KR101372163B1 - Structure on soft ground using a compensated foundation and improved surface layer and construction method for the compensated foundation - Google Patents

Abstract

The present invention relates to a structure on soft ground using a compensated foundation and an improved surface layer and a construction method for the compensated foundation comprising a step of analyzing the strata of soft ground; a step of excavating soil; a step of compacting soil; a step of filling the excavated area with the excavated soil; a step of calculating an allowable bearing capacity and checking whether the allowable bearing capacity is enough to bear a design load; a step of forming an improved surface layer; a step of increasing the depth of the improved surface layer for areas expected to have abnormal settlement; a step of determining a design load and designing a foundation area; a step of forming a compensated foundation; and a step of forming a foundation and a bottom floor and constructing a building or a structure on the top of them. Therefore, the present invention prevents differential settlement after the construction of the building or the structure by compacting the excavated surface and applying surface improvement materials to the excavated surface. [Reference numerals] (20) Compensated foundation; (30) Foundation and a bottom floor; (40) Building

Description

Structure on soft ground using a compensated foundation and improved surface layer and construction method for the compensated foundation}

The present invention relates to a soft ground structure using a compensation foundation and a surface improvement layer and a construction method of the foundation, and more particularly, to excavate the weight of soil corresponding to the load of the structure with a trench and to the surface of the excavation surface by the trench. The present invention relates to a soft ground structure and a method of constructing the foundation using the compensation base and the surface improvement layer, which solidify the foundation and improve the foundation of the compensation by using the improved materials.

If the foundation is used as a pile in soft ground, there are problems of safety on the heaving during excavation, problems of construction work due to pile foundation construction on the soft layer, and increase of pile head water due to the reduction of bearing capacity due to the consideration of pile friction. .

In order to solve the problem of pile foundation method, compensation foundation principle is introduced and foundation on existing soft ground is established. However, in the case of compensation basis, there is a fear of uneven settlement due to the imbalance of use load and creep settlement.

Compensation foundation method is a basic method to install the foundation on the intermediate support layer by subtracting the ground stress, which is reduced by the trench, when the support layer is very deep and difficult to transfer the load of the upper structure to the support layer. In the same way, it is a basic method that suppresses settlement by making the stress acting on the ground to be zero, which is more economical than the existing pile method.

However, in the case of compensation basis, there are disadvantages of inequality settling due to the imbalance of use load and creep settling. Therefore, surface solidification treatment should be applied to secure the supporting force to the compensatory base support layer and distribute the concentration of stress to induce even settlement.

For the purpose of reinforcing soft ground such as wetlands, ponds, river shores, reclaimed land or dredged landfills with high water content, solidification or soil modifiers for solidifying wastewater containing sludge or heavy metals, improving treatment slopes or retaining walls, etc. Is being used.

The present invention has been proposed to solve the above problems, and introduces the concept of compensation basis as an alternative to problems that may occur when the foundation is applied as a pile, and also to determine the problem of inequality that occurs in the compensation basis and Soft ground structure using surface compensation layer and compensation base to improve the existing compensation base by reducing the occurrence of uneven settlement as much as possible by dispersing settlement stress by surface improvement process and inducing equal settlement within the allowable settlement range. Its purpose is to provide a foundation construction method.

In addition, it is also possible to shorten the construction time and construction period and reduce the construction cost by constructing the surface improvement material suitable for the optimal solidification time (2 to 3 hours) according to the construction of the surface improvement layer.

In addition, there is also an object to compensate for the disadvantages of the existing compensation basis by applying a surface solidification treatment to secure the support force to the compensation base support layer and to distribute the concentration of stress to induce equal settlement within the allowable settlement range.

And in the case of soft ground, problems of the ground when installing buildings and structures are largely divided into bearing capacity and settlement, and bearing capacity has the purpose of solving ground problems with the principle of surface improvement and settlement compensation.

In order to achieve the above object, the construction method of the soft ground structure and its foundation using the compensation foundation and the surface improvement layer according to the present invention comprises the steps of: analyzing the ground of the soft ground on which the building or the structure is to be built; Excavating soil corresponding to twice the weight of the building or structure; Compacting the soil of the excavated portion; Filling the excavated soil in the excavated portion to have an excavated state of soil corresponding to one times the weight of the building or structure; After calculating the allowable bearing capacity of the soft ground, examining whether the calculated allowable bearing capacity can support the design load q _n of the building or structure; Mixing the surface-improving material with the soil of the excavated portion to solidify to form a surface-improving layer; Calculating an expected settlement amount by the construction of the building or structure to increase the depth of the surface improvement layer by 1.2 to 1.5 times with respect to the portion where the settlement is expected to be more than the allowable settlement amount; Determine the design load q _n = P-σ _Z ≒ 0 so that the weight of the excavated soil σ _Z = γ (base area) · h (height of the complementary sheath) is equal to the load P of the building or structure, and the compensation basis Designing a base area γ such that the height h is less than 1.5 m; Placing concrete according to the basis area γ and height h (1.5 m or less) of the compensation basis determined in the step to form a compensation basis; Placing concrete on the compensating foundation to form a foundation and a bottom layer, and building a structure or structure thereon; Constituents of the surface improving material, SiO ₂ 15-30 parts by weight, CaO 45-60 parts by weight, Al ₂ O ₃ 5-10 parts by weight, SO ₃ 0-10 parts by weight, MgO 1-5 parts by weight, Fe ₂ O ₃ 1~5 weight that can be achieved is by, including _{TiO 2, K 2 O, Na} 2 O, P 2 O 5, B 2 O 3, BaO, MnO, ZnO any one or more further include a It features.

At this time, the allowable bearing capacity of the soft ground is calculated by the formula Terazaghi bearing capacity (q _ult ), by the following equation (1)

Permissible bearing capacity (q _a ) = ultimate bearing capacity (q _ult ) / 3 + removal load (P) ... (1) It is characterized by calculating.

And the estimated settlement amount by building of the said building or structure is by following formula (2)

Settlement amount (S) = consolidation settling (load more than removal) + settling

+ Growth settlement (sedimentary soil, weathered soil) ... (2) It is characterized by calculating.

According to the present invention, in order to economically design the foundation of a building installed on the soft ground by using the principle of compensation, it is difficult to excavate as the foundation is deepened by designing the foundation area γ so that the height h of the foundation is smaller than 1.5 m. It is possible to solve the disadvantage of increasing the quantity of pouring and earthquake facilities, and increasing the amount of digging work, and to process the compaction and surface improvement material on the excavated excavation surface to reliably prevent the uneven settlement occurring after the construction of the building. .

In addition, the present invention, by using the surface-improving material is added to each component at the optimum ratio, the initial solidification time and the initial condensation time for forming the surface-improving layer is shortened to facilitate the optimal solidification time (2 ~ 3 hours), the construction time can be shortened, thereby reducing the construction cost, and at the same time, the production cost of the surface-improved material can be lowered, resulting in further reduction in the construction cost.

1 is a conceptual diagram of a soft ground structure using a compensation basis according to the present invention
2 is a process diagram of the basic construction method of the soft ground building to compensate for the disadvantages of the compensation basis according to the present invention
Figure 3 is an application case of the soft ground structure to which the compensation basis according to the present invention is applied
Figure 4 is an application case of the stockpiling base construction work applying the compensation base and surface improvement treatment according to the present invention
5 is a plan view showing the installation position of the measuring instrument after applying the compensation basis and surface improvement process according to the present invention
6 is a graph showing the measurement results of the ground subsidence of the building foundation according to the present invention.
7 is a graph showing the displacement pile measurement results according to the present invention
8 is a graph showing the measurement results of the ground slope meter according to the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram of a soft ground structure using a compensation basis according to the present invention.

The soft ground structure 100 using the compensation base according to the present invention, compacting the soil of the excavated soft ground (G) and fill the excavated soil in the excavated portion, 0.5 to 2m in the excavated soft ground (G) A surface improvement layer (10) formed by mixing the soil and the surface improvement material of the soft ground to a depth; A compensation base 20 formed by pouring concrete on the surface improvement layer 10; A base and bottom layer 30 formed by pouring concrete on the compensating foundation 20; It is composed of a building or structure 40 that is built on the foundation and floor layer 30.

At this time, the surface improvement layer 10 is formed by mixing with the surface improvement material and the soil of the excavated ground. Cement-based, lime-based, urethane-based, acrylamide-based and the like have been reported as solidifying agents for improving the surface layer of soil.

In addition, the surface modifier is a cement-based solidifying agent, usually a pozzolanic agent (solidifies with clay minerals and reinforces the strength-expressing function of cement), surfactant (smooth solidification reaction with clay, organic soil), and Several catalysts etc. are mixed and used suitably.

In addition, the surface-improving material is based on the chemical reaction of the soil particles and inorganic reactive additives (hydrochemical minerals), fly ash (SiO ₂ , Al ₂ O ₃ ) is used as the main material reactive additives.

The surface layer improving agent of the present invention 15 to 30% by weight of SiO ₂ , 45 to 60% by weight of CaO, 5 to 10% by weight of Al ₂ O ₃ , 1 to 10% by weight of SO ₃ , 1 to 5% by weight of MgO, Fe ₂ O ₃ It comprises 1 to 5% by weight, comprising 4 to 8% by weight of any one or more of TiO ₂ , K ₂ O, Na ₂ O ,, P ₂ O ₅ , B ₂ O ₃ , BaO, MnO, ZnO It is characterized by.

The principle of surface improvement according to the present invention is that the hydration reaction and the pozzolanic reaction occur due to the proper mixing of the water and the surface improvement material of the field soil. When the surface-improving material according to the present invention is mixed with the soil in situ, the porous component absorbs moisture, organic matter, odor, etc., and then absorbs a large amount of aluminate lactic acid hydrate while absorbing moisture in the surroundings and soil particles during the hydration reaction. (Ettrinite, 3CaO · Al ₂ O ₃ · 3CaSO ₄ · 32H ₂ O) is formed to bind water and 32 molecules of water in the soil particles, constraining the movement of soil particles to strengthen the bond It will freeze between particles.

Ethrinzite, mixed with soil soil, reduces the water content of soil and densifies solids by forming needle crystallization to fill gaps, solidifies harmful heavy metals and organics by ion exchange and expansion, and simultaneously improves surface hydrate hydrate and granular minerals. The pozzolanic reaction takes place in between, producing lime silicate over a long period of time, thereby exhibiting the strength and durability of the ground.

The resulting ethrinzite reacts with the pozzolan component in the soil particles for a long time to maintain the long-term strength of the topsoil. The time required for the hydration reaction and the solidification is usually 1 to 2 hours for the initial reaction and 3 to 4 hours for the first condensation.

In the surface improvement material according to the present invention, the first condensation is completed after 2 to 3 hours after the mixing construction with the soil of the excavation surface, and stable strength is exerted, so that the foundation of the compensation 20 can be poured within a short time after the mixing construction. As curing of the compensation base 20 proceeds and a pozzolanic reaction occurs between the surface-improved hydrate of the surface-improved layer 10 and the particulate mineral, the silicate hydrate is produced over a long period of time, thereby enhancing the strength and durability of the ground. Therefore, even after the construction of the building or structure 40 can be prevented inequality.

At this time, the first condensation completion time is 2 to 3 hours, so if the first condensation is completed before 2 hours, there is no time for the surface improvement layer to be formed in the wide strata, so the work proceeds quickly. This is because it is difficult to form an accurate and uniform thickness of the surface improvement layer, and when the first condensation is completed after 3 hours, the construction time is delayed because the next construction cannot be progressed while waiting for condensation.

Therefore, when forming the surface improving layer using the surface improving material, the most suitable first setting time is 2 to 3 hours, which is a combined time based on the advice of those skilled in many construction sites, and by various experiments Emphasize that the result is obtained.

In order to provide the strength required for the stabilization of the soil, the surface improvement material according to the present invention, unlike conventional lime or cement system, which relies only on chemical reactions, the composition of the present invention is a pozzolanic reactant silicon dioxide (SiO ₂ ) and oxidation It contains a large amount of aluminum (Al ₂ O ₃ ) and also contains more sulfur trioxide (SO ₃ ), which is more effective in producing ethrinite in the hydration reaction than lime or cement. Thus, the stable strength of the ground can be maintained for a long time.

Therefore, the surface improvement material composition according to the present invention can stabilize the foundation of the building by mixing with the soil of the soft ground when building the construction on the soft ground, such as wetlands, ponds, rivers, coasts, reclaimed land and dredging landfill with high water content have.

On the other hand, there is a conventional surface modifier containing a large amount of SiO ₂ and CaO and Al ₂ O ₃ bar, the surface modifier of the present invention is different in weight ratio of the conventional surface modifier and the containing components and the effect thereof is also different .

The first example of the conventional surface layer improver comprises 30 to 50% by weight of SiO ₂ , 20 to 60% by weight of CaO, and 10 to 30% by weight of Al ₂ O ₃ .

The second example of the conventional surface layer improver comprises 20 to 40% by weight of SiO ₂ , 35 to 70% by weight of CaO, and 10 to 25% by weight of Al ₂ O ₃ .

Since the SiO ₂ is added at a ratio of up to 50% by weight in the first example and up to 40% by weight in the second example, the use of SiO ₂ in excess of the present invention has a problem of lengthening the solidification time.

That is, the SiO ₂ Since it is usually also blended with concrete to improve the fluidity and pumpability by improving the fluidity during the site-pouring of concrete, the solidification time becomes longer when a large amount is added to the surface improvement material.

At this time, the workability (workability) is an important property of the unsolidified concrete refers to a property showing the good and bad workability until the concrete is mixed and then transported and chopped.

And the pumpability (pumpability) is to represent the kneading of the concrete not hardened.

The first example of CaO contains at least 20% by weight, the second example contains at least 35% by weight, and the use amount is less than that of the present invention, so the initial hydration reaction is relatively long. The first and second examples have a problem in that the hydration reaction is delayed due to the use of very little CaO, so that the initial reaction and the first condensation time are long.

That is, the CaO is very reactive to water, and the surface-improving material according to the first and second examples according to the first and second examples having a small amount of addition should be reacted with water in the soil quickly and condensed. You lose.

The first example of Al ₂ O ₃ includes up to 30% by weight, and the second example includes up to 25% by weight. The Al ₂ O ₃ is expensive finite mineral resources, there is a problem of rising construction cost, waste energy. In the present invention, the maximum ratio of Al ₂ O ₃ is 10% by weight, thereby lowering the construction cost and saving energy.

Therefore, the surface modifier used in the present invention is the result of repeated studies to solve the problems derived from the surface modifier according to the first and second examples of the prior art, and completely solve the conventional problems. It has an optimum addition ratio that can be solved.

That is, in the present invention, by adding SiO ₂ to up to 30 parts by weight, CaO to at least 45 parts by weight, and Al ₂ O ₃ to up to 10 parts by weight, the initial reaction and the first condensation time is shortened We succeeded in obtaining the optimal solidification time (2 ~ 3 hours), which is easy for construction.As a result, construction time can be shortened and construction cost can be reduced, and production cost of surface-improved materials can be lowered. will be.

In addition, since the surface-improving material of the present invention is composed of the optimum addition ratio, it is possible to mass-produce high-quality surface-improving material according to the optimum addition ratio which can obtain the optimum workability, and to provide a low price and ease of construction. It can be increased.

After the surface improvement layer 10 is formed by using the surface improvement material according to the present invention, the construction site or the structure 40 is excavated in order to form the compensation foundation 20, and the weight of the excavated soil σ _The design load q _n = P−σ _Z ≒ 0 is determined so that _Z = γ (base area) · h (height of the compensation base) is equal to the load P of the building or structure 40.

However, if the height h of the compensation base 20 is deeper than 1.5m, it is difficult to excavate, the amount of pouring and the clogging facilities are increased, and the amount of digging work increases, so that the height h of the compensation base 20 is smaller than 1.5m. Design.

The ultimate bearing capacity (q _ult ) is calculated by the Terazaghi bearing capacity formula, the allowable bearing capacity of the soft ground is calculated by the following equation (1), and the calculated allowable bearing capacity is the design load q of the building or structure 40. Design to support _n .

Allowable load capacity (q _a ) = ultimate load capacity (q _ult ) / 3 + removal load (P) ...... (1)

Allowable bearing capacity (q _a )> design load (q _n )

After construction of the building or structure 40, the estimated settlement is calculated by the following equation (2) to select the zone where settlement occurs above the allowable settlement, and to minimize the differential settlement for the zone where settlement above the allowable settlement occurs. The depth of the surface improvement layer 10 is increased by 1.2 to 1.5 times.

Settlement amount (S) = consolidation settling (load more than removal) + settling

+ Growth settlement (sedimentary soil, weathered soil) ...... (2)

Figure 2 is a process diagram of the basic construction method of the soft ground building to compensate for the disadvantages of the compensation basis according to the present invention.

In step S1, the ground layer of the soft ground G on which the building or the structure 40 is to be built is analyzed through drilling.

In step S2, the soil corresponding to twice the weight of the building or structure 40 is excavated.

In step S3, the soil of the excavated portion is compacted. At this time, in the compaction of the soil, according to the form of the ground must be made of various methods of course.

In other words, the viscosity, sand, and organic soil are determined by the Sand Compaction Pile method, and the sandy soil is determined by one of the Vibroflotation method, the Vivro tamper method, and the dynamic consolidation method, and the clay, sandy soil is the crushed pile method. Make a commitment. However, this is only an example and can be determined by various methods depending on the soil of the ground.

When the soil of the excavated portion is compacted as described above, settlement is reduced, liquefaction is prevented, and activity destruction is prevented. In other words, the soil becomes harder and stronger.

In step S4, the excavated portion is filled with the excavated soil in the excavated portion to have a state in which the soil corresponding to one times the weight of the building or structure 40 is excavated.

In this case, the reason for filling the soil on the top of the compacted soil is to form the surface improvement layer 10 by mixing the surface improvement material in the filled soil, and the excavated soil to form the surface improvement layer 10. This is because the weight of the building or the structure 40 to be equal to the weight.

Therefore, in order to form the compacted and surface-improved layer 10, in step S2 is excavated soil twice the weight of the building or structure 40, in step S3 is the excavated soil, and in step S4 The excavated portion is to fill the excavated soil in the excavated portion so that one times the weight of the building or structure 40 is excavated.

Due to the compaction and surface improvement layer 10 formed on the ground as described above, settlement and liquefaction and activity destruction are further prevented, so that the safety of the building or structure 4 can be maintained for a long time.

In step S5, the ultimate bearing capacity is calculated by the Terazaghi bearing capacity formula, the allowable bearing capacity of the soft ground is calculated by the following equation (1), and the calculated allowable bearing force is the design load q of the building or structure 40. Examine whether _n can be supported.

Terazaghi bearing formula (extreme bearing capacity):

Ultimate bearing capacity (q _ult ) = cN _c + o.5γ ₁ BN _r + qN _q

Where c is the undrained shear strength (kN / m 2), and q is the effective skin pressure (kN / m 2 = γ'D ₁ ).

N _{c ,} N _{r ,} N _q : Terazaghi Modified Bearing Factor

Allowable load capacity (q _a ) = ultimate load capacity (q _ult ) / 3 + removal load (P) ...... (1)

Allowable bearing capacity (q _a )> design load (q _n )

In step S6, the soil corresponding to the weight of the building or structure 40 is excavated and excavated, and then the surface-improved layer 10 is solidified by mixing the surface-improved material in the soil having a depth of 0.5 to 2 m from the surface of the excavated portion. Form.

In step S7, the depth of the surface improvement layer 10 in order to minimize the differential settlement for the portion expected to sink more than the allowable settlement amount by calculating the estimated settlement amount by the construction of the building or structure 40 by the following equation (2). Increase 1.2 to 1.5 times.

Settlement amount (S) = consolidation settling (load more than removal) + settling

         + Growth settlement (sedimentary soil, weathered soil) ...... (2)

In step S8, the design load q _n = P-σ _Z ≒ 0 is set such that the weight of the excavated soil σ _Z = γ (base area) · h (the height of the compensator sheath) is equal to the load P of the building or structure 40. Decide

However, when the height h of the compensation base 20 is deeper than 1.5m, it is difficult to excavate, and the height of the compensation base 20 is smaller than 1.5m because the amount of pouring and the clogging facilities are increased and the amount of digging work is increased. The basic area γ is designed so that

In step S9, concrete is poured according to the base area γ and height h (1.5 m or less) of the compensation base 20 determined in step S5 to form the compensation base 20.

In step S10, concrete is placed on the compensating foundation 20 to form a foundation and a bottom layer 30, and a building or structure 40 is built thereon.

4 shows an application example of the construction of a soft ground stockpiling base applying the compensation foundation and the surface improvement treatment according to the present invention.

The site to which the present invention is applied is a stockpiling base located near the port, and the soft ground treatment through pre-loading is completed, and it appears to be a stable area in case of sinking and working load, but it satisfies the bearing capacity of mobile equipment and unloading equipment during the movement of stockpiles. The site was used to secure support through compaction and surface improvement.

5 is a plan view showing a measuring instrument installation position after applying the compensation basis and the surface layer improver according to the present invention.

In the case of the application site, the depth of the soft layer is distributed up to 40m, so pre-loading was carried out, but the second consolidation settlement is expected to occur more than 1.4m. It is a site that drastically shortened construction cost and air by using soft ground building foundation that combines surface improvement treatment.

After applying the compensation base and compaction and surface improvement treatment according to the present invention, as shown in Figure 5, the groundwater level, ground slope, displacement pile and ground sedimentation result, measured, until the completion of September 2011 until about 18 Soil sediment and underground slope system of the Busan Procurement Service stocks were observed for months. So far, ground level displacements of 8.7 for building foundations and -6.31 ~ 6.13 for underground slope systems have occurred.

Looking at the graph of the displacement and time of the representative measuring instrument for each position as shown in Figures 6 to 8, when viewed in the graph it is determined that the ground state is stable because the displacement converges to a certain value.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

10: Surface Improvement Layer 20: Compensation Foundation
30: foundation and floor 40: building or structure

Claims (3)

Analyzing the strata of the soft ground (G) on which the building or structure 40 is to be built through drilling;
Excavating soil corresponding to twice the weight of the building or structure 40;
Compacting the soil of the excavated portion;
Filling the excavated soil in the excavated portion to have an excavated state of the soil corresponding to one times the weight of the building or structure 40;
After calculating the allowable bearing capacity of the soft ground (G), examining whether the calculated allowable bearing capacity can support the design load q _n of the building or structure (40);
Mixing the surface-improving material with the soil of the excavated portion to solidify the surface-improving layer (10);
Calculating an expected settlement amount by the construction of the building or structure 40 to increase the depth of the surface improvement layer 10 by 1.2 to 1.5 times with respect to the portion where the settlement is expected to be more than the allowable settlement amount;
Determine the design load q _n = P-σ _Z ≒ 0 such that the weight of the excavated soil σ _Z = γ (base area) · h (height of the complementary sheath) is equal to the load P of the building or structure 40, Designing a base area γ such that the height h of the compensation basis 20 is less than 1.5 m;
Placing concrete according to the foundation area γ and the height h (1.5 m or less) of the compensation basis 20 determined in the step to form a compensation basis 20;
Placing concrete on the compensating foundation (20) to form a foundation and a bottom layer (30), and building a structure or structure (40) thereon; Respectively,
The surface modifier is SiO ₂ 15-30% by weight, CaO 45-60% by weight, Al ₂ O ₃ 5-10% by weight, SO ₃ 1-10% by weight, MgO 1-5% by weight, Fe ₂ O ₃ 1 It is made up to include -5% by weight, containing 4 to 8% by weight of any one or more of TiO ₂ , K ₂ O, Na ₂ O ,, P ₂ O ₅ , B ₂ O ₃ , BaO, MnO, ZnO A method of constructing a soft ground structure and its foundation using the compensating foundation and the surface improvement layer. The method of claim 1,
Permissible bearing capacity of the soft ground (G),
The ultimate bearing capacity (q _ult ) is calculated by Terazaghi bearing capacity formula, and the following equation (1)
Allowable load capacity (q _a ) = ultimate load capacity (q _ult ) / 3 + removal load (P) ...... (1)
A method of constructing a soft ground structure and its foundation using a compensation basis and a surface-improved layer characterized in that it is calculated.
3. The method according to claim 1 or 2,
Expected settlement amount by the construction of the building or structure 40,
By the following equation (2)
Settlement amount (S) = consolidation settling (load more than removal) + settling
+ Growth settlement (sedimentary soil, weathered soil) ...... (2)
A method of constructing a soft ground structure and its foundation using a compensation basis and a surface-improved layer characterized in that it is calculated.

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