SU767404A1 - Method and device for diminishing countercurrents in centrifugal pump - Google Patents

Description

(54) METHOD FOR REDUCING ANTI-DRAINS IN A CENTRIFUGAL PUMP AND DEVICE FOR ITS IMPLEMENTATION

one

The invention relates to pump engineering and can be used in power engineering and chemical engineering to reduce backflow in a pump at low flow rates when pumping gas-liquid mixtures.

There is a known method for reducing backflows in a centrifugal pump by increasing the axial component of the speed of the pumped medium L.

It is also known to implement a method for reducing backflows in a centrifugal pump C2,

A disadvantage of the known method and device is the low efficiency of the pump, since the reduction of counterflow is achieved by bypassing part of the pumped liquid to the pump inlet

The aim of the invention is to increase the efficiency of the pump for pumping gas-liquid media with separation of the gas phase.

The goal is achieved that in the proposed method of reducing countercurrents in a centrifugal pump, the axial component of the speed of the pumped medium is increased by creating at the inlet of the pump 30

kayernyh kayerny supported by the supply of part of the separated gas phase.

For this purpose, a device for reducing backflows in a centrifugal pump includes a cavitating element located in the inlet of the pump, with a channel for feeding the separated gas phase.

The drawing shows a device for carrying out a method for reducing backflows in a centrifugal pump, a general view.

The device contains a cavitating element 2 located in the inlet pipe 1 of the pump, for example a disc with a channel 3 for supplying the separated gas phase to the cavitation

20 cavern.

In the pump casing, the wheel 5 is mounted on the shaft 4 with its front-mounted sleeveless screw 6 and the wing 7 of the suction device (not shown) connected to the cavity of the screw 6 by the hole 8. The outlet 9 of the suction device 10 is connected to the channel 3 ..

A method for reducing countercurrents in centrifugal iilcbce is implemented as follows.

When mixing gas-liquid media at a reduced flow rate, the axial component of the speed of the pumped medium is increased by creating a cavitation cavity in the inlet 1 of the cavitating element 2 flowing around it, and the cavity is then supported by supplying a portion of the separated gas phase into it. The gas phase is twisted by screw b and sucked through the hole 8 in the impeller 5, the impeller 7, and then fed to the outlet 9 of the suction device.

A portion of the separated gas through conduit 10 is supplied to the cavities for cavitation after cavitation & 2, maintaining the stability of the latter.

The cavity, occupying a significant part of the cross section of the inlet nozzle 1, leads to an increase in the axial component of the velocity of the pumped medium and a decrease due to this counterflow.

Diameter d midsection cavitating. element is determined by the formula

 °

.

do - diameter of the inlet

where is the pump;

Shoo the coefficient of drag of a cavitating element with zero cavitation number (for a disk Shoo 0/2 is an expense parameter equal to

the ratio of current fluid flow at zero angle of attack;

The proposed method will increase the efficiency of the pump, because, due to the low density of the gas, the power expended to create an artificial cavity is much less power consumed to increase the pressure of the bypass fluid.

Claims (2)

1. A method of reducing countercurrent in a centrifugal pump by increasing the axial component of the speed of the pumped medium, and is also distinguished by the fact that, in order to increase the efficiency of the pump when pumping hydraulic fluid. media with separation of the gas phase, the axial component of the velocity of the medium is increased by creating a cavitation cavity at the pump inlet supported by feeding it a part of the separation gas phase. 2. A device for carrying out the method according to Claim 1, comprising a cavitating element located in the pump inlet nozzle with a channel for supplying the separated gas phase. Sources of information taken into account in the examination  1. Borovsky B.I., Ershov N.S., Ovs nnikov B.V. and others. High-speed vane pumps. M., Mechanical Engineering, 1975, p.292. 2. Arinushkin L.S. Aircraft centrifugal pumping units. M., Mechanical Engineering, 1967, p. 64., fig. 2.22.