SU1048031A1 - Method of erecting a stone-fill dam - Google Patents

Abstract

1. THE METHOD OF IMPLEMENTATION OF A NON-FURNED DAM, including driving openings in a rock massif, placing explosives charges in them and displacing an array of collapses into the dam body, in order to achieve the given filtration characteristics of the dam body. reducing the cost of its erection and enhancing the stability of the slopes after the collapse of the array, the peripheral parts of the array are formed in the form of triangular prisms oriented deep into the array by drilling along their external contour of the system of inclined wells, and by internal contour on the border with the central part of the array drilling of the system of vertical wells, This preliminarily weakens the peripheral parts of the collapse massif, preserving its geological structure by the explosion of borehole charges, and after the explosion displaces the prices In the central part of the massif of the collapse into the body of the dam, exploding charges in the system of inclined wells. 2. The method according to claim 1, characterized in that the preliminary attenuation of the peripheral parts of the collapse array is carried out (L with loosening coefficients equal in the upper slope region 1.03-1.05, and in the lower slope region 1.12- 1.15. 4 00 oo

Description

The invention relates to the construction and can be used for the construction of dams in the canyons of mountain rivers. There is a known method of raising dams, which includes making mines in the undisturbed rock mass, placing explosives charges in them, followed by a mass explosion to choose and laying rocks into the body of the dam 1. The disadvantage of this method is to achieve low filtration characteristics of the body of the dams due to with the explosion of the granulometric composition of predominantly large fractions. The closest to the invention is the method of erecting a stone-penetrating dam, which includes sinking workings in the rock massif, placing explosive charges in them and moving the blast mass to the dam body by means of an explosion. A decrease in filtration flow through the dam body is achieved by moving the less permeable soils 2 previously stored to the flat charge system to the uphill slope. However, the known method is characterized by high cost of work due to the gradual erection of the dam body and increased material costs for pre-storage of rocks, difficulty in obtaining the body dams with the required filtration characteristics as well as insufficient slope stability after the mash Siwa. The aim of the invention is to achieve the desired filtration characteristics of the dam body, reduce the cost of its construction and increase the stability of the slopes after the collapse of the array. The goal is achieved by the fact that, according to a well-known method, the peripheral portions of the rupture massif are formed as triangular prisms oriented deep into the array by drilling along the outer contour of the system of inclined wells, and drilling the vertical well system at the inner contour on the core with the central part of the array. the peripheral parts of the collapse massif with the preservation of its geological structure by the explosion of borehole charges, and after the explosion displaces the central part of the massif EIW dam body blow charges in deviated well system. In addition, the preliminary attenuation of the peripheral portions of the collapse massif is performed with loosening coefficients equal to 1.03-1.05 in the upper slope region, and 1.12-1.15 in the lower slope region. In FIG. 1 shows a dam, a vertical section; in fig. 2 - the same plan view. The creation of high-pressure dams of increased stability with predetermined filtration characteristics is carried out by forming a dense core or stop prism along the transverse axis of the dam loaded on both sides (upstream and downstream slopes) by a previously destroyed rock mass. The method is carried out as follows. Initially, explosions of downhole charges of explosives produce loosening with preservation of the geological structure of the peripheral part of the rock mass to be laid in the dam body, namely in the area of the upper 1 and lower 2 slopes. For this, rock masses in the upper and lower slopes are drilled with vertical or inclined to the base wells, the wells are charged in the upper slope with charges with a specific flow rate of explosives, for example, 0.3-0.45 kg / m to obtain a grain size distribution. the composition of rocks with an average piece size of 0.25 m in the volume of the rock mass, subsequently laid in the upper slope of the dam, in order to obtain a coefficient of loosening of 1.03-1.05. The wells of the bottom slope area are charged and blasted, based on the specific consumption of explosives 0.5-0.6 kg / m, to obtain a loosened rock mass with a loosening coefficient of 1.12-1.15 and an average piece size of 0.3-0 , 4 m. At the same time, the explosion of vertical wells located on the border with the central indestructible part of the rock massif forms the inner edge of the prism of rocks in the upper and lower slopes of the rocks. After that, the preparation of explosions for discharge of the main part of the rock mass into the dam body is started. To this end, behind the outer contour of the prism of the previously loosened rock mass, a series of inclined wells 3 are drilled to create a charge system with a specific consumption of explosives. for example, 1.6-1.8 kg / m, thereby ending the formation of triangular prisms with orientation of them to the depth of the array. In order to form a dense dam core in the central intact part of the rock mass, excavation 4 is carried out in which chamber charges 5 are placed. In this way, a trapezium is formed in plan, the triangular sections-prisms of which are preliminarily weakened and contoured by inclined boreholes to accommodate chamber charges. Initially, chamber charges 5 are blown up, and then charges in the system of inclined wells 3 are delayed with a delay, thereby ending the construction of the dam. The preliminary weakening of the rocks in the overburden zone of the dam with a coefficient of loosening of 1.03-1.05 is the minimum of the conditions for ensuring the least filtration of rocks, and the weakening of rocks in the zone of the downstream slope of the dam with a coefficient of loosening 1.12-1.15 conditions for the preservation of the geological structure after the explosion and for ensuring the compactness of the rock mass laying. The amount of explosives required is determined in accordance with the accepted coefficients of rock loosening. The assignment of the diameter and number of wells is made taking into account the consumption of explosives to loosen or move one cubic meter of rock. The use of a system of inclined wells to move the peripheral parts of the collapse array allows to increase the stability of the sides of the slopes and reduce the cost of work on their subsequent consolidation. The application of the invention also makes it possible to achieve the desired filtration characteristics of individual parts of the dam body, using varying degrees of pre-loosening of rocks in the collapse array, and reduce the cost of erecting the dam by eliminating the need for pre-storage of low-filtering soils.

Claims (2)

1. METHOD FOR CONSTRUCTING A STONE TURNING DAM, including the excavation of workings in a rock mass, the placement of explosive charges in them, and the explosion moving the collapse mass into the dam body, characterized in that, in order to achieve the specified filtration characteristics of the dam body. reduce the cost of its construction and increase the stability of the slopes after the collapse of the array, the peripheral parts of the collapse array are formed in the form of triangular prisms oriented deep into the array by drilling an inclined well system along their outer contour, and drilling a vertical well system along the inner contour at the border with the central part of the array The peripheral parts of the collapse massif are previously weakened with the preservation of its geological structure by the explosion of borehole charges, and after the explosion has moved, the central charges in the system of deviated wells explode in the upper part of the collapse massif into the dam body. 2. The method according to π. 1, characterized in that the preliminary attenuation of the peripheral parts of the collapse massif is carried out with loosening coefficients equal to 1.03-1.05 in the uphill slope, and 1.12-1.15 in the downhill area.