SU1093872A1 - Liquid vibration damper for pump - Google Patents

Abstract

AN ADDITIONAL VIBRATION FLUID for PUMP, comprising a housing with a central tube and a throttling element installed at the end of the tube and communicating the housing cavity with the main line, characterized in that, in order to increase vibration damping, the damper housing is provided with a connection for connection to the pump and // 7 2 and the tube is fixed in the nozzle with the formation of an annular channel between its outer surface and the inner surface of the nozzle, through which the body cavity communicates with the cavity Asosa, wherein the geometrical dimensions of the annular channel, the central area of the tube and the volume of the cavity associated dependence E i (Se housing

Description

The invention relates to auxiliary devices for a pipe network and can be used to eliminate fluctuations in the working fluid. A pressure oscillation damper for hydraulic lines is known, comprising a housing inside which a central tube is installed communicated with the internal cavity of the body through two throttling elements installed at the ends of the tube fl. The disadvantages of the known devices are the large size and weight that it acquires in order to achieve high damping efficiency while ensuring low resistance to the stationary fluid flow. The purpose of the invention is to increase the efficiency of damping vibrations. This goal is achieved by the fact that in a fluid vibration damper for a pump, comprising a housing with a center tube and a throttling element installed at the end of the tube and communicating the housing cavity, with the main line, the sleep damper housing is connected to the pump the tube is fixed in the nozzle with the formation between the outer surface and the inner surface of the nozzle of the annular channel, by means of which the housing cavity communicates with the pump cavity, and the geometric size of the rings th channel, the central area of the tube and the volume of the cavity associated dependence E SK, -a housing. S (o5-2). where bc is the length of the channel SK the cross-sectional area of the channel; a is the speed of sound in the working LIQUID} Vnp is the reduced volume of the case of the extinguisher; Wjvfo.- the maximum of the suppressed oscillation frequencies} SW..T. the area of the central tube of the quencher. The drawing shows a liquid quencher for a pump, a slit. The damper has a housing 1 with a nozzle 2, a cover 3 in which is placed an insert 4 with openings 5 for the passage of fluid, fixing the throttling element 6 of porous material. Box 4 also installs a central tube 7, forming an annular channel 8 inside the nozzle 2. The second end of the tube is fixed on the pylons 9 with the help of the tip element 10. The internal volume of the housing 1 forms a cavity 11. The damper works as follows. . A pulsating flow from the pump distribution unit spreads through the central tube 7 to the output line and through the annular channel 8 to the cavity 11 of the quencher. The central tube 7 of the quencher has a reduced flow area determined by the allowable pressure loss for the stationary flow of fluid from the pump, and having a length much larger than the diameter, has a large inertial resistance to the variable component of the flow. The annular channel 8 together with the cavity 11 of the quencher form a resonant oscillatory circuit, which in the operating frequency range has a much lower acoustic resistance. Therefore, the variable component of the flow branches into the cavity 11 of the quencher i, and due to the resulting oscillatory pressure drop between the cavity 11 and the outlet from the central tube 7 on the throttling element 6, the process occurs. The oscillation energy is dissipating. The input acoustic impedance of the proposed device in the working frequency range of the pumps is always less than the known device when selecting the parameters of the annular channel in accordance with the indicated dependences. This is because the resonant circuit - the annular channel - the cavity of the extinguisher case has its own oscillation frequency equal to the maximum 4actoTe operating range. This follows from the equation. At all operating (pre-resonant) frequencies, the loop impedance has a capacitive nature and values much lower than the wave resistance.

of the main line, therefore the technical and economic effect of the pressure oscillations in front of the retreat is to increase the effectiveness of the proposed device will always be the quenching of the oscillations of the fluid, less than that known by the pump.

Claims (1)

LIQUID OSCILLATOR FOR A PUMP containing a housing with a central tube and a throttling element installed at the end of the tube and communicating with the main cavity of the housing, characterized in that, in order to increase the damping efficiency, the damper body is equipped with a nozzle for connection to the pump, and the central tube is fixed in the nozzle with the formation of an annular channel between its outer surface and the inner surface of the pat · cutting, through which the body cavity is in communication with the pump cavity, The geometric dimensions of the annular channel, the area of the central tube and the volume of the body cavity are related by where Lk is the channel length; S ((~ the cross-sectional area of the channel; 'a is the speed of sound in the working fluid; . Vnp is the reduced volume of the cavity of the damper body; Nmyaig is the maximum of the suppressed oscillation frequencies; ~ area of the central pipe of the damper.