EP0528845A1

EP0528845A1 - Single-blade impeller for rotary pumps.

Info

Publication number: EP0528845A1
Application number: EP91908572A
Authority: EP
Inventors: Wolfgang Metzinger; Rolf Witzel
Original assignee: KSB AG
Current assignee: KSB AG
Priority date: 1990-05-12
Filing date: 1991-05-02
Publication date: 1993-03-03
Anticipated expiration: 2011-05-02
Also published as: WO1991018210A1; US5348444A; AR244396A1; EP0528845B1; DE4015331A1; DE59106053D1

Abstract

L'invention concerne une roue à aube pour pompes centrifuges destinées à l'extraction de liquides chargés d'impuretés solides, notamment à l'extraction d'eaux polluées chargées de constituants à fibres longues, dans laquelle un canal (4) est formé entre le disque de recouvrement avant (1) et le disque de recouvrement arrière (2) de la roue à aube, et l'aube, dont l'épaisseur varie sur toute son étendue. Outre les exigences courantes formulées pour satisfaire l'absence d'engorgements, l'obtention de valeurs aussi faibles que possible du balourd mécanique et de la poussée hydrodynamique, ainsi que l'obtention d'une réduction considérable de la cavitation préjudiciable à la rotation et au refoulement, l'invention prévoit que l'angle (beta) mesuré sur la ligne médiane (11) de l'aube (3), à partir de l'entrée (5) jusqu'à au moins 90 degrés de l'angle de rotation, est égal ou inférieur à 0 degré, tandis que l'angle de l'aube (beta) à la sortie (6) est positif.The invention relates to an impeller for centrifugal pumps intended for the extraction of liquids laden with solid impurities, in particular the extraction of polluted water laden with constituents of long fibers, in which a channel (4) is formed between the front cover disc (1) and the rear cover disc (2) of the impeller, and the blade, the thickness of which varies over its entire extent. In addition to the current requirements formulated to satisfy the absence of bottlenecks, obtaining values as low as possible of the mechanical unbalance and the hydrodynamic thrust, as well as obtaining a considerable reduction in cavitation detrimental to rotation and at the discharge, the invention provides that the angle (beta) measured on the center line (11) of the blade (3), from the inlet (5) to at least 90 degrees from the angle of rotation, is equal to or less than 0 degrees, while the angle of the blade (beta) at the exit (6) is positive.

Description

description

Bucket wheel for centrifugal pumps

The invention relates to an impeller for centrifugal pumps for conveying liquids mixed with solid admixtures, in particular for conveying dirty water with long-fiber constituents, with a channel between the front and rear cover plates of the impeller and the blade, the strength of which changes over the extent thereof is formed.

The designer of a paddle wheel that is primarily used in wastewater production faces a complex task. He must not only design the paddle wheel and its channel in such a way that an accumulation of solid components in the conveying path, but above all a blockage caused thereby, can be avoided with certainty. He must also be careful to meet the somewhat contradictory requirement for the most favorable possible mass distribution of the inevitably asymmetrical designed impeller. And last but not least, he has to aim for a high energy turnover in the bucket wheel he developed.

The fulfillment of the stated requirements is impaired by various problems which result from the funding conditions and the special features of the paddle wheel and which can influence and overlap one another in a manner which is often not predictable. In the majority of all applications, centrifugal pumps with paddle wheels are operated at a constant drive speed. The delivery conditions of such a centrifugal pump are usually subject to constant change. For example, the inlet height fluctuates between a maximum and a minimum value. The operating point of the centrifugal pump, i.e. the intersection between the constant pump characteristic and the variable system characteristic, is therefore also subject to the change.

The shift in the operating point now involves both a change in the relative blade inflow velocity and a change in the relative inflow direction. This results in a static pressure distribution along the blade contour, which is specific for the respective blade shape. The integration of the pressure distribution from the blade inlet to the blade outlet edge results in a blade force that rotates relative to a fixed reference point as a deflecting transverse force. This transverse force, which is also referred to as hydrodynamic buoyancy, forms a harmonically acting excitation force, which in a system capable of oscillation, ie, for example, B. a system that can cause major problems. It should therefore be kept as small as possible.

Another problem with single-impeller or single-channel impellers is the mechanical imbalance that results from the uneven mass distribution of the impeller. It would now be obvious to use the mechanical imbalance to compensate for the hydrodynamic lift, the residual force resulting from the vectorial addition of the two forces being compensated for by an additional weight. Now, however, the mechanical imbalance and the centrifugal forces are forces independent of the load, while the hydrodynamic buoyancy changes with the delivery rate also the angle of attack relative to the blade. It follows that there is a compensation of mechanical unbalance and the hydrodynamic force can only be achieved for one working point of the centrifugal pump.

There is therefore a requirement to keep the mechanical imbalance of the impeller as small as possible in addition to the hydrodynamic buoyancy. For the bucket, it is important to strive for a geometric design, the hydrodynamic buoyancy of which does not undergo a change of direction within the working area. With a wing one would speak of a pressure point fixed profile.

Another important aspect in the design of the blades is the optimization of the cavitation behavior of the centrifugal pump. Due to the system-induced hydrodynamic asymmetry, early cavitating paddle wheels can release stationary and transient excitation forces which occur in the form of vibrations and which endanger the operation of the centrifugal pump.

Various articles are known from the literature that deal in detail with mass balancing and the risk of constipation. However, less attention was paid to the mutual influence of the various forces acting on the impeller. Above all, the influence of cavitation was not given the importance that it really has.

Thus, the US-PS 17 54 992 deals with the problem of balancing the mass imbalance on a single or single channel. To cope with this problem, the cited patent provides two measures: First, the blade forming the channel has a continuously decreasing thickness over its extension, so that, despite the asymmetrical mass distribution, an overall relatively low mass unbalance is caused. Second, a counterweight is used on the back of the impeller to balance the mass. As A possible third measure is the arrangement of cavities on the rear side of the paddle wheel, wherein the location can be varied to optimize the unbalance compensation.

On the basis of the finding that the channel wheels, which are particularly suitable for conveying solid admixtures, continue to tend to blockage under unfavorable circumstances, the experts have thought of a solution to the problem. On the assumption that irregularities in the channel routing and the resulting uneven flow behavior lead to deposits and clogging, the aim was to ensure that the channel routing was as uniform as possible.

The essay "Pumps regulate water balance" (VDI News No. 25/23 June 1965) then proposed an impeller shape for sewage systems which was equipped with a smooth passage to avoid an acute risk of constipation. It was also essential for this impeller that the cross-section of the inlet was preserved over the entire length of the channel.

A similarly designed impeller was known from US Pat. No. 4,575,312, but the shape of the channel cross section changed over the course. However, the cross-sectional size should remain the same or increase slightly towards the outlet. Since the duct guide, which was similar in cross section to a pipe bend, had to be purchased with a very thick shovel, US Pat. No. 4,575,312 provided the option of making the shovel partially hollow. However, this does not yet eliminate the problem of wheel imbalance, which cannot be completely compensated for over an entire speed range. Here, the relatively large mass is particularly important, even with a partially hollowed-out shovel. Moreover, such an impeller requires increased manufacturing effort. The invention has for its object to provide a paddle wheel of the type mentioned, which has a balanced design with respect to the mechanical unbalance and hydrodynamic buoyancy and the cavitation existing in the inlet area of the paddle wheel for a trouble-free operation harmless minimum reduced.

The object is achieved according to the invention in that the blade angle measured on the skeleton line of the blade is 0 degrees or smaller from the entrance to at least 90 degrees of the angle of rotation, while the blade angle at the outlet is positive.

This solution is based on the following consideration:

In practice, it can be assumed that the first steam bubbles form on the blade when the static pressure of the flow drops to the steam pressure. The pressure difference generated by the blade is superimposed on the mean pressure of the inflow. The minimum pressure in the system, which inevitably forms in the area of the blade start, depends on the level of the average relative speed and, above all, on the average change in swirl. The mean change in swirl is in turn determined by the blade angle. A blade angle that is constant or decreases along the flow path, as is implemented in the invention, results in a small mean swirl change and thus a less deeply lowered mean pressure. The shape of the blade according to the invention thus prevents premature, intensive bubble formation. The smoothness of the centrifugal pump which is negatively influenced when the bubbles swim away and implode (cavitation) is thus avoided. The subclaims name advantageous embodiments of the invention.

The invention is explained in more detail using an exemplary embodiment. The drawing shows in

Fig. 1 shows an axial section through an impeller designed according to the invention and in

2 shows a radial section through the impeller of FIG. 1st

The paddle wheel produced by a casting process forms a channel (4) between a front cover plate (1), a rear cover plate (2) and a blade (3), the cross section of which decreases from the inlet (5) of the paddle wheel to the outlet (6).

The blade (3) equipped with a suction side (7) and a pressure side (8) has a flattened blade head (9). In contrast to the conventional blade head, which is provided with an rounded radius of half the blade thickness, a stagnation point flow results on a blade head with a very large rounded radius, which has a repellent effect on solids contained in the flow medium. The flattening, which in the limit case has an infinitely large rounding radius, prevents the attachment of long-fiber components.

The paddle wheel is designed so that the suction side of the paddle forms a semicircle concentrically to the axis of rotation of the paddle wheel for the first 180 degrees of the angle of rotation. Following the condition of the invention, the blade angle β measured from the blade head (9), the entry (5) into the impeller, is up to 180 ° of the angle of rotation less than 0 °, measured on the skeleton line (10) of the blade (3). while it is positive at the outlet (6), that is in the area of the blade end (11).

On the first 180 ° of the angle of rotation, the suction side (7) of the blade (3) forms a semicircle with the radius r, which is arranged concentrically to the axis of rotation of the impeller.

The blade (3) has a continuously decreasing thickness towards the outlet. It therefore has a mass distribution that is favorable for the imbalance behavior of the impeller. This advantage can be determined for the impeller as a whole, since it does not have large accumulations of material, particularly in the outer circumferential area.

The suction side (7) and the pressure side (8) of the blade (3), seen in the meridian view, run axially parallel over their entire extent, with a rounding into the cover disks (1) and (2). The radius of such a rounding corresponds here to approximately one third of the width of the channel (4) at the outlet (6). It can be up to half the channel width at the outlet (6) of the paddle wheel.

The paddle wheel according to the invention has a comparatively uncomplicated shape. It is therefore not only easy to pour, it can also be produced in sheet metal construction, which above all brings additional advantages with regard to the unbalance behavior.

Claims

1. paddle wheel for centrifugal pumps for conveying liquids mixed with solid admixtures, in particular for conveying dirty water with long-fiber components, a channel being formed between the front and rear cover disks of the paddle wheel and the blade, the strength of which changes over its extent, characterized in that the temperature measured on the skeleton line (10) of the blade (3) blade angle (ß) to at least 90 degrees of the rotation angle of 0 degrees or less from the egg ^'nlauf (5), while the blade angle (ß) at the outlet (6 ) is positive.

2. Paddle wheel according to claim 1, characterized in that the pressure side (8) and the suction side (7) of the blade (3), with the exception of possible transition areas to the cover plates (1, 2), seen in the meridian view, on their entire extent are axially parallel.

3. Bucket wheel according to claims 1 and 2, characterized in that the pressure side (8) and / or the suction side (7) of the blade (3) with a curve in the cover disks (1, 2) pass, the radius of which is about a third corresponds to the width of the channel (4) at the outlet (6) of the paddle wheel.

4. Paddle wheel according to claim 1, characterized in that the suction side (7) of the blade (3) forms a semicircle arranged concentrically to the axis of rotation of the paddle wheel on the first 180 degrees of the angle of rotation.

5. Bucket wheel according to claim 1, characterized in that the transition between the suction side (7) and the pressure side (8) of the blade (3) forming the blade head has a radius of curvature which is substantially greater than half the blade thickness.

6. Bucket wheel according to claim 1, characterized in that the blade head (9) forms a flat surface.

7. Paddle wheel according to claim 1, characterized in that the paddle wheel consists of sheet metal, the blade consisting of two welded together, each forming the suction and the pressure side of the blade.