RU105381U1 - CENTRIFUGAL PUMP BODY - Google Patents

Abstract

The utility model relates to pump engineering, namely, to the designs of centrifugal pump housings with double-turn bends.

The centrifugal pump housing contains a two-turn outlet with 180 ° of the external and internal turns 1 and 2, respectively. The outer turn 1 includes a spiral, bypass and diffuser sections 3, 4 and 5, respectively. The inner turn 2 includes a spiral and diffuser sections 6 and 7, respectively. In this case, turns 1 and 2 are made with the following geometric relationships:

F _C1 = F _C2 ; F _D1 / F _D2 = 1.4 ... 1.6; F _B1 = F _B2 , where

F _C1 - the initial cross-sectional area of the spiral portion of the outer turn;

F _C2 - the initial cross-sectional area of the spiral section of the inner loop;

F _D1 - the initial cross-sectional area of the diffuser section of the external coil;

F _D2 - the initial cross-sectional area of the diffuser section of the inner coil;

F _B1 - the area of the output section of the diffuser section of the external coil;

F _B2 - the area of the output section of the diffuser section of the inner coil.

The use of the claimed utility model by optimizing the design of the flowing part of the centrifugal pump housing ensures the most complete alignment of fluid flows in the two-turn outlet, significantly reduces hydraulic losses in the external and internal turns of the outlet, which generally provides effective unloading from the radial forces of the impeller of the centrifugal pump using in its composition of the claimed building.

1 P. F-LA, 1 IL.

Description

The utility model relates to pump engineering, namely, to the designs of centrifugal pump housings with double-turn bends.

As a prototype, a centrifugal pump housing was selected, which contains a two-turn outlet with 180 ° external and internal turns, the first of which includes spiral, bypass and diffuser sections, and the second includes spiral and diffuser sections in which the external turn is made with an initial cross-sectional area of 1.15 ... 1.80 of the initial cross-sectional area of the inner coil, and the final cross-sectional area of 1.2 ... 2.5 the final cross-sectional area of the inner coil [USSR author's certificate No. 1710853, F04D 29/44, application No. 4793811/29 of 15.01 .90, publ. 02/07/92, bull. No. 5].

The disadvantages of the known housing are the low efficiency of equalizing fluid flows, significant hydraulic losses in the external and internal coils of the outlet, which generally leads to insufficient unloading of the centrifugal pump impeller from the radial forces using the known housing.

The technical problem to which the proposed utility model is aimed is to optimize the design of the flowing part of the centrifugal pump housing with a double-turn outlet, increase the efficiency of equalizing fluid flows in the double-turn branch, reduce hydraulic losses in the external and internal turns of the branch, and also unload from the radial forces of the impeller a centrifugal pump using the inventive housing in its composition.

This goal is achieved by the fact that in. a centrifugal pump housing containing a two-turn branch with 180 ° offset external. and internal turns, the first of which includes spiral, bypass and diffuser sections, and the second - spiral and diffuser sections, according to a utility model, the turns are made with the following geometric relationships:

F _C1 = F _C2 , where

F _C1 - the initial cross-sectional area of the spiral portion of the outer turn;

F _C2 - the initial cross-sectional area of the spiral section of the inner loop.

F _D1 / F _D2 = 1.4 ... 1.6, where

F _D1 - the initial cross-sectional area of the diffuser section of the external coil;

F _D2 - the initial cross-sectional area of the diffuser section of the inner coil.

F _B1 = F _B2 , where

F _B1 - the area of the output section of the diffuser section of the external coil;

F _B2 - the area of the output section of the diffuser section of the inner coil.

A comparative analysis of the claimed case with the prototype and with other solutions in the art shows that the set of features set forth in the patent formula is unknown from the existing level of technology, on the basis of which we can conclude that it meets the criterion of the utility model “novelty”.

The compliance of the proposed solution with the criterion of “industrial applicability” is evident from the following example of a specific implementation of the housing.

The utility model is illustrated by a drawing, which shows a General view of the body of a centrifugal oil main pump in longitudinal section.

The list of positions and symbols on the drawing.

1 - external coil;

2 - internal coil;

3 - spiral section of the external coil;

4 - a bypass section of the outer turn;

5 - diffuser section of the external coil;

6 - spiral section of the inner coil;

7 diffuser section of the inner coil;

F _C1 - the initial cross-sectional area of the spiral portion of the outer turn;

F _C2 - the initial cross-sectional area of the spiral section of the inner loop;

F _D1 - the initial cross-sectional area of the diffuser section of the external coil;

F _D2 - the initial cross-sectional area of the diffuser section of the inner coil;

F _B1 - the area of the output section of the diffuser section of the external coil;

F _B2 - the area of the output section of the diffuser section of the inner coil.

The body of a centrifugal oil main pump contains a two-turn branch with 180 and 1 and 2 turns displaced by 180 °, respectively. The outer turn 1 includes a spiral, bypass and diffuser sections 3, 4 and 5, respectively. The inner turn 2 includes a spiral and diffuser sections 6 and 7, respectively. In this case, turns 1 and 2 are made with the following geometric relationships:

F _C1 = F _C2 , where

F _C1 - the initial cross-sectional area of the spiral section 3 of the outer turn 1;

F _C2 - the initial cross-sectional area of the spiral section 6 of the inner coil 2.

F _D1 / F _D2 = 1.4 ... 1.6, where

F _D1 - the initial cross-sectional area of the diffuser section 5 of the outer turn 1;

F _D2 - the initial cross-sectional area of the diffuser section 6 of the inner turn 2.

F _B1 = F _B2 , where

F _B1 - the area of the output section of the diffuser section 5 of the outer turn 1;

F _B2 - the area of the output section of the diffuser section 6 of the inner coil 2.

The operation of a centrifugal pump using the inventive housing in its design is as follows.

The flow of the pumped liquid flows from the impeller (not shown) into turns 1 and 2. Owing to the experimentally selected geometric ratios of the flow parts of the turns 1, 2, an optimal redistribution of the flows of the pumped liquid in them is achieved, and the maximum speed equalization at the outlet of the diffuser sections 5, 7 is ensured. which reduces hydraulic losses when the fluid enters the discharge line. This significantly reduces the radial forces acting on the impeller of a centrifugal pump, which is especially important for large, for example, main oil pumps from the point of view of increasing their service life.

The use of the claimed utility model by optimizing the design of the flowing part of the centrifugal pump housing ensures the most complete alignment of fluid flows in the two-turn outlet, significantly reduces hydraulic losses in the external and internal turns of the outlet, which generally provides effective unloading from the radial forces of the impeller of the centrifugal pump using in its composition of the claimed building.

Claims (1)

A centrifugal pump housing containing a two-turn outlet with 180 ° external and internal turns, the first of which includes spiral, bypass and diffuser sections, and the second includes spiral and diffuser sections, characterized in that the turns are made with the following geometric ratios: F _C1 = F _C2 , where F _C1 is the initial cross-sectional area of the spiral portion of the outer turn; F _C2 - the initial cross-sectional area of the spiral section of the inner loop; F _D1 / F _D2 = 1.4 ... 1.6, where F _D1 - the initial cross-sectional area of the diffuser portion of the external coil; F _D2 - the initial cross-sectional area of the diffuser section of the inner coil; F _B1 = F _B2 , where F _B1 - the area of the output section of the diffuser section of the external coil; F _B2 - the area of the output section of the diffuser section of the inner coil.