RU2598665C1 - Method of enhancing natural base formed by weak soils for road bed erection - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention can be used for amplification of weak natural base, erection of railways roadbed, construction of dams, dams. Method of enhancing natural base formed by weak soils for roadbed erection includes reinforcement of the weak soil massif by mechanical mixing with reinforcing materials, including astringent materials added under pressure. Strengthening is performed at variable depth and width, connected to the calculated mounted zones of maximum attenuation base caused by the worst combination of acting stresses in the base and mechanical properties of weak soil, defining the base (zone of low resistance in the base).

EFFECT: control of depth and width of reinforcement, phasing reinforcement and its performance only part of the massif in zones of maximum attenuation of the base, reduction of material consumption and labour intensity.

4 cl, 4 dwg

Description

The invention relates to road construction, and more specifically, relates to a method of strengthening the natural base, composed of soft soils, to a considerable depth (from 3 meters) for the subsequent construction of the roadbed of roads. The method can also be used in the construction of the subgrade of railways, the construction of dams, dams, etc.

Known methods of constructing a subgrade on a base composed of soft soils by arranging a pile field of concrete or cement-hard ground piles (Manual for the design of subgrade of roads on soft soils - M., Informavtodor, 2004, p. 77-89 [1]) flexible simultaneously draining piles with additional vertical drainage by tape geodrains (a method of erecting an earthen structure on weak natural grounds according to patent RU 2337205 C1, Е01С 3/06, 01/18/2007).

The known methods have disadvantages, which are manifested in possible uneven deformations due to the presence of weak soils in the inter-pile space, which is only partially compensated by the costly piling grillage, as well as due to the possible instability of the strength and transverse dimensions of the piles created at the place of production.

In addition, the known methods involve the use of heavy reinforced concrete structures or various types of special equipment, including equipment for performing expensive drilling operations.

The closest is the known method of strengthening a natural base composed of soft soils (International Standard EN 14679: 2005-7 "Execution of special geotechnical works - Deep mixing" [2], Design Rules "EuroSoilStab" CT97-0351 [3]), providing for the strengthening weak soils by mechanical mixing with reinforcing materials (binders - lime, cement, active - ash, slag, inert - weakly active ash, slag, sand) and the introduction of binders under pressure, and the entire mass of weak soil is strengthened within the subgrade width to a limited depth binu (up to 5 meters). However, this method of reinforcement is not always sufficient to ensure the required stability and degree of consolidation of soft soils when exposed to loads from the weight of the embankment and vehicles and is not optimal, since the stress distribution in the thickness of soft soil is uneven. This does not guarantee the reliable functioning of the road, leading to additional material costs.

The problem to which the claimed invention is directed, is to implement a amplification method that meets modern requirements for reliability, device convenience and resource saving.

The tasks are solved due to the fact that the foundation of the subgrade, composed of soft soils, is strengthened by strengthening the array of weak soils by mechanical mixing with reinforcing materials, including cementitious materials applied under pressure, and the reinforcement is carried out at a variable depth and width associated with the calculated set areas of the greatest weakening of the base, caused by the worst combination of acting stresses in the thickness of the base and indicators of the mechanical properties of soft soils, x base (zone of low stability at the base).

In the case when soft soils are organic (peat, etc.), it is preferable to use local cohesive substandard (overmoistened) clay soil as one of the components of the reinforcing materials.

With a significant depth of a shallow thickness, when the technical capabilities of the equipment used to implement the method are insufficient to strengthen the thickness to the required depth, the strengthening is carried out in two stages, removing the soil that has been strengthened but has not gained strength, for its subsequent use in layer-by-layer with compaction the construction of the subgrade at the first stage and strengthening at the second stage the weak soil of the base below the level of the bottom of the layer of reinforced soil.

In the case where the removal of reinforced soft soil is difficult due to difficult soil and hydrological conditions (the presence of soils of fluid consistency, close to the surface or the level of the ground water coinciding with the surface of the base, etc.), the weak soil is preliminarily reinforced in areas adjacent to the sole subgrade, and the removal of reinforced soil and the subsequent strengthening of the soil between the zones is performed after reaching located in them reinforced soil of the required strength.

Achievable technical result consists in optimal regulation of the depth, width of reinforcement, staging of reinforcement and its implementation only in part of the array, in areas of greatest weakening of the base without limiting the depth of reinforcement with the technical capabilities of the equipment, from the standpoint of reliability, which reduces the consumption of reinforcing materials brought in and increases the convenience of the device the use of the same type of equipment, reducing the time of the device).

The invention is illustrated by drawings, which do not cover and, moreover, do not limit the entire scope of the claims of this technical solution, but are only illustrative material of a particular case of execution.

In FIG. 1 is a general diagram of the technology used to implement the method.

In FIG. 2 - examples of cross sections of the subgrade and weak base.

When implementing the method, the following technology is used (Fig. 1). The weak soil of the base 1 is mechanically mixed with reinforcing materials, the type and quantity of which is selected depending on the required strength, type and condition of the weak soil, using a mixer 2, which simultaneously supplies the binder (cement, lime, etc.) under pressure and placed as attachments on the base machine 3 (for example, a crawler excavator), the binder is fed under pressure by the feeder 4, and the strengthening work is carried out according to the method "on my own", that is, the base machine and the feeder are laid on the lower layer of the arranged subgrade 5, over which, on the surface of the weak soil 6, if necessary, a separating and reinforcing layer of geosynthetic material 7 is placed, and the strengthening is carried out in the direction 8 (“away from you”).

When implementing the method, a calculated stability assessment and prediction of the embankment settlement on a weak foundation are preliminarily performed in accordance with Section 3 of the Handbook [1], establishing zones 9 of the greatest attenuation of the base, composed of soft soils 10, caused by the worst combination of acting stresses in the thickness of the base from the weight of the subgrade 11 , load 12, equivalent transport, and indicators of the mechanical properties of soft soils. The points of greatest attenuation in the thickness of soft soil are distinguished by the calculated stability coefficient K _st , the values of which 13 are applied to the transverse profile of the base, after which the contour of the zone of greatest attenuation 14, covering points with a stability coefficient below the required value, is isolated. Reinforcement is performed within the performed contour 14, variable in depth and width, without performing an excessive amount of reinforcement work outside the contour and, at the same time, providing, if necessary, as shown in FIG. 2, strengthening the weak soil outside the subgrade, which increases the reliability of strengthening the weak base.

As follows from the results of experimental studies [3], the worst results from the point of view of increasing the strength of the soils composing the base at a single binder consumption are achieved when strengthening organic soils, the best - when strengthening cohesive clay soils. As a result, local substandard (waterlogged) soil can be used to reduce the binder consumption while maintaining the strength of the reinforced soil. Such local soil is often available at the construction site, due, for example, to the need to develop excavations and the inability to use it in embankments (soil moisture exceeds permissible). In this case, such soil is subject to disposal (removal outside the construction site with subsequent unloading and leveling at the designated disposal site), which complicates the production process and leads to additional costs. In this case, substandard cohesive clay soil can be unloaded directly onto the base and mixed with a mixer with weak organic base soil.

In the case when the technical capabilities of the equipment do not provide the required depth of strengthening of the thickness of soft soil, the reinforcement is performed to a possible depth h _in (Fig. 2), the strengthened, but not formed (not gained strength) soil 15 is moved into the embankment with layering, compaction and the formation of its lower part in the first stage, the strengthening of weak soil below the sole level of the 16th layer of removed soil in the second stage. A simple removal of soft soil with its replacement would require the complexity of the technology and additional costs, due to the need for disposal of soft soil.

In the case where the removal of the strengthened soft soil of FIG. 3 is difficult, due to the presence of soils of fluid consistency, watering of the construction site, weak soil is pre-fortified in zones 17 adjacent to the sole of the subgrade 11, and the strengthening of the strengthened soil 15 and the strengthening of the weak soil below the base of the embankment 16 is performed after reaching the weak soil located in the zones 17 required strength. The preliminary strengthening of the soil in zones 17 creates the convenience of performing work in particularly unfavorable soil and hydrological conditions, since the soil strengthened in zones 17 prevents the spread of weak soil 10 into the zone of location of the strengthened and strengthened soil 15.

The strengthening of weak soil, which is variable in width and depth, makes it possible to optimize the geometrical parameters of strengthening based on their combination with the zones of greatest weakening of the soil without performing excessive amounts of work outside these zones when performing work on strengthening outside the width of the subgrade, if necessary, if it is calculated that the presence of zones of weakening outside soles of the subgrade. This allows you to increase the stability of the subgrade with optimal use of resources.

The introduction of local cohesive substandard materials among the reinforcing materials while strengthening organic soft soils leads to a reduction in the consumption of cementitious materials, a reduction in the cost of utilization of local clay soil, and an increase in the convenience of construction work.

The introduction of the phasing of work with the preliminary strengthening of soft soil, its movement until it forms (until strength is set) to the lower part of the embankment, improves the reliability of the subgrade itself by forming the lower part of the soil with high strength and at the same time allows not to limit the technical capabilities of the method regarding the depth of strengthening with the technical capabilities used to implement the equipment methods.

Claims (4)

1. A method of reinforcing a natural base, composed of soft soils, for the construction of the subgrade, including strengthening the array of soft soils by mechanical mixing with reinforcing materials, including cementitious materials applied under pressure, characterized in that the reinforcement is made to a variable depth and width associated with calculated areas of greatest weakening of the base, caused by the worst combination of acting stresses in the thickness of the base and the mechanical properties of weak g untov composing base (low resistance zones in the bottom). 2. The method according to p. 1, characterized in that in the case when the base is composed of weak organic soils, a local cohesive clay soil is used as one of the components of the reinforcing materials. 3. The method according to p. 1, characterized in that the strengthening is carried out in two stages, removing at the first stage strengthened, but not gaining strength, soil for subsequent use with erection of the subgrade in layers at the first stage and consolidating weak soil at the second stage foundations below the level of the bottom of the removed soil 4. The method according to p. 3, characterized in that the weak soil is pre-strengthened in areas adjacent to the sole of the subgrade, and the removal of the reinforced soil and the subsequent strengthening of the soil between the zones is performed after the reinforced soil located in them is of the required strength.

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