UA28126C2 - - Google Patents

Claims (2)

шо (51)6 Э21843/25, 43/28, 43/26 MINISTRY OF EDUCATION AND SCIENCE OF UKRAINE OP YS DEPARTMENT OF INTELLECTUAL AND OWNED TO THE PATENT FOR THE INVENTION OWNED BY nn (54) METHOD OF PROCESSING MINE ROCK MASSIVE THROUGH DRILLING AND EQUIPMENT 21) 98073974 main lines, an emitter installed in a (22)21.07.1998 bi-waveguide, a reflector and a system of automatic (24)16.10.2000 control of the process of loading the massif of rock (33) OA, containing a limit switch, mutual (46) 16.10.2000, Bull. Mo. 5, 2000 modulating with a limiter of forward and reverse (72) Gurov Vadym Mykolayovych, Zyugan Anatoliy of the emitter stroke, and hydraulically connected with the piston cavity of the hydraulic cylinder and with the drain Volodymyr Mykolayovych, Oleksandr Ruzhynskyi main line, which differs in that the automatic system for controlling the loading process (73) Gurov Vadim Mykolayovych, TSA, Zyuhan Anato of the rock massif additionally contains a terminal oil Ivanovych, OA, Mykhailo Borisovych Kolisaev, a switch installed with the possibility interaction of CA, Ostapenko, Volodymyr Mykolayovych, OA, Ru with the limiter of the forward stroke of the emitter, and Zynsky Oleksandr Lvovich, SHA, Sedler Ivan hydraulically connected to the unit for regulating the time and energy of shock waves, made in the form of (56) 1 A. p. USSR Mo. 1701896, E218B 43/28. parallel connected regulators out- 2. A. p. USSR Мо 1301024, Е21В 43/26, 43/28 working fluid extraction, the inputs of which are hydraulically connected with the piston cavity of the hydraulic cylinder through the boreholes, which includes the operations of breaking to create static pressure, the outputs through the formation of a mineral bed through a well, a switch with a hydraulic motor for distributing fluid into the well, the effect of a spool made with the possibility of an alternating transducer on the liquid column by static pressure and the connection of the pressure and drain mains with the shock waves that are transmitted along the liquid frame of the forward and reverse motion of the shock-SM waveguide generator through the reflector into the bed of rock, these waves, respectively, and the gas consumption regulator, which differs in that the shock waves of the generator of the working fluid, the input of which is connected to the mechanism of low and high frequencies with different energy of the supply of the working fluid, and the output through the return stroke, which alternately affect the array valve, connected to the cavity of the pipe- mining rock, and the duration of the impact of the shock waveguide, which is made of a composite one, and in them, waves of the same frequency change the function of the emitter located in the upper part, and in the "SM of the lithological properties of the processed massif, the bottom, perforated with longitudinal grooves, of mining rock . bivach 00 CM 2. The device for processing the massif of mining rock Z. The device according to claim 2, which differs in that in the borehole, which includes on one axis of the waveguide installation in front of the reflector, a new hydraulic cylinder is installed to create a static partition with a throttle hole, the diameter of which pressure , a shock wave generator, composed of cor- is equal to or a multiple of the pulse wavelength, inside which a piston is placed, which 4. The device according to claim 2 or 3, which differs in that it forms a forward-moving chamber, connected to the forward- that the width of the longitudinal grooves in the lower part of the trunk line, and the return chamber, which would be a waveguide equal to or a multiple of the wavelength. is alternately connected to the pressure and drain 0" The invention relates to mining and can place of occurrence, which includes mining operations in flooded mining massifs, the operation of loosening the layer of mineral deposits and for draining wells, by changing the well, feeding fluid into the well, the physical and mechanical properties of the mining massif, the impact on the liquid column by static pressure, generu- rock. shock waves and their transmission through a liquid waveguide through a reflector into a layer of mining gas includes the operations of loosening a layer of useful DIGI mineral by a well, feeding it into the well. , and shock waves that are caused by the inhomogeneity of the acoustic waves are transmitted along the liquid waveguide through the reflective properties of the densified massif from the liquid into the layer of slag rock, west of the invention, by the waveguide In the process, forcefully! mass processing - shock waves generate low and high frequency from the rock, there is an intense mixing of different impact energy, which alternately affects the solid microparticles that are in the rock mass, and the three-layer waveguide, and particles, which are formed due to the impact of shock waves of the same frequency during the formation destruction process, which prevents the complete filling of the formed microcracks and pores in the formed massif of the slag rock and leads to the deterioration of the physical and mechanical properties of the formation. The problem is solved by the fact that in complexes for the stiffness of the liquid waveguide, violation of its implementation method, which includes on one axis of homogeneity, continuity and, ultimately, a hydraulic cylinder is installed to create a static - to reduce its operational properties and pressure, a shock wave generator composed of a sharp drop in work efficiency the waveguide, the body, inside which the piston is placed, what what making the method energy-intensive, it forms a forward-flow chamber connected to a pressure- The closest in technical essence is the device mainstrale, and a reverse-flow chamber, which, to control the permeability of the mining rock, is alternately connected to a pressure drain, which includes a hydraulic cylinder for creating static mainstrales, an emitter , installed at the coffin pressure, a shock wave generator, consisting of a bi-waveguide, a reflector and an automatic body system, inside which a piston is placed, which controls the process of loading the prny massif - forms a straight-line chamber, connected to the supporting rock, containing The end switch, connected by a main line, and the reverse travel chamber, which, modulating with the forward and reverse limiter, is alternately connected to the pressure and drain lines of the emitter, and is hydraulically connected to the main line, the emitter installed in the piston cavity of pdrocylinder I with drain cavity pipe-waveguide, a reflector installed in the main line According to the invention house, automatic wells, automatic control system, control system of the loading process of ma- the loading process of the massif of mining rock, gray prnych rock additionally contains the end that contains the end switch that interacts with the switch installed with the possibility of interaction! limiter of the forward and reverse stroke of the emitter, with the limiter of the forward stroke of the emitter, and the watcher, and hydraulically connected to the piston hydraulically connected to the control unit by the frequency cavity of the hydro cylinder and with the drain line and the energy of shock waves, made in in the form of (2) regulators connected in parallel with each other. The disadvantage of the given device is the low consumption of the working fluid, the inputs of which are hydraulically efficient in using the energy of shock waves and are limited in functionality due to the absence of static pressure, exits through kKIN- of feedback between physical and mechanical own switch with a hydraulic motor for distributing the current of the processed massif of the mining spool, made with the possibility of alternating rock and its loading mode, the combination of the pressure and drain mapstrale with the camera. In addition, the impossibility changes in the mode of forward and reverse motion of the array shock-pull generator, which is processed, at a high THEIR WAVE ACCORDINGLY, AND! the regulator of the well acceptability consumption in the liquid wave-working fluid, the input of which is connected to the di mechanism, the formation of gaseous inclusions is possible, which supply the working fluid, and the output through the return leads to a violation of homogeneity and the continuous valve is connected to the cavity of the wave pipe liquid waveguide and lowering its explo- water, which is made of folded, and the emitter is placed in the upper part of the choke, extraction of minerals through the well, installed with the possibility of combining and by changing the load mode of the massif of rock components In the waveguide pipe in front of the reflector of the rock, to ensure acoustic uniformity, a partition with a choke hole is installed, decompression of the massif of rock with a liquid diameter equal to or a multiple of the wavelength of the waveguide and due to this to significantly increase the width of the longitudinal grooves in the lower part of the pipe - the efficiency of the method and reduce its energy - the waveguide is equal to or a multiple of the wavelength of the waveguide due to the fact that in the claimed method rock through drill-pour a device for the implementation of the method, by fault, shock waves generate low and high introduction of additional elements in a new interaction frequency with different energy of the impact, which communication, provide automatic control re- alternately affect the array of prnic rock by pressing load massif of mining rock in the presence of static pressure, and the duration depends on its lithological properties and due to the influence of shock waves of the same frequency due to this increase the efficiency of the device and spread CHANGING IN THE FUNCTION OF LITHOLOGICAL properties its functional capabilities of the processed massif of mining rock, the problem is solved by in sp during the processing itself, the massif is alternately processed by power forces of the massif of mining rock through the well, which pulses of low frequency and high energy for the formation of cracking and high frequency, for juicy frequency, to fill the formed water 28 with liquid enters the well ZO, reinforced with cracks, the efficiency of the next system increases casing pipe 31 with profile holes 32 of low-frequency processing. This made it possible to create acoustic homogeneity of the decompacted fluid flow distributor inlet 34 connected to the array with the liquid waveguide. i.e., complete with the pump 35, and the outlet - with the pressure line 8, filling the cracks and pores with the liquid in the place of the shock treatment. 8 and tivity of the method and reduce its energy consumption by draining 10 mag arrows The design solution of the control system An example of the implementation of the method of processing the massif with a shock wave generator in connection with the mining rock through the wells by the end mechanisms of the complex made it possible to implement an effective method of processing the massif of the rock mass with a 200 mm diameter ZO borehole, which is reinforced with no rock Automatic by the casing column control system 31 with profile holes 32 by the mode of alternate processing of the massif of mining rock. and the reflector 13 Into the waveguide tube 12, the working fluid 28 is compressed under a pressure which, regardless of the delatant properties, exceeds the processing pore by at least 1.5 times, based on the mass of the mass and, due to this, to compensate for the mining pressure, on p to increase the efficiency of the device and extend its functionality in the waveguide tube 12. The working fluid 28 is pumped into the waveguide tube 12 until the level is reached, The essence of the invention is explained by the drawings, placed with the uppermost position of the emitter 11. After that, the column of working fluid 28, Fig. 1 - the general view is presented, is affected by shock waves in the presence of a stator for the implementation of a method of processing massive pressure, which are transmitted through liquid wave-bearing rock through wells, du 28 through reflector 13 into the surrounding mountain massif Fig. 2 - liquid waveguide in a borehole of no rock. In the process of processing the massif is generated The device for the implementation of the method includes a hydraulic cylinder 1 with a piston impact energy, which alternately affects 2 and a rod with cavities to create a solid mass of rock in the presence of static pressure, installed on low and high frequency shock waves with different one axis, a shock wave generator 4, composition of pressure. Moreover, the duration of exposure to shock waves from the body 5, inside of which is placed one-frequency pulses are changed in the function of dilations b, forming a direct travel chamber 7, depending on the properties of the mining rock connected to the pressure line 8 and the spring chamber. Thus, processing of the massif of mining rock of the main course 9, which is alternately connected to the shaft, is carried out cyclically, that is, in two stages. On the primary 8 and drainage 10 mains, the radiating stage performs power treatment of the formation from the part 11 and installed in the waveguide pipe 12, and reflected by the tota and energy that create the pressure amplitude, vach 13 Automatic process control system that exceeds the voltage compressive-tensile in the plane of the som load of the massif of mining rock contains a layer that ensures delatant deformation and the end switch 14 with contacts "b", "v", due to densification of the massif. by waves with a frequency of 16, 17 of the stroke of the emitter 11. The final switch is not less than 75 Hz, the value of which is set by the valve 14, which is hydraulically connected to the piston in the following way, starting from the physical and mechanical part 2 of the hydraulic cylinder 1 and with the drain line of the granulometric composition of the liquid in the well Additional limit switch 18 from the contact As a result, at this stage of processing, we will create "d", "d", set with the possibility of interaction conditions to ensure increased fluidity and more complete filling of cavities, 11, it is hydraulically connected to the control unit formed from the previous power processing of the frequency and energy of shock waves 19 , made at a low frequency, which creates a more uniform acoustic conductivity of the parallel-connected regulators and increases the efficiency of the working fluid consumption units 20, 21, the inputs of which are hydraulically connected to the piston cavity 2 of which frequency The processing time at each stage is selected hydraulic cylinder 1 to create static pressure is determined experimentally and set- outputs through the limit switch 18 with a hydromotor depending on the physical and mechanical properties of 22 distribution valve 23 made of rock the place of occurrence within the possibility of alternating connection of the pressure 8 and at least 5-10 minutes of drain 10 mains with cameras of direct 7 and the device for implementing the method of reverse 9 stroke of the shock wave generator 4, in a step manner ACCORDING to the working fluid consumption regulator The installation is brought to the well ZO Gene- 24 input is connected to the liquid supply mechanism of the rotor of free waves 4 is placed above the mouth 25, and exiting through the non-return valve 26, the bottom of the well ZO and its axis are combined with the axis common to the cavity of the waveguide pipe 12, which is the side of the seed pipe 31 and the waveguide pipe 12 is radiated folded, and in the upper part of the distributor 11, the placed emitter 11 is introduced into the waveguide pipe 12, and in the lower part - the reflector. By switching the distributor 34 to position 13, in the lower part of the waveguide pipe 12, the "normally open" pump 35 starts pumping the longitudinal grooves 27, through which the working fluid to wave the working fluid to the pressure determined by by adjusting the valve Zb in the pressure line 8 When ACCORDING to the normally open position "c" and the emitter 11 is in the extreme "g" At the same time, the working fluid from the pressure line in the upper position, its direct limiter 8 enters the rod cavity From the hydraulic cylinder of stroke 16 in contact with the limit switch 14, and 1, and the piston cavity 2 is connected to the drain contacts "b" in the normally open hollow main line 10. The reverse of the hydraulic cycle occurs, "c" in the normally closed position of the cylinder 1, at the same time as this the liquid by the mechanism 25, the liquid from the pressure line 8 enters and is compressed in the waveguide pipe 12. Since the piston through the normally open contact "in" of the final valve, cavity 2 of the hydraulic cylinder 1 is communicated from the switch 14 to the piston cavity 2 by the hydraulic drain line 10, with a drain, it is communicated- ndra 1 Under the pressure of the working fluid, the piston moves and both regulators 20, 21 of block 19, the hydraulic motor of cylinder 1 is set in motion and affects the and 22 stops, thus turning off the work of the emitter 11 through the piston 6 of the shock generator shock wave generator 4. At the same time, the generator of these waves 4 As a result, the column of liquid 28 in the hole 4 with the emitter 11 moves up to the bi-waveguide 12 is affected by static pressure , which the contact of the backstop 15 radiates through the liquid waveguide 28, i.e. the column of liquid, the switch 11 with the end switch 14 and is switched into the massif of mining rock from position "c" and position "b" and the working At the same time, the working fluid supplied to the liquid from the pressure line 8 again enters the input of the frequency and energy regulation unit 19, into the piston cavity 2 of the hydraulic cylinder 1. At the same time, the regulator 20 is set to consume the liquid, with this the working fluid enters the regulator unit 19, which sets the mode of generating shock waves of decreasing the frequency of pulses of a frequency with high energy, and the regulator 21 In the mode of generating high shock waves is set to consume the liquid that In the frequency mode, the limit switch 18 is in the mode of generating high-frequency shock waves from position "g", the regulator 20 is cut off, and the regulated energy of the torus 21 is connected to the hydraulic motor 22. In the mode of generating low-frequency shock waves, as the liquid is displaced again, frequency emitter 11 is in the extreme switching of the limit switches 14, 18 and further to the upper position, contact "d" of the final re- process is repeated switch 18 is normally open Working fluid on To change the processing time in the generation mode, the hydraulic motor 22 comes from the regulator 20 From the shock waves of low or high-frequency pressure pipe 8 working fluid enters the waveguide 12 connected to the mechanism 25 through the redistributive spool 23 and through the channel in the housing 5 into the fluid consumption regulator 24, configured on the return chamber 9 of the shock generator certain constant consumption of liquid, which fed into the waves 4 Camera of direct movement 7 of the shock-well generator, and dor is equal to or greater than the initial waves 4 through the spool 23 alternately with the acceptance of the well. As the processing progresses, it glows either with the pressure line 8, then from the drainage well, receiving the well, and under the line 10. At the same time, the piston 6 of the generator, under the action of the static force of the hydraulic cylinder 4, in the well - of shock waves 4 begins to carry out the reverse-catch ZO begins to be displaced, an additional portion of gradual movement is displaced, striking the liquid from the waveguide pipe 12. At the same time, the transducer 11, which along the liquid waveguide 28 moves the shock wave generator 4 and transmits power pulses of low frequency on the reflection emitter 11. Regulating the consumption of fluid 13 and further into the productive layer through the casing fed into the well by the regulator 30, the pipe 31 in the well ZO. - the mode of their waves on the liquid waveguide 28 takes place - Reduction of losses shock power is facilitated by the displacement of liquid from the waveguide pipe 12 into the borehole seal of the liquid through the hole in the partition and the depth of the ZO, which leads to the movement of the longitudinal grooves, the parameters of which are limited, of the shock wave generator 4 and the emitter 11 to the experimentally established contact of it limiters of direct travel 16, 17 with The results of the above experiments are given by limit switches 14, 18 and their translation into table 1 Table 1 Mo Hole diameter Impact on- Impact on- n/n Wave length, m | or groove width, | longing for openness intensity AFTER M ru, kW opening, kW 77951 05 | 2 1 39 877795 1 058 1 2 1 25 Continuation of table 1 Mo Wavelength, m | Diameter of the hole Percussive per- Percussive per- p/p or groove width, | longing for openness hardness AFTER M ru, kW hole, kW It follows from the table that the smallest shock losses In the case of reducing or increasing the hole, the power of the shock wave when passing through the hole drops sharply, and the energy of the wave in those cases when the diameter of the hole or is spent to overcome obstacles, that is, the width of the groove is equal to and/or multiples of the length of the destruction of the waveguide pipe or reflector.