DE1068602B - - Google Patents

Description

GERMAN

The invention relates to a device for destroying the structure of ceramic and the like plastic masses in a screw extruder with einöm behind the press screw transversely to the feed direction of the mass strand vibrating, causing a thixotropic effect in the mass, lattice-like organ. The known devices of this type can be generated by the screw Destroying structures, but at the same time new structures can appear, so that no completely homogeneous Earth strand arises. A number of proposals have therefore become known to prevent a structure formation is based, however, without reliably achieving the desired goal.

It is known to introduce vibrations into the mass by means of external and internal vibrators, the vibration organs acting on the mass strand either in the axial and / or in the radial direction. To achieve vibrations in the mass strand, among other things, a device has also been proposed in which an electromagnetic external vibrator cooperates with a vibrating element provided inside the mass strand, which consists of knife-shaped lamellae which can also cross each other in a grid-like manner. In this device, the distance between two lamellae or between the lamellae and the wall is approximately Vs of the beam diameter. The lamellas themselves and the entire vibrating device have a length of almost ² / s of the diameter of the strand, measured in the direction of advance of the strand of mass.

Another proposal makes use of more varied ones Unbalance vibrators as vibration exciters for the destruction of structures on screw extrusion presses.

Neither the devices of the first-mentioned nor those of the second-mentioned type can do the desired thing To produce result, regardless of whether the vibrator as a magnetostrictive vibrator, as an electromagnetic vibrator or are designed as unbalance vibrators. In all of these versions it has been shown that only a small Area is affected directly on the surface of the vibrating parts. Only those parts of the Mass strands that are directly on or at a short distance from the vibrating parts are influenced by them. This is because that the ceramic mass in the state in which it is processed in the screw press represents a good vibration damping agent. If it is further taken into account that the amplitudes of the mentioned Vibrators are very small and only a fraction of a millimeter, depending on tem resistance, the pipe and the mass for external vibrators, the device located in the mass for internal vibrators to destroy the structure

ceramic and similar plastic masses

in a screw extruder

Applicant:

Soest-Ferrum Apparatebau GmbH,
Düsseldorf-Oberkassel, Hansaallee 159

Hans-Werner Hagen, Siegen,

and Wilhelm KirchhofE, Düsseldorf,

have been named as inventors

Oppose the vibrating organ and the mass of the vibration, so it necessarily follows that the known vibrators the structure of the Influence the mass too little to destroy the structures and the new formation over the entire cross-section of structures to prevent. While it has been recognized that it is necessary in the crowd to produce the thixotropic effect. However, this is consistently only in the known devices the edge zones of the vibrating organs have been achieved, so that a not inconsiderable part of the mass strand, viewed in cross section, has remained without the desired effect.

Another proposal also achieves the required level Effect not. According to this, the vibration transmitter consists of an inner and an outer one pipe section tapering in the direction of mass transport. The two pipe pieces are connected to one another by cross-shaped webs and by means of themselves vertically extending rods approximately in the middle of the Pipe cross-section held. Both the vertically arranged connecting webs between the pipe sections as well as their vertical support rods, with which the connection with the vibrators is established move during the oscillation process only in the direction of their longitudinal axis, so they act similarly to a stationary obstacle and cause thereby creating new structures that they cannot trigger the thixotropic effect. The thixotropic At best, the effect can be in the edge zones and the immediate vicinity of the pipe sections and set transverse webs without, however, making it impossible to form a structure over the entire cross-section is made. This results at least from the

90S 647/247

3 4

Wall parts of the cross-section located in a vertical position again except for the original cross-tubular shape Vibration transmitter to narrow its retaining cut. The invention therefore provides rods and the vertically arranged connection that the cross-sectional area behind the lattice-like webs between the pipe pieces. Since the Schwin organ is smaller again, but larger than the cross generators as a pipe section is the inside 5 sectional area of the original mass strand. borrowed mass strand moved up and down, occurs similarly in the device at least two

As with the already mentioned vibrating lamellae, lattice-like organs connected in series, do not see any detachment of small chips of the mass, it is advantageous according to the invention to move the Orstrands out of phase and not apply these chips to other gane and insert them into one part of the strand. Such a machining of the io phase shift of 180 ° at a small distance from the strand is, however, still essential for the destruction of one another,
of the structures. . A further improvement can thereby be achieved

On the basis of known devices for comminuting, the lattice-like organ is connected to a vacuum disturbance of the structure of ceramic and other plastic pumps for evacuating the cut chips and shear masses in a screw extruder with 15 during cutting.
one behind the press screw transversely to the feed In the figures, the invention is illustrated in some orientation of the mass strand vibrating, in the management examples. Show it
Mass a thixotropic effect causing, lattice Fig. 1 and 2 the elementary process of cutting

like organ, the invention provides that the grid and simultaneous pressing at two different like organ no such with the ground strand in 20 cross-sectional shapes of the bars of the lattice-like Having connecting parts, whose longitudinal organ according to the invention,

axis in or approximately in the direction of vibration.
on other strand parts again applying grid- Fig. 4 a cutting element with horizontally lying

rods, which in a substantially different way from the Schwin- 25 lattice rods,

direction deviating direction and FIG. 5 shows a further embodiment with horizontal

with smaller distances from each other evenly right lattice bars,

are distributed over the strand cross-section, as the Fig. 6, a cutting member, the bars of a

Oscillation stroke of the lattice-like organ is. Form meshes,

It has been known for a long time that from FIG. 7 two bars with a triangular transverse worm incoming material before entering the section,

Mouthpiece mounted in the press head movable Fig. 8 two bars, the cross-section of a

To let the grid system pass, which is formed in a constant circular segment,
horizontal or vertical movement transversely to the Fig. 9 two circular bars,

direction of movement of the strand is to use 35 Fig. 10 two oval bars,
this lattice the structure generated by the screw Fig. 11 a longitudinal section through a device

destroy door. The known grids of this type are used with a grid-like organ in application to a vacuum press in a schematic representation, which extends transversely through the press head.
Kenden carrier held, which, in contrast to Fig. 12, a lattice mounted in a rubber tube

Grid itself only movements in its axial direction, 40-like organ,

but not transversely to the movement of the mass strand from Fig. 13 a grid-like organ, supported in a

leads. This has the consequence that the mass of the Trä rubber tube, which is stiffened by ring-shaped inserts ger pushed past, the new structures and is
Earth strand caused. FIG. 14 shows an enlarged detail from FIG. 16.

In order to avoid that any drive- +5 Fig. 1 illustrates the operation of the elements for the lattice-like organ in the closed lattice bars, the longitudinal axis of which is substantially different from the These chambers protrude through which the mass strand deviates from the direction of oscillation. The grid-like orhin wanders through, the lattice-like organ can consist of rods with a triangular cross-section, further embodiment of the invention in a rubber as shown in FIGS. 4 and 5. From the trellis be stored, the with the grid-like organ 5 ° -like organ are only for the sake of clarity performs the vibrations. The two bars 1 are preferably shown. The grid-like organ Rubber tube stiffened with an insert, around the over- is printed vertically in the direction of the arrow up and down inside, which the compressed mass causes, moves away. With 2 the one from the screw extruder is to be taken up to be able to. - incoming mass strand called. He moves in

In another embodiment, the rubber tube can move from left to right from the direction of arrow b. In this case, a reinforcement sheathing in the same direction or intersecting the vertically moving bars 1 mass-regular lay surrounded. Finally, the chips 3 with the front edges 4 are removed and, as a further embodiment, they are pressed in such a way that the rubber tube with the rear side 5 to the draining mass rubber tube again has an annular insert. The strand 6. The same process is shown in Fig. 2 for an advantage of this form is that when the ⁶⁰ lattice-like organ is moved, the stiffening is not composed of round bars lattice-like organ. The way of working is the same in both movements, just a sliding movement in each case.

next stiffening ring learns. As a result, FIGS. 3 to 6 show different embodiments

Reinforcement particularly durable and energy-saving. shapes of the lattice-like organ, namely FIG. 3 shows

It is also useful ^{to arrange the grid-like 6} 5 a cross-section through a grid-like organ according to organ in an extension of the mass leading to FIGS Are arranged. The effective transverse bars 1, reduced horizontally by the bars, are supported in order to almost compensate for the bending of the section of the pipe due to the expansion. But it is not necessary to prevent the strand 7 °. The supports are denoted by 23.

Claims (5)

Of course, other forms of support are also possible. In the embodiment according to FIG. 6, a mesh-shaped cutting element 8 is achieved by the bars, which in the same way as those described above, intersects the strand of mass and presses it to achieve the thixotropic effect. 7 to 11 show different cross-sectional shapes of the bars 1. Thus, FIG. 7 shows a triangular cross-sectional shape, as it is already shown in FIG. FIG. 8 shows a triangular profile similar to that of FIG. 7, but with a rounded cutting surface. Compared to the profile according to FIG. 7, this has the advantage of lower flow resistance. Further cross-sections are illustrated in FIGS. 9 and 10. FIG. 11 shows the overall structure of a screw extruder for preparing and shaping ceramic and other plastic masses, which is equipped with bars according to the invention. In the tube 20 of the screw press, the rear part of which is not shown for the sake of clarity, the screw 21 moves the mass in the direction of arrow c. The device for destroying the structure is connected to the press part 20 via the cone 24. It consists of the lattice-like cutting element 25, which in the example shown is designed as a bar lattice according to FIG. 4 or 5 and the bars of which have a circular cross-section. The grid is held by means of the inner ring 26 and the outer ring 27. The push rod 30 transmits the movement of the connecting rod 29 to the outer ring 27. To absorb the axial pressure, the outer ring 27 is articulated by the lever 31 to the conical tube part 24 of the screw press. The connection between the tube 34 and the mouthpiece 35 is achieved by a rubber tube 32, which at the same time ensures the seal between the inner and outer rings 26, 27. The rubber tube is fastened with clamp straps 33 on the tube 34 or on the mouthpiece 35. The method of operation of the device is as follows: The ceramic mass 2 is conveyed in the tube 20 by the screw 21 in the direction of the arrow c against the grid 25, which is moved vertically up and down. The grid is moved by the motor 28 via the connecting rod 29 and the tie rod 30. The mass 2, as shown in FIGS. 1 and 2, is machined and then immediately pressed again, namely by the grid-like member 25 against the one resistance performing, constricting mouthpiece 35 works. Fig. 11 shows that the diameter of the screw 21 can be smaller than the exit diameter of the mouthpiece 35. The reason is as follows: With a conventional press for fine ceramic materials with a screw diameter of 250 mm, a strand of about 130 to 140 mm diameter can be drawn. In many cases, you limit yourself to drawing a maximum of 120 mm in diameter. When building a porcelain press with a grid-like cutting element with a diameter of about 450 mm and an expansion of the component 24 adjoining the screw tube 20 in a corresponding manner, one can use the same extrusion press by narrowing the cross-section behind the grid-like element 25 to 320 mm in diameter Pull a strand with a diameter of about 320 mm without any problems. In addition, the mass throughput per unit of time increases considerably. The strand with a diameter of 320 mm emerges from the press at a speed of about 30 to 60 cm / min, depending on the composition of the mass. If the spacing of the bars 1 from one another is 8 mm, the stroke of the cutting device 25 is 17 mm and the speed of the drive motor 28 is 2000 rpm, a grid 25 with a diameter of 450 mm cuts the strand into chips of 0.04 mm or up to 0.08 mm thick. In FIG. 12, the connection of the lattice-like cutting element 25 to the press is shown in a simplified representation. The peculiarity of this illustration compared to FIG. 11 can be seen in the fact that the rubber tube 32, which is enclosed by the inner ring 26 and the outer ring 27, is provided with an insert 50 made of cord fabric or of steel wire fabric. As shown in FIG. 11, the rubber tube 32 is fastened to the tube 34 or the mouthpiece 35 by means of clamp straps 33. 13 shows another embodiment of the rubber tube, also in a simplified representation. The rubber tube 32 is also enclosed by the inner ring 26 and the outer ring 27. Both rings move in the direction of the arrow α. The tube is in turn fastened with clamp straps 33 on the tube 34 or the mouthpiece 35. The rubber tube 32 has been armored with inserts. As shown in the left-hand part of FIG. 13, these inserts are designed as rings 60 made of solid material with a square cross-section. In the right part of FIG. 13, this insert is shown as an annular wire rope 61, the embedding of which can be seen in detail in FIG. 14 in an enlarged illustration. Patent claims: 1. Device for destroying the structure of ceramic and similar plastic masses in a screw extruder with a screw behind the press transverse to the feed direction of the Vibrating mass strand, in the mass a thixotropic «! Effect causing, grid-like Organ, characterized in that the grid-like organ has no such with the mass strand has related parts, the longitudinal axis of which runs in or approximately in the direction of oscillation, and from the strand by chips lifting and on other strand parts again applied lattice bars, which in a run significantly different from the direction of oscillation and with smaller Distances from each other are evenly distributed over the strand cross-section than the oscillation stroke of the grid-like organ is. 2. Lattice-like organ according to claim 1, characterized by its design as a mesh (25) with bars (1) running transversely to the direction of oscillation. 3. Apparatus according to claim 1 and 2, characterized in that the grid-like member (25) in a rubber tube (32) is mounted. 4. Apparatus according to claim 3, characterized in that the rubber tube (32) with a Insert (50) is stiffened. 5. Apparatus according to claim 3, characterized in that the rubber tube (32) of one Reinforcement sheathing is surrounded in Lang or regular lay.