DE1205914B - Feed device for a conical screw screen centrifuge - Google Patents

Description

Feed device for a conical screw screen centrifuge The invention relates to a supply device for a cone-shaped Screw screen centrifuge with a flange protruding into the inlet and transfer sleeve connected to the feed line.

In the known supply devices of this type is for sealing of the inlet on the rotating centrifugal drum a sleeve is arranged, which with a sealing lip against the circumference of the transfer sleeve. That in the Inlet protruding end of the transfer sleeve can be at the point of contact of the sealing sleeve provided with a metal insert or covered with a metal sleeve and with the Feed line be elastically connected or consist of elastic material itself.

Since in these known supply devices, the sealing collar is arranged on a rotating part of the centrifuge and its sealing lip on the fixed transfer sleeve is applied, there is friction during operation of the Sealing lip on the transfer sleeve, which is particularly useful at higher speeds Centrifugal drum can lead to considerable wear on the sealing sleeve. This wear and tear is increased by the vibrations in the centrifuge occur especially when passing through the critical drum speeds.

At high speeds, the sealing collar must also be used considerable centrifugal forces are absorbed. These have the aspiration that Lift the sealing lip off the transfer sleeve so that there is a gap on the sealing lip open through which the material to be thrown can pass and thus the separated liquid Phase can contaminate.

The invention aims to improve such a supply device, which, of simple training, are subject to little wear and so on should be designed so that even larger amounts of material to be thrown in jets of the centrifugal drum can be supplied without the material being thrown back from the inlet and thereby contaminates the separated phase.

. According to the invention, the transfer sleeve is arranged telescopically on the inlet connection of the feed line and is provided with a flange which lies between the ends of the transfer sleeve and has a sealing ring. The sealing ring is arranged at a distance from an end face surrounding the opening at the inlet of the centrifuge, which is not larger than the largest dimension of a perforation in the sieve drum. With the supply device designed according to the invention, the disadvantages of the known devices are avoided, in particular in that the sealing surfaces do not slide against one another, so that the sealing ring arranged on the flange is not subjected to any noteworthy wear.

In addition, no centrifugal forces act on the sealing ring Sense of enlarging the opening to be sealed. The width of the sealing gap between the sealing ring and the annular surface interacting with it at the opening the centrifuge is on the order of a few tenths of a millimeter. It will therefore, contamination of the separated liquid phase is avoided with certainty.

The feed device according to the invention is particularly then Can be used with advantage when a pulpy material to be thrown from a pressure vessel in bursts is fed directly to the centrifuge and therefore the risk of contamination of the separated liquid phase under the effect of the one that appears in the enema Turbulence is particularly great.

In the drawings, an embodiment of the invention is shown. It shows F i g. 1 shows a section through a sieve centrifuge with a feed device according to the invention, FIG . 2 shows the device according to FIG. 1 on a larger scale, FIG. 3 shows a detail in section along line 3-3 in FIG.

In the exemplary embodiment, the screw screen centrifuge 10 has a frame 12 on which the drive is arranged, which allows the screen drum 16 and the discharge screw 18 to rotate at different speeds. The sieve drum 16 and the Austra ' screw 18 are arranged coaxially to one another. The sieve drum 16 is driven by arms 14 and the discharge screw 18 is driven directly.

The sieve drum 16 has a conical drum 20 which is formed in a known manner from a plurality of coaxial rings 20 a, which are arranged at a distance from one another. The rings are held by webs 22. At the upper ends, the webs 22 are connected to one another by a ring 24. The inner surface of the sieve drum is covered with a sieve 26 made of metal or the like.

The discharge screw 18 mounted coaxially in the sieve drum has a screw drum 28 , on the outer surface of which the screw 30 is arranged. At the narrow end of the discharge screw an insert 32 is provided which encloses a hood 33. The insert 32 has a central inlet opening 34 with an annular radial end face 36 . The inlet opening 34 extends downward to the hood 33 and is there in connection with a number of inlet channels 38 running obliquely downward. The inlet channels 38 end in openings in an annular chamber which lies between the discharge screw 18 and the sieve drum 16 .

On the frame 12, a housing 40 is arranged, which at its upper End has a flat annular surface with a central opening 42, the is in alignment over the inlet opening 34. The inlet nozzle lies on the surface 44, which is firmly connected to the housing 40 with its lower flange.

The upper flange of the inlet connection is with the flange of a feed line 46 connected. It can be expedient to at least partially remove the inlet connection 44 made of transparent plastic so that the flow of the material to be centrifuged can be observed can be.

The centrifugal drum can be connected via a pipe 47. rinsing liquid are supplied in a known manner. According to the invention, a transfer sleeve 48 is provided. In order to avoid turbulence in the material to be centrifuged, the inner, upper edge 50 of the transfer sleeve is beveled. On the outer wall of the transfer sleeve, grooves for sealing rings 52 are provided, which bear against the inner wall of the inlet connection 44 in a sealing manner.

Between the sealing rings 52 on the outer wall of the transfer sleeve 48 there is provided a section 54 with a tapered diameter into which a screw 56 protrudes, which is screwed into the wall of the inlet connection 44 near its lower flange. The screw 56, in the exhaust section 54 are clamped against the sleeve via circuit 48, to fix the position of the axially displaceable sleeve over circuit.

About halfway along its length, the transfer sleeve 48 has a flange 58 , the underside of which is provided with an annular groove into which a flat sealing ring 60 with a lower annular end face 62 is inserted. In order to prevent the sealing ring from being damaged when it comes into contact with the end face of the revolving discharge screw, a material is expediently used for the sealing ring which has a certain flexibility.

The sealing ring 60 is made of plastic, preferably of tetrapolyfluoroethylene with 25 1 / o glass inclusion. This plastic has a low coefficient of friction, which makes it easier to slide, a property that is very desirable in the present case. The inclusion of glass also gives the plastic a high level of wear resistance.

Although plastics are particularly useful, you can use them for the sealing ring of course, other substances can also be used. For example, the Sealing ring made of carbon, of soft metal such as lead, of bearing metal or other solid, water-resistant fabrics are made.

Like F i g. 1 and 2, the sealing ring is adjusted with the aid of the screw 56 in such a way that its end face 62 is slightly above the end face 36 .

According to Fig. 3 , the sieve 26 is provided with sieve openings 64.

In order to prevent substances from passing through the gap between the end face 36 and the end face 62 which are larger than the substance particles which pass through the sieve openings 64, the gap must not be larger than the diameter of the sieve openings. Since the gap between the end faces 36 and 62 has an elongated shape and there is therefore the risk that flat, oversized solid particles will be discharged through the gap in the appropriate position, the end face 62 is expediently placed a little closer to the end face 36 , namely in a distance that is less than the diameter of the sieve openings 64.

The gap between the end faces 62 and 36 accordingly preferably has the gap width a ( FIG. 2), while the diameter of the sieve openings 64 has a value a + (FIG. 3) which is greater than the value a.

Because the transfer sleeve 48 is adjustable in the vertical direction within the inlet connection 44, it can be set at the correct distance from the discharge screw before the centrifuge is started up. The discharge screw for its part is adjustable in the axial direction in order to be able to adapt it to different thicknesses of the sieve 26 and to be able to change the gap between the discharge screw and the sieve shell depending on the type of material to be centrifuged.

The invention is not restricted to the exemplary embodiment described. For example, it can also be used if the axis of the sieve centrifuge is from deviates from the vertical.

The embodiment shown in the drawing can also be modified in such a way that the upper part of the discharge screw 18, which forms the wall of the inlet channels 38 , and the parts above it are omitted. In this case, the ring 24 can be pulled inwards so that it forms a radial annular surface which, similar to the end surface 36 in FIG. 1, lies opposite the end surface 62. The advantages of the device designed according to the invention can also be achieved with such an arrangement.

In the exemplary embodiment described, the end surfaces 36 and 62 are designed as flat surfaces for the sake of simplicity, in order to avoid any possibility of interference that could occur due to a lateral movement of the discharge screw at critical speeds. The end faces can, however, without negating the advantages of the invention, be cooperating surfaces of revolution which rotate about axes of different inclinations. They can also be sawn off upwards or downwards relative to the axis or ribbed concentrically in such a way that they interlock with their ribs and depressions.

Claims (2)

Claims: 1. Feeding device for a conical screw sieve center with a transfer sleeve projecting into the inlet, provided with a flange and connected to the feed line, characterized in that the transfer sleeve (48) is arranged telescopically on the inlet nozzle (44) and with a Sealing ring (52) provided flange (58) lies between the ends of the transfer sleeve (48), the sealing ring (52) being set at a distance (a) from an end face (36) surrounding the opening at the inlet of the centrifuge which is not greater is the largest dimension (a +) of a perforation in the sieve drum. 2. Device according to spoke 1, characterized in that the distance (a) is not greater than the diameter of the largest circle that can be inscribed in an opening of the sieve drum. 3. Device according to claims 1 and 2, characterized in that the end face of the sealing ring (60) is flat. 4. Device according to claims 1 to 3, characterized in that the sealing ring (60) consists of plastic, preferably of glass-reinforced plastic. 5. Device according to claims 1 to 4, characterized in that the inlet opening (34) is arranged on the small end face of the screw drum ( 28) and the transfer sleeve (48) engages in the inlet opening (34). 6. Device according to claims 1 to 5, characterized in that the screw drum (28) is adjustable in the axial direction. 7. Device according to claims 1 to 6, characterized in that an opening concentric to the inlet opening (34) is provided in the centrifuge housing and an inlet connection (44) is arranged above this, in which the transfer sleeve (48) lies. 8. Apparatus according to claim 7, characterized in that the transfer sleeve (48) is sealed against the inlet connection (44). 9. Device according to claims 7 and 8, characterized in that the transfer sleeve (48) can be determined in the inlet connection (44). Considered7 publications: German Patent Specifications No. 1 059 841, 1060 326; German interpretative document No. 1081 384.