EP0565824A1 - Press for dewatering substances through compression - Google Patents

Abstract

A method is proposed for dewatering materials which can be dewatered by means of compression, especially waste from the preparation of pulp, by means of which method the materials can be dewatered to a very substantial extent, until they are ready for dumping. To this end, the material to be dewatered is first subjected to preliminary dewatering in a transport section (5), under the force of gravity and with compression if necessary. This preliminary dewatering may be carried out by a continuously operating conveying section (7) via a perforated basket (10). Then the material proceeds to a pressing section (6) in which an intermittently operating pressing device is active. Various designs of the pressing elements (13, 14) belonging to the said pressing device make it possible to increase dewatering performances further. The invention relates both to the method and to the apparatus for implementing the method. <IMAGE>

Description

The invention relates to a press for dewatering according to the preamble of claim 1. It is described in the following using the example of waste arising in waste paper processing, but is also applicable to other materials that can be dewatered by compression.

As is known, the waste paper mostly contains a certain proportion of contaminants which should be removed during processing for the purpose of reusing the waste paper. A number of machines and processes are available for this purpose, which derive the waste paper for further processing as a good substance and the contaminants removed from it as a reject. These rejects are usually deposited or, in special cases, processed into new products. Since waste paper is usually processed in an aqueous suspension, the rejects are highly water-containing, which makes them difficult to manipulate and considerably increases the costs of transport and landfill for their disposal.

Mechanical pressing of water out of the material has proven to be an economical and practical method. For example, screw presses are used in which a driven screw conveyor is arranged within a substantially concentrically cylindrical or conical, perforated sheet metal jacket or the like. The radially added reject entry is dewatered in cooperation with a damming device, whereby the water can escape through the perforated sheet metal jacket or the like while the rejects are retained. The compression and dewatering of the reject is improved if a conical shape is chosen for the sheet metal jacket, the diameter of which decreases in the direction of the reject, and of course the outer screw diameter must also be adapted to these geometric conditions. Are the well-known drainage screws like described, they are exposed to particularly great wear due to the intense friction between the reject and the components of the machine. This is because there is a considerable relative movement with enormous axial and radial forces between the already strongly thickened material and the components. In addition to a remnant of fibers, this reject often contains many small metal parts and hard plastic pieces, which experience has shown can lead to high wear and tear even of high-quality metallic components.

It is therefore the task of designing a dewatering press for materials that can be dewatered by compression in such a way that a high degree of dewatering can be achieved and at the same time excessive wear on the machines carrying out the method is avoided. This should also be possible if the material to be dewatered consists of waste from the processing of waste paper.

The stated object is achieved in full by the characterizing features of claim 1.

Subclaims 2 to 23 describe particular embodiments of the invention.

Because the pressing treatment in the device according to the invention does not take place continuously but batchwise, very high forces can easily be exerted on the material. Only slight relative movements take place between the components transmitting the pressing force on the material and the material. If the pressing movement takes place at right angles to the direction of the initial conveying, the material is enclosed and can be compressed very strongly without a disadvantageously high force being transmitted to the components causing the initial conveying.

Figur 1

ein Funktionsschema des Erfindunggegenstandes

Figur 2

ein schematisches Schnittbild des Erfindunggegenstandes

Figur 3

eine Draufsicht der in Fig. 2 gezeigten Vorrichtung

Figur 4

schematisch den Ablauf der Preßbehandlung in den Darstellungen a, b, c

Fig. 5-7

schematisch dargestellt das Wirken verschiedener Preßvorrichtungen

Fig. 8, 9

schematisch: eine vorteilhafte Ausführung der Preßelemente

Fig. 10

schematisch: eine weitere Preßeinrichtung mit Absätzen

Fig. 11

schematisch: eine weitere Preßeinrichtung mit Gelenken.

Fig. 12

schematisch: den Erfindungsgegenstand mit geschwenkter Schnecke

Fig. 13

schematisch: den Erfindungsgegenstand mit abgeklappter Austragsvorrichtung

Figur 1 erläutert in einem Schema die einzelnen Funktionen, die durch die erfindungsgemäße Vorrichtung erfüllt werden können. In dem hier dargestellten Beispiel wird ein Altpapierstoff S in der Aufbereitung 1 bearbeitet, wobei Abfälle anfallen, während der aufbereitete und von Abfällen zumindest teilweise gereinigte Stoff S' weitergeführt wird. Die Abfälle gelangen als das zu entwässernde Material A in eine Förderung 2 mit einer Förderstrecke 5. Infolge der Schwerkraft und meistens auch durch Verdichtung wird dabei Wasser W aus den Abfällen entfernt. Das so entwässerte Material A' wird anschließend in der Preßstrecke 6 der Preßbehandlung 3 unterzogen und unter Abgabe von weiterem Wasser W' noch stärker entwässert als pfropfenförmiges Material A'' herausgeführt.The invention is explained with reference to drawings. Show

Figure 1

a functional diagram of the subject of the invention

Figure 2

a schematic sectional view of the subject of the invention

Figure 3

a plan view of the device shown in Fig. 2

Figure 4

schematically the course of the press treatment in the representations a, b, c

Fig. 5-7

schematically shown the action of various pressing devices

8, 9

schematically: an advantageous embodiment of the pressing elements

Fig. 10

schematically: another pressing device with shoulders

Fig. 11

schematically: another pressing device with joints.

Fig. 12

schematically: the subject of the invention with a swiveled screw

Fig. 13

schematically: the subject of the invention with the discharge device folded down

Figure 1 explains in a diagram the individual functions that can be performed by the device according to the invention. In the example shown here, a waste paper stock S is processed in the preparation 1, waste being produced, while the processed stock S 'which has been at least partially cleaned of waste is carried on. The waste arrives as the material A to be dewatered in a conveyor 2 with a conveyor section 5. As a result of gravity and usually also by compression, water W is removed from the waste. The material A 'thus dewatered is then subjected to the pressing treatment 3 in the pressing section 6 and, with the release of further water W', is dewatered even more than plug-shaped material A ''.

FIG. 2 shows a pressing device designed according to the invention. In the case shown here, a transport screw is used as the conveyor device 7. The material A passes through an opening 11 into the volume 8 in which the transport screw is located. The volume 8 is limited by a jacket 10 provided with holes 9, which is cylindrical here. The material is already pre-dewatered by gravity as well as by any compression that may occur during transport. The water W runs through the openings 9 of the jacket 10 into a drainage box 17. After passing through the conveying section 5, the material reaches the area of the discharge 12.

The pressing elements 13, 14, which are located between an upper and a lower plate 23 or 24, are used in the pressing section 6 that follows. In the case shown here, they can be moved at right angles to the conveying direction of the screw conveyor in guides 18 and are periodically pressed against the material A 'by servomotors 19. The, for example, hydraulically operated servomotor is supplied with a pressure medium via pipe socket 21. By pressing further water W 'gets into the drainage box 17. Of course, servomotors according to FIG. 11 or other devices generating pressure forces are also conceivable. The material A '', which is now very drained, can fall out of the device or be conveyed out by the following material. The screw conveyor is driven by a drive motor 16 which - as indicated schematically - sets the shaft of the screw conveyor in rotation via a belt or the like.

The same pressing device is shown in FIG. 3 with the upper plate 23 omitted as a view from above with a view of the housing 15 and the inlet opening 11.

Fig. 4 shows a rough schematic representation of the deformation of the compressed material A 'to the pressed plug-shaped material A' '. The representations a, b, c show the course of the pressing process, namely (a): unpressed, the pressing elements 13 and 14 are moved against the waste A '; (b): With the help of relatively large forces K and K 'the waste is pressed and accrues according to (c) as a deformed and compressed plug.

The change of a material compacted to a round cross-section to one with an elongated cross-section brings about a reshaping of the entire plug, which means a significant improvement in the drainage options. As a result, the position of adjacent areas to one another in the material to be pressed is changed and the joining into a compact compact is made considerably easier, which in turn improves the dewatering performance with the same effort. Examples of this are outlined in FIGS. 5 to 7, but this selection could not be complete.

According to FIG. 8, a further improvement in the effect is brought about by elevations 27 on the pressing element 13 which are designed as cones and have holes not shown. They are attached to the side facing the material to be pressed and are pressed into it during the pressing process. This advantageously shortens the path for the water. Fig. 9 shows the arrangement with such designed pressing elements 13 and 14 together with the upper (23) and lower (24) plate in section.

As shown in FIG. 10, the pressing elements 13 ″, 14 ″ can be designed such that they can treat the material A ′ to be pressed particularly intensively in several individual steps. Therefore, the pressing section 6 is shown here as being divided into partial pressing sections 6 'and 6' '. After pressing in the partial pressing section 6 ', the material reaches the partial pressing section 6' 'through the pressing material, not shown, after the pressing elements have opened again. Then another strong compaction and drainage takes place. When the pressing elements are opened again, the plug which is still compacted can fall out or be pressed out by the following material. The paragraph 26 shown can advantageously enhance the effect, but is not necessary. Of course, other partial press sections, not shown, can also follow. The openings in the pressing elements, not shown here, can be chosen larger for better water drainage where the material is more compressed because the plug, which is then more compacted, has less tendency to press into the holes and thus block them.

Fig. 11 schematically represents another possibility, namely how the pressing elements 13 'and 14' on the housing 15 can be pivoted by joints 25 and moved by servomotors 19 '. The open position is drawn thinner than the press position.

In Fig. 12 is a sectional side view - somewhat exaggerated for clarification - the pivoting movement of the screw conveyor 7 together with the Drive unit 16 'shown. The pivot point D for this rotary pendulum movement lies, viewed axially, in the area of the screw bearing. The bearings 28 and 29 shown there can absorb both the axial forces and the radial forces at this point, but the possibility of the screw axis to carry out a rotary pendulum movement is retained. The drive unit 16 'is essentially carried by the described bearing, since it is connected to the drive-side end of the screw conveyor 7. The torque resulting from the driving force is transmitted to the housing 15 of the press via the torque support 30. With a corresponding construction of the machine, the lever torques on the bearings 28 and 29 originating from the weight forces of the screw conveyor 7 and the drive unit 16 'can essentially balance each other.

13 shows, in simplified form, an opened discharge device. The view from above was chosen for the display. The discharge device contains a frame 31 which is fastened in hinges 32 to parts of the housing 15 of the dewatering press so that it can be opened and closed. This frame 31 in turn carries joints 25 which serve to fasten the simplified pressing elements 13, 14 so that they can be moved relative to the frame 31. If the discharge device is folded down while the dewatering press is at a standstill, the end of the screw conveyor 7 is relatively easily accessible, while the plug A 'can remain in the pivoted discharge device. For example, after the maintenance work on the dewatering press has been carried out, the discharge device can be folded forward again and the operation of the dewatering screw can be started again. Since the plug A 'has returned to its old position, the optimal operating state of the dewatering press is reached relatively quickly.

Even if only devices with horizontally lying conveying and pressing sections are shown here, vertically or obliquely arranged ones are also conceivable, in some circumstances even advantageous. Furthermore, the number of pressing elements used for the pressing process need not be limited to two.

Claims (24)

Dewatering press, which contains a conveying device (7) defining a conveying path (5), which is arranged in a volume (8), with an opening (11) for the material introduction, through which material to be dewatered (A) into the initial region of the conveying path (5) can reach, the volume (8) being partially limited by a jacket (10) provided with a plurality of openings (9), by the water (W) contained in the material (A) to be dewatered, with the retention of a substantial part of the material (A ') present as a solid, whereby it is compacted and partially dewatered and with a material discharge (12) located at the end of the conveyor line,
characterized by
that in the area of the material discharge (12) there are pressing elements (13, 14, 13 ', 14', 13 '', 14 '') which extend over a pressing section (6) in the conveying direction into which the material (A ') can enter and pass through at the end of the conveyor line (5), a passage cross section being formed between the pressing elements (13, 14, 13', 14 ', 13'',14''), which can be enlarged and reduced as a result, that at least one of the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') is moved. Dewatering press according to claim 1,
characterized by
that the movement of the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') in the pressing section (6) can essentially bring about compacting at right angles to the direction of the initial conveyance. Dewatering press according to claim 1 or 2,
characterized by
that the conveyor (7) is a screw conveyor. Dewatering press according to claim 1 or 2,
characterized by
that the jacket (10) is formed by a cylindrical screen plate. Dewatering press according to claim 1 or 2,
characterized by
that the jacket (10) is formed by a conical screen plate. Dewatering press according to claim 1 or 2,
characterized by
that the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') consist of at least two components which can be moved transversely to the conveying direction in guides (18) and are designed such that they move through them when they converge can compress essentially enclosed emerging material (A ', A'') or release them when they diverge. Dewatering press according to claim 1 or 2,
characterized by
that in the area of the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') there is space for receiving a part of the material that has escaped at the material discharge (12) and that the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') can be folded down together with the plug-like solidified material (A ') located in this room in such a way that the solidified material (A') can remain therein so that the area of the material discharge (12) is exposed and can be made accessible. Dewatering press according to claim 1 or 2,
characterized,
that the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') consist of at least two components which are attached to the press housing (15) by joints (25) and are designed in such a way that they are pivoted about the said joints (25) compress the material (A ', A'') that is essentially enclosed by them and release them when they are swung out. Dewatering press according to claim 7,
characterized,
that the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') consist of at least two components which are attached to the frame (31) by means of joints (25) and which are designed in such a way that they are in a pivoting-in movement around said joints (25) can compress the material (A ', A'') that is essentially enclosed by them and release them when swiveling out, and the frame (31) is in turn hingedly connected to the press housing (15). Dewatering press according to claim 1, 2, 7, 8 or 9,
characterized,
that the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') have openings for the reception or passage of squeezed water. Press according to claim 10,
characterized by
that the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') are provided with openings for the squeezed water, the size of which increases in the conveying direction of the material. Press according to claim 10 or 11,
characterized by
that the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') have tapered elevations in the pressing direction, which can penetrate into the material (A ', A'') during the pressing process and have openings for discharging the Water (W ') are provided. Press according to claim 7, 8 or 9,
characterized by
that the pressing elements (13, 14, 13 ', 14', 13 '', 14 '') are shaped such that they can change both the volume of the material (A ', A'') passing between them and its cross-sectional shape . Press according to claim 13,
characterized by
that an elongated cross-section can be made from an essentially point-symmetrical cross-section. Press according to claim 13 or 14,
characterized by
that the cross-sectional shape of the emerging material is essentially round and can be changed to an angular shape by the pressing elements. Press according to claim 1,
characterized by
that at least one pressing element (13, 14, 13 ', 14', 13 '', 14 '') can be moved by a servomotor (19, 19 '). Press according to claim 16,
characterized by
that two servomotors (19) acting in the opposite direction are combined in one structural unit in such a way that the pressing forces can support one another within one structural unit. Press according to claim 16 or 17,
characterized by
that a control device for the servomotor (19, 19 ') is present which controls the movement of the at least one press element (13, 14, 13', 14 ', 13'',14'') as a function of time. Press according to claim 16 or 17,
characterized by
that there is a control device for the servomotor (19, 19 ') which allows the at least one pressing element (13, 14, 13', 14 ', 13'',14'') to be moved as a function of the drive torque for the conveyor device ( 7) controls so that the value for the drive torque can be kept within a predetermined range. Press according to claim 3, 5 or 6,
characterized by
that the screw conveyor is driven and supported at the entry end and is free from mechanical storage at the discharge end. Drainage press according to claim 20,
characterized by
that the screw conveyor is mounted at the entry end so that it can change its position under the action of the forces acting essentially at right angles to its axis line. Dewatering press according to claim 21,
characterized by
that the screw conveyor is held at the entry end by a predominantly torque-free bearing. Press according to claim 3, 5 or 6,
characterized by
that the drive motor of the screw conveyor is connected to it in such a way that it can be pivoted together with it about a pivot axis perpendicular to the screw axis. Use of the press according to one of the preceding claims,
characterized by
the material to be dewatered (A) consists of waste arising from the processing (1) of waste paper stock (S).

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