CN118498329B - Three-dimensional operation auxiliary device of electric power construction - Google Patents

Abstract

The invention belongs to the technical field of power engineering construction, in particular to a three-dimensional operation auxiliary device for power engineering, which comprises a walking frame, a variable-pitch moving mechanism, an asymptotic compacting mechanism and an auxiliary force type weighting mechanism, wherein the variable-pitch moving mechanism is arranged on the side wall of the walking frame, the progressive compaction mechanism is arranged on the inner wall of the walking frame, the auxiliary force type weighting mechanism is arranged at one end of the walking frame based on the principle of the progressive compaction mechanism, and the progressive compaction mechanism comprises a sliding connection mechanism and a walking mechanism. The invention provides an electric power construction three-dimensional operation auxiliary device which is used for gradually compacting and tamping a backfilled foundation surface in a weight superposition mode, compacting and tamping under low gravity are beneficial to discharging air in foundation surface soil, increasing the compactness of the foundation surface soil and improving the bearing capacity and stability of the foundation surface soil.

Description

Three-dimensional operation auxiliary device of electric power construction

Technical Field

The invention belongs to the technical field of power engineering construction, and particularly relates to a three-dimensional operation auxiliary device for power construction.

Background

Electric power engineering, i.e. engineering related to the production, transportation, distribution of electrical energy, also broadly includes engineering that uses electricity as a motive force and energy source in a variety of fields. Meanwhile, the power transmission and transformation project can be understood, the project is built according to a plan, in the power construction process, in order to ensure the normal installation of the power equipment, the foundation surface is required to be compacted and tamped, the stability of the foundation surface is ensured, and the subsequent installation of the power equipment is firmer.

The existing auxiliary device for three-dimensional operation of electric power construction has the following problems:

When the existing electric power construction auxiliary device is used for tamping and compacting the construction foundation surface, the backfilled foundation surface is relatively loose in soil, after the backfilled foundation surface is tamped and compacted, a large topography gap exists between the compacted soil and the uncompacted soil, so that the situation of uneven ground after compaction occurs, the compaction force is large, air in the compacted soil can not be discharged timely, and stability of the compacted foundation surface is further affected.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the scheme provides the electric power construction three-dimensional operation auxiliary device which is used for gradually compacting and tamping the backfilled foundation surface in a weight superposition mode, compacting and tamping the backfilled foundation surface under low gravity to facilitate air discharge in the foundation surface soil, increase the compactness of the foundation surface soil and improve the bearing capacity and stability of the foundation surface soil.

The technical scheme adopted by the scheme is as follows: the utility model provides a three-dimensional operation auxiliary device of electric power construction, including walking frame, displacement type moving mechanism, asymptotic type compaction mechanism and auxiliary force type aggravate the mechanism, displacement type moving mechanism locates the walking frame lateral wall, the travelling frame inner wall is located to the asymptotic type compaction mechanism, auxiliary force type aggravates the mechanism and locates the one end that the walking frame was kept away from to the asymptotic type compaction mechanism, the asymptotic type compaction mechanism includes slip mechanism and running gear, slip mechanism locates the walking frame inner wall, slip mechanism locates the one end that the walking frame was kept away from to the slip mechanism, auxiliary force type aggravates the mechanism and includes pressure boost mechanism and tilting mechanism, pressure boost mechanism locates the running mechanism both sides, tilting mechanism locates on the pressure boost mechanism.

As further preferable in the scheme, the variable-pitch moving mechanism comprises a threaded shaft and a moving wheel, wherein the threaded shaft is arranged on the side wall of the walking frame, the threaded shaft is in threaded connection with the walking frame, and the moving wheel rotates and is arranged at one end, far away from the walking frame, of the threaded shaft.

When the power engineering backfill foundation is used, a constructor needs a threaded shaft with the length, the movable wheel is rotated and mounted at one end of the threaded shaft, which is far away from the movable wheel, is screwed into the side wall of the walking frame, and the walking frame moves on roadbeds at two sides of the power engineering backfill foundation surface to be compacted through the movable wheel.

Preferably, the sliding connection mechanism comprises a U-shaped frame, a sliding shaft, a sliding block and a variable-distance spring, wherein the U-shaped frame is arranged on the inner walls of the two ends of the walking frame, the sliding shaft is arranged at one end of the U-shaped frame far away from the walking frame, the sliding block is arranged on the outer side of the sliding shaft in a sliding manner, and the variable-distance spring is arranged between the sliding block on the outer side of the sliding shaft and the inner wall of the U-shaped frame; the travelling mechanism comprises compaction plates, compaction shafts and compaction wheels, wherein the compaction plates are arranged on one side, far away from the U-shaped frame, of the sliding blocks, the compaction shafts are arranged between the compaction plates, and the compaction wheels are rotationally arranged on the outer sides of the compaction shafts.

When the electric power engineering backfill foundation surface compacting device is used, the walking frame moves on the roadbed through the moving wheels, the walking frame drives the compacting disc to move under the action of the sliding shaft and the sliding block through the U-shaped frame in the moving process, the compacting disc drives the compacting shaft to move, and the compacting wheel rotates around the walking frame to roll on the electric power engineering backfill foundation surface to be compacted, so that the electric power engineering backfill foundation surface is compacted.

Specifically, the boosting mechanism comprises a boosting frame, a boosting shaft, boosting pinch rollers, multi-angle threaded holes and multi-angle bolts, wherein the boosting frame is symmetrically arranged at two ends of the compaction disc, the boosting frame is rotationally arranged at the outer side of the compaction disc, the boosting shaft is arranged between the boosting frames, the boosting pinch rollers are rotationally arranged at the outer side of the boosting shaft, a plurality of groups of multi-angle threaded holes are arranged on the side wall of the compaction disc, the multi-angle bolts are arranged on the side wall of the boosting frame, one end of each multi-angle bolt, which is far away from the boosting frame, is arranged in each multi-angle threaded hole, and the multi-angle bolts are in threaded connection with the multi-angle threaded holes; the turnover mechanism comprises a rotating disc, a guide frame, a force adjusting plate, a booster spring, a locking nut and a guide block, wherein the rotating disc is symmetrically arranged at two ends of the compacting shaft in pairs, the rotating disc is rotationally arranged at the outer side of the compacting shaft, the guide frame is symmetrically arranged at two ends of the force adjusting shaft, the guide block is respectively arranged at the upper wall and the bottom wall of the guide frame, the force adjusting shaft penetrates through the side wall of the guide block, the force adjusting plate is arranged at one side, close to the rotating disc, of the force adjusting shaft, the booster spring is arranged between the force adjusting plate and the rotating disc, the locking nut is arranged at one end, far away from the force adjusting plate, of the force adjusting shaft, and the locking nut is in threaded connection with the force adjusting shaft.

During the use, need increase the weight of compaction wheel at the rolling in-process of compaction wheel along the electric power engineering backfill basal plane of waiting to compact, be convenient for reach the degree of ramming of electric power engineering backfill basal plane, under the initial state, the helping hand frame is the level setting, the multi-angle screw bolt screw in is to multi-angle screw hole inside, the helping hand frame is fixed state, the helping hand spring that the helping hand frame upper wall set up has the pulling force that contracts, the helping hand spring that helping hand frame diapire set up has the promotion elasticity, multi-angle screw bolt keeps away from multi-angle screw hole inside, the helping hand frame that compaction dish both ends set up is the level setting under the state of not receiving multi-angle screw bolt fastening, the force adjustment axle is equipped with the leading truck laminating, the gravity of force increasing pinch roller equals with the sum of the pulling force and elasticity of helping hand spring, at this moment, the compaction wheel is the same with the weight of increasing pinch roller, roll on electric power engineering backfill basal plane through compaction wheel and force increasing pinch roller.

The side walls of the compaction wheel and the reinforcement pinch roller are respectively provided with a weighting threaded hole, the weighting threaded column is arranged between the weighting threaded holes, and the weighting threaded column is in threaded connection with the weighting threaded holes.

When the electric power engineering backfill foundation surface compression strength increasing device is used, when the weight of the compression wheel and the reinforcing pinch roller can not meet the compression strength of the electric power engineering backfill foundation surface, the weighting threaded column is screwed into the weighting threaded hole, so that weight of the compression wheel and the reinforcing pinch roller is increased, and the compression strength of the compression wheel and the reinforcing pinch roller to the electric power engineering backfill foundation surface is improved.

The beneficial effect that this scheme of adoption above-mentioned structure obtained is as follows:

Compared with the prior art, the scheme adopts a mode of overlapping weight, through the arranged asymptotic compaction mechanism and auxiliary force type weighting mechanism, under the mutual cooperation of the compaction wheel and the reinforcement pinch roller, the compaction operation can be gradually carried out on the relatively loose electric power engineering backfill foundation surface, the air inside the soil of the backfill foundation surface is convenient to discharge, the compactness of the backfill soil is increased, the bearing capacity and the stability of the backfill soil are improved, the topography gap between the uncompacted electric power engineering backfill foundation surface and the electric power engineering backfill foundation surface after compaction can be reduced through the gradual increase of the weight of the compaction wheel, the flatness of the electric power engineering backfill foundation surface after compaction is ensured, thereby the use efficiency of the electric power construction auxiliary equipment is improved to a certain extent, the compaction wheel and the reinforcement pinch roller are arranged at the same level, locking nuts arranged on the upper part and the bottom of the power-assisted frame are respectively rotated, the length of a power-assisted spring arranged on the upper part of the power-assisted frame is prolonged, the length of the power-assisted spring arranged on the bottom of the power-assisted frame is shortened, at the moment, the tension of the spring on the upper part of the power-assisted frame is maximum, the thrust of the spring on the bottom of the power-assisted frame is maximum, the reinforcement pinch roller is lifted upwards, the reinforcement pinch roller is changed into an inclined state from a horizontal state, the multi-angle bolts are screwed into the multi-angle threaded holes, the power-assisted frame is changed into a fixed state from an active state, an included angle between the power-assisted frames is an obtuse angle, the weight of the compaction wheel is increased, and the compaction wheel slides down by a sliding shaft under the deformation of the variable-distance spring to reduce the height, so that the compaction wheel improves the compaction force on a backfilled foundation surface of an electric engineering.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present solution;

FIG. 2 is a bottom perspective view of the present solution;

FIG. 3 is a top perspective view of the present solution;

FIG. 4 is a front view of the present solution;

FIG. 5 is a side view of the present solution;

FIG. 6 is a top view of the present solution;

FIG. 7 is an enlarged view of the portion I of FIG. 1;

FIG. 8 is an enlarged view of the portion II of FIG. 2;

Fig. 9 is an enlarged structural view of a portion III of fig. 6.

The device comprises a walking frame, 2, a variable-pitch type moving mechanism, 3, a threaded shaft, 4, a moving wheel, 5, an asymptotic compacting mechanism, 6, a sliding connection mechanism, 7, a U-shaped frame, 8, a sliding shaft, 9, a sliding block, 10, a variable-pitch spring, 11, a walking mechanism, 12, a compacting disc, 13, a compacting shaft, 14, a compacting wheel, 15, an auxiliary force type weighting mechanism, 16, a pressurizing mechanism, 17, an auxiliary force frame, 18, an auxiliary force shaft, 19, an auxiliary force pressing wheel, 20, a multi-angle threaded hole, 21, a multi-angle bolt, 22, a turnover mechanism, 23, a rotating disc, 24, a guide frame, 25, a force adjusting shaft, 26, a force adjusting plate, 27, an auxiliary force spring, 28, a locking nut, 29, a guide block, 30, a threaded hole, 31 and a weighting threaded column.

The accompanying drawings are included to provide a further understanding of the present disclosure and are incorporated in and constitute a part of this disclosure, illustrate and do not limit the disclosure.

Detailed Description

The technical solutions in the embodiments of the present solution will be clearly and completely described below with reference to the drawings in the embodiments of the present solution, and it is apparent that the described embodiments are only some embodiments of the present solution, but not all embodiments; all other embodiments, based on the embodiments in this solution, which a person of ordinary skill in the art would obtain without inventive faculty, are within the scope of protection of this solution.

In the description of the present embodiment, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate orientation or positional relationships based on those shown in the drawings, merely to facilitate description of the present embodiment and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and thus should not be construed as limiting the present embodiment.

As shown in fig. 1-9, the power construction three-dimensional operation auxiliary device provided by the scheme comprises a walking frame 1, a variable-pitch type moving mechanism 2, an asymptotic compaction mechanism 5 and an auxiliary force type weighting mechanism 15, wherein the variable-pitch type moving mechanism 2 is arranged on the side wall of the walking frame 1, the asymptotic compaction mechanism 5 is arranged on the inner wall of the walking frame 1, the auxiliary force type weighting mechanism 15 is arranged on one end of the asymptotic compaction mechanism 5 far away from the walking frame 1, the asymptotic compaction mechanism 5 comprises a sliding connection mechanism 6 and a walking mechanism 11, the sliding connection mechanism 6 is arranged on the inner wall of the walking frame 1, the walking mechanism 11 is arranged on one end of the sliding connection mechanism 6 far away from the walking frame 1, the auxiliary force type weighting mechanism 15 comprises a pressurizing mechanism 16 and a turnover mechanism 22, the pressurizing mechanism 16 is arranged on two sides of the walking mechanism 11, and the turnover mechanism 22 is arranged on the pressurizing mechanism 16.

The variable-pitch moving mechanism 2 comprises a threaded shaft 3 and a moving wheel 4, the threaded shaft 3 is arranged on the side wall of the walking frame 1, the threaded shaft 3 is in threaded connection with the walking frame 1, and the moving wheel 4 is rotatably arranged at one end, far away from the walking frame 1, of the threaded shaft 3.

The sliding mechanism 6 comprises a U-shaped frame 7, a sliding shaft 8, sliding blocks 9 and a variable-pitch spring 10, wherein the U-shaped frame 7 is arranged on the inner walls of the two ends of the walking frame 1, the sliding shaft 8 is arranged at one end of the U-shaped frame 7 far away from the walking frame 1, the sliding blocks 9 are arranged on the outer side of the sliding shaft 8 in a sliding manner, and the variable-pitch spring 10 is arranged between the sliding blocks 9 on the outer side of the sliding shaft 8 and the inner walls of the U-shaped frame 7; the travelling mechanism 11 comprises compaction plates 12, compaction shafts 13 and compaction wheels 14, wherein the compaction plates 12 are arranged on one side, far away from the U-shaped frame 7, of the sliding blocks 9, the compaction shafts 13 are arranged between the compaction plates 12, and the compaction wheels 14 are rotatably arranged on the outer sides of the compaction shafts 13.

The boosting mechanism 16 comprises a boosting frame 17, boosting shafts 18, boosting pinch rollers 19, multi-angle threaded holes 20 and multi-angle bolts 21, wherein the boosting frame 17 is symmetrically arranged at two ends of the compaction disc 12, the boosting frame 17 is rotationally arranged at the outer side of the compaction disc 12, the boosting shafts 18 are arranged between the boosting frames 17, the boosting pinch rollers 19 are rotationally arranged at the outer sides of the boosting shafts 18, a plurality of groups of the multi-angle threaded holes 20 are arranged on the side walls of the compaction disc 12, the multi-angle bolts 21 are arranged on the side walls of the boosting frame 17, one ends of the multi-angle bolts 21, which are far away from the boosting frame 17, are arranged in the multi-angle threaded holes 20, and the multi-angle bolts 21 are in threaded connection with the multi-angle threaded holes 20; the turnover mechanism 22 comprises a rotating disc 23, a guide frame 24, a force adjusting shaft 25, a force adjusting plate 26, a power-assisted spring 27, a locking nut 28 and a guide block 29, wherein the rotating disc 23 is symmetrically arranged at two ends of the compaction shaft 13 in pairs, the rotating disc 23 is rotationally arranged at the outer side of the compaction shaft 13, the guide frame 24 is symmetrically arranged at two ends of the force adjusting shaft 18, the guide block 29 is respectively arranged on the upper wall and the bottom wall of the guide frame 24, the force adjusting shaft 25 penetrates through the side wall of the guide block 29, the force adjusting plate 26 is arranged on one side, close to the rotating disc 23, of the force adjusting shaft 25, the power-assisted spring 27 is arranged between the force adjusting plate 26 and the rotating disc 23, the locking nut 28 is arranged at one end, far away from the force adjusting plate 26, of the force adjusting shaft 25, and the locking nut 28 is in threaded connection with the force adjusting shaft 25.

The side walls of the compacting wheel 14 and the boosting pinch wheel 19 are respectively provided with a weighting threaded hole 30, the weighting threaded column 31 is arranged between the weighting threaded holes 30, and the weighting threaded column 31 is in threaded connection with the weighting threaded holes 30.

In the specific use, in the first embodiment, a threaded shaft 3 with the length required by a constructor is selected, a movable wheel 4 is rotatably installed at one end of the threaded shaft 3, which is far away from the movable wheel 4, is screwed into the side wall of a walking frame 1, the walking frame 1 moves on roadbed at two sides of a backfill foundation surface of an electric engineering through the movable wheel 4, the walking frame 1 drives a compaction disc 12 to move under the action of a sliding shaft 8 and a sliding block 9 through a U-shaped frame 7 in the moving process, the compaction disc 12 drives a compaction shaft 13 to move, a compaction wheel 14 rotates around the walking frame 1, the compaction wheel 14 rolls on the backfill foundation surface, and the compaction operation is performed on the foundation surface;

Specifically, in the process that the compaction wheel 14 rolls along the backfilled foundation surface of the electric power engineering to be compacted, the weight of the compaction wheel 14 needs to be gradually increased, on one hand, the air in the soil of the pressed foundation surface can be timely discharged, on the other hand, the operation intensity of compacting and tamping the soil of the foundation surface is conveniently achieved, in the initial state, the power assisting frame 17 is horizontally arranged, the multi-angle bolt 21 is screwed into the multi-angle threaded hole 20, the power assisting frame 17 is in a fixed state, the power assisting spring 27 arranged on the upper wall of the power assisting frame 17 has a retraction pulling force, the power assisting spring 27 arranged on the bottom wall of the power assisting frame 17 has a pushing elastic force, the multi-angle bolt 21 is far away from the multi-angle threaded hole 20, the power assisting frames 17 arranged at two ends of the compaction disc 12 are horizontally arranged in a state of being not fixed by the multi-angle bolt 21, the force adjusting shaft 25 is in fit with the guide frame 24, the weight of the power assisting pressing wheel 19 is equal to the sum of the pulling force and the elastic force of the power assisting spring 27, at the moment, the weight of the compaction wheel 14 is identical to the weight of the compaction wheel 19, the compaction wheel 14 and the pressing wheel 19 are synchronously rolled on the foundation surface of the electric power engineering, the power assisting frame 17 is in a fixed state, the backfilled, and the air in the soil of the foundation surface of the electric power engineering is gradually discharged under the low weight of the compacted soil of the backfilled;

After the electric power engineering backfill foundation surface is preliminarily compacted, the weights of the compacting wheel 14 and the boosting pinch roller 19 are required to be adjusted, the electric power engineering backfill foundation surface is further compacted, the multi-angle bolt 21 at one end of the compacting disc 12 is rotated, the multi-angle bolt 21 is screwed out from the multi-angle threaded hole 20, the boosting frame 17 is changed from a fixed state to an active state, the locking nut 28 at the bottom of the boosting frame 17 in the active state is rotated, the locking nut 28 is rotated along the adjusting shaft 25 to be far away from the side wall of the guide frame 24, the wheel base of the adjusting shaft 25, which is close to the locking nut 28, is gradually shortened, the adjusting plate 26 is far away from the side wall of the guide frame 24, the boosting spring 27 at the bottom of the boosting frame 17 in the active state is shortened, the pushing elastic strength of the boosting spring 27 at the bottom of the boosting frame 17 is increased, then the boosting frame 17 in the active state is lifted, the boosting frame 17 is rotated around the compacting disc 12 to drive the boosting frame 19 to be far away from the electric power engineering backfill foundation surface to be compacted, the boosting frame 17 is rotated by the boosting frame 17 through the boosting shaft 18, the boosting spring 27 at the upper part of the boosting frame 17 in the active state is rotated to be driven by the boosting frame 17, the boosting frame 17 is driven by the boosting frame 17 in the common driving frame 17 in the active state, and the boosting frame 17 in the active state is driven by the stretching state to reach the boosting frame 19, and the boosting frame 19 is screwed up to the position is increased to the fixed state, and the boosting frame 19 is screwed up to the boosting frame is positioned to the boosting frame 19 in the boosting frame is positioned at the position to be at the position to the boosting frame is positioned;

after the electric power engineering backfill foundation surface is further compacted, the weight of the compaction wheel 14 is required to be adjusted to carry out final compaction operation on the electric power engineering backfill foundation surface, the position of the reinforcement pressing wheel 19 placed in a preliminary state is used as a standard, the compaction wheel 14 and the reinforcement pressing wheel 19 are horizontally arranged, locking nuts 28 arranged at the upper part and the bottom of the booster frame 17 are respectively rotated, the length of a booster spring 27 arranged at the upper part of the booster frame 17 is prolonged, the length of the booster spring 27 arranged at the bottom of the booster frame 17 is shortened, at the moment, the tension of the spring at the upper part of the booster frame 17 is the maximum, the thrust of the spring at the bottom of the booster frame 17 is the maximum, the reinforcement pressing wheel 19 is lifted up, the reinforcement pressing wheel 19 is changed into an inclined state from a horizontal state, the multi-angle bolts 21 are screwed into the multi-angle threaded holes 20, the booster frame 17 is changed into a fixed state from an active state, the included angle between the booster frames 17 is an obtuse angle, the weight of the compaction wheel 14 is increased, the compaction wheel 14 slides down by the sliding shaft 8 through the sliding block 9, and the sliding of the sliding block 9 under the deformation of the variable distance spring 10, the compression wheel 14 is lowered by the height, so that the compaction force of the compaction wheel 14 on the electric power engineering backfill foundation surface is improved;

After the foundation surface is backfilled by the compaction power engineering, the boosting pinch roller 19 is lowered to a horizontal state, the locking nuts 28 arranged at the upper part and the bottom of the boosting frame 17 are rotated, the length of the boosting spring 27 at the upper part of the boosting frame 17 is shortened, the elastic tension of the boosting spring 27 at the upper part of the boosting frame 17 is weakened, the boosting spring 27 at the bottom of the boosting frame 17 is stretched, the elastic thrust of the boosting spring 27 at the bottom of the boosting frame 17 is weakened, the multi-angle bolts 21 arranged on the side walls of the boosting frame 17 at the two ends of the compaction disc 12 are rotated, the multi-angle bolts 21 are screwed out from the inside of the multi-angle threaded holes 20, the boosting pinch roller 17 arranged at the two ends of the compaction disc 12 is changed into an active state from a fixed state, so that the boosting pinch roller 19 is reset to the same level as the compaction wheel 14 under the action of gravity, the multi-angle bolts 21 are screwed into the multi-angle threaded holes 20, and the boosting pinch roller 19 is fixed at the horizontal position, thereby completing the compaction operation of the foundation surface of the power engineering;

when the weight of the compacting wheel 14 and the reinforcing pinch roller 19 can not meet the compacting strength of the backfill foundation surface of the electric power engineering, screwing the weighting threaded column 31 into the weighting threaded hole 30, so as to further increase the weight of the compacting wheel 14 and the reinforcing pinch roller 19, and improve the compacting strength of the compacting wheel 14 and the reinforcing pinch roller 19 on the backfill foundation surface of the electric power engineering; repeating the operation when the product is used next time.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The present embodiment and the embodiments thereof have been described above with no limitation, and the embodiment shown in the drawings is merely one of the embodiments of the present embodiment, and the actual structure is not limited thereto. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the technical solution.

Claims (1)

1. The utility model provides an electric power construction three-dimensional operation auxiliary device, includes walking frame (1), its characterized in that: the walking device is characterized by further comprising a variable-pitch type moving mechanism (2), an asymptotic type compacting mechanism (5) and an auxiliary force type weighting mechanism (15), wherein the variable-pitch type moving mechanism (2) is arranged on the side wall of the walking frame (1), the asymptotic type compacting mechanism (5) is arranged on the inner wall of the walking frame (1), the auxiliary force type weighting mechanism (15) is arranged at one end, far away from the walking frame (1), of the asymptotic type compacting mechanism (5), the asymptotic type compacting mechanism (5) comprises a sliding connection mechanism (6) and a walking mechanism (11), the sliding connection mechanism (6) is arranged on the inner wall of the walking frame (1), the walking mechanism (11) is arranged at one end, far away from the walking frame (1), of the sliding connection mechanism (6), the auxiliary force type weighting mechanism (15) comprises a pressurizing mechanism (16) and a turnover mechanism (22), the pressurizing mechanism (16) is arranged on two sides of the walking mechanism (11), and the turnover mechanism (22) is arranged on the pressurizing mechanism (16).

The variable-pitch moving mechanism (2) comprises a threaded shaft (3) and a moving wheel (4), wherein the threaded shaft (3) is arranged on the side wall of the walking frame (1), the threaded shaft (3) is in threaded connection with the walking frame (1), and the moving wheel (4) is rotatably arranged at one end, far away from the walking frame (1), of the threaded shaft (3);

The sliding connection mechanism (6) comprises a U-shaped frame (7), a sliding shaft (8), sliding blocks (9) and a variable-distance spring (10), wherein the U-shaped frame (7) is arranged on the inner walls of two ends of the walking frame (1), the sliding shaft (8) is arranged at one end, far away from the walking frame (1), of the U-shaped frame (7), the sliding blocks (9) are arranged on the outer side of the sliding shaft (8) in a sliding mode, and the variable-distance spring (10) is arranged between the sliding blocks (9) on the outer side of the sliding shaft (8) and the inner walls of the U-shaped frame (7);

The travelling mechanism (11) comprises compaction plates (12), compaction shafts (13) and compaction wheels (14), wherein the compaction plates (12) are arranged on one side, far away from the U-shaped frame (7), of the sliding blocks (9), the compaction shafts (13) are arranged between the compaction plates (12), and the compaction wheels (14) are rotatably arranged on the outer sides of the compaction shafts (13);

The boosting mechanism (16) comprises a boosting frame (17), a boosting shaft (18), boosting pinch rollers (19), multi-angle threaded holes (20) and multi-angle bolts (21), wherein the boosting frame (17) is symmetrically arranged at two ends of the compaction disc (12), the boosting frame (17) is rotationally arranged at the outer side of the compaction disc (12), the boosting shaft (18) is arranged between the boosting frames (17), and the boosting pinch rollers (19) are rotationally arranged at the outer side of the boosting shaft (18);

The multi-angle threaded holes (20) are formed in the side wall of the compaction disc (12), the multi-angle bolts (21) are formed in the side wall of the power-assisted frame (17), one end, away from the power-assisted frame (17), of each multi-angle bolt (21) is formed in the multi-angle threaded hole (20), and each multi-angle bolt (21) is in threaded connection with each multi-angle threaded hole (20);

The turnover mechanism (22) comprises a rotating disc (23), a guide frame (24), a force adjusting shaft (25), a force adjusting plate (26), a power-assisted spring (27), locking nuts (28) and guide blocks (29), wherein the rotating disc (23) is symmetrically arranged at two ends of the compaction shaft (13) in pairs, the rotating disc (23) is rotationally arranged at the outer side of the compaction shaft (13), the guide frame (24) is symmetrically arranged at two ends of the power-assisted shaft (18), and the guide blocks (29) are respectively arranged at the upper wall and the bottom wall of the guide frame (24);

The power adjusting shaft (25) penetrates through the side wall of the guide block (29), the power adjusting plate (26) is arranged on one side, close to the rotating disc (23), of the power adjusting shaft (25), the power assisting spring (27) is arranged between the power adjusting plate (26) and the rotating disc (23), the locking nut (28) is arranged at one end, far away from the power adjusting plate (26), of the power adjusting shaft (25), and the locking nut (28) is in threaded connection with the power adjusting shaft (25).