RU2275470C1 - Method of floating pile load-bearing capacity increase - Google Patents

Abstract

FIELD: building, particularly pile foundations including floating piles.

SUBSTANCE: method involves injecting hardening mortar via injectors driven in ground in area between the piles and at pile ends for depth exceeding 1-2.5 m, wherein the injectors are spaced 1.5-2.0 meters apart. The hardening mortar pressure gradually increases. The hardening mortar is injected up to creation of hydraulic fracture cavities having 1.5-2.0 m radii around each injector. Then the injection operation is preformed under constant pressure of 2-10 atm to consolidate and reinforce ground, compress the piles to multiply load-bearing capacity thereof by 1.5-2 times.

EFFECT: increased load-bearing pile capacity due to increased side friction and head resistance.

3 cl, 1 dwg

Description

The invention relates to construction, in particular to the creation of pile foundations of buildings and structures on suspended piles in weak dispersed soils of high power.

The closest are ways to increase the bearing capacity of suspended piles by: a) increasing the length and diameter of piles, b) reducing the distance between piles and increasing the total number of piles per unit area of the foundation, c) expanding the lower end (heel) of the pile, d) increasing the diameter of the pile using discharge-pulse technology (1).

A disadvantage of the known methods is that the increase in the bearing capacity of the hanging piles is achieved by increasing the area of their rubbing surfaces (side and frontal), and not by increasing the friction of the soil in contact with the pile. This leads to the need to increase the size of piles and their number per unit area of the foundation, which is associated with an increase in labor costs and material consumption of construction and ultimately leads to a significant increase in the cost of pile foundations.

The objective of the invention is to increase the bearing capacity of suspended piles by increasing friction and resistance at the contact of soil with piles.

The essence of the method is as follows.

The load-bearing capacity of hanging piles to create pile foundations on weak dispersed soils is increased by supplying a hardening mortar through injectors located in increments of 1.5-2.0 m into the soil located in the inter-pile space and the pile foundation, under increasing pressure until cavities form in the soil hydraulic fracturing with a radius of 1.5-2.5 m around each injector, and further feeding is carried out at a constant pressure of 2-10 atm, and the injectors are immersed to a depth exceeding the depth of immersion of piles by 1-2.5 m. The injection of the solution can be carried out in opposite directions, for example, by means of three-directional slotted injectors located along the external and internal contours of the foundation at a distance of 0.5-1.0 m from it. When creating a slab foundation on piles, injectors are immersed throughout the pile field along a grid of 1.5 × 1.5, 2 × 2, 2 × 3 m through metal pipes mounted in the foundation plate during its creation.

To enhance the bearing capacity of piles of constructed structures, the installation of injectors is carried out from the basement of the structure.

After completion of the injection of the solution, the injector is immersed to a new depth so that the zones of hardened soil at two adjacent injection points adjoin each other. As a result of this procedure, the soil is compacted with a solution filling the cavity, which causes an increase in the physical and mechanical properties of the soil and enhances the contact interaction of the soil-pile. In addition, when the solution solidifies, solid cement inclusions are formed in the soil that reinforce the soil, which enhances the effect of soil compaction and its interaction with the pile.

Thus, the high efficiency of the method is achieved through the use of a hardening solution as a sealing and reinforcing material, which is supplied under pressure into the inter-pile space and the foundation of the piles, which leads to compaction of the soil and its reinforcement (after the cement mixture has hardened), as well as compression of the piles and ultimately, an increase in their bearing capacity by 1.5-2.0 times due to the growth of friction forces along the side surface of the pile and their drag.

An additional positive technical result of this method is the ability to achieve an increase in the bearing capacity of suspended piles under previously built including emergency buildings during their repair, reconstruction or superstructure, which is extremely difficult to implement by known methods in view of the need to introduce an additional number of piles under the constructed building.

The drawing shows in axonometric projection a fragment of the pile foundation in the form of hanging piles and a grill connecting them.

The method is as follows.

At the construction site of a building or structure along the internal and external contours of the strip pile foundation (grillage 1 connecting the hanging piles 2) at a distance of 0.5-1.0 m, three-directional slotted injectors 3 are immersed on both sides of the foundation in increments of 1.5-2 , 0 m to a depth exceeding by 1-2.5 m the depth of immersion of the pile (h). In case of increasing the bearing capacity of the pile foundation of a building or structure already built, the inner row of injectors is immersed from the basement or inclined injectors are introduced from the outside of the foundation. The size of the step is determined by the state of the soil mass and the set value of the increase in the bearing capacity of the piles. By decreasing the step, the greatest effect is achieved in the application of the proposed method.

Through injectors 3 with a vertical step of 1.5-2.0 m, a hardening mortar (for example, sand-cement, grade M-200) is injected, which serves to compact the soil around the piles and at their base. The injection is carried out initially with increasing pressure until the formation of hydraulic fracture cavities, and then under a pressure of 2-10 atm. As soil density increases, soil compaction increases. The upper pressure limit is limited by the beginning of the mixture exit to the surface along the injector. The flow rate of the mixture is 2-5 l / min. The total duration of injection at one point is on average 0.5-2 hours.

The volume of injected hardening solution is calculated by the density and porosity of the soil, which must be achieved to obtain the planned increase in the bearing capacity of the piles. For example, to increase the load-bearing capacity of a standard pile by 2 times in loam with a porosity of 48%, it is necessary to reduce its porosity to 42%, therefore, the volume of sand-cement mixture required to compact 1 m ^{3 of} soil is 0.06 m ³ .

After hardening the solution in a compacted mass, hard inclusions are formed that reinforce the entire mass. The compacted and reinforced natural and technogenic massif compresses piles, increasing their lateral friction and drag.

Thus, an increase in the bearing capacity of suspended piles occurs due to compaction and reinforcement of the soil in the inter-pile space and at the base of the piles, leading to an increase in lateral friction of the piles during compression and drag - when the soil is hardened under the lower ends of the piles.

In case of increasing the bearing capacity of the slab foundation on piles, the injectors are placed on a grid of 1.5 × 1.5, 2 × 2, 2 × 3 m throughout the pile field. The injection of the cement mixture is carried out after the creation of the foundation slab. During the construction of the plate, metal pipes with an internal diameter of 5-6 cm, which are necessary for the injection of the hardening solution from the surface of the plate, are vertically installed in it according to a given grid. Injection along the outer contour of the plate is carried out using a three-slot injector, and inside the pile field of the plate through a four-slot injector.

When reinforcing plate pile foundations of constructed buildings and structures, the installation of injectors is carried out from the basement of the building.

Example. The 14-story block building, consisting of two block sections 14.1 × 26.4 m in size, was built on pile strip foundations. Piles rely on clay soils with a deformation modulus of 11 MPa and dusty sands with a deformation modulus of 13–20 MPa. The length of the piles is 6-7 m. The grillages are the foundations of the transverse load-bearing walls. Piles are staggered along the grillage in increments of about 1.5 m.

At the base of the building, from the surface to a depth of 4.0-5.0 m, unconsolidated bulk soils are deposited, dumped a month before the start of construction, moist, water-saturated (due to overhead water). Below to a depth of 6.0-8.0 m, a pack of interbedded upper Quaternary alluvial clays and loams is located, soft plastic to semi-solid consistencies with interlayers of sand, sandy loam and organic residues. The deformation modulus of the pack rocks is 5-15 MPa. Still lower are the upper Quaternary alluvial deposits, represented by sands of different sizes from silty to large with a deformation modulus of 13 to 40 MPa. Groundwater opened at a depth of 6.5-7.0 m.

The insufficient bearing capacity of the piles led to uneven settlement of the building and its significant roll. According to the results of static tests of three piles until the foundation was strengthened, the bearing capacity of the piles was 36 and 42 tons. In this case, the calculated bearing capacity of the piles was taken 60 tons, i.e. the lack of bearing capacity of piles amounted to 18-24 tons. As a result, the building received a roll in the front. By the time the work began, the average uneven draft reached about 160 mm, the average deviation of the upper part of the building was 475 mm.

In order to increase the bearing capacity of the existing pile foundation and to prevent further deposits, work was done to increase the bearing capacity of the pile using the proposed method. The project envisaged at the first stage the strengthening of soils to a depth of 2.0-2.5 m under the tip of the piles and by 0.5-1.0 m along the side surface of the piles. At the second stage, bulk soils were strengthened, which eliminated the negative friction of these soils due to their ongoing gravitational compaction, and secondly, increased their friction along the lateral surface of piles.

The volume of injected hardening solution was calculated in such a way as to reduce the porosity of the dusty sand in the base of the piles by 5%. According to calculations, this could lead to an increase in the deformation modulus of these sands from 11 to 18 MPa. Since the additional effect of soil reinforcement was difficult to evaluate, it was decided, after completion of the work, to test the bearing capacity of piles by immersing them with jacks. In total, three piles were tested from the front of the building (two of them were tested before the beginning of the strengthening work) and two from the courtyard of the building. The ultimate resistance values for the tested piles ranged from 64 to 78 tons. The standard value of the ultimate resistance was taken to be 64 tons. Thus, as a result of the work performed, the average bearing capacity of the piles increased from 36 to 64 tons, i.e. almost 2 times and exceeded by 4 tons the required design value of the bearing capacity of piles (60 tons).

Information sources

L.E. Linovich. Calculation and design of parts of civil buildings. Kiev: Budivelnik, 1972, p. 293-294.

Claims (3)

1. A method of increasing the bearing capacity of suspended piles to create pile foundations on weak dispersed soils by supplying a hardening mortar, characterized in that the solution is supplied through injectors located at a distance of 1.5-2.0 m into the soil located in the inter-pile space and base piles under increasing pressure until hydraulic fracturing cavities are formed in the soil with a radius of 1.5-2.5 m around each injector, and further feeding is carried out at a constant pressure of 2-10 atm, and the injectors are immersed to a depth exceeding at 1-2.5 m depth of immersion of piles. 2. The method according to claim 1, characterized in that when creating a slab foundation on piles, the injectors are immersed throughout the pile field along a 1.5 × 1.5 grid; 2 × 2; 2 × 3 m through metal nozzles mounted in the foundation plate during its creation. 3. The method according to claim 1, characterized in that when strengthening the bearing capacity of piles of the constructed structures, the installation of injectors is carried out from the basement of the structure.