UA142553U - METHOD OF EXPLOSION OF AN EXPLOSIVE WELL - Google Patents

Abstract

The method of driving an explosive well includes drilling a well, filling it with explosive, placing in the explosive means of initiation and execution of driving. To plug the well, the polymer container, the diameter of which is not larger than the diameter of the well, is filled with compressed air and fed into the well with a filling neck towards the wellhead and moved to a given distance from the explosive, then fill with compressed air a second hollow polymeric container. for the diameter of the well, and feed the specified polymer container into the well with the filling neck towards the mouth of the well and move to a predetermined distance to the neck of the first hollow polymer container. Between the first and second polymer tanks have n-polymer tanks, the diameter of which is not larger than the diameter of the well, filled with compressed air and placed with the neck towards the mouth of the well.

Description

The useful model belongs to the mining industry and can be used to increase the efficiency of rock destruction during mass blasting in the underground development of mineral ore deposits.

In particular, the useful model is used as a plug of the well charge, which provides isolation of the explosive substance from the production space to prevent the breakthrough of gases and prevent the reduction of the dynamic effect on the rock mass for its subsequent crushing.

There is a known method of mechanical plugging of explosive wells after filling them with an explosive substance (Russian Patent Mo 164461 for a useful model).

Implements mechanical hammering by a device made in the form of a wedge-type strut, containing a structural main outer sleeve with at least two sliding structures in the form of longitudinal cheeks, spatially oriented along the axis of the strut shutter, and also a wedge element placed in the cavity of the outer sleeve, which contacts its main outer wedge surfaces with the inner surfaces of sliding structures facing them in the form of longitudinal cheeks of the outer sleeve.

Technological channels are structurally formed in the component parts of the spacer valve.

Technological channels are functionally the means for placing the conductors of the detonator pulse that initiates. Technological channels are spatially arranged with the possibility of removing the free ends of the conductors beyond the spacer shutter.

The outer sleeve is made with an end surface, which is functionally a surface for providing an external dynamic action on this end surface with the help of a technological punch.

The method is implemented as follows.

Before installing the shutter, the spacer provides a kinematic connection of the outer sleeve with the wedge element using a ratchet. Next, the profile projection of the rod element is connected to the corresponding structural element of the technological slaughterhouse. After that, the conductors of the initiating pulse are placed in the technological channels. Then the specified system is introduced into the cavity at a given distance, which excludes the contact of the end surface of the wedge element with the explosive charge, and preliminary wedging of the spacer shutter in the cavity is carried out with the help of a movable element of the technological

From the butcher due to the interaction of this element of the butcher with the end surface of the outer sleeve. At this stage, the additional sleeve is also wedged in advance in the cavity, and the means of additional fixation of the plug in the hole or well were squeezed out in the cavity, filling all possible voids.

The final wedging of the spacer valve in the cavity, including the sleeve and means of additional fixation, is carried out in the process of detonation of the explosive charge due to the action of the explosive wave on the end surface of the wedge element of the spacer valve.

When the explosive substance is initiated, the external dynamic action is carried out along the axis of the spacer shutter in the process of preliminary wedging of the spacer shutter in the production cavity by forced movement of the outer sleeve relative to the wedge element. At the same time, the end surface of the smaller area of the wedge element is equipped with a rod element, which is located along the axis of the spacer shutter and passes through the hole made in the end surface of the outer sleeve with an exit beyond it in the direction of the mouth, at the end of the rod element, on the side of the mouth, a profile structure is made.

The disadvantage of the known method is that the device that implements the method is characterized by a rather large complexity of the design, which causes the probability of failure when it interacts with the gases formed as a result of the explosion. Inefficient operation of the device leads to the breakthrough of gases into the production and, accordingly, a decrease in the dynamic effect on the mountain massif.

A known method of mechanical plugging of explosives in wells and holes during underground development of ore deposits (Russian Patent No. 2695904 for the invention).

To implement the method, a device in the form of a spacer valve is used, which includes a spacer with a central hole and a structure equipped with a rod element that passes through a hole made in the spacer and extends beyond it in the direction of the mouth. At the end of the rod element, a profile structure is made, which is a means of its capture during the preliminary wedging process. The structure is spatially located opposite the spacer with the formation of a gap between their mutually inverted end surfaces. The strut is either a resilient umbrella structure or a rigid compression structure. Between the mutually inverted end surfaces of the strut and the support structure, a means of additional fixation of the plug is placed, equipped with a central hole and in contact with the specified surfaces of the support structure and the strut. The rod element is kinematically connected to the spacer 60 by means of an umbrella-type ratchet coupling, the locking elements of which are placed along the length of the rod element and on the inner surface of the hole of the spacer with the possibility of their preliminary fixation before the plug is installed in the cavity.

An additional means of fixation can be made in the form of an elastic element made of rubber or in the form of an ampoule, which is filled with a hardening structure.

To implement the well plugging method, before installing the spacer valve in the cavity, ensure the installation of an additional fixing device on the rod element of the stop device. Next, the kinematic connection of the spacer with the rod element is carried out by means of a ratchet engagement and preliminary pressing of the means of additional fixation is carried out between the mutually inverted end surfaces of the spacer and the structure of the spacer. Then the shutter of the spacer assembly is installed at a technologically specified distance, the conductors of the detonator, which initiates the pulse, are brought out of the mouth of the hammer and provide external dynamic action with the help of a hammer on the structure of the spacer, thereby ensuring its movement along the rod element and the final compression of the means of additional fixation. Thus, the plug in the assembly is held due to the force of rest friction between the mutually inverted surfaces of the means of additional fixation.

The disadvantage of the known method is that during the impulse action on the plug, it does not ensure reliable closing of the well, since the primary area of interaction of the device with the walls of the well or hole is minimal. This area increases as the blast wave acts, and since this action is pulsed, the increase in contact of the device with the walls of the well occurs with a delay, which causes a significant displacement of the plug until it falls out of the well mouth.

There is a known method of installing a plug in the cavity of a hole or a well (Russian Patent No. 2656629 for the invention). The hammer is placed in contact with the surface facing it, fixed along the longitudinal axis of the production of the resisting agent. After that, an external axial dynamic action is performed on the filling with the possibility of changing the structure of the composition, in particular, mixing its components or structural compaction. With this help, they ensure the hardening of the composition in the zone of the technologically regulated location of the plug. As a fixed abutment with a surface that is in contact with the mentioned filling, a technological structure is used, which is constructively performed with the possibility of its

From placement in the cavity. For this purpose, a stop-measuring element rigidly connected to the technological structure is used, with a means of its positioning in the cavity and the subsequent fixation of this stop means relative to a fixed basic structure, for example, a section of the rock surface at the place of a stop means of a regulated installation in the production cavity.

Constructive variants of the performance of the resistant means are provided.

The disadvantage of the known method is the high cost of plugging the well due to the fact that the plugging is carried out in combination with the use of a hardening solution and a mechanical device. This increases the cost of blasting and requires significant labor costs when equipping wells. The design of the device leads to the possibility of inefficient clogging due to the impulse action of the shock wave during the detonation of the explosive substance, in which the structural elements of the device do not have time to ensure the closure of the cavity of the explosive well or hole in a regulated manner.

The task of the useful model is to improve the method of plugging the explosive well due to: filling the polymer container with compressed air; placement of a container filled with air in the well cavity; placement of the container in the well with the neck towards the mouth of the well; filling the second container with compressed air; placement of the second container filled with air in the well cavity; placement of the second container in the well with the neck towards the mouth of the well; placement of containers at a given distance from the explosive substance; in the variant execution of the well charge, placement of n-containers filled with compressed air, located with the neck towards the mouth of the well between the first and second containers filled with compressed air. placement in the well of containers filled with compressed air, the diameter of which does not exceed the diameter of the well.

The task is solved due to the fact that the method of plugging an explosive well during underground development of ore deposits includes drilling a well, filling it with an explosive substance, placing means of initiation and plugging in the explosive substance.

According to a useful model, for plugging a well, a polymer container, the diameter of which is at least larger than the diameter of the well, is filled with compressed air and fed into the well through the filler neck towards the wellhead and moved to a given distance from the explosive. The second polymer container, the diameter of which is not larger than the diameter of the well, is filled with compressed air, and the polymer container is fed into the well through the filling nozzle towards the mouth of the well and moved to the specified distance to the mouth of the first hollow polymer container.

To improve the quality of isolation of the explosive substance, in the well charge between the first and second polymer containers, n-polymer containers are placed, the diameter of which is not larger than the diameter of the well, filled with compressed air, which are placed with the neck towards the wellhead.

The technical result of the use of a useful model is that: the volume of labor costs when plugging an explosive well is reduced; the cost of blasting works decreases; the quality of mining massif crushing increases during underground mineral development; high quality isolation of gaseous products formed during the initiation of an explosive substance is ensured. the method can be implemented with any designs of well charges; implementation of the method does not require special equipment for hammering.

The method is implemented as follows.

Well charges are drilled, according to the passport of drilling and blasting works. After drilling wells, they are charged by placing explosives and initiation means in the well cavity.

A plug is formed in a charged well. For this, a cylindrical container, the diameter of which does not exceed the diameter of the well, is filled with compressed air.

The use of containers, the diameter of which does not exceed the diameter of the well, is due to the fact that when the diameter of the containers increases, it becomes difficult to move them into the cavity of the well during plugging. In addition, if the diameter of the container exceeds the diameter of the well, then due to the friction of the container against the surface of the well, the integrity of the switching means is destroyed, which can lead to failures during mass explosions and, as a result, unregulated destruction of the rock massif, which worsens the quality indicators of the underground

From the development of mineral deposits.

The container filled with air is fed into the well at a given distance from its mouth. The main condition for placing the indicated container is that the filling nozzle should be directed towards the mouth of the well. After placing the container, a second container is fed into the well, which is also pre-filled with compressed air. The second container, as well as the first one, is fed in the same way - through the filler neck toward the wellhead until the filler neck of the first container comes into contact with the bottom part of the second container.

Similarly, all wells intended for mass explosion are plugged.

When the explosive substance is initiated, the gaseous products of the explosion, which are formed while moving in the well, affect the end part of the container. Due to the impulse action on the end part of the container, its side walls are expanded, increasing the pressure on the walls of the well, thereby completely covering its section. Complete final overlap of the well section is achieved due to the fact that the area of the end part of the filling neck of the first container is much smaller than the area of the bottom part of the end part of the second container.

During the impulse action of gaseous products, the filling nozzle of the first container, shifting, affects the bottom part of the second container filled with compressed air. Due to the significant difference in the areas of the interacting bodies, a significant deformation of the second container occurs, thus increasing the interaction with the walls of the well and closing its section from the breakthrough of gaseous explosion products.

In the case when charges of increased power are used during a mass explosion, it is necessary to increase the degree of isolation of the well from the breakthrough of gaseous products. To do this, n-polymer containers are placed between the first and second polymer containers, the diameter of which is not larger than the diameter of the well, filled with compressed air and placed with the neck towards the mouth of the well. The number of polymer containers is determined depending on the mass and design of the explosive charge and the length of the well.

Claims (2)

USEFUL MODEL FORMULA 1. The method of plugging an explosive well, which includes drilling a well, filling it with an explosive substance, placing means of initiation and plugging in the explosive substance, which is distinguished by the fact that for plugging a well, a polymer container, the diameter of which is not larger than the diameter of the well, is filled with compressed air and fed into the well through the filler neck toward the wellhead and moved to a given distance from the explosive substance, after which a second hollow polymer container, the diameter of which is not larger than the diameter of the well, is filled with compressed air, and the indicated polymer container is fed into the well through the filler neck toward the wellhead and moved to a given distance to the neck of the first hollow polymer container. 2. The method according to claim 1, which differs in that between the first and second polymer containers, p-polymer containers are placed, the diameter of which is not greater than the diameter of the well, filled with compressed air and placed with the neck towards the mouth of the well.