DE4420976C2 - Method and device for the controlled transport of thickened fibrous material from a pressurized space - Google Patents

Description

The invention relates to a method for the controlled transport of thickened fiber according to the preamble of claim 1 and on a Device for its implementation.

Procedure of the above Kind are used in plants for the processing of fiber material, especially of waste paper. In the course of such systems, it is often necessary to Fibrous material in a thickened form by a working under positive pressure Treat high temperature processes. The pressurized ones must be used Devices are sealed against the environment. Particular difficulties arise at the openings from which the pulp emerges from the apparatus. Unlike fluids that flow well cannot be reliably measured by a pressure Remove normal throttle point. Rather, it is necessary to find a suitable one Conveyor to use that the thickened substance from the higher to the transported lower pressure. The problems mentioned can already occur at Fibers with a solids content of about 15% occur, the Flow properties from the composition of the fabric and the type of fibers depend.

As is known, such conveyors work with a cellular wheel or one intermittently operated lock and are thus able to differentiate the rooms Pressure to seal against each other.

Such solutions with cellular wheel or other locks are complex and at risk of wear. It has been shown that the conveyor devices used cannot always do their job well with the substances mentioned. The reason  for this lies in the unevenness of the material, that is, a certain brokenness that understandably the function complicates. The control behavior is also for the Conveying volume in such conveying devices is unfavorable because the conveying is too fast Loss of print media increased, as did the upstream one High temperature treatment negatively affected and too slow conveying to Blockage of the overpressure system can result in what is considered an extremely undesirable form the seal can be seen.

Furthermore, different funding is available from the prior art devices known that both screw conveyors and Have sealing body at the end of the conveyor line.

Such a device is known from DD-PS 13 23 89, which, however, from a room of lower pressure into a room promotes higher pressure, which at the end of the device orderly flap the inflow of gas from the room higher Prevent pressure in the room of lower pressure.

DE-GM 85 90 051 relates to a conveyor device with a Screw conveyor, with a drainage zone provided at the end is. To ensure the drainage of the material to be conveyed Counter pressure elements provided.

According to DE-OS 42 32 684, the seal between two rooms, which are connected by the conveyor, by a Fabric plug achieved by the different Slope of the screw conveyor is generated.

DE-OS 21 08 911, DE-OS 23 63 405 and DE-OS 27 56 737 show each a closing device in the form of a truncated cone at the end of a screw conveyor.

The object of the invention is to create a method with which from a room of higher pressure, the one inside is evenly and reliably Thickened fiber can be transported out and at the same time a good one Sealing between the room under higher pressure and the itself subsequent can be done under lower pressure.

This object is completely achieved by the characterizing part of claim 1.

The device claims 11 to 18 give advantageous devices for Implementation of the procedure.

With the help of the method according to the invention, the flow of the thickened Fibrous material reliably held under counter pressure, because the sealing body Fabric plug supported. The material is brought from the conveying zone into the compression zone and heavily compacted there. Depending on the version and operating conditions, the Grafting of the fibrous material also in the conveying zone, that is between the Use conveyor elements. In the compression zone, the transport mainly takes place through the material pressing out of the production zone instead. The funding body of the production zone is advantageously designed for the maximum throughput, since with the help of the invention used sealing body is also a good plug formation is guaranteed if the amount of substance is less. If e.g. B. the material flow, for what reasons whatsoever, the sealing body becomes smaller when there is a constant Move force against the direction of exit of the fabric and thereby also with smaller ones Amount or even loss of material enable a reliable seal at this point.  

An improvement of the method according to the invention is possible through a Relative movement of the sealing body and the fiber material passing through. It follows a friction between the fabric and the sealing body, which leads to an equalization and thus leads to better sealing in the outlet opening.

The invention and its advantages are explained with reference to drawings. It shows

. Figure 1 shows a suitable apparatus for carrying out the method according to the invention;

Figure 2 shows a sealing body in detail.

Fig. 3 schematically: device with the stuffing tube pivoted away.

In Fig. 1 is cut in a side view, very schematically shown a conveying device 3, and using the example of a screw conveyor.

The method is illustrated using a typical example in which there is an overpressure of approximately 1.7 bar in the first room 1 compared to the surroundings, the second room 2 . In the first room 1 there is thickened, about 130 ° C hot waste paper fiber S with a solids content of 20 to 25%. Such a substance is known to be crumbly or crumbly. The method according to the invention now takes place as follows:
The substance S passes through the filling opening 9 into the conveying zone 5 of the conveying device 3 . This works with a screw conveyor 7 in a substantially closed, here partly cylindrical, partly conical housing 8 , the screw with conveyor elements 10 , for. B. coils is provided. After passing through the conveying zone 5 , the material enters the compression zone 6 , which begins at the latest where the conveying elements 10 end and a stuffing tube 13 connects. The filling of the device with fabric is indicated by lines 12 and 12 ', respectively, according to line 12 , the plug 11 already forms in the last section of the screw conveyor 7 and according to 12 ' only in the stuffing tube 13 . In the compression zone 6 forms or condenses the plugs 11 in that material 5 is tracked from the production zone. The stuffing tube 13 is cylindrical here, but can also be conical. The sealing body 4 is located at the outlet opening. In the space between the sealing body 4 and the outlet opening, an annular passage surface for the substance S 'is formed here. At this point, the fibrous material can take the form of a sealing collar that constantly slides out. The force F is indicated by an arrow.

A truncated cone-shaped sealing body 4 is shown in more detail in FIG. 2, in particular the angle (alpha) between the surface 14 and the axis of the sealing body 4 . The surface 14 can - as already mentioned - be roughened in order to achieve a certain homogenization in contact with the exiting substance S ', whereby the sealing effect can be improved. This effect can be increased by additionally setting the sealing body 4 in rotation. It is also possible to design the roughness of the surface 14 in such a way that grooves 15 are formed which cause the material to be deflected by the fact that they do not run in the axial direction but at an angle (beta) to it.

In order to facilitate cleaning or maintenance work, the stuffing tube 13 can be pivoted sideways, in such a way that the plug 11 remains inside ( FIG. 3). After closing and when restarting, the plug 11 is then immediately available for sealing again, so it does not have to be formed first. This means that restarting is possible with almost no loss of steam.

Claims (18)

1. A method for the controlled transport of thickened fibrous material (S) from a pressurized first space ( 1 ) into a second space ( 2 ) in which there is a pressure which is at least 0.2 bar lower with a conveying device ( 3 ) for discharge of the thickened fibrous material (S) from this space ( 1 ), characterized in that
that the conveying device ( 3 ) is designed in such a way that it conveys at least through a conveying zone ( 5 ) into a subsequent compression zone ( 6 ) and then the fiber material compressed in this way in the form of a plug with an annular cross section doses into the second space ( 2 ) is carried out. 2. The method according to claim 1, characterized, that the thickened fibrous material (S) has a solids content of at least 15% having. 3. The method according to claim 1 or 2, characterized, that the thickened fibrous material (S) consists predominantly of waste paper and water. 4. The method according to claim 1 or 2, characterized, that the thickened fiber (S) predominantly from freshly boiled pulp and There is water.   5. The method according to any one of the preceding claims, characterized in that there is a temperature above 100 ° C in the pressurized first space ( 1 ). 6. The method according to any one of the preceding claims, characterized in that the fiber plug ( 11 ) in the conveyor ( 3 ) with the aid of a screw conveyor ( 7 ) and a maximum 2 meter long compression zone ( 6 ) is formed. 7. The method according to any one of the preceding claims, characterized in that the fiber plug ( 11 ) in the conveyor ( 3 ) with the aid of a screw conveyor ( 7 ) and a minimum 0.1 meter long compression zone ( 6 ) is formed. 8. The method according to any one of the preceding claims, characterized in that a sealing body ( 4 ) with an adjustable force (F) is pressed against the fiber plug ( 11 ), the size of which depends on the excess pressure in the first space ( 1 ). 9. The method according to claim 8, characterized in that the force (F) is proportional to the excess pressure in the first space ( 1 ). 10. The method according to any one of the preceding claims, characterized in that the emerging substance (S ') relative to the sealing body ( 4 ) has a peripheral speed of at least 0.1 m / sec. 11. Conveying device for carrying out the method according to one of claims 1 to 10, characterized in that it has a substantially closed housing ( 8 ) with a filling opening ( 9 ) and a round outlet opening and one in the housing ( 8 ) rotatable by a motor Screw conveyor ( 7 ) whose conveyor element ( 10 ) ends at a distance of at least 0.1 m in front of the outlet opening and that the sealing body ( 4 ) which is displaceable against the emerging fiber stream (S ') has a conical or frustoconical shape and is thus attached that its diameter increases in the conveying direction, means being provided to press the sealing body against the outlet opening with an adjustable force (F). 12. Conveying device according to claim 11, characterized in that the conveying element ( 10 ) ends at a distance of a maximum of 2 m before the outlet opening. 13. Conveyor device according to claim 11 or 12, characterized, that the maximum sealing body diameter is larger than that of Outlet opening. 14. Conveying device according to claim 11, 12 or 13, characterized in that the conical surface of the sealing body ( 4 ) has an angle (alpha) of 15 to 45 ° to the axis. 15. Conveying device according to claim 11, 12, 13 or 14, characterized in that the sealing body ( 4 ) is rotatably driven about its axis. 16. Conveying device according to one of claims 11 to 15, characterized in that the sealing body ( 4 ) has a surface ( 14 ) with a roughness of 0.1 to 2 mm roughness. 17. Conveying device according to one of claims 11 to 16, characterized in that the sealing body ( 4 ) has grooves ( 15 ) with a direction which extends obliquely to the axis at an angle (beta) of over 10 °. 18. Conveying device according to one of claims 11 to 17, characterized in that a region of the housing ( 8 ) between the end of the conveying element ( 10 ) and the outlet opening is designed as a stuffing tube ( 13 ) and can be pivoted sideways or downward with the rest of the housing ( 8 ') connected is.