EP0616072A1 - Process for screening a fibrous suspension and apparatus for its application - Google Patents

Abstract

In the screening process for fibrous suspensions a partition (3, 3') with openings is used, through which the components of the suspension (S) to be screened are classified according to size. In this case, on the supply side (4) to the partition (3,3'), the gentle removal of the rejected components is achieved with the aid of flow vanes (7,7'), while on the passage side (5), pressure surges are generated by means of reamers (6), pass through the openings of the partition and prevent their blockage. <IMAGE>

Description

The invention relates to a method for sorting fiber suspension according to the preamble of claim 1 and a screening device for carrying it out.

Such sorting processes are often used in plants for the processing of waste paper, possibly also in the treatment of pulp suspensions. The aim of such a treatment of pulp suspensions is the separation of impurities or pieces of pulp which cannot be dissolved sufficiently. The focus is on contaminating substances that come from the use of the paper and would interfere with the processing and reuse of the recycled waste paper. Plastic contaminants, adhesive backs and highly wet-strength paper parts are particularly important. In principle, other contaminants can also be removed by means of such screening devices; For economic reasons, however, it is advisable in many cases to use the density deviating from the suspension, particularly in relation to stones, broken glass and metal parts, in hydrocyclones. Although the styrofoam parts also have the property of being able to float easily due to a much lower density and thereby be removable in hydrocyclones, on the other hand they are very easy to shred by mechanical forces to such an extent that their removal then becomes difficult. For this reason, it is often also desirable to remove styrofoam parts from the suspension very early in the preparation process.

So that such a sorting process can be carried out in a manner that is reliable in operation, the means mentioned for clearing must be used. In addition to the effect desired per se, namely to prevent the setting down and clogging of machine parts, they can also have the undesirable effect, namely that due to itself to reduce the size of solid particles which can be separated out to such an extent that their removal becomes difficult. Attempts have also been made to avoid this disadvantage by using the broaching agents on the accepting side of the release agents. However, this did not always result in sufficient security against clogging, especially not when there is a lot of dirt.

The aim of the invention is therefore to provide a method which guarantees problem-free operation, in particular freedom from blockages in a continuous driving style, but on the other hand does not crush the contaminants to be separated out or at most to such an extent that they can be eliminated effectively and economically.

This goal is fully met by the features in the characterizing part of claim 1. Advantageous devices for carrying out the invention are listed in the subsequent subclaims.

The fact that on both sides of the partition provided with an opening, which thus serves to retain the solids due to their size, have parts which are movable relative to it, makes it possible to achieve the object. This is because on the flow side with the clearers working there, it is possible to keep the openings in the partition wall clear, in particular by pressure and suction pulses which are strong enough to also act in the openings and through them. These pressure and suction impulses are the result of a large relative movement between the suspension and the clearers.

On the opposite side, that is to say the inlet side of the partition provided with openings, on the other hand, very gentle removal of the rejected, concentrating solids by the flow blades is possible.

In the devices provided for carrying out the method, the flow blades are designed in this way and relative to the other parts of the machine positioned that mechanical comminution of the solids is extremely low. For this purpose, relatively large distances to the parts of the machine, relative to which the flow blades move, can be selected, rounded edges on the flow blades and / or a cross-sectional geometry of the blades, which is designed such that the greatest possible momentum transfer to the suspension takes place, and so the relative movement between suspension and flow blades is reduced.

The effect of the flow blades can advantageously be adjusted so that a transport movement of the solids takes place on the inlet side when they are being lifted off the partition by the pressure impulse of the scrapers through the openings. A clogging of the openings in the partition can therefore not occur.

A low mechanical stress on the fibrous material may occasionally be desirable as long as there is no excessive comminution of contaminants.

• Fig. 1 grob schematisch die Wirkung des erfindungsgemäßen Sortierverfahrens,
• Fig. 2 eine Siebvorrichtung mit ebener Trennwand,
• Fig. 3 eine Detailansicht der in Fig. 2 gezeigten Vorrichtung,
• Fig. 4 eine Siebvorrichtung mit zylindrischer Trennwand,
• Fig. 5 eine Siebvorrichtung mit Rotoren von stark unterschiedlichen Durchmessern.

The invention and its advantages are illustrated by FIGS. 1 to 4.
Show

• 1 roughly schematically the effect of the sorting method according to the invention,
• 2 a screening device with a flat partition,
• 3 shows a detailed view of the device shown in FIG. 2,
• 4 a screening device with a cylindrical partition,
• Fig. 5 shows a screening device with rotors of widely different diameters.

1 shows a model of the sorting process according to the invention in three phases (1a, 1b, 1c), shown roughly schematically. According to FIG. 1 a, both a flow blade 7 and a scraper 6 move along a partition wall 3 serving as a separating element. The suspension flow is indicated by arrows 12 in the area of the openings 2. Wherever the scraper 6 just passes, a pressure pulse forms, which causes a backflow through the openings of the separating element. One notices already the solid particle 13 approaching the separating element. In Fig. 1 b, the solid particle 13 has attached itself to the separating element 3 and clogs part of the openings. The next flow blade 7 and the next scraper 6 are already approaching. As shown in FIG. 1 c, the pressure pulse of the scraper 6 pushes the solid particles away from the separating element 3 so far that they can be moved by the flow generated by the blade 7 .

2 shows an example of a screening device with which the method according to the invention can be carried out. It shows schematically a side sectional view of a housing 1 receiving the suspension S, which contains a partition 3 as a partition. The partition 3 has a multiplicity of openings 2 (FIG. 3). The suspension flow, which can pass through the dividing wall 3 through the openings 2, is led out of the housing through a connecting piece as a good substance G. The remaining amount also comes out of the housing 1 through a nozzle other than Reject R. In normal operation, the amount G is much larger than the amount R.

Due to the effect of the partition wall, a distinction can be made between an inlet side 4 and a through side 5. On the through side 5, the scrapers 6 are visible as part of a scraping rotor 8. Broaching means in the broader sense are also located on the inlet side 4 of the partition 3, here in the form of flow blades 7. They are parts of a blade rotor 9, which - as drawn here - is connected to the clearing rotor 8 by a shaft. However, this connection is not always necessary if it is usually recommended for economic reasons.

In the case of a connection of the two rotors described above, the connecting shaft is guided centrally through the dividing wall 3, it being possible for sealing parts 10 to be used. However, it may also be the case that a gap remains through which part of the suspension can flow. This would be harmless as long as no coarse parts get into the casting and there is no blocking of this space.

The rotors can be driven, for example via a pulley 11. Furthermore, there is storage 12 indicated.

FIG. 3 shows a section of FIG. 2 and shows in particular how the distance A1 between flow blades 7 and partition 3 and the distance A2 between partition 3 and reamer 6 are defined.

FIG. 4 again shows schematically, in section, a differently designed screening device according to the invention, in which the partition 3 is constructed essentially in a circular cylindrical manner, the openings (not shown here) for the passage of the suspension being located in the cylinder surface. Such machines are referred to as pressure sorters and the partitions used therein because of their shape as screen baskets. The sorter shown here has an inlet for the material suspension S on its radial outer wall, so that the main flow of the suspension takes place radially from the outside inwards and the cleaned suspension as accept material G can flow out of the interior of the sieve basket here through the cover.
The retained parts are removed as reject R from the annular space radially outside the strainer basket. Again, clearers 6 can be seen on the flow side and flow blade 7 on the inlet side of the partition walls 3. Here, too, the scraper on the one hand and the flow blade on the other hand are each combined on a rotor 8 or 9 and can be driven together via a pulley 11.

As a special feature, the outer diameter of the rotor with the flow blades 7 'is selected in FIG. 5 so that it is slightly smaller than the inner diameter of the annular perforated partition 3'. This makes it easy to Install and remove from the inlet side 4 without removing the rotor carrying the flow blades 7 '. The rotor itself becomes smaller and therefore cheaper. In operation, its effect also extends to the radially outside area, so that the holes can be kept free by interaction with the clearers 6 passing close to the partition 3 '.

It is known that sorters with screen baskets also radially from the inside out can be flowed through, with the application of the invention, the more intensely acting clearers are located radially outside and the less intensely acting flow blades are located radially inside the screen basket.

Claims (15)

Process for sorting fiber suspension, in particular for separating contaminants from an aqueous suspension containing waste paper, in a sieving device by retaining solids due to their size on the inlet side of an opening-provided separating element which allows water and fiber to pass to the flow side, clogging the Screening device is prevented by means of clearing means which can be moved near the opening outlets and which generate hydraulic pressure surges,
characterized by
that in addition, on the inlet side in the area of the openings, means for clearing are operated less intensively than the means for clearing on the flow side. Screening device for carrying out the method according to claim 1 on or in a housing (1) for receiving the fiber suspension to be treated, which screen device has as a separating element an opening (2) provided with a partition (3,3 ') for retaining solids due to their size the inlet side (4) and which water and fibrous material can pass to the throughflow side (5), clogging of the screening device being prevented by means of clearers which can be moved at a distance from and along the partition,
characterized by
that there are pressure surge generating clearers (6) on the flow side (5) of the partition (3,3 ') and additionally on the inlet side (4) at a distance from the partition (3,3') movable flow blades (7,7 ') . Screening device according to claim 2,
characterized by
that the clearers (6) movable on the flow side (5) of the partition (3,3 ') have a hydrodynamic profile for generating pressure surges essentially transverse to the direction of movement. Screening device according to claim 2 or 3,
characterized by
that the flow blades (7, 7 ') movable on the inlet side (4) have the shape of feed or pump blades. Screening device according to one of claims 2 to 4,
characterized by
that the distance (A1) of the flow blades (7,7 ') on the inlet side (4) from the partition (3,3') is more than twice as large as the distance (A2) of the clearers (6) on the passage side (5) from the partition (3,3 '). Screening device according to one of claims 2 to 5,
characterized by
that the reamer (6) to a reamer rotor (8) and the flow blades (7,7 ') belong to a blade rotor (9). Screening device according to claim 6,
characterized by
that both rotors (8 and 9) are connected to each other and are driven at the same speed. Screening device according to one of claims 2 to 7,
characterized by
that the distance (A2) between the partition (3,3 ') and clearers (6) is between 0.5 and 3 mm. Screening device according to one of claims 2 to 8,
characterized by
that the distance (A1) between the flow blades (7,7 ') and the partition (3,3') is between 20 and 50 mm. Screening device according to one of claims 2 to 9,
characterized by
that the partition (3,3 ') is a flat screen plate. Screening device according to claim 10,
characterized by
that the partition (3 ') has an annular shape and that the radially outer extent of the flow blade (7') is smaller than the inside diameter of the partition (3 '). Screening device according to one of claims 2 to 11,
characterized by
that the partition (3) is part of a circular cylindrical screen basket. Screening device according to claim 10 or 12,
characterized by
that the openings (2) are a plurality of cylindrical holes. Screening device according to claim 10 or 12,
characterized by
that the openings (2) are a plurality of conical holes widening in the direction of flow of the suspension. Screening device according to claim 10, 11 or 12,
characterized by
that the openings (2) are a plurality of slots.

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