RU2345194C1 - Ground slope or hillside consolidation method - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention refers to the sphere of construction in general and hydraulic engineering in particular, dealing with protection of aquatoria shores and hydraulic engineering structure slopes against wave and wind forces as well as ground slope or hillside consolidation. Each section of the ground slope or hillside being consolidated undergoes engineering-and-geological and geotechnical survey as well as surface vegetation clearance. Based on the survey findings one defines the range and depth of excavation into the solid and resistant mass of the slope soil or the hillside rock crack-free mass. Excavation is performed lengthwise along the whole of the section being consolidated without application of impact and/or vibration load onto the mass of slope soil or hillside rock. From the excavation sideways in the direction of at least one section being consolidated there are holes bored for embedment of anchors fabricated of wire cables or metal rods. The anchors are inserted through the boreholes from the excavation or from the surface of the section being consolidated with the cables and rods subsequently interconnected to form an integrated meshed metalwork. The cord/rod stretches laid inside the boreholes become pre-tensioned with the help of tension devices installed either in the excavation or on the consolidated section land surface. The pre-tensioned cord and rod stretches laid inside the boreholes are then fixed with a liquid curable polymeric material injected into the boreholes from the excavation. On the surface of the section being consolidated there is a meshed metalwork arranged filled with a liquid curable polymeric material poured into it so that to form a protective layer on its surface.

EFFECT: enhanced hardness and reliability of slope or hillside consolidation; possibility of the slope or hillside consolidation activities under the conditions of imminent soil slip commencement, soil/rock strata movement, fall, collapse or inrush, landslide, rockfall etc; reduction of the amount of mechanical, impact and vibration load applied to the slope/hillside masses of soil and/or rock.

5 cl, 3 dwg

Description

The invention relates to the fields of construction, including hydrotechnical and mining, and can be used to protect the shores of water areas and slopes of hydraulic structures from local materials from wave and wind effects, as well as to strengthen soil slopes and mountain slopes to stabilize landslide processes or to prevent shear, collapse, landslides and dumps of soils or rocks, talus, rockfalls, etc., mainly when it is impossible or technical or economic impractical changes in the relief of the soil slope or mountain slope, for example, when installing separate engineering structures, such as bridge supports, viaducts or aqueducts, on the slope or slope surface, or when placing linear engineering structures, such as roads, railways, on slope or slope bores ways, power lines or communications, water lines, gas pipelines or oil pipelines.

A known method of strengthening the soil slope, including fixing on the slope of a flexible coating of non-woven synthetic material, which is carried out by means of ellipsoid arrays, which are formed from soil and cementitious material injected into it and are located in the thickness of the slope with a mutual distance from each other of 3 ÷ 4 diameters array, and each array is connected through a non-woven synthetic material with a hemispherical volume of the hardened binder material formed on the surface of the non-woven synthetic of material (SU 1361233 A1, IPC E02V 3/12, published on 12.23.1987).

The disadvantages of this known method of strengthening the soil slope are the high cost of materials for creating often located large-volume ellipsoid arrays with hemispherical volumes of hardened binder material protruding above the slope and the low bond strength of the arrays through non-woven synthetic material with these hemispherical volumes, and hence the low reliability of fixing the non-woven synthetic material on the slope.

Another method of strengthening the soil slope for stabilizing landslide masses of the soil is also known, including laying a protective coating on the surface of the soil slope and securing it to the slope with anchors fixed in wells previously drilled in the soil of the slope with immersion in stable soil layers, using elastic as an anchor deformable mats made of artificial materials, which are bent in the form of a pipe, which is then immersed in the corresponding well, after which they fill the well with fill sand, such as crushed stone, gravel or slag, which is compacted by tamping and fixed by the addition of a mortar made on the basis of clay or cement, resulting in a “soft” anchor which, when overloaded, does not break like a hard anchor, but gently inhibits landslide masses of slope soil (DE 3630969 A1, IPC E02D 17/20, published on 03.24.1988).

The disadvantages of this known method of strengthening the soil slope are its complexity and low strength and reliability obtained as a result of its implementation of the strengthening of the slope.

The closest analogue of the proposed method to strengthen the soil slope or hillside is a known method of strengthening the soil slope or mountain slope (slope) mainly to stabilize landslide processes or to prevent shear, collapse, landslides and dumps of soils or rocks, scree, rockfalls, etc. ., including laying on the surface of at least one reinforced section of the soil slope or the mountain slope of the protective coating (made of geotextile) and metal mesh and last drilling on this site with anchors fixed in previously drilled in slope or rock slope rocks by injecting hardening material (concrete) into wells with anchors installed in them (FR 2615542 A1, IPC E02D 17/20, published on 11/25/1988).

The disadvantages of this known method of strengthening a soil slope or hillside are the low strength and reliability obtained as a result of its implementation of strengthening a soil slope or mountain slope, as well as the fact that when it is carried out, all work is performed on the surface of a strengthened soil slope or mountain slope, which limits the scope of use of this known method due to the impossibility in some cases of the placement of the necessary equipment and work on the surface of the reinforced soil slope or hillside, for example, in the face of the threat of landslide processes, shear, collapse, landslides and dumps of soil or rocks, talus, rockfalls, etc. from mechanical, shock or vibration loads produced during the implementation of this method on the slope soil massif or slope rock mass.

The objective of the present invention is to increase the strength and reliability of the resulting strengthening of the soil slope or hillside, as well as expanding the field of use of the method of strengthening the soil slope or mountain slope by providing the possibility of its implementation in the face of the threat of landslide processes, shear, caving, landslides and dumps of soil or mountain rocks, screes, rockfalls, etc. due to the reduction in the number of works carried out during the implementation of the method on the surface of the soil slope or mountain slope, and the reduction of mechanical, shock or vibration impacts on the slope soil massif or rock mass of the slope.

The solution to this problem is achieved by the fact that in the method of strengthening the soil slope or hillside mainly to stabilize landslide processes or to prevent shear, collapse, landslides and dumps of soils or rocks, scree, rockfalls, etc., including laying on the surface, at least one reinforced section of the soil slope or hillside of the protective coating and the metal mesh and fixing the latter on this section with anchors fixed in pre-drilled in the soil According to the invention, engineering-geological and hydrological surveys are preliminarily carried out on each reinforced section of a soil slope or hillside to determine the degree of landslide hazard, shear, collapse landslides and dumps of soils or rocks, screes, rockfalls, etc., as well as the vertical depth and distribution deep into the slope or slope with accordingly, weak soils or fractured rocks and cleaning the surface of the site from vegetation, then, according to the results of surveys, determine the laying mortar and the depth of the excavation in a strong and stable slope soil massif or in a crack-free rock mass of the slope and in the intended alignment at a specified depth along and along the entire length of the reinforced section of the soil slope or mountain slope from the day surface with a rise or slope and access to the day surface to bring drainage water to it t development using tools and production methods that do not have a slope or rock mass of a slope of shock or vibration loads on the massif of rocks, after which they are drilled from the mine to the side of at least one reinforced slope of the soil slope or slope on the day surface of the well for the installation of anchors that are made of metal cables or metal rods and lead into the wells from the excavation or from the surface of the reinforced section of the soil slope or mountainside a, on which metal ropes or metal rods are then connected into a single metal mesh, and parts of metal ropes or metal rods located in wells are pulled by tensioning devices placed in a mine or on the surface of the reinforced section of the soil slope or slope until metal ropes form in these parts or metal rods of prestressing necessary to increase the strength and stability of an array of slopes or an array of mountainous the type of slope, the stretched parts of metal cables or metal rods located in the wells are fixed and hardening material is injected into the wells from the working, using polymer liquid hardening material, after which a protective coating is performed on the surface of the reinforced section of the soil slope or hillside by pouring laid on the surface of the reinforced section of the soil slope or hillside of the metal mesh with polymer liquid hardening material to the thickness of the mesh the formation of a protective layer on its upper surface, moreover, liquid polymer material is used for injecting into the wells, which, after hardening, is waterproof and indecomposable in natural conditions, and liquid polymer material is used to fill the reinforced section of the soil slope or hillside of the metal structure laid after solidification possessing waterproofness, indecomposability in natural conditions and ability reflecting solar radiation.

When strengthening several sections of the soil slope or hillside, separated by berm, on which linear engineering structures are located, additional workings are carried out with the formation of the minimum required total number of all workings, which is less than the number of strengthened sections of the soil slope or mountain slope, and from some workings they drill to the sides of at least two near-reinforced sections with access to the surface of the well for installing anchors, with each above the lined output is connected by gaizens with the nearby lower output.

When completing the development of a dead end, it is completed by drilling a ventilation well.

In the manufacture of a single metal mesh on the surface of the reinforced section of the soil slope or hillside, metal beams are used to strengthen it, including from rolled shaped metal, for example, I-beams or channels.

In the most dangerous areas of the reinforced section of the soil slope or hillside, the cells of a single metal mesh fabricated on its surface are reduced by welding additional metal beams to its metal beams with the formation of small-mesh sections of a single metal mesh in these zones.

The invention is illustrated by drawings, where Fig. 1 shows a dirt slope or hillside, the reinforced sections of which are separated by berm, on which linear engineering structures are placed, a cross section; figure 2 is the same plan; figure 3 - coastal slopes or slopes, on the surfaces of which are placed the support of the bridge.

The method of strengthening the soil slope or hillside mainly to stabilize landslide processes or to prevent shear, collapse, landslides and dumps of soils or rocks, talus, rockfalls, etc. includes laying on the surface of at least one reinforced section of the soil slope or mountain slope of the protective coating (not shown in the drawings) and metal mesh 1 and fixing the latter on this site with anchors 2, fixed in previously drilled in the soil slope or rock formations of the wells 3 by injecting hardening material into the wells 3 with the anchors 2 installed therein.

At the same time, geological and hydrological surveys are preliminarily performed on each strengthened section of a soil slope or hillside to determine the degree of exposure of this section to the risk of landslide, shear, collapse, landslides and dumps of soils or rocks, talus, rockfalls, etc., and also vertical depths and in-depth propagation into slopes or slopes of respectively weak soils or fractured rocks. Then, on each strengthened section of the soil slope or hillside, the surface of the site is cleaned of vegetation and, if necessary, it is treated with continuous action herbicides. According to the results of engineering-geological and hydrological surveys, the laying target and the depth of excavation 4 are determined in a strong and stable slope soil mass or in a crack-free slope rock mass. In the planned range at a specified depth along and along the entire length of the reinforced section of the soil slope or mountain slope from the day surface, slightly higher than the water level in the reservoir 5, with or without a slope and access to the day surface, drainage water is drawn for 4 s the dimensions of the cross-section necessary for the implementation of further work, using the means and methods of work that do not provide slope or rock massif on a slope of shock or vibration loads, t. . in this case, for example, the drilling and blasting method of generating 4 cannot be used. Then from the development 4 in the direction of at least one reinforced section of the soil slope or hillside, drill with access to the day surface of the well 3 for installing anchors 2.

Anchors 2 are made of metal cables or metal rods and are driven into wells 3 from a mine 4 or from the surface of a reinforced section of a soil slope or hillside. As metal cables, metal ropes spent in mine hoists can be used for a specified period. Then, on the surface of the reinforced section of the soil slope or hillside, the metal cables or metal rods are connected into a single metal mesh 1. The 3 parts of the metal cables or metal rods located in the wells are pulled by tensioning devices placed in the excavation 4 or on the surface of the reinforced section of the soil slope or the mountain slope ( not shown) until the formation of metal cables or metal rods of prestressing in these parts th to increase the strength and stability of the array or an array of ground slope mountain slope rocks. Stretched parts of metal cables or metal rods located in the boreholes 3 are fixed and hardening material is injected into the boreholes 3 from the workout 4, using polymer liquid hardening material. After that, a protective coating is performed on the surface of the reinforced section of the soil slope or hillside by pouring polymer hardening material laid on the surface of the strengthened section of the soil slope or hillside onto the thickness of the mesh 1 with the formation of a protective layer on its upper surface. At the same time, liquid polymer material is used for injecting into wells 3, which, after hardening, is watertight and non-degradable under natural conditions, and liquid polymer material is used to fill the reinforced slope or mountain slope of the metal structure mesh laid on the surface of the slope 1, which, after hardening, is watertight and cannot be decomposed. in vivo and solar reflective ability.

When strengthening several sections of a dirt slope or hillside, separated by berm 6, on which linear engineering structures are located, such as highway 7, railway 8, power lines or communications (not shown in the drawings), water supply lines, gas pipelines or oil pipelines, carry out additional workings 4 with the formation of the minimum required total number of all workings 4, which is less than the number of reinforced sections of the soil slope or hillside. Of some workings 4, at least two near-reinforced sections are drilled to exit to the day surface of the well 3 for installing anchors 2. In this case, each upstream working 4 is connected by gozensk 10 with the nearest lower working 4 to bring drainage water to the deepest working 4 and from it to the day surface.

When you perform the development of 4 dead-end it is completed by drilling a ventilation well 11.

In the manufacture of a single metal mesh 1 on the surface of the reinforced section of the soil slope or hillside, metal beams are used to strengthen it, including from rolled shaped metal, for example, I-beams or channels.

In the most dangerous zones of the reinforced section of the soil slope or hillside, the cells of the single metal mesh 1 produced on its surface are reduced by welding additional metal beams to its metal beams with the formation in these zones of small-mesh sections 12 of the single metal mesh 1.

As a result of the implementation of this method, the entire dirt slope or hillside can be strengthened, which will not be destroyed in the future and create a danger to separate and linear engineering structures located on it and below it, moving cars and trains. This method allows you to strengthen sections of soil slopes or mountain slopes with any angle of steepness, including hinged rock cornices with reverse slopes of the reinforced surface, and, in addition, can be used to protect the shores of water areas and slopes of hydraulic structures from local materials from wave and wind impacts.

This invention provides high strength and reliability of the obtained strengthening of the soil slope or hillside, reduces the number of work performed on the surface of the soil slope or mountainside when they are strengthened, and reduces the mechanical, impact or mechanical effects of the slope soil or rock massif vibration effects, which expands the scope of the proposed method for strengthening the soil slope or hillside by providing the possibility of its implementation Nia under threat start landslides, shear collapse, collapses and dumped soil or rocks, scree, rock falls, etc.

Claims (5)

1. The method of strengthening the soil slope or hillside, mainly to stabilize landslide processes or to prevent shear, collapse, landslides and dumps of soils or rocks, talus, rockfalls, etc., including laying on the surface of at least one reinforced section of the soil slope or mountain slope of the protective coating and the metal mesh and fixing the latter on this site with anchors fixed in the wells drilled previously in the soil of the slope or rocks along the slope by means of injecting hardening material into wells with anchors installed in them, characterized in that on each reinforced section of the soil slope or hillside, preliminary engineering-geological and hydrological surveys are carried out to determine the degree of exposure of this section to the risk of landslide, shear, collapse, landslides and dumps or rocks, talus, rockfalls, etc., as well as vertical depth and distribution deep into the slope or slope, respectively, of weak soils or fractured mountains rocks, and cleaning the surface of the plot from vegetation, then, based on the results of surveys, determine the laying ground and the depth of the excavation in a strong and stable slope soil massif or in a crack-free rock mass of the slope, and in the target range at a specified depth along and along the entire length the reinforced section of the soil slope or hillside from the day surface with a rise or slope and access to the day surface to bring drainage water to it, work out using the means and method works that do not exert a slope or rock mass on a slope or rock mass of a slope of shock or vibration loads, after which they drill from the excavation towards at least one reinforced section of a soil slope or mountain slope with access to the day surface of the well for installing anchors, which are made of metal cables or metal rods and lead into wells from a working hole or from the surface of a reinforced section of a soil slope or hillside, on which metal cables or metal metal rods are connected into a single metal mesh, and parts of metal cables or metal rods located in the wells are pulled by tensioning devices placed in the excavation or on the surface of the reinforced section of the soil slope or mountain slope until the metal ropes or metal rods are formed with prestressing necessary to increase the strength and stability of the slope or rock mass of the slope, the stretched parts of metal cables hardening material is fixed in or metal rods located in the wells and hardening material is injected into the wells from the production, which is a polymer liquid hardening material, after which a protective coating is performed on the surface of the reinforced section of the soil slope or hillside by pouring the laid on the surface of the strengthened soil section slope or hillside of the metal mesh with polymer liquid hardening material to the thickness of the mesh with the formation on its upper surface of a protective the first layer, moreover, liquid polymer material is used for injecting into the wells, which, after hardening, is watertight and non-degradable in natural conditions, and liquid polymer material is used to fill the reinforced slope or hillside of the metal structure laid on the surface of the slope, and after curing, it is watertight and cannot be decomposed. in vivo and solar reflective ability. 2. The method according to claim 1, characterized in that when strengthening several sections of the soil slope or hillside, separated by berm, on which linear engineering structures are located, additional workings are carried out with the formation of the minimum required total number of all workings, which is less than the number of strengthened sections of a soil slope or a mountain slope, and from some workings, drill at least two nearby reinforced sections to the side of the well to be installed ki anchors, wherein each upstream production winze connected with the proximal downstream generation. 3. The method according to claim 1 or 2, characterized in that when completing the development of a dead end it is completed by drilling a ventilation well. 4. The method according to claim 1 or 2, characterized in that in the manufacture of a single metal mesh on the surface of the reinforced section of the soil slope or hillside, metal beams are used to strengthen it, including from rolled shaped metal, for example, I-beams or channels. 5. The method according to claim 4, characterized in that in the most dangerous zones of the reinforced section of the soil slope or hillside, the cells of a single metal mesh made on its surface are reduced by welding additional metal beams to its metal beams with the formation of small-mesh sections of a single metal in these zones the grid.

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