CN111535183B - Bridge pile foundation construction equipment of water conservancy construction environmental protection - Google Patents

Abstract

The invention discloses a water conservancy construction environment-friendly bridge pile foundation construction device, which comprises steel pipe piles distributed in a matrix, wherein a flat union pipe is welded on the outer wall between the adjacent steel pipe piles and used for enhancing the overall firmness between the steel pipe piles, the steel pipe piles and the flat union pipe are buried beside a constructed foundation, the top ends of the steel pipe piles extend out of the foundation, an attached sleeve frame is nested at the top ends of the steel pipe piles, and a plurality of sleeve frames are welded with the lower surface of a main beam, so that the water conservancy construction environment-friendly bridge pile foundation construction device has the beneficial effects that: utilize the vibratory hammer to execute the vibrations to the top of tube, with muddy water extrusion inflow escape orifice, the side discharge from the tube through the export, at the in-process of pouring, utilize the setting of conducting hole, fill up the tube with the concrete in, and the tamping that constantly sinks, utilize simultaneously in the muddy water entering tube of the isolated its bottom of closing cap board, utilize escape orifice and export cooperation rivers to carry out the mud drainage, reduce the work load of mud extraction, the completion time of engineering with higher speed, need use the problem of a large amount of energy extraction muddy water undoubtedly.

Description

Bridge pile foundation construction equipment of water conservancy construction environmental protection

Technical Field

The invention relates to the field of bridge pile foundation construction, in particular to a water conservancy construction environment-friendly bridge pile foundation construction device.

Background

The low pile foundation is a deep foundation consisting of piles and pile bearing platforms (bearing platforms for short) connected with the pile tops or a single pile foundation connected with the piles by the piles and the pile foundation, namely a pile foundation for short, and if the pile bodies are completely buried in the soil and the bottom surfaces of the bearing platforms are contacted with the soil body, the low pile foundation is called as a low pile foundation; when the upper part of the pile body is exposed out of the ground and the bottom of the pile cap is positioned above the ground, the pile body is called a high pile cap pile foundation. Building pile foundations are generally low-cap pile foundations, and in high-rise buildings, pile foundations are widely applied, and similarly, in the erection of bridges, the pile foundations are often required to be used for supporting.

The pile foundation is widely applied to each construction structure in the current building engineering construction, and in the modern building engineering construction, the pile foundation is adopted, so that the construction period is saved, the construction quality of the building engineering can be ensured, and good economic benefit and social benefit can be obtained in the construction process. Along with the continuous development of current social technical measures and social systems, the types of piles, the pile foundation forms, construction processes and equipment, the pile foundations and related methods are gradually developed along with the development of current social science and technology, and the pile foundation type, the pile foundation construction process, the pile foundation construction equipment, the pile foundation type, the construction process, the construction equipment, the pile foundation foundations and the related methods are the main forms for improving foundations in various poor soil qualities and regions, and the main foundation treatment requirements in the construction of high-rise buildings and large buildings.

Present bridge pile foundation is built and is exactly utilizing equipment cooperation to protect a section of thick bamboo extraction mud, then utilize concrete placement's process, the mud of taking out need just can discharge through handling, the polluted environment that the rubbish that various during operation produced can be serious simultaneously, need use a large amount of energy undoubtedly in the processing, such pile driving mode is slow at some rivers, when the water layer is more shallow and build the bridge in the river of surface of water broad, will appear serious energy waste, can not respond the number of national energy-concerving and environment-protective.

An effective solution to the problems in the related art has not been proposed yet.

Disclosure of Invention

Aiming at the problems in the related art, the invention provides a water conservancy construction environment-friendly bridge pile foundation construction device, which aims to overcome the technical problems in the prior related art.

The technical scheme of the invention is realized as follows:

the utility model provides a bridge pile foundation construction equipment of water conservancy construction environmental protection, is matrix distribution's steel-pipe pile 1, outside the top of steel-pipe pile 1 extended to the ground to there is adnexed stock 3 on its top nestification, the lower surface of a plurality of stocks 3 and girder 4 welds mutually, four end foot departments of the up end of girder 4 weld vertical ascending base 5, be tying on the tower crane 61 of installation on the base 5 and pour into concrete pipe 7.

Further, a flat connecting pipe 2 is welded on the outer wall between the adjacent steel pipe piles 1 and is used for enhancing the overall firmness of the steel pipe piles 1, the steel pipe piles 1 and the flat connecting pipe 2 are buried beside a constructed foundation, the outer walls of the two symmetrical sleeve frames 3 are respectively movably connected with an inner support 31 and an outer support 32 through pin shafts, and the other end ports of the inner support 31 and the outer support 32 are meshed on the pier cap 10 through penetrating bolts;

reinforcing plates 51 connected with the main beam 4 are welded on four side walls of the base 5, a plurality of tower crane bases 52 accumulated with each other are fixed at the top end of the base 5, a rotary table 6 for rotation is installed at the top of each tower crane base 52, tower cranes 61 extending from two ends are fixed on each rotary table 6, a balancing weight 611 is fixed at one end of each tower crane 61 through a bolt, a displacement sleeve 612 sliding back and forth is installed at the other end of each tower crane 61, and a concrete pouring guide pipe 7 is tied on a rope for up-down extension in the displacement sleeve 612;

the concrete-pouring guide pipe 7 comprises a steel bar 71, partition plates 72, a cover plate 73 and a pipe shell 74, wherein the steel bar 71 is inserted along the axis of the pipe shell 74 and is encircled into a ring structure, a plurality of partition plates 72 are fixed on the inner wall of the pipe shell 74 and divide the inner cavity of the pipe shell 74 to form a plurality of spaces which are distributed up and down, a plurality of through holes 721 are all processed on the partition plates 72 in a surrounding manner, and the plurality of spaces inside the pipe shell 74 are mutually communicated through the through holes 721;

the cover plate 73 is fixed on the inner wall near the end of the pipe shell 74 and seals the lower end opening of the pipe shell 74, a plurality of drain holes 8 are processed on the inner wall of the pipe shell 74 below the cover plate 73 at equal intervals, and the drain holes 8 are processed on the pipe shell 74 above the cover plate 73 along the axial direction of the pipe shell 74 and communicated with the outlet 9.

Furthermore, the number of the drain holes and the number of the outlets correspond to each other, and a channel formed by the drain holes and the outlets is located between the adjacent reinforcing steel bars.

Further, the pipe shell at one end of the cover plate is inserted in alignment with the dug pile position and is always kept in a vertical state during insertion.

Furthermore, the steel pipe piles are distributed in a 3-by-3 matrix, and the cross sections of the parallel connecting pipes and the steel pipe piles form a 'field' -shaped component.

Further, the pulleys connected to the displacement sleeve 612 are clamped on the tower crane 61 and move on the tower crane 61.

Further, the pier cap 10 fixed by the inner brace 31 and the outer brace 32 is horizontally flush with the bridge pile foundation.

The invention provides another technical method, in particular to a method for constructing an environment-friendly bridge pile foundation construction device through water conservancy, which comprises the following steps:

s1: firstly, mounting a pier bearing platform beside a bridge pile foundation, digging a foundation pit for accommodating a steel pipe pile and a horizontal coupling pipe beside the pier bearing platform, inserting the steel pipe pile into the foundation pit, filling soil and tamping;

s2: the sleeve frame and the main beam are welded on the protruded top end of the steel pipe pile, the bolt penetrates through two ends of the inner support and the outer support, and the inner support and the outer support are fixed with the sleeve frame and the pier cap respectively after the angle of the inner support and the angle of the outer support are adjusted through the bolt;

s3: the tower crane bases are mutually accumulated and then fixed on the bases, and pile positions for placing concrete pouring guide pipes are dug out;

s4: hoisting the concrete pouring guide pipe to the position right above the pile position by using a tower crane to ensure that the concrete pouring guide pipe is vertical, downwards arranging one end of the sealing cover plate, slowly and vertically sinking the pipe shell until the pipe shell is stably filled with the mud, and then, positioning the upper end of the pipe shell above the water surface;

s5: vibrating the top end of the pipe shell by using a vibration hammer, and sinking the pipe shell to the designed depth in the descending process;

s6: pour the concrete in the opening more than the tube surface of water, utilize the setting of conducting hole, fill up the tube with the concrete in, reuse the vibration hammer and execute the vibrations to the tube, the concrete constantly sinks at the in-process of vibrations and tamps, fills up the tube and accomplishes the construction.

Further, for S5, the drain hole and the capping plate sink slowly into the mud during constant vibration, the capping plate blocks mud water from entering the pipe case, and presses the mud water into the drain hole, and the mud water is discharged from the side of the pipe case through the outlet.

The invention has the beneficial effects that: the method comprises the steps of hoisting a concrete pouring guide pipe to be right above a pile position by using a tower crane, enabling the concrete pouring guide pipe to be vertical, enabling one end of a sealing cover plate to face downwards, enabling a pipe shell to slowly and vertically sink to be stable in mud entering, vibrating the top end of the pipe shell by using a vibration hammer, extruding and flowing mud water into a drainage hole, discharging the mud water from the side face of the pipe shell through an outlet, filling the concrete into the pipe shell by using the arrangement of the conduction hole in the pouring process, continuously sinking and tamping, isolating the mud water at the bottom of the pipe shell from the pipe shell by using the sealing cover plate, conducting sludge drainage by using the cooperation of the drainage hole and the outlet to cooperate with water flow, then extracting the sludge in the space in the descending process, reducing the workload of sludge extraction, accelerating the completion time of engineering, and undoubtedly using a large amount of energy for extracting the mud water.

Drawings

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

FIG. 1 is a front view of the whole of a water conservancy construction environment-friendly bridge pile foundation construction device according to an embodiment of the invention;

FIG. 2 is a top view of the whole of the water conservancy construction environment-friendly bridge pile foundation construction device according to the embodiment of the invention;

FIG. 3 is a schematic structural diagram of the upper end of a concrete pouring guide pipe in the water conservancy construction environment-friendly bridge pile foundation construction device according to the embodiment of the invention;

FIG. 4 is a schematic structural diagram of the lower end of a concrete pouring guide pipe in the water conservancy construction environment-friendly bridge pile foundation construction device according to the embodiment of the invention;

FIG. 5 is a schematic structural diagram of a partition plate in the water conservancy construction environment-friendly bridge pile foundation construction device according to the embodiment of the invention;

FIG. 6 is a schematic diagram of an internal structure of a concrete pouring guide pipe in the water conservancy construction environment-friendly bridge pile foundation construction device according to the embodiment of the invention;

FIG. 7 is a schematic diagram of bridge laying in the water conservancy construction environment-friendly bridge pile foundation construction device according to the embodiment of the invention;

fig. 8 is a schematic side view of bridge laying in the water conservancy construction environment-friendly bridge pile foundation construction device according to the embodiment of the invention.

In the figure:

1. steel pipe piles; 2. parallel connection pipes; 3. sleeving a frame; 31. internal bracing; 32. externally supporting; 4. a main beam; 5. a base; 51. a reinforcing plate; 52. a tower crane base; 6. a turntable; 61. tower crane; 611. a balancing weight; 612. a displacement sleeve; 7. pouring a concrete guide pipe; 71. reinforcing steel bars; 72. a partition plate; 721. a via hole; 73. sealing the cover plate; 74. a pipe shell; 8. a drain hole; 9. an outlet; 10. a pier cap.

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 that can be derived by one of ordinary skill in the art from the embodiments given herein are intended to be within the scope of the present invention.

The first embodiment is as follows:

according to the embodiment of the invention, the invention provides the water conservancy construction environment-friendly bridge pile foundation construction device.

As shown in fig. 1-2, a water conservancy construction environment-friendly bridge pile foundation construction device comprises steel pipe piles 1 distributed in a matrix, parallel pipes 2 welded on the outer walls between adjacent steel pipe piles 1 for enhancing the overall firmness between the steel pipe piles 1, the steel pipe piles 1 distributed in a 3 x 3 matrix, the parallel pipes 2 and the cross sections of the steel pipe piles 1 form a member shaped like a Chinese character 'tian', the structure shaped like a Chinese character 'tian' has stronger horizontal supporting force, a plurality of rows of parallel pipes 2 generate the same supporting force on the steel pipe piles 1 from top to bottom, the lateral pressure borne by the steel pipe piles 1 is the same to prevent the steel pipe piles 1 from deforming, the steel pipe piles 1 and the parallel pipes 2 are buried beside a constructed foundation, the top ends of the steel pipe piles 1 extend out of the foundation, and are nested with attached sleeves 3 on the top ends, the sleeves 3 are arranged around the steel pipe piles 1, the sleeves 3 are welded with the lower surfaces of main beams 4 in a spot welding and rivet welding combined mode, welding and fixing the inner support and the outer support are completed, wherein the outer walls of the two symmetrical sleeve frames 3 are respectively movably connected with the inner support 31 and the outer support 32 through pin shafts, the inner support 31 and the outer support 32 complete rotation by taking the outer wall of the sleeve frame 3 as a center, a plurality of angles can be adjusted, and the ports at the other ends of the inner support 31 and the outer support 32 are meshed on the pier bearing platform 10 through penetrating bolts; the four end feet of the upper end face of the main beam 4 are welded with vertical upward bases 5, four side walls of each base 5 are welded with reinforcing plates 51 connected with the main beam 4, the reinforcing plates 51 are arranged to improve the firmness of connection between the bases 5 and the main beam 4, a plurality of tower crane bases 52 accumulated with each other are fixed at the top end of each base 5, a rotating disc 6 used for rotation is installed at the top of each tower crane base 52, the rotating disc 6 is installed on each tower crane base 52, a tower crane 61 extending from two ends is fixed on each rotating disc 6, the tower crane 61 rotates on each rotating disc 6, one end of each tower crane 61 is fixed with a balancing weight 611 through a bolt, the balancing weight 611 is arranged to complete balance, a displacement sleeve 612 sliding back and forth is installed at the other end of each tower crane 61, one back and forth end of each displacement sleeve 612 is tied to a concrete filling conduit 7 on a rope used for up-down stretching in each displacement sleeve 612, the upper end and the lower end of each concrete filling conduit 7 are controlled by each tower crane 61, and the lifting of the concrete filling conduit 7 is completed, And (4) replacing the position and hanging down.

As shown in fig. 3-5, the concrete-pouring duct 7 includes a steel bar 71, a partition plate 72, a cover plate 73 and a pipe shell 74, the steel bar 71 is inserted along the axis of the pipe shell 74 and is wound into a circle, the partition plates 72 are fixed on the inner wall of the pipe shell 74 and partition the inner cavity of the pipe shell 74 to form a plurality of spaces distributed up and down, a plurality of through holes 721 are formed around the partition plates 72, the cross section of each through hole 721 is trapezoidal, the through hole 721 is larger in diameter and is upward, the through hole is smaller in diameter and is downward, so that concrete can conveniently flow into the inner cavity of the pipe shell 74 in the next layer, the pipe shell 74 makes the plurality of spaces inside the pipe shell mutually communicated through the through hole 721 to perform independent partition and improve the radial supporting force of the pipe shell.

As shown in fig. 6, the cover plate 73 is fixed on the inner wall near the end of the pipe shell 74, the pipe shell 74 at one end of the cover plate 73 is inserted in alignment with the dug pile position and always kept in a vertical state when being inserted, the pipe shell 74 is vertically just aligned with the pile opening and can be inserted, the lower end opening of the pipe shell 74 is sealed, a plurality of drain holes 8 are formed in the inner wall of the pipe shell 74 below the cover plate 73 at equal intervals, the drain holes 8 are formed in the pipe shell 74 above the cover plate 73 along the axial direction of the pipe shell 74 and are communicated with outlets 9, the number of the drain holes 8 corresponds to that of the outlets 9 one by one, the channel formed by the drain holes 8 and the outlets 9 is located between adjacent reinforcing steel bars 71, the channel formed by the drain holes 8 and the outlets 9 cannot be communicated with the reinforcing steel bars 71, moisture cannot enter the reinforcing steel bars 71, and the rusting and damage speed of the pipe shell is prevented from being increased.

The invention provides another technical method, in particular to a method for constructing an environment-friendly bridge pile foundation construction device through water conservancy, which comprises the following steps:

the method comprises the following steps: firstly, mounting a pier bearing platform 10 beside a bridge pile foundation, digging a foundation pit for accommodating a steel pipe pile 1 and a connecting pipe 2 beside the pier bearing platform 10, inserting the steel pipe pile 1 into the foundation pit, filling soil and tamping;

step two: the sleeve frame 3 and the main beam 4 are welded on the protruded top end of the steel pipe pile 1, the bolt penetrates through two ends of the inner support 31 and the outer support 32, and the inner support 31 and the outer support 32 are fixed with the sleeve frame 3 and the pier platform 10 respectively after the angle is adjusted through the bolt;

step three: the tower crane bases 52 are mutually accumulated and then fixed on the base 5, and a pile position for placing the concrete pouring guide pipe 7 is dug out;

step four: hoisting the concrete pouring guide pipe 7 to the position right above the pile position by using a tower crane 61 to ensure that the concrete pouring guide pipe 7 is vertical, downwards facing one end of a sealing cover plate 73, slowly and vertically sinking the pipe shell 74 until the pipe shell is stably filled with the mud, and at the moment, the upper end of the pipe shell 74 is positioned above the water surface;

step five: vibrating the top end of the pipe shell 74 by using a vibration hammer, slowly sinking the drain hole 8 and the cover plate 73 to be embedded into mud in the continuous vibration process in the descending process, blocking mud water from entering the pipe shell 74 by the cover plate 73, extruding the mud water to flow into the drain hole 8, and discharging the mud water from the side surface of the pipe shell 74 through the outlet 9 to enable the pipe shell 74 to sink to the designed depth;

step six: concrete is poured into the opening above the water surface of the pipe shell 74, the pipe shell 74 is filled with the concrete by the arrangement of the through hole 721, the vibration hammer is used again to vibrate the pipe shell 74, the concrete sinks continuously and is tamped in the vibration process, and the pipe shell 74 is filled to complete construction.

Through the scheme of the invention, the hoisting, position replacement and hoisting of the concrete-filled conduit 7 can be completed by rotating the tower crane 61 on the rotary table 6, the concrete-filled conduit 7 is hoisted to be right above the pile position by the tower crane 61 to be vertical, one end of the sealing cover plate 73 faces downwards, the pipe shell 74 slowly and vertically sinks until the mud is stably filled, the top end of the pipe shell 74 is vibrated by the vibration hammer, the mud water is extruded and flows into the drainage hole 8 and is discharged from the side surface of the pipe shell 74 through the outlet 9, the pipe shell 74 is vibrated by the vibration hammer, the concrete continuously sinks and tamps in the vibrating process, the pipe shell 74 is filled up to complete construction, the concrete can be filled in the pipe shell 74 by the arrangement of the conducting hole 721 and tamps continuously, meanwhile, the mud water at the bottom of the pipe shell is isolated by the sealing cover plate 73 to enter the pipe shell 74, and the drainage of the mud is performed by the cooperation of the drainage hole 8 and the outlet 9, then the sludge in the space in the descending process is extracted, the workload of sludge extraction is reduced, the completion time of the project is accelerated, and a large amount of energy is undoubtedly needed to extract muddy water.

Example two:

as shown in fig. 7-8, in the first embodiment, after the concrete-pouring conduits 7 are embedded into the fabricated foundation pit, a bridge is laid on the concrete-pouring conduits 7, the elevation of the top ends of the concrete-pouring conduits 7 is measured, the deviation generated by each concrete-pouring conduit 7 is adjusted in time, the bearing platform is fixed on the centers of the pile foundations and the upright posts, and the middle pier and the first pier are poured; the bridge is characterized in that a plurality of middle bridge piers and end bridge piers at two sides are connected to form a bridge support higher than a ground line, an anti-seismic stop block is fixed above the end bridge piers of the cross beams, a support is fixed above the middle bridge pier of the cross beams, a wedge-shaped groove in the bridge floor is inserted into the support, and the support is connected and fixed with the erected bridge floor by using a bolt; the arch feet are assembled on the bridge floor in sections to connect the arch ribs into an arch, an arc arch bridge is designed, the length of the lower chord line is consistent with the distance between the arch feet, the height of the arch ribs is consistent with the height of a steel structure building, part of the thickness of the upper surface layer of the bridge floor is planed, then floating dust impurities on the surface of the road surface are removed, and open-graded asphalt mixture is laid.

The bridge floor adopts steel and concrete combination roof beam, solves traditional concrete bridge floor and has had from great, the tired key technical problem such as outstanding of steel bridge floor, and the structure setting of pouring into concrete pipe 7 improves bridge structures security and durability, improves lower part foundation bearing capacity, improves bridge security and life.

In conclusion, by means of the technical scheme of the invention, the concrete pouring guide pipe 7 is lifted to the position right above the pile by the tower crane 61, so that the concrete pouring guide pipe 7 is vertical, one end of the sealing cover plate 73 faces downwards, the pipe shell 74 slowly and vertically sinks until the mud is stably filled, the top end of the pipe shell 74 is vibrated by a vibration hammer, the mud is extruded and flows into the discharge hole 8 and is discharged from the side surface of the pipe shell 74 through the outlet 9, in the process of pouring, the tube shell 74 is filled with concrete by the arrangement of the through hole 721, and is continuously sunk and compacted, meanwhile, the sealing cover plate 73 is used for preventing muddy water at the bottom of the sealing cover plate from entering the pipe shell 74, the drainage hole 8 and the outlet 9 are used for matching with water flow to conduct sludge drainage, then the sludge in the space in the descending process is extracted, the workload of sludge extraction is reduced, the completion time of the project is accelerated, and a large amount of energy is undoubtedly needed to extract muddy water.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (4)

1. The utility model provides a bridge pile foundation construction equipment of water conservancy construction environmental protection which characterized in that: the steel pipe pile foundation comprises steel pipe piles (1) distributed in a matrix, wherein the top ends of the steel pipe piles (1) extend out of a foundation, and are nested with attached sleeve frames (3), a plurality of sleeve frames (3) are welded with the lower surface of a main beam (4), four end feet of the upper end surface of the main beam (4) are welded with vertically upward bases (5), and concrete pouring guide pipes (7) are tied on tower cranes (61) installed on the bases (5); the outer wall between the adjacent steel pipe piles (1) is welded with a flat connecting pipe (2) for enhancing the overall firmness between the steel pipe piles (1), the steel pipe piles (1) and the flat connecting pipe (2) are buried beside a constructed foundation, wherein the outer walls of the two symmetrical sleeve frames (3) are movably connected with an inner support (31) and an outer support (32) through pin shafts respectively, and the other end ports of the inner support (31) and the outer support (32) are meshed on a pier bearing platform (10) through penetrating bolts;

reinforcing plates (51) connected with the main beam (4) are welded on four side walls of the base (5), a plurality of tower crane bases (52) accumulated with each other are fixed at the top end of the base (5), a rotating disc (6) used for rotating is installed at the top of each tower crane base (52), a tower crane (61) with two extending ends is fixed on each rotating disc (6), a balancing weight (611) is fixed at one end of each tower crane (61) through a bolt, a displacement sleeve (612) capable of sliding back and forth is installed at the other end of each tower crane (61), and a concrete pouring guide pipe (7) is tied on a rope used for extending up and down in each displacement sleeve (612);

the concrete pouring guide pipe (7) comprises steel bars (71), partition plates (72), a cover plate (73) and pipe shells (74), wherein the steel bars (71) are inserted along the axis of the pipe shells (74) and are encircled into a circle of structure, a plurality of partition plates (72) are fixed on the inner walls of the pipe shells (74), a plurality of vertically distributed spaces are formed in the inner cavities of the partition plates (74), a plurality of through holes (721) are formed in the partition plates (72) in a surrounding mode, and the plurality of spaces in the pipe shells (74) are communicated with one another through the through holes (721);

the sealing cover plate (73) is fixed on the inner wall close to the port of the pipe shell (74), the lower end opening of the pipe shell (74) is sealed, a plurality of drain holes (8) are formed in the inner wall, below the sealing cover plate (73), of the pipe shell (74) at equal intervals, and an outlet (9) communicated with the drain holes (8) is formed in the pipe shell (74) above the sealing cover plate (73) along the axial direction of the pipe shell (74); the number of the drain holes (8) is one-to-one corresponding to that of the outlets (9), and a channel formed by the drain holes (8) and the outlets (9) is positioned between the adjacent reinforcing steel bars (71); the pipe shell (74) at one end of the sealing cover plate (73) is inserted in alignment with the dug pile position and is always kept in a vertical state during insertion.

2. The water conservancy construction environment-friendly bridge pile foundation construction device according to claim 1, wherein the steel pipe piles (1) are distributed in a 3 x 3 matrix, and the cross sections of the parallel pipes (2) and the steel pipe piles (1) form a member shaped like a Chinese character tian.

3. The water conservancy construction environmental protection's bridge pile foundation construction device of claim 1, characterized in that, the pulley card that connects on the displacement cover (612) is on tower crane (61) to move on tower crane (61).

4. The water conservancy construction environmental protection bridge pile foundation construction device of claim 1, characterized in that the pier cap (10) fixed by the inner support (31) and the outer support (32) is level with the bridge pile foundation.

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