RU2360063C1 - Embankment on frozen soil - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: embankment on frozen soil includes base with placed thereon technological layers of soil, divided by width with soil longitudinal lines. According to the invention, in the base of the embankment there are cross slots filled up with frost-free material. Top of the base is covered with waterproofing material, with placed thereon heat insulation layer in the shape of non-isosceles triangle with the corner offset towards the lateral side of the embankment in the direction of solar radiation; heat insulating layer is covered with waterproof casing with arranged there at the width of the embankment longitudinal soil lines, whereat along the lateral slopes of the internal soil line there are placed filtrating cloths meeting with lower part of waterproof casing and separating it from lateral soil longitudinal lines.

EFFECT: prevention of water saturation and soil fluidisation at ice thawing, during its operation, securing enhanced strength of earth bed due to reinforcement of its separate zones.

6 cl, 2 dwg

Description

The present invention relates to the field of construction and can be used in the construction of oil and gas and transport facilities on frozen soils in both summer and winter season.

It is known subgrade in swamps, including a mound formed on frozen soils, sprinkled on the base with a heat-insulating layer made with a slope from the axis of the mound to its edges. (SU 578392, CL E01C 3/06, 1977).

A disadvantage of the known technical solution is that thawed free water at variable loads penetrates the structure of the insulating layer and the embankment, liquefying it and worsening the thermal protection of the frozen base, which generally reduces the stability of the subgrade.

The closest technical solution is an embankment erected on frozen soils, consisting of a base on which technological soil layers are located, separated by longitudinal stripes in width (RU 2293814, class Е01С 3/04, 2007).

A disadvantage of the known technical solution is that the embankment during operation loses stability due to its liquefaction of waterlogged or high-icy soil during thawing, which reduces the stability of the roadbed.

When creating the present invention, the task was to develop the design of the embankment on frozen soils with increased stability of the subgrade.

The technical result is to prevent water saturation and liquefaction of the soil during thawing of ice during its operation, providing increased stability of the subgrade by strengthening certain areas of the body of the embankment.

The problem is achieved in that the embankment on frozen soil, including a base on which the technological soil layers are located, separated by width of longitudinal longitudinal strips, according to the invention, transverse slots are made in the base of the embankment, filled with non-porous material, the base is covered with a waterproof material on top of which a heat-insulating layer in the form of an isosceles triangle with a vertex shifted to the side of the embankment oriented in the direction of solar radiation, with erhu insulating layer is covered with a waterproof membrane, in which the width of the mound are longitudinal ground strip, wherein at the inner side slopes dirt strip stacked filter web contactee lower part with a watertight sheath and separating it from the ground side of the longitudinal strips. In this case, the transverse slots of the base are made with a step equal to the width of the embankment at its base. The top of the isosceles triangle of the insulating layer is shifted to the side by an amount equal to a quarter of the width of the base of the embankment, the angle at the base of the isosceles triangle, directed toward solar radiation, β ₁ = (0.4-0.5) α, and the opposite angle of the base of the triangle - β ₂ = (0.2-0.25) α, where α is the angle of repose of the embankment. Lateral soil longitudinal strips contain a mixture of high-icy soil and porous filler in a ratio of 3: 1, respectively. The upper technological layer contains drainage soil and is located above all longitudinal stripes of the embankment.

Cutting the transverse cracks in the base of the embankment, followed by backfilling with non-porous material, such as sand, allows, firstly, to effectively drain thawed water into the ditches, and secondly, it allows to further strengthen the base, which generally increases the stability of the embankment on the frozen base in the case of thawing it.

The filling of the soil along the longitudinal strips allows the use of various soil mixtures and materials for them, which makes it possible to combine the optimal structure of the embankment and thereby also increases its stability.

Laying on the slopes of the inner strip of filter sheets allows, firstly, to more efficiently remove excess thawed water, and secondly, to strengthen the body of the embankment, which also increases its stability.

In the process of thawing the embankment, free water will flow down the waterproof shell, as if on an inclined plane, into the drainage ditches. The lower waterproof material protects the heat-insulating layer from wetting during thawing of the base.

In those sections of the road that are exposed to intense solar radiation, and accordingly, where the largest thawing areas occur, the top of the heat-insulating layer is shifted by 0.25b towards the radiation source. In this case, the thawed water will drain more intensively along the steeper part of the insulating layer, preventing its stagnation and thinning of the embankment soil, since the angle β ₁ > β ₂ , which also increases the stability of the embankment in hazardous sections of the route.

The role of the porous filler of longitudinal soil strips is to absorb thawed water, thereby preventing the soil from thinning the embankment and increasing the structural strength of the embankment, which in general also leads to the strengthening of slopes and to an overall increase in the stability of the embankment. Such a device of the embankment erected on frozen soils increases its efficiency, stability and long-term operation.

The invention is illustrated by drawings, where Fig. 1 shows a structural diagram of an embankment erected on frozen ground; figure 2 is a side view.

The embankment on frozen soils consists of a frozen base 1, along which drainage ditches 2 are cut, connected by transverse slots 3 formed in the base 1 and filled with non-porous material (for example, sand). The step between the slots 3 is equal to the width of the embankment at its base 1. On the base 1, a waterproof material 4 is laid on top, on which a heat-insulating layer 5 is located in the form of an isosceles triangle with a vertex shifted to the side of the embankment oriented in the direction of solar radiation 6 by the amount equal to a quarter of the width of the base 1 of the embankment, while the angle of the base of the non-isosceles triangle β ₁ = (0.4-0.5) α closest to the solar radiation 6, and the far angle β ₂ = (0.2-0.25) α, where α is the angle of repose of the embankment. The heat-insulating layer 5 on top is covered with a waterproof shell 7, for example, from DORNIT geotextile, on which longitudinal soil strips are scoured - side strips 8 from a mixture of substandard high-icy soil (for example, sandy loam, loam) and porous filler 9 in a ratio of 3: 1, respectively, and internal a strip 10 of substandard high-icy soil with filtering cloths laid on its slopes 11. The webs 11 are in contact with the waterproof shell 7 of the heat-insulating layer 5 from below. At the top of the strip is the inner 10 and side New 8 are covered with the upper technological layer 12 of drainage soil.

The construction of the embankment on frozen soil is as follows.

Clear the surface of the base 1 of the route of the future embankment. The drainage ditches are arranged 2. Cut in the base 1 across the route between the drainage ditches 2 slots 3 with a step equal to the width of the embankment at its base, and fill them with non-porous material, such as sand. On the base 1, a waterproof material 4 is spread, on which a heat-insulating layer 5, for example peat, is laid in the form of an isosceles triangle with a slope to its edges. Next, the heat-insulating layer 5 is covered with a waterproof sheath 7. The inner strip 10 is poured from substandard high-icy soil, after which the slopes of the strip 10 are covered with filtering webs 11. The side strips 8 are poured from a previously prepared mixture of high-poured soil and porous material 9, for example, expanded clay gravel, pumice and others, in a ratio of 3: 1, respectively. Next, the upper technological layer 12 is poured from the draining soil, which is distributed over all longitudinal stripes of the embankment 8 and 10.

The design of the embankment on frozen soils was modeled in the construction laboratory of the PSK department and showed the possibility of its implementation in real construction conditions.

Claims (6)

1. An embankment on frozen ground, including a base on which technological soil layers are located, separated by longitudinal longitudinal stripes in width, characterized in that transverse slots are made in the base of the embankment, filled with non-porous material, the base is covered with a waterproof material on top of which a heat-insulating layer is located in the form of an isosceles triangle with a vertex shifted to the lateral side of the embankment, oriented toward solar radiation, from above the insulating layer is covered in a watertight shell, on which longitudinal soil strips are located along the width of the embankment, while filtering cloths are laid along the side slopes of the inner soil band, which are in contact with the waterproof part of the lower part and separate it from the side longitudinal earth bands. 2. The embankment according to claim 1, characterized in that the transverse slots of the base are made in increments equal to the width of the embankment at its base. 3. The embankment according to claim 1, characterized in that the apex of the isosceles triangle of the insulating layer is shifted to the side by an amount equal to a quarter of the width of the base of the embankment. 4. The embankment according to claim 1, characterized in that the angle at the base of the isosceles triangle directed towards solar radiation β ₁ = (0.4-0.5) α, and the opposite corner of the base of the triangle β ₂ = (0.2 -0.25) α, where α is the angle of repose of the embankment. 5. The mound according to claim 1, characterized in that the lateral soil longitudinal strips contain a mixture of high-icy soil and porous filler in a ratio of 3: 1, respectively. 6. The embankment according to claim 1, characterized in that the upper technological layer contains drainage soil and is located above all longitudinal stripes of the embankment.

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