DE1908148C3 - Device for extracting soluble components from solids - Google Patents

Description

The invention relates to a device for extracting soluble components from solids by means of a liquid in countercurrent, with a drum rotatable around its axis, with in the drum Discs arranged perpendicular to its axis and connecting adjacent discs through the axis the drum going partition walls, each of which is a compartment delimited by two adjacent disks in divide two cells, each of which in the region of the portion adjacent to the drum of their in Direction of rotation of the drum rear partition wall at least one opening for draining off the liquid with one placed in the area of each cell in each disk, towards the circumference of the disk open recess and with the opposite edges of two corresponding recesses adjacent slices connecting sloping walls to the inside of the drum are connected.

Such a device is essentially known from DT-PS 8 15 638. Although in the DT-PS 8 15 638 there are no disks directed perpendicular to the axis of the drum, but within the drum two nested, continuous screws are arranged, however the screws were also carried out in practical devices according to DT-PS: 8 15 638 Discs arranged perpendicular to the axis of the drum are formed with recesses, the edges of which are connected by inclined walls in order to achieve a snail-like course. The recesses ranged from the circumference of the drum to the middle partitions.

In the known device, the partitions are directly close to the circumference of the drum with provided openings which allow a passage of the liquid through the partitions. As a result, make up

the flat disks with the partition walls extending over the entire circumference of the drum screws, which effect the transport of the liquid. In contrast, the solids are transported with the help of special channels, which in the middle area of the drum are symmetrical to the axis of the drum and adjoin the partition walls on both sides and connect each cell to the next but one opposite to the conveying direction of the screws.

In the known device , therefore, the liquid is conveyed in two partial flows through the two nested screw conveyors, which could also be referred to as double screw conveyor, through the drum , the liquid always from a cell arranged on one side of the partition into a cell on the cell arranged on the other side of the partition changes. The solids , on the other hand, always remain on one side of the partition, so that here too there are two partial flows separated by the partition walls, and are passed through the drum through channels arranged in the region of the center of the drum, counter to the direction of conveyance of the screw conveyors. After each transport of the solids through a channel in which a cell is skipped, the solids move together with the liquid for half a revolution in the conveying direction of the conveyor screw before they leave the next cell in the conveying direction of the conveyor screw again through a channel into the cells two cells behind can be transported.

Although the known device has proven itself in practice and excellent extraction results can be achieved with it, the performance of the known device, measured in terms of the amount of solids that can be processed per unit of time, is limited. The drawn for practical limits are due to the fact that the channels through which the separated from the liquid and therefore substantially dry solids are passed, a loading ^ ₀ agreed must have inclination and a sufficiently large cross section so that the solids through this Channels can slide through unhindered and no blockage of the channels occurs. As a result, has a widening of the limited of two slices of compartments or cells is required to increase the capacity of the cells and thus the throughput of the device is forcibly an enlargement of the drum diameter to the sequence, so that the inclination of the channels is maintained despite of increase in cells further is important that only the remaining to both sides of the channels section of the partitions is for flow of the liquid available to the drum diameter, this surface will only change square in a broadening of the cells and an enlargement, increases during the capacity as the cube, so that the drainage area for the liquid in relation to the solid mass decreases with increasing drum volume, so that limits are reached here too, which result from the desired treatment time, speed of rotation of the drum, etc. Devices according to DT-PS 8 15 638 with a drum diameter of about 4 m, a length of about 30 m and a daily throughput of about 1500 t of sugar beet pulp have been implemented in practice.

The invention is based on the object of improving a device of the type described at the outset in such a way that a higher performance, that is to say a higher throughput of solids, can be achieved with the same dimensions.

This object is achieved according to the invention in that the recesses in the disks end at a distance from the axis of the drum and the disks in connection with the inclined walls on both sides of the partition walls, each bounded by the partition walls and the adjacent section of the drum Form a screw conveyor with a feed device for the solids and that a liquid line connects to the opening of each cell, each of which leads to a further opening in the opposite to the conveying direction of the screw conveyor next but one cell belonging to the other screw conveyor.

In the device according to the invention, in contrast to the known Vorrichiung in the range The cutouts on the panes do not extend to the partition, but end at a distance from the Partition wall, so that the sections of the discs adjoining the recesses each have parts of the screw conveyors, which are arranged on both sides of the partition walls for the solids. Through these screw conveyors remove the solids from a cell with one revolution of the drum transported to the next. For the transport of the solids it is important that the screw conveyor is bounded on one side by the flat partition, each with its rear partition lifts the solids and thereby lifts them out of the liquid that flows through the openings and Liquid lines can drain. The raised solid parts can then de when turning further. Slide the drum vertically or at least approximately vertically downwards into the adjacent cell, in which they come into contact with the liquid contained therein. So that's a way for the solids created, which has a large cross-section and regardless of the drum diameter a very has a great inclination, so that a very effective and very gentle transport of the solid parts is guaranteed is. As a result, the width of the compartments can be chosen regardless of the drum diameter will.

In the case of the arrangement according to the invention, the liquid is not transported by screws, but rather passed through special liquid lines. The transport of the liquid through the lines does not present any difficulties, because there is no risk of clogging in the case of liquids and the inclination of the liquid lines need only be slight. The flow rate of the liquid is determined less by the pipe cross-section than by the surface available for the liquid to drain from the solids, because these are relatively slow processes that are similar to the passage of a liquid through a filter cake. It is precisely here that the device according to the invention offers the particular advantage that it allows large drainage areas to be provided in that the entire lower section of a cell is provided with openings to which the fiü.; Sigke'.sk device is connected. A particularly effective drainage of the liquid can be achieved in a further embodiment of the invention that in each cell in one of sectors of two adjacent disks

on the one hand and the inclined drainage surfaces on the other hand device according to FIG. 12 to illustrate the path

formed area a permeable for the liquid of the liquid flow and the solids flow.

Basket is arranged. Such an arrangement of In the various figures of the drawing

Baskets is synonymous with attaching a denote the same reference numerals or identical

liquid-permeable cell wall to which the 5 similar parts.

The device according to the invention has a cylinder, liquid-permeable cell wall and, on the other hand, a drical drum 1 with a horizontal axis which can be displaced in the part of the revolution surrounding this cell wall. Inside the drum is a disc, the drum shell and the partition wall a certain number of parallel discs 2 is formed. io which contact the inner surface of the drum perpendicular Moreover, the openings may be on the longitudinal axis of the drum and defining a particularly simple manner by incisions in the number η compartments in the cells in. Each of the disks and the liquid lines 7 shown in FIGS. 6 and 7 has two recesses 3 and are guided along the partition walls. As a result of this 3 ', which is essentially in the shape of a half, a particularly simple structure is achieved in which the 15 are hexagonal and fluid lines through flat wall sections are open to the circumference of the disk. Furthermore, the discs are delimited by two, which both provide the movement of the liquid with incisions 4 and 4 'which also favor the shape as well as that of the solids. In particular, have half a hexagon, but a significantly different one can occupy a smaller surface adjoining the partition walls. The recesses 3 inclined drainage surfaces opposite one another 10 and 3 'as well as the incisions 4 and 4' are each in the edges of the incisions of the spaced apart with respect to a diameter of the disc symmetrically connecting discs of two compartments, whereby they are arranged by each other and it are the arcs of a circle that cut the middle disk. are located between the incisions 4 or 4 'and Further details and configurations of the recesses 3 and 3', larger than the invention are to be found in the following description Invention on the basis of the incisions 4 and 4 'in the drawing. It is therefore possible to describe and explain each disc 2 illustrated exemplary embodiments in more detail consisting of four sectors / .. M, L ' and M'. The features of the description and the features that can be taken from the edges of the recesses and drawings can be limited individually for incisions 3 and 3 'or 4 and 4' as well as in the other embodiments of the invention for 30 Diirchmcsserteile that are or to several Connect the apices of the recesses and incisions in any combination. Find application. It shows the disks 2 are inside the drum 1 in Fig. 1, the side view of part of a device arranged in such a way that the apex of the invention after removing the jacket plate, recesses 3 and 3 'of any disk 2 in the not all Trennungselemcntc are shown, 35 connecting diameter in the sense of rotation of the Trom-F ig. 2 is a plan view of part of the device mcl at an angle with respect to the corresponding one according to FIG. 3 is an end view of the device of FIG. 1 first-mentioned disc in the direction of the feed device of the arrow HI, direction 31 for solids is adjacent. This Fig. 4, a section along the line IV-IV in Fig. I, 40 angles is preferably about 180 ° / nor in Fig. 5 is a section along the line VV in Fig. 1, an integral multiple of this value, so that Figs 8 each top view of the disks, the drum is balanced. FIGS. I, 2, 6, 7 and 8 form parts of the device according to FIG. I, each in their entirety clearly illustrating this height of the sections VI-VI. VII-VII and VIlI-VIII in offset. Between two adjacent panes 2 F i g. 1, 45 connects an inclined wall 5, which with the inside Fi g. 9 schematize!) A development of the arrangement of the drum t and full metal sheets 6 and 7 in the inner surface of a portion of the device connection is opposite to each other according to FIG. Two cut-out disks, the oblique wound, the oblique wound 5 form the inclined collecting area in the circumferential area, the arrangement of the separating drum 1 a passage 32 which connects two adjacent elements and the path of the liquid and solids compartments. A sloping wall 5 'flows in the device according to FIG. 1 and solid metal sheets 6' and 7 'connect in the same way two opposing rounders of the recesses 3'. FIGS. 10 and 11 form a variant of a part of the two inclined wound 3 'in the circumferential area of the device in FIG. 1, 55 drum 1 one passage 32 '. 'Existing 5 Fig from the Wtlnden. 12 is a view Uhnlich Fig. I to another, and 5' and the L, M, L sectors' and M embodiment of the invention, arrangement forms in Umfnngsbereich the drum 1 Figure ₁ 13 shows a section IHngs of the line XIII-XIII In two deformed, nested transporting. 12, snails.

14 is a plan view at the level of the section line to each bounded by two adjacent disks 2 Xl V-XIV in FIG. 12 uur a deformed disc, abolished by a partition 8 in two cells I and I ' FI g. 15 a side view of the disk according to FI g. 14, or 11 and IΓ to N and N 'divided. The partitions 8 16 shows a side view of a section of the are arranged in an axial plane and on both Device according to Flg. 12 At a slight angle at a side up to drum 1 through full collecting plates 9

twisted position to illustrate the interior »5 and 9 'extended with respect to the partition wall 8

FlHclic the delivery chamber and the first chamber which are inclined and opposite to each other Device according to Flg. 12 and rounder of the two incisions 4 and 4 'of each other V I g. 17 a Mchomntlscho development of the device-removed disks 2 connect two compartments, by

they penetrate the incision 4 or 4 'of the central disc. The partitions 8 are connected to the full collecting plates 9 and 9 'by means of full plates 11 and W. In one compartment there are accordingly two full collecting plates 9 and two full collecting plates 9 'which, together with the full plates 11 and W and the inner wall of the drum 1, delimit liquid lines 10 and 10' that define the intended connection between the opposing cells of two compartments produce that lie on both sides of the compartment under consideration.

A perforated basket 12, 12 'is provided in each cell for lifting solids and separating them from liquid. Each basket 12, 12 'is arranged in the zone of the cell which is formed on the one hand by the sectors M of two adjacent disks and the collecting plate 9 and, on the other hand, by the sectors M' of the adjacent disks and the collecting plate 9 ', so that a larger filter surface is achieved. The liquid that pours out of a basket passes directly into the liquid line 10 or 10 ', which is arranged immediately behind the basket. The liquid thus flows upstream in the direction of rotation of the drum, which is indicated by the arrow 34. The following describes the parts of the device that are used to input and remove the solids and the liquid.

The entrance to the drum is delimited by a first disc 13 of the same diameter like the disks 2. This first disk 13 has no recesses and incisions, but is in the Provided with a circular opening 14 in the middle. Inclined walls 5 and 5 'as well as full sheets 6 and 6' connect the free edges of the recesses 3 and 3 ′ of the second disk 2 to the first disk 13. Between the discs 2 and 13, the drum is extended by a perforated plate 30, the drainage of liquid that was used to transport the solids to the device.

Each of the two incisions 4 and 4 'of the second disc 2 has, as FIG. 8 shows, a widening 15 or 15' towards the periphery of the disc, on the one on the side of the first compartment, that between the second and the third Disk 2 is formed, a partition 16 or 16 'is attached, on the one hand with a second partition 17 or 17', which is attached to the side facing the feed device 31 between the disk 13 and the second disk 2, and on the other hand with three Transversalwandcn 18, 19 and 20 or 18 ', 19' and 20 ', which are attached around the incisions 4 and 4' around, a chamber 21 and 21 'forms, which are made in the drum 1 through openings 22 and 22 'are connected to a collecting container 23 which surrounds the drum 1. The collecting container 23 is divided by an annular partition 26 into two zones 24 and 25, each of which constitutes a line for discharging the liquid.

The last compartment, i.e. the one through which the solids leave the device, only shows two half-cells symmetrical with respect to the diameter. These half-cells are in the middle Area of the drum limited by guide walls 27 and 27 ', which are in a to the axial plane of the Partitions 8 are located in a vertical plane and are inclined to the axis of the drum 1. This tour «- fts walls 27 and 27 'cause the solids to be ejected from the device.

The extraction liquid is at the end of the

Drum fed where the solids leave the drum. You will be in one or more compartments Pipes entered which penetrate either the drum or the inclined walls 5 and 5 '. The penetrations 28 and 28 'of the pipelines with the drum and the penetrations 29 and 29' with the bevels Walls are only shown in the penultimate compartment.

In the following, on the basis of FIG. 1,2,4 and 9 of the Path of the two solids flows and the two liquid flows in the device described explained.

The direction of conveyance of the screw is indicated by arrow 33 and the direction of rotation of the drum is indicated by arrow 34

specified. The two groups of cells are marked I, II

VI N or Γ, ΙΓ VI ', ... N'. As each

Compartment contains two cells, it is represented by the digits I, I '; II, II ';...; VI, VI ';...; N, N '. Dash-dotted lines - · - · - represent the path of part of the solids flow A and the dash-dotted lines with

two points illustrate the way

of a part of the solids flow B. Dashed lines illustrate the path of a part of the liquid flow a, whereas the dotted lines show the path of a part of the liquid flow b . Dashed lines with three dots denote the liquid portions c which enter the device together with the solids and accompany them to the first compartment, from which they exit through the openings 22 and 22 '.

The solids are mixed with the liquid that was used for the extraction, continuously introduced through the opening 14 into the feed device 31, in which they are broken down into two equal parts when passing the lower points of the inclined walls 5 and 5 ', which are the streams A and B form. The portion forming the stream A is guided into a passage 32 during a rotation of the drum through 180 ° and collected in the perforated basket 12 of the cell I. During the following rotation through a further 180 °, the portion forming the stream B is carried along into a passage 32 'and collected in the perforated basket 12' of the cell Γ. The same process takes place every time the drum rotates 360 °. The main part of the liquid that has entered the feed device 31 with the solids penetrates the perforated plate 30 and reaches the zone 24 of the collecting container 23, while the remainder c of this liquid, which together with the solids in the passage 32 or 32 'and the first compartment the drum has been carried along, penetrates the basket 12 or 12 'and passes through the incision 4 or 4' into the chamber 21 or 21 ', from which it passes through the opening 22 or 22' into the zone 25 of the collecting container ! 23 drains.

Then the path should be followed which is followed before the portion of the solids which form the stream A and which have been introduced into the cell 1. Starting from a lower position of the basket i; of the cell 1 is first lifted from the perforated basket 12 during a rotation of the drum through 180 ° in the direction of the arrow 34, the considered Antci of the flow A of the solids. Then it slides over a partition 8 to the opposite part of line 1, where it arrives at the base of a full collecting plate.

During the following rotation by 180 ", this portion of the flow A of the solids is carried along into a passage 32 and arrives in the cell U, where it is vo

a basket 12 is raised again and the process just described is repeated. With each rotation of the drum through 360 °, the considered portion of the flow A of the solids is transported from one cell to the other until it arrives in cell N of the last compartment, in which it is lifted one last time and then onto the guide wall 27 is poured out, on which it slides along to get out of the device. It can therefore be seen that the shares of the current A are only the group of

Cells 1.11 VI N passes through one half of the

Form drum, and in the sense of the conveying) direction of the screw advance from compartment to compartment at a speed of one compartment per rotation of the drum through 360 °. Because of the symmetry between the two cell groups of the drum it is obvious that the portion of the flow B of the solids which has been introduced into cell I 'follows a similar path through all cells of group Γ,

IP N 'passes through the other half of the drum

forms.

In the embodiment described, the extraction liquid is fed continuously or discontinuously to the compartment WI, N '- \ through two pipes which open at the penetrations 28, 28' and 29, 29 '. It is evenly distributed between the two cells of this compartment and forms the liquid streams a and b.

The liquid stream b introduced into the cell NI is passed through the passage 32 into the cell N during the rotation of the drum through 180 °. From this cell N , this liquid flow pours through a liquid line 10 into the cell N'-U. During the following 180 ° rotation, this same stream of liquid is passed through a passage 32 'into cell N'- 1, from which it pours through a liquid line 10' into cell N-III. This is how it works for everyone Rotation by 180 ° further, so it can be seen that the liquid flow b. has been introduced into the cell N- 1, so that it has a displacement of a compartment opposite to learn to the transport direction of the solids passes at a rotation of 180 "to N and then flows to N '~ Il and thereby from a Zcllcngruppc to During the following 180 "turn, the same flow of liquid passes from cell / V'-II to cell / VI and from there into cell / V-III. With a rotation of 360 "the liquid flow b advances by two compartments in opposite directions to the truncation of the solids and accordingly passes cells N- 1, N, / V-II, / VI, / V-III, / V in the drum -Il, N'- IV, / V-III ... For reasons of symmetry , the liquid sirom n introduced into the cell / VI pleats the cells Λ / '- l, N', N-II, NI, / V-III , / V-II, N-IV, N-III ... The two streams of liquid therefore pass through ulic cells, but without ever mixing, and they only cross the curses separating liquids and solids in each /, wide cell Compartment II, II 'accordingly enter the two liquid flows ti and b separately, and one through the liquid line to and the other through the liquid ring 10', and open into the chamber 21 or, 2Γ, from which they take care of the Openings 212 and 22 'flow into zone 25 of collecting container 23.

In summary, it can be seen that on the one hand each of the two liquid flows alternately passes from the cells of one group to the cells of another group and in this way alternately and successively meets the flows A and B of the solids, with which the liquid flows the passages 32 and 32 'at Axial progression of the solids go through together, while on the other hand the liquid flows during the rotation of the drum through 360 ° by two compartments opposite to the conveying direction of the solids and consequently twice as fast as these solids progress.

ίο The advantages of the invention described above are numerous and are based primarily on the fact that the axial conveyance of solids in the Direction of conveyance of the screw takes place through a guide in the lower edge zone of the drum, which passes through due to the inclined walls that form part of the spiral ducts, and dodged in spite of this transport of the solids in contact with the liquid not as in known devices in the central area of the Drum inclined channels need to be provided for the axial conveyance of the solids.

The absence of inclined channels makes it possible to use the usable capacity of the compartments for loading To increase solids, because there is no fear that the solids overflow via the inclined channels.

Furthermore, after lifting the solids, they are poured into the section opposite the cell, from which they come, and which has exactly the same capacity as the partition that the compartment in divided into two cells, running axially, while in the known devices the inclined channels the Pour solids onto a grid, the level of which is on the same level as the grid from which the solids come Angle of 180 ° minus twice the angular rate that would normally be used because of the balance the drum is being used. An additional increase in the metabolic capacity of the cells can be achieved continue to be achieved by the difference in the length of the arches extending between the recesses 3,3 'and incisions 4,4' of a disk 2 are located, whereby the volume can be compensated, which by the arrangement of a perforated basket 12 resp. 12 'is lost in a cell. Compared to known devices, the capacity of the drum is still magnified by the fact that the movement that

The solids run outside the liquid, in a transport from one end of a cell to the at the other end by lifting and pouring it out inside the same cell, without a axial promotion takes place. The width of the transition

over the dividing walls is of course greater than in inclined cannulas, so that the height of the sections for concealing the solids below the recesses 3 and 3 'can be smaller than that of the inclined cannula and therefore for premixing

SS liquid and solids in the lower position dci Cell a larger volume is available because!

through the overflow over the inclined wound 5 unc

5 'is limited.

You pour out the solids much early

takes place as in known devices, is used for dli Drum requires a smaller drive torque.

As the solids per revolution of the drum Continuously advancing one compartment at a time, ohm making a return movement, the solids can «

⁶ S can be taken from the last compartment, Im Oegensut; to known devices where they have to be removed from the penultimate compartment. The discharge of solids can therefore take place at a greater height

the inclined guide walls 27 and 27 'are shorter than the inclined channels of the known devices.

In the device according to the invention, the mixture experiences during the phase of contact between the solids and the liquid undergo a distinct change of direction while they are from the slants Walls is guided. Due to this fact, the extraction of the substances contained in the solids are included, accelerated. The elimination of the channels enables an increase in the surface area of the to Separation of liquid and solids serving elements. As a result, either the crowd of liquid entrained by the solids with each revolution of the drum is reduced or the speed of rotation of the drum can be increased.

Another advantage of eliminating the inclined channels is the fact that this results in the Limitations on the ratio of compartment width to drum diameter are reduced. It is therefore possible to give different compartments of the same device different widths, So to change the pitch of the screw conveyor or the screw conveyor. It was determined, that the volume of the proportions of the amount of solids is reduced in the course of the extraction, so that it an advantage since · can to reduce the capacity of the last compartments.

In the device according to the invention, the head part has the same diameter as the Troinmclkörper, so that the overall space requirement of the device is reduced. The width of the feeder is also smaller than that of the head compartment of the known devices, which is based on FIG The fact is that the liquid coming out of the drum is easily drained off in front of the feed device can be, so that serving for the separation of liquid and solids surface of the feed device can be reduced. Furthermore, there is no more lifting of the solids in the feed device, because it gets the solids through into the first compartment entrained the movement of the screw conveyor, while it is not with the known devices was possible to compensate for the build up of solids in the head compartment by offsetting the screens. Since the head section is less wide and already through the oblique wound 5 and 5 'is reinforced, can be applied to the special devices are dispensed with, which must be provided in known devices.

From the foregoing it can be seen that the structure is so of the device according to the invention is simplified, cluli no longer an inclined cannula are required that the feeder forms part of the rest of the drum, that none special facilities are required for the head section and the width of the compartments can be increased without increasing the diameter of the drum change.

The device described can be used in particular for the extraction of succhurose or sugar beet Sugar cane are used as well as for the extraction of all other substances that are contained in solids, such as for example the tunnine and gall apples.

In the AusfUhningsform of the invention according to the Flg. IO and II are the summing plates 37 and 37 '6s perpendicular to the discs and end at a short distance from the drum. Curved sheets 33 and 39 'as well as spiral-shaped, solid metal sheets 36 and 36' together with the wall form the drum 1 Liquid channels 38 and 38 'which connect the opposing cells of two compartments to one another connect, which are separated by at least one compartment.

The embodiment of the invention shown in FIGS. 12 to 17 differs from the embodiment according to FIGS. 1 to 9 in that the disks 50 are not flat, but have two sectors 51 and 51 'of approximately 90 °, which form the sectors mouth M' of the disk according to FIG. 6 and lie in the same plane perpendicular to the drum's longitudinal axis, while the two sectors L and L ' correspond to circular sections 52 and 52' of the disks 50, which also lie in a common plane perpendicular to the drum axis, but along the drum axis in the conveying direction of the solids are offset from the level of sectors 51 and 5Γ. The circular sections 52 and 52 'are with the sectors 51 and 5Γ and the edges of recesses 66 and 66' and of incisions 67 and 67 ', which correspond to the recesses 3,3' and the incisions 4,4 'of the disks 2, connected by inclined sheets 53,53 ', 54 and 54' and sections 65 and 65 'of axial partitions. The recesses 66 and 66 'are delimited by a cut edge 68 and 68', which corresponds to that of the recesses 3 and 3 'in the sector L and L', and by the corresponding free edge 69 and 69 'of the sector M or . M '. Accordingly, the length of the arc of the disc which they cover is in each case reduced by half in favor of the sector M or M '. Finally, as with the device according to FIGS. 1 to 9, the deformed disks are arranged inside the drum with a regular angular offset.

The axial distance between sectors 51 and 5Γ and the circular segments 52 and 52 'is preferably such that a circular segment 52 or respectively. 52 'of two adjacent sectors 51 and 51 or 5Γ iindSl 'the same is far away.

As with the device according to FIGS. I to 9 are the opposing cut edges 68 and 68 ' or edges 69 and 69 'of the recesses of two adjacent deformed disks 50 by inclined Walls 5 and 5 'connected, delimiting the passageways 32 and 32' which connect between adjacent ones Create compartments. It can be seen that the drum contains two transport screws in this way, the are nested and each of which is characterized by a sequence of surfaces of the components 5Γ, 65 ', 54', 53 ', 52', 5 \ 51,65,54,53,52,5, ... is formed.

As in the embodiment according to tion 1 · 'i g. 1 to 9, each compartment delimited by two adjacent, deformed disks 50 is divided into two cells by axial partitions 8, to which the sections 63 and 65 'adjoin, and by the metal sheets 9, 9' and 11, W. The metal sheets 9 and II as well as 9 'and W form liquid lines 10 and 10', respectively. In front of the sheet 9 or 9 'of each cell, in the part delimited by the sectors 51 and 51', there is a perforated basket for lifting the solids (beet pulp) and for separating them from the liquid.

The entrance to the drum is delimited by a flat disc 13, which has a central opening to the Having introduced the schnitzel. The disc 13 is by inclined Wttndc 3 and 5 'with the free round of the recesses 66 and 66 'of the first deformed disk 30 connected. Between the first deform th disc 50 and the disc 13, the drum is through

13 '14

sin perforated plate 30 extended. A full sector 60 of a cell minus the length of the axial offset

The 60 'which corresponds to the last liquid conduit before the opening. When passing through a liquid

device 10 or 10 'on the input side on the keitsleitung 10 or 10' from a compartment N or N ' to

Collector plate 9 or 9 'is attached, forms with part of a compartment N'-II or, N- II, the liquid passes

of the circular segment 52 or 52 ', a part of FIG. 5 in the axial direction by a distance that corresponds to the width

inclined sheets 53 and 54 or 53 'and 54' as well as the two compartments minus the length of the axial

full sheets 64 or 64 'a line 63 or 63', the offset is the same. Overall, like the first

for discharging the embodiment coming out of the drum, the liquid during a

Liquid is used. This conduit limits an opening half turn of the drum a distance

61 or 61 'in the drum wall and ends in the io promoted, which is equal to the width of a compartment, so at

Zone 25 of the collecting container 23. The drum wall is a complete rotation of the drum about one of the

between sectors 51 and 5Γ of the first stretch corresponding to the width of two compartments,

second deformed disc 50 with openings 62 and In the feeder 31 and the first cell

62 'provided that a drainage of the liquid that remains from the path traversed by the solids

originating from the feeder, in zone 24 of 15, but is the path followed by the liquid

Allow collecting container 23. slightly changed. The main part of the liquid carried by

The last compartment of the drum has carried the same solids into the feed device 31.

Structure as is assumed in the embodiment according to FIG. 1, flows through the perforated sheet metal 30 and into

to 9. Likewise, in the same way as there, the zone 24 of the collecting container 23, while the rest

Extraction liquid introduced into the device. 20 of the liquid through a passage 32 or 32 '

Inside the drum and at the exit for the first cell I or Γ together with the solids

Solids is the path of the two solids flows and the drum pelangt, then the basket 12 or 12 '

of the two liquid flows analogous to that on the basis of the and through the opening 62 or 62 'into the zone

Embodiment according to the F i g. 1 to 9 described- 24 of the collecting container 23 exits,

as is clear from FIG. As a result of the 25 In cells II and II ', the liquid flows a

special design of the discs 50 suffer, however, and b separated by the liquid line 10 and 10 '

the solids as they slide over the from and get into the line 63 or 63 ', from which they

Partition 8, that is, during its transition from that through the opening 61 or 61 'in the zone 25 of the

between the two adjacent sectors 51 and 51 collecting container 23 flow off.

or 5 'and 51' delimited part of the cell to which 30 The described with reference to FIGS. 12 to 17 are

between the two adjacent circular sections 52 embodiment of the invention is primarily for very

and 52 or 52 'and 52' located section of the cell determines large systems. In the embodiment

an axial feed in the sense of the general according to FIGS. 1 to 11 would have a very large width

Direction of conveyance in the drum by a distance that has a disproportion between the length of the cells

axial offset between the circular sections 52 35 inclined walls 5 and the circumferential length of the sectors

and 52 'and corresponds to sectors 51 and 51'. In the case of the discs 2 result in the zones of the cells

common transition of the solids and the limit of which zones the one serves the

Liquid from a cell / V-1 or N '- \ to a cell to allow collection of the chips and filtration

N or N 'of the following compartment through a passage, in which the basket 12 is arranged, while in

32 or 32 ', the solids move axially only 40 of the other the chips into a new liquid

by a distance equal to the width of a compartment.

minus the axial offset mentioned above. The one described with reference to FIGS. 12 to 17

is equivalent to. It can thus be seen that as well as construction enables with respect to construction

in the embodiment described first, according to FIGS. 1 to 9 with the same width of the compartment one

Solids during a full rotation of the 45 reducing the length of the sloping walls and one

The drum advance by a distance that increases the width of the surface of the baskets and, as a result,

of a compartment is the same, but in contrast to that of the filter area.

What is in the first-mentioned embodiment. It goes without saying that the invention does not apply to the

game is playing, part of the axial conveyance of the solids described embodiments is limited,

takes place outside the liquid. 5 ° but deviations from it are possible without the

Because of the axial misalignment, the liquid falls, leaving the scope of the invention. So could

the solids through a passage 32 or 32 'of, for example, a device according to the invention mil

a compartment N- 1 or N'- 1 to a compartment Nbzw. N ' one or with three screw conveyors, one only

accompanied, with respect to the conveying direction of the or three drainage plates for the liquid per abbey

Fluid axially back a distance equal to 55 width and so on.

For this purpose 10 sheets of drawings

Claims (9)

Patent claims! 1. Device for extracting soluble components from solids by means of a liquid in countercurrent, with a drum rotatable around its axis, with vertical in the drum to their axis arranged disks and connecting adjacent disks, through the Partition walls extending along the axis of the drum, each one of two adjacent discs Divide the limited compartment into .two cells, .of which each ·· '> in the area of the to the drum adjoining section of their rear partition in the direction of crushing of the drum at least one Has opening for draining off the liquid, with one in the area of each cell in each disc attached, to the circumference of the disc open recess and with the opposite Edges of two corresponding recesses of adjacent disks connecting, sloping Walls connected to the inside of the drum, characterized in that that the recesses (3, 3 ') in the discs (2) end at a distance from the axis of the drum (1) and the discs (2) in connection with the inclined walls (5.5 ') on both sides of the partition walls (8) one bounded by the partition walls (8) and the adjacent section of the drum (1) Form a screw conveyor with a feed device (31) for the solids; and that at the opening (4,4 ') each cell is connected to a liquid line (10, 10'), each of which leads to a further opening in the opposite to the conveying direction of the screw conveyors The cell belonging to the other screw conveyor leads to the next but one. 2. Apparatus according to claim 1, characterized in that the openings in the cells of Incisions (4, 4 ') are formed in the discs (2) and that the liquid lines (10, 10') are connected the partitions (8) are guided along. 3. Apparatus according to claim 2, characterized in that the partition walls (8) adjoining, inclined run-off surfaces (9, 9 ') the opposite edges of the incisions (4, 4') the spaced apart disks (2) connect two compartments, whereby they through the incisions (4, 4 ') of the middle disk (2). 4. Device according to one of the preceding claims, characterized in that the recesses (3, 3 ') in the discs (2) and the partitions (8) between the successive ones Discs (2) around the axis of the drum in the conveying direction of the screw conveyor at an angle in Direction of rotation of the drum are offset from one another. 5. Apparatus according to claim 4, characterized in that the angular offset of the recesses (3, 3 ') and the partition walls (8) is approximately 180 ° / n or an integral multiple of this value, where η is equal to the number of the disks ( 2) is limited compartments. 6. Device according to one of the preceding claims, characterized in that in each cell in one of sectors (M, M ') of two adjacent disks (2) on the one hand and the inclined drainage surfaces (9, 9') on the other hand, an area formed for the liquid permeable basket (12,12 ') is arranged. 7. Device according to one of the preceding claims, dadMrch ^ characterized in that the in the Cells ^ each fish in the direction of rotation rear edge of recesses (66, 66 ') and the inclined drainage surfaces (9, 9'). Circular sectors (51, 51 ') of the disks (50) opposite the intermediate edge in the direction of rotation Aussparupgen (66,66 ') and the inclined drainage surfaces (9, 9 ') of the partition walls lying Kreisab "cut; (52, 52') of the disks in the conveying direction the screw conveyor offset and with the circular sections (52, 52 ') by inclined metal sheets as well Abscfinitfe axial partition walls (53, 54, 65, 53 ', 54', 65 ') are connected, 8. Device according to one of the preceding claims, characterized in that the first two disks (13, 2) limit a feeding device (31) which is not divided into cells and which has an opening (14) for the input of the solids and in the area thereof the drum (1) with Make holes for the passage of liquid is. 9. Apparatus according to claim 8, characterized in that the in the feeding device (31) opening liquid lines (10,10 ') are connected to a liquid outlet (115 to 21) which is connected to Openings (22,22 ') of the drum (1) ends.