RU2467127C2 - Butt connection of pile pipe sections - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to the field of geotechnical construction, namely, to manufacturing of piles that perceive vertical and horizontal forces and moments acting at a pile, side pressure of soil during their use to fix pits and slopes of mines, and also for a device of pressed piles, when it is nit possible to use a solid pipe for the entire length of the pile for pile reinforcement. The highest advantage the proposed invention has in case of piles arrangement under conditions that limit application of pipes for the entire length of the pile, for instance, when arranging piles of reinforcement of building foundations from basement rooms or under ramps and under other conditions. The butt connection of pile pipe sections includes an additional section of a pipe of a smaller and/or larger diameter compared to accordingly an inner or outer diameters of pile pipe sections placed in the zone of jointing of the upper and lower pipe. The entire space, which is not occupied with pipes, is filled with a disperse hardening material. When using the additional section of a smaller diameter pipe it is placed with one end for the depth of at least one diameter inside the lower part of the upper pipe and is fixed in it, and with its other end the specified pipe section is freely arranged inside the pipe of the lower section for the depth of at least one its diameter, preferably.

EFFECT: higher bearing capacity of a pile as a result of reduction of a value of its longitudinal axis diversion from the design position, and also improved quality, lower labour intensiveness and material intensity.

7 cl, 10 dwg

Description

The invention relates to the field of geotechnical construction, namely to the manufacture of piles that absorb vertical and horizontal forces and moments acting on the pile, lateral pressure of the soil when they are used for fastening pits and slopes of mine workings, as well as for the device of crushed piles, when it is impossible to reinforce piles use an integral pipe for the entire length of the piles. The claimed invention has the greatest advantage when installing piles in conditions restricting the use of pipes to the entire length of the pile, for example, when installing piles to strengthen the foundations of buildings from basements or under racks, etc. conditions.

A known method of reinforcing drill piles by immersing successively joined pipe elements with an open upper end. At the ends of the pipes from the outer surface, elements (overlays) are fixed that ensure the coaxiality of the individual sections and their strong connection to each other, as well as elements that center the pipe when it is immersed in the well. Pipe sections are interconnected by electric welding, both pipe sections and connecting elements (overlays), which simultaneously ensure the alignment of individual sections [see “Restoration, reconstruction with partial new construction and adaptation to modern functional and engineering requirements of the complex of buildings of the Federal State Educational Institution of Higher Professional Education (University) of the Moscow State Conservatory named after PI Tchaikovsky ", Bored injection piles BI-1 ... BI-2, sheet 25; Bored injection piles BI-3 ... BI-6, sheet 26, 45 / 35-61-09 / SP., 2008].

However, the complexity of such a butt joint of reinforcing pile pipes is very high. It is impossible to exclude non-uniform temperature deformations in each joint node of individual sections connected by welding of a large volume of metal by electric welding, as a result, the pipe immersed in the well is not straightforward. The curvature in each node of the butt joint is rigidly fixed by electric welding, as a result, the reinforcing pipe represents a broken line that changes direction in each joint. When drilling wells, the drilling tool always deviates to the side where the soil is found, which is easier to break when drilling. Due to the "yaw" of the drilling tool, the well receives deviations from a straight line. The curvature of the well does not coincide with the curvature of the reinforcing pipe. When a straight pipe is immersed in a well, the protective layer of concrete in some places can wedge out to zero, despite the presence of centralizers, which in this case become practically useless. In places where there is no protective layer of concrete or its size is less than required, intense reinforcement pipe oxidation occurs. As a result, it is not possible to guarantee the required durability of the reinforcing pipe. Immersion of stacked pipes heated to a high temperature in the joint zone of sections is unacceptable until the temperature in the welding zone is reduced to a level at which the destruction of the deposited metal and pipe material that are unevenly heated during electric welding is excluded. When reinforcing piles with a pipe made up of separate sections connected by electric welding, even after cooling around the weld points, local zones of elevated temperature are preserved. In these areas, accelerated hydration of cement occurs, concrete plugs are formed that impede the immersion of the pipe in a well filled with concrete. Very often formed concrete plugs do not allow to immerse the composite pipe reinforcing the pile to the design depth. Despite the high complexity of the electric-welded butt joint of pipes reinforcing the pile, it is very difficult to ensure the joint strength equal to the strength of the pipe without a joint, also filled with concrete mixture, under the effect of horizontal load, for example, from lateral soil pressure in the pile of the pit side fence. If it is necessary to immerse a reinforcing pipe docked from many sections into a well to a great depth, the problem of setting concrete mix arises. Even with the introduction of additives of cement hardening agents, it is practically impossible to perform more than one joint qualitatively before the cement hardening is completed.

Known butt joint of piles with a pipe segment, covering with a gap the lower and upper sections of the connected piles and filled in its cavity and in the gaps between the sections of the piles with hardening dispersed material (USSR patent No. 9228, E02D 5/52, 1929).

The closest known joint is the butt joint of the pipe sections of the piles, made in the form of pipe sections arranged with gaps along its internal and external perimeters, interconnected, the gap between the pipe sections being filled with hardening dispersed material (RF patent No. 2098555 C1, E02D 5/52 , 1997).

Known technical solutions do not provide high quality and optimal bearing capacity of piles, have a high cost, laboriousness, energy and time consumption for equal strength connection of pipe sections reinforcing the pile.

The objective of the present invention is to eliminate the above drawbacks - increasing the bearing capacity of the pile by reducing the deviation of its longitudinal axis from the design position, as well as improving the quality, reducing the complexity, energy consumption and time for connecting pipe sections to each other when they are installed in the well with a minimum possible resource consumption and maximum use of material properties.

The task is achieved as follows.

According to this technical solution, the butt joint of the sections of the pile pipes (during the installation is non-rigid, and after installation is completed, due to the set of strength by hardening material, it becomes rigid), comprising at least two sections - the lower pipe (lower section) and the upper pipe (upper section), additionally in the joint zone is equipped with a short pipe (pipe segment) of smaller diameter, which is installed (inserted) at one end into the lower part of the upper pipe and connected to it, and the pipe with a smaller diameter at the other end installed (inserted) into the pipe of the lower section. All free space is filled with finely divided hardening material to the upper cut of the upper pipe. In this case, a segment of a pipe of a smaller diameter is inserted inside the lower part of the upper pipe to a depth of at least one pipe diameter and fixed there, and the other end of the pipe of a smaller diameter is freely located inside the pipe of the lower section to a depth of at least one pipe diameter. The ends of the pipes of larger diameter, the lower section and the upper section, in the joint zone are contacted by end surfaces. When choosing pipe sections, the following rule should be followed: the gap between the outer wall of the pipe of smaller diameter and the inner wall of the pipe of the lower section is filled with fine-grained hardening material containing grains whose maximum size is less than the gap. In other words, the outer radius of the inner pipe is less than the inner radius of the outer pipe by d _max , where d _max is the maximum particle size of the aggregate in the hardening material. Each section of the pipe immersed in the well is equipped with centralizers to provide the required protective layer of concrete. Each pipe section is equipped with hooks or similar elements for temporarily hanging a string of pipes immersed in a well; centralizers are allowed to function as elements for temporarily hanging a string of pipes submerged in a well and vice versa, elements for temporarily hanging a string of pipes act as centralizers. After the pipe of a smaller diameter of the upper section is installed in the pipe of the lower section, until the contact of the end edges of the joined pipes, the joined pipes are connected by flexible connections, for example, knitting wire, electric welding or special devices that temporarily hold the pipe string assembled into the well until the hardening material has gained strength. After the solidification of the material filling the well and the cavity of the pipes, the pipe string maintains the position that the pipes occupied when immersion in the well was completed. During the immersion of the pipe reinforcing pipe string, the concrete mixture retains rheological properties, including mobility (fluid state), so each butt joint has the possibility of limited rotation until the outer wall of the inner pipe (pipe of smaller diameter) comes in contact with the inner wall of the outer lower pipe. At the same time, the pipe during the process of immersion in the well will seek to repeat the shape of the well, and after curing by hardening material (concrete), the reinforcing composite pipe acquires the necessary rigidity.

Along the length of the pile, the diameter of the reinforcing pipes and / or wall thickness can vary in accordance with the loads acting on the pile, including torque. When immersing the first lower section, the first pipe can be installed, which enters the pipe of the next section, for which one of these pipes is equipped with stops that limit the maximum depth of the butt mating of the pipes with two pipe diameters, as well as devices connecting and holding the lower pipe from slipping from the upper pipe. The function of these stops can be performed by centralizers installed in the upper part of the lower pipe of smaller diameter. Centralizers of the lower pipe can be connected (connected) with centralizers above the installed pipe. This connection is solved, for example, by connecting the centralizers of the lower and upper pipe sections with a knitting wire. When immersing the last uppermost section of the pipe, a pipe can be installed that enters the pipe of the penultimate section, for which such a pipe is equipped with stops that keep the upper pipe from immersing in the lower by more than two diameters.

When immersing composite pipes into the ground by indentation, the joint is performed similarly to the joint of pipes reinforcing the pile. Before installing the next section, the cavity of the pipes immersed in the ground is filled with fine-grained concrete mixture. At the same time, centralizers and hanging elements are not required. A pipe of a smaller diameter can enter the cavity of a pipe of a larger diameter to half its length. Moreover, the pipe may rise above the surface of the earth at the beginning of the formation of piles, and then, as the piles form, plunge into the ground.

Thus, the maximum possible value of the protective layer of concrete is provided, and at the same time, the bearing capacity increases with a possible deviation of the longitudinal axis of the pile. When drilling wells, the drilling tool always deviates to the side where the soil is found, which is easier to break when drilling. Due to the "yaw" of the drilling tool, the well receives deviations from a straight line. Immersion in a straight borehole of a pipe composed of short straight pipes having a kind of hinge in the joint, allows each pipe section to be deflected at a certain angle until the concrete mix hardens, i.e. in the process of diving. In this case, due to the presence of centralizers, each section, repeating the deviations of the well, occupies the optimal position from the conditions for ensuring the maximum protective layer of concrete. By varying the pipe sections along the length of the pile, in accordance with the loads acting on the pile in a particular section, the consumption of metal rolling is minimized.

As experimental studies showed when conducting comparative tests of a continuous pipe (without joint) filled with concrete and joined pipes according to the claimed technical solution (with concrete filling), the destruction of the samples of joined pipes occurred with large deformations and large force impacts. Concrete located between the outer surface of the pipe wall of smaller diameter and the inner surface of the pipe wall of larger diameter, operates under conditions of triaxial compression. Deformations of the concrete in the "cage" are limited, therefore, for the destruction of the butt joint, loads with higher values are required. Thus, the cavity between the walls of the pipes is as if filled with heavy-duty concrete working in a confined space. In this case, concrete provides joint work of joined pipes as a single continuous pipe.

This is achieved by the fact that the butt joint of the pile pipe sections includes an additional pipe segment of a smaller and / or larger diameter located in the joint zone of the lower and upper pipes than the inner or outer diameters of the pipe pipe sections, and the entire space not occupied by the pipes is filled with dispersed hardening material, and when using an additional length of pipe of a smaller diameter, it is placed at one end to a depth of at least one of its diameter inside the lower part of the upper pipe and fixed in it, and the other to nets, said pipe segment, is freely located inside the pipe of the lower section to a depth of at least one of its, preferably its diameter. In this case, a pipe segment of a smaller diameter can enter the cavity of the pipe section to half its length. The ends of the sections of the pipe piles in the joint zone can be contacted by end surfaces along their entire perimeter or with the formation of channels for the passage of dispersed hardening material. Each section of the pipe is equipped with centralizers, ensuring the implementation of the protective layer of concrete or temporary hanging of the pipe string. Also, each section of the pipe can be equipped with hooks or loops for temporary hanging when immersed in the well. In this case, the abutting pipe sections can be made of various diameters and / or with different wall thicknesses. Inside the penultimate section of the pipe before immersing the last, uppermost section placed in the body of the grillage, a pipe segment is included in the last section.

The invention is illustrated by drawings.

Figure 1 shows the junction of two sections, bottom 1 and top 2.

Figure 2 shows a section 1-1 in figure 1.

Figure 3 shows a section 2-2 of figure 1.

Figure 4 shows the butt connection of two sections (lower 1 and upper 2) with a cutout in section 3-3.

Figure 5 shows a fragment of the node And in figure 4.

Figure 6 shows the upper section of the lower section with centralizers.

7 shows the upper section of the lower section with hooks for connecting sections.

On Fig shows the butt connection of two sections, the bottom 1 and the uppermost, smaller diameter, with a cutout in section 3-3.

Figure 9 shows the butt connection of two sections, the lower 1 and upper 2, at the time of their connection.

Figure 10 shows the reinforcement of piles in separate sections.

Moreover, the drawings indicate: lower section 1, upper section 2, connecting pipe 3, the radius of the outer surface of which is less than the radius of the inner surface of the sections 1 and 2, so that between the outer surface of the pipe 3 and the inner surfaces of the sections 1 and 2, a gap is ensured, the size of which corresponds to twice the size of the largest particles in the hardening material, inserted into the upper section 2 and fixed in it, and then immersed in the lower section 1, filled with hardening material (concrete mixture) 5. At the ends with In the case of sections facing the joint zone, centralizers 7 or hooks 8 are attached. When immersed, the lowest pipe 9 and the highest pipe 9 have a smaller diameter than the other sections, and to prevent the pipes 9 from slipping more than a certain size, the stops 10 are fixed on the surface of the pipes 9. To connect the sections to each other, connecting elements 11 are used. Before immersion of the reinforcing elements in the wellhead, an inventory conductor pipe 12 is installed. When assembling the sections of reinforcing elements, a set of sec. It is hung out on centralizers 7 or hooks 8.

Thus, for the first time, it is possible to produce drilling piles reinforced with composite pipes that effectively work on horizontal loads, for example, lateral soil pressure when attaching the side of the foundation pit from the basement of the building.

The process of arranging piles reinforced with composite pipes can be carried out as follows: in the well drilled in the soil from a limited height building filled with plastic concrete mix, immerse the lower section of the pipe reinforcing the pile to the upper cut, the lower section is hung out, the connecting section is inserted into it pipe of the subsequent section. Sections are connected using connecting elements. All reinforcing elements are also immersed.

Claims (7)

1. A butt joint of pipe pile sections, including an additional pipe segment of a smaller and / or larger diameter located in the joint zone of the lower and upper pipes than the inner or outer diameters of the pipe pipe sections, and the entire space not occupied by the pipes is filled with dispersed hardening material, moreover, when using an additional pipe segment of a smaller diameter, it is placed at one end to a depth of at least one of its diameter inside the lower part of the upper pipe and is fixed in it, and the other end dressings tube freely located inside the lower section tube to a depth of at least one of its, preferably it diameter. 2. The butt joint of the pipe sections of the piles according to claim 1, characterized in that the pipe segment of a smaller diameter extends into the cavity of the pipe section to half its length. 3. The butt joint of the sections of the pipe piles according to claim 1, characterized in that the ends of the sections of the pipe piles in the joint zone are contacted by end surfaces along their entire perimeter or with the formation of channels for the passage of dispersed hardening material. 4. The butt joint sections of the pipe piles according to claim 1 or 2, characterized in that each section of the pipe is equipped with centralizers that provide a protective layer of concrete or temporary hanging of the pipe string. 5. The butt connection of the sections of the pipe piles according to claim 1 or 2, characterized in that each section of the pipe is equipped with hooks or loops for temporary hanging when immersed in the well. 6. The butt joint of the pipe sections of the piles according to claim 1 or 2, characterized in that the joined sections of the pipes are made of different diameters and / or with different wall thicknesses. 7. The butt joint of the pipe sections of the piles according to claim 1 or 2, characterized in that a pipe section is included in the last section inside the penultimate section of the pipe before immersing the last, highest section located in the body of the grill.

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