steel pipe rod is in butt joint with the top of the lower steel pipe rod through the guide section 2; the indexing unit 3 drives the upper steel pipe rod to circumferentially rotate, and monitors the rotation of the upper steel pipe rod through the monitoring unit 6 until the bolt holes of the upper steel pipe rod and the lower steel pipe rod are centered; the nut and bolt pushing unit 4 drives the nut to move to the assembly position; the tightening unit 5 drives the bolt to rotate to pass through screw holes of the upper steel pipe rod and the lower steel pipe rod to be matched with the screw threads of the nut. The following details for each unit:

guide section 2:

as shown in fig. 1 and 2, the guide section 2 comprises a horn section 21 and a cylindrical section 22 which are coaxially communicated; the horn section 21 is located above the cylindrical section 22; the inner diameter of the cylindrical section 22 is the same as or slightly larger than the outer diameter of the flange at the bottom end of the upper steel pipe pole so as to be convenient for adapting to flanges with different sizes. In this embodiment, the horn section 21 is used as a guide, so that the upper steel pipe pole can be guided to be positioned roughly, and when the upper steel pipe pole gradually enters the cylindrical section 22 from the horn section 21, the accurate positioning is completed. Because the upper steel pipe rod and the lower steel pipe rod are not fixed at this time and are in a suspension state, the cylindrical section 22 has a certain height in the embodiment, so that the perpendicularity of the upper steel pipe rod can be limited, and the butting precision of the flanges of the upper steel pipe rod and the lower steel pipe rod is ensured. In addition, in order to reduce friction and noise when the upper steel pipe rod moves downwards from the horn section 21, the present embodiment further installs a plurality of rollers 211 on the wall of the horn section 21, and as shown in fig. 3, friction and noise reduction are realized by rolling engagement with the balls when the upper steel pipe rod falls.

Indexing unit 3:

as shown in fig. 4, the function of the positioning unit 3 in this embodiment is to rotate the upper steel pipe rod, center the screw holes of the upper and lower steel pipe rods, and facilitate the next operation. The indexing unit 3 comprises a first driving piece 31, a second driving piece 32, a swing arm 33 and a first friction wheel 34; the first driving piece 31 is fixed on the outer wall of the cylindrical section 22 through a mounting bracket 35, one end of the swing arm 33 is fixed with the output end of the first driving piece 31, the second driving piece 32 is fixed on the other end of the swing arm 33, and the first friction wheel 34 is fixed with the output end of the second driving piece 32; a window 221 (shown in fig. 2) is formed in the side wall of the cylindrical section 22; the first driving piece 31 drives the swing arm 33 to rotate, so that the first friction wheel 34 passes through the window 221 to contact with the outer wall of the upper steel pipe rod; the second driving member 32 drives the first friction wheel 34 to rotate, so as to drive the upper steel pipe pole to rotate circumferentially. In this embodiment, the swing arm 33 may be made of i-steel or C-steel, and the first driving member 31 and the second driving member 32 are driving motors to drive the swing arm 33 and the first friction wheel 34 to rotate respectively. The friction wheel is made of materials such as silica gel with a large friction coefficient, and slipping with the outer wall of the steel pipe rod is avoided.

In order to adapt to steel pipe rods with different diameters, the swing arm 33 comprises a first swing arm section 331 and a second swing arm section 332; the side of the swing arm first section 331 facing the window 221 is elastically connected with the swing arm second section 332 through a spring 333, and the side of the swing arm second section facing away from the window 221 is connected with the swing arm second section through an elastic block 334. In this embodiment, in order to reduce the influence of the spring 333 on the indexing operation, the spring 333 is fixed on the inner sides of the first swing arm 331 and the second swing arm 332, i.e. the inner walls of the i-shaped or C-shaped wing plates, and one end of the spring 333 is fixed on the first swing arm 331 and the other end is fixed on the second swing arm 332. The side of the swing arm first section 331 and the swing arm second section 332 facing away from the window 221 is fixed by an elastic block 334. The elastic block 334 is made of flexible materials such as rubber and silica gel, is approximately square, covers the outer walls of the wing plates of the first swing arm section 331 and the second swing arm section 332, and is fixed with the first swing arm section 331 and the second swing arm section 332 respectively through bolts. In this embodiment, the spring 333 has a certain stiffness, when the first swing arm section 331 and the second swing arm section 332 are in a straight line, the spring 333 is in a natural state, the elastic block 334 is not bent, when the first driving member 31 is started, the swing arm 33 moves towards the window 221, the first friction wheel 34 abuts against the outer wall of the upper steel pipe rod, under the action of the abutting force, the first swing arm section 331 and the second swing arm section 332 form an included angle, the spring 333 is pressed, and under the reaction of the spring 333, the rotation angle of the first swing arm section 331 is limited, so that the first friction wheel 34 can be tightly abutted against the upper steel pipe column, and meanwhile, due to the certain flexibility of the spring 333, a certain buffer margin can be provided for the first friction wheel 34 and the upper steel pipe column. Of course, the elastic block 334 also plays the same role as the spring 333, under the action of the spring 333 and the elastic block 334, the first friction wheel 34 is always tightly abutted against the outer wall of the upper steel pipe rod, at this time, the second driving piece 32 is started, and under the rotation driving of the first friction wheel 34, the upper steel pipe rod is enabled to rotate circumferentially until the screw holes of the upper steel pipe rod and the lower steel pipe rod are centered.

In this embodiment, since the operation is unmanned, the monitor unit 6 needs to be provided to monitor whether the upper and lower screw holes are aligned. In this embodiment, as shown in fig. 5, the monitoring unit 6 is a camera fixed on a section 331 of the swing arm through a bracket, the camera extends horizontally towards the window 221, and enters the cylindrical section 22 from the window 221 along with the rotation of the swing arm 33, when the first friction wheel 34 rotates the upper steel pipe rod, the camera shoots the lower flange of the upper steel pipe rod from top to bottom, and sends the shot picture or video to the ground, the first driving member 31 and the second driving member 32 are manually controlled to stop acting, or the automatic control is used for acquiring images and identifying targets, and when the upper screw hole and the lower screw hole are aligned, the first driving member 31 and the second driving member 32 are controlled to stop acting through a control program.

In this embodiment, in order to reduce the overall height of the device, the first driving member 31 is fixed with the mounting bracket 35 in a transverse direction, and the output shaft of the first driving member 31 passes through the fixing bracket to be linked with a worm gear (not shown in the figure), so that the horizontal rotating shaft is converted into the vertical rotating shaft 311 through the worm gear, and the vertical rotating shaft 311 is fixed with the second swing arm section 332 through the rotating shaft flange, thereby not only driving the swing arm 33 to rotate, but also reducing the overall height of the device.

Nut and bolt pushing unit 4:

in this embodiment, after the upper steel pipe rod and the lower steel pipe rod are connected in a butt joint, a nut is required to be placed above the flange plate of the upper steel pipe rod to be in tight fit with the bolt below. In order to avoid the obstacle caused by the falling of the upper steel pipe rod by the nut and bolt pushing unit 4, the telescopic structure is adopted in the embodiment, and the concrete structure is as follows:

as shown in fig. 6, the nut-bolt pushing unit 4 includes an annular bracket 41, an annular push plate 42, a pressing plate 43, a nut holder 44, a bolt holder 45, and a third driver 46; the annular support 41 has a certain height and width, is sleeved on the outer wall of the cylindrical section 22 and is close to the lower end of the cylindrical section 22, and the annular support 41 and the cylindrical section 22 can be fixed by welding, bolts and the like; the annular push plate 42 is in a thin-wall cylinder shape, the diameter of the annular push plate is larger than the maximum diameter of the annular support 41, the annular push plate is sleeved outside the annular support 41, an arc-shaped slide rail 47 is fixed on the upper surface of the annular support 41, a first slide block 48 is in sliding fit on the slide rail, and the first slide block 48 is welded or bolted with the annular push plate 42 through a connecting piece 481 (generally adopts a steel plate as a connecting piece and is convenient to weld and fix), so that the annular push plate 42 and the annular support 41 are concentric and can circumferentially rotate; for stability, at least two pairs of arc-shaped slide rails 47 and first slide blocks 48 are symmetrically distributed on two sides of the annular support 41. The third driving piece 46 is a driving motor and is fixed at the bottom of the annular bracket 41 through a bracket 461, the output end of the third driving piece 46 is fixed with a second friction wheel 49, the second friction wheel 49 is abutted with the inner wall of the annular push plate 42, and the third driving piece 46 is started to drive the second friction wheel 49 to rotate, so that the annular push plate 42 is driven to rotate under the action of friction force.

An annular cavity is formed between the annular push plate 42 and the annular, the pressing plates 43 are multiple, are horizontally and obliquely fixed on the inner wall of the annular push plate 42 in a clockwise or anticlockwise direction, the pressing plates 43 are of a sheet-shaped structure and have certain rigidity, steel plates, plastic plates and wood plates can be adopted, one ends of the pressing plates are fixed with the inner wall of the annular push plate 42 (fixing modes can be welding, bolt fixing and the like, proper fixing modes are selected according to different materials of the pressing plates 43), the other ends of the pressing plates are free ends, and the pressing plates 43 are vertically arranged.

As shown in fig. 7, slide holes 411 which are the same as the number of the pressing plates 43 are formed in the annular bracket 41 in a radial manner, and a nut holder 44 is slidably fitted in each slide hole 411; the plurality of nut holders 44 are arranged in a radioactive manner, and through holes for the nut holders 44 to pass through are formed in the cylindrical section 22; as shown in fig. 8 and 9, one end of the cylindrical section 22 facing the nut retainer 44 is provided with a nut placing platform 441, and one side of the nut placing platform 441 facing the center of the cylindrical section 22 is open for horizontally withdrawing the nut retainer 44 after the nut and the bolt are fixed; a third friction wheel 400 is fixed at one end of the nut retainer 44 facing away from the center of the cylindrical section 22; the third friction wheel 400 is abutted against the side wall of the pressing plate 43 facing the cylindrical section 22; the third driving piece 46 is driven, the second friction wheel 49 drives the annular push plate 42 to rotate, the annular push plate 42 drives the pressing plate 43 to circumferentially rotate, and the pressing plate 43 extrudes the nut retainer 44 to move towards the cylindrical section 22 through the third friction wheel 400, so that the nut is sent to a set position;

as shown in fig. 9, the bolt retainer 45 includes a bolt retaining platform 451, the bolt retaining platform 451 is provided with a limiting step, the center of the limiting step is a bolt through hole penetrating up and down, a gasket is limited in the limiting step, and the bolt passes through the bolt through hole from bottom to top to be in threaded fit with the gasket. The diameter of the bolt through hole is larger than that of the nut of the bolt, when the bolt and the nut are fixed, the bolt walks upwards, and finally the nut of the bolt passes through the bolt through hole.

In this embodiment, the bolt holder 45 and the nut holder 44 may be integrated, and as shown in fig. 9, both holders have a substantially rectangular parallelepiped shape, and are connected by a connecting rod, so that the weight can be reduced. The screw holder 45 may be provided in a split type, or may extend from the bottom of the ring bracket 41 toward the center, and the screw holder and the ring bracket are integrally designed as indicated by reference numeral 45 in fig. 6. Of course, since the flange of the steel pipe pole has the reinforcing rib, the bolt holder 45 is interfered, and in order to solve this problem, the bolt holder 45 is partially cut, and when the cut area is large and the gasket cannot be placed, the bolt holder 45 and the nut holder 44 can be fixed to extend and retract together with the nut holder. In this embodiment, the bolt holder 45 of the interference portion is integrated with the nut holder 44, and the bolt holder 45 without interference position is integrated with the ring-shaped bracket 41, and one end of the connecting rod 100 between the clamping section and the guiding section is fixed to the bottom wall between the rings, and the other end is fixed to the clamping section.

When the nuts and bolts are fixed, the third driving member 46 is turned over to cancel the pressure of the pressing plate 43 on the nut holder 44, and at this time, the nut holder 44 needs a reverse thrust force to reset the nut holder 44, so in this embodiment, a limiting cavity 442 is formed on the side wall of the nut holder 44, as shown in fig. 9, a stop (not shown) extends out of the side wall of the sliding hole 411 toward the limiting cavity 442, a spring (not shown) is limited in the limiting cavity 442, one end of the spring abuts against the baffle, the other end abuts against the end of the limiting cavity 442 away from the cylindrical section 22, when the nut holder 44 moves toward the cylindrical section 22, the spring is pressed, and after the pressing plate 43 is removed, the nut holder 44 is reset under the action of the spring reset. The telescopic nut holder 44 does not cause any obstacle to the falling of the upper steel pipe rod.

In this embodiment, the pushing position of the nut is controlled by the following method:

two capacitive proximity switches 431 are fixed on one side of one pressing plate 43, which is opposite to the third friction wheel 400, the two proximity switches 431 are arranged front and back, when the third friction wheel 400 runs to the proximity switch 431 positioned at the rear position of the pressing plate 43, the proximity switch 431 is conducted, a description nut is sent to the position, at the moment, a controller receives a signal of the rear proximity switch 431, a signal for tightening a bolt can be sent out, at the moment, the tightening unit 5 is started, when the nut is sleeved on the bolt for a certain time, the controller sends a control signal to control the third driving piece 46 to overturn, so that the pressing plate 43 is driven to retract, when the third friction wheel 400 runs to the proximity switch 431 positioned at the front position of the pressing plate 43, the nut retainer 44 is stopped after reset, and the third driving piece 46 is stopped.

Tightening unit 5:

as shown in fig. 10, the tightening unit 5 includes a linear motor 51, a fourth friction wheel 52, a rotary motor 53, a tightening motor 54, a second slide rail 55, and a second slider 56; the second sliding rail 55 is an annular rail and is fixed outside the clamping section 1, the second sliding block 56 is in sliding fit with the second sliding rail 55, the linear motor 51 is fixed with the second sliding block 56, the tightening motor 54 is fixed at the output end of the linear motor 51, and the tightening motor 54 is driven by the linear motor 51 to move up and down; the rotating motor 53 is fixed to the second slider 56, the fourth friction wheel 52 is fixed to the output end of the rotating motor 53, and the fourth friction wheel 52 abuts against the outer wall of the lower steel pipe rod. Specifically, a horizontal bracket 57 is fixed on one side of the second sliding block 56, which is opposite to the steel pipe rod, the stand of the linear motor 51 is fixed on the lower surface of the horizontal bracket 57, the output end passes through the horizontal bracket 57 upwards, a third sliding block 58 is fixed on the output end, the third sliding block 58 is in sliding fit with a limiting rod 59, and the limiting rod 59 is fixed on the horizontal bracket 57 through a vertical frame 500. The third slider 58 is generally square and has a side wall secured to the side wall of the housing of the screw down motor 54. The rotary motor 53 is fixed to the second slider 56 by an L-shaped bracket 501. One side wing of the L-shaped bracket 501 is fixed with the second sliding block 56 in a vertical state, the other side wing is in a horizontal state, the rotating motor 53 is fixed on the upper surface of the side wing in the horizontal state of the L-shaped bracket 501, the output end passes through the side wing, and the fourth friction wheel 52 is fixed with the output end of the rotating motor 53. In this embodiment, an up proximity switch 501 is also fixed on the stand 500, and when the tightening motor 54 goes up to the position of the up proximity switch 502, the up proximity switch 502 sends a tightening completion signal to the controller. The specific working principle is as follows:

the linear motor 51 is started to drive the third sliding block 58 to move up and down, so that the tightening motor 54 can be driven to move up and down, when the tightening approaching switch 501 is located, the controller receives a tightening completion signal, and controls the linear motor 51 to rotate reversely to drive the tightening motor 54 to move down, after the tightening motor is moved down in place, the rotating motor 53 is started, the fourth friction wheel 52 rubs against the outer wall of the steel pipe rod to drive the second sliding block 56 to move along the second sliding block 56, and the running distance is determined according to the rotation angle of the fourth friction wheel 52, which can be controlled by the bolt interval. When the screw moves to the lower part of the next screw, the screw is screwed up by repeating the above actions, and the like until all the screws are screwed up.

In this embodiment, in order to facilitate the clamping with lower steel pipe pole, vertically divide into two halves with whole device, the installation face of two halves adopts slot structure cooperation bolt fastening.

When the bolt is particularly used, the bolt and the gasket are placed on the bolt limiting step before assembly. Then, the two halves are held at the top of the lower steel pipe rod on the ground, the clamping is fixed by bolts, the clamping section tightly holds the lower steel pipe rod, the lower steel pipe rod is lifted to a vertical state by a crane, the upper steel pipe rod is lifted to be vertical and slowly dropped, the upper steel pipe rod is guided to the cylindrical section 22 from the horn section 21, the upper steel pipe rod is roughly butted with the lower steel pipe rod, the first driving piece 31 and the second driving piece 32 are started, when the upper steel pipe rod is rotated by the first friction wheel 34, the lower flange plate of the upper steel pipe rod is shot by the camera from top to bottom, the shot picture or video is sent to the ground, the first driving piece 31 and the second driving piece 32 are controlled manually to stop action, or the picture is acquired by automatic control and target identification is performed, and when the upper screw hole and the lower screw hole are aligned, the first driving piece 31 and the second driving piece 32 are controlled to stop action by a control program, and the upper screw hole and the lower screw hole are completed. Then, the third driving member 46 is started to push the nut, and after the nut is put in place above the flange of the upper steel pipe pole, the tightening unit 5 is started to rotate the bolt to move upwards so as to tighten the bolt. After one tightening step is completed, the controller receives a tightening completion signal, controls the linear motor 51 to rotate reversely, drives the tightening motor 54 to move downwards, starts the rotating motor 53 after the tightening motor moves downwards in place, and drives the second sliding block 56 to move along the second sliding block 56 by friction between the fourth friction wheel 52 and the outer wall of the steel pipe rod, wherein the running distance is determined by controlling the rotation angle of the fourth friction wheel 52 according to the bolt distance. And when the device runs below the next bolt, repeating the above actions to complete the screwing of the bolt, and the like until all the bolts are screwed, so that the butt joint device can be manually dismantled.

The above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (8)

1. The single-column steel pipe pole high-altitude unmanned auxiliary butting device comprises an indexing unit and a butting device, wherein the butting device comprises a cylindrical section (22) for limiting the perpendicularity of the upper steel pipe pole; the device is characterized by comprising a first driving piece (31), a second driving piece (32), a swing arm (33) and a first friction wheel (34); the first driving piece (31) is fixed on the outer side of the cylindrical section (22), one end of the swing arm (33) is fixed with the output end of the first driving piece (31), the second driving piece (32) is fixed on the other end of the swing arm (33), and the first friction wheel (34) is fixed with the output end of the second driving piece (32); a window (221) is formed in the side wall of the cylindrical section (22); the first driving piece (31) drives the swing arm (33) to rotate, so that the first friction wheel (34) passes through the window (221) to be in contact with the outer wall of the upper steel pipe rod; the second driving piece (32) drives the first friction wheel (34) to rotate, so that the upper steel pipe rod is driven to rotate circumferentially.

2. The indexing unit of the single-column steel pipe pole high-altitude unmanned docking device according to claim 1, further comprising a monitoring unit (6); the monitoring unit (6) collects screw hole information of the upper steel pipe rod and the lower steel pipe rod and sends the screw hole information to the controller, and the controller controls the starting and stopping of the first driving piece (31) and the second driving piece (32) according to the centering condition.

3. The indexing unit of the single-column steel pipe pole high-altitude unmanned docking device according to claim 1 or 2, wherein the swing arm (33) comprises a swing arm first section (331) and a swing arm second section (332); one side of the swing arm first section (331) and one side of the swing arm second section (332), which faces the window (221), are elastically connected through a spring (333), and one side of the swing arm second section, which faces away from the window (221), is connected through an elastic block (334); when the first swing arm section (331) and the second swing arm section (332) are in a straight line, the spring (333) is in a natural state.

4. The indexing unit of the single-column steel pipe pole high-altitude unmanned auxiliary docking device according to claim 2, wherein the monitoring unit (6) is a camera, is fixed on a swing arm section (331) through a bracket, enters a window (221) along with a swing arm (33), and shoots a screw hole from top to bottom.

5. The indexing unit of the single-column steel pipe pole high-altitude unmanned docking device according to claim 4, wherein the camera is fixed with a swing arm section (331) through a bracket, and extends horizontally to the window (221).

6. The indexing unit of the single-column steel pipe pole high-altitude unmanned butt joint device according to claim 3, wherein the first swing arm section (331) and the second swing arm section (332) are made of C-shaped steel, and the spring (333) is fixed on the inner wall of a C-shaped steel wing plate.

7. The indexing unit of the single-column steel pipe pole high-altitude unmanned docking device according to claim 3, wherein the elastic block is fixed on the outer wall of the C-shaped steel wing plate.

8. A single pole steel pole high altitude unmanned docking apparatus indexing unit according to claim 3, wherein the first swing arm section (331) and the second swing arm section (332) are rectilinear under the action of the spring (333) and the resilient block (334) when the first friction wheel (34) is not in contact with the steel pole.

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