SU1273674A2 - Liquid pressure variation damper - Google Patents

Abstract

The invention relates to the field of machine building and is an improvement of the invention according to the author. St. No. 1225979. The purpose of the invention is to increase the efficiency of the device by increasing the volume of the cavitation zone. Inside the insert 5, located on the initial part of the expanding part of the nozzle 3, an annular profiled cavity p is made of (PPC) 6, separated from the flow part of the nozzle 3 by an elastic partition (EP) 7. In this part of the nozzle 3, a cavitation zone is formed 9, containing dry, dried steam; In EP 7, at least one hole 10 is made through which the gearbox 6 communicates with AC 9. The oscillation of the vibrations is carried out in. by changing the volume of bubbles of dry, dry steam in the PCA 9 and CAT 6, as well as due to the transfer of fluid from one aggregate state to another. CAT 6, together with EP 7, form a stagnant zone with the same properties as RC 9, as a result, the volume of the damping cavity increases, since EP 7 does not prevent the passage of pressure waves in CAT 6. 1 Il.

Description

The invention relates to mechanical engineering, in particular to devices for eliminating pressure fluctuations in hydraulic systems, can be used in the petrochemical industry, heat supply and energy and is an improvement of the known device for the main author. St. No. 1225979.

The purpose of the invention is to increase the efficiency of the device by increasing the volume of the cavitation zone.

The drawing shows a vibration damper, General view.

The damper comprises a housing 1 with connecting flanges 2. A narrowing-expanding cavitation nozzle 3 is installed in the housing 1, the input 4 of which is connected to an autonomous source of liquid (not shown). At the initial section of the expanding part of the nozzle, an insert 5 is placed, inside of which an annular profiled cavity 6 is made, separated from the flow part of the nozzle by an elastic partition 7. The edges of the partition 7 are pinched by the nozzle sleeve 8, which has an external thread. In the initial section of the expanding part of the nozzle, a cavitation zone 9 is formed containing bubbles of dry saturated liquid vapor. At least one hole 10 is made in the elastic partition 7, with the help of which the profiled cavity 6 is in communication with the cavitation zone 9. The pressure in the cavitation zone 9 and cavity 6 is equal to the pressure of the saturated liquid vapor, therefore, the partition 7 occupies the initial position indicated in the drawing. The opening angle οό of the expanding part of the nozzle does not exceed 10 °, since at large angles the cavitation nozzle becomes an oscillator.

The damper works as follows.

With a steady flow of the working fluid through the housing 1 and through the cavitation nozzle 3 in the initial section of the expanding part of the nozzle, a cavitation zone 9 containing bubbles of dry saturated steam is formed. The pressure in the cavitation zone is equal to the saturated vapor pressure of the working fluid 5. The same pressure is established in the annular cavity 6, since it is communicated with the cavitation zone 9 through the opening 10 in the elastic partition 7. In the event of 10 fluctuations in the pressure of the liquid, they are quenched by changing the volume of bubbles of dry saturated steam in the cavitation zone 9 and in the annular cavities 6. Thus, with an increase in the liquid pressure in the housing 1, the volume of the vapor bubbles of the working fluid decreases, while part of the vapor passes into the fluid. The decrease in fluid pressure in the housing 1 leads to 20 the appearance of new vapor bubbles and an increase in volume. Thus, the damping of fluid pressure fluctuations occurs both due to a corresponding change in the volume of vapor bubbles 25 and due to the transition of fluid from one state of aggregation to another. The annular profiled cavity 6 together with the elastic partition 7 forms a stagnant zone 30 having the same properties as the cavitation zone 9. As a result, the volume of the damping cavity increases, since the elastic partition does not prevent the passage of pressure waves into the cavity 6.

Claims (2)

"The invention relates to a machine CTpoeHHiOj, in particular, to devices for eliminating pressure fluctuations in ri-hydraulic systems, can be used in petrochemical industry, heat and water supply and energy, and is an improvement of the known device according to the main author. Saint 1225979. The purpose of the invention is to increase the efficiency of the device by increasing the volume of the cavitation zone. The drawing shows a vibration damper, a general view. The damper includes a housing 1 with connecting flanges 2. In the housing 1 a tapering-expanding cavitation nozzle 3 is installed, the inlet 4 of which is in communication with an independent source of fluid (not shown). In the initial part of the expanding part of the nozzle there is an insert 5 inside which an annular shaped cavity 6 is made, which is separated from the nozzle through part by an elastic partition 7. The edge of the partition 7 is clamped by a nozzle sleeve 8 which has an external thread. On on. The initial part of the expanding part of the nozzle is formed by a zone of cavitation 9 containing bubbles of dry saturated vapor of a liquid. In the elastic partition 7, at least one hole 10 is filled, through which profiled cavity 6 communicates with the cavitation zone 9. The pressure in the cavitation zone 9 and cavity 6 is equal to the pressure of saturated liquid vapor, therefore the partition 7 occupies the initial position indicated on the drawing . The opening angle c6 of the expanding part of the nozzle does not exceed 10 °, so at large angles the cavitation nozzle becomes an oscillation generator. The damper works as follows. At steady flow of working fluid through the housing 1 and through the cavitation nozzle 3, a cavitation zone forms at the initial part of the expanding part of the nozzle 742. 9 containing bubbles of dry saturated steam. The pressure in the cavitation zone is equal to the saturated vapor pressure of the working fluid. The same pressure is established in the annular cavity 6, as it communicates with the cavitation zone 9 through the opening 10 in the elastic septum 7. In the event of fluctuations in the fluid pressure, they are extinguished by changing the volume of dry bulk (venous vapor in the cavitation zone 9 and in the annular cavity 6. Thus, with an increase in the pressure of the fluid in the housing 1, the volume of vapor bubbles of the working fluid decreases, and a part of the vapor passes into the fluid. vapor bubbles and an increase in volume. Thus, the quenching of the fluid pressure fluctuations occurs both due to a corresponding change in the volume of the steam bubbles and due to the transfer of fluid from one aggregate state to another. The annular shaped cavity 6 together with the elastic partition 7 forms a stagnant zone, possessing the same properties as the cavitation zone 9. As a result, the volume of the damping cavity increases, because the elastic partition does not prevent the passage of the pressure into the cavity 6, the Formula from Bretenoux damper fluid pressure oscillations by the authors. St. No. 1225979, characterized in that, in order to increase efficiency by increasing the volume of the cavitation zone, the cavitation nozzle is provided with an annular shaped cavity located in the initial portion of the expanding part of the nozzle, while the cavity is separated from the nozzle by an elastic partition containing at least one hole.