RU2249082C1 - Method for erecting shallow and surface foundations in thawed ground located above underlying permafrost or rock grounds - Google Patents

Abstract

FIELD: foundation building, particularly for all-purpose buildings and structures, electric power lines and outer service lines in continuous or discontinuous permafrost conditions on all types of thawed ground except water-saturated grounds, seasonally thawing and freezing ground with 3 - 9 m depth located above permafrost or rock underplaying ground.

SUBSTANCE: method involves ramming foundation pit in seasonally thawing and freezing ground layer with forming compacted area around foundation pit and under it; building foundation unit in foundation pit. Foundation pit ramming is performed in thawed ground before freezing thereof. Compacted area is formed as solidified ground column supported by permafrost or rock grounds. Foundation pit is rammed up to bulging ground out of pit in upward direction, which indicates that solidified ground column rests upon permafrost or rock ground. After that thawed ground ramming is stopped and foundation unit is built in foundation pit so that foundation unit is supported by solidified ground column.

EFFECT: increased reliability of foundation base, reduced power and labor inputs, improved load-bearing capacity of thawed ground, prevention of foundation settlement during ground thawing and heaving thereof during foundation base freezing.

10 cl, 6 dwg

Description

The invention relates to construction and is intended for the construction of shallow and surface, precast and monolithic reinforced concrete, metal and wood, columnar, strip and slab foundations of residential, public, industrial, auxiliary buildings and agricultural buildings, as well as linear structures: power lines and external engineering communications, with non-merging and merging permafrost on all types of thawed soils, except for water-saturated, a layer of seasonal thawing and frost penetration a 9 m, underlain by permafrost or rocky soils.

Depending on the geocryological and soil conditions, as well as on the purpose of the structures, foundations based on a thawing foundation are of various designs. With dense lower underlying soils, including rocky soils, depending on the thickness of the upper layers of the soil and the strength of the base, columnar foundations with shoes and base plates, rack piles, frame frames, cross reinforced concrete tapes and solid reinforced concrete slabs are used. With the proper strength of the foundation soils, if they lie at a shallow depth (up to 4 m), single columnar foundations are permissible, in which case they should be connected on top by random beams that are part of the building’s overhead frame structure. With a deep occurrence of soils, taken as the basis, it is necessary to use pile piles. In those cases when the foundation soils lie at shallow depths, have insufficient bearing capacity and single foundations cannot be used, foundations from cross reinforced concrete tapes or frame foundations are used. With limited outlines of the structure in the plan, as well as with the construction of foundations for equipment, continuous reinforced concrete slabs can be used [1, p. 139].

In the construction of the abovementioned foundations for the preparation of pits for them, various rather laborious and uneconomical methods of developing frozen soils are used, which also require special machinery and equipment [2], or methods of piling on permafrost soils, which are also very laborious and expensive [3].

The least time-consuming and most economical are the methods of building foundations in rammed pits [4], which are practically not used in the conditions of thawed soils of the seasonal thawing and freezing layer.

The closest analogue of the proposed method in terms of technical nature and the achieved result is a method of erecting foundations in winter conditions, which can be used for erecting shallow and surface foundations in a layer of thawed soils, underlain by permafrost and rocky soils [5].

This known method includes tamping the pit in a layer of seasonal thawing and freezing with the formation of a compacted zone in the melt soils around the pit and under it and constructing a foundation block in the tamped pit.

The disadvantages of this known method are that it is carried out in winter conditions and at the same time they crush the upper frozen soil and move it in fragmented form to the lower thawed soil, which is a time-consuming operation, leads to excessive energy consumption for creating a compacted zone and, moreover, reduces the quality of compaction of the soil due to the subsequent thawing of particles of crushed frozen soil embedded in the compacted thawed soil.

The objective of the present invention is to provide the possibility of creating a reliable foundation for shallow and surface foundations in a layer of melt soils, underlain by permafrost and rocky soils, with the lowest energy and labor costs, increase the bearing capacity of melt soils of the layer of seasonal thawing and freezing, eliminating sediment during thawing and heaving during freezing of the bases of the named foundations.

The solution of this problem is achieved by the fact that in the method of erecting shallow and surface foundations in a layer of thawed soils, underlain by permafrost or rocky soils, including tamping the foundation pit in the layer of seasonal thawing and freezing with the formation in the thawed soils around the pit and underneath of it a compacted zone and construction in the rams foundation foundation pit, according to the invention, tamping of the pit is carried out before seasonal thawing and freezing layer is frozen in thawed soils and, when tamping the pit, the compacted zone around it and under it is created in the form of a compacted soil pillar, resting on the underlying permafrost or rocky soils, while tamping the pit is carried out until the soil extends upward, indicating the support of the compacted soil column formed under the pit on underlying permafrost or rocky soils, after which the compaction of thawed soils of the seasonal thawing and freezing layer is stopped and a foundation is built in the rammed foundation pit entny unit, based on the generated compacted compactor post.

In special cases, the implementation of the proposed method:

- during the formation of a compacted zone in loose melt soils around the foundation pit and under it, a layer of seasonal thawing and freezing, for example, dusty and fine sands, sandy loams and loams, to further increase their bearing capacity, create an expanded base of the foundation block by tamping into the named loose melt soils surrounding foundation pit, non-porous hard ground material, such as coarse sand, or gravel, or gravel;

- the required volume V of the layer of seasonal thawing and freezing of non-porous hard ground material, which is compacted into loose melt soils, is determined by the dependence:

where Δ S - sediment compaction, m;

ρ _d - soil density in the natural occurrence in the dry state, t / m ³ ;

ρ _ds - soil density after compaction in the dry state, t / m ³

- the broadened base of the foundation block is created by ramming into the lower part of the rammed foundation pit in separate portions of non-porous hard ground material;

- around the foundation block constructed in a rammed foundation pit at the level of the natural surface of thawed soils, a layer of seasonal thawing and freezing over the sealed area is laid on the surface of the heat shield;

- the area A _{te of the} surface heat shield is determined by empirical dependence:

where H _about - the depth of seasonal thawing, m;

H _th - the permissible depth of thawing under the foundation block from the condition that its draft does not exceed the maximum allowable, m;

R _te - heat transfer resistance of the surface heat shield, m ² ° C / W;

K ₁ and K ₂ are empirical coefficients:

K ₁ = 0.015, 1 / m ² ;

K ₂ = 0.17, W / m ² ° C;

moreover, this dependence extends to surface heat shields having the following parameters:

4 m ² <A _te <20 m ² and 1 m ² ° C / W <R _te <5 m ² ° C / W;

- during the construction of shallow foundations before the construction of the foundation block in a rammed foundation pit, a buried heat shield is laid on the entire bottom surface of the latter, after which a foundation block is built in the foundation pit on top of the buried heat shield;

- when erecting shallow foundations, the pit cavity remaining after construction of the foundation block is filled with non-porous hard soil material, for example coarse sand, or gravel, or crushed stone, with its layer-by-layer compaction to the level of the natural surface of thawed soils of the seasonal thawing and freezing layer, after which thawed soils are re-compacted a layer of seasonal thawing and freezing around the pit above the compacted zone;

- during the construction of surface foundations before the construction of the foundation block, the cavity of the rammed foundation pit is filled with non-porous hard ground material, for example coarse sand, or gravel, or crushed stone, with its layer-by-layer compaction, after which thawed soils of the thawing layer are thawed and frozen around the pit above the compacted zone and a foundation block is built on top of a compacted non-porous hard soil material on the filling pit;

- during the construction of surface foundations before the construction of the foundation block, the lower and middle parts of the cavity of the rammed foundation pit are filled with non-porous hard ground material, for example coarse sand, or gravel, or crushed stone, with its layer-by-layer compaction, and melt compaction of the layer of seasonal thawing and freezing around the foundation pit is made above the sealed area, and then in the upper part of the cavity of the rammed foundation pit left with the necessary depth to the entire surface of the sealed nepuchin of the hard soil material is placed flush thermal shield, an upper surface which is flush with the surface of the melted natural soil layer seasonal freezing and thawing, and stacked on top of the heat shield construct submerged foundation block.

The invention is illustrated by drawings, where Fig. 1 shows a shallow foundation in a foundation pit stamped in a layer of thawed soil; figure 2 is the same with a surface and recessed heat shields; figure 3 is the same with the broadened base of the foundation block of tamped non-porous hard ground material; figure 4 - surface foundation with a surface heat shield, figure 5 - surface foundation with a surface and recessed heat shield; in Fig.6 is a top view of the surface foundations shown in Fig.4 and 5.

The proposed method for the construction of shallow and surface foundations in a layer of thawed soils, underlain by permafrost or rocky soils, is as follows.

The main operations of the proposed method are tamping the pit 1 in layer 2 of seasonal thawing and freezing with the formation in the melt soils around the pit 1 and underneath it of a compacted zone 3 and constructing the foundation block 4 in the tamped pit 1 before tamping the layer 1 before freezing occurs. 2 seasonal thawing and freezing, and when tamping the pit 1, the compacted zone 3 around it and underneath it is created in the form of a compacted soil column resting on the underlying echnomerzlye rocky soils or 5 (see FIG. 1).

In the process of tamping the pits in sandy soils, a soil outburst is usually observed, and after tamping the pit to a depth of about 2 m, a digging failure occurs [4, p.25].

Studies have shown a feature of compaction of thawed soils of layer 2 of finite thickness, below which underlying undercompressible soils are located: permafrost or rocky soils 5, consisting in the fact that the number of tamper strokes, its weight and dumping height are determined by the resistance of permafrost or rocky soils 5 to shock loads. Experimental tamping showed that compaction of thawed soils of layer 2 of final thickness does not occur to failure; with a larger number of strokes, brittle destruction of the underlying incompressible soil occurs, i.e. permafrost or rocky soil 5.

Therefore, in the proposed method, the tamping of the pit 1 is carried out until the soil is upward, indicating the support of the compacted soil column formed under the pit 1 on the underlying permafrost or rocky soils 5, after which the compaction of thawed soils of the seasonal thawing and freezing layer 2 is stopped in the rammed pit 1 build the foundation block 4, based on the created compacted soil pillar.

In the process of formation around the pit 1 and under it of compacted zone 3 in loose melt soils, layer 2 of seasonal thawing and freezing, for example, dusty and fine sands, sandy loams and loams, to further increase their bearing capacity create a broadened base 6 of the foundation block 4 by tamping into the named loose thawed soils surrounding the pit 1, non-porous hard soil material 7, such as coarse sand, or gravel, or crushed stone (see figure 3).

The required volume V of the layer 2 of seasonal defrosting and freezing of non-porous hard soil material 7, which is compacted into loose melt soils, is determined by the dependence:

where Δ S - sediment compaction, m;

ρ _d - soil density in the natural occurrence in the dry state, t / m ³ ;

ρ _ds - soil density after compaction in the dry state, t / m ³ .

The broadened base 6 of the foundation block 4 is created by ramming into the lower part of the rammed foundation pit 1 in separate portions of non-porous hard ground material 7.

Around the foundation block 4 constructed in rammed foundation pit 1 at the level of the natural surface of thawed soils, a layer 2 of seasonal thawing and freezing over the sealed zone 3 is laid on a surface heat shield 8 (see FIGS. 2-6).

The area A _{te of the} surface heat shield 8 is determined by empirical dependence:

where H ₀ - the depth of seasonal thawing, m;

H _th - the permissible depth of thawing under the foundation block from the condition that its draft does not exceed the maximum allowable, m;

R _te - heat transfer resistance of the surface heat shield, m ² ° C / W;

K ₁ and K ₂ are empirical coefficients:

K ₁ = 0.015, 1 / m ² ;

K ₂ = 0.17, W / m2 ° C;

moreover, this dependence extends to surface heat shields having the following parameters:

4m ² <A _te <20m ² and 1m ² ° C / W <R _te <5m ² ° C / W.

In some cases, when erecting shallow foundations before the construction of the foundation block 4, in a rammed foundation pit 1, a recessed heat shield 9 is laid on the entire bottom surface of the latter, after which a foundation block 4 is constructed in the foundation pit 1 on top of the laid in buried heat shield 9 (see Fig. 2 and 3).

In the construction of shallow foundations, the cavity of the pit 1 remaining after the construction of the foundation block 4 is filled with non-porous hard ground material 7, for example coarse sand, or gravel, or crushed stone, with its layer-by-layer compaction to the level of the natural surface of thawed soils of layer 2 of seasonal thawing and freezing, after which they are produced the compaction of thawed soils of layer 2 of seasonal thawing and freezing around the pit 1 over the compacted zone 3 (see figures 1 and 2).

During the construction of surface foundations before the construction of the foundation block 4, the cavity of the rammed foundation pit 1 is filled with non-porous hard ground material 7, for example, coarse sand, or gravel, or crushed stone, with its layer-by-layer compaction, after which thawed soils of layer 2 of seasonal thawing and freezing around the foundation pit 1 are compacted a foundation block 4 is constructed above the sealed area 3 and from above on the filling excavation pit 1 compacted non-porous hard soil material 7 (see FIG. 4).

During the construction of surface foundations, in some cases, before the construction of the foundation block 4, the lower and middle parts of the cavity of the rammed foundation pit 1 are filled with non-porous hard soil material 7, for example, coarse sand, or gravel, or crushed stone, with its layer-by-layer compaction and compaction of thawed soil of layer 2 seasonal thawing and freezing around the pit 1 over the compacted zone 3, after which, in the upper part of the cavity of the rammed pit left with the necessary depth, the entire surface A densified non-porous hard ground material 7 is laid with a buried heat shield 9, the upper surface of which is flush with the natural surface of thawed soils of seasonal defrosting and freezing layer 2, and a foundation block 4 is built on top of the laid buried heat shield 9 (see Fig. 5).

The compacted zones created by this method in the form of compacted soil pillars, resting on underlying permafrost or rocky soils, are a reliable basis for shallow and surface foundations in a layer of melt soils, which takes up loads in the first years of operation of the structure until the melt zone completely freezes under the influence of cooling devices (ventilated underground, seasonally operating devices, etc.). At the same time, in-depth heat shields prevent heat from penetrating through the foundation structure into these compacted zones, and surface heat shields prevent thawing of compacted zones and underlying permafrost in winter from the effects of positive temperatures of a heated building and in summer from positive outside temperatures.

References

1. Bondarev P.D., Ushkalov V.P. Features of design and construction of foundations in frozen soils. M ..: Stroyizdat, 1964.

2. Cherkashin V.A. Development of frozen soils. L .: Stroyizdat, 1977.

3. Goncharov Yu.M., Kim M.V., Targulyan Yu.O., Vartanov S.Kh. Piling works on permafrost soils. M .: Stroyizdat, 1971.

4. Krugov V.I., Bagdasarov Yu.A., Rabinovich I.G. Foundations in rammed pits. M .: Stroyizdat, 1985.

5. Patent No. 2043461, IPC E 02 D 7/26, 27/35, published September 10, 1995.

6. Krugov V.I., Avazov P.P., Rafalzuk V.L. The construction of foundations in rammed pits in sandy soils. The journal “Construction and Architecture of Uzbekistan”, 1981, No. 2, pp. 5-9.

Claims (10)

1. A method of erecting shallow and surface foundations in a layer of thawed soils underlain by permafrost or rocky soils, including tamping the foundation pit in the layer of seasonal thawing and freezing with the formation of a compacted zone in the thawed soils around the pit and underneath it and constructing a foundation block in the rammed pit, characterized in that the tamping of the pit is carried out before the beginning of freezing in thawed soils of the seasonal thawing and freezing layer, and when tamping the pit, the area around it and below it is created in the form of a compacted soil column, resting on underlying permafrost or rocky soils, with the tamping of the pit being up to the soil upward, indicating the support of the compacted soil column formed under the foundation pit on the underlying permafrost or rocky soils, after which the thawing of thawed soils of the seasonal thawing and freezing layer is stopped and a foundation block is built in the rammed foundation pit, based on the compacted g untovy post. 2. The method according to claim 1, characterized in that during the formation of a densified zone around the foundation pit and underneath it in loose melt soils, a layer of seasonal thawing and freezing, for example, dusty and fine sands, sandy loam and loam, to create a broader bearing capacity the foundation of the foundation block by ramming into the aforementioned loose melt soils surrounding the pit, non-porous hard ground material, such as coarse sand, or gravel, or gravel. 3. The method according to claim 2, characterized in that the required volume V of the layer of seasonal thawing and freezing of the non-porous hard soil material rammed into loose melt soils is determined by the dependence

where ΔS - sediment compaction, m; ρ _d - soil density in the natural occurrence in the dry state, t / m ³ ; ρ _ds - soil density after compaction in the dry state, t / m ³ . 4. The method according to claim 2 or 3, characterized in that the broadened base of the foundation block is created by ramming into the lower part of the rammed foundation pit in separate portions of non-porous hard ground material. 5. The method according to any one of claims 1 to 4, characterized in that a surface heat-shielding screen is laid around the foundation block constructed in a rammed foundation pit at the level of the natural surface of thawed soils, a layer of seasonal thawing and freezing over the sealed area. 6. The method according to claim 3, characterized in that the area A _{te of the} surface heat shield is determined by empirical dependence

where H ₀ - the depth of seasonal thawing, m; H _th - the permissible depth of thawing under the foundation block from the condition that its draft does not exceed the maximum allowable, m; R _te - heat transfer resistance of the surface heat shield, m ² ° C / W; K ₁ and K ₂ are empirical coefficients: K ₁ = 0.015.1 / m ² ; K ₂ = 0.17 W / m ² ° C; moreover, this dependence extends to surface heat shields having the following parameters: 4 m ² <A _te <20 m ² and 1 m ² ° C / W <R _te <5 m ² ° C / W. 7. The method according to any one of claims 1 to 6, characterized in that when erecting shallow foundations before constructing the foundation block in a rammed foundation pit, a recessed heat shield is laid on the entire bottom surface of the latter, and then a foundation block is built in the foundation pit on top of the laid in recessed heat shield. . 8. The method according to any one of claims 1 to 7, characterized in that when erecting shallow foundations, the pit cavity remaining after construction of the foundation block is filled with non-porous hard ground material, for example coarse sand, or gravel, or crushed stone, with its layer-by-layer compaction to the level of natural the surface of thawed soils of the seasonal thawing and freezing layer, after which the thawed soils of the layer of seasonal thawing and freezing around the excavation over the compacted zone are compacted. 9. The method according to any one of claims 1 to 6, characterized in that when the surface foundations are erected before the foundation block is constructed, the cavity of the rammed foundation pit is filled with non-porous hard ground material, for example coarse sand, or gravel, or crushed stone, with its layer-by-layer compaction, after which make thawed soils of the layer of seasonal thawing and freezing around the foundation pit above the compacted area and on top of the foundation pit, compacted with non-porous hard ground material, build a foundation block . 10. The method according to any one of claims 1 to 6, characterized in that when the surface foundations are erected before the foundation block is built, the lower and middle parts of the cavity of the rammed foundation pit are filled with non-porous hard ground material, such as coarse sand, or gravel, or crushed stone, with by layer-by-layer compaction, and melt compaction of the layer of seasonal thawing and freezing around the foundation pit above the compacted zone is performed, and then in the upper part of the cavity of the rammed boiler left with the necessary depth On the entire surface of the compacted non-porous hard ground material, a buried heat shield is laid, the upper surface of which is flush with the natural surface of thawed soils of the seasonal thawing and freezing layer, and a foundation block is built on top of the laid buried heat shield.

Images