RU2556646C1 - Method to prevent deformations of linear structures erected on landslide slopes or manmade slopes on melting permafrost soils - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: method to prevent deformations of linear structures, erected on landslide slopes or manmade slopes on melting permafrost soils, includes erection of a working site, installation of piles into slope soil, combination of piles into a single grill. After submersion of piles into soil at the free end of each pile they install a reinforced concrete head, and combination of piles into a single grill is carried out by installation of a vertical geogrid, stiffly connected to heads of piles and layers of horizontal geogrids arranged above heads of piles. The working site from the bottom of the pile heads to the first layer of the horizontal geogrid and also gaps between layers of geogrids are filled with crushed stone and compacted. Horizontal geogrids are installed with the condition of their partial arrangement in a non-moving massif of the slope soil or natural slope.

EFFECT: prevention of deformations of motor and rail roads on slopes under conditions of melting permafrost soils in process of operation of structures, reduced material intensity, realisation of anti-landslide actions.

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Description

The invention relates to the field of construction and operation of linear structures on slopes or artificial slopes, for example, roads and railways and can be used to prevent their deformations arising from the occurrence of landslide processes in complex engineering and geological conditions, for example, in the presence of thawing permafrost soils.

A known method of erecting on slopes or artificial slopes of a single-row pile fence from bored piles united by a grillage (Guide to the design and construction of buried engineering structures / NIISK GOSSTROY USSR. - M .: Stroyizdat, 1986. - S. 8, Fig. 4).

The disadvantages of this method are as follows:

- the need for frequent arrangement of piles in plan in order to prevent the possible flow of soil around individual piles;

- the perception of small amounts of landslide pressure on the barrier;

- low strength of the fence due to the lack of an anchor system;

- high cost of implementing the method.

Closest to the proposed method is a method of erecting on slopes or artificial slopes of single-row walls with bored piles with grillage and anchors. The role of the retaining wall is performed by a reinforced concrete blocking, installed vertically and covering the gaps between the piles (Design and Construction Instrument for Buried Engineering Structures / NIISK GOSSTROY USSR. - M.: Stroyizdat, 1986. - p. 8, Fig. 5).

The disadvantages of this method are:

- zabirka creates a filter curtain, blocking the path of the filter flow with all the ensuing consequences, especially in permafrost soils;

- the difficulty of ensuring the necessary bearing capacity of anchors on the ground;

- high cost and low manufacturability of the method.

The technical result of the invention is to increase the efficiency of preventing deformation of linear structures erected on landslide slopes or artificial slopes in the presence of thawing permafrost soils.

The result is achieved by the fact that the method of preventing deformation of linear structures erected on landslide slopes or artificial slopes on thawing permafrost soils, including the construction of a working platform, installation of piles in the soil of the slope, the union of piles in a single grill, differs in that after the piles are immersed in the soil on the free end of each pile is installed reinforced concrete head, and the Association of piles in a single grillage is carried out by installing a vertical geogrid, rigidly connected to the heads with wai and layers of horizontal geogrids located above the pile heads, while the working platform from the bottom of the pile heads to the first layer of the horizontal geogrid, as well as the gaps between the layers of the geogrids, are filled with crushed stone, and the installation of horizontal geogrids is made with the condition of their partial location in the non-moving ground mass slope or natural slope.

The claimed method differs from the prototype in that it allows:

- to exclude deformations of linear structures erected on landslide slopes or artificial slopes in the conditions of changing temperature and humidity conditions of soils;

- to avoid the hydrodynamic pressure created by the filtration flow on the pile barrier and thereby exclude its thermal effect on permafrost soils located at the base of the slope;

- to increase the efficiency of the pile fence in the conditions of local permafrost degradation due to the possibility of changing the ratio of the geometric dimensions of vertical and horizontal geogrids and their location;

- fundamentally change the stress-strain state of the slope in order to increase its stability.

To implement the method using:

- excavation of the slope or slope, in order to arrange the working platform, to a depth sufficient to position the vertical geogrid and layers of horizontal geogrids, the number and dimensions of which are determined by calculation;

- immersion in pre-drilled wells or driving piles from the surface of the working platform with their ends embedded in permafrost soils;

- the device at the upper ends of the piles of individual formwork for the purpose of concreting the pile heads with the simultaneous termination of the lower end of the vertical geogrid in them;

- filling the working platform, starting from the bottom of the pile heads to the level of the first (lower) layer of the horizontal geogrid with crushed stone of the required fraction, followed by compaction;

- laying on the compacted crushed stone of the paintings of the first (lower) layer of the horizontal geogrid end-to-end with a vertical geogrid. In this case, the end parts of the horizontal geogrid facing the upper part of the natural slope should be laid on the lower stage of the unshifted mass of soil,

- connection of a vertical geogrid with a horizontal one using overlays and clamps;

- filling the space between the horizontal geogrid of the lower layer and to the level of the second layer of the horizontal geogrid with crushed stone of the required fraction with compaction;

- laying on the compacted crushed stone of the second layer of the horizontal geogrid with the repetition of subsequent steps similar to laying the first (lower) layer of the horizontal geogrid.

In the case of the close location of the roof of permafrost soils to the day surface and, accordingly, the real possibility of their degradation as a result of exposure to solar radiation (slope of the southern exposure) and positive air temperature, as well as filtering surface water to permafrost soils, layers are laid over layers of horizontal geogrids - and waterproofing materials.

The prevention of deformation of linear structures on landslide slopes or artificial slopes in the face of changes in the temperature and humidity regime of permafrost soils can be explained as follows. It is known that deformations of linear structures are caused by a complex of factors associated with the manifestation of various physical and geological processes, including and thawing permafrost. The vast majority of traditional design solutions of anti-landslide structures is based on the assumption that the size and shape of the landslide body are constant, the lower surface of which coincides with the roof of permafrost soils, the position of which is considered unchanged. This factor as a parameter is introduced into the calculation scheme.

In the case where permafrost soils are ubiquitous, the assumed sliding surface, which coincides with the roof of permafrost soils, captures both the upper and lower parts of the slope, in the middle of which there is a linear structure, for example, a highway. It is from these positions that the pile fence is traditionally calculated, the location of which on the slope is determined by the calculated landslide pressure plot. But, given the fact that permafrost soils are water-resistant, the infiltrating melt and rainwater of the slope accumulate in the thaw and seasonally frozen layers, overwhelming them. As a result, a change in the consistency (state) of soils occurs with the development of local visco-plastic and fluid-plastic deformations on the slope. The development of such deformations is especially promoted by the inhomogeneous structure of the slope with interlayers of weak soils, which can serve as potential local sliding surfaces that affect individual sections of both the upper part of the slope and the lower part. Thus, it is possible to develop local landslide processes in separate sections of the slope that threaten the safe operation of linear structures. In this regard, design decisions based on the assumption of the constancy of the roof of permafrost soils in time and space may be ineffective.

In connection with the foregoing, there is a need to implement such methods of erecting linear structures on landslide slopes or artificial slopes in conditions of changing the temperature and humidity regime of permafrost soils, when the entire slope as a whole, and its individual parts, are protected from local landslide occurrences.

Physically, the process of preventing deformation of linear structures erected on landslide slopes under conditions of changes in the temperature and humidity regime of permafrost soils can be explained as follows. In the initial period of operation of linear structures on landslide slopes or artificial slopes, the position of the roof of permafrost soils corresponds to the surface that is taken as the position of the potential sliding surface of the landslide body, capturing the upper and lower parts of the slope. Based on this position, taking into account the magnitude of landslide pressure, the location and design of the pile fence made of piles with grillage, anchors and reinforced concrete blockings (prototype) are accepted.

With the further operation of the linear structure due to the influence of a complex of natural and technogenic factors, for example, changes in the temperature and humidity conditions of permafrost soils (MMG), landslide occurrence in certain sections of the slope or slope is possible, with the crawling of soil masses through the barrier due to local non-uniform degradation of the MMG and the formation of new local surfaces slip in thawed water-saturated soils. The situation is also aggravated by the installation of continuous reinforced concrete blockages that impede the free filtration of groundwater down the slope and facilitate their accumulation in front of the pile barrier with all the ensuing consequences.

In the claimed method, combining pile heads into a single grillage by connecting them with a vertical geogrid and then connecting it with layers of horizontal geogrids, filling the gaps between them with crushed stone with compaction, helps prevent local landslides on slopes and artificial slopes. In this case, the height of the vertical geogrid and the number of layers of horizontal geogrids with interlayers of compacted rubble are taken in each case depending on the position of the MMG roof, forecast estimates of the possibility of the formation of local sliding surfaces in individual sections of the slope or artificial slope with the corresponding landslide pressure, as well as the possibility crawling of the ground mass through the fence.

The basis of the proposed method are pile rows that penetrate the entire landslide body, capturing the upper and lower parts of the slope or slope, and are immersed in the MMG to the estimated depth. This solution helps prevent a landslide process that captures both parts of the slope. The combination of individual piles with heads is carried out using a vertical geogrid connected to the heads and several layers of horizontal geogrids connected with it with interlayers of compacted crushed stone. In this case, three problems are solved: the perception of a combined design of vertical and horizontal geogrids with layers of compacted crushed stone of landslide pressure with its partial transfer to piles; prevention of soil creeping through the barrier in case of local landslide occurrences; preservation of the natural regime of groundwater filtration down the slope, which, in turn, is an opportunity to protect the soil of the slope or slope from additional overmoistening. If the landslide mass is represented by loose sediments of a fluid consistency, it is extremely difficult or simply impossible to maintain such a mass with the traditional approach used in the prototype due to, for example, the creation of hydrodynamic pressure on a pile fence, grillage, and trowel. The construction of a combined structure of vertical and horizontal geogrids with layers of compacted rubble allows you to create a compacted zone of creeping soil from the side of the landslide with the possibility of free outflow of water from it, i.e. realization of the so-called arched effect.

The work of a vertical geogrid connected to the heads of piles and with layers of horizontal geogrids with interlayers of compacted rubble can be explained as follows.

1. Working in conjunction with compacted gravel filling the geogrid cells and dividing them into layers, a vertical geogrid structure connected to horizontal geogrid layers and pile heads dramatically changes the stress-strain state of the soil mass in the near-pile space. This occurs for the following reasons:

- a partial arrangement of horizontal geogrids in an unshifted mass of soil with the filling of their cells and layers between them with compacted rubble, which increases the friction forces there, prevents horizontal displacement of soil masses during local landslide occurrences. From this position, horizontal geogrids, with their partial location in an unshifted mass of soil and filling their cells and layers with compacted gravel, can be considered as an anchor system that increases the overall stability of the pile fence;

- the estimated location of the layers of horizontal geogrids is such that the potential sliding surfaces, in the case of local landslide occurrences, will intersect them. In this case, not only the direction of the sliding surfaces will change, but also the design scheme of the force action of the local landslide body on the barrier;

- the connection of the vertical geogrid with the heads of piles and layers of horizontal geogrids, with filling the gaps between them with compacted gravel, can significantly reduce landslide pressure on the pile fence.

In FIG. 1 shows a general view of a pile fence with a structure of a vertical and lower layer of horizontal geogrids located on an artificial slope; in FIG. 2 is a cross-sectional view of a pile fence and a junction of vertical and horizontal geogrids.

Figures 1 and 2 show: vertical geogrid 1, pile head 2, pile 3, lower layer of horizontal geogrid 4, crushed stone 5, overlays for connecting vertical and horizontal geogrids 6, clamps or knitting wire 7, middle layer of geogrid 8, the upper layer of the horizontal geogrid 9, the working platform 10, the surface of the slope or slope 11, the alleged local sliding surfaces 12.

The implementation of the method is as follows.

On a pre-planned working platform 10, piles 3 are driven or immersed in pre-drilled wells, followed by installation of reinforced concrete heads 2 in the upper part of the piles; moreover, during concreting of the heads in the formwork, the lower end of the vertical geogrid is introduced into them 1. After exposure of the concrete heads and formwork removal, the working platform 10 is filled with crushed stone of the required fraction with compaction to the mark of the lower layer of the horizontal geogrid 4. Lay on the compacted crushed stone 2 parts of the lower th layer of the horizontal geogrid 4 end-to-end with the vertical geogrid 1 with their subsequent connection with the help of plates 6 and clamps or a knitting wire 7. Next, they are laid, followed by compaction, on the horizontal geogrid 4 of the crushed stone layer with simultaneous bending of its end part with a smooth transition in the horizontal plane. The thickness of the crushed stone layer should correspond to the mark of the second (middle) layer of the horizontal geogrid 8. The subsequent steps for installing horizontal geogrids 8 and 9 are completely similar to those discussed above for the lower horizontal geogrid 4. The use of bending of the end parts of vertical geogrids and their smooth transition to the horizontal plane is due to the need to increase the efficiency of the anchor system of layers of horizontal geogrids with crushed stone located in an unshifted slope ground mass or from braid. The bending of the horizontal geogrid creates additional resistance to tensile forces arising in it during local landslide occurrences.

In the present invention, the positive effect is as follows:

- minimizing the risk of deformation of linear structures erected on landslide slopes or artificial slopes in the face of changes in the temperature-wet regime of permafrost soils;

- reduction in the cost of implementing landslide measures;

- improving the efficiency of protection of linear structures from local landslide occurrences.

Claims (1)

A method of preventing deformation of linear structures erected on landslide slopes or artificial slopes on thawing permafrost soils, including the construction of a working platform, installation of piles in the soil of the slope, the union of piles in a single grillage, characterized in that after the piles are immersed in soil on the free end of each pile reinforced concrete head, and the Association of piles in a single grillage is carried out by installing a vertical geogrid rigidly connected to the heads of piles and layers of horizontal geogrids located above the pile heads, while the working platform from the bottom of the pile heads to the first layer of the horizontal geogrid, as well as the gaps between the layers of geogrids, are filled with crushed stone, and the installation of horizontal geogrids is made with the condition of their partial location in an unshifted mass of slope or natural slope .

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