SU1448057A1 - Pulsed hydraulic monitor - Google Patents

Abstract

The invention relates to hydro-pulse technology and may be. used to destroy rocks by pulsating streams of liquid. The goal is to increase the efficiency of hydroforming by controlling the amplitude of the high pressure in the pulse and the frequency of the pulsations. The device contains a flow interrupter 1, a hydro-pneumatic accumulator 2, a hydromonitor 3 communicating with the supply line 14. The control system has main and additional control hydraulic cylinders 55, 56. The accelerating devices 6 and 7 are made in the form of pistons 33 and 34 with rods 35 and 36. In the case of each accelerating device 6 and 7, additional pistons 49 and 50 are installed. The latter are located between the main pistons 33, 34 and partitions 39, 40. Near the last holes are made. The pistons 49 and 50 are connected to the additional hydraulic cylinders 55 and 56 by means of additional rods 53, 54. By moving additional pistons 49, 50 by hydraulic cylinders 55, 56, the volume of the internal cavities of the accelerating devices 6 and 7 is reduced or increased. This changes the frequency and amplitude of the pulse . 3 il. with 5S (/)

Description

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The invention relates to hydro-impulse technology, in particular, to the design of pulsating hydro-monitors and can be used in the mining industry, in hydraulic engineering for the destruction of rocks and coal by pulsating jets of liquid with an increase in pressure in the impulse, as well as in power engineering for cleaning the thermal-energy elements of boiler units of power plants.

The aim of the invention is to increase the efficiency of hydrotreatment by controlling the amplitude of the high pressure pulse and the frequency of the pulsations.

FIG. 1 shows a general view of the pulsating jet monitor in section; in fig. 2 - a general view of a hydromonitor in a section; in fig. 3 - a general view of the accelerating device in the section.

The pulsating hydromonitor contains a flow interrupter 1, a hydropneumoaccumulator 2, a hydromonitor 3 with pipes 4 and 5, accelerating devices 6 and 7 with pipes 8 and 9. The flow interrupter 1 consists of a body 10 with saddles 11 and 12, an inter-space 13 which, via the internal cavity of the hydro-pneumatic accumulator 2, communicates with the halfway line 14, and in the seating spaces 15 and 16 there are pistons 18 and 19 which are rigidly interconnected by means of a rod 17 and 15 are connected with the hydromonitor 3 through internal cavities of pipelines 4 and 5. Zaporshnevy cavities 20 and 21 communicate with pipelines 4 and 5 by transfer pipes 22 and 23 and are separated from cavities 24 and 25 with an elastic element (compressed gas) by separating diaphragms 26 and 27, the course of which is limited on both sides grids 28, 29 and 30, 31. One of the rotary cavities, for example 21, is in communication with the atmosphere through the control valve 32. On the pipelines 4 and 5 near the hydromonitor 3 there are installed accelerating devices 6 and 7, made in the form of pistons 33 and 34 with rods 35 and 36 placed in housings 37 and 38, which are divided into two chambers 41, 42 and 43 by partitions 39 and 40, 44. Chambers 41 and 42 through the internal cavities of pipelines 9 and 8 communicate with the supply line 14, and chambers 43 and 44 through windows 45 and 46 with the internal cavities of pipelines 5 and 4. In chambers 43 and 44 between the pistons 33 and 34 and stroke controllers 47 and 48 are installed by partitions 39 and 40 of cases 37 and 38. They are made in the form of pistons 49 and 50 with rods 51 and 52. Rods 51 and 52 pass through partitions 39 and 40 outside the chambers 41 and 42 and are interconnected by sleeves 53 and 54. Hydraulic cylinders 55 and 56 are mounted on accelerating devices 6 and 7 and are connected via sleeves 53 and 54 to regulators 47 and 48 of the stroke. The pistons 49 and 50 of the regulators 47 and 48 of the stroke are in direct contact with the pistons 33 and 34 of the accelerating device.

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7 and 6. In addition, in housings 37 and 38 near partitions 39 and 40, holes 57 and 58 are made on the side of chambers 43 and 44. Hydraulic monitor 3 consists of a horizontal hinge 59 with annular grooves 60 and 61 and a vertical stand 62 divided by a partition 63 into two chambers 64 and 65 connected through windows 66 and 67 to pipelines 3 and 4. On the vertical stand 62, vertical hinges 68 and 69 are installed with annular chambers 70 and 71, which through radial windows 72 and 73 and cavities 74 and 75 are connected to chambers 64 and 65 of vertical stack 62. Vertical hinges 68 and 69 connect us with n trunks 76 with nozzles 77 of the same diameter. The barrels 76 and 77 are rigidly fastened to each other by a bracket 78, to which the hydraulic cylinder of the vertical rotation of the barrels 76 m 77 is connected. In addition, it should be noted that the hydraulic resistance of the transfer pipes 22 and 23 is much greater than the hydraulic resistance of the nozzles installed on the barges 76 and 77 of the jetting device 3 .

The workflow in a pulsing monitor is as follows.

When the control valve 32 is open and the pistons 18 and 19 with the choke 17 are in the extreme right position, fluid from the supply line 14, the passage through the internal cavities of the hydropneumatic accumulator 2, fills the space between the seats 13 of the housing 10 of the flow interrupter 1, the gap between the piston 19 and the saddle 11, enters the seating space 15, and from there into the pipeline 5, the horizontal hinge 59, the annular groove 61, the window 67 of the vertical stand 62, the chamber 65 between the partition 63 and the vertical stand 62, cavity 75, the window 73 , the annular chamber 71 in vertical hinge 69, the barrel 77 with a nozzle and out through the nozzle of the trunk 77 into the atmosphere. In addition, the fluid from the pipeline 5 through the transfer pipe 23 fills the piston cavity 2 of the piston 19. Since the valve 32 is open, the pressure in this cavity is close to atmospheric. At the same time, pressure in the buried cavity 0 is also close to atmospheric due to the fact that it communicates with the atmosphere through the transfer pipe 22, pipe 4 and barrel 76 with the nozzle of jetting unit 3. Therefore, the diaphragm 26 and 27 of the cavities 24 and 25 with elastic the element is pressed by gas pressure to the grids 28 and 29. The piston 33 with the stem 35 of the accelerating device 7 and the regulator 47 of the stroke are also in the rightmost position at the partition 39 of the housing 37. The chamber 43 through the window 45 is filled with fluid from the pipeline 5. Its volume is maximum . At the same time, the piston 43 with the rod 36 of the accelerating device 6 is under the action of the pressure of the liquid coming from

The supply line 14 through the pipeline 8 into the chamber 42, also in the extreme right position near the window 46 in the pipeline 4. And the controller 48 of the stroke is in the leftmost position at the partition 40. The stem of the hydraulic cylinders 55 and 56 are extended, the accelerating devices 7 and b are prepared to receive the maximum volume of fluid from pipelines 5 and 4. The volume of the chamber 44 is minimal.

The transient process occurring in the system is characterized by the propagation of shock waves of pressure between the accelerating device 6 and the hydro-pneumatic accumulator 2 and the acceleration of the liquid in the left flow part of the pulsating hydraulic monitor. An increase in the rate of movement of the fluid will be observed until

Putting the device into self-oscillation mode. The piston 34 with the rod 36 will alternately close the control valve 32. At the same time, in the piston cavity 21 of the piston 19, the pressure of the fluid smoothly increases until it is divided in the chambers 44 and 42. At the time when the piston 34 with the rod 36 takes the leftmost position, i.e. With a piston 34 on the piston 50 of the controller 48 stroke.

on the diaphragm 27, pressed by the force of pressure, the working fluid is braked.

laziness of the liquid from the grid 29, will not reach the grid 31. After that, the pressure in the piston cavity 21 instantly increases to the inlet, i.e. to a pressure equal to the pressure in the pipeline 5. As a result, a force arises that moves the pistons 18 and 19 with the rod 17 from the rightmost position to the left. Fluid from the intersectional space 13 of the flow interrupter 1 now rushes no longer to the trunk

dispersed in the left flow part of the pulsating jet monitor before the nozzle barrel 76. A hydraulic shock occurs in the system. The pressure in the pipe 4 and the barrel 76 with the nozzle increases sharply. 20 The pressure wave propagates from the nozzle of the barrel 76 through the flow section of the hydraulic monitor 3 through the pipeline 4 through the flow section of the flow interrupter 1 to the hydro-pneumatic accumulator 2,

77 through pipeline 5, and to trunk 76 with mounted-5 installed on the supply line through pipeline 4. Main stream 14. It is reflected from the hydropneumatic fluid, the passage of the gap between the pressure of the multiplier 2 in the form of a pressure wave, close to 18 and the saddle 12, enters the gauge to the pressure in line 14. During

space 16, pipeline 4, the horizon of the shock wave to the hydro-pneumatic hinge 59, the annular bore of the accumulator 2 and the back pressure of the liquid 60, the window 66 of the vertical flow 62, the bones in the piston 20 of the piston measure 64 between the partition 63 and vertical one hundred 62, cavity 74, window 72, an annular chamber 70 of a vertical hinge 68, a barrel 76 with a nozzle and exits through the nozzle of a trunk 76 into the atmosphere on the object

18, which through transfer pipe 22 is filled from conduit 4, initially increases smoothly until separation diaphragm 26, pressed by pressure from lattice 28, reaches fracture. At the same time, the fluid from 35 of the grid 30, and then abruptly to the pipe 4, flows through the window 46 into the chamber 44, filling it and moving the piston 34 with the rod 36 from the right end position from the window 46 to the left until it stops on the piston 50 Torus 48 turn. The fluid from the chamber 42 of the housing 38 of the accelerating device 6 when the piston 34 moves with the brush 36 to the extreme left position against the stop on the piston 50 of the stroke regulator 48 will be forced out through the pipeline 8 into the supply line 14, and the air between the windows and the window 45 In the chamber 43, suction through the partition 40 and the piston 34 will also open the holes 57 in the housing 37, the air from the atmosphere, and then as a result of the outflow of liquid through the nozzle barrel 77 into the atmosphere, gradually decreases until the separating diaphragm 27 is pressed from. e. the piston 34 with the rod 36 is not with children on the rock - 50 lattice 31, will not reach the lattice 29. In this shen 50 of the stroke controller 48, the resistance in the process in the pipeline 5 will attenuate

and the pressure in it becomes equal to the atmospheric pressure, and in the spill-filled cavity 21 it also decreases to atmospheric, but in steps. The pressure before the nozzle of the barrel

pressure in the pipeline 4. At the same time, the liquid from the piston cavity 21 flows through the transfer pipe 23 into the cavity of the pipeline 5. At the same time, the same pressure as in pipeline 5 is maintained at the beginning of the piston 33 when the piston cavity 21 the rod 35 under the action of pressure from the side of the chamber 41 connected by a pipe 9 to the supply line 14 from the regulator 47

through the holes 58 in the housing 38 to be forced out into the atmosphere. Until the piston 34 with the rod 36 of the accelerating device 6 reaches the leftmost position.

the system is determined by the hydraulic resistance of the nozzle of the barrel 76 and the window 46. The time during which the liquid fills the chamber 44 of the accelerating device 6,

depends on the volume of the latter, the resistance of 55 76 at the beginning increases to an increased

window 46, as well as the initial pressure value in line 4, which is equal to the pressure difference, is sufficient

compared with the pressure in the supply line 14, and then gradually approaches the value of the latter. Liquid under

to move the piston 34 with the brush 36 from one extreme position to the other.

The transient process occurring in the system is characterized by the propagation of shock waves of pressure between the accelerating device 6 and the hydro-pneumatic accumulator 2 and the acceleration of the liquid in the left flow part of the pulsating hydraulic monitor. An increase in the rate of movement of the fluid will be observed until

 The piston 34 with the rod 36 will move the piston 34 with the rod 36 to move in the chambers 44 and 42. At the time when the piston 34 with the rod 36 will take the leftmost position, i.e. With a piston 34 on the piston 50 of the controller 48 stroke.

working fluid braking occurs.

working fluid braking occurs.

dispersed in the left flow part of the pulsating jet monitor before the nozzle barrel 76. A hydraulic shock occurs in the system. The pressure in the pipe 4 and the barrel 76 with the nozzle increases sharply. The pressurized wave propagates from the nozzle of the barrel 76 through the flow section of the hydraulic monitor 3 via line 4 through the flow section of the flow interrupter 1 to the hydropneumatic accumulator 2,

mounted on supply line 14. It is reflected from hydro-pneumatic 18, which through transfer pipe 22 is filled from pipe 4, initially increases smoothly until separation diaphragm 26, pressed by pressure from lattice 28, reaches lattice 30, and then abruptly to the threshold to the window 45 in the chamber 43, sucking the air from the atmosphere through the holes 57 in the housing 37, and then as a result of the outflow of the liquid through the nozzle barrel 77 into the atmosphere, gradually decreases until the separating diaphragm 27 from lattice 31, will not reach lattice 29. At this time, the process in the pipeline 5 will attenuate

pressure in the pipeline 4. At the same time, the liquid from the piston cavity 21 flows through the transfer pipe 23 into the cavity of the pipeline 5. At the same time, the same pressure as in pipeline 5 is maintained at the beginning of the piston 33 when the piston cavity 21 the rod 35 under the action of pressure from the side of the chamber 41 connected by a pipe 9 to the supply line 14 from the regulator 47

compared with the pressure in the supply line 14, and then gradually approaches the value of the latter. Liquid under

varying pressure from elevated to injected flows through the nozzle 76 into the atmosphere at the object of destruction. After the end of the redistribution of pressures in the piston cavities 20 and 21, the pistons 18 and 19 move with the rod 17 of the flow interrupter 1 from the leftmost position to the right position.

The process is repeated and the system enters, 15-oscillatory mode of operation.

The system is brought out of self-oscillation mode by opening the control valve 32, which leads to constant pressure maintenance in the piston cavities 21, which is close to atmospheric, and the pistons 18 and 19 with the rod 7 of the flow interrupter 1 in the extreme right

11: LESSONS.

In the specified self-oscillating mode of operation of the pulsating hydromonitor, the regulators 47 and 48 of the stroke were in the extreme right and left positions, respectively. Pistons 49 and 50 rested against partitions 39 and 40 of chambers 43 and 44 of housing 37 and 38 of accelerating devices 7 and 6. The volume of fluid received by cameras 43 and 44, with a maximum of 33 and 34 with rods 35 and 36 of accelerating devices 7 and 6, will be through pistons 49 and 50 with rods 51 and 52 and bushings 53 and 54 are transferred to rods of hydraulic cylinders 55 and 56. The high pressure pulse amplitude decreases, and the pressure pulsation frequency increases. In the event that the hydraulic cylinder rods 55 and 56 are fully retracted, the regulators 47 and 48 of the stroke will take the left and right positions in the chambers 10 43 and 44, pressing the pistons 33 and 34 against the holes 45 and 46, respectively. The volume of chambers 43 and 44 will decrease to zero, i.e. will be minimal. The increase in the amplitude of the high pressure in the pulse will not be, the pressure in the trunks will be lower than the input, and the frequency of the pressure pulsations will be maximum.

Claims (1)

Invention Formula Pulsating hydromonitor, including a hydropneumatic accumulator, flow interrupter, nozzles, control hydraulic cylinders, an oil power station, a control system, accelerating devices in the form of pistons with rods mounted in the housing and forming piston and rod 15 Mr. - - - - - ,,. ,, j j, „. - ny. This ensures maximum amplitude - chambers, separated by a partition, distinguish between high pressure impulse and minimized by the fact that, in order to increase the effective frequency of pressure pulsations, which is due to control of the hydroflux, the time of amplitude of high pressure is mainly determined in the chambers 43 and 44 acceleration units; g-pulse and pulsation frequency, hydromonitor roystv 7 and 6 liquid. Hydraulic cylinder rods, Q equipped with additional hydraulic cylinders Ditch 55 and 56 extended. If the rods of the hydraulic cylinders 55 and 56 are now half moved, then through the sleeves 53 and 54 and the rods 51 and 52, the pistons 49 and 50 of the stroke adjusters 47 and 48 move in the chambers 43 and 44, reducing the stroke of the pistons 33 and 34 with the rods 35 and 36 accelerating devices 7 and 6, as well as the received volume of liquid, in this case by half, the process occurring in the system will be similar to that indicated, with the entire load associated with moving controls, which are installed on the body of accelerating devices, and additional rods and pistons, which are located in the body between the main pistons of the accelerating devices and the partition, while the body of the accelerating devices has holes in which additional rods are located, and the ends are rigidly connected between themselves and installed with the ability to interact with the rods of additional hydraulic cylinders. By moving the rods 33 and 34 with the rods 35 and 36 of the accelerating devices 7 and 6, through pistons 49 and 50 with the rods 51 and 52 and the sleeves 53 and 54 will be transmitted to the rods of the hydraulic cylinders 55 and 56. The high pressure pulse amplitude will decrease, and the pulse rate of pressure will rises In the event that the hydraulic cylinder rods 55 and 56 are fully retracted, the adjusters 47 and 48 of the stroke will take the left and right positions in the chambers 0 43 and 44, pressing the pistons 33 and 34 against the holes 45 and 46, respectively. The volume of chambers 43 and 44 will decrease to zero, i.e. will be minimal. The increase in the amplitude of the high pressure in the pulse will not be, the pressure in the trunks will be lower than the input, and the frequency of the pressure pulsations will be maximum. Invention Formula Pulsating hydromonitor, including hydropneumatic accumulator, flow interrupter, nozzles, control hydraulic cylinders, oil power station, control system, accelerating devices in the form of pistons with rods installed in the housing and forming piston and rod five  ,, j j, „. - - chambers, separated by a partition, differ with additional hydraulic cylinders controls, which are installed on the body of accelerating devices, and additional rods and pistons, which are located in the body between the main pistons of the accelerating devices and the partition, while the body of the accelerating devices has holes in which additional rods are located, and the ends are rigidly connected between themselves and installed with the ability to interact with the rods of additional hydraulic cylinders. BO 66 6i4 6Z OT 65 Shig.