CN112573215B

CN112573215B - Bridge construction is with bed stone pile device that has skew limiting mechanism

Info

Publication number: CN112573215B
Application number: CN202011410915.1A
Authority: CN
Inventors: 陈雪美
Original assignee: Qingdao Jiaojian Group Co ltd
Current assignee: Qingdao Jiaojian Group Co ltd
Priority date: 2020-12-05
Filing date: 2020-12-05
Publication date: 2023-01-10
Anticipated expiration: 2040-12-05
Also published as: CN112573215A

Abstract

The invention relates to the technical field of bridge construction, in particular to a foundation stone stacking device with an offset limiting mechanism for bridge construction. According to the invention, the second moving block and the rotating roller are arranged, the second driving block moves up and down on the surface of the connecting rod, the first moving block can drive the second moving block to slide in the partition plate, the foundation stone can fall on the surface of the partition plate through the rotation of the rotating roller, and the foundation stone can slide on the surface of the partition plate through the movement of the second moving block, so that the foundation stone can be effectively and conveniently loaded, the condition that the foundation stone needs to be orderly placed to be piled is avoided, the time for placing the foundation stone can be reduced, and the piling efficiency of the foundation stone is accelerated.

Description

Bridge construction is with bed stone pile device that has skew limiting mechanism

Technical Field

The invention relates to the technical field of bridge construction, in particular to a foundation stone stacking device with an offset limiting mechanism for bridge construction.

Background

The bridge is a component of a road, from the perspective of engineering technology, the development of the bridge can be divided into three periods of ancient, recent and modern times, the bridge generally consists of an upper structure, a lower structure, a support and an auxiliary structure, the upper structure is also called a bridge span structure and is a main structure for crossing obstacles, the lower structure comprises a bridge abutment, a bridge pier and a foundation, the support is a force transmission device arranged at the bridge span structure and the bridge pier or the support of the bridge abutment, the auxiliary structure refers to a bridge head butt strap, a conical protection slope, a revetment, a diversion project and the like, when the bridge is constructed, a large amount of foundation stones are generally used, the foundation stones are stones of the foundation of a building, and when the foundation stones used for bridge construction are piled, the piling is generally carried out through a piling device.

When the stacking device is used for stacking, the foundation stones need to be orderly arranged in advance and then sequentially sent into the stacking device in order to stack the foundation stones layer by layer, so that the stacking time of the foundation stones needs to be arranged in advance, and the working efficiency of the stacking device is influenced;

in addition, the stacking device directly places the foundation stones on the tray, and the foundation stones are easy to shift in the stacking process, so that the overall stability of the foundation stones after stacking is finished is poor, the foundation stones are easy to skew, and the foundation stone stacks are scattered, so that the foundation stone stacking device with the shift limiting mechanism for bridge construction is needed, and stacking is performed on the construction foundation stones.

Disclosure of Invention

The invention aims to solve the problems that the stacking time of the foundation stones is prolonged, the stacking efficiency is influenced, the foundation stones are easy to deviate, the stability of the stacked foundation stones is poor and the foundation stones are easy to deflect due to the fact that the foundation stones are manually placed in order and then are fed into a device layer by layer in the prior art, and the foundation stone stacking device with the deviation limiting mechanism for bridge construction is provided.

In order to achieve the purpose, the invention adopts the following technical scheme:

a foundation stone stacking device with an offset limiting mechanism for bridge construction comprises a stacking device body, wherein a pushing mechanism is arranged inside the stacking device body and comprises a supporting rod, the inner wall of the stacking device body is fixedly connected with the supporting rod, one end of the supporting rod, far away from the inner wall of the stacking device body, is fixedly connected with a fixed frame, a motor is arranged inside the fixed frame, the output end of the motor is connected with a fixed rotating shaft, one end, far away from the motor, of the fixed rotating shaft is fixedly connected with a first driving block, a first driving rod is inserted inside the first driving block, a first spring is welded on the side face of the first driving block, a hinge block is welded at one end, far away from the first driving block, of the first spring, a second driving block is hinged at one end, far away from the first spring, and a connecting rod is sleeved inside the second driving block, the top end of the connecting rod is fixedly connected with a third driving block, a first guide column is sleeved in the third driving block, baffle plates are sleeved on the two end surfaces of the first guide column, a first moving block is fixedly connected to the surface of the third driving block, a first sliding block is inserted in the first moving block, a second moving block is fixedly connected to one end, away from the first moving block, of the first sliding block, a second spring is welded to one end, close to the first sliding block, of the second moving block, the surface of the first moving block is fixedly connected with a second sliding block, one end, away from the first moving block, of the second sliding block is inserted in the partition plate, a limiting mechanism is arranged at the top end of the stacking device body, a stacking mechanism is arranged on the side surface of the stacking device body, the stacking mechanism comprises a stacking bin, and the right side surface of the stacking device body is fixedly connected with the stacking bin, and the inside in pile storehouse is inserted and is equipped with the connecting block, the one end fixedly connected with limiting plate in pile storehouse is kept away from to the connecting block, and the skin weld of limiting plate has the third spring, the one end welding that the limiting plate was kept away from to the third spring has the gag lever post, the inner wall fixed connection hinge bar in pile storehouse, and the one end fixedly connected with that the hinge bar kept away from in pile storehouse place the board, place the one end fixedly connected with stopper that the hinge bar was kept away from to the board, and the stopper inserts the inside of establishing at the collection frame, place the both sides fixedly connected with third movable block of board, and the inside of third movable block is inserted and is equipped with the second guide post, the skin weld of second guide post has the fourth spring.

Preferably, stop gear includes the pan feeding mouth, the pan feeding mouth is installed on the top of sign indicating number heap device main part, and the inside of pan feeding mouth installs the fixed axle through the bearing, the balancing weight has been cup jointed on the surface of live-rollers, and the inner wall fixedly connected with balancing weight of balancing weight, fixed bull stick is installed through the bearing in the surface of sign indicating number heap device main part, and the surface cover of fixed bull stick is equipped with the second drive rod, the second drive rod is inserted and is established the inside one end fixedly connected with splint of sign indicating number heap device main part, and the internally mounted of splint has the ball.

Preferably, the first driving block is rectangular, a circular through hole is formed in the first driving block, the first driving rod is cylindrical, and the size of the inner wall of the circular through hole formed in the first driving block is matched with the surface size of the first driving rod.

Preferably, the second driving block is rectangular, a circular through hole is formed in the second driving block, the connecting rod is cylindrical, and the size of the inner wall of the circular through hole formed in the second driving block is matched with the surface size of the connecting rod.

Preferably, the third driving block is cylindrical, a circular through hole is formed in the third driving block, the first guide column is cylindrical, and the third driving block is connected with the first guide column in a sliding mode.

Preferably, the first moving block is rectangular, a groove is formed in the first moving block, the second moving block is rectangular, an inclined plane is arranged on the surface of the second moving block, and the first moving block and the second moving block are in sliding connection.

Preferably, the partition plate is rectangular, a sliding groove is formed in the partition plate, the second sliding blocks are rectangular, two groups of the second sliding blocks are symmetrically arranged on the surface of the first moving block, and the two groups of the second sliding blocks are connected with the partition plate in a sliding mode.

Preferably, the spout has been seted up to the inside in pile storehouse, the surface symmetry of limiting plate is provided with two sets of connecting blocks, and two sets of connecting blocks all set up to the rectangle, pile storehouse and two sets of connecting blocks constitute sliding connection.

Preferably, the inner wall of the stacking bin is provided with a sliding groove, the third moving block is arranged to be rectangular, a circular through hole is formed in the third moving block, the stacking bin and the third moving block are connected in a sliding mode, the second guide column is arranged to be cylindrical, and the size of the inner wall of the circular through hole formed in the third moving block is matched with the surface size of the second guide column.

Preferably, the limiting rod is set to be rectangular, the surface of the limiting rod is set to be an inclined plane, through holes are formed in one side, away from the stacking device body, of the collecting frame at equal intervals, and the surface size of the limiting rod is matched with the size of the inner wall of each through hole formed in one side of the collecting frame at equal intervals.

Compared with the prior art, the invention has the beneficial effects that:

1. the device is provided with a second moving block and a rotating roller, the second driving block can move up and down on the surface of a connecting rod through the rotation of a first driving rod, at the moment, the connecting rod can drive a third driving block to move on the surface of a first guide column through the second driving block, so that the first moving block can drive the second moving block to slide in a partition plate, the foundation stone can fall on the surface of the partition plate through the rotation of the rotating roller by placing the foundation stone in the rotating roller, and the foundation stone can slide on the surface of the partition plate through the movement of the second moving block, so that the foundation stone can be effectively and conveniently loaded, the foundation stone can be prevented from being stacked after being placed orderly, the time for placing the foundation stone can be shortened, and the stacking efficiency of the foundation stone is accelerated;

2. the device is through being provided with the gag lever post and collecting the frame, removal through the bed stone, can make the bed stone get into the inside of collecting the frame, when the bed stone extrudees each other, can make the surface of bed stone extrusion gag lever post, when the bed stone is inconsistent with the inner wall of collecting the frame, can make the gag lever post shift out the inside of collecting the frame, at this moment, can make the whole downstream of collection frame, and elasticity through fourth spring self, can play the effect of buffering, when collecting the frame when removing, collect the inside through-hole of seting up of frame and when the gag lever post is in same level, can make the gag lever post insert the inside of establishing collecting the frame, and can play spacing bed stone's effect through splint, thereby conveniently push the inside of collecting the frame with bed stone layer upon layer, be convenient for carry out the pile up neatly to building bed stone, can restrict the bed stone pile through collecting the frame simultaneously, thereby can prevent that the bed stone from taking place the skew when the pile up.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and those skilled in the art will be able to derive other drawings without creative efforts.

FIG. 1 is a schematic cross-sectional view of the structure of the present invention;

FIG. 2 is a schematic top sectional view of the structure of the present invention;

FIG. 3 is a schematic top sectional view of the pushing mechanism and palletizing mechanism of the present invention;

FIG. 4 is a schematic top sectional view of a pushing mechanism according to the present invention;

FIG. 5 is a schematic top sectional view of the stacking mechanism of the present invention;

FIG. 6 is a schematic side sectional view of a stacking mechanism according to the present invention;

FIG. 7 is a schematic side sectional view of the structure of the spacing mechanism of the present invention;

FIG. 8 is a side sectional view of the pushing mechanism of the present invention.

In the figure: 1. a stacker device body; 2. a pushing mechanism; 21. a support bar; 22. a fixing frame; 23. a motor; 24. fixing the rotating shaft; 25. a first driving block; 26. a first driving lever; 27. a first spring; 28. a hinged block; 29. a second driving block; 210. a connecting rod; 211. a third driving block; 212. a first guide post; 213. a baffle plate; 214. a first moving block; 215. a first slider; 216. a second moving block; 217. a second slider; 218. a partition plate; 219. a second spring; 3. a limiting mechanism; 31. a feeding port; 32. a fixed shaft; 33. a rotating roller; 34. a balancing weight; 35. fixing the rotating rod; 36. a second driving lever; 37. a splint; 38. a ball bearing; 4. a stacking mechanism; 41. stacking; 42. connecting blocks; 43. a limiting plate; 44. a third spring; 45. a limiting rod; 46. a hinged lever; 47. placing the plate; 48. a limiting block; 49. a collection frame; 410. a third moving block; 411. a second guide post; 412. and a fourth spring.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 8, the present invention provides a technical solution: a foundation stone stacking device with an offset limiting mechanism for bridge construction comprises a stacking device body 1, a pushing mechanism 2 is arranged inside the stacking device body 1, the pushing mechanism 2 comprises a supporting rod 21, the supporting rod 21 is fixedly connected to the inner wall of the stacking device body 1, a fixed frame 22 is fixedly connected to one end, away from the inner wall of the stacking device body 1, of the supporting rod 21, a motor 23 is installed inside the fixed frame 22, the output end of the motor 23 is connected with a fixed rotating shaft 24, one end, away from the motor 23, of the fixed rotating shaft 24 is fixedly connected with a first driving block 25, a first driving rod 26 is inserted inside the first driving block 25, a first spring 27 is welded on the side surface of the first driving block 25, a hinged block 28 is welded on one end, away from the first driving block 25, of the hinged block 28 is hinged to a second driving block 29, and a connecting rod 210 is sleeved inside the second driving block 29, the top end of the connecting rod 210 is fixedly connected with a third driving block 211, a first guide post 212 is sleeved inside the third driving block 211, baffle plates 213 are sleeved on the surfaces of two ends of the first guide post 212, a first moving block 214 is fixedly connected to the surface of the third driving block 211, a first sliding block 215 is inserted inside the first moving block 214, a second moving block 216 is fixedly connected to one end, far away from the first moving block 214, of the first sliding block 215, a second spring 219 is welded at one end, close to the first sliding block 215, of the second moving block 216, a second sliding block 217 is fixedly connected to the surface of the first moving block 214, one end, far away from the first moving block 214, of the second sliding block 217 is inserted inside a baffle plate 218, the top end of the stacking device body 1 is provided with a limiting mechanism 3, the side surface of the stacking device body 1 is provided with a stacking mechanism 4, the stacking mechanism 4 comprises a stacking bin 41, the right side fixed surface of sign indicating number heap device main part 1 is connected with sign indicating number heap storehouse 41, and the inside of sign indicating number heap storehouse 41 is inserted and is equipped with connecting block 42, the one end fixedly connected with limiting plate 43 of sign indicating number heap storehouse 41 is kept away from to connecting block 42, and the skin weld of limiting plate 43 has third spring 44, the one end welding that limiting plate 43 was kept away from to third spring 44 has gag lever post 45, the inner wall fixed connection hinge bar 46 of sign indicating number heap storehouse 41, and the one end fixedly connected with of hinge bar 46 is kept away from to hinge bar 46 places board 47, place the one end fixedly connected with stopper 48 that hinge bar 46 was kept away from to board 47, and stopper 48 inserts the inside of establishing at collection frame 49, place the both sides fixedly connected with third movable block 410 of board 47, and the inside of third movable block 410 is inserted and is equipped with second guide post 411, the skin weld of second guide post 411 has fourth spring 412.

Further, the limiting mechanism 3 comprises a feeding port 31, the feeding port 31 is installed at the top end of the stacking device main body 1, a fixed shaft 32 is installed inside the feeding port 31 through a bearing, a balancing weight 34 is sleeved on the surface of the rotating roller 33, the balancing weight 34 is fixedly connected to the inner wall of the balancing weight 34, a fixed rotating rod 35 is installed on the surface of the stacking device main body 1 through a bearing, a second driving rod 36 is sleeved on the surface of the fixed rotating rod 35, the second driving rod 36 is inserted into one end inside the stacking device main body 1 and is fixedly connected with a clamping plate 37, a ball 38 is installed inside the clamping plate 37, the feeding port 31 is inclined, the feeding port 31 is arranged to be an inclined surface, when a bed stone is placed inside the feeding port 31, the bed stone can slide into the rotating roller 33, the second driving rod 36 is arranged to be L-shaped, when the second driving rod 36 moves, the clamping plate 37 is pushed to move, and two ends of the second driving rod 36 are fixedly connected with the clamping plate 37, so that the stability of the clamping plate 37 when the moving can be improved;

furthermore, the first driving block 25 is rectangular, a circular through hole is formed in the first driving block 25, the first driving rod 26 is cylindrical, the size of the inner wall of the circular through hole formed in the first driving block 25 is matched with the surface size of the first driving rod 26, and the first driving rod 26 can move in the first driving block 25 in a telescopic manner when the fixed rotating shaft 24 drives the first driving block 25 to rotate through the circular through hole formed in the first driving block 25, so that the first driving rod 26 can drive the second driving block 29 to move;

furthermore, the second driving block 29 is rectangular, a circular through hole is formed in the second driving block 29, the connecting rod 210 is cylindrical, the size of the inner wall of the circular through hole formed in the second driving block 29 is matched with the size of the surface of the connecting rod 210, and the second driving block 29 can move on the surface of the connecting rod 210 through the circular through hole formed in the second driving block 29, so that the second driving block 29 can drive the connecting rod 210 to move in the stacking device main body 1;

further, the third driving block 211 is cylindrical, a circular through hole is formed in the third driving block 211, the first guide post 212 is cylindrical, the third driving block 211 and the first guide post 212 are connected in a sliding manner, and the third driving block 211 is driven to move on the surface of the first guide post 212 when the connecting rod 210 is driven to move through the circular through hole formed in the third driving block 211, so that the first moving block 214 can be driven to move in the partition 218;

further, the first moving block 214 is rectangular, a groove is formed in the first moving block 214, the second moving block 216 is rectangular, an inclined surface is formed on the surface of the second moving block 216, the first moving block 214 and the second moving block 216 are connected in a sliding mode, and the inclined surface formed on the surface of the second moving block 216 enables the second moving block 216 to be subjected to extrusion force when the inclined surface is abutted against the surface of the foundation stone, so that the second moving block 216 can be contracted into the first moving block 214, and the foundation stone on the surface of the partition plate 218 can be pushed out of the interior of the stacking device main body 1 by the second moving block 216;

furthermore, partition plate 218 is rectangular, a sliding groove is formed in partition plate 218, second sliding blocks 217 are rectangular, two groups of second sliding blocks 217 are symmetrically arranged on the surface of first moving block 214, two groups of second sliding blocks 217 are in sliding connection with partition plate 218, and sliding grooves are formed in partition plate 218, so that when first moving block 214 moves, two groups of second sliding blocks 217 are driven to move in the sliding groove formed in partition plate 218, and the function of limiting first moving block 214 is achieved;

furthermore, a sliding groove is formed in the stacking bin 41, two groups of connecting blocks 42 are symmetrically arranged on the surface of the limiting plate 43, the two groups of connecting blocks 42 are both rectangular, the stacking bin 41 and the two groups of connecting blocks 42 form a sliding connection, and the two groups of connecting blocks 42 can be inserted into the sliding groove formed in the stacking bin 41 through the sliding groove formed in the stacking bin 41, so that the limiting plate 43 can be conveniently detached and installed;

furthermore, a sliding groove is formed in the inner wall of the stacking bin 41, the third moving block 410 is rectangular, a circular through hole is formed in the third moving block 410, the stacking bin 41 and the third moving block 410 are connected in a sliding mode, the second guide column 411 is cylindrical, the size of the inner wall of the circular through hole formed in the third moving block 410 is matched with the size of the surface of the second guide column 411, the third moving block 410 can be driven to slide in the sliding groove formed in the inner wall of the stacking bin 41 when the placing plate 47 moves through the sliding groove formed in the inner wall of the stacking bin 41, the effect of limiting the placing plate 47 can be achieved, meanwhile, when the third moving block 410 moves, the third moving block 410 can slide on the surface of the second guide column 411 through the circular through hole formed in the third moving block 410, and the effect of supporting the fourth spring 412 can be achieved through the second guide column 411;

furthermore, the limiting rod 45 is rectangular, the surface of the limiting rod 45 is an inclined plane, through holes are formed in one side, away from the stacking device main body 1, of the collecting frame 49 at equal intervals, the size of the surface of the limiting rod 45 is matched with the size of the inner wall of the through hole formed in one side of the collecting frame 49 at equal intervals, and the limiting rod 45 can be inserted into the through holes through the through holes formed in one side of the collecting frame 49 to limit the collecting frame 49;

the working principle is as follows: when the foundation stone needs to be piled up, according to the attached drawings 1, 2, 3, 4, 7 and 8, the foundation stone can be placed in the feeding port 31 to slide into the rotating roller 33, at this time, the rotating roller 33 can rotate in the feeding port 31 by the self-gravity of the foundation stone, the foundation stone can fall on the surface of the partition plate 218 by the rotating roller 33, at this time, the fixed rotating rod 35 can drive the second driving rod 36 to move by rotating the fixed rotating rod 35, the two groups of clamping plates 37 can be driven to approach each other by the second driving rod 36, so that the foundation stone can be conveniently limited, at this time, the fixed rotating shaft 24 can be driven to rotate by the motor 23, when the fixed rotating shaft 24 rotates, the first driving block 25 can be driven to rotate by the first driving block 25, and when the first driving rod 26 rotates, the second driving block 29 can be driven to rotate by the hinged block 28, at this time, the hinge block 28 can drive the second driving block 29 to move up and down on the surface of the connecting rod 210 by the first driving rod 26 extending and contracting inside the first driving block 25, the second driving block 29 can drive the connecting rod 210 to move inside the stacking apparatus main body 1, when the connecting rod 210 moves, the third driving block 211 can be driven to slide on the surface of the first guide column 212, the first moving block 214 can be driven to move by the movement of the third driving block 211, when the first moving block 214 moves, the second sliding block 217 can be driven to move inside the partition plate 218, at this time, the second moving block 216 is driven to move by the first moving block 214, the bed stone on the surface of the partition plate 218 can be pushed out of the inside of the stacking apparatus main body 1, when the second moving block 216 moves back and forth, the slope on the surface of the second moving block 216 is abutted against the surface of the bed stone, second moving block 216 can be retracted into first moving block 214, so that second moving block 216 can be facilitated to push the foundation stone to move;

when the base stones move out of the stacking device body 1, according to fig. 1, fig. 2, fig. 3, fig. 5 and fig. 6, when the base stones move into the collecting frame 49, the base stones can be made to abut against the surface of the limiting rod 45 through mutual extrusion between the base stones, at this time, the limiting rod 45 can be made to draw out the inside of the limiting rod 45, when the inclined surfaces arranged on the surface of the limiting rod 45 abut against the through holes arranged inside the collecting frame 49, the limiting rod 45 can be made to move out of the inside of the collecting frame 49, so that the collecting frame 49 can drive the placing plate 47 to move inside the stacking bin 41, when the placing plate 47 moves, the third moving block 410 can be driven to move on the surface of the second guide column 411, and the hinged rod 46 can be made to fold and shrink, at this time, the effect of buffering the falling speed can be achieved through the self elastic force of the fourth spring 412, when the collecting frame 49 falls, the through holes arranged inside are at the same level as the limiting rod 45, through the self elastic force of the third spring 44, so that the collecting frame 49 can be inserted into the stacking device body 49, when the collecting frame 49 falls, the collecting roller 33 is made to be made to enter into the horizontal entrance of the stacking device, and the stacking roller 33, when the stacking device is made to make the stacking roller 33, and the stacking device body 33, when the stacking device body 33 is made to be convenient for stacking device.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. A bridge construction is with foundation stone pile device that has skew limiting mechanism, includes pile device main part (1), its characterized in that: the inner part of the stacking device main body (1) is provided with a pushing mechanism (2), the pushing mechanism (2) comprises a supporting rod (21), the inner wall fixedly connected with supporting rod (21) of the stacking device main body (1) is provided with a supporting rod (21), the supporting rod (21) is far away from a fixed frame (22) fixedly connected with one end of the inner wall of the stacking device main body (1), a motor (23) is arranged inside the fixed frame (22), the output end of the motor (23) is connected with a fixed rotating shaft (24), the fixed rotating shaft (24) is far away from a first driving block (25) fixedly connected with one end of the motor (23), the inside of the first driving block (25) is inserted with a first driving rod (26), the side of the first driving block (25) is welded with a first spring (27), the hinged end of the first driving block (27) is welded with a hinged block (28) at one end of the first spring (27) is hinged with a second driving block (29), the inside of the second driving block (29) is sleeved with a connecting rod (210), the top end of the connecting rod (210) is fixedly welded with a third driving block (212), and a guide post (211) is sleeved with a third driving block (213), and two guide post (213) is sleeved on the inner side of the first driving block (211), a first moving block (214) is fixedly connected to the surface of the third driving block (211), a first sliding block (215) is inserted into the first moving block (214), a second moving block (216) is fixedly connected to one end, far away from the first moving block (214), of the first sliding block (215), a second spring (219) is welded to one end, close to the first sliding block (215), of the second moving block (216), a second sliding block (217) is fixedly connected to the surface of the first moving block (214), one end, far away from the first moving block (214), of the second sliding block (217) is inserted into the partition plate (218), a limiting mechanism (3) is arranged at the top end of the stacking device body (1), a stacking mechanism (4) is arranged on the side face of the stacking device body (1), the stacking mechanism (4) comprises a stacking bin (41), a stacking bin (41) is fixedly connected to the right side surface of the stacking device body (1), a connecting block (42) is inserted into the side face of the stacking device body (41), one end, far away from the fixed stacking bin (43), a third spring (43) is welded to the inner wall (46) of the limiting rod (44), and a third spring (46) is welded to the limiting rod (43), and articulated pole (46) keep away from the one end fixedly connected with of sign indicating number pile storehouse (41) place board (47), place board (47) and keep away from one end fixedly connected with stopper (48) of articulated pole (46), and stopper (48) insert and establish the inside of collecting frame (49), place both sides fixedly connected with third movable block (410) of board (47), and the inside of third movable block (410) is inserted and is equipped with second guide post (411), the skin weld of second guide post (411) has fourth spring (412), stop gear (3) include pan feeding mouth (31), pan feeding mouth (31) are installed on the top of sign indicating number pile device main part (1), and the inside of pan feeding mouth (31) installs through the bearing and move pole (32), and the surface cover of live-roll (33) has cup jointed balancing weight (34), and the inner wall fixedly connected with balancing weight (34) of balancing weight (34), the surface of sign indicating number pile device main part (1) has fixed rotating rod (35) through the bearing installation, and the surface cover of fixed rotating rod (35) is equipped with second and moves pole (36), the splint (37) are inserted and are connected with the inside of the splint (37) of the fixed splint (37).

2. The device for stacking bedrock with an offset limiting mechanism for bridge construction according to claim 1, wherein: the first driving block (25) is rectangular, a circular through hole is formed in the first driving block (25), the first driving rod (26) is cylindrical, and the size of the inner wall of the circular through hole formed in the first driving block (25) is matched with the surface size of the first driving rod (26).

3. The apparatus of claim 1, wherein the foundation stone pile device with the offset limiting mechanism for bridge construction comprises: the second driving block (29) is rectangular, a circular through hole is formed in the second driving block (29), the connecting rod (210) is cylindrical, and the size of the inner wall of the circular through hole formed in the second driving block (29) is matched with the surface size of the connecting rod (210).

4. The apparatus of claim 1, wherein the foundation stone pile device with the offset limiting mechanism for bridge construction comprises: the third driving block (211) is cylindrical, a circular through hole is formed in the third driving block (211), the first guide column (212) is cylindrical, and the third driving block (211) is connected with the first guide column (212) in a sliding mode.

5. The apparatus of claim 1, wherein the foundation stone pile device with the offset limiting mechanism for bridge construction comprises: the first moving block (214) is rectangular, a groove is formed in the first moving block (214), the second moving block (216) is rectangular, an inclined plane is formed in the surface of the second moving block (216), and the first moving block (214) and the second moving block (216) are connected in a sliding mode.

6. The device for stacking bedrock with an offset limiting mechanism for bridge construction according to claim 1, wherein: the partition plate (218) is rectangular, a sliding groove is formed in the partition plate (218), the second sliding blocks (217) are rectangular, two groups of the second sliding blocks (217) are symmetrically arranged on the surface of the first moving block (214), and the two groups of the second sliding blocks (217) are in sliding connection with the partition plate (218).

7. The apparatus of claim 1, wherein the foundation stone pile device with the offset limiting mechanism for bridge construction comprises: the inside in pile storehouse (41) has been seted up the spout, the surface symmetry of limiting plate (43) is provided with two sets of connecting block (42), and two sets of connecting block (42) all set up to the rectangle, sliding connection is constituteed with two sets of connecting block (42) in pile storehouse (41).

8. The device for stacking bedrock with an offset limiting mechanism for bridge construction according to claim 1, wherein: the inner wall of the stacking bin (41) is provided with a sliding groove, the third moving block (410) is arranged to be rectangular, a circular through hole is formed in the third moving block (410), the stacking bin (41) and the third moving block (410) are connected in a sliding mode, the second guide column (411) is arranged to be cylindrical, and the size of the inner wall of the circular through hole formed in the third moving block (410) is matched with the surface size of the second guide column (411).

9. The device for stacking bedrock with an offset limiting mechanism for bridge construction according to claim 1, wherein: the limiting rod (45) is arranged to be rectangular, the surface of the limiting rod (45) is arranged to be an inclined plane, through holes are formed in one side, away from the stacking device body (1), of the collecting frame (49) at equal intervals, and the surface size of the limiting rod (45) is matched with the size of the inner wall of the through hole formed in one side of the collecting frame (49) at equal intervals.