RU2018661C1 - Method for breaking monolithic objects - Google Patents

Abstract

FIELD: mining and construction. SUBSTANCE: method includes drilling of hole, installation of extended working member of hydraulic breaking device, high-pressure air hose and pneumatic cartridge, sealing of hole mouth with packer. To form cracks, pressure in breaking device is raised. After pressure drop in breaking device, static air pressure is raised in high-pressure air hose, air is supplied to hole up to pressure stabilization in extending working member, and compressed air is supplied to pneumatic cartridge up to its operation. Supply of compressed air is continued up to stabilization of pressure in extending working member. Supply of compressed air tp pneumatic cartridge is discontinued only after breakage of monolithic object. EFFECT: higher efficiency.

Description

 The invention relates to mining and construction and can be used for coal and ore mining, the destruction of oversized, foundations and other monolithic objects.

 A known method of destruction of rocks, including drilling a hole, placing a pneumatic chuck in it, increasing the air pressure in the pneumatic chuck to a predetermined value, cutting off the air supply after reaching a predetermined pressure, and air flowing out of the pneumatic chuck into the array through the exhaust holes in the pneumatic chuck, increase in air pressure in the pneumatic cartridge to a predetermined value and so on [1].

 The disadvantage of this method is the short-term compared with the time of the entire cycle, the impact of a pulse of compressed air on the array and therefore the low efficiency of the method.

 A known method of destruction of rocks, including drilling a hole, placing an expansion member of a hydraulic destructive device therein, destroying an object by increasing hydraulic pressure in a destructive device, disabling the hydraulic device when pressure drops therein, in which bore holes are drilled to improve the quality of a split in a plane the planned split, in all the boreholes place the spacer working bodies of hydraulic destructive devices and increase the pressure first simultaneously in of all destructive devices, carry out a cyclical increase in hydraulic pressure in the destructive devices with the shutdown of those in which there is a drop in hydraulic pressure [2].

 The disadvantage of this method is the low efficiency of destruction due to the inability to provide with it the collapse of the rock.

 The aim of the invention is to increase the destruction efficiency by obtaining a rock collapse.

 The goal is achieved by the fact that in the method of destruction of rocks, including drilling a hole, placing an expansion member of a hydraulic destructive device therein, cracking an object with an increase in hydraulic pressure in a destructive device, and disabling the hydraulic destructive device when pressure drops in it, additionally place high-pressure air hose and pneumatic cartridge, and the mouth of the hole is sealed, for example, with a packer, after a pressure drop in the spacer working body is increased static air pressure in a high-pressure air hose, supplying air to the hole, until the pressure in the expansion tool is stabilized and begin to supply compressed air to the pneumatic chuck until it operates, after which they continue to supply compressed air until the pressure stabilizes in the expansion tool and stop the air supply to the pneumatic chuck only after a rock collapse.

 The inventive act in creating the method consists in the fact that for the first time the author established the phenomena of effective production of long cracks in an array, provided that the initial cracks were obtained by drilling a hole using a spacer of a hydraulic destructive device, further crack propagation was carried out by applying static air pressure to the initial cracks through a high-pressure air hose, and the complete destruction of the rock is carried out by supplying pulses of compressed air through a pneumatic cartridge into long cracks s in the array. This is due to the fact that initial cracks can be most effectively obtained using spacers of hydraulic destructive devices, the continuation of cracks to the formation of long cracks in the massif is easily obtained by injection of compressed air directly into the short cracks formed, and then the collapse of the rock is most easily obtained by “shaking” array over its entire volume, applying pulses of compressed air through a pneumatic cartridge to the long cracks formed. This phenomenon was not previously known, and therefore, operations to form long cracks by applying static air pressure to dry previously formed short cracks and then to collapse the rock by applying pulses of compressed air to previously formed dry long cracks confirm the inventive step of the method. To achieve this goal, the following distinctive features of the method are necessary and sufficient: 1) a high-pressure air hose with the possibility of applying static air pressure to the hole with it is placed in a hole in addition with a spacer working body of a hydraulic destructive device; 2) in addition to the pneumatic chuck with the ability to supply pulses of compressed air to the hole in the hole, in addition with the spacer working member of the hydraulic destructive device and high-pressure air hose; 3) the mouth of the hole is sealed, for example, with a package; 4) after the pressure drop in the spacer working body of the hydraulic destructive device, increase the static air pressure in the high-pressure air hose, supplying air to the hole; 5) air is fed into the hole from a high-pressure air hose until the pressure stabilizes in the spacer working body; 6) after stabilization of the pressure in the spacer working body by applying static air pressure to the hole in the same hole, compressed air begins to be supplied to the pneumatic cartridge before it is triggered; 7) the supply of compressed air to the pneumatic cartridge is continued until the pressure in the spacer working body is stabilized and the supply of compressed air to the pneumatic cartridge is stopped only after a rock collapse. The set of seven distinctive features of the method meets the criteria of "Novelty" and "Significant differences".

 The method of destruction of rocks is implemented by the following sequence of operations.

 Drill a hole so that in the drilled hole it was possible to install a spacer working element of a hydraulic destructive device, a high-pressure air hose, a pneumatic chuck and a packer to seal the mouth of the hole after installing a spacer, a high-pressure hose and a pneumatic chuck in the hole.

 A working spacer body of a hydraulic destructive device, a high-pressure air hose with the possibility of applying with its help static air pressure either directly into the hole, or into the pneumatic cartridge, also placed in the hole, is placed in the drilled hole.

 The wellhead is sealed, for example, with a packer.

 The hydraulic pressure of the liquid in the destructive device is increased until the pressure in it first stabilizes and then begins to drop. First, with increasing pressure, the spacer working member effectively forms initial cracks in the walls of the hole. When pressure is stabilized, the efficiency of the formation of initial cracks decreases and when the pressure drops in the destructive device, the process of formation of initial cracks stops.

 When the pressure drops in the destructive device, it is turned off, for example, by stopping the supply of liquid to it.

 After the pressure drop in the spacer working body of the hydraulic destructive device and its shutdown, they begin to increase the pressure in the high-pressure air hose, supplying compressed air directly to the hole. In this case, compressed air enters the dry (without injection of liquids in them) initial cracks and, forming high pressure in them, leads to elongation and broadening of the initial cracks. While this process is developing efficiently, the pressure in the destructive hydraulic device is increasing. When pressure is stabilized in a hydraulic destructive device, the process of elongation and broadening of the initial cracks decreases, since part of the compressed air leaves the array through the long and wide cracks formed in the array.

 After stabilization of the pressure in the spacer working body, they begin to supply compressed air to the pneumatic cartridge before it is triggered. After that, the air supply to the pneumatic cartridge is continued until the pressure in the spacer working body is stabilized and the compressed air supply to the pneumatic cartridge is stopped only after a rock collapse.

 After placing a hydraulic destructive device, a high-pressure hose and a pneumatic chuck in the drilled hole of the spacer working body and sealing the mouth of the hole, for example, with the help of a packer, the pressure in the hydraulic destruction device is increased. Moreover, with increasing pressure, the pressure of the spacer working member on the borehole walls increases approximately proportionally at first, as a result of which initial cracks form in the borehole walls. The working body of the hydraulic destructive device is designed so that when cracks form in the walls of the borehole, the liquid does not leak out of the hydraulic destructive device and does not fall into the borehole and its walls. The increase in hydraulic pressure in the destructive device is carried out until the pressure in its spacer working body begins to drop. This will indicate that the process of formation of initial cracks in the walls of the hole is basically over. After that, the hydraulic destructive device is turned off, that is, the increase in the hydraulic pressure of the incoming liquid is stopped.

 Now increase the pressure in the high-pressure air hose. Compressed air enters the hole, fills the previously formed initial cracks and under its action the cracks increase in length and width, that is, long cracks form in the massif to be destroyed. With the effective formation of long and wide cracks, the pressure in the hydraulic destructive device first increases, since compressed air forms cracks and does not leave the rock mass, but also presses on the hydraulic destructive device, increasing the pressure in it. The stabilization of pressure in the hydraulic demolition device indicates that the process of formation of long cracks in the massif is on the decline, which is due to the beginning of the release of part of the compressed air from the massif through the formed long and wide cracks.

 After stabilization of the pressure in the hydraulic destructive device, compressed air begins to be supplied to the pneumatic cartridge before it is triggered. When the pneumatic chuck is triggered, the air in a pulsed mode under excess pressure through the exhaust holes enters the previously formed long slots and effectively destroys these cracks after each subsequent operation of the pneumatic chuck. With the next actuation of the pneumatic cartridge, an increasing amount of air enters the drilled hole under high pressure and long cracks and the entire mass of the rock are more and more destroyed. In this case, at first the pressure in the spacer working body gradually increases, since compressed air also presses on it. Some time after the increase in pressure, it begins to stabilize. This indicates that a significant part of the air begins to escape through the resulting cracks from the array. Then the pressure in the spacer working body of the hydraulic destructive device and, accordingly, in the hole will begin to drop, which indicates the intensity of air out of the hole during the collapse of the rock.

 The effectiveness of the new method of destruction of rocks is confirmed by subsequent data.

The first stage of coal breaking begins with the formation of a flat crack that cuts the formation along the normal to the roof and the soil of the formation in parallel at the distance of the line of least resistance from the free surface. Initial conditions: in a well with a diameter of 100 mm, an expanding working element, a diameter of a rubber sleeve of 80 mm, a diameter of metal plates of a spacer working body of 100 mm, a well diameter of 110 mm, a formation thickness of 2.5 m. Coal f = 2.5, tensile breaking stress σ ^x = 25 kg / cm ² . The maximum pressure in the spacer working body is 38 MPa. The force developed with the help of a spacer working body per 1 cm of the length of the well in the radial direction is 4180 kg / cm ² . The total length of radial cracks on both sides of the well is 167.2 cm.

The next stage is the supply of a pulse of compressed air with a pressure of 70 MPa into the formed cavity. In this case, the crack will completely split the formation. At 1 cm along the length of the well in the fracture and in the well, the gas pressure will be 65 MPa. The area of action of the force to which the compressed air pressure is applied is 200 cm ² . Strength 130,000 kg. Given the resistance of coal to 250 kg / cm ² , even at narrowing, destructive forces are obtained with a line of least resistance of 520 cm.

 Compare with conventional blasting. The force developed by the cartridge without a spacer working element just in the well is 7700 kg, which is almost 17 times less. The above is a static calculation. In fact, the process of loading and fracture in dynamics, characterized by loading speeds of about 400 m / s and the propagation of cracks at a speed of 500-600 m / s. Therefore, gas leakage due to porosity and microcracks of coal occurs only within 10-15%. These losses are compensated for by the dynamic impact and sealing of the well by a spacer working body. Therefore, compressed air is used to destroy coal in wells without a power element, that is, without a spacer working body — open from the end and without cracks, transforming power loads by 17 times.

 The technical advantages of the new fracture method compared to the prototype are: obtaining longer and wider cracks in the mass to be destroyed, the ability to effect directional fracture, reducing the number of drill holes and fracture tools used due to the rarer grid of drill holes.

Claims (1)

 METHOD OF DESTRUCTION OF MONOLITHIC OBJECTS, including drilling a hole, placing a spacer working member of a hydraulic destructive device therein, cracking the object with increasing hydraulic pressure in the destructive device, and disabling the hydraulic destructive device when pressure drops in it, characterized in that a high-pressure air hose is placed in the hole and pneumatic cartridge, and the mouth of the hole is sealed with a packer, after the pressure drop in the spacer working body, increase the static pressure in air in a high-pressure air hose, supplying air to the hole, until the pressure in the expansion tool stabilizes and begin to supply compressed air to the pneumatic chuck until it operates, after which they continue to supply compressed air until the pressure stabilizes in the expansion tool and stop supplying compressed air to the pneumatic cartridge only after the collapse of the monolithic object.