SU1656130A1 - Method of driving the under-vault part of large-span underground structure - Google Patents

Abstract

The invention relates to underground construction and m. used when driving the downstream part of large-span lifting structures in rocks. The goal is to increase the rate of penetration. The method includes the penetration of advanced production (B) 1. The latter is held at the top of the subsurface part of the structure within its design contour, and the subsurface part passes through two pairs of lateral ledges. From the advancing C 1 6ypaf of the downstream borehole 2, form the lower ledge 3, destructible to emit. Leading lateral ledges 4 and lagging lateral ledges 5 are smoothed by parallel holes with axis B 1. Alternate blasting of blast-hole charges is done at one time. Initially, explosive destruction of the lagging pair of lateral benches is carried out with movement of crushed rock to the axis of the subsurface part, then explosive destruction of the leading pair of lateral benches with movement of rock to the axis of the subsurface part of the structure. The minimum distance between the leading and lagging pairs of lateral benches is determined by a given formula, based on the need to ensure the compactness of the blasted rock while ensuring the effectiveness of aeration. 1 hp f-ly, 5 ill. cl

Description

The invention relates to underground construction and can be used when sinking a downstream part of large-span underground structures in rock formations.

The purpose of the invention is to increase the rate of penetration.

FIG. 1 shows the subsurface clean structures, a longitudinal section; figure 2 is the same, the view in the plan; fig.Z - the same cross-section; Fig. 4 shows a sequence of explosive destruction of rock volumes with indication of the direction of movement of the blasted rock; Fig. 5 is a longitudinal section of the downstream part of the structure with an indication of the approximate type of rock pile.

The drawings indicate: 1 - advanced development, 2 - downward holes, 3 - lower ledge ahead of excavations, 4 - advanced lateral ledges, 5 - lagging lateral ledges, 6 - boreholes, parallel to the axis of excavation, 7 - pile of rock from the explosion of lagging lateral ledges, 8 - left

about

SA)

about

the rock shaft from the explosion of the lower ledge of the leading development, 9 - the rock bulk from the explosion of the leading lateral ledges,

Example. Advance production 1, for example, a section of Son.in Sq.m, extends along the entire length of the subsurface part of the structure, for example, a section Zp.ch 60 m2, From advanced generation 1 drill of a row of downstream bore-holes 2, for example , 3 m deep, forming the lower usgup 3, destructible to emit. The leading lateral ledges 4 and the lagging lateral ledges 5 are smoothed by parallel holes to the axis of production 6, for example, 3.5 m deep. At the same time, the Zef. Son at. (based on the air flow rate) and in accordance with the provided yf value - 3.5 m with the rock loosening coefficient Kp 2, the distance between the leading 4 and lagging 5 lateral ledges is determined to be L 7 m. meters of installation of an explosive network explode blast-hole charges in the following order: first — drilled — charges of lagging lateral ledges 5 with the crushed rock moving to the axis of the subsurface portion of the structure; then, for example, after 200 ms, the descending blast-hole charges of the lower ledge 3 with the crushed rock moving to bulk, formed as a result of the explosion of the lagging lateral ledges 5; then, for example, after another 100 ms, the drilled charges of the leading lateral ledges 4 with the crushed rock moving to the axis of the subsurface part of the structure. Due to such a blasting sequence, a compact (as a result of oncoming movement of the rock) pile 7 of the rock from the lagging lateral ledges is formed at the beginning, then the pile 8 of the blast of the lower ledge 3 of the advanced generation 1 is placed on it, and then the pile of the leading lateral ledges 4 In this case, in the upper part of the section, there remains a free space with a section of 3Ef, sufficient to ensure effective ventilation.

The minimum distance between the advancing and lagging pairs of lateral benches is determined on the basis of the need to ensure the compactness of the pile of the blasted rock while ensuring the ventilation efficiency using the following formula:

on.v

S p.ch S

(- "

J p.-Eef

| wow

Kg

where Zp.ch is the cross-sectional area of the downstream part of the structure, m2;

Son.в - advanced cross-sectional area

output, m2;

5eff effective cross-section of the free space in the subsurface part according to the ventilation factor, m2; uh - depth of care for the explosion, m;

Кр - coefficient of rock loosening, units

Claims (1)

Invention Formula -one. The method of penetration of the subsurface part of the large-span underground structure, including the advance development, the formation of lateral ledges within the design contour of the subsurface part of the structure and their destruction by blasting of shpurovogo charges, characterized by the fact that, in order to increase the rate of penetration, within its design contour, and the subsurface part passes by two pairs of lateral ledges, the leading pair of which is formed to the depth of the blasting by the release of downhole holes, drilled from the advance working soil with the formation of the lower ledge within the design contour of the subsurface part of the structure, alternately blasting of blast-hole charges produced at one time, while first producing an explosive destruction of the lagging pair of lateral escapes with the crushed rock moving to the axis of the feed part, then explosive destruction of a leading pair of side ledges with the movement of rock to the axis of the subsurface part of the structure. 2, the method according to claim 1, characterized in that the minimum distance between the leading and lagging pairs of lateral benches is determined by the formula S P.CH - 3 OP.V. | v wow L - S P.Ch Zef where Zp.ch. - cross-sectional area of the subsurface part of the structure, m; Zop.v anticipated generation cross-sectional area; Zeff is the effective cross section of the free space in the downstream part according to the ventilation factor; Uh - the depth of care for the explosion; Кр - coefficient of rock loosening, g N FIG. S 1