The present invention relates to a centrifugal pump, which has a housing holding one or more impellers. The impellers may be of axial or semiaxial, closed or open design. An intake channel is arranged in front of a first impeller, and a plurality of grooves distributed around the circumference are provided in the wall face of the intake channel.
In centrifugal pumps which have a high specific velocity, a significant locally limited increase in the respective net positive suction head (NPSH) curve often occurs in the delivery range of 65-80% of the design volume flow. Meanwhile, depending on the pump design, the respective curve of the Q-H characteristic line may additionally have an instability which is referred to in general as a break or discontinuity in the characteristic line or as a saddle.
Such characteristic line shapes are due to the formation of the so-called partial load vortex, which occurs when the volume flow is reduced in the outside range of an impeller intake. A partial load vortex has a significant influence on the oncoming flow to the impeller under which the impeller is subjected to blocking of the meridional flow cross section and experiences a high velocity component in the direction of rotation of the impeller (spiral co-rotation).
U.S. Pat. No. 4,239,453 (=DE 25 58 840) describes an approach for avoiding the disadvantages of a partial load vortex, in which a diffusor is arranged in front of an impeller intake. Using this approach, the direction of action of a partial load vortex is reduced before it can reach the components situated in front of the impeller intake and can cause their destruction.
Other measures for influencing a partial load vortex are described in U.S. Pat. No. 6,290,458 (=EP 1,069,315), particularly in the description of the prior art. The measures “casing treatment, separator or active control” either require additional units in the machine periphery (active control), or reduce the efficiency even at the optimum point of the machine (casing treatment), or are associated with increased structural complexity (separator). This publication itself proposes the use of a plurality of grooves, which are generally referred to as J-grooves in accordance with the published article “An Improvement of Performance-Curve Instability in a Mixed-Flow Pump by J-Grooves,” May 29-Jun. 1, 2001, New Orleans, La., FEDSM 2001-18077, Proceedings of 2001 ASME Fluids Engineering Division Summer Meeting (FEDSM '01), because of their curved J shape.
J-grooves are shallow grooves but in another embodiment they may also have a spatial curvature and are provided in the pump housing in the direction of flow upstream from and above the impeller blades which are designed to be open at the impeller intake. The deciding factor for the functionality of the grooves is that they must partially cover the outside diameter of the impeller. In the area of the impeller cover, the impeller must be designed to be open to obtain a connection between a fluid zone provided with a higher pressure in the area of the open impeller blades and the beginnings of the J-grooves provided above that. As a result of this design measure, a fluid-carrying connection to the oncoming flow zone situated upstream is created via the J-grooves. Due to the J-grooves arranged in the main direction of flow, the open impeller wheel blades permanently deliver a partial stream of fluid already pumped upstream from the impeller back into the area of the oncoming flow to the impeller. These J-grooves have the disadvantage that their return flow is always active over the entire operating range of the pump. Consequently, the peak efficiency of a pump equipped with J-grooves declines.
Another disadvantage is the interaction between the free impeller blade tips and the opposing groove parts of the J-grooves fixedly positioned on the housing, which leads to increased noise and vibration phenomena. The passage on page 2 of the aforementioned literature citation in conjunction with
The object of the present invention is to provide a simple possibility for improving both the NPSH performance and the partial load performance in centrifugal pumps which have a high specific velocity with impellers of an axial, semiaxial, open or closed design.
Another object of the invention is to provide a simple procedure for subsequently upgrading centrifugal pumps already in use without adversely affecting the operating performance in normal operation of the centrifugal pump.
These and other objects have been achieved in accordance with the present invention by providing a centrifugal pump having a housing containing at least one impeller having an axial or semiaxial, open or closed design and an intake channel positioned in front of the first impeller, a plurality of grooves provided in the wall surface of said intake channel, said grooves being distributed around the channel circumference and extending in the direction of flow, wherein a closed annular wall surface is provided in the housing wall of the intake channel between an impeller intake point of the first impeller and the proximate ends of the grooves, whereby the grooves are operatively connected exclusively with the space in the intake channel.
In accordance with the invention, grooves are provided in the housing wall of the intake channel and a closed annular wall surface is constructed between an impeller intake point of the first impeller and the nearest ends of the grooves, whereby the grooves are in operative connection exclusively to the intake channel. A first impeller is designed as an intake impeller. The closed annular wall surface constructed in the housing wall of the intake channel is situated between the ends of the grooves located upstream from the impeller intake point in the direction of oncoming flow and the impeller intake point of the first impeller. Such an intake impeller may have a specific high velocity nq≧70 min−1.
Due to this approach, the optimum operating point of a centrifugal pump remains unchanged and is not subject to any negative influence. The same is true for the other operating points. A partial load vortex, which develops in partial load operation and is also known as a pre-rotation vortex, however, is diminished with the help of the elongated recesses. The elongated grooves result in an energy transfer by friction from the area of the partial load vortex near the wall to multiple small vortices which develop in the grooves. Due to this energy transfer which occurs only in partial load operation, the circumferential component and thus the intensity of the resulting partial load vortex are drastically reduced and consequently the partial load behavior of the centrifugal pump is improved. Since the grooves manifest their energy-dissipating effect only in conjunction with a partial load vortex separating from the impeller, the oncoming flow to the impeller remains unaffected for the other operating points. There is no negative effect on normal oncoming flow to the impeller and thus there is also no negative effect on the efficiency curve. In contrast with the embodiments known in the past in the form of J-grooves, there is no mixing of the flow conveyed back from the impeller via the grooves with a main flow approaching the impeller.
Due to the deliberate avoidance of any input of high-energy medium into the grooves, any disturbance in the impeller oncoming flow is prevented in normal operation. Only when a disturbance in the form of the developing partial load vortex is induced by the impeller does an interaction begin so to speak between the grooves and the partial load vortex. This interaction leads to a self-regulating effect. In doing so the energy of the partial load vortex is dissipated in the grooves due to the formation of a plurality of small groove vortices, which result in a significant weakening of the partial load vortex. This function can be achieved only when the groove ends in the intake channel upstream from the impeller are reliably cut off from a supply of fluid already being conveyed, and this is accomplished by a closed wall face in the form of an annular or ring-shaped closed wall face.
In accordance with one embodiment of this invention, the grooves are arranged between rib-like projections on the housing wall of the intake channel. In such applications in which machining of an intake channel is impossible, or is possible only with great difficulty, an annular insert which contains the grooves or ribs may also be inserted into an existing intake channel of a pump. Use of such an insert permits simple machining of the grooves, and the insert can be installed without difficulty in the intake channels of newly manufactured pumps or even in pumps that have already been delivered.
Due to the low groove depth, which amounts to only a few millimeters, the grooves being provided only in the area of the borderline areas near the wall, an insert constructed in this way is capable of achieving an improvement, even subsequently, in the partial load performance of centrifugal pumps already shipped or installed in systems. To do so, it may perhaps be necessary to slightly increase the inside diameter of the intake channel in which the insert is received to be able to accommodate a corresponding diameter size of a grooved insert. A type of modular system is used here to permit use of such an insert by virtue of a skilled gradation in diameters in a plurality of types of pumps.
In accordance with another embodiment of the invention, the closed ring-shaped wall surface has an axial length which depends on the intensity of the partial load vortex. The length of the axial surface is at least large enough to reliably suppress any interference between the impeller blades at the impeller intake and the groove ends in front of them. This prevents the development of interfering noises and vibrations in an extremely simple manner. On the other hand, the length of the axial ring face is selected to be not larger than would correspond to the extent of the gradually developing partial load vortex, which is harmless at this point. Only when the developing partial load vortex develops a greater intensity is it possible for its so-called separation line to become detached from the impeller and jump over the closed ring-shaped wall surface. As a result of this, the partial load vortex separates completely from the impeller. It is thereby directed against the oncoming flow and rotates about the machine axis in the direction of rotation of the impeller. Due to the tangential flow over the recesses and the development of multiple small vortices in the recesses, most of the energy in the partial load vortex is dissipated, and the effect of the partial load vortex is drastically reduced.
In accordance with other embodiments of this invention, the closed ring-shaped wall surface has an axial length, which depends on the intensity of the partial load vortex. This axial length is on the order of magnitude of 0.005-0.02 times the diameter of the impeller intake. Furthermore, the lengths of the grooves or ribs are of an order of magnitude of 0.03-0.5 times the diameter of the impeller intake. The depths of the grooves or the heights of the ribs in this case are on the order of magnitude of 0.005-0.02 times the diameter of the impeller intake.
Furthermore, according to another embodiment of this invention, the product of the width b of the groove multiplied by the number n of grooves corresponds to a ratio of:
n·b=0.45−0.65·π·D
where D is the impeller intake diameter.
The invention will be described in further detail hereinafter with reference to illustrative preferred embodiments shown in the accompanying drawing figures, in which:
Another NPSH curve is shown in the diagram by a solid line, corresponding to a centrifugal pump with the same operating points, but in which grooves arranged according to this invention have additionally been provided in the intake channel of this pump. The shape of the curve determined for a centrifugal pump designed in such a way illustrates convincingly the essentially more favorable NPSH properties. The local rise in NPSH typical of partial load operation still occurs, but is at a much lower level in comparison with a pump without grooves. A pump improved in this way has a greatly expanded operating range.
This return flow region R has a direction of flow along the housing wall 6, as indicated by arrows, running in the opposite direction from the oncoming flow LA to the impeller. A so-called separation line SL is drawn at the location, at which the return flow region R reverses its direction of flow. This is to a certain extent a borderline which runs around the circumference of the housing wall 6. In the area of this line SL the energy of the impeller oncoming flow LA is greater than the energy of the return flow region R and therefore causes its flow reversal. In pumps with open axial or semiaxial impellers, such a return flow region R exists over the entire operating range and also occurs in the range of the optimum efficiency point.
According to
With reference to the example of an open impeller 2,
The absolute velocity cx is obtained at the location X from the circumferential velocity ux of a blade 5 near the wall and from the return flow relative velocity wx of the partial load vortex PLV separating from the impeller. This absolute velocity is characterized by a high circumferential component cux. The arrows with the velocity information c4 symbolize undisturbed oncoming flow to the impeller within the intake channel 9, with the blades 5 shown here in cross section with a profile.
In an analogous manner, a velocity triangle is drawn in at Y. This triangle prevails at the location Y in the area of the point of intake of the partial load vortex PLV into the impeller 2. Since the point of intake Y is on a smaller diameter, the circumferential velocity uy is correspondingly lower. And due to the fact that the energy of the partial load vortex PLV is weakened, its absolute velocity cy is also correspondingly lower, which yields a relative velocity wy which in this example is offset by 90° to a certain extent in relation to the relative velocity wx of an emerging current stream of the partial load vortex PLV.
In particular, the causative factor in the weakening of the partial load vortex PLV is the circumferential component cux which leads to a tangential flow over the axially parallel grooves 10, as shown in
In addition, various separation lines SL1, SL2 and SL3 are shown as dotted lines in
Only when the partial load vortex PLV develops does the separation line SL2 jump over the closed ring-shaped wall surface 12 and reach the wall surface 6 provided with the grooves 10. The separation line SL3 forms the border of the axial extent of the partial load vortex PLV which then develops.
Thus when the partial load vortex PLV achieves a high energy accordingly, it jumps over the ring-shaped closed wall surface 12 situated in front of the impeller and flows back into the intake channel 9. Due to the absolute velocity component cux running mainly in the circumferential direction, the partial load vortex PLV that develops in the intake channel 9 flows primarily tangentially over the grooves 10. In doing so, its swirl energy is dissipated in numerous small vortices which develop within the grooves 10. In the case of the partial load vortex PLV, this leads to a withdrawal of velocity energy so that the partial load vortex PLV becomes weaker on the whole and is greatly reduced in axial and radial extent. It therefore extends only up to the separation line SL3 at which there is a reversal of flow of the partial load vortex PLV. Due to the simultaneous reduction in the spiral component of this partial load vortex, the stability of the characteristic line of the centrifugal pump at partial load is also improved significantly in addition to the reduction in the NPSH slope. The function of the grooves 10 is thus based on energy transfer by friction from a large pre-rotation vortex in the form of the partial load vortex PLV to multiple small vortices which develop in the grooves 10.
In
The paired diagrams in
However, with the same pump a characteristic curve represented by a solid line develops when grooves 10 are provided accordingly in front of the intake impeller in the wall surface 6 of the intake channel 9. The matching curve shapes in the normal operating range at the right of QPLV prove convincingly the efficacy of the grooves in normal operation.
The respective NPSH curves are shown in
It is thus the accomplishment of the inventors to have recognized that profiling in the form of grooves provided at a distance in front of the impeller in the intake opening/intake opening in the housing wall has a retarding effect only on a partial load vortex separating from the impeller in partial load operation. An additional surprising effect has been an unchanged noise characteristic of the centrifugal pump. Pumps that have already been shipped and installed into systems may thus be retrofitted with no problem because their noise level remains at the previous level.
The foregoing description and examples have been set forth merely to illustrate the invention and are not intended to be limiting. Since modifications of the described embodiments incorporating the spirit and substance of the invention may occur to persons skilled in the art, the invention should be construed broadly to include all variations within the scope of the appended claims and equivalents thereof.
Number | Date | Country | Kind |
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102 58 922.4 | Dec 2002 | DE | national |
This application is a continuation of international patent application no. PCT/EP2003/011721, filed Oct. 23, 2003 designating the United States of America, and published in German as WO 2004/055381 on Jul. 1, 2004, the entire disclosure of which is incorporated herein by reference. Priority is claimed based on Federal Republic of Germany patent application no. DE 102 58 922.4, filed Dec. 17, 2002.
Number | Date | Country | |
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Parent | PCT/EP03/11721 | Oct 2003 | US |
Child | 11154590 | Jun 2005 | US |