NO334127B1 - Device for pedestal connection for impeller - Google Patents

Description

DEVICE FOR SOCKET CONNECTION FOR IMPELLER

The present invention relates to a base connection for an impeller. More specifically, the invention relates to a base connection for an impeller for a hydraulic flow machine, where the impeller comprises an impeller hub and a plurality of vanes distributed around the impeller's central axis and releasably attached to the impeller hub by means of sockets that fit complementary to grooves in the impeller hub.

Impellers for fluid machines such as pumps and turbines can be subject to considerable wear. Particularly vulnerable are impellers through which particulate fluids are guided. For example, sandy river water has been shown to wear out impellers in hydraulic flow machines after a short period of use.

From patent NO 327520 Bl, an impeller for a fluid machine with vanes releasably connected to the impeller is known. The vanes are connected to an impeller hub by means of sockets, which fit complementary to grooves in the impeller hub, and screw connections. The blades are thus held in place by means of a simple friction coupling between the base and the impeller hub. The patent also describes how the vanes and other impeller components can be coated with a hard coating, for example a carbide, to increase the wear resistance, and thus the lifetime of a fluid machine which is exposed to great wear and erosion.

Patent document US 20080286130 Al describes an impeller with removable and flexibly positionable vanes.

It has been shown that known solutions are not sufficiently robust to withstand particularly hard stresses during extreme operation, for example during rush hour or large load changes in the impeller. This can lead to sliding of the base in the groove in the impeller hub, both radially and tangentially, whereby the screw connections can be exposed to large shear stresses and, in the worst case, break. When the plinth slides in the groove, any hard coating on the side surfaces of the plinth could also crack (crackle) at the side edges of the groove in the impeller hub, thus reducing the service life of the vanes.

The purpose of the invention is to remedy or to reduce at least one of the disadvantages of known technology, or at least to provide a useful alternative to known technology.

The purpose is achieved by features that are stated in the description below and in subsequent patent claims.

In a first aspect, the invention relates to a device for an impeller for a hydraulic flow machine, where the impeller comprises an impeller hub and a plurality of vanes distributed around the central axis of the impeller and releasably attached to the impeller hub by means of sockets which fit complementary to grooves in the impeller hub, characterized in that the one of the sockets or slots is designed with recesses on one side facing the other of the sockets or slots, and where the other of the sockets or slots is designed with wedges suitably complementary in the recesses.

In one embodiment, the recesses on one of the bases or tracks can be designed with a trapezoidal section. A wedge designed with a complementary suitable trapezoidal section can be wedged into the recess, whereby a tight frictional coupling occurs between the base and the impeller hub at the inclined surfaces between wedge and recess. The connection of the plinth to the impeller hub will thus be arranged to be able to take off lateral forces without the outer sides of the plinth, which may be coated with a hard coating, being loaded.

The actual wedge connection between the base and the impeller hub does not need to be coated with a hard coating, even if the vanes are coated with the hard coating, as the wedge connection will

be shielded from the fluid in the impeller. An advantage of this is that the positioning accuracy of the socket in the slot can be improved compared to a coupling according to known technology. This is because there is a relatively large uncertainty in the thickness of the hard coating as a result of standard, and to the extent known, application methods. The eccentricity of the impeller can thus be reduced, whereby the safety operation of a hydraulic flow machine will be improved.

In one embodiment, it may be the sockets which are designed with recesses, while the grooves in the impeller hub are designed with wedges suitably complementary to the recesses in the sockets.

In an alternative embodiment, it may be the slots that are designed with recesses, while the bases are designed with wedges suitably complementary to the recesses in the slots.

In one embodiment, the recesses on one of the sockets or tracks, and thus also the wedges on the other of the sockets or tracks, can extend over essentially the entire length of the sockets or tracks. In alternative embodiments, the wedge connection between the recess and the wedge may extend over a smaller portion of the length of the sockets and tracks.

In one embodiment, the bases can further be attached to the impeller hub by means of screw connections. The screw connections can be of known types.

In another aspect, the invention relates to a method for providing an impeller for a hydraulic flow machine, where the impeller comprises an impeller hub and a plurality of vanes distributed around the central axis of the impeller and releasably attached to the impeller hub by means of sockets which fit complementary to grooves in the impeller hub, characterized in that the method comprises: - designing one of the sockets or slots with recesses on a side facing the other of the sockets or slots; and - designing the other of the sockets or slots with wedges suitably complementary to the recesses.

A hydraulic flow machine comprising an impeller according to the above description is also described.

Furthermore, it describes a turbine comprising an impeller according to the above description.

In what follows, an example of a preferred embodiment is described which is illustrated in the accompanying drawings, where:

Fig. 1 shows in perspective an impeller according to known technology

Fig. 2 shows, seen from the side, a section of a coupling between a base and a running wheel hub according to known technology; Fig. 3 shows, seen from the side, a section of a coupling between a base and an impeller hub according to the present invention; and Fig. 4 shows, seen from the side, a section of an alternative connection between a base and an impeller hub according to the present invention.

In the following, the reference number 1 denotes an impeller according to the present invention. The impeller 1 comprises an impeller hub 2 in which a plurality of vanes 4 are designed to be releasably attached.

In Figure 1, the impeller 1 is shown with an impeller hub 2 to which nine vanes 4 are arranged to be attached to the impeller hub 2 around a central axis S of the impeller 1, but where only eight vanes 4 are shown for the sake of overview. The vanes 4 are designed with hollow wedges 43 which form a transition between the vanes 4 and sockets 41 which are used when attaching the vanes 4 to grooves 21 in the impeller hub 2, as shown in the subsequent figures. The vanes 4 have a curvature which is essentially adapted to the curvature of the tracks 21. In a situation of use, the impeller 1 could also include a ring, not shown, to which the upper part of the vanes 4 can be attached in a similar way as the lower part of the vanes 4 is attached to the impeller hub 2. Figure 2 shows a section through a part of a vane 4 which is attached to an impeller hub 2 with a coupling according to known technology. A screw connection in the form of a bolt 3 is screwed into the blade 4's base 41 from the underside of the impeller hub 2, whereby the blade 4 is attached to the impeller hub 2 by means of a simple friction coupling. As described in the above, it has been shown that a friction coupling of this type is not strong enough to prevent sliding of the base 41 in the groove 21 under particularly large stresses. Large lateral trifugal forces from rushing could cause radial sliding of the base 41 in the groove 21, while other stresses on the vanes 4, for example from large load changes, could cause a tangential sliding. This could cause large shear forces on the bolt 3, which in the worst case could break. There will typically be up to a couple of tenths of a millimeter clearance between the base 41 and the side edges in the slot 21 so that the base 41 can be placed down in the slot 21. The clearance is not easily visible on the figures in the measuring stick shown. Pressure between the base 41 and the side edges of the track 21, due to sliding, could destroy any hard coating on the vanes 4, and thus reduce the lifetime of the impeller 1. Figure 3 shows a section through a part of a vane 4 which is attached to a impeller hub 2 by means of a wedge coupling according to the present invention. The base 41 is designed with a recess 413 with a trapezoidal section, while the groove 21 in the impeller hub 2 is designed with a wedge 211 suitably complementary in the recess 413. The wedge 211 thus forms a wedge connection with the recess 413. The base 41 is pulled further down into the groove 21 by means of the bolt 3, in a similar manner as mentioned above, whereby a frictional coupling between inclined surfaces 211f on the wedge 211 and inclined surfaces 413f in the recess 413 is maintained. The wedge coupling removes lateral forces against the base 41, so that the bolt 3 is not loaded with shear forces.

Figure 4 shows an alternative embodiment of a wedge coupling according to the present invention. In this embodiment, the base 41 of the vane 4 is designed with a projecting wedge 411 suitably complementary in a recess 213 in the groove 21 in the impeller hub 2. Inclined surfaces 41 lf of the wedge rest against inclined surfaces 213f in the recess in a similar manner as described above.

Claims (9)

1. Device for an impeller (1) for a hydraulic flow machine, where the impeller (1) comprises an impeller hub (2) and a plurality of vanes (4) distributed around the central axis (1) of the impeller (1) and releasably attached to the impeller hub (2) by means of sockets (41) which fit complementary to grooves (21) in the impeller hub (2) characterized in that one of the sockets (41) or grooves (21) is designed with recesses (213, 413) on one side facing the other of the sockets (41) or grooves (21), and where the other of the sockets (41) or grooves (21) is designed with wedges (211, 411) suitably complementary in the recesses (213, 413). 2. Device according to claim 1, where the recesses (213, 413) on one of the bases (41) or the tracks (21) are designed with a trapezoidal section. 3. Device according to claim 1 or 2, where the sockets (41) are designed with recesses (413), while the grooves (21) in the impeller hub (2) are designed with wedges (211) suitably complementary to the recesses (413) in the sockets (41). 4. Device according to claim 1 or 2, where the grooves (21) in the impeller hub (2) are designed with recesses (213), while the bases (41) are designed with wedges (411) suitably complementary to the recesses (213) in the grooves (21). 5. Device according to any of the preceding claims, where the recesses (213, 413) on one of the bases (41) or the tracks (21), and thus also the wedges (211, 411) on the other of the bases ( 41) or the tracks (21), extend over essentially the entire length of the bases (41) and the tracks (21). 6. Device according to any of the preceding claims, where the sockets (41) are further attached to the impeller hub (2) by means of screw connections (3). 7. Hydraulic flow machine comprising an impeller (1) according to claim 1. 8. Turbine comprising an impeller (1) according to claim 1. 9. Method for providing an impeller (1) for a hydraulic flow machine, where the impeller (1) comprises an impeller hub (2) and a plurality of vanes (4) distributed around the center axis (S) of the impeller (1) and releasably attached to the impeller housing - leg (2) by means of sockets (41) which fit complementary into grooves (21) in the impeller hub (2) characterized in that the method includes: - designing one of the sockets (41) or grooves (21) with recesses ( 213, 413) on one side facing the other of the bases (41) or the tracks (21); and - designing the second of the sockets (41) or grooves (21) with wedges (211, 411) suitably complementary to the recesses (213, 413).