RU51130U1 - RADIAL VANE PUMP - Google Patents

Abstract

The utility model relates to pump engineering and can be used for pumping liquid media, preferably highly viscous. In a radial vane pump containing a housing with a branch, a suction pipe and an impeller mounted on a shaft with a spiral blade mounted on the disk, a spiral blade is additionally made on the reverse side of the disk, two covers with a suction pipe on each side are attached to each, with the ability to control the gap between the spiral blades and covers, while the spiral blades are made with a width that decreases from the center of the impeller to its periphery. More than one spiral blade can be installed on each side of the impeller disk. The technical result of using the utility model is to increase the pressure and efficiency of the pump.

Description

The utility model relates to pump engineering and can be used to pump liquid media, preferably highly viscous.

Known centrifugal-spiral pump, protected by USSR Patent No. 8969, class. 59 e, 8/01, publ. 1929.04.30.

All surfaces of the flow channel are movable, which reduces the energy performance of the pump.

Closest to the claimed technical essence and the achieved result, selected as a prototype, is a pump for pumping highly viscous liquids, protected by RF patent No. 2031253, cl. F 04 D 7/04, publ. 1995.03.20.

In a known pump comprising a housing, an impeller mounted on a hollow shaft with one spiral blade mounted on one disk with holes communicating through a hollow shaft with a source of lubricating fluid. Lubricating radial grooves connected with holes in the disk are made in the disk on both sides of the disk, while the lubricating groove on the suction side of the disk is in communication with the lubricating fluid source through the throttling hole.

A disadvantage of the known pump are not high enough pressure and efficiency.

The problem solved by the proposed solution is the creation of a pump for pumping liquid media, mainly highly viscous with high energy performance.

The technical result of using the utility model is to increase the pressure and efficiency of the pump.

This result is achieved by the fact that in a radial vane pump containing a housing with a tap, a suction pipe and an impeller mounted on the shaft with a spiral blade mounted on the disk, a spiral blade is additionally made on the back of the disk, two covers are attached to the housing from opposite sides with a suction pipe on each, with the possibility of adjusting the gap between the spiral blades and covers, while the spiral blades are made with a width decreasing from the center of the impeller to its periphery.

More than one spiral blade can be installed on each side of the impeller disk.

Figure 1 shows a radial vane pump, a longitudinal section; figure 2 - the impeller; figure 3 - impeller, view A; figure 4 - plot of radial velocities (V _r ) of the fluid flow at the exit of the impeller having one spiral blade mounted on one disk; figure 5 is a plot of radial velocities (V _r ) of the fluid flow at the outlet of the impeller having two spiral blades mounted on one disk on both sides of it.

The radial vane pump comprises a housing 1 and an impeller 3 mounted on the shaft 2 with spiral blades 4 mounted on one on both sides of the disk 5. The blades 4 have a width that decreases from the center of the impeller to its periphery.

Two covers 6 are attached to the housing 1, each of which contains one suction pipe 7. The gap between the blades 4 of the impeller 3 and the covers 6 can be adjusted, for example, by means of squeezing screws 8. The turns of the spiral blades 4, the disk 5 and the inner surface of the covers b form two flow channels 9 of the impeller 3. The housing 1 includes an outlet 10. It is possible to install more than one spiral blade on each side of the impeller disk.

Radial vane pump operates as follows. The engine (not shown in FIG.) Drives the shaft 2 and the impeller 3 with the blades 4. The fluid through the suction nozzles 7 of the covers 6 enters two flow channels 9 of the impeller 3 and is pumped from the center of the impeller 3 to its periphery. After exiting the flow channels 9 of the impeller 3, both fluid flows are combined and enter the outlet 10, from where the combined flow is directed to the discharge pipe (not shown in Fig.).

From the diagrams of the radial velocities (V _r ) of the fluid flow at the exit of the impeller shown in Figs. 4 and 5, it can be seen that for the same impeller width, the area of the diagrams of the radial velocities (V _r ) at the exit of the wheel with one spiral blade installed on one side of the disk, and at the exit of the wheel with two spiral blades mounted on both sides of the disk, are identical, therefore, the same feed. However, with the same impeller width in the case of a wheel with two spiral blades mounted on both sides of the disk, the depth of the flow channel of the impeller is half as much. As a result of this, when pumping liquids, a multiple increase in pressure or the possibility of reducing the outer diameter of the impeller and, accordingly,

Claims (2)

1. A radial vane pump, comprising a housing with a branch, a suction pipe and an impeller mounted on a shaft with a spiral blade mounted on the disk, characterized in that a spiral blade is additionally made on the back of the disk, two covers with a suction are attached to the housing from opposite sides a branch pipe on each, with the possibility of adjusting the gap between the spiral blades and covers, while the spiral blades are made with a width that decreases from the center of the impeller to its periphery. 2. The radial vane pump according to claim 1, characterized in that more than one spiral blade is installed on each side of the impeller disk.