EP1651869B1 - Blade wheel for a pump - Google Patents

Abstract

A rotary wheel for radial pumps includes an intermediate wall at which one or more vanes are provided on both sides. Passage openings are formed in the intermediate wall in order to distribute a desired pump flow onto the vanes on both sides of the intermediate wall.

Description

The invention relates to an impeller for pumps, in particular radial pumps, according to the preamble of claim 1, and a pump, in particular radial pumps, with such an impeller, and a method for operating such a pump.

In centrifugal pumps with one or more impellers, the resultant of all axial forces acting on the impeller or impellers can reach considerable values during operation. Without additional measures, this resultant, which is referred to as axial thrust, would be transferred to the bearings via the pump shaft and load the same accordingly. From the prior art suitable design measures are known to reduce the axial thrust, for example, by a zweiströmige pump assembly with mirror-symmetrical design of the wheels or in single-flow pumps by attaching sealing gaps on both sides of the impeller and openings in the impeller, which the suction side with the Connect rear side of the impeller. Another possibility is to relieve the pump shaft by means of a suitable relief device, such as a relief ring or piston, from the axial pressure. Similar pump are also off US 2658455 A . US 564897A . US 1867290 A . EP 0112462 A and US 3478691A known.

To characterize a centrifugal pump impeller, the specific speed n _q is often used, which is in a known manner Flow Q, head H and speed n calculated. In pumps for small specific speeds n _q of, for example, less than 15 min. ^-1 , corresponding to a comparatively large delivery heights of, for example, greater than 50, 75 or 150 m and comparatively small delivery rates of, for example, less than 100, 50 or 25 m ³ / h, especially in such process pumps, the problem arises that the above-mentioned measures for the axial thrust balance can be used only limited. Thus, a zweiströmige execution of a pump for small flow rates a considerable additional effort compared to a single-flow design. A relief piston is also relatively complicated and is therefore used mainly in larger, multi-stage pumps. For a single-stage process pump, sealing gaps are usually provided on both sides of the impeller and openings in the impeller. An axial thrust compensation by means of sealing gaps on both sides of the impeller and openings in the impeller is only possible with closed wheels. For closed wheels with small specific speeds n _q , the problem of production, since the exit widths of such wheels are in the range of less mm and the production of closed wheels with small exit widths is technically difficult and expensive.

Another disadvantage of closed wheels are the high wheel friction losses (also called Radseitenreibungsverluste) and leakage that have such wheels at low specific speed n _q . At a specific speed n _q of, for example, 8 min. ^-1 alone, the wheel friction loss is 30% or more. Closed impellers for small specific speeds n _q therefore have a comparatively low efficiency.

For the above reasons, impellers for specific speeds n _q less than 10 or 15 min. ^-1 often semi-open. This has casting advantages and the wheel friction semi-open wheels is significantly lower than that of closed wheels. Semi-open impellers for specific speeds n _q less than 10 or 15 min. ^However, they have the disadvantage that the axial thrust compensation is difficult and the wheel friction losses are still very high.

An additional problem of closed and semi-open impellers for low specific speeds nq is the tendency to instability in the part-load range, ie such wheels have a characteristic that either unstable (corresponding to a falling characteristic when the flow Q approaches zero) or barely stable is (corresponding to a characteristic curve with no appreciable increase when Q approaches zero).

The object of the invention is to provide an impeller for pumps, in particular radial pumps, available, even at specific speeds n _q under 15 min. ^-1 enables a safe Axialschubausgleich, is comparatively inexpensive to produce, compared with a correspondingly sized closed or semi-open impeller has lower wheel friction losses and has a stable characteristic in the partial load range. Another object of the invention is to provide a pump, in particular a radial pump, with such an impeller and a method for operating such a pump.

This object is achieved according to the invention by the defined in claim 1 impeller, and the defined in claim 8 pump, as well as by the method defined in claim 10.

The impeller according to the invention for pumps, in particular radial pumps, comprises one or more blades and additionally an intermediate wall, on each of which one or more blades are provided on both sides. In the intermediate wall of the impeller at least one passage is formed to distribute a desired flow on the blades on both sides of the partition. Preferably, the impeller has a suction side, which is directed in the installed state of the impeller to a suction port of the pump, and preferably the blades are connected on the side remote from the suction side of the intermediate wall via the at least one passage to the suction side.

In a preferred embodiment, the impeller has a hub and a plurality of passage openings in an area of the impeller adjacent to the hub. In a further preferred embodiment, the impeller is open to the suction side or on both sides. Preferably The blades comprise shortened blades, so-called splitter vanes. Preferably, the impeller has a specific speed n _q in the range of 2 to 20 minutes. ^-1 , in particular in the range of 5 - 12 min. ^-1 , up.

Preferably, the blade outlet edges are chamfered on the suction side and / or on the suction side facing away from the intermediate wall. Advantageously, a bevel of the blades on the suction side, which falls to the suction side, while the blades have on the side facing away from the suction side of the intermediate wall axis-parallel exit edges. The bevel of the blade outlet edges supports an orderly circulation, which is particularly advantageous in the partial load range.

Preferably, the blades are formed on both sides of the intermediate wall so that at partial load an orderly circulation is formed and the impeller has a characteristic that steadily increases, in particular steadily and significantly increases when the flow Q goes to zero. For this purpose, the blades are preferably designed differently on both sides of the intermediate wall, for example in that the blades have different bevels of the outlet edges and / or different blade outlet angles β ₂ and / or different blade numbers on both sides of the intermediate wall.

Furthermore, the invention comprises a pump, in particular a radial pump, with an impeller according to the above description.

In the method according to the invention for operating a pump, in particular a radial pump, with at least one impeller, the impeller is additionally provided with an intermediate wall, on each of which one or more blades are provided on both sides, and with at least one passage connecting the two sides. In the method according to the invention, a desired delivery flow is distributed to the blades on both sides of the intermediate wall, preferably by passing part of the delivery flow through the at least one passage from one side of the intermediate wall to the other side.

The impeller according to the invention has the advantage that the distribution of the flow on the blades on both sides of the partition wall enables a safe Axialschubausgleich. Furthermore, the impeller is characterized by a stable characteristic curve and a stable partial load behavior. In the open mold, the impeller according to the invention allows a good efficiency, since the wheel friction, which makes up a large part of the losses, in particular for wheels with low specific rotational speeds, is completely eliminated. Thanks to the open shape, bucket outlet widths of a few mm can also be produced very well, for example by means of casting and / or milling. The distribution of the flow on the blades on both sides of the partition results in a reduced blade width, which has a favorable effect on the castability and the natural frequency of the blades. If necessary, the blade thickness compared to a conventional impeller with the same delivery and the same flow can be reduced.

Further advantageous embodiments will become apparent from the dependent claims and the drawings.

Fig. 1a

eine Schrägansicht eines Ausführungsbeispiels eines Laufrades gemäss vorliegender Erfindung,

Fig. 1b

das in Fig. 1a gezeigte Ausführungsbeispiel eines Laufrades von vorn,

Fig. 2

eine Detailansicht einer Ausführungsvariante mit einer verkürzten Zwischenwand, und

Fig. 3

ein Ausführungsbeispiel einer Prozesspumpe mit einem Laufrad gemäss vorliegender Erfindung.

In the following the invention will be explained in more detail with reference to the embodiments and with reference to the drawing. Show it:

Fig. 1a

an oblique view of an embodiment of an impeller according to the present invention,

Fig. 1b

this in Fig. 1a shown embodiment of an impeller from the front,

Fig. 2

a detailed view of a variant with a shortened partition, and

Fig. 3

an embodiment of a process pump with an impeller according to the present invention.

The FIGS. 1a and 1b show an embodiment of an impeller for pumps, in particular radial pumps, according to the present invention. The impeller 1 of the embodiment comprises a hub 4, a Intermediate wall 6, on each of which one or more blades 2a, 2'a, 2b, 2'b are provided on both sides, and a passage 3, for example, as in the FIGS. 1a and 1b is shown formed in the form of five passage openings to distribute a desired flow on the blades 2a, 2'a, 2b, 2'b on both sides of the partition 6. The passage openings are formed in the embodiment in a region adjacent to the hub 4 region of the impeller. Of course, other embodiments of the passage 3 are possible. Conveniently, the impeller 1 has a suction side 5a, which is directed in the installed state of the impeller to a suction port of the pump, and the blades 2b, 2'b on the side facing away from the suction side 5b of the intermediate wall are above the passage 3, ie in the shown example via the five passage openings, connected to the suction side 5a.

In the exemplary embodiment, the impeller 1 is open on both sides. But it is also possible that the impeller is only open on one side, for example, the suction side 5a or closed if necessary. In the exemplary embodiment, shortened blades 2'a, 2'b, so-called splitter vanes, are provided between the passage openings and the wheel circumference. In one embodiment variant, the blade edges are chamfered at the outlet. In the in the FIGS. 1 a and 1 b shown variant, the blade outlet edges on the suction side 5a are double bevelled, once they have a chamfer to the suction side and in addition to a pressure-side profiling (taper). If necessary, as in the FIGS. 1 a and 1 b, the blade inlet edges are provided on the suction side 5a with a suction-side profiling. Of course, it is also possible to bevel the blade outlet edges on the side facing away from the suction side 5b or provide for both sides together a common bevel, and to provide one and / or both sides axially parallel blade outlet edges.

In the exemplary embodiment, all blades 2a, 2'a, 2b, 2'b extend outward in the radial direction. The blade entry angle β ₁ and the blade exit angle β ₂ are thus both 90 ° in a first approximation. The actual blade outlet angle β ₂ on the suction side 5 a is slightly smaller as a result of the pressure-side profiling of the blade outlet edge 90 °. However, it is also possible to provide curved blades with a Schaufelaustritswinkel β ₂ less than or greater than 90 °. Advantageously, the blade entry angle β _{1 is} smaller than the blade exit angle β ₂ and preferably less than or equal to 90 °. Advantageously, the blades 2a, 2'a, 2b, 2'b at least on one side, preferably on the suction side 5a, a vane inlet width b ₁ which is greater than the vane outlet width _B2. The blade inlet widths b ₁ on the suction side 5 a and the side 5 b facing away from the suction side are expediently determined such that a good absorbency is obtained. The ratio of the blade widths on the suction side 5a and the side facing away from the suction side 5b can be selected within wide limits. In a typical embodiment, the blade widths are approximately equal on both sides.

In a preferred embodiment, the impeller 1 has a specific speed n _q in the range of 2 to 20 minutes. ^-1 to, preferably in the range of 7 - 12 min. ^-1 .

In the in Fig. 2 the embodiment shown, the impeller comprises an intermediate wall 6, the outer diameter is smaller than the outer diameter of the impeller. On both sides of the intermediate wall 6, a respective blade 2a, 2b is formed, which unite at the outer end, so that the two blades have a common outlet edge 7. The intermediate wall 6 and the blades 2a, 2b are arranged on a hub 4. In addition, in an area adjacent to the hub 4 region of the impeller, a passage 3 is formed, which connects the two sides of the intermediate wall 6 fluidly. Since the intermediate wall 6 extends in this embodiment only over part of the blade length, the intermediate wall can optionally also be referred to as a gutter.

Fig. 3 shows an embodiment of a pump, preferably a process pump, with an impeller according to the present invention. The pump 10 of the present embodiment comprises an impeller 1, for example an open impeller according to the embodiment described above, with a hub 4, an intermediate wall 6, on each side of each blades 2a, 2b are provided, and with a passage 3 to distribute a desired flow on the blades 2a, 2b on both sides of the partition 6. Furthermore, the pump 10 comprises a housing 11, an inlet or suction opening 12, an annular channel 17a, which adjoins the outside of the impeller 1, a diffuser insert 17 and an annular space 17b which opens into an outlet or discharge nozzle 13. By means of a modified insert 17, a spiral or an annular space can be generated, which are connected directly to the outlet or discharge nozzle 13. By adapting the diffuser insert 17, it is possible to compensate for the usually considerable radial thrust in pumps with low specific speeds. Of course, as a guide and a cast housing can be used without interchangeable insert.

Further, the pump comprises a shaft 14, a shaft seal 15, for example a stuffing box, and bearings 16a, 16b for supporting the shaft. The bearings 16a, 16b are designed in the embodiment as ball bearings, which can accommodate depending on the design in addition to radial and axial forces. In Fig. 3 For example, the bearings 16b on the right in the image are specially designed to receive radial and axial forces so that a possible, not fully balanced residual component of the axial thrust can be easily absorbed.

In a preferred embodiment of the inventive method for operating a pump, for example a pump according to the above-described embodiment, with at least one impeller, the impeller 1 is additionally provided with an intermediate wall 6, on each of which one or more blades 2a, 2b provided on both sides are, and with a passage 3, which connects the two sides of the intermediate wall 6 fluidly. In this embodiment of the method according to the invention, a desired flow is distributed to the blades 2a, 2b on both sides of the intermediate wall 6 by passing a portion of the flow, for example between 5 and 75% and preferably about 50%, through the passage 3 from one side of the partition 6 is led to the other side. The flow of the impeller 1 is advantageously split on the blades 2a, 2b on both sides, that the axial thrust is compensated. The above-described embodiment of the inventive Process can be used in both single-stage and multi-stage pumps.

The inventive impeller has the advantage that the distribution of the flow on the blades on both sides of the partition allows a simple and virtually complete axial thrust balance. Furthermore, the impeller described above is characterized by a stable characteristic and good efficiency. The inventive impeller can be used both in single-stage and in multi-stage pumps.

Claims (10)

1. An impeller for pumps, in particular radial pumps, said impeller including one or more vanes (2a, 2'a, 2b, 2'b), characterised in that the impeller (1) additionally includes an intermediate wall 6) at which a plurality of straight vanes (2a, 2'a, 2b, 2'b) extending radially outwardly are provided at each of the two sides and additionally include shortened vanes (2'a, 2'b), so called splitter vanes, and in that at least one passage (3) is formed in the intermediate wall (6) in order to distribute a desired pump flow to the vanes (2a, 2'a, 2b, 2'b) on both sides of the intermediate wall.
2. An impeller in accordance with claim 1 wherein the impeller (1) has a suction side (5a) which is directed towards a suction opening of the pump, wherein the vanes (2b, 2'b) at the side (5b) of the intermediate wall (6) directed away from the suction side are connected to the suction side (5a) via the at least one passage (3).
3. An impeller in accordance with one of the claims 1 or 2 wherein the impeller (1) has a hub (4) and wherein a plurality of passages (3) are formed in a region of the impeller (1) adjacent to the hub (4).
4. An impeller in accordance with any one of the claims 1 to 3 wherein the impeller (1) is open towards the suction side (5a) or towards both sides (5a, 5b).
5. An impeller in accordance with any one of the claims 1 to 4 wherein the vane outlet edges (7) are chamfered on the suction side (5a) and/or on the side (5b) of the intermediate wall (6) directed away from the suction side (5b), in particular in such a way that the vanes (2a, 2'a) are shortest on the suction side (5a) in the radial direction, whereas the vanes (2b, 2b') on the side (5b) directed away from the suction side of the intermediate wall (6) have outlet edges parallel to the axis.
6. An impeller in accordance with any one of the claims 1 to 5 wherein the vanes (2a, 2'a, 2b, 2'b) are formed on both sides of the intermediate wall (6) in such a way that in the case of part load an ordered circulation occurs and the impeller has a characteristic curve which rises constantly, in particularly rises constantly and clearly when the pump flow Q approaches 0.
7. An impeller in accordance with claim 6 wherein the vanes (2a, 2'a, 2b, 2'b) are designed differently on both sides of the intermediate wall (6) in particular in that the vanes (2a, 2'a, 2b, 2'b) have different chamfers of the outlet edges and/or different vane outlet angles β₂ and/or different numbers of vanes at the two sides of the intermediate wall (6).
8. An impeller in accordance with any one of the claims 1 to 7, wherein the impeller (1) has a specific rotational speed n_q in the region of 2 - 20 min.^-1, in particular in the region of 5 - 12 min. ^-1.
9. A pump, in particular a radial pump with an impeller (1) in accordance with any one of the claims 1 to 8.
10. A method for the operation of a pump, in particular a radial pump, with an impeller (1), characterised in that the impeller (1) is additionally provided with an intermediate wall (6) at which a plurality of straight vanes (2a, 2'a, 2b, 2'b) extending radially outwardly are provided at each of the two sides and additionally include shortened vanes (2'a, 2'b), so called splitter vanes, and is provided with at least one passage (3) which connects the two sides, and in that a desired pump flow is distributed to the vanes (2a, 2'a, 2b, 2'b) on both sides of the intermediate wall (6), in particular in that one part of the pump flow is fed through the at least one passage (3) from one side of the intermediate wall to the other side.

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