KR20230001976U - Concrete pipe pile - Google Patents

Abstract

The concrete pipe pile provided according to the present application has a pile body and an antifreeze material; The pile body has a first support section, a second support section and a third support section disposed from bottom to top in the listed order and communicating internally, the first support section being in the soil below the freezing line. configured to be inserted, wherein the interior of the first support section is configured to receive soil below the frost line, and the interior of the second support section is configured to receive soil above the frost line; The anti-freeze agent is configured to cover the outer periphery of the second support section and fill the interior of the third support section. In the technical solution of the present application, corrosion of the pipe pile due to rainwater and groundwater can be reduced by filling the outer circumference of the second support section and the inside of the third support section with an anti-freeze agent. The concrete pipe pile according to the present application is not affected by frost heaving force in cold winter, protecting the safe operation of solar power projects.

Description

Concrete pipe pile {CONCRETE PIPE PILE}

This application relates to the technical field of photovoltaic power generation, especially concrete pipe piles.

The construction of solar power projects requires a large number of concrete pipe piles. The interior of each concrete pipe pile is hollow and both ends are not sealed. As shown in Figure 1, rainwater easily enters the top of the existing concrete pipe pile; In addition, due to pressure, after the concrete pipe pile is driven into the ground, the inside of the concrete pipe pile is filled with soil at the deep end of the soil, so that groundwater at the bottom easily flows into the concrete pipe pile; In cold winter, concrete pipe piles above the freezing line are easily affected by frost heaving, which causes cracks and corrosion of the concrete pipe piles, affecting solar power projects.

The concrete pipe pile according to the present application is provided to prevent cracking or corrosion of the concrete pipe pile due to frostbite in cold winter.

In order to realize the above purpose, the concrete pipe pile according to the present application,

A pile body comprising a first support section, a second support section and a third support section arranged in the listed order and in internal communication, wherein the first support section is inserted into the soil below the freezing line. The pile body is configured so that the interior of the first support section is configured to receive soil below the frost line, and the interior of the second support section is configured to receive soil above the frost line; and

An antifreeze material configured to cover the outer periphery of the second support section and fill the interior of the third support section.

It is provided to be equipped with.

In one embodiment, the concrete pipe pile further includes a protective plate mounted on the outside of an end of the third support section adjacent to the second support section, and the protective plate is reinforced with an anti-freeze agent covering the outer periphery of the second support section. It is configured to do so.

In one embodiment, the protection plate includes a first reinforcement plate and a second reinforcement plate, the first reinforcement plate and the second reinforcement plate being detachably connected and spliced on the outside of the third support section. ) and is installed.

In one embodiment, the concrete pipe pile further includes a pile plug, the pile plug being disposed at an end of the third support section away from the second support section, the pile plug being disposed at an end of the third support section away from the second support section. 3 It is configured to plug the support section.

In one embodiment, the concrete pipe pile is configured to fill the outer circumference of the second support section with the anti-freeze agent, and/or a filling assembly configured to fill the interior of the third support section with the anti-freeze agent. assembly) is further provided.

In one embodiment, the filling assembly includes a first filling pipe configured to fill the interior of the third support section with the antifreeze agent; and/or

The filling assembly includes a second filling pipe configured to fill the outer periphery of the second support section with the antifreeze agent.

In one embodiment, the filling assembly further includes a flow control device, the flow control device being connected to the first fill pipe to control a filling rate of the first fill pipe, and/or the flow control device is connected to the second filling pipe to control the filling speed of the second filling pipe.

In one embodiment, a filling hole is formed in the pile plug, the filling hole is configured to communicate the inside of the third support section with the outside, and one end of the first filling pipe is connected to the filling hole. extends within.

In one embodiment, the first filling pipe is connected to the pile plug through a movable joint, and the movable joint is detachably connected to the first filling pipe.

In one embodiment, the cryoprotectant has a waterproof function and/or the cryoprotectant has an insulating function.

In the technical solution of the present application, corrosion of the pipe pile against rainwater and groundwater is reduced by filling the outer circumference of the second support section and the inside of the third support section with an anti-freeze agent. In order to stabilize the pile body in the soil, it is necessary to insert the pile body into the ground at a relatively deep depth. The first support section is located in soil below the frost line, and the second support section is located in soil above the frost line, and at least a portion of the interior is filled with soil above the frost line so that the soil above the frost line is It may freeze, and the frozen soil may then exert a frost heaving force on the pile body, and the second support section may crack or corrode due to the effect of the frost heaving force on the soil. In addition, because the upper end of the third support section is open, rainwater may flow into the interior of the third support section from the upper end of the third support section, and water is likely to freeze in cold winter, and condensed ice may form in the third support section. This can create in-phase forces on the third support section, causing cracks or corrosion in the third support section. By excavating a foundation pit around the second support section and filling the inside of the foundation pit with an anti-freeze agent, the second support section is prevented from cracking due to frostbite; By filling the inside of the third support section with an anti-freeze agent, the third support section is prevented from cracking or corrosion due to frostbite. The concrete pipe pile according to this application is not affected by frostbite in cold winter, protecting the safe operation of solar power projects.

In order to more clearly explain the technical solutions of the embodiments of the present application or the prior art, the drawings referred to for explaining the embodiments or the prior art will be briefly described below. Obviously, the drawings in the following description are only some examples of the present application, and those skilled in the art will be able to obtain other drawings based on the drawings provided without any creative effort.
1 is a schematic configuration diagram of a concrete pipe pile according to the prior art.
Figure 2 is a schematic structural diagram of a concrete pipe pile according to an embodiment of the present application.
Figure 3 is a schematic structural diagram of the pile plug of Figure 2.
Figure 4 is a schematic configuration diagram of the protection plate of Figure 2.
The implementation of the objectives, functional features and advantages of the present application will be further explained with reference to the drawings in relation to the embodiments.

The technical solutions according to the embodiments of the present application will be clearly and completely explained as follows in relation to the drawings of the embodiments of the present application. It is obvious that the described embodiments are only some, not all, of the embodiments according to the present application. Based on the embodiments of this application, all other embodiments obtained by a person skilled in the art without creative work fall within the protection scope of this application.

In the embodiments of the present application, all direction indicators (up, down, left, right, front, rear...) describe the relative positional relationships and movement situations between components in a specific posture (as shown in the attached drawings). It is used only for When a specific posture changes, the direction indicator changes accordingly.

In addition, if there is a description related to "first", "second", etc. in the embodiments of the present application, "first", "second", etc. are used only for the purpose of explanation and do not indicate or imply relative importance. The number of technical features indicated should not be understood as implicit. Accordingly, the features defined as “first” and “second” may explicitly or implicitly include at least one feature. In addition, the meaning of "and/or" appearing throughout this specification includes three parallel solutions, including "A and/or B" as an example, A solution, B solution, or all solutions of A and B. means that Additionally, technical solutions between various embodiments may be combined with each other, but this should be based on implementation by a person skilled in the art. If the combination of technical solutions is contradictory or unfeasible, it shall be considered that such combination of technical solutions does not exist and does not fall within the scope of protection of this application.

A concrete pipe pile 100 according to the present application is provided.

Referring to Figure 2, in one embodiment of the present application, the concrete pipe pile 100 is provided with a pile body 10 and an anti-freeze agent 30; The pile body 10 has a cylindrical tubular shape, and the pile body 10 has a first support section 11, a second support section 13 and a third support section 15 internally communicating in the listed order. The first support section 11, the second support section 13 and the third support section 15 are all cylindrical and tubular in shape. In an actual project, the first support section (11) is configured to be inserted into the soil below the frost line (L), the first support section (11) is configured to receive the soil below the frost line (L), and the second support section (11) is configured to receive the soil below the frost line (L). The interior of the support section (13) is configured to receive soil above the frost line (L); The anti-freeze agent 30 is configured to cover the outer circumference of the second support section 13 and fill the inside of the third support section 15.

The anti-freeze material 30 is a waterproof material, and/or the anti-freeze material 30 is an insulating material, and the anti-freeze material 30 may be one or more of rubber-plastic sponge insulation, polyethylene insulation, or composite silicate insulation. Rubber sponge insulation is a closed-cell elastic material that has excellent properties such as flexibility, bending resistance, cold resistance, heat resistance, flame retardancy, waterproofing, low thermal conductivity, shock absorption, and sound absorption, and is expected to provide the next generation of high quality. It is a cross-over insulation material; Polyethylene insulation is produced by a special process, and its cells have a closed cell structure, which has the characteristics of heat insulation, moisture retention, anti-condensation, anti-aging, etc., and is a high-performance energy-saving material; Composite silicate insulation is a new type of lightweight and efficient high-temperature insulation material that has the advantages of low thermal conductivity, convenient construction, no irritation, and no dust contamination.

The construction steps of the concrete pipe pile 100 are as follows:

S1: Determining the pile site at the construction site according to the design drawing;

S2: Drive the pile body (10) into the soil, insert the first support section (11) below the frost line (L) of the soil, and insert the first support section (11) into the first support section (11) according to the actual situation of the project and geological survey data. Determining the driving depth into the soil and positioning the third support section (15) above the ground (S);

S3: Excavate the foundation pit 200 around the bottom surface of the pile body 10, so that the excavation depth of the foundation pit 200 is deeper than the frost line L, and the second support section 13 is formed at the foundation pit 200. ) a step located in; and

S4: The interior of the second support section 13 is filled with the antifreeze agent 30, the foundation pit 200 is filled with the antifreeze agent 30, and the outer periphery of the second support section 13 is filled with the antifreeze agent 30. ) step of covering.

The construction sequence of steps S2 and S3 can be adjusted appropriately. Once the pile site is determined, a foundation pit 200 is excavated in the ground (S), the pile site and its surroundings are located with the pile site as an axis, and the excavation depth of the foundation pit 200 is equal to the frost line (L). deeper than; The pile body 10 is driven into the bottom surface of the lower part of the foundation pit 200 so that the first support section 11 is inserted below the foundation pit 200, and the second support section 13 is within the foundation pit 200. is positioned, a part of the third support section 15 is positioned within the foundation pit 200 and another part is positioned on the ground S above the foundation pit 200 .

The technical solution of the present application fills the outer circumference of the second support section 13 and the inside of the third support section 15 with anti-freeze agent 30 to reduce corrosion due to rainwater and groundwater on the pile body 10. . In order to stabilize the pile body 10 in the soil, it is necessary to insert the pile body 10 into the ground (S) at a relatively deep depth. The first support section (11) is located in the soil below the frost line (L), and the second support section (13) is located in the soil above the frost line (L), with at least a portion of the interior located above the frost line (L). filled with the soil above, the soil above the frost line (L) may freeze, and then the frozen soil may exert a frost force on the pile body (10), and due to the effect of the soil frostbite, the second support section. (13) may crack or corrode. In addition, because the upper end of the third support section 15 is open, rainwater can flow into the interior of the third support section 15 from the upper end of the third support section 15, so the water is likely to freeze in cold winter, Condensed ice can create frostbite forces on the third support section 15, causing the third support section 15 to break or erode. By excavating the foundation pit 200 around the second support section 13 and filling the inside of the foundation pit 200 with anti-freeze agent 30, the second support section 13 is prevented from cracking due to frostbite. ; By filling the inside of the third support section 15 with the anti-freeze agent 30, cracking or corrosion of the third support section 15 due to frostbite is prevented. The concrete pipe pile 100 according to the present application is not affected by frostbite in cold winter, thereby protecting the safe operation of the solar power generation project.

4, based on the above-described embodiment, in one embodiment, the concrete pipe pile 100 is further provided with a protective plate 50, and the shape of the protective plate 50 is the upper surface of the foundation pit 200. It is similar to the shape of the lower surface, and the area of the lower surface of the protective plate 50 is slightly larger than the upper surface area of the foundation pit 200. A through hole is formed in the center of the protective plate 50, and the through hole is formed from the upper surface of the protective plate 50. Extending to the lower surface, the pile body 10 penetrates the through hole, and the protection plate 50 is mounted on the outside of the end of the third support section 15 close to the second support section 13, and the protection plate 50 is configured to reinforce the anti-freeze material 30 covered on the outer circumference of the second support section 13. Specifically, the protective plate 50 is disposed on the lower end of the third support section 15, and the protective plate 50 is disposed on the foundation pit 300 and fixed to the ground S above the foundation pit 200. The protection plate 50 covers the foundation pit 200, and the protection plate 50 serves to reinforce and compress the antifreeze agent 30 when the antifreeze agent 30 is filled into the interior of the foundation pit 200. 2 The support section 13 can be firmly covered by the anti-freeze agent 30, and the second support section 13 can be rigidly protected so that the anti-freeze agent 30 on the second support section 13 is not rigidly covered. This prevents localized freezing cracks in the second support section 13 from occurring, or prevents defects in the anti-freezing agent 30 from occurring due to an excessively large gap between the anti-freezing agents 30.

The foundation pit 200 may be irregularly polyhedral, rectangular, tapered, or cylindrical. Preferably, the foundation pit 200 is cylindrical. Compared with the foundation pit 200 of other shapes, the cylindrical foundation pit 200 can ensure the antifreeze effect of the antifreeze material 30 constant at different heights of the second support section 13, which provides 2 Prevents a local shortage of anti-freeze agent in the support section 13 or prevents insufficient utilization of the internal space of the foundation pit 200. The rectangular foundation pit 200 and the tapered foundation pit 200 will be described in detail. First, assuming that the minimum thickness of the anti-freeze material 30 covered on the outer periphery of the second support section 13 is d , the distance from the side wall of the foundation pit 200 to the second support section 13 is at least d ; When the foundation pit 200 is a rectangular foundation pit 200, the distance between the side wall of a part of the foundation pit 200 and the second support section 13 cannot be kept constant at the same height. If the distance between the middle part of the side wall of the foundation pit 200 and the second support section 13 is the minimum distance, and the minimum distance is d , then the edge of the side wall of the foundation pit 200 and the second support section 13 The distance between the sections 13 should be greater than d , that is, the anti-freeze agent 30 on the side wall of the foundation pit 200 and close to the edge of the foundation pit 200 has no substantial anti-freeze effect; When the foundation pit 200 is tapered at different heights, the distance from the inner wall of the foundation pit 200 on the same bus to the second support section 13 is different, and from the inner wall at the upper end of the foundation pit to the second support section ( 13), if the distance from the inner wall at the lower end of the foundation pit 200 to the second support section 13 is the minimum distance and the minimum distance is d , it must be greater than d , and at the upper end of the foundation pit 200 and the anti-freeze agent 30 close to the side wall of the foundation pit 200 has no substantial anti-freeze effect. The above two cases cause waste of antifreeze agent 30, and excavation of a larger volume foundation pit 200 also causes waste of manpower and increases the construction period.

In addition, the protection plate 50 is provided with a first reinforcement plate 51 and a second reinforcement plate 53, and the first reinforcement plate 51 has a through hole extending from the upper surface to the lower surface of the first reinforcement plate 51. Formed, both the first reinforcement plate 51 and the second reinforcement plate 52 have a semi-flat cylindrical shape, and the first reinforcement plate 51 and the second reinforcement plate 53 are detachably connected to form a third reinforcement plate. It is spliced and mounted on the outside of the lower end of the support section 15. The first reinforcement plate 51 and the second reinforcement plate 53 are configured together to cover the foundation pit 200 and to reinforce and compress the antifreeze agent 30 filled in the foundation pit 200. Since the second protective plate 50 is detachably spliced from the first reinforcing plate 51 and the second reinforcing plate 53, the state of the antifreeze agent 30 filled inside the foundation pit 200 can be checked. It is convenient to disassemble the protective plate 50 for viewing, and ensures that the anti-freeze effect of the anti-freeze agent 30 inside the foundation pit 200 is effective. The through hole can be formed by the first reinforcement plate 51 and the second reinforcement plate 53, making assembly and disassembly between the protection plate 50 and the pile body 10 more convenient and faster.

3, based on the above embodiment, in another embodiment, the concrete pipe pile 100 is further provided with a pile plug 70, and the pile plug 70 is located away from the second support section 13. The pile plug 70 is arranged at the end of the third support section 15 and is configured to plug the third support section 15 . Specifically, the pile plug 70 is disposed at the top of the third support section 15. The pile plug 70 prevents rainwater from flowing into the pile body 10 from the nozzle at the top of the pile body 10 by plugging the nozzle at the upper end of the pile body 10. On the one hand, rainwater stored in the third support section 15 after flowing into the interior of the pile body 10 may cause the third support section 15 to frostbite and crack in cold winter, and on the other hand, the third support section 15 may cause frostbite and cracking in the cold winter. Rainwater flowing into the support section 15 may affect the anti-freeze performance of the anti-freeze agent 30, thereby reducing the anti-freeze effect of the anti-freeze agent 30 in the third support section 15. In order to plug the pile plug 70 into the opening at the upper end of the third support section 15, the pile plug 70 is formed tapered. In order to improve the sealing force of the pile plug 70, the pile plug 70 is an elastic member, and the pile plug 70 may be made of rubber.

Referring to Figure 2, the concrete pipe pile 100 is filled with the outer circumference of the second support section 13 with anti-freeze agent 30 and the inside of the third support section 15 with anti-freeze agent 30. An assembly is further provided. During construction, a protective plate 50 is covered over the foundation pit 200, a pile plug 70 is plugged into the opening at the upper end of the third support section 15, and then the foundation pit 200 is filled through the filling assembly. The inside of the inner and third support sections 15 are filled with anti-freeze agent 30, and both the protection plate 50 and the pile plug 70 reinforce and compress the anti-freeze agent 30 when filled with the anti-freeze agent 30. can do.

A filling hole 70a is formed in the middle of the pile plug 70, extending from the upper surface to the lower surface of the pile plug 70, and the protective plate 50 also has a filling hole 70a extending from the upper surface to the lower surface of the protective plate 50. is formed, and the filling hole 70a may be formed in the first reinforcement plate or the second reinforcement plate; The filling assembly includes a first filling pipe 91 and a second filling pipe 93, and the outer diameter of the first filling pipe 91 matches the hole diameter of the filling hole 70a of the pile plug 70, The first filling pipe 91 is configured to fill the inside of the third support section 15 with the anti-freeze agent 30, and the second filling pipe 93 has a hole diameter of the filling hole 70a in the protective plate 50. Consistent with , the second filling pipe 93 is configured to fill the inside of the foundation pit 200 with the anti-freeze agent 30. The nozzle at the output end of the first filling pipe 91 extends into the filling hole 70a in the middle of the pile plug 70, and the first filling pipe 91 extends into the filling hole 70a in the pile plug 70. Filling the inside of the third support section (15) with antifreeze agent (30); The nozzle at the output end of the second filling pipe 93 extends into the filling hole 70a formed in the protection plate 50, and the second filling pipe 93 flows into the base through the filling hole 70a in the protection plate 30. Fill the pit 200 with anti-freeze agent 30.

Additionally, the filling assembly further includes a flow control device, the flow control device is connected to the first filling pipe 91 to control the filling speed of the first filling pipe 91, and/or the flow control device is connected to the second filling pipe 91. It is connected to the filling pipe 93 and controls the filling speed of the second filling pipe 93. By providing a flow control device, the filling start and end time of the antifreeze agent 30 can be controlled, and splashing accidents due to fast filling or extension of application time due to slow filling can be avoided by controlling the filling speed. there is. The volume inside the foundation pit 200 does not match the volume inside the third support section 15, so that the anti-freeze agent 30 is filled inside the foundation pit 200 and the inside of the third support section 15. causes a speed difference. In order to independently adjust the filling speed of the first filling pipe 91 and the second filling pipe 93, in one embodiment, the input end of the first filling pipe 91 and the input end of the second filling pipe 93 A valve 95 is provided at each end to independently control the opening/closing and opening sizes of the first filling pipe 91 and the second filling pipe 93, thereby filling the first filling pipe 91 with the anti-freezing agent 30. ) and the speed of the second filling pipe 93 are controlled, respectively.

In order to facilitate disassembly and installation of the first filling pipe 91, the first filling pipe 91 is connected to the pile plug 70 through a movable joint 97, and the movable joint 97 is connected to the first filling pipe 91. It is detachably connected to the pipe 91; Likewise, the second filling pipe 93 can be connected to the protection plate 50 through a movable joint 97, and the movable joint 97 is detachably connected to the second filling pipe 93.

The above-described embodiments are only preferred embodiments of the present application and do not limit the scope of the present application. With the concept of this application, all equivalent structural modifications made using the contents of the description and drawings of this application or direct/indirect implementation in other related technical fields are included in the protection scope of this application.

100: Concrete pipe pile
10: file body
11: First support section
13: Second support section
15: Third support section
30: Antifreeze agent
50: protective plate
51: first reinforcement plate
53: second reinforcement plate
70: File plug
70a: Filling hole
91: first filling pipe
93: Second filling pipe
95: valve
97: Movable joint
200: base feet
S: ground
L: frost line

Claims (10)

In a concrete pipe pile,
A pile body comprising a first support section, a second support section and a third support section arranged in the listed order and internally communicating, wherein the first support section is inserted into the soil below a freezing line. The pile body is configured so that the interior of the first support section is configured to receive soil below the frost line, and the interior of the second support section is configured to receive soil above the frost line; and
An antifreeze material configured to cover the outer periphery of the second support section and fill the interior of the third support section.
Including,
Concrete pipe pile.
According to paragraph 1,
The concrete pipe pile further includes a protection plate mounted on an outer side of an end of the third support section adjacent to the second support section, wherein the protection plate is configured to reinforce the anti-freeze agent covering the outer periphery of the second support section.
Concrete pipe pile.
According to paragraph 2,
The protective plate includes a first reinforcing plate and a second reinforcing plate, and the first reinforcing plate and the second reinforcing plate are detachably connected and spliced and mounted on the outside of the third support section.
Concrete pipe pile.
According to paragraph 1,
The concrete pipe pile further includes a pile plug, the pile plug being disposed at an end of the third support section away from the second support section, the pile plug plugging the third support section. configured to,
Concrete pipe pile.
According to paragraph 4,
The concrete pipe pile further includes a filling assembly configured to fill the outer periphery of the second support section with the anti-freeze agent, and/or to fill the interior of the third support section with the anti-freeze agent. doing,
Concrete pipe pile.
According to clause 5,
The filling assembly includes a first filling pipe configured to fill the interior of the third support section with the anti-freeze agent; and/or
The filling assembly includes a second filling pipe configured to fill the outer periphery of the second support section with the anti-freeze agent,
Concrete pipe pile.
According to clause 6,
The filling assembly further comprises a flow control device, the flow control device being connected to the first fill pipe to control a filling rate of the first fill pipe, and/or the flow control device being configured to control the filling rate of the second fill pipe. connected to a second filling pipe to control the filling rate of the pipe,
Concrete pipe pile.
According to clause 6,
A filling hole is formed in the pile plug, the filling hole is configured to communicate the inside of the third support section with the outside, and one end of the first filling pipe extends into the filling hole,
Concrete pipe pile.
According to clause 8,
The first filling pipe is connected to the pile plug through a movable joint, and the movable joint is detachably connected to the first filling pipe.
Concrete pipe pile.
According to any one of claims 1 to 9,
The anti-freeze agent has a waterproof function, and/or the anti-freeze agent has an insulating function,
Concrete pipe pile.