NO322075B1 - Impeller for a hydraulic hydraulic machine according to the Francis principle - Google Patents

Abstract

The paddle wheel for a hydraulic flow machine, especially a water turbine, has a wheel base (1.1), a wheel crown (1.2) and a number of paddles (1.3), each of which has an entry edge (1.3.1) and an outlet edge (1.3.2). Each outlet edge (1.3.2) has deflection at point (C) near the wheel base (1.1) to run (1.3.3) on the base (1.1) to meet a point (B) which is opposite to, and downstream from, the point (A) where the outlet edge (1.3.2) would meet the wheel base without any deflection. The deflection line between points (B,C) is straight, concave or convex.

Description

The invention relates to an impeller for a hydraulic flow machine according to the Francis principle, in particular for a water turbine, pump turbine or pump, comprising a housing which encloses the impeller as well as appropriate connections for water supply and outlet. Such a machine also generally comprises a guide apparatus which exhibits a number of vanes and which is connected in front of or behind the impeller or a further impeller. See for example US-A-4 496 282.

DE-C-323 190 and DE-C-322 233 respectively refer to a hydraulic flow machine based on the Francis pir sippet and as stated in the introduction in claim 1.

During operation, the impeller in such a machine is exposed to high stresses from the acting forces. This is particularly the case at the connection point between the vanes on the one hand and the impeller base and the impeller rim on the other side. A particularly large stress peak occurs in the transition area between the vanes and the impeller base. In case of extreme stress, this can lead to cracks at the mentioned places.

The normal measures only have a limited effect. Thus, for example, the blade thickness has been partially or completely increased. Cracks still occur. In addition, optimal hydraulic performance will not be achieved in this way.

The present invention consists in designing the impeller of a flow machine according to the Francis principle in such a way that, at the critical points mentioned, unnecessary strength is ensured for the machine to have the desired service life, without thereby affecting the optimum design in flow technology, and that the necessary the effort is the least possible. Thus, among other things, the blades must be made as thin as possible.

This task is solved using the features in claim 1.

According to this requirement, each of the vanes in the area at the outlet edge and primarily in the area at the connection to the impeller bottom is enlarged by means of a small surface element in the downstream direction. The outlet edge of the vanes, which normally shows a continuous course, thus exhibits a deflection at a certain distance from the impeller base, so that the end point of the outlet edge is further downstream on the impeller base than would otherwise have been the case.

The relief element thus takes over the task of transforming the stiffness of the vane so that the maximum occurring crack stress in the connection area which is sensitive to crack formation is added to a large surface area in the area of the relief element, which leads to a simultaneous lowering of the stress level.

Thus, the inventor has indicated a very simple measure. The aforementioned surface element need not be thicker than the rest of the blade in the area of the outlet edge.

What applies to the transition between the blade and the impeller base can also apply to the transition between the blade and the impeller rim. However, the tension in the transition area to the impeller bottom is usually greater and more dangerous, so that the measure according to the invention is more important in this area.

The invention shall be explained in more detail with reference to the drawing. The following is shown on this:

Figure 1 shows a Francis turbine seen in axial section.

Figure 2 shows, in a meridian section, a section of an impeller for a Francis turbine.

Figure 3 shows the object in Figure 1 on a larger scale.

The Francis turbine shown in Figure 1 has as its main element an impeller 1, a housing 2, a guide device 3 and a shaft 4.

The impeller comprises an impeller base 1.1, an impeller rim 1.2 and a number of vanes 1.3. Between the turbine cover 2.1 and the impeller base 1.1 there is a side space 5 for the wheel, and between the impeller rim 1.2 and the housing 2, there is a side space 6 for the wheel.

Figure 2 again shows an impeller bottom 1.1 in a Francis tubin, the impeller rim 1.2 and a vane 1.3.

The vane 1.3 has an inlet edge 1.3.1 and an outlet edge 1.3.2.

As can be seen further, the vane 1.3.2 exhibits a deflection not far from the impeller base 1.1. The course of the outlet edge 1.3.2 on a previously known blade is shown with a dotted line. Due to the course of the outlet edge 1.3.2 according to the invention, the vane 1.3.1 according to the invention has, compared to previously known vanes, an additional vane element 1.3.1 which is clearly larger than the usual arc-shaped transition. In the present case, the blade element 1.3.1 is essentially triangular in shape.

Figure 3 shows the conditions in detail. As can be seen, the outlet edge 1.3.2 shown with a dotted line - as is the case with conventional blades - hits the impeller bottom 1.1 at a point A. In the process according to the invention, however, the outlet edge 3.2 hits the impeller bottom 1.1 at point B. The impact point B is downstream in relation to to impact point A on a conventional blade.

In detail, the course that follows is seen in the direction towards the impeller bottom 1.1: First there is a first rounding that starts from a largely rectilinear outlet edge. This first rounding turns into a convex curvature. There is then a further rounding which at point B runs smoothly into the inner contour of the impeller base 1.1.

As an alternative to this, the course of the outlet edge according to the invention can also take place in a straight line. Furthermore, in general, i.e. over the largest part of its extent, it can also be slightly concave.

The further blade element 1.3.1 according to the invention can be produced in one piece with the blade 1.3. This will particularly be the case when the entire impeller is produced by casting. However, it can also be produced in one piece. It can have the same thickness as the drainage edge area 1.3.2 otherwise. However, it can also have a thickness that deviates from this range. Furthermore, it can slope in relation to the main part of the blade 1.3, so that there is a certain deflection of the flow in one direction or the other.

The location at point C, from which edge section 1.3.3 runs out, can also be different from case to case. Thus, the distance between points A and C can be between 0.1 to 0.3 of the entire 1.3.2 overall length of the outlet edge. The ratio of 0.2 has been found to be particularly advantageous. Deviations from the aforementioned range upwards and downwards are nevertheless possible.

That is why no one has so far shown that the measure A-C as well as the measure B - C must be at least 5% of the blade length measured in the direction of flow. However, it is not out of the question that an even smaller target can provide an improvement with regard to the solution of the given task.

Claims (6)

1. Impeller for a hydraulic flow machine after the Francis pirn sippet, in particular for a water turbine; with an impeller bottom (1.1), an impeller rim (1.2) and a number of vanes (1.3); each vane (1.3) having an inlet edge (1.3.1) and an outlet edge (1.3.2); in that the outlet edge (1.3.2) of each vane (1.3) is deflected at point (C) in the area of the impeller bottom (1.1) in such a way that the further course of the outlet edge (1.3.2) (1.3.3) hits the impeller bottom ( 1.1) at point (B) which is downstream in relation to an impact point (A) without deflection of the outlet edge (1.3.2), characterized by the longitudinal section (1.3.3) situated between the deflection point (C) and the impact point (B) of the outlet edge (1.3.2) is straight or convex. 2. Impeller according to one or more of claims 1, characterized in that the length section between points (A) and (B) is at least 3% of the blade's length section at the bottom of the impeller between the inlet edge and point (A). 3. Impeller according to claim 2, characterized in that the length section between points (A) and (B) is at least 5% of the length section of the blade at the bottom of the impeller between the inlet edge and point (A). 4. Impeller according to one of claims 1 to 3, characterized in that the distance between points (A) and (C) is at least 3% of the longitudinal section of the blade at the bottom of the impeller between the inlet edge and point (A). 5. Impeller according to one of claims 1 to 4, characterized in that the distance between points (A) and (B) is at least 5% of the length of the blade at the bottom of the impeller between the inlet edge and point (A). 6. Hydrodynamic flow machine according to the Francis pirn sippet, characterized by an impeller as stated in one of claims 1 to 5.