RU2527955C1 - Method of carrying out counter-heading drivage at their breakthrough - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: method comprises determining the direction of carrying out counter-heading drivage using instrumental method, drilling counter-heading drivage, charging and blasting the holes, airing the bottomhole and removal of the exploded rock mass. In one of the counter-heading drivage the hole is drilled in the center of the bottomhole. Before drilling in the counter-heading drivage opposite to it the direction of counter-heading drivage is additionally determined on the greatest degree of exposure of vibration of the surface of the rock mass by the palm of the hand by applying the palm of the hand to the surface of the rock mass in the center and in other parts of the bottomhole.

EFFECT: reduction of costs for counter-heading drivage at their breakthrough by reducing the amount of deviation from the predetermined direction at their breakthrough.

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Description

The invention relates to the mining industry and can be used when conducting counter workings when they fail in ore mines.

The claimed invention relates to a priority area for the development of science and technology "Technologies for environmentally sound development of deposits and mining" [Alphabetical index to the International Patent Classification in priority areas for the development of science and technology / Yu.G. Smirnov, E.V. Skidanova, S.A. Krasnov. - M .: PATENT, 2008. - p.110].

The problem of counter workings during their failure is that they often do not match, which leads to unjustified costs, reduced safety and environmental friendliness.

There is a method of oncoming workings when they are interrupted using a compass (Georgy Agrikol. On mining and metallurgy. - Publishing House of the Academy of Sciences of the USSR, 1962, 602 S., p.142). The method includes determining the direction of the oncoming workings when they are interrupted using a mountain compass, drilling, loading, blasting holes, airing and cleaning the blasted rock mass from the face.

Common features of the known method with the claimed invention are:

- determination of the direction of oncoming workings using the instrumental method.

- drilling, loading and blasting holes, ventilating the face and cleaning the blasted rock mass.

The disadvantages of this method is the significant cost of eliminating the results of a failure of oncoming workings due to errors in determining the direction of their conduct. This happens as a result of the following. When using the known instrumental method, a deviation from the direction of the oncoming workings occurs when they fail due to errors of the known method. Using a tape measure and a mountain compass, the azimuths of the direction of the oncoming workings are determined. All results are displayed on graph paper using a compass and a protractor. After that, they attach to the mountainous area. To orient the direction of the oncoming workings when they fail, use plumb bob. The plumb line is a load with a flexible thread attached to the roof of the mine. The direction is determined by the transmission of a miner lamp located on the same line of two plumb lines.

The prototype adopted a method of oncoming workings when they fail using a theodolite with a laser pointer (Sinanyan P. P. Surveying: Textbook for high schools. - M .: Nedra, 1982, - p.216). The method includes determining the direction of the oncoming workings when they are malfunctioning using a theodolite with a laser pointer, drilling, loading and blasting holes, airing and cleaning the blasted rock mass from the face.

Common features of the known method with the claimed invention are

- instrumental way to determine the direction of oncoming workings when they fail.

- drilling, loading and blasting holes, ventilating the face and cleaning the blasted rock mass.

The disadvantages of the method are the significant costs of eliminating the results of deviations from the given direction of failure, reducing the safety and environmental friendliness of the work due to errors in the instrumental method. This happens as a result of the following. When using the known instrumental method, a deviation from the direction of the oncoming workings occurs when they fail due to errors of the known method. Using the theodolite with a laser pointer, determine the direction of the oncoming workings at the surveying points with plumb lines. The direction is determined by the transmission of a miner lamp located on the same line of two plumb lines.

The reason for the lack is the lack of technical solutions aimed at eliminating errors in determining the direction of oncoming workings when they fail.

The invention is aimed at solving the problem of improving the method of oncoming workings when they fail, which contributes to a more accurate, safer and more environmentally friendly, as well as less costly driving.

The technical result of the claimed invention is to improve the accuracy of sinking of oncoming workings when they fail by reducing the deviation from a given direction when they fail. In addition, the technical result consists in increasing the safety of work, as well as in the environmental friendliness of the method, which excludes the development of unjustified volumes of rocks.

The technical result of the claimed invention is achieved by the fact that in the method of counter workings when they fail, including determining the direction of the counter workings using the instrumental method, drilling counter workings, loading and blasting holes, ventilating the face and cleaning the blasted rock mass, according to the invention, one of the oncoming workings of holes is drilled in the center of the face, and before drilling in the opposite workings, the direction of the drilling is additionally determined generating a counter using tactile sensory system of a human palm of the hand by applying to the surface of the rock in the center of the array and at other points on the bottom most surface of the vibration of a rock mass on the palm of the hand.

An additional determination of the direction of the oncoming workings during their failure is necessary to reduce the error in determining the direction by the instrumental method. This reduces the cost of oncoming workings when they fail and is aimed at achieving a technical result.

Drilling a hole in the center of the face of the oncoming mine creates a vibration of the rock mass in the center of the face of the oncoming mine and facilitates the orientation of this mine in space. Therefore, this technical solution contributes to the achievement of a technical result.

In the center and at other points of the face of the opposite oncoming working out, the palm of the hand is put to the surface of the rock mass of the working face of this working out. On the palm of the hand are the endings of nerves of sensitivity - receptors that perceive vibrations of the surface of a rock massif, distinguishing these fluctuations in amplitude and frequency.

The tactile sensor system is known to be used for pressure and touch analysis. Its receptors are free nerve endings and complex formations (Meissner bodies, Pacchini bodies), in which the nerve endings are enclosed in a special capsule. They are located in the upper and lower layers of the skin, in the skin vessels, in the bases of the hair. Especially a lot of them on the fingers and toes, palms, soles, lips. These are mechanoreceptors that respond to tension, pressure and vibration (Sensor systems. Article 11/18/2007. Access mode: http://sportzal.com/post/861/).

The hole in the center of the face of the oncoming mine is drilled with a perforator, which produces 2100-3000 strokes per minute with a drill bit over the rock mass, causing vibrations with a vibration frequency of 35-50 Hz and an amplitude of 0.40-0.15 mm. (Mining. Terminological Dictionary. L.I. Baron, G.D., Lidin et al., Moscow: Nedra, 1991, 479 pp. 57). The vibration from the borehole of the oncoming mine extends to the surface of the rock mass of the face of the opposite oncoming mine. The amplitude and frequency of this vibration acts on the palm of the hand pressed to the face of the opposite oncoming workout. At the same time, the palm of the hand reacts not only to vibration in general, but also determines the degree of vibration - more, less or at the same level. It is believed that the sense of touch works exclusively on a spatial principle: our skin is covered with a network of tactile receptors, and we feel the surface by comparing different parts of it (Source: sciencelife.uchospitals.edu, article: “HowOurSenseofTouchisaLotLiketheWayWe Hear”), However, experiments have shown conducted at the Medical Center of the University of Chicago (USA), the sense of touch also has a temporary parameter. In other words, tactile receptors can sense frequency, similar to auditory receptors.

In the experiment, a special apparatus was used, which produced complex vibrations. The vibrations created by this device made Rhesus monkeys and several volunteers feel it. At the same time, the activity of tactile neurons that transmit information from the center to the brain was recorded. It turned out that neurons are excited in full accordance with the vibrations that they have to feel. And even more than that: by the nature of the nerve vibrations one can guess the nature of the vibration of the surface. To understand what’s the matter, you need to imagine not a vibrating, but a calm surface - for example, a silk thread. We can distinguish between silk and wool by touch. However, when we drag a finger along a silk or wool thread, we feel a certain specific texture, in which there is a repeating pattern of irregularities. These irregularities act on our receptors like vibrations, that is, the same receptor is excited at some intervals, and these intervals are an important characteristic of the surface. In a word, the feeling of a silk thread can be caused without even touching the material itself. Researchers emphasize the fact that in their experiments they used not regular, sinusoidal, but "polluted", irregular vibrations that are usually found in nature.

Drilling holes creates fluctuations in the rock mass of high frequency and a small amplitude, i.e. vibration The amplitude and frequency of vibration of the rock mass depends on the distance between the source of its excitation (the point of drilling the hole) and the point of perception of this vibration - the place where the palm of the hand is applied to the surface of the rock mass of the opposite oncoming generation. The above technique is aimed at achieving a technical result.

Drilling a hole in the center of the face of the oncoming excavation and applying the palm of the hand in the center and at other points of the face of the opposite oncoming excavation to the surface of the rock mass is carried out simultaneously. Only with simultaneous drilling of a hole and applying a palm of your hand to the surface of a rock mass can the direction of vibration propagation be determined. Such a technological technique is aimed at achieving a technical result.

The direction of the oncoming workings during their failure is determined by comparing the degree of vibration of the surface of the rock mass in the center and at other points of the face of the opposite oncoming workings on the palm of the hand. The amplitude and frequency of vibration of the surface of the rock mass at different points of the face of the opposite oncoming working out depends on the distance between the place of drilling the hole and the place of applying the palm of the hand. The larger this distance, the smaller the amplitude and frequency of vibration of the surface, and vice versa. Therefore, the largest amplitude and frequency of vibration of the surface of the rock mass of the face of the opposite oncoming production corresponds to the smallest distance between the faces of the oncoming workings. The smaller amplitude and frequency of vibration of the surface of the rock mass of the face of the opposite oncoming production corresponds to a greater distance between the faces of the oncoming workings. The degree of impact of vibration of the surface of the rock mass of the face of the opposite oncoming workings on the palm of the hand is determined by applying the palm of the hand at least 3 points. In the absence of deviation from a given direction, the degree of vibration impact on the palm of the hand at the midpoint should be the greatest, and at the extreme points the smallest, and equal to each other. The distances from the middle to the extreme points should be equal to each other. The direction of the oncoming workings is determined graphically. Therefore, a technical result is achieved.

Differences from the prototype prove the novelty of the method, and the unknown from the prior art of the influence of distinctive features on the claimed technical result proves the compliance of the method with the condition of patentability "inventive step".

The method of oncoming workings during their failure is illustrated by drawings, where:

Figure 1 - a method for determining the direction of oncoming workings when they fail with a minimum deviation from a given direction.

Figure 2 - a method for determining the direction of oncoming workings when they fail when deviating from a given direction by an amount not exceeding half the width of the oncoming workings.

Figure 3 - a method for determining the direction of oncoming workings when they fail when deviating from a given direction by an amount exceeding half the width of the oncoming workings. This drawing shows the possibility of applying the method to determine the degree of vibration of the rock mass in the side wall of the opposite oncoming workings.

The position of the method of conducting oncoming workings during their failure is indicated by the following figures.

1 - counter development.

2 - the face of the counter production.

3 - a hole in the center of the counter development.

4 - the center of the face of the counter production.

5 - opposite counter production.

6 - the face of the opposite oncoming production.

7 - the center of the face of the opposite oncoming production.

A, B, C, D - places where the palm of the hand is applied to the surface of the array of rocks of the face of the opposite oncoming production.

In figures 1, 2, 3, additionally dashed lines with arrows show the directions of propagation of vibration of the rock mass from the hole to the place of application of the palm of the hand. FIG. 1-3 show the possibility of applying the method in determining the degree of vibration of the surface of a rock mass in the side wall of the opposite oncoming working out.

The method of oncoming workings when they fail is as follows.

When conducting counter-excavation 1 (Fig. 1), a hole 3 is drilled in the face 2 of this excavation 3. The hole is located in the center 4 of the face 2 of this counter-output 1. In the opposite counter-excavation 5, a hand is put to the surface of the rock mass of the face 6 of this output. The palm of the hand is applied in at least three points A, B, C, including in the center of the face 6. The degree of impact of vibration on the palm of the hand is compared at points A, B, C. With the relative positions of the oncoming workings 1, 2 shown in FIG. . 2, the greatest vibration is felt by the palm of the hand in the center 7 of the face 6 of the opposite oncoming production 5. At points B, the vibration felt by the palm of the hand is less than at points A - the center 7 of the face 6 of the opposite oncoming production 5. Moreover, other points B, in are located at equal distances from each other to the center 7 of the face 6. In addition, the vibration of the surface of the rock mass at points B and C, felt by the palm of the hand, is the same. The equality of the distances from point A (center 7 of the face 6) to points B, C, as well as the equality of the degree of influence of vibration felt by the palm of the hand at these points (B, C), shows that the counter workout 1 and the opposite workout 5 are carried out without deviations from the set directions. This is confirmed by a graphical definition of the direction of the oncoming workings. To do this, conduct a semicircle with a center at point A. The radius of the semicircle is equal to the length of the segments AB (AB). A straight line is drawn through the middle of the semicircle and point A. This straight line is the direction of the oncoming workout 1 when it malfunctions with the opposite oncoming workout 5. When working on the workings 1, 5, each driving cycle is accompanied by a determination of the degree of vibration of the surface of the rock mass in the center and at other points of the face on the palm of the hand. If necessary, the directions of the oncoming output 1 and the opposite oncoming output 5 are adjusted. As a result, it is established that the oncoming 1 and opposite oncoming 5 workings are conducted without deviation from the given direction and their failure will be performed without additional costs. To conduct counter workings when they fail without deviating from a given direction, it is necessary that the degree of vibration impact on the palm of the hand in the center of the face of the opposite counter work exceed the degree of vibration impact on the hands at other points.

Figure 2 shows the relative position of the oncoming and opposite oncoming workings when they fail with a deviation from the given direction by an amount not exceeding half the width of the oncoming workout. In the center 4 of the face 2 of the oncoming excavation 1, drill a hole 3. In the face 6 of the opposite oncoming excavation 5 determines the degree of vibration of the surface of the rock mass by applying the palm of the hand at points A, B, C, D located along the width of the face of the mine 5. The degree of vibration next in the palm of your hand. At point B, more than at points A, B; at point A, more than at point G. The greatest degree of vibration is at point B. As a result, it is established that the face 6 of the opposite oncoming workout 5 is offset relative to the face 2 of the oncoming workout 1, and the oncoming workout is deviated from the given direction by a distance equal to AB. A semicircle is drawn with a center at point B and a radius equal to the distance AB. It is assumed that the deviation of the oncoming output 1 from a given direction is AB. Define a new direction for the oncoming development 1. Given the deviation AB. Divide the AB deviation into deviation sections equal to the displacement sections of the face 2 of the oncoming mine 1 when it is carried out in a new direction. The number of deviation plots is taken equal to the number of displacement plots. In this case, the total length of the sections of the deviation should be equal to the total length of the sections of the bias. As a result, the oncoming workout 1 leaves at a fault in point A (center 7 of the oncoming workout 5) or in a given direction. During each cycle of driving the oncoming excavation 1 and the opposite oncoming excavation 5, the degree of impact of vibration of the surface of the rock mass in the center and other points of the face on the palm of the hand is determined. If necessary, the direction of the oncoming workings is adjusted. Therefore, for the failure of the oncoming workout 1 with the opposite oncoming workout 5, it is necessary to change the direction of their conduct, taking into account the deviation by a distance equal to AB. In the process of malfunctioning the oncoming workings 1, 5, the distance equal to AB decreases (between the center 7 of the face 6 of the opposite oncoming workout 5 and point B, at which the greatest effect of vibration on the palm of the hand occurs). This distance when the oncoming workings are interrupted will be equal to zero.

Figure 3 shows the relative position of the oncoming and opposite oncoming workings when they fail with a deviation from a given direction by an amount exceeding half the width of the oncoming workings. In the center 4 of the face 2 of the oncoming excavation 1, drill a hole 3. In the face 6 of the opposite oncoming excavation 5, the degree of vibration of the surface of the rock mass on the palm of the hand is determined by applying the palm of the hand at points A, B, C, G. The degree of vibration effect on the palm of the hand is as follows . At point B, more than at points A, G, at point A, more than at point B. The greatest degree of vibration is at point B. As a result, it is established that the face 6 of the opposite oncoming workout 5 is offset from the face 2 of the oncoming workout 1, and oncoming workings are carried out with a deviation from a given direction by an amount exceeding half the width of the oncoming workings. To determine the direction of disruption of oncoming workings, the distances A-B and B-G are taken equal to each other, with an equal degree of vibration impact on the palm of the hand at points A, D. A semicircle is centered with center at point B and a radius equal to the length of segments A-B or G-d. A straight line is drawn through the middle of the semicircle and point B, the direction of the oncoming work is determined 1. The new direction of this work is taken taking into account the deviation by the length of the segment AB. At the same time, when conducting oncoming workings 1 in a new direction, the face 2 is shifted by the length of the deviation of segment AB. During each cycle of driving the oncoming excavation 1 and the opposite oncoming excavation 5, the degree of impact of vibration of the surface of the rock mass in the center and other points of the face on the palm of the hand is determined. If necessary, the directions of the oncoming workings are corrected when they fail.

The proposed method for oncoming workings during their failure has been tested in the mine. Matrosova, located in the Magadan region. The circuits were tested with the mutual arrangement of the oncoming workings shown in Figs. 1, 2, 3, as well as circuits with a significant deviation from the given direction — more than 3.0 m. Positive results were obtained with all the circuits.

As a result of the application of the claimed invention, the costs of oncoming workings are reduced when they fail, not only as a result of a decrease in deviation from a given direction, but also when their driving time is reduced. This is confirmed by a decrease in downtime during the breaking of steeply falling ore zones, due to an increase in the accuracy of penetration of rifted workings during their failure.

The novelty of the claimed invention lies in the absence of such technical solutions to determine the direction of the oncoming workings when they fail. The inventive step of the claimed invention lies in the fact that when using known techniques, a new, previously unknown technical result is obtained. Known techniques include drilling holes and using the palm of your hand to determine the degree of exposure to various factors. However, the joint use of vibration when drilling holes and the effect of vibration on the palm of the hand leads to a new technical result, which consists in determining the direction of oncoming workings when they fail. The application of the proposed method consists in the positive results of its testing in practical conditions.

Claims (1)

A method of conducting counter workings during their malfunction, including determining the direction of conducting counter workings using the instrumental method, drilling counter workings, loading and blasting holes, ventilating the face and cleaning the blasted rock mass, characterized in that in one of the oncoming workings, holes are drilled in the center face, and before drilling in the opposite oncoming workout, they additionally determine the direction of the oncoming work using a tactile sensory system oveka palm of the hand by applying to the surface of the rock in the center of the array and at other points on the bottom most surface of the vibration of a rock mass on the palm of the hand.

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