DE102004053087B4 - Turbine, pump or pump-turbine for water has hub fitted asymmetrically on axis of rotation of wheel - Google Patents

Abstract

The turbine, pump or pump-turbine has a running wheel (1) with blades (1.1) on a hub (5) in a housing (2) with a flow regulating path. A suction tube guides the water coming from the running wheel. The hub is fitted to, or made in one with, the axis of rotation (1.2) of the running wheel asymmetrically,

Description

The The invention relates to a turbine or pump or pump turbine, in particular the design of the impeller hub of such a turbine for optimized Discharge of water from the turbine towards the underwater. The The invention relates primarily to Francis engines, it comes but also Kaplan and pump turbines into consideration.

At Hydro turbines like Francis turbines are becoming increasingly demanding in terms of efficiency and the widest possible work area posed. Desirable is a variable use in terms of water flow from the extreme partial load operation up to overload operation. In all load ranges should one possible High efficiency with simultaneous vibration-free running of the turbine be achieved.

Francis turbines are due to different operating conditions due to the adjustment adapted to the vanes. Nevertheless occur especially under partial load unsteady flow conditions on, which lead to strong vibrations on the machine. Material damage as Episode can especially when the natural frequencies of components to agree with these vibrations. Another negative consequence of turbine vibrations are above all for big machines the impact that these vibrations have on the power grid. Synchronization riots are over The generator is coupled into the power grid and go there As voltage fluctuations unpleasantly noticeable. This results in adverse restrictions of the turbine operating area. So are critical part load ranges to drive through the turbine particularly fast when starting up and to avoid in continuous operation. It also finds an unwanted mutual Influencing water-bearing Systems take place.

At the optimal operation of a Francis turbine, ie in the so-called best-point, flows the water from the inlet spiral is axially symmetrical in the impeller, is there deflected by the blades so that it is axially in the Intake manifold flows and there is derived to the underwater. With such an ideal Operation is the flow Virtually swirl-free in the intake manifold. In operating conditions of the turbine outside the best point is this swirl freedom of the outflow to the impeller no longer exist. The causal relationship between the rotative component of the flow in the intake manifold and the machine vibrations is known. For stabilization the flow in the intake manifold and for suppression of the twist are baffles according to the current state of the art introduced along the suction tube. Such baffles can as Finns may be formed, which are oriented in the axial direction. this leads to to a suppression the twist in the intake manifold, but with the disadvantage of a diminished Efficiency associated.

to solution For this problem, variable baffles have been developed, which correspond the flow conditions can be retracted and extended. Other types of baffles are parallel to the wall surfaces of the Suction tube oriented and thus prevent by the stabilization the flow between baffle and suction tube wall a detachment of flow areas. Like the ones before This fin-like structures also reduces this construction the energy yield of the turbines. Furthermore, such increase static or variable constructions the effort for the production and Maintenance of turbines and are therefore a cost-relevant factor.

Other approaches to reducing the swirl and its effect under partial load conditions are the feeding of air or water into the transient flow. Design principles are known in which air is blown into the impeller or into the suction pipe from the intake manifold walls or the axis of the impeller. Such a principle is for example from the DE 97 10 42 B out.

A continuation This idea consists of a chamber partly filled with water and air to put the suction pipe through openings in the suction tube wall in contact with the flow in the suction tube is. Through this finds the inflow and outflow of Air and water according to the pressure conditions in the Saugrohrströmung instead. Also this solution for swirl control is associated with corresponding design effort, because here next to the extra Pressure chamber also a scheme for the air pressure in the environmental chamber must be established.

From the US 4 017 211 A Another approach has become known. Herein it is proposed to mount additional fins on the impeller which extend from the vane root in a spiral arrangement to the downstream boundary of the hub of the impeller.

The invention has for its object to provide an impeller hub for a water turbine or pump or pump turbine, which has significant advantages over the prior art. In particular, the hub should minimize the effect of pressure fluctuations in the intake manifold, as they are due to swirling flow at partial load conditions occur. This object is solved by the features of claim 1.

The Inventors have recognized that it is operating a Francis turbine under partial load to form a recirculation zone behind the Impeller comes. The transitional layer between this area and the main flow is characterized by strong speed gradients. Hydrodynamic instabilities of Kelvin-Helmholtz type lead for the formation of pegs, due to the total rotation of the flow a rotative component have. This rotating vortex braid causes a rotating pressure, in the area of the elbow the suction tube causes a force in the axial direction and to corresponding pressure fluctuations, which also in axial Direction and thus act in the direction of the turbine. Furthermore Is it possible, that these axial pressure fluctuations, associated with the helically shaped Wirbelzopf, to boundary layer detachments in the wall area of the bend to lead, the effect of acting in the axial direction of pressure fluctuations Additionally strengthen. This explains the emergence of pressure fluctuations in the intake manifold depends on the rotational frequency of the impeller.

A further component of stochastic pressure fluctuations can thereby arise due to the helical vortex top local pressure areas with pressing under the vapor pressure, resulting in the formation of cavitation bubbles leads. At the Bursting of these cavitation bubbles creates additional Voltage pulses.

According to the invention the hub of the wheel - in Reference to the axis of rotation of the impeller - asymmetrically designed. there the expression "asymmetry" is very comprehensive too understand. All solutions come into consideration, in which the hub is not rotationally symmetrical is. So the hub - also called "exhaust hood" or "impeller nut" - in usual Be wise hemispherical at its end, but on one side the axis of rotation bounded by a plane inclined to the rotation axis. Also, recesses are possible for example, those that are open towards the suction pipe, or Blind holes, their opening in the outflow direction point. Also, combinations of the above measures are possible, for example bevels of the Hub in combination with holes or recesses.

Also can the hub asymmetric projections be formed. So can for example, in the hub body Pens are used - always again asymmetrical with respect to the axis of rotation of the impeller.

By the measures mentioned becomes a force on the flow applied as an incentive to influence the said Swirl or vertebral braid is used. The vortex contains a different rotation frequency than before, one that has less adverse effects. There are thus no pressure pulsations, or only those of to a lesser extent.

Of the Gets vertebrae through the measures according to the invention also a different form than before. He is "hacked" by breaking off and not so stable anymore is as before.

The The invention is explained in more detail with reference to the drawing. Show it:

1 a Francis turbine in an axial section.

2 numerical flow simulation of the formation of a vortex head.

3 an impeller cutout in an axial section.

4 - 7 four different hub configurations.

In the 1 Francis turbine shown is constructed as follows: An impeller 1 includes a plurality of blades 1.1 , It is about a rotation axis 1.2 rotatable.

The impeller 1 is from a volute casing 2 surround. The impeller 1 is a wreath of vanes 3 upstream.

The turbine has a suction pipe 4 on. This includes an entrance diffuser 4.1 with an axis 4.1.1 , an adjoining manifold 4.2 , and adjoining suction box 4.3 , See the ideal dividing plane 1 between entrance diffuser 4.1 and manifold 4.2 , as well as the ideal dividing plane II between elbows 4.2 and suction box 4.3 ,

The entrance diffuser 4.1 can with respect to the axis of rotation 1.2 be designed asymmetrically. There are numerous possibilities for this. So can the axis 4.1.1 of the entrance diffuser 4.1 opposite the axis of rotation 1.2 be offset. The axis 4.1.1 of the entrance diffuser can be curved. The peripheral wall of the entrance diffuser 4.1 may be bulged on one side, based on the axis of rotation 1.2 , The cross section of the entrance diffuser 4.1 may be out of round, for example elliptical.

You recognize the hub 5 , This is limited at its downstream end by a respect to the axis of rotation 1.2 sloping surface 5.2 , The inclined surface is located on one side of the axis of rotation 1.2 ,

2 shows a numerical flow simulation in the working area of the partial load of a Francis turbine. Shown is the velocity distribution of the flow in the intake manifold with the formation of a helical Wirbelzopfes. This dissolves in the region of the manifold with dissipation of energy. In this process, pressure fluctuations occur due to the rotating pressure field of the vortex head, which continue in the axial direction to the turbine. This transient flow state is the cause of the rotational frequency-dependent vibrations on the turbine.

In the embodiment according to 3 In turn, one recognizes a moving blade as the most important elements 1.1 , the hub 5 as well as the rotation axis 1.2 , The hub 5 is here by a sloping surface 5.2 limited. Here is the oblique surface 5.2 the only downstream interface of the hub 5 represents.

You can also see a blind hole 5.3 , This is in relation to the axis of rotation 5.2 arranged eccentrically.

Instead of the blind hole 5.3 or in addition to this could also be on one side of the axis of rotation 1.2 further holes are provided, again in terms of size and arrangement asymmetrical to the axis of rotation 1.2 ,

The 4 to 7 each schematically illustrate a hub 5 , with different embodiments of the invention.

That's the way the hub points 5 according to 4 as the downstream end, a first inclined surface 5.2.1 and a second inclined surface 5.2.2 on.

The hub 5 according to 5 points to one side of the axis of rotation 1.2 a bowl-like recess 5.4 on.

The hub 5 according to 6 is with a bunch of pens 5.5 provided on one side of the axis of rotation 1.2 into the hub 5 are introduced.

The hub according to 7 is in its outflow area by a hemisphere surface 5.1 and a sloping surface 5.2 limited. It also has a relative to the axis of rotation 1.2 eccentrically arranged blind bore 5.3 on.

The hub 5 can also be asymmetric in that on its outer surface a bulge is applied, for example by means of build-up welding.

1

Wheel

1.1

blade

1.2

axis of rotation of the impeller

2

volute

3

vanes

4

suction tube

4.1

inlet diffuser

4.1.1

axis of the entrance diffuser

4.2

elbow

4.3

suction box

5

hub

5.1

Hemispherical surface

5.2

sloping surface

5.2.1

sloping surface

5.2.2

sloping surface

5.3

blind hole

5.4

shell-like recess

5.5

pencils

Claims (8)

Water turbine or pump or pump turbine; with an impeller ( 1 ), which has a variety of blades ( 1.1 ), a hub ( 5 ); with a spiral housing ( 2 ), which has a distributor for regulating the inflow into the impeller ( 1 ) having; with a suction tube ( 4 ) for guiding the out of the wheel ( 1 ) effluent water; characterized in that the flow-guiding outer contour of the hub ( 5 ) with respect to the axis of rotation ( 1.2 ) of the impeller ( 1 ) is asymmetrically designed and / or arranged. Water turbine or pump or pump turbine according to claim 1, characterized in that the hub ( 5 ) a blind bore ( 5.3 ), which in relation to the axis of rotation ( 1.2 ) of the impeller ( 1 ) is asymmetrically designed or arranged asymmetrically. Water turbine or pump or pump turbine according to claim 1 or 2, characterized in that the hub ( 5 ) in its outflow region of at least one with respect to the axis of rotation ( 1.2 ) inclined surface ( 5.2 ) is limited. Water turbine or pump or pump turbine according to one of claims 1 to 3, characterized in that the hub ( 5 ) in its outflow area through a hemisphere surface ( 5.1 ) and a sloping surface ( 5.2 ) is limited. Water turbine or pump or pump turbine according to one of claims 1 to 4, characterized ge indicates that the hub ( 5 ) in its outflow area by two with respect to the axis of rotation ( 1.2 ) inclined surfaces ( 5.2.1 . 5.2.2 ) is limited. Water turbine or pump or pump turbine according to one of claims 1 to 5, characterized in that the hub ( 5 ) at least one shell-like recess ( 5.4 ) having. Water turbine or pump or pump turbine according to one of claims 1 to 6, characterized in that the hub ( 5 ) over its outer surface protruding pins ( 5.5 ) having. Water turbine or pump or pump turbine according to one of claims 1 to 7, characterized in that the hub ( 5 ) has one or more bulges on its outer surface.