EP0520321A1 - Centrifuge - Google Patents

Abstract

Centrifuge for the separation of a suspension into a solid phase and at least one liquid phase, in particular a decanter centrifuge with a downstream separator, solid bowl screw centrifuge or the like with a screw (2) rotating around its shell (1) with a differential speed, the spiral (4) of which follows the course of the Inner surface of the jacket are adapted with a small distance and between which the worm hub (3) and the jacket (1) the separation space (6) is formed, into which the suspension is fed, which centrifuge to improve the separation result according to quality and quantity and thus savings Time and material is designed such that over at least a portion of the longitudinal extent of the worm hub (3) over its circumference, arranged in the manner of threads or bristles elongated structures (7, 8) are provided, which attack larger solid particles transversely to them Longitudinal extension are compliant and at the latest below he effect of centrifugal force in the operation of the centrifuge from the screw hub (3) extending approximately radially into the separation space (6). <IMAGE>

Description

The invention relates to a centrifuge for the separation of a suspension into a solid phase and at least one liquid phase, in particular a decanter centrifuge with a downstream separator, solid bowl screw centrifuge or the like with a screw rotating around its casing with a differential speed, the spiral of which adjoins the course of the inner casing surface Seen in particular with regard to the discharge of solids, at least over a partial longitudinal region they are conically narrowed, are adapted at a short distance and between which the screw hub and the casing the separation space is formed, into which the suspension is fed, in particular through a cavity in the screw hub.

Centrifuges for the separation of a liquid containing solids, a so-called suspension, into a solid phase and one or more liquid phases are known. The suspension is accelerated inside the rotating centrifuge jacket, so that the solids, which are heavier than the clear liquid, settle towards the inside surface of the jacket. The solid is usually composed of a large number of particles of different sizes and / or weights. While the sedimentation of the coarse and heavy particles hardly poses any problems, this becomes more and more difficult or lengthy in the direction of the small, light particles. In order to achieve a desirably good separation result, there is of course an endeavor to also separate finer to finest solid particles in order to make the clear liquid to be discharged cleaner and to increase the amount of solid discharged, to briefly optimize the separation result.

The invention has for its object to improve centrifuges of the type mentioned in terms of their separation result in terms of quality and quantity, and in particular with a view to saving time and material.

According to the invention, this object is achieved in that elongated structures arranged in the manner of threads or bristles are provided over at least a portion of the longitudinal extent of the worm hub, which are flexible under attack of larger solid particles transversely to their longitudinal extent and which are at the latest under the action of centrifugal force in the operation of the centrifuge from the screw hub extending approximately radially into the separation space.

In the following, the problem mentioned at the outset or the endeavor for the best possible separation, which exists in all centrifuge ideas for the separation tasks mentioned here and is accessible to the extent that the above solution is available, is explained on the basis of the particularly preferred exemplary embodiment of a solid-bowl screw centrifuge, but without the task and solution to limit this centrifuge operation. In principle, a centrifuge without a transport device for the solid matter (screw) is also addressed. It also does not matter whether the separation into one solid part and one clear liquid part or several of them takes place.

By arranging the elongated structures in the manner of threads or bristles striving from the worm hub and attached to them more or less directly, better solid separation of even the smallest particles is achieved in that they collect on the surfaces of these structures and thus under centrifugal force along the threads can be separated from the liquid better and / or faster and can be fed to the possibly already sedimented solid on the inner surface of the centrifuge. The result is a further separation than was previously possible. Depending on the solids, this "gathering or catching effect" for fine and very fine solid particles can also be influenced by selecting suitable materials for the elongated structures. Furthermore, the cross-sectional shape or a change in shape seen in the longitudinal direction of the structures can be shaped differently and possibly adapted to the separation task, the simplest form being a round, constant cross-section is to be selected. However, band-shaped cross sections and / or tapering in the longitudinal direction can also be considered.

Especially in the inlet area of the suspension or in its vicinity, the elongated structures help to accelerate the liquid in the direction of circulation, which also serves a better separation result, because the flow turbulence in the inlet area and its proximity without the structures impair the settling of the solid.

Against this background, it is clear that the elongated structures can in principle be designed to be resilient in such a way that they are stiff to the extent that they increase their entrainment properties in the sense of the rotational acceleration of the suspension, so that they assume their radial stripping direction from the worm hub on their own, that is to say also without centrifugal force. The structures would then have the character of elastic bristles. Above all, however, in the area outside the suspension inlet, in which the clarification of finer solid particles is in the foreground, the elongated structures are designed in a particularly preferred embodiment in the manner of threads without resilient elastic properties, so that they only develop under the centrifugal force that occurs during operation of the centrifuge extend radially into the separation space and thus into the pond. Between these two designs - bristles and thread - there is every transition area of possible elongated structures to be used here, nor should threads and bristles be understood in such a way that a bristle-shaped character of the structures must necessarily be present in the inlet area and a thread-like character in the clarification area located outside the inlet . A bristle-like, spring-elastic design of the elongated structures can very well be provided throughout or a thread-like structure continuously. Different structures can preferably be used, for example in the inlet area with a bristle-like character and in the separating area outside the inlet with a thread-like character. Finally, in a further preferred embodiment, a change in the stiffness character, carried out continuously or in stages, from the slurry inlet is possible via the separation path. Furthermore, the structures do not have to extend over the entire longitudinal region of the worm hub, they can also include partial regions, for example at least in the vicinity between the suspension inlet region the solids discharge. These options will be used in particular in adaptation to the design of the centrifuge, in particular the counterflow principle and the direct current principle. Furthermore, the teaching according to the invention is independent of whether single-screw or multi-screw designs are provided.

In the case of a continuous helix, the liquid theoretically passes through the screw flight between the adjacent helixes and thus has a relatively long section to the clear liquid outlet, but due to the pressure drop which results in the axial direction from helix to helix, tends to rinse the helix, ie to flow between the outer edge of the screw helix and the adjacent inner wall of the shell. Thereby settled fine solid is whirled up again. In a particularly preferred embodiment of the invention, therefore, in this area, in particular in the clarification area facing away from the solids discharge in countercurrent centrifuges, in particular that between the suspension inlet and the clear liquid outlet, the screw spiral is interrupted, in such a way that the liquid can flow at least with a strong axial component, the spiral with regard to However, its task of solids transport is maintained so that it is not interrupted with regard to its axial discharge path. There is no gap in the longitudinal direction of the screw and thus seen in the solids conveying direction between the helical sections created by the interruption of the helix, which are offset with respect to one another in the longitudinal direction of the screw, the helixes can also overlap a little, so that the solids transport is only passed on in stages from one helical section to the next.

The threads, which in principle can consist of any material, here chosen in view of the prevailing centrifugal forces and impingement of solids, preferably made of plastic, have a flexibility transversely to their longitudinal direction, which causes the elongated structures to deflect towards coarser solid particles, so that blockages accordingly be avoided. This applies both to the resilient, bristle-like designs and to those that do not have their own alignment stability, that is to say that they align themselves under the influence of centrifugal force and are therefore particularly suitable under which To react flexibly to attack of larger solid particles and thus to avoid blockages. The attachment of the elongated structures to the worm hub is in principle arbitrary and can also be directed to holders which are arranged so as to be resistant to rotation and centrifugal force relative to the worm hub. In particular in the case of thread-like structures, a loop shape is provided in such a way that the central region is fixed to the worm hub or the holder and the two striving partial regions protrude into the separation space as two elongate structures.

• Figur 1
  ein Ausführungsbeispiel einer Schnecke mit in einem Teilbereich angeordneten länglichen Gebilden in perspektivischer Darstellung;
• Figur 2
  einen schematischen Längsschnitt durch eine Zentrifuge in hinsichtlich der Rotationsachse hälftiger Darstellung zur Erläuterung des Teichdruckgefälles innerhalb des Trennraumes;
• Figur 3
  einen schematischen Längsschnitt durch eine Vollmantel-Schneckenzentrifuge nach dem Gegenstromprinzip in Darstellung entsprechend Figur 2;
• Figur 4
  einen schematischen Längsschnitt durch eine Vollmantel-Schneckenzentrifuge nach dem Gleichstromprinzip in Darstellung entsprechend Figur 2.

These and other preferred embodiments of the invention result from the subclaims, in particular with reference to the exemplary embodiments shown in the drawing, the following description of which explains the invention in more detail. Show it

• Figure 1
  an embodiment of a screw with elongated structures arranged in a partial area in a perspective view;
• Figure 2
  a schematic longitudinal section through a centrifuge in half with respect to the axis of rotation to explain the pond pressure gradient within the separation space;
• Figure 3
  a schematic longitudinal section through a solid bowl screw centrifuge according to the countercurrent principle in the representation corresponding to Figure 2;
• Figure 4
  3 shows a schematic longitudinal section through a solid-bowl screw centrifuge according to the direct current principle in a representation corresponding to FIG.

The figures show exemplary embodiments of solid-bowl screw centrifuges or their screws in a basically known design with a casing 1 and a screw 2, which is driven at a differential speed to the rapidly rotating casing 1, in accordance with the sense of pitch of the helix 4, which is from the outer circumference of the screw hub 3 is protruding, the plastic settling on the inner lateral surface is conveyed through the helix 4 to the solids discharge 13. As can be seen in particular in FIG. 2, in the separation space 6 formed between the helices 4, the worm hub 3 and the casing 1, the mirror of the suspension fed through the inlet opening 10 from an inlet cavity in the worm hub sets a slope, so that the radial thickness of the pond decreases from the suspension inlet 10 starting from the clear liquid outlet 14. Due to the resulting pressure difference between adjacent helical paths, a certain flow is established between the radial outer edge of the helix and the inner lateral surface, as a result of which solid matter deposited there can be partially whirled up again.

For this reason, in the exemplary embodiment according to FIG. 1, the helix of the screw 2 reproduced there is designed to be interrupted in the axial region between the suspension inlet openings 10 and the end region of the clear liquid outflow which is provided for the conically narrowing end associated with the discharge of solids in such a way that helical sections 5 result which are offset from one another in the axial direction, but seen in this direction do not release any gaps, so that the solid to be conveyed by the spiral sections is transported in a correspondingly stepped manner. The intermittent execution of the helix 4 in sections 5 in this axial screw region, however, creates an axial flow path for the liquid between the sections, so that the under-rinsing of the radially outer helix edges described with reference to FIG. 2 is omitted insofar as the pressure equalization takes place through axial flow.

In the exemplary embodiment according to FIG. 1, the screw region with an intermittent helical formation is also provided with a plurality of elongate structures 7 of thread-like character when viewed over the circumference of the screw hub. Since this is the clarification section of a countercurrent centrifuge outside the slurry inlet, the result is finer solid particles - the coarser particles settle in or near predominantly from the inlet area - so that here the thread-like structures primarily have to fulfill their task of collecting fine solids and therefore have to be fine, preferably becoming finer when viewed towards the clear liquid drain.

In the exemplary embodiments according to FIGS. 3 and 4, the elongated structures 7, 8 extend over the entire clarification area or end in the conically narrowing jacket area in front of the solids discharge 13. FIG. 3 shows the principle of a countercurrent centrifuge, i.e. the suspension is passed through an inlet pipe 11 into the longitudinal central region of the worm hub and is fed there via inlet openings 10 into the separation chamber 6, so that the solid, coarser nature settling in the inlet region is fed to the solids discharge 13 in a short way, while especially the Area between the inlet 10 and the clear liquid outlet 14 settling finer solid must cover the correspondingly longer transport route. In the countercurrent centrifuge according to FIG. 4, the suspension is fed in via the inlet pipe 12 and corresponding inlet openings 10 at the beginning of the entire conveying path of the screw 2, so that the solid settling in the inlet area has to cover a correspondingly long transport route. The clarified liquid is drained off in the longitudinal central region of the screw and fed to the clear liquid outlet 14. Both types are known and need no further explanation here.

In the respective suspension inlet area - inlet openings 10 - the supplied suspension must be accelerated in the circumferential direction, which was previously done in this area by the inner surface of the jacket. The elongated structures 8 now arranged in this inlet area according to FIGS. 3 and 4 serve primarily for acceleration and are therefore stiffer than outside this area. A bristle-shaped, i.e. Provide radially aligning structures under spring elasticity, while thread-like structures can be arranged in the remaining separation area, in particular in the vicinity of the clear liquid discharge. The entraining effect of the elongated structures in the suspension inlet area also has a particularly favorable effect in that the inner surface area otherwise causing acceleration of the entered suspension is protected in this area with regard to its abrasion.

Claims (10)

Centrifuge for the separation of a suspension into a solid phase and at least one liquid phase, in particular a decanter centrifuge with a downstream separator, solid bowl screw centrifuge or the like with a screw (2) rotating around its shell (1) with a differential speed, the helix (4) of which follows the course of the Inner surface of the jacket, which is conically constricted at least over an axial sub-area, in particular for the discharge of solids (13), is adapted at a short distance and between which the worm hub (3) and the jacket (1) the separation space (6) is formed, in which the Suspension - in particular through a cavity (10, 11; 10, 12) in the screw hub (3) - is fed,
characterized,
that over at least a portion of the longitudinal extent of the worm hub (3) distributed over its circumference, elongated structures (7, 8) are provided in the manner of threads or bristles, which are flexible transversely to their longitudinal extent under attack by larger solid particles and which can be found at the latest under Influence of centrifugal force during operation of the centrifuge from the worm hub (3) extends approximately radially into the separation space (6). Centrifuge according to claim 1,
characterized,
that the elongated structures in the manner of threads (7) assume their radial orientation only under the influence of centrifugal force around the hub circumference. Centrifuge according to claim 1,
characterized,
that the elongated structures in the manner of bristles (8) are resilient. Centrifuge according to claim 2 or 3,
characterized,
that the elongated structures consist of corresponding tensile plastic, in particular filament-like nylon. Centrifuge according to one of claims 1 to 4,
characterized,
that the helix (4) in the area of the elongated structures (7, 8) are interrupted and, seen in the longitudinal direction of the worm hub (3), there are staggered sections (5) which are gap-free or slightly overlap as regards the transport of solids in this longitudinal direction. Centrifuge according to one of claims 1 to 5,
characterized,
that the elongated structures (7, 8) in the longitudinal direction of the worm hub (3) are limited to the area between the suspension inlet (10) and the solids discharge (13), preferably ending at a distance from the latter. Centrifuge according to one of claims 1 to 6,
characterized,
that elongated structures of higher rigidity, in particular resilient in the manner of bristles (8), are arranged in the area of the suspension inlet (10). Centrifuge according to one of claims 1 to 7,
characterized,
that the elongated structures are increasingly finer or more flexible and / or thinner in the direction of the liquid phase flow. Centrifuge according to one of claims 1 to 8,
characterized,
that the elongated structures - in particular in the form of threads (7) - are loop-shaped, such that the central region of a loop is fixed to the worm hub (3) and the two adjoining half regions run out as elongated structures in the separation space (6). Centrifuge according to one of claims 1 to 9,
characterized,
that the elongated structures in the inlet area (10) of the suspension are designed as resilient bristles (8) and in the axially adjoining area or areas as slack threads (7).

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