EP0257270B1 - Continuously operating sugar centrifuge - Google Patents

Description

The invention relates to a continuously operating sugar centrifuge with a drivable about a central axis of rotation, truncated cone-shaped from the bottom to the discharge edge, with a sieve drum that extends from the bottom of the drum or the upper band of a bottom-side acceleration pot for the purpose of filling material into the area of Throwing edge extends, the drum and / or the screen covering viewed in the direction of the central axis of rotation forms a different angle with it in sections and a device for supplying cover water is provided in the cross-sectional area of the drum.

There are publications on continuously operating sugar centrifuges of the aforementioned type known (DE-PS 100 787) in which the drum has a paraboloidal shape in order to ensure a uniformly rapid flow of the filling compound at all points of the drum. Two partial drums with a paraboloidal shape arranged one above the other in the direction of the central axis of rotation have also been proposed in order to achieve an additional residence time of the filling compound in a cylindrical section located between the two Tellromme.

Drums of the aforementioned type are difficult to produce in practice because it is very expensive to adapt the screen coverings to the paraboloidal shape of the drum or partial drums.

Sugar centrifuges of the type mentioned at the outset have also become known (magazine "Zucker" 13th year No. 14 of July 15, 1960, pages 358-363) in which the drum is divided into three sections. The base step on the bottom is provided as a cylindrical section, which is followed by a middle step with an inclination of 22 _° and a so-called large step with an inclination of 35 _° . In this design, it is provided that different screens can be installed in the individual stages in order to take into account the different filling masses.

In the course of the development, it was found that sugar centrifuges of the latter type did not lead to the desired result of a uniform centrifuging off of the filling compound and of the covering liquid applied to this filling compound and, moreover, did not allow a uniform discharge of the centrifuged crystal compound over the discharge edge of the drum. This applies in particular to filler with coarse crystals.

ist, kann die Schleuderziffer durch die Änderung der Drehzahl der Schleudertrommel beeinflußt werden. Dies ist zur Anpassung des Schleudervorganges an wechselnde Füllmassequalitäten oftmals erforderlich.The above findings have led to the fact that currently only produces and operates continuously operating sugar centrifuges with an inclination angle that remains constant over the drum height relative to the axis of rotation. Depending on the respective maximum diameter of the drum and its speed, the angles mentioned are selected between approximately 22 and 30 _° in order to achieve centrifugal numerals in the order of magnitude of 2000 to 2500 in the cross-sectional area near the throwing edge of the drum. Since the spin number z =

the spin speed can be influenced by changing the speed of the spin drum. This is often necessary to adapt the spinning process to changing filling material qualities.

The layer thickness and the centrifuging time can also be influenced in order to adapt to changing filler mass qualities, since the transport of the filler mass on the screen of the centrifugal drum takes place under the action of the centrifugal force component and the pressure of the subsequent feed material in the direction of the cone generators.

The invention is based on the knowledge that the aforementioned force components acting on the filler mass change continuously during the transport of the filler mass, since the filler mass continuously reaches areas of larger diameter of the sieve drum during the transport until the discharge end and at a constant angle of the sieve covering in with respect to the central axis of rotation is subject to a constantly increasing discharge force, but on the other hand, due to the changing consistency of the filling compound as a result of the liquid separation and the abandonment of the covering liquids, it influences changes in the flow properties of the filling compound during its movement along the changing discharge force. In the case of centrifuges with a constant angle between the axis of rotation and the screen covering, only a very unfavorable compromise solution can be achieved, in which essentially the most uniform possible removal of the material from the drum is used.

The invention is based on the sugar centrifuges mentioned in the introduction, in which the drum and / or the sieve covering, viewed in the direction of the central axis of rotation, forms a different angle with it in sections. According to the present invention, these centrifuges are to be developed in such a way that the smallest possible number of sections of the sieve covering takes into account the influencing variables which act differently on the conveying path of the filling compound, and an even distribution of the filling compound in the individual sections with a layer thickness decreasing towards the discharge edge is achieved.

To solve the above problem, it is provided that a first, starting from the throwing edge of the drum section of the drum and / or the screen covering with the axis of rotation forms such an angle that during operation with interruption of the filling material supply and maintenance of the operational supply of cover water, the material layer on this screen section persists that a subsequent second section extends over the central height range of the drum and an approximately 3 to 7 _° larger angle with the rotary axis se forms and a third section is provided which extends from this central section to the feed area of the filling compound and which forms approximately the same angle with the central axis of rotation as the first section.

The above-mentioned design of the centrifuge takes into account that the liquid contained in the filling compound in the narrow cross-sectional area favors the flowability of the filling compound, so that relatively small discharge forces acting in the direction of the cone ends are sufficient to move the filling compound in this area in the direction of the ejection edge. The liquid present as a syrup in the filling compound acts as a lubricant between the crystals. This sliding effect becomes less with increasing separation of the liquid, so that the fluidity is reduced in the central region of the centrifuge drum and for this reason the central region of the drum forms a larger angle with the axis of rotation than in the feed region of the filling compound. As a result, a greater discharge force is exerted on the filling compound and the sliding of the filling compound is promoted even without a liquid film on the screen covering. In this way, the tendency of the filling compound layer to remain on the screen surface is counteracted.

In the upper, i.e. the portion of the drum or screen covering adjacent to the discharge edge in turn forms a smaller angle with the axis of rotation than in the central region. In this way, the increasing discharge force is taken into account in the area of the drum with the widest cross section, the lid water supply which is generally provided in this area also having to be taken into account.

While in previously known centrifuges with a constant angle of the drum or the sieve covering with the central axis of rotation in the application area of the filling compound, only a thin layer is created and in the middle area due to the risk of the sugar sticking more strongly to the sieve wall and due to the lack of lubricant between the crystals An increase in the layer thickness can be observed and on the discharge side a washboard-like distribution of the crystals and thus an uneven layer thickness as well as a continuous tearing off of the spilled filling mass in the upper area of the centrifuge was observed seen the drum or the screen covering, the layer thickness becomes thinner towards the discharge edge, but without leading to localized accumulations of the crystals, which is the cause of the described tearing off of the filling compound are in the top area of the centrifuge.

Since the lubricity of the filling compound and the discharge force that is exerted on the filling compound depend on a number of parameters, such as consistency of the filling compound, crystal size, perforation of the sieve coating, centrifugal number of centrifuges and residence time of the filling compound in the centrifuge, none can be used for everyone Centrifuges valid absolute values for the angles between the sections of the centrifuge drum or the screen lining and the axis of rotation and also no absolute lengths for the individual sections can be specified.

On the basis of the dimensions of known sugar centrifuges with a constant angle between the drum wall or the sieve covering and the central axis of rotation, the procedure can be that the angle of the central region is left and the subsequent regions pointing to the bottom and the discharge edge by about 3 to 7 _° be carried out steeper, in order to then achieve the above-mentioned conditions in the section pointing towards the discharge edge by appropriately setting the rotational speed, namely a uniform sliding of the layer to the discharge edge while maintaining the filler material supply and a persistence of the layer when the filler material supply is interrupted, but the cover water supply is maintained.

Experience has shown that it is favorable if the first section extends approximately over 1/3 to 35%, the second section approximately 1/3 to 40% and the third section approximately 25% to 1/3 of the drum height. As a rule, the height of the third section, that is to say the section adjacent to the bottom of the drum, can be kept somewhat lower than the other two sections.

It is advantageous if the middle section has a greater length than the other two sections. It has proven to be expedient if the first section is approximately 35%, the second section approximately 40% and the third section approximately 25% of the drum height.

In a practical embodiment of a centrifuge, in particular for filling material of higher purity, in which a number of centrifuges of 800 to 1500 occurs in the area of the discharge rim during operation, it has proven to be advantageous if the first section and the third section unite with the central axis of rotation Angle 25 _° and the second section form an angle of 30 _° .

• Fig. 1 stellt den Schnitt durch eine Trommel mit einem Beschleunigungstopf dar,
• Fig. 2 zeigt einen Schnitt gemäß Fig. 1 durch eine Trommel, deren Siebbelag sich bis zum Trommelboden hin erstreckt.

The drawing shows a schematic representation of two embodiments of the invention based on a central sectional view through the drum of a sugar centrifuge.

• 1 shows the section through a drum with an acceleration pot,
• FIG. 2 shows a section according to FIG. 1 through a drum, the screen covering of which extends to the drum base.

In the two figures, the screening drum 1 is provided with a screen covering 2 which follows its course. The drums 1 expand from the bottom 1a or from the upper edge of an acceleration plug 3 (FIG. 1) in the shape of a truncated cone and can be driven about a central axis of rotation 4 in a manner not shown. The opening-side closure of the drums 1 is formed by a discharge edge 5, which is formed by a ring-like component.

Between the drum 1 and the sieve covering 2 held thereon there is a gap, which leads to the removal through the sieve covering 2 passing liquid in the direction of the outlet openings 6, which are arranged on the underside of the discharge edge 5. The liquid escaping there is removed separately from the sugar crystals which are flung off along the top of the discharge edge 5 in a manner not shown.

It can be seen that in FIGS. 1 and 2 both the sieve drum 1 and the sieve covering 2 are divided into three sections I, II and III, the individual sections I to III having approximately the same height h in the example shown.

Sections I and III show a matching angle α with respect to the central rotary ash 4 or the parallel to it, while section II has an angle β which is larger by about 5 _° in the example.

In the figures it is indicated that a cover water supply line 7 shown in dashed lines in the lower part of section I covers water on the screen surface 2 or the filling migrating on this screen surface from the bottom 1 a of the centrifuge drum to the discharge edge 5.

The angle a of section I is now selected so that at the operational speed of the centrifuge drum 1 and interrupted filling material supply to the bottom 1a or to the acceleration pot 3 and maintenance of the deck water supply through the supply line 7, the material layer remains on this sieve section 1 while it is at the filling material supply is set in motion again in order to move in the direction of the discharge edge while simultaneously reducing the layer thickness.

Section II runs with a greater inclination than section I with respect to the central axis of rotation 4, while section III in turn forms the same angle a with the central axis of rotation 4 as section 1.

It can be seen that despite the different inclinations of the sections mentioned, the triple division of the centrifuge drum 1 or the sieve covering 2 enables simple manufacture of the sieve covering 2, the sieve covering also being divided into the sections mentioned and the individual sections being clamped to the Sieve drum 1 can be attached.

Claims (4)

1. Continuously operating sugar centrifuge, with a screening drum which is drivable about a central rotation axis and which opens, in frustoconical shape, from the base towards the runoff edge, with a screen cloth which extends from the base of the drum or from the upper edge of an accelerator pot at the base, for the charging of the filling mass, to as far as into the region of the runoff edge; wherein the drum and/or the screen cloth, viewed in the direction of the central rotation axis, forms different angles with the latter in different sections; and an installation for supplying washwater in the region of wide cross-section of the drum, characterised in that a first section (I) of the drum and/or of the screen cloth (2), extending from the runoff edge (5) of the drum (1), forms with the rotation axis (4) an angle (a) such that during the operation, when an interruption occurs in the infeed of the filling mass whilst maintaining the routine operational supply of washwater, the layer of material is delayed on this screen section, that an associated second section (II) extends over the central height-region of the drum, and forms with the rotation axis an angle approximately 3 to 7_° larger, and a third section (III) is provided, extending from this central section to as far as the base of the drum and/or to the upper edge of an acceleror pot which is at the base, and forming with the central rotation axis approximately the same angle as the first section.

2. Centrifuge according to claim 1, characterised in that the first section (I) extends approximately over 1/3 to 35%, the second section (II) extends approximately over 1/3 to 40%. and the third section (III) extends approximately over 25% to 1/3, of the drum height.

3. Centrifuge according to one of the claims 1 or 2, characterised in that the first section (I) amounts to approximately 35%, the second section (II) amounts to approximately 40%, and the third section (III) amounts to approximately 25%, of the drum height.

4. Centrifuge according to one of the preceding claims, in particular for filling masses which are of comparatively high purity, in which, during the operation, in the region of the runoff edge, a centrifuging number of 800 to 1500 appears, characterised in that the first and third section (I and/or III) form with the central rotation axis (4) an angle of 25_° and the second section (II) forms an angle of 30_°.

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