MD147Y - Process for dam erection against landslides - Google Patents

Abstract

The invention relates to the construction and can be used for protection against landslides or as a supporting wall. The process of executing the dam against the landslides consists of drilling some wells, introducing into them a chemical solution for artificial consolidation of the earth through some injectors, placing some reinforcement devices in the wells, fixing their lower ends, pre-fixing them and filling the wells with a consolidating material. The probes are drilled to a depth that exceeds the level of the landslide surface with 4 ... 5 probe diameters, forming spherical spaces in the non-displaceable layer with the diameter equal to two probe diameters. The upper ends of the reinforcing devices protruding above the ground level are joined together in a reinforced concrete belt. The dam is executed in the form of mesh walls with planar semicircles, which entails the entire landslide, dividing it into smaller sectors, placed in rows in the direction of the slope.

Description

The invention relates to construction and can be used for protection against landslides or as a load-bearing wall.

The process of consolidating a retaining wall in the ground is known, which includes sinking by hammering injectors with constant cross-section, at a distance of 1 m between them, and creating a fence by consolidating the ground with chemicals introduced through the injectors, where only a part of the wall is in contact with the ground [1].

The disadvantage of this process is the low resistance to the action of overturning forces, which occur during earthquakes, or to the appearance of groundwater.

The process of constructing a landslide dam is also known, which in plan has a linear shape, made up of semicircles with a given radius, which includes drilling wells at a depth exceeding the level of the displacement surface, introducing a chemical solution into them to artificially consolidate the soil through injectors, placing reinforcement devices in the wells, fixing the lower ends, pre-tensioning them and filling the wells with a consolidating material, the upper ends of the reinforcement devices protruding above the ground being joined together by a reinforced concrete base [2].

The disadvantage of this process is that it cannot exclude landslides and landslides on steep slopes.

The problem solved by the present invention is to create a landslide dam that would eliminate the disadvantage of the closest solution and ensure the stability of steeply sloping lands.

The problem is solved by the fact that the procedure for constructing the landslide dam consists of drilling wells, introducing a chemical solution for artificial soil consolidation into them through injectors, placing reinforcement devices in the wells, fixing their lower ends, pre-tensioning them and filling the wells with a consolidating material. The wells are drilled to a depth exceeding the level of the landslide surface by 4…5 well diameters, forming spherical spaces in the immovable layer with a diameter equal to two well diameters. The upper ends of the reinforcement devices protruding above the ground level are joined together in a reinforced concrete belt. The dam is made in the form of a mesh with walls of semicircles in plan, which entrain the entire landslide area, dividing it into smaller sectors, arranged in rows in the direction of the slope and overlapping starting from the lower to the upper part of the slope of the landslide area, dividing it into floors. The ends of the semicircles on the upper floor rest on the bolts of the semicircles on the lower floor and are joined together by pillars.

The result of the invention consists in ensuring increased soil stability by dispersing the sliding mass into smaller portions (meshes) and redistributing the sliding soil mass to the walls of the meshes of the net, while avoiding sliding and rolling of the soil.

The invention is explained by the drawings in Fig. 1-4, which represent:

- Fig. 1, plan view of the dam;

- Fig. 2, overall view of the vertical cross-section of the dam wall;

- Fig. 3, the reinforcement device;

- Fig. 4, joining of reinforcing bars in a reinforced concrete belt.

The landslide dam includes the mesh massif with walls of semicircles 2 in plan, which engage the entire landslide terrain, dividing it into smaller sectors 1 formed by a semicircle 2 and two quarters of a circle 3, placed in rows in the direction of the slope and overlapping starting from the lower to the upper part of the slope of the landslide terrain, dividing it into floors: I-II-III-IV.

The ends of the semicircles 2 on the upper floor rest on the bolts 4 of the semicircles on the lower floor and are connected to each other by pillars.

The wings of the semicircles on the upper floor rest on the bolts of the 4 semicircles on the lower floor.

The walls of the net made of soil consolidated with chemicals are formed by wells 5, in which the reinforcement devices are installed, which contain the bottom anchor 6, rigidly connected to the reinforcement rod 7, which in the upper part contains a thread, the support 8, on which the reinforcement rod 7 can move freely, on which the nut 9 is installed, and on the upper end of the reinforcement link 7 a loop 10 is fixed for stretching and pre-tensioning the device.

The procedure for executing the landslide dam provides for the following operations and technological stages: drawing the axes of the semicircles, installing the pickets, fixing the centers of the wells, drilling the wells 5, forming the fence with chemicals, inserting the reinforcing device with the bottom into the wells 5. The ends of the lower rods are installed in the immovable layer in specially drilled spherical spaces with a diameter equal to two diameters of the wells 5, then they are fixed with monolithic concrete, and after the concrete hardens, the reinforcing device is pre-tensioned and fixed (Fig. 3).

To avoid destroying the top of the wall, the upper ends of the reinforcement devices, protruding from the wall, are joined together in a reinforced concrete belt (fig. 4).

The process according to the invention eliminates the disadvantages mentioned above and has the following advantages.

The planar dam has a shape that contributes to the dispersion into smaller portions (holes) and the redistribution of the mass of sliding soil between the floors and the walls of the holes, reduces the action of pressure forces and avoids the displacement and rolling of the soil over the walls of the dam holes.

The plan dam is made up of walls in the shape of semicircles with a given radius, the ends of which are joined together by piers, which give the dam a high resistance to overturning.

The substances in the immovable layer below, increasing the adhesion between the movable and immovable layers, form a seamless monolith.

At the bottom, between the wings of the semicircles, unconsolidated spaces are left for groundwater drainage, thus avoiding raising their level.

1. Gorlov V. С. Опыт применения чимикого просмотровния грунтов для безосадочной продажи тоннелей и соружении станции Московского метрополитена. Сборник: "Закраните и удаление грунтов в строительстве". Materials of the VIII-go all-union meeting, Издательство Budevelnik, 1974, p. 414

2. MD 3490 C2 2008.01.31

Claims (1)

A procedure for constructing a landslide dam, which consists of drilling wells, introducing a chemical solution for artificially consolidating the soil into them through injectors, placing reinforcement devices in the wells, fixing their lower ends, pre-tensioning them and filling the wells with a consolidating material. The wells are drilled to a depth that exceeds the level of the landslide surface by 4...5 well diameters, forming spherical spaces in the immovable layer with a diameter equal to two well diameters, and the upper ends of the reinforcement devices protruding above ground level are joined together in a reinforced concrete belt, characterized by the fact that the dam is made in the form of a mesh with walls made of semicircles in plan, which entrain the entire landslide terrain, dividing it into smaller sectors, placed in rows in the direction of the slope and overlapping starting from the lower to the upper part of the slope of the landslide terrain. sliding, dividing it into floors, while the ends of the semicircles on the upper floor rest on the bolts of the semicircles on the lower floor and are connected to each other by pillars.