RU2248446C1 - Method for determining sheeting parameters for rock solids in massif and device for realization of said method - Google Patents

Abstract

FIELD: mining industry.

SUBSTANCE: method includes drilling wells and mounting electrodes with conductors therein, which are connected to recording equipment. Signal lines are formed by filling wells with hardening mass, which after hardening forms fragile electric-conductive rods, rigidly engaged with well walls. Change of electric resistance between electrodes is measured in time, moments of tears of signal lines are recorded and parameters of rock solids sheeting are determined. Fragile electric-conductive rods can be formed in such a way, that their specific resistance depended on pressure. As hardening mass a mixture of graphic powder, cement and water can be used. Between fragile electric-conductive rods and wells walls a layer of fragile dielectric material can be previously formed. Device for method realization includes signal line in form of fragile and electric-conductive rod. Inside the rod a wire is placed, on which electrodes are mounted being in contact with rod and connected by conductors to recording equipment. Specific electric resistance of rod can depend on pressure. On surface of rod a layer of fragile dielectric material can be applied.

EFFECT: higher efficiency.

2 cl, 1 dwg

Description

The technical solution relates to mining and is intended to control the occurrence and propagation of cracks and delaminations in the rock mass.

There is a method of determining stratifications in the roof of mine workings according to ed. testimonial. USSR No. 1008445, class E 21 C 39/00, publ. in BI No. 12, 1983. In this method, drilling a hole is carried out in the roof. Then, a reference cylindrical rod made of brittle material is fixed in it using cement mortar. Ultrasonic pulsed oscillations are emitted into the rod. The presence of delamination in the roof is judged by the vibrations radiated into the cylindrical rod and reflected from the crack formed in it.

This method does not allow to determine the number of bundles and the distance between them. In addition, its implementation requires special acoustic equipment.

The closest in technical essence and the set of essential features is a method for determining the parameters of rock stratifications in the massif according to ed. testimonial. USSR No. 1196505, cl. E 21 C 39/00, publ. in BI No. 45, 1985, based on the registration of emerging cracks by fixing breaks in signal lines fixed in the well. In it, the signal lines are set on a square grid, the moments of breaks in the signal lines are recorded, and the velocity of the separation front is determined according to the established dependence.

The method allows you to control the parameters of stratification only in one plane passing through the wells within a given area.

A device for determining stratifications in the roof of mine workings according to ed. testimonial. USSR No. 1008445, class E 21 C 39/00, publ. in BI No. 12, 1983. It includes equipment for the emission and registration of ultrasonic pulsed oscillations and a reference cylindrical rod made of brittle material.

This device is complex due to the presence in it of equipment for radiation and registration of ultrasonic pulsed oscillations. It does not allow you to follow the process of formation of cracks that occur in several planes.

The closest in technical essence and the set of essential features is a device for determining the parameters of rock stratifications in the massif according to ed. testimonial. USSR No. 1196505, cl. E 21 C 39/00, publ. in BI No. 45, 1985. It contains a signal line made with recording equipment. The rod is made hollow of a dielectric material and is filled with an electrically conductive liquid under pressure. At the ends of the rod are plugs with electrodes.

The device is laborious to manufacture. It does not allow fixing the moments of cracking in several planes.

The technical problem to be solved is to increase the information content of the method due to the possibility of tracking the process of stratification of the rock mass in several planes at the same time and the efficiency of the device due to the simplification of the design and the possibility of fixing cracks that occur at different levels.

The problem is solved in that in the method for determining the parameters of rock stratifications in the array, including drilling wells, installing signal lines in them, fixing the moments of breaks in the signal lines and determining the parameters of the bundles, according to the proposed technical solution, electrodes with conductors for connecting to the recording equipment, and the signal lines are formed by filling the wells with a hardening mass, which after hardening forms brittle electrically conductive rods, w JCOMM coupled with the walls of wells, determining the change in electrical resistance between the electrodes and the time thereon judged parameters bundles of rocks in the array.

The formation of signal lines by filling the wells with a hardening mass, which, after hardening, forms brittle electrically conductive rods rigidly adhered to the walls of the wells, allows us to judge the parameters of the stratification of the rock mass by the change in the electrical resistance of these rods as a result of the formation of cracks in them. Installation in the wells at different levels of electrodes with conductors for connection to the recording equipment allows you to determine the change in the electrical resistance of brittle electrically conductive rods between the electrodes. Determination of the change in electrical resistance between the electrodes over time provides information on the nature of the formation of cracks throughout the volume of a brittle electrically conductive rod. The set of marked features provides the ability to monitor the process of stratification of the rock mass in several planes simultaneously. This significantly increases the information content of the method.

It is advisable to fill the well with a hardening mass, which after hardening forms brittle conductive rods, the electrical resistivity of which depends on pressure. This allows not only to monitor the process of separation, but also the nature of the deformation of the walls of the well, which significantly increases the information content of the method, because in this case it becomes possible to evaluate the change in stress in the array.

It is advisable to use a mixture of graphite powder, cement and water as a hardening mass. Such a mixture by changing the ratio of its constituent components allows the formation of brittle electrically conductive rods of various strengths and having a specific electrical resistance, which depends on the pressure and the presence of cracks in them.

It is advisable between the brittle electrically conductive rods and the walls of the wells to pre-form a layer of brittle dielectric material. This provides the ability to monitor the stratification process in rocks with any electrical conductivity.

The problem is also solved by the fact that in the device for determining the parameters of rock stratifications in the array, including a signal line in the form of a rod and electrodes connected to the recording equipment, according to the proposed technical solution, the rod is made brittle and electrically conductive, a wire is laid inside the rod on which electrodes are installed in contact with the rod and connected by conductors to the recording equipment.

The implementation of the rod brittle and electrically conductive allows you to record the moments of occurrence of cracks in it by changing its electrical resistance. Laying inside the wire rod, on which electrodes are installed, which are in contact with it and connected by conductors to the recording equipment, makes it possible, by the nature of the formation of cracks in this rod, to monitor the stratification of the rock mass in several planes simultaneously. In addition, the device has a simpler design compared to the prototype and therefore is more reliable in operation. All this increases the efficiency of the device.

It is advisable to carry a brittle conductive rod so that its electrical resistivity depends on pressure. This allows you to evaluate the change in stress in the rock mass.

It is advisable to apply a layer of brittle dielectric material on the surface of a brittle electrically conductive rod. This provides the ability to monitor the stratification process in rocks with any electrical conductivity.

The essence of the technical solution is illustrated by an example of a specific design and drawing.

The drawing shows a diagram of an implementation of a method for determining the parameters of rock stratifications in an array and a device for its implementation.

The method is implemented using the device as follows.

A well 1 is drilled in the rock mass, into which a device is supplied, including wire 2, bare at the end 3, electrodes 4 with conductors 5 installed on wire 2. In the well 1, signal lines (not marked) are formed by filling it with a hardening mass, which after hardening, it forms a brittle electrically conductive rod 6 (hereinafter the rod), rigidly adhered to the walls of the well 1 and having a specific electrical resistance that depends on pressure. Conductors 5 and wire 2 are connected to a recording apparatus 7 (for example, an electrical resistance meter). The change in electrical resistance between the electrodes 4 in time is determined, and it is used to judge the parameters of the bundles 8 and evaluate the change in stresses in the array. The bare end 3 of the wire 2 is used as one of the electrodes 4 (the last from the wellhead 1).

Note that on the curve of the change in electrical resistance between the electrodes 4 in time, the jumps correspond to the moments of cracking (rupture of the signal line by the delamination front 8), and its smooth change in time corresponds to the change in pressure on the rod 6 from the side of the walls of the well 1 (at the contact with the mountain pore ) Therefore, with the help of the same rods 6 with the indicated properties, the moments of rupture of signal lines (the formation of bundles) and the previous change in pressure in the rock mass (in rods 6) are recorded.

Wire 2 and conductors 5 are made of material (copper, aluminum), which, unlike rocks and rods 6, is capable of large deformations without destruction (wire break 2 or conductors 5). Therefore, after the formation of cracks in the rod 6, the electrical connection between the electrodes 4 and the resistance meter 8 is not violated. The thickness of the wire 2 is chosen so that it can be irrespective of the length (for example, a larger diameter of the excavation from which observations are made) to be fed into the well 1 by bending, but at the same time so that in the well 1 it holds the electrodes 4 at the required distance from each other .

In some cases (when the working diameter is greater than the length of the controlled section), the device is manufactured not in well 1, but in a collapsible cylindrical shape (hereinafter referred to as the form). To do this, wire 2 with electrodes 4 and conductors 5 is placed in a mold (not shown in the drawing), which is then filled with a hardening mass. After hardening the supplied mass, a rod 6 with the indicated properties is formed. This rod 6 is removed from the mold, fed into the well 1 and fastened with its walls with cementing material, which facilitates the implementation of the method for rising wells.

The formation of cracks (as a result of stratification of the massif) is preceded by deformation of rocks due to changes in stresses in the massif. Therefore, according to the deformation of the walls of the well 1, stress changes can be estimated. In the proposed method, the deformation of the walls of the well 1 is manifested as a change in pressure on the rods 6 (or inside the rods 6). Therefore, using rods 6, the electrical resistivity of which depends on pressure, it is possible to evaluate the nature of the change in voltage in the array by the change in time of the electrical resistance between the electrodes 4 installed inside the rods 6.

As a result of special studies, a mixture was found that allows the formation of rods 6 having the noted properties. This is a mixture of graphite powder, cement and water. The total volume of cement and water is determined from the requirements for strength, brittleness and electrical conductivity of the rods 6. It can reach up to 40% of the total volume of the mixture.

At a number of mines, the rock has a high electrical conductivity capable of shunting the rods 6. To the proposed method does not depend on the electrical properties of the rocks, between the rods 6 and the walls of the borehole 1 previously form a layer (not shown) of brittle dielectric material, for example, epoxy pitches. In the manufacture of the device using the mold (outside the well 1), a brittle dielectric material is applied to its surface before being fed into the well 1.

The drawing shows the simplest diagram of the implementation of the method. Using modern equipment, it can be used to create measuring systems for continuous monitoring of the stress-strain state of the rock mass at a given site or within the entire mining enterprise as a whole. It also allows you to monitor the status of artificial structures, such as dams of hydroelectric power plants.

The proposed method technically implements the idea of introducing elements of the measuring system into the rock mass, which are directly affected by the processes. Therefore, it is a direct measurement method and allows you to obtain reliable information regardless of the properties of rocks in the massif. When using several wells, it is possible to determine the velocities of the displacement of the stratification front (as in the prototype), the orientation of the stratification plane, monitor the development of stratifications along several planes at the same time, evaluate the nature of changes in stresses in the massif, and diagnose (determine the deformation of rocks, the nature of the development of cracks, the stability of mountain workings) of the rock mass in a given area. In addition, even one well allows you to evaluate the change in stress in a specific area of the rock mass, determine the number of bundles and the distance between them. The method and device can be applied at any mining enterprises using simple standard means.

Claims (7)

1. The method of determining the parameters of rock stratifications in the array, including drilling wells and installing signal lines in them, fixing the moments of breaks in the signal lines and determining the parameters of the bundles, characterized in that electrodes with conductors are installed at different levels in the wells for connecting to recording equipment, and the signal lines are formed by filling the wells with a hardening mass, which after hardening forms brittle electrically conductive rods, rigidly adhered to the walls of the wells, determine the time variation of the electrical resistance between the electrodes and it is used to judge the parameters of rock stratification in the massif. 2. The method according to claim 1, characterized in that the wells are filled with a hardening mass, which after hardening forms brittle electrically conductive rods, the electrical resistivity of which depends on pressure. 3. The method according to claim 1 or 2, characterized in that the mixture of graphite powder, cement and water is used as a hardening mass. 4. The method according to any one of claims 1 to 3, characterized in that between the brittle electrically conductive rods and the walls of the wells, a layer of brittle dielectric material is preliminarily formed. 5. A device for determining the parameters of rock stratification in the array, including a signal line in the form of a rod and electrodes connected to recording equipment, characterized in that the rod is made brittle and electrically conductive, a wire is laid inside the rod on which electrodes are installed that are in contact with the rod and connected by conductors to the recording equipment. 6. The device according to claim 5, characterized in that the electrical resistivity of a brittle electrically conductive rod depends on pressure. 7. The device according to claim 5 or 6, characterized in that a layer of brittle dielectric material is applied to the surface of the brittle electrically conductive rod.