SU1173818A1 - Resonance hydraulic pulser - Google Patents

Abstract

RESONANT HYDROSHOPLUSATOR, including an oscillator installed on the impact pipe with a working and discharge nozzles and a piston valve installed in the housing With the formation of the chambers, opening and closing of the relief and high and low pressure chambers, and a conversion mechanism that is different from the efficiency of water scrubbing by increasing the frequency of pulsations, the transfer mechanism is made in the form of a tube, which connects the high-pressure chamber and the discharge opening chamber to each other and has a length equal to twice th the length of the impact of the pipeline. CO From the side Piston-valve 5 and bodies 4 form chambers of high 12 and low 13 pressure, as well as chambers of the cover 14 and closure 15 of the relief (i.e., from the chamber, the pressure in which creates 00 forces directed towards the piston-valve 5, respectively, at 00 OTXpfen-He and the closure of the access of water from the impact pipe 2 to the discharge nozzle 9). The discharge shut-off chamber 15 communicates with the impact pipeline directly through the openings 16 in the piston-valve 5, therefore, when the device is operated at any time, the water pressure in it is equal to the pressure in the final section of the impact pipeline 2 adjacent to the oscillator 3. The pressure oscillations - from high to

Description

reduced in relation to the supplied. In the high-pressure chamber 12, the pressure during operation is 6-years from high to atmospheric, and in the low-pressure chamber 13 from low to atmospheric. The opening chamber 14 by means of a transfer tube 17, the length of which is equal to twice the length of the impact pipe water 2, is connected to the high pressure chamber 12.

In order to start the device in self-oscillation mode, the open-reset chamber 14 by means of the control valve 18 has the ability to communicate with the atmosphere, and the piston-valve 5 through, for example, the tip 19 has a larger overlapping area on the saddle side and 11 side compared to the end face area high side 10. In addition, the saddle of one high side 10 is connected to the housing 4 of the oscillator 3 by a partition 20 with windows 21, which divides the high pressure chamber 12 into two chambers, one of which is pre-day , 22, and another, the commissio, —23. They are interconnected by windows 21 in a partition 20.

The operation of the resonant impulse is carried out in the following manner.

When the Control 18 valve is open, the water coming from the main pipeline to which the hydraulic impulse is connected, the passage of the hydraulic accumulator J and the shock pipeline 2, goes to the oscillator 3. Since the reset opening chamber / 14 is connected to the atmosphere when the control valve 18 is open Then, filling the discharge chamber 15 through the openings 16, water depending on the previous position of the piston-valve 5 or moves it all the way to the low side 11, or even more presses it to this seat, the passage gave e gap between the piston and septum valve seat 5 and the high side 10 dosedelnuyu chamber 22, windows 21, 20, zasedelnuyu chamber 23, water will expire through the working nozzle 8 to the atmosphere to destroy the object. In addition, the water from the limiting chamber 22 of the high-pressure chamber 1.2 through the transfer pipe 17

The bladder opens the open chamber 14, and FROM it through the control port 1B flows into the atmosphere.

In the self-oscillation mode, the resonant hydropulse is turned on by closing the control valves 18. At the same time, the pressure in the opening opening chamber 14 becomes equal to that supplied, as well as in the closing pressure chamber 15, and in the high pressure chamber 12. But the tip area 19 is blocked by a low seat side 11, more than the area of the free end of the piston-valve 5 from the side of the high side of the seat 10, then with equal pressure on all working areas of the piston-valve 5) the piston-valve 5 will move to the extreme right position, will open the access of water from the impact pipe 2 to the low pressure chamber 13 and further to the discharge nozzle 9 and at the same time blocking the access of water to the high pressure chamber 12 ;, to the weekly chamber 22, the sitting room 23 through the windows 21 of the partition 20 with the saddle 10 and connecting them through the working nozzle 8 with the atmosphere. Due to the fact that the diameter of the waste nozzle 9 is larger and the hydraulic resistance is less than the diameter of the working nozzle 8, the hydraulic resistance of the system decreases. This causes a hydraulic shock with a decrease in pressure in the zone of the oscillation generator 3. A low phase of the oscillations begins, and shock pipeline 2 will send a shock wave of reduced (compared to the supplied) pressure to the hydropneumatic accumulator 1 and 14 to the discharge opening chamber 14 a shock wave of pressure close to atmospheric will occur. Thus, at the time of the beginning and throughout the low phase, the pressure in the high pressure chamber 12 is close to atmospheric, in the shut-off chamber 15 and the low pressure chamber 13 is equal to low pressure, and in the open-discharge chamber 14 is equal to the pressure that preceded low phase (in this case supplied).

When the reduced pressure wave reaches the hydropneumoaccumulator 1 and is reflected from it by the applied pressure wave, the atmospheric pressure wave moving through the transfer tube 17 reaches only half of its length. When the pressure wave reflected from the hydropneum accumulator 1 reaches the oscillator 3 and, therefore, the chamber is closed. The pressure drop 15 and the pressure in it rises from low to the inlet, the atmospheric pressure wave passes the entire length of the transfer tube 17 and reaches the relief open chamber 14, and the pressure in it decreases from the supplied to atmospheric pressure. As a result, a pressure difference occurs that the piston causes the displacement - valve 5 to the extreme left position until it stops in the saddle of the low side 11, water access to the discharge nozzle 9 is stopped and access to the working nozzle 8 simultaneously opens. - The resistance of the system increases, which causes the guide avlichesky punch that is accompanied pressure increase / phase terminates low pressure oscillations and high chinaets phase. On the shock pipeline 2 in the direction of hydropneumo. The accumulator i and along the transfer tube 17 toward the opening chamber 14 of the accumulator propagate a wave of increased (as compared to the supplied) pressure. Under the same pressure, water will expire through the working load 8. Thus, during the high phase, the high pressure chamber 12, the secondary chamber 22, the seating chamber 23, as well as the discharge closing chamber 15 and the pressure above the nozzle 8 remain. , while in the opening chamber of the vent 14 and the low pressure chamber 13 there is a pressure close to atmospheric. When the pressure wave going along shock conduit 2, П 6 reaches hydro-pneumatic accumulator 1 and reflects from it the wave of pressure applied, the wolf walking along transfer pipe 17 reaches only half of its length. By the time of the arrival; reflected from the hydropneumatic accumulator 1 of the applied pressure wave to the oscillation generator 3 and the discharge chamber 15 (the pressure in the latter decreases from elevated to supplied), the wave pressure of the pressure going through the transfer tube 17 will reach the discharge chamber 14, and the pressure in it will increase TC from atmospheric to high. As a result of the pressure difference in chambers 14 and 15, the valve-valve 5 will move to the right extreme position until it stops on the high side saddle 10. As a result, the water supply from the impact pipe 2 to the week-end chamber 22, the sitting-room commissary 23 through the windows 21 of the partition walls 20 high pressure chambers 12 and to the working nozzle 8, and open with access of water to the low pressure chamber I3 and to the discharge nozzle 9. As a result, the resistance of the system will decrease, which will cause a hydraulic shock in the oscillator 3 zone reduced by pressure. The high phase of the oscillation ends, and the low phase begins again. The process is repeated. The system entered into a stable resonant self-oscillation mode characterized by equality of low and high phases in time. , outputting the system from self-oscillation mode. it is enough to open the control valve 18. h.A.yajVf.g. 1 14 15

Claims (1)

The invention relates to the mining industry and is intended for hydraulic breaking of rocks with pulsating jets of high pressure, as well as for cleaning heat and power elements of boiler units. The aim of the invention is to increase the efficiency of hydraulic erosion by increasing the frequency of pulsations.