SU750209A1 - Pressure pulsation suppressor - Google Patents

Description

(54) ABSORBER PULSATIONS PRESSURE

The invention relates to the field of hydraulic and gas drive, in particular to pulsation dampers, and can be used to dampen pressure pulsations in pipelines. A pulsation damper for pressure is known in the case of which a core is installed, on the outer surface of which a flow-through screw groove is made, communicating with radial channels with an internal axial channel of the core, in which the sleeve is installed. A disadvantage of the known device is that The pulsations are determined by the axial movement of the hollow sleeve through the axial channel of the core, which increases the size of the device and its weight. The aim of the invention is to reduce the size and weight of the device. This is achieved by the fact that in the wall of the sleeve bushing there is a through-screw slot connecting the radial channels with the bushing volost. I FIG. 1 shows a device, a longitudinal section; in fig. 2 and 3 is a cross-section A-A and BB of FIG. 1 respectively {in FIG. 4 - isometric core. The pulsation damper includes a housing 1 with an opening 2 for discharging the working fluid. The housing 1 is sealed with a lid 3 comprising a supply opening 4. working fluid. Inside the case there is a core 5j on the outer surface of which a screw groove 6 is made, communicating with a number of radial channels 7 located along the axis 5 of the radial channels 7 (see Fig 4) with an internal channel 8 which is rotatably installed relative to the core 5 a sleeve 9, the internal cavity of which forms a flow axial channel 10. T1ola sleeve 9 is rigidly connected to the shank 11, which can be associated with any type of regulator. There is a through hole in the wall of the hollow sleeve 9

screw slot 12, yes yes ICM. , figs. 1,3) the first hole of a row of 5 radial channels 7 along the axis of the bolter 7 a screw groove 6 with a flow axial channel Y.

The floor sleeve 9 has a radial hole 13, which communicates its internal channel 10 with a cavity 14 that communicates with a hole 2,

The length difference of the flow screw

the grooves 6 and 2. of the flow axial channel 10 in the place of their communication through one of the row of radial channels 7 along the axis 5 of the radial channels 7 and the screw slot 12 is selected from the ratio r

R.- (p.1-) l,

where P 1, 2, 3. „;

D. Pulsation wavelength, pressure. Rotation of the hollow sleeve 9 relative to the core 5 allows using the radial channels 7 and the screw slot 12 along the axis of the core 5 to change along the length of the axial channel the communication point of the flowing helical groove 6 with the flowing axial channel 10, and therefore the ratio of the lengths of & i ,, and thus tune in to the frequency of the pulsations to be quenched. ,

The damper operates as follows. When a pulsating fluid flow is supplied to the inlet 4, its flow rate splits into two parts, one of which enters the screw flow knob 6 and the other into the flow axial channel 1O of the hollow sleeve 9. The indicated main flow and its branched components The screws in the helical flow channel 6 and the axial flow channel 10 of the hollow sleeve 9 are characterized by a certain frequency and wavelength of the pulsations. In this case, one part of the flow passes a smaller path in the flow axial canap 10 of the hollow bushing 9 and enters the drain hole 2 with a certain pulse frequency of the other, the passage is a longer path in the flow helical groove 6,

enters the outlet hole 2, but with a phase shift of the pulsations by half a period.

As a result of this, mutual pulsation is suppressed.

To tune the main frequency of the pulsations to be quenched, the hollow sleeve 9 through the shank 11 is rotated to the required angle by the controller, thereby changing along the length of the axial channel 8

place, message flow helical. The winding 6 is through a screw slot 12 and one of a row of radial channels 7 C along the axis of the core 5 with a flow axial channel 1O. In this case, the ratio of the lengths of the 6th flow helical groove 6 to the t of the flow axial channel 10 is changed so that (2l

This allows the pulsation damper to be tuned to the fundamental frequency of the subject

damping pulsations. Due to the communication of two branched fluid flows through one of a row of radial housings 7 arranged along the core axis 5, and a screw slot 12 with a pulsation phase shift by half a period, pulsations are smoothed and two flux flows are deprived of pressure pulsations in the outlet 2 of the working fluid.

Claims (1)

1. USSR author's certificate in application number 2448434/29-О8, cl. F16L 55 / O2, 1977.