SU1102956A1 - Stepped hydraulic pulser - Google Patents

Abstract

STEPPED HYDROPULSATOR, which includes the main oscillator, whose input through the impact pipe and hydro-pneumatic accumulator is connected to the supply line, and the output through the pipeline to the make-up mechanism, and an additional vibration generator connected to the output of the make-up mechanism, characterized by that, in order to improve the performance of the hydroturbing by increasing the pressure in the impulse, the make-up mechanism is communicated with the inlet a pipeline through a pipeline with a check valve placed in it, the shut-off element of the check valve being located on the side of the shock pipeline of a smaller diameter, and the diameter of the pipeline connecting the output of the main oscillator to the input of the make-up mechanism is equal to the diameter of the shock pipeline of a smaller diameter. (L

Description

The invention relates to the field; and: p1 ;;; m;) from the destruction of the 11ulci mountain massif with 1 jets of the liquid of the secondary branch. III and can be used in the mining industry, hydraulic engineering, as well as in power engineering for cleaning the heat and power equipment of power plants from combustion products fuel.

A hydraulic pump is known that contains a hydropneumoaccumulator, a shock conduit, an oscillator with a working and discharge nozzles, a piston valve, low and high side seats, an air cavity, the submembrane space of which is communicated with the high sided seat space varies depending on the direction of movement of the fluid 1.

However, this device is characterized by an insufficient degree of pressure increase in front of the working nozzle.

The closest technical solution to the present invention is a stepped hydraulic impulse that includes the main oscillator, the input of which is connected to the supply line through the impact pipe and hydropneumatic accumulator, and the additional oscillator connected to the impact pipe smaller diameter with the output of the feed mechanism 2.

A disadvantage of the device is the impossibility of ensuring a sufficiently high hydrotreating capacity.

The purpose of the invention is to improve the performance of hydrotreatment by increasing the pressure in the pulse.

This goal is achieved by the fact that in a stepped impulse that includes a main oscillator, the input of which is connected to the supply line through the impact pipe and hydropneumatic accumulator, and an additional oscillator connected to a smaller impact pipe diameter with a feed mechanism outlet, the feed mechanism communicates with the supply line through a pipeline with a check valve placed in it, Rich constipation first non-return valve element is arranged to; the sides of the impact pipeline are smaller than the diameter, and the diameter of the pipeline connecting the main oscillator with the E stroke of the feeding mechanism is smaller than the diameter of the shock pipeline of smaller diameter.

Pa figs. 1 shows a stepped hydro puller; section; in fig. 2 - valve, general view.

C / gun11chat1) 1Y i the iodopulse switch includes 1 Idronnemokkumul g (; р 1, installed on the main T1) pipeline 2, a percussion pipeline made in the form of two

segments, one of which is larger than 3, and the other is smaller than 1–4 diameters, the main oscillator 5, installed at the junction of impact pipelines of greater 3 and smaller 4 diameters and an additional generator co. The 6, mounted on a shock pipe of smaller 4 diameters before the working nozzle 7 and also the pipeline 8 connecting the supply line 2 with the output of the main oscillator 5. The oscillators of oscillations 5 and 6 themselves consist of piston-valves 9 and 10, the course of which is limited by low seats 11 and 12 and high 13 and 14 sides , waste nozzles 15 and 16, connected to cavities 17 and 18, which, through the gaps between piston-valves 9 and 10 and the low And And 12-side seats, are connected by impact pipelines of greater 3 and smaller 4 diameters, air cavities 19 and 20, made in as separation diaphragms 21 and 22 and restrictive grids 23 and 24.

5 The sub-diaphragm spaces 25 and 26 of the air cavities 19 and 20 communicate with both the piston cavities 27 and 28 of the piston valves 9 and 10 of the oscillators 5 and 6 on the side of the saddles on the low 11 and 12 sides, and with the main pipeline

0 2 with the help of transfer pipes 29 and 30, and with the atmosphere with the help of control valves 31 and 32. The cavities 33 and 34 of the piston-valves 9 and 10 of the oscillators 5 and 6 are directly connected to the impact pipelines of a greater 3 and smaller

5 4 diameters through the openings 35 and 36 of the piston-valves 9 and 10, and the cavities 37 and 38 are connected to the impact pipelines of greater 9 and 10 and the seats 13 and 14 high. Hydropneumatic accumulator 1 is made in the form of a separating diaphragm 39 located between the cavity 40 filled with compressed air and the restrictive grating 41 through which the hydro-pneumatic accumulator 1 is connected with the internal cavities of the impact pipeline greater than 5 diameters 3. Inside the pipeline 8 a valve 42 is installed with a saddle 43, having windows 44, and a spring 45.

Stepped hydraulic pulse works as follows.

With open control valves 31

0 and 32, the liquid flowing through the transfer pipes 30 and 29 from the main pipeline 2 into the subdiaphragmatic space 25 and 26 of the air cavities 19 and 20 of the main 5 and an additional 6 oscillators, freely expire into the atmosphere. This leads to the fact that in the piston cavities 27 and 28 of the piston-valves 9 and 10, the pressure is close to atmospheric. The separating diaphragms 21 and 22 of the air cavities 19 and 20 are pressed by the pressure of the air in the air substations 19 and 20 to the restrictive brackets 23 and 24, being in the extreme right positions. At the same time, the pressure in the cavities 33 and 34 of the piston-valves 9 and 10 is close to that supplied in view of the fact that they are through the openings 35 and 36 of the piston-valves 9 and 10, the shock pipelines larger than 3 and less than 4 diameters, the internal cavity of the hydro-pneumatic accumulator 1 is connected to the main pipeline 2. In this case, a redistribution of forces occurs on the piston valves 9 and 10 between the piston cavities 27, 28 and 33, 34, causing the neck to cause the piston valves 9 and 10 to move to their lowest positions until they stop in the seats low 11 and 12 sides. Until the piston valves 9 and 10 are moved to the lowest position, the valve 42 under the action of the same pressure from the impact pipe of a smaller diameter 4 and the pipe 8 is in the extreme right position on the saddle 43, closing the windows 44. Discharge nozzles 15 and 16 are closed, and the impact pipes of smaller 4 and larger 3 diameters are interconnected and the working nozzle 7 is opened. The fluid from the main pipeline 2, the passage of the hydropneumatic accumulator 1, moving the separating diaphragm 39 from the restrictive lattice 41 and compressing the air in the cavity 40 until the pressure on both sides of the separating diaphragm 39 is the same, shock pipe of larger diameter 8, saddle low 11 the sides, the piston-valve 9 of the main oscillator 5, the shell between the piston-valve 9 and the seat of the high 13 side, field 37, a shock pipe of smaller diameter 4, the saddle of the low 12 side, the piston valve 10, w, spruce between the Porsche s-valve seat 10 and high side 14, the cavity 38 ends through the working nozzle 7 into the atmosphere.

The operation of the stepped impulse hydropulse is carried out as follows. At the beginning, the control valve 31 closes. The pressure in the subdiaphragm cavity 25 rises smoothly to the pressure in the main pipeline 2. Over time, this continues until the separation diaphragm 21 moves under the action of the pressure difference forces in the subdiffraction space 25 and the initial pressure of the air injected in the air cavity 19 from the restrictive lattice 23, it will not reach the extreme left position when the pressure on both its sides will be the same. The pressure in the piston cavity 27 of the piston-valve 9 increases according to the same law, becoming at the same time greater than in the piston cavity 33 of the piston-valve 9, and due to the pressure differential on the piston-valve 9, it moves to

the upper extreme position is from the sema of the low 11th side to the villages, first () th of the 13th side, the garden is facing it. The piston valve 9 closes the gap between the high side 13 seat and the poryen valve () m 9, i.e., cuts off the shock pipe of a smaller diameter 4, an additional oscillator 6 with a working nozzle 7, and directs the entire fluid flow to the discharge nozzle 15 The working fluid from the main pipeline 2, the passage of the hydro-pneumatic accumulator I, the separation diaphragm 39 of which tie rests on the restrictive clamp 41, the shock pipeline of larger diameter 3, the saddle of the low 11 side, the gap between the saddle of the low 1 I side and the piston-valve 9, along spine 17 is supplied to the relief nozzle 15 and flows out of it into the atmosphere. Since we have a hydraulic resistance of the nozzle 15 less than the resistance of the impact pipe of less than 4 diameter and the working nozzle 7, the resistance of the system decreases. Hydraulic shock occurs. The pressure of the fluid in the zone of the main oscillator 5 decreases the first wave of this reduced pressure propagates through a shock conduit of greater 3 diameters to the hydropneumatic accumulator 1. After this wolf is reflected from the hydropneumatic accumulator I and reaches the main oscillator 5, the pressure before the discharge the nozzle 15 and in the piston cavity 33 of the piston-valve 9 slightly increases, remaining, however, less than the constant pressure in the nopniene cavity of the piston-valve 9. Therefore, the discharge nozzle 15 remains open When the main oscillator 5 is operated in a ramming mode, the number of pressure waves running through the shock conduit of greater 3 diameters at both ends in the low phase is usually equal to 3-5 and depends on the value of the constant pressure of the liquid in the shock pipe of a larger diameter 3 up to the maximum possible speed. At the same time, through the working nozzle 7 from the shock pipe of smaller diameter 4, the liquid passes the low 12-way seat, the piston-valve 10 of the additional oscillator 6, the gap between the valve 10 and the high 14-side seat, cavity 38, flows out into the atmosphere under pressure below supplied. As soon as the pressure in the impact pipeline of smaller 4 diameter becomes less than from the side of pipeline 8, and the force on the valve 42 from the side of pipeline 8 is greater, then the valve 42 will move from the right end position to the left, i.e. the saddle 43 and will compress the spring 45. The fluid from the supply line 2 through line 8 through the windows 44

the saddle 43, the gap between the saddle 43 valve 42 and the walls of the pipeline 8 falls into a shock pipe of smaller 4 diameters, and from it, an additional generator passes to (}; 1paniy 6, flows through the working nozzle 8 into the atmosphere. This will cause the pressure before the working nozzle 7 and in the zone of the additional oscillator 6 is slightly lower than the supplied pressure. The same pressure will be in the piston cavity 34 of the junction valve 10 of the additional oscillator 6 due to the fact that it is connected to the shock pipes through the openings 36 of the piston valve 10 the conduit of smaller diameter 4, and since the control valve 32 is open, the pressure in the nodiaphragm cavity 26 and the piston cavity 28 of the piston-valve 10 is atmospheric. Therefore, the piston valve 10 remains in its lowest position near the low-side saddle 12. After the control valve closes 32, the pressure in the sub-diaphragm space 26 and the piston cavity 28 of the additional oscillator 6 increases smoothly, increasing to the pressure in the main pipeline 2. In time, this will continue until it divides The displaced diaphragm 22, moving under the action of differential pressure forces in the subdiaphragmatic space 26 and the initial pressure of pumping air in the air cavity 20 from the restrictive lattice 24, does not reach 4 points to its left position when the pressure from the wallpaper.x of its sides is the same. The pressure in the piston cavity 28 of the piston valve 10 increases along the same bury, becoming at the same time greater than in the piston cavity 34 of the piston-valve I), and due to the pressure differential on the piston-clan 10 it moves in the uppermost position from the saddle low side 12 to the saddle high 14 side, garden sat on it. The piston valve 10 closes the gap between the high side 14 seat and the piston valve 10, i.e., cuts the working nozzle 7 from the shock pipe of smaller 4 diameter, and directs the entire fluid flow to the discharge nozzle 16 of the additional oscillator 6. the main pipeline 2, the passage of the pipeline 8 window 44, seat 43, P1.el between the saddle 43 and the valve 42, the gap between the pipe 8 and the valve 42, the pipeline of smaller diameter 4, the saddle of the low side 12, the gap between the low seat 12 side and the piston with valve 10 The oscillator 6, cavity 18, goes to the discharge nozzle 16, and flows out of it into the atmosphere. Since the hydraulic resistance of the discharge nozzle 16 is less than the resistance of the working nozzle 7, the resistance of the system decreases. Hydraulic shock occurs, accompanied by the appearance of low pressure and increased speed in the pipeline of smaller 4 diameters from the side of the additional oscillator 6. This wave propagates through pipe 5 of smaller 4 diameter to the main oscillator 5 and non-return valve 42. When it approaches the non-return valve 42 and the main oscillation generator 5 in the lower section of the pipeline smaller than Q 4 of diameter arises a reflected wave of pressure close to the pressure in pipeline 8 and the speed is greater than soon The motion of the fluid in the low pressure wave that has come down. The reflected wave propagates through a pipe of less than 4

5 diameter from the check valve 42 and the main oscillator 5 to the additional oscillator 6. After this wave approaches the additional oscillator 6, the pressure before the discharge nozzle 16 and in the piston strip 34 of the piston-valve 10 increases, remaining less than the pressure in the piston cavity 28 of the piston-valve 10 of the additional oscillator 6. Therefore, the discharge nozzle 16 will remain open and the next wave of reduced pressure propagates through the shock conduit of smaller 4 diameters And increased speed, etc. When an additional oscillator 6 is operating in a ramming mode, the number of pressure waves,

0 running through the impact pipe of a smaller diameter 4 at both ends in the low phase, usually 3-5 and depends on the value of the constant pressure in the piston cavity 28 of the piston-valve 10. A liquid acceleration occurs in the shock pipeline of less than 4 diameter to the maximum possible speed fluid movement at the supplied pressure in the main pipeline 2 to the step hydro impulse. The closure of the discharge nozzle 15 of the main oscillator 5 and the end of the low phase of the fluid pressure oscillations in the shock pipe of a larger diameter 3 occurs when the pressure in front of the discharge nozzle 15 and in the piston-valve piston cavity 23 increases step-wise with each arrival reflected from the hydro-pneumatic accumulator 1 wave does not become larger than in the piston cavity 27 of the piston-valve 9. As a result of this, the maximum pressure drop occurs on the piston-valve 9 and it

0 will move as far as possible to the lowest position from the high side seat 13 to the low 11 side seat. Access of the fluid flow to the discharge nozzle 15 and both of the impact pipelines greater than 3 and less than 4 is terminated.

5 diameters are interconnected. Since the resistance of the shock-filled impact pipe of a smaller diameter 4 is greater than the resistance of the shock

a larger diameter pipe 3 diameter and waste nozzle 15, then the total resistance of the system increases sharply. A hydraulic shock occurs, the pressure and velocity of the fluid in the lower section of the impact pipe of less than 4 diameter increases sharply, and the check valve 42 closes, landing on the saddle 43. The first wave arises, which additionally increases pressure and speed and spreads through a pipe of less than 4 diameter to the additional oscillation generator 6. When approaching it to an additional oscillator 6 in the final section of the pipeline with a smaller diameter 4, the piston cavity 34 and cavity 18, an abrupt change occurs lichenie pressure, the fluid ejection speed into the atmosphere from the pipe 4 of smaller diameter through the lower seat 21 side, sh.el between the piston-valve 10 further oscillator 6 and the lower seat 12 side, a cavity 18 and a discharge nozzle 16, is increased. There is a first reflected wave of increased pressure and increased fluid velocity in the upper section of the pipeline with a smaller diameter of 4 for the additional oscillator b, which propagates through the pipeline of smaller 4 diameter to the lower section of the pipeline of smaller 4 diameter for the main oscillator 5 and the check valve 4. At approach to the check valve 42 and the main oscillator 5 in the lower section of the pipeline of smaller diameter 4, a second wave occurs. Its occurrence is accompanied by a decrease in pressure and an increase in the velocity of the fluid in the lower section of a pipe smaller than 4 in diameter compared with the pressure and velocity of the fluid in the first wave. Due to the decrease in pressure in the lower section of the pipeline with a smaller diameter 4, the check valve 42 opens. This leads to an additional increase in the flow rate in the lower section of the pipeline of smaller diameter 4 due to the flow of fluid from the pipeline 8 through the windows 44 of the saddle 43, sh, spruce between the saddle 43 and valve 42, the gap between the pipeline pipe. 8 and a valve 42 in a pipeline of smaller 4 diameter. The resulting pressure and velocity wave propagates through a pipeline of smaller 4 diameters to an additional oscillator 6. At the time of its arrival to an additional oscillator 6, a second reflected wave occurs, which is characterized by a further abrupt increase in pressure and velocity of the fluid in pipeline smaller 4 diameter. In this case, the pressure in the piston cavity 34 of the additional oscillator 6 becomes the same as in the pipeline

of smaller diameter 4, due to its connection through openings 36 with the internal cavity of the pipeline of smaller diameter 4. This leads to a redistribution of pressures in the piston cavities 34 and 28 of the additional oscillator 6, which ensures the transfer of the piston-valve 10 from the extreme upper position to the lower to the stop in the low 12 side. The nozzle 16 is closed, and the working nozzle 7 is opened. The liquid from the supply line 2, the passage of the internal cavities of the hydro-pneumatic accumulator of torus 1, the shock pipe larger between the piston-valve 9 of the main oscillator 5 and the high side 13 seat, cavity 37, falls into the impact pipe of a smaller diameter 4 and from it through the saddle low 12 side, the piston-valve 10 additional oscillator 6, the gap between the piston-valve 10 and the seat 14 high side, the cavity 38 enters the working nozzle 7, and from it flows into the atmosphere. Since the hydraulic resistance of the working nozzle 7 is significantly greater than the hydraulic resistance of the discharge nozzle 16, a hydraulic shock occurs in the system. Fluid motion in the upper section of a pipeline of smaller diameter 4 decreases and pressure increases. is lost. A high-pressure and low-velocity wave propagates to the working nozzle 7 and through a conduit of smaller 4 diameters to the main oscillator 5. The high pressure liquid flowing from the working nozzle 7 destroys the bottom. A wave propagating through a conduit of less than 4 diameters at the moment of approaching the main oscillator 5 and the non-return valve 42 is converted into a reduced pressure wave, the magnitude of which is larger than the input, and a zero velocity of the fluid in the lower section of the pipeline with a diameter of 4. This is due to the fact that at the moment of arrival of the high pressure wave from the side of the additional oscillator 6 to the main oscillator 5, the piston-valve 9 of the main oscillator 5 due to the redistribution of pressure in the piston cavities 33 and 27 moves from the lowest position to the top an emphasis is placed on the saddle of the high side 13, with the discharge nozzle 15 opening and the pipelines of smaller 4 diameters and larger 3 diameters disconnecting. The main generator of oscillations 5 is prepared for the repeated cycle of acceleration of the liquid in the shock pipe of a larger 3 diameters.

At the same time, the check valve 42 closes sitting on the saddle 43. The pipe 8 is disconnected from the pipe of smaller 4 diameter. A dead end is formed, from which the wave is reflected

DAB, 1SN. B (J3HHKiiiaji reflected wave of reduced pressure and zero speed D1 and liquid fluid expands) but at the vieHbiHcro pipe 4 diameter to additional oscillator 6. When it approaches the working nozzle 7, pressure decreases and the outflow rate of the fluid from the working nozzle 7 decreases. a reflected wave of low pressure (but greater than the supplied one) and a reduced velocity, which propagates through a pipeline of 4 diameters to the main oscillator 5 and a check valve 42 (dead end). At the moment of its approach to the deadlock, the pressure in the lower section of the pipeline of smaller 4 diameter decreases and becomes lower than the supplied one. The velocity of the fluid is still zero. The non-return valve 42 is opened by the action of the differential pressure from the pipeline of the smaller diameter 4 and the pipeline 8 opens, thus a flow of fluid from the pipeline 8 to the pipelines of smaller diameter 4 occurs. The pressure in the initial section becomes equal to that supplied. A wave of applied pressure and an increased fluid velocity propagates through a pipeline of smaller 4 diameters to the working nozzle 7. At the moment this wave approaches the working nozzle 7, a reflected wave occurs, the pressure and the velocity of the liquid decrease. There is a redistribution of pressure forces on the piston-valve 10 of the additional oscillator 6 from the side

| 1 () p11 of the cavities 28 and 34, under the action of which the junction valve 10 additionally oscillates the oscillator 6 from the lowest position to the top up to the saddle of the high 14 side. The working nozzle 7 is closed, and the discharge nozzle 16 through the cavity 18, the shell between the piston valve 10 and the saddle of the low 14 side, is connected to an impact pipeline of smaller 4 diameters.

The operation process is repeated, the system enters auto-flight mode.

To take the system out of self-oscillation mode, it is necessary to open control valves 31 and 32, which will ensure a decrease in pressure in the sub-diaphragm spaces 25 and 26, piston cavities 33 and 34, which are connected through holes 35 and 36 to the internal cavities of pipelines smaller 4 and larger 3 diameters , will ensure transfer of piston-valves 9 and 10 of oscillators of the main 5 and additional 6 from the upper positions to the bottom. This will cause the waste nozzles 15 and 16 to close, and the working nozzle 7 and the smaller pipe 4 diameter will open and the hydraulic connection of the main pipeline 2 will be provided through the larger diameter 3 shock pipe, the smaller 4 diameter pipe with the working nozzle 7.

The proposed device makes it possible to increase the performance of hydrotreatment by increasing the pressure in the pulse. 32 J4 figure 1

Claims (1)

A HYDRAULIC HYDRAULIC PULSATOR, including a main oscillation generator, the input of which is connected via a shock pipe and a hydropneumatic accumulator to the supply line, and the output through a pipe with the input of the feed mechanism, and an additional oscillator connected via a shock pipe of smaller diameter with the output of the feed mechanism the fact that, in order to increase the performance of hydraulic breakdown by increasing the pressure in the pulse, the feed mechanism is communicated with the supply mag by means of a pipeline with a non-return valve located in it, and the shut-off element of the non-return valve is located on the side of the shock pipe of smaller diameter, and the diameter of the pipe connecting the output of the main oscillation generator to the input of the feed mechanism is equal to the diameter § of the shock pipe of smaller diameter.