NL1007763C2 - Transport system for a two-phase flow. - Google Patents

Description

Transport system for a two-phase flow

The invention relates to the transport of a two-phase flow in a transport pipe. Such a two-phase flow occurs, for example, in the hydraulic transport of dredging material.

The flow is formed by water with a granular material, such as sand, gravel, boulders and the like. A further example of a two-phase flow concerns the pneumatic transport of solids.

Transport by two-phase flows is widely used in industry 10 for economically moving solids over greater distances. The resistance generated by the flow is in equilibrium with the pressure difference over the pipe, which pressure difference can be generated by means of a rotary pump or plunger pump. In this respect, the nature and size of the parts of the fabric to be transported are important.

Relatively small dust parts lead to a flow behavior that closely resembles that of the homogeneous liquid. The settling speed of smaller particles is in fact so slow that they are kept floating by the vortices in the water.

Even with larger particles, for example sand particles up to 150 µm in mixtures with a not too high concentration of solids, the flow still appears to approximate that of a homogeneous flow, while the pipe resistances also almost correspond.

However, the image is different with flow in which the particles have larger dimensions. Due to the higher fall speed of such particles, more frequent and more intensive contacts are made with the pipe wall, as a result of which measurable speed differences between the liquid and the particles occur. The frictional resistance of such particles with the pipe wall is such that speed differences between the liquid and the particles are created. A bed of settled particles forms on the bottom of the pipe and slowly slides.

As a result, the average speed of the suspension, that is to say the liquid with the suspended particles flowing over the bed, is greater than the average speed of the bed. The faster flowing liquid (with floating particles) has a dragging effect on the underlying bed material. The bed 1007768 2 can herein be presented in a layered state, whereby transition zones are created between the successive layers which have increasingly slower speeds. There is interaction between the liquid flow and the successive layers.

As the size of the transported particles increases, the difference in velocity between the liquid flow on the one hand and the layers of particles in the bed on the other becomes larger. The average velocity of the mixture of liquid and particulate matter therefore increases with increasing particle size. However, this phenomenon also influences the dragging effect on the bed exerted by the mixture.

In addition, the bed also moves under the influence of the pressure difference across the pipeline, generated by, for example, a pump. This pressure difference, together with the interaction between flow and bed, makes the bed move.

In summary, the hydraulic transport of soil, as is customary in the dredging and mining industry (transport of coarse sand, gravel, stones and mixtures thereof; transport of minerals such as ores and coal), results in a bed formation described above. higher pipe resistance, which in turn leads to higher required transport energy.

Attempts have been made to reduce this higher pipe resistance by making the particles to be transported smaller (crushing, breaking), or by adding polymers to the mixture. However, both approaches have drawbacks. Crushing or crushing is not always desirable, and is an additional treatment that increases costs. Adding polymers is also expensive.

The object of the invention is therefore to provide a transport system for transporting a mixture of liquid and solid particles to be transported, which yields a better efficiency. This is achieved by means of a two-phase flow conveying system, such as water with sand, gravel and the like, comprising at least one flow conduit with means for generating a flow, the internal surface of the conveyance line carrying guiding means for influencing the flow, characterized in that a rotary pump is included in the transport conduit, and the guide means are located directly in front of the inlet of the pump to provide a pre-rotation to the flow.

The guiding means on the internal surface of the transport conduit 5 offer the possibility of locally effecting an impulse transfer of the 1007763 3 liquid flow to the bed. The ideal situation would then produce a homogeneous mixture with a certain average speed. In reality, the average velocity of such a mixture will be higher than that of the original bed and lower than that of the original flow.

The advantages of such an influence on the transport by the transport pipe are many. As an example is mentioned the improvement obtained thereby in the efficiency of the rotary pump. The impeller blades of such a pump have an inflow angle that best suits the design flow rate of a homogeneous liquid to be pumped. As a result of low impact losses, the inflow losses are the least and the hydraulic efficiency maximum. This inflow angle can normally only be achieved with a homogeneous flow. The flow components in a non-homogeneous flow, where both the liquid and the bed deviate from the ideal flow associated with the design flow rate, however, have different inflow angles which result in a lower efficiency of the pump.

An important further drawback resulting from such a deviating approach angle is the large impeller wear.

A conveying line with internal guide means for influencing the flow is known per se from US-A-1451272. These guide means 20 must prevent sand or clay in the flow from settling in the transport pipe, and thereby hinder the transport.

However, an arrangement in which the guiding means are directly in front of a rotary pump is not known.

The guide means are preferably located opposite the sliding bed of solid particles, which usually means in the highest part of the transport pipe. However, this does not always have to be the case. In non-horizontal parts of the transport pipe, the guide means can also be located at a location other than the highest part. In addition, the bed of mineral parts can be in many other positions in the case of bends and taps in the pipe.

The material in the bed does not come into contact with the guiding means, but only the liquid or suspension flow. This liquid flow is therefore imparted a pulse in the direction of rotation by the guiding means. The liquid flow then transfers this rotational impulse to the bed, which thereby acquires a direction of movement and speed such that the inflow of the impeller of a rotary pump can take place in a more uniform manner and at a more suitable inflow angle, with less intensive collisions.

The bed movement and speed thus influenced lead to a higher pumping efficiency, and to a less strong and more distributed impeller wear. These properties also have a favorable effect on the wear of the pump housing. A further advantage is that with a properly designed guide, the cavitation sensitivity of the pump also decreases, despite the flow resistance caused by the guide.

The guide means can be plate-shaped and extend essentially radially from the inner surface. The guide means can extend radially to a distance from the center line of the conveying line. This distance depends on the (average) amount of bed transport per unit time and the extent to which impulse transfer must take place to achieve the desired effect, while minimizing the surface of the guide is desired in order to keep the inevitable additional pressure drop as low as possible.

The guiding means can form at least one substantially helical plate with a pitch angle which may or may not increase in the direction of flow. Furthermore, the guide means can have an axial plate section which is straight in transport direction and which connects to a helical plate section. The guide means are preferably included in a pipe section which has a circumferentially adjustable orientation. In that case, the rotational position of the guide means can be adjusted such, for instance relative to a pump, that a maximum effect is ensured.

In order to prevent the rotational effect of the ring flow from being reduced by the straight core flow, the radially inner edge of the plate-shaped guide means can be provided with a longitudinally extending end plate. The end plate can be curved according to the curvature of the transport pipe, and can be designed as a concentric pipe piece.

The invention will be explained in more detail below with reference to an illustrative embodiment shown in the figures.

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Figure 1 shows a perspective view, partly in section, of a transport system with a impeller pump according to the invention.

Figure 2 shows a detail of the transport pipe in cross-section and in top view.

Figure 3 shows a cross section III-III of figure 2.

Figure 4 shows a second embodiment of the transport pipe in top view, partly in section.

Figure 5 shows section V-V of figure 4.

The transport system according to the invention shown in figure 1 comprises a transport pipe indicated in its entirety by 1, a rotary pump 2, more in particular a centrifugal pump, and a discharge pipe 3. The transport pipe 1 is connected via a flange 4 to the cochlea 5 of the centrifugal pump 2.

As can be seen in the cut-away part of the transport conduit 1, a guide means 15, indicated in its entirety by 7, is attached to the internal wall 6 thereof. As can also be seen in figure 2, this guide means comprises a guide plate 8, which has a straight part 9 running in axial and radial direction of the transport pipe 1, as well as a helical plate part 8 adjoining it. The flow through the transport system, as indicated by the arrows in figure 1, the straight plate part 9 first strikes, and then a rotational movement is communicated to the flow by the helical plate part 8.

On the radially innermost side of the guide member 8, as shown in figures 2 and 3, a curved plate piece 11 is welded, which has chamfered front and rear edges 12 and 13, respectively.

The transport system according to figure 1 is used for a two-phase flow, ie a liquid with solid parts therein. With such a two-phase flow, a relatively slow-moving bed 14 of solid larger parts forms on the bottom of the transport pipe 1, above which liquid with solid smaller parts floating therein flows. At the location of the guide member 8, this liquid is imparted a speed component in the direction of rotation around the center line of the transport line 1.

The fluid moving in that direction collides with the bed 14, causing impulse transfer. As a result, the bed 14 is given an additional 1007763 6 speed component in the direction of rotation, and also moves / rotates in that direction as shown by the bed portion 15 in Figure 3. The helical portion 9 has an end edge 21, which is preferably parallel is on the twisted bed 15.

A further effect of the impulse transfer between liquid and bed material is that a more uniform or homogeneous mixture is obtained. Both these effects, i.e. the more homogeneous mixture and the adjustment in the direction of movement of the bed material, lead to a favorable inflow of the impeller (not shown) of the rotary pump 2.

By rotating the transport pipe 1, or at least the part thereof adjacent to the rotary pump 2, which is possible by means of flanges 4 and 19, the position of the guide means 7 can be optimally adjusted relative to the rotary pump 2. As a result of the pipe run, the bed 14 can already approach the guide means with a pre-rotation.

The same effect can be obtained with at least two consecutive and rotated positions relative to each other, or positioned in line shown in figures 4 and 5. These blades 16 are accommodated on a pivot plate 17, which is mounted on the exterior of the transport line 1 is operable by means of cams 18 for adjusting the inflow angle 20 of the blades 16. An advantage of the embodiment shown in Figure 4 is the possibility that the blades 16 overlap in radial direction and the ultimate deflection angle is adjustable.

Such blades also impart a speed component in the direction of rotation to the liquid flow, which in turn leads to impulse transfer to the bed material 14. At least one of the blades 16 can be designed with a fixed and an adjustable wing part 22 and 23, respectively, in order to increase the size and direction of the influence deflection angle.

Although the guiding means according to the invention have been described above in combination with a rotary pump, other applications are also conceivable. Such another application concerns the placement of guide means in front of and near a bend, in order to reduce the wear there.

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Another application is possible by arranging the guiding means according to the invention at more or less regular distances in straight transport pipes, in order to make the two-phase transport more efficient, that is to say that the transport produces an average lower pipe resistance, and the wear is better over 5 the pipe wall is distributed.

Finally, combinations of the above installations can also be used.

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Claims (11)

Transport system for a two-phase flow, such as water with sand, gravel and the like, comprising at least one transport line (1) with means (2) for generating a flow, which transport line (1) on its internal surface (6 ) carries guide means (7, 16) for influencing the flow, characterized in that a rotary pump (2) is included in the conveying line (1), and the guide means (7, 16) are located directly in front of the inlet of the pump to provide a pre-rotation to the flow. 10 Transport system as claimed in claim 1, wherein the guide means (7, 16. are located in the part of the transport pipe (1) which is situated opposite a bed of solid parts formed in the transport pipe. Conveyor system according to claim 2, wherein the guide means are at least partly inclined with respect to the conveyor line (1). Transport system according to claim 3, wherein the guide means (7) are plate-shaped and extend substantially radially from the internal surface (1). Conveyor system according to claim 4, wherein the guide means (7) extend radially to a distance from the center line of the conveyor line (1). Transport system according to claim 4 or 5, wherein the guide means (7) comprise an essentially helical plate (10). 1 2 1007763 Conveyor system according to claim 6, wherein the helical plate has a pitch angle increasing in flow direction. 2. Transport system according to claim 6 or 7, wherein the guide means (7) have an axial plate section (9) straight in the conveying direction, which connects to a helical plate section (18). Conveyor system according to any one of the preceding claims, wherein the guide means (7) are included in a pipe section which has a circumferentially adjustable orientation. Transport system as claimed in any of the claims 4-8, wherein a longitudinally extending stiffening edge or end plate (11) is provided on the radially inner edge of the plate-shaped guide means (8). Conveyor system according to claim 10, wherein the end plate (11) is curved according to the curvature of the conveyor pipe (1). Transport system according to claim 10 or 11, wherein the end plate is a pipe piece (11) concentric with respect to the transport pipe (1). Transport system as claimed in any of the foregoing claims, wherein a plurality of guide means are provided, which are regularly spaced in a substantially straight transport line. 1007763