EP2892856A1

EP2892856A1 - Extruder unit and dryer equipped therewith

Info

Publication number: EP2892856A1
Application number: EP13759494.1A
Authority: EP
Inventors: Sven PENKWITT; Karl-Heinz BECHTL
Original assignee: Huber SE
Current assignee: Huber SE
Priority date: 2012-09-10
Filing date: 2013-09-05
Publication date: 2015-07-15
Also published as: US9827704B2; DE202012012605U1; BR112015002087A2; WO2014037424A1; DE102012108404A1; US20150239164A1

Abstract

The invention relates to an extruder unit for a dryer (2) for biomass, in particular slurry, wherein the extruder unit (1) has a surface section (4) for the biomass to pass through and a plurality of apertures (3), wherein the extruder unit (1) comprises a base support (5) which is connected by means of a connecting section (6) to a driving element (7) and can be driven by means of the driving element (7) about an axis of rotation (8) and relative to the surface section (4), wherein the base support (5) comprises at least one support arm (9) having at least one scraper blade (10) which during a rotation of the base support (5) follows the shape of the face of the surface section (4) facing the scraper blade (10). According to the invention the base support (5) also comprises at least one breaker element (11) having at least one scraper blade (10) which during a rotation of the base support (5) also follows the shape of the face of the surface section (4) facing the scraper blade (10) and during the rotation of the base support (5) effects a crushing of constituents contained in the biomass which are retained by the surface section (4). The invention further relates to a dryer having at least one corresponding extruder unit.

Description

Extruder unit and dryer equipped therewith

The present invention relates to an extruder unit for a drying plant for biomass, wherein the extruder unit has to be passed by the biomass and having a plurality of perforations surface portion, wherein the extruder unit comprises a base support which communicates via a connecting portion with a drive element and on the Drive element about a rotational axis and relative to the surface portion is driven, wherein the base support comprises at least one support arm with at least one doctor blade, which follows the rotation of the base support the shape of the doctor blade facing surface of the surface portion. In addition, a drying plant for biomass is proposed, wherein the drying plant has at least one drying surface with a plurality of passages, wherein the drying plant comprises at least one air supply for supplying drying air in the region of the drying surface, and wherein the drying plant has at least one extruder unit, with their Help the biomass can be applied to the drying surface, wherein the drying surface and the extruder unit are mounted relative to each other movable.

Corresponding, equipped with an extruder drying units are known in the art and are usually the drying of pasty biomass, such as (sewage) sludge. For this purpose, the drying surface and the extruder unit are mounted so as to be movable relative to one another, wherein the relative movement is preferably coordinated so that the biomass is deposited in a serpentine shape after leaving the extruder unit and as an endless strand on the drying surface. The drying surface is in turn associated with an air supply, with the aid of which warm and / or dried drying air can be conveyed through the drying surface provided with corresponding air passages. The track In this case, contact air comes into contact with the biomass and causes it to dry to a desired dry substance.

The extruder unit usually has a perforated plate with a plurality of perforations, through which the biomass is pressed by applying a corresponding overpressure and thereby brought into the desired strand shape, which promises a high surface area and thus rapid drying of the biomass.

Since sludge in addition to unproblematic fines also contains coarse material (fiber material, hair, etc.), which could cause clogging or picking the perforations of the perforated plate, it has been proven to equip the extruder unit with a blade unit. The blade unit in turn has one or more doctor blades, which are movable by means of a drive relative to the perforated plate and thereby cause a shearing of accumulated in the openings coarse materials.

However, it has been found that the known blade units, especially in the treatment of biomass with a high solids content (dry matter> 30%) are no longer able to ensure the proper operation of the extruder unit. Reason for this are coarse materials, such as highly compressed sludge lumps, which are not caught in the perforations of the perforated plate due to their size, but are moved only by the blade unit like a snowplow along the surface of the perforated plate. As a result, the full passage opening of the openings for the passage of the biomass is no longer available (since the coarse cover a part of the same), so that it comes as a result to a reduction of the extrusion performance.

The object of the present invention is therefore to propose an extruder unit and a drying plant equipped therewith, which mentioned problem.

The object is achieved by an extruder unit and a drying plant with the features of the independent claims.

According to the invention, the extruder unit now comprises a surface section having a plurality of perforations, which is formed for example by a, preferably circular, perforated plate (the openings themselves preferably have a circular, oval or cross-shaped or star-shaped cross section). The area section in turn serves for the described strand formation of the biomass supplied via a corresponding feed (for example a pipe or a hose). Likewise, at least one doctor blade is provided, which is attached to a rotatable base support or part thereof. The doctor blade is also aligned with respect to the surface portion such that it follows the shape of the doctor blade facing surface of the surface portion upon rotation of the base support. In addition to the shearing or cutting of accumulated in the openings of the surface portion impurities (fibers, hair, etc.), the doctor blade also has the task of providing the biomass when passing through the openings with a kind of predetermined breaking point. In other words, the biomass flow when passing through the openings through the scraper blade or cut repeatedly and then connects immediately afterwards with the inflowing biomass flow, whereby corresponding sections with lower density or strength arise. Now falls the biomass flow, which has passed through the openings (and therefore usually in the form of a plurality of single strands) of a drying surface equipped with the extruder unit drying plant on a deeper further drying surface or in a corresponding collecting container, so cause the predetermined breaking points that the individual strands disintegrate into individual fragments (so-called pellets). This is especially for further processing of the dried biomass, for example in the form of a Combustion, of considerable advantage. Finally, the drive of the basic carrier preferably takes place via a drive element, for example a drive axle, which is connected to a drive and to the basic carrier or a connecting section thereof.

As a result, the doctor blade is thus guided along the surface of the surface section facing the doctor blade (preferably by a rotational movement of the base support) and performs the function of the blade carrier described above and known from the prior art.

In addition, the invention provides that the base support comprises at least one breaker element, which is formed integrally with the base support or connected thereto. The breaker element, which likewise follows the shape of the surface of the surface section facing the doctor blade when the base support is rotated, now causes the coarse particles retained by the surface section to be crushed by the doctor blade only along the surface section without passing through it. For this purpose, the breaker element has an active surface facing the surface section, wherein the distance between the active surface and the surface section should decrease counter to the direction of movement of the base carrier. In this case, coarse materials first come into contact with the crusher element between said active surface and the surface section. Since the distance between the active surface and surface portion decreases counter to the direction of movement of the base support and thus also of the crusher element, a kind of clamping of the corresponding coarse material and finally a comminution of the same takes place. In other words, the active surface of the crusher element opposite the surface portion should be set opposite the surface portion, so that coarse particles are increasingly pressed against the surface portion during contact with the crusher element and are thereby comminuted. Finally, at this point showed that the crusher element not only serves for the comminution of hard constituents of the biomass. Rather, also components with a tough, clay-like consistency (for example, pressed in a (chamber filter) press mud components) are detected and pressed or passed through the openings of the surface portion. In other words, the crusher element ensures that all the components that are not conveyed through the perforations due to their shape and / or consistency, detected by the crusher element, possibly crushed and finally pressed or pushed through the openings of the surface portion ,

It is advantageous if the breaker element is cylindrical. The breaker element can be present, for example, as a roll rigidly connected to the base carrier, which is guided along the surface section. The roller can z. B. have a central axis extending radially from the base carrier to the outside. The roll surface forms in this case the said effective surface of the breaker element, which, in interaction with the surface section, causes a comminution of correspondingly large coarse materials of the biomass. The roller can be made of metal or else a plastic. Furthermore, in addition to a cylindrical shape and a cone (dull) form conceivable. The roller may also have a smooth or roughened, for example, corrugated, surface to ensure that the corresponding coarse materials are not simply pushed in front of the roller due to the friction occurring, but are reliably crushed by this.

It is also extremely advantageous if the crusher element is mounted rotatably about an axis of rotation on the base carrier. In particular, if the crusher element is the described roller, the friction between the roller surface and the surface section can thereby be reduced (this is advantageous if the crusher element bears directly against the surface section). It is also advantageous if the axis of rotation or a central axis of the (possibly non-rotatably mounted on the base support) crusher element extends parallel to each of the crusher element adjacent region of the surface portion. The distance between breaker element and surface section is constant in this case over the entire extension of the breaker element. In other words, it is advantageous if the surface portion is present as a flat perforated plate and the breaker element is perpendicular to the axis of rotation of the base support or perpendicular to a central axis of the perforated plate.

It is likewise advantageous if the breaker element has a play that is perpendicular to the axis of rotation, so that the distance between the breaker element and the surface section adjacent thereto can be changed. This can be particularly advantageous if the biomass contains hard and edged substances (eg small stones) which tend to tilt between a rigid breaker element and the surface section. If the crusher element now has the abovementioned clearance, then it can avoid corresponding constituents of the biomass, so that the comminution of these components gradually, i. H. by repeated contact with the crusher element, can take place. Alternatively, however, it is also possible to store the breaker element completely or at least almost free of play in order to effect a direct comminution of all coarse materials present in the biomass. Breaker element and surface section should be dimensioned in this case, in order to avoid damage to these components.

Also, it is extremely advantageous if the doctor blade with the surface portion forms an angle whose magnitude has a value between 75 ° and 105 °, preferably a value between 80 ° and 100 °, particularly preferably a value between 85 ° and 95 °. The scraper blade should therefore be in the area in which it rests against the surface section, as low as possible run right to this. As a result, it can be ruled out that coarse materials are clamped between the surface section and the doctor blade and lead to damage to the possibly sharp-edged doctor blade or knife surface. The scraper blade in this case primarily serves for shearing off impurities accumulated in the perforations of the surface portion, such as, for example, textiles, fibers or hair accumulations. Finally, the comminution of coarse matter takes over the breaker element (s) according to the invention.

In addition, it is advantageous if the base support comprises at least one brush element, which also follows the shape of the surface of the surface section facing the doctor blade during a rotation of the base support. The brush element is preferably located directly against the surface portion and extends radially outwardly from a central axis thereof. As a result, it comes with rotation of the base support to the said axis in contact with the entire surface portion and causes a cleaning of the same. The brush element is preferably also mounted on a support arm of the base support, wherein the support arm may be part of the base support or attached thereto.

It also brings advantages when the doctor blade and / or the breaker element and / or the brush element are releasably secured to the base support. This is a, z. B. wear-related, replacement of said components at any time, without having to replace the entire extruder unit. The components could be bolted to the base support, the corresponding screws could either engage in a thread of the base support or the respective component. It is also conceivable to use the respective screw as an axis, on which finally the corresponding component, for example oscillating about the axis, can be suspended.

In this context, it is extremely advantageous if the doctor blade and / or the brush element in each case between two adjacent shark are stored sections of a support arm of the base support. For example, it is conceivable to form the support arm U-shaped, wherein the doctor blade or the brush element is held between the two legs and the base of the U-shape formed by the base support or connected thereto, for example welded, is.

Likewise, it brings advantages when the support arms extend radially outward with respect to a longitudinal axis of the drive element. In a plan view of the base support, this therefore preferably has a plurality of outwardly projecting support arms, wherein one or more may be equipped with a doctor blade and one or more with a brush element. Likewise, one or more support arms may be present, to which the breaker element is attached, which of course can also be arranged directly on the base support.

As already mentioned initially, it is finally advantageous if the surface portion is formed as a perforated plate. The perforated plate preferably has a circular shape, so that the surface of a doctor blade, a brush element and / or a breaker element can be painted, which extends from a central axis of the perforated plate radially outward.

Likewise, it is advantageous if the drive element is designed as a drive axle, which preferably penetrates the surface section in the center. In addition, it has proven useful when the surface portion is pressed by means of a thrust bearing against the doctor blade to ensure that the doctor blade is always completely applied to the surface portion. For this purpose, it is of course to be preferred that the thrust bearing is placed on the side facing away from the doctor blade side of the surface portion and presses the perforated plate against the doctor blade. The thrust bearing may comprise, for example, a threaded-nut combination, wherein tightening the screw an increase of the contact pressure on the thrust bearing causes. As a result, with the help of the screw, the force can be adjusted, with which the doctor blade rests against the surface portion. A wear-related increase in distance between the doctor blade and the surface section can therefore be taken into account at any time.

Finally, the drying installation according to the invention is distinguished by the fact that it has an extruder unit with one or more of the features described so far or below (where the individual features can be combined as desired with the feature of the crusher element according to the invention, as far as this is technically possible).

In this case, it is advantageous if the drive element (for example in the form of a drive axle), which is connected to the base carrier, is connected to a drive whose direction of rotation can be reversed. If, during operation of the extruder unit, a decrease in the extruder output or a clogging of the described surface section are detected, it would be possible in this case to reverse the direction of rotation of the drive. This can finally cause a loosening of the clogging or a dissolution of canted components of the biomass with a component of the extruder unit, so that the risk of failure of the extruder unit can be further reduced. In other words, it may be advantageous if the drying installation has a reversibly drivable drive (eg in the form of an electric motor), so that the direction of rotation of the drive can be reversed with the aid of a control and / or regulating unit. For this purpose, the control and / or regulating unit can be in communication with one or more sensors which can detect, for example, a blocking of the drive element. By appropriate (if necessary repeated) reversal of direction of the drive, the blockage can be finally solved, so that a possible maintenance-free operation of the extruder unit of the drying plant is ensured.

Further advantages of the invention are described in the following exemplary embodiments. play described. Show it:

1 is a perspective view of a section of a drying plant for sludge,

2 shows a known blade unit of an extruder unit for a

Drying plant according to Figure 1,

FIG. 3 shows a partially sectioned side view of an extruder unit according to the invention,

FIG. 4 shows the top view of the extruder unit shown in FIG. 3, and FIG

Figure 5 is a plan view of an alternative extruder unit.

FIG. 1 shows a schematic diagram of a drying plant 2 for sludge 12 (whereby sludge 12 is chosen only as an example of a biomass to be dried and is not to be understood as limiting).

The drying plant 2 generally comprises a drying surface 19 with a plurality of only indicated passages 21, which allow a passage of drying air, which in turn is introduced from one, for example below the drying surface 19, arranged air supply 20 in the drying plant 2. In the example shown, the drying surface 19 is formed by a drying belt, which is wound around two shafts 25 and can be driven via at least one of the shafts 25.

In addition, the drying plant 2 has a along a guideway 24 and by means of a drive reciprocable extruder unit 1, with the help of the biomass to be dried (which is supplied to the extruder unit 1 via a hose or pipe, not shown) controlled on the Drying surface 19 can be applied. The extru- dereinheit 1 in known drying systems usually consists of a perforated plate 16 (see Figure 3) and a relative to the perforated plate 16 movable blade unit 22, as shown for example in Figure 2. For the drive of the blade unit 22, this may, for example, have a central bore 23, via which it is non-rotatably connected to a drive shaft, not shown, of a motor unit. Knife unit 22 and perforated plate 16 are in turn within a mostly cylindrical delivery section, via which the biomass of the extruder unit 1 is supplied under a certain pressure.

Here, the biomass is pressed against the perforated plate 16, penetrates the holes of the perforated plate 16 and passes in the form of biomass strands (see Figure 1) on the drying surface 19. The course, in particular the mutual distance of the individual strands, in this case by the speed of Drying surface 19, the extruder unit 1 and the pressure with which the biomass is pressed through the perforated plate 16 thereof are affected.

While the use of the blade unit 22 shown in FIG. 2 could possibly be dispensed with in the processing of a homogeneous biomass, it has proven particularly useful in the processing of inhomogeneous masses, such as, in particular, sludge 12. Thus, the individual blade wings of the blade unit 22, which bear against the perforated plate 16, during a relative movement between the perforated plate 16 and blade unit 22 shearing off impurities (clogging by hair, textile fibers, etc.) and thus keeping the holes of the perforated plate 16.

However, it has been found that, especially during the processing of sludge 12 (eg sewage sludge), blockage of the perforated plate 16 occurs again and again, which is caused, on the one hand, by cracks which can not be detected by the blade unit 22 or by coarse materials which can not be detected and crushed by the blade unit 22. correspond The coarse materials are generally very heavily pressed sludge constituents which are then absorbed by the blade unit 16 on the perforated plate 16. The coarse materials are, in particular, sludges with a dry substance of more than 35% be guided along and always block a part of the holes of the same.

The extruder unit 1 according to the invention therefore has one or more additional components which serve to solve the described problem and are described in more detail below, initially with reference to FIGS. 3 and 4 (the openings 3 in FIG. 4 are not shown for reasons of clarity ).

Initially, the extruder unit 1 has a base carrier 5, which is non-rotatably connected in the region of a connecting section 6 (eg via positive locking, see FIG. 4) to a drive element 7, for example a drive shaft 17. The drive element 7 is in turn connected to a drive (not shown) (eg an electric motor) and allows a rotation of the base support 5 about the longitudinal axis 15 of the drive element 7 and relative to a fixedly placed surface section 4 (FIG. wherein the surface portion 4 has a plurality of apertures 3 for the passage and may be formed, for example, as a perforated plate 16).

The surface section 4 is preferably surrounded at its peripheral region by a wall (not shown) adapted to the circumference of the surface section 4, so that the biomass coming from above can reach the drying surface 19 only via the surface section 4. The wall also extends to above the components shown in Figure 3 and opens, for example, in a delivery hose through which the biomass is supplied. The base support 5 in turn comprises a doctor blade 10 (for example in the form of a metal plate with or without sharp-edged contact surface for contact with the surface portion 4), which is attached to a support arm 9 of the base support 5 or part thereof. The support arm 9 can also be integrally formed with the base support 5 or attached to this, for example, welded, be.

In addition, the extruder unit 1 now comprises a crusher element 11, which follows the shape of the surface of the surface section 4 facing the doctor blade 10 during a rotation of the base carrier 5 in accordance with the movement of the doctor blade 10. While the doctor blade 10 primarily serves for shearing off partially fixed in the openings 3 of the surface portion 4 clogging, the crusher element 1 1 has the task during its common rotation with the base support 5 to effect comminution of coarser components of the biomass and thus blocking the To prevent breakthroughs 3.

The breaker element 1 1 differs from the doctor blade 10 in principle in that it has a cooperating with the surface portion 4 mating surface, which approximates to the surface portion 4. In the examples shown in FIGS. 3 to 5, the crusher element 11 is cylindrical and preferably rotatable about an axis of rotation 8 (of course, a non-rotatable embodiment is also conceivable). The axis of rotation 8 preferably extends parallel to the surface section 4, wherein the crusher element 11 (eg in the form of a hollow cylinder) can be held on the axis of rotation 8 with the aid of an end-side fixing 28. The fixation 28 can be a bending of the axis of rotation 8 (see FIGS. 3 and 4) or else a screw placed on the front side, which prevents the breaker element 11 from being pulled off the axis of rotation 8.

During its movement along the surface section 4, the breaker element 1 1 now causes by the decreasing in the direction of movement stood between the surface of the crusher element 1 1 (in the example shown, the roll surface) and the surface portion 4 a crushing of retained components of the biomass, so that, for example, mud 12 can be processed with a dry matter of over 50%, without causing a failure the extruder unit 1 comes.

In order to prevent jamming of biomass components between the crusher element 11 and the region of the surface section 4 adjacent to the openings 3, the crusher element 11 may have a certain play relative to the component holding the crusher element 11 (eg the rotation axis 8 shown). However, the clearance should be less than the diameter of the apertures 3 to ensure the desired size reduction of larger biomass components.

Furthermore, FIG. 3 shows a possibility of producing the necessary contact pressure between the doctor blade 10 and the surface section 4. Thus, the drive shaft 17 in the lower region has a thread 27 and a cooperating nut 26. If the nut 26 is tightened, this is pressed against a thrust bearing 18 and in this case presses the surface portion 4 against the doctor blade 10. With the aid of this arrangement, the contact pressure of the doctor blade 10 (for example, depending on the unavoidable wear) can be readjusted at any time without the individual components would have to be removed.

Finally, FIG. 5 shows two further possible developments of the invention. For example, it would be conceivable to fix the doctor blade 10 about a pivot bearing 29 (for example, a screw connection engaging in a slot in the doctor blade 10 or the support arm 9) on the base support 5 or a corresponding support arm 9. Height differences or different inclinations of the surface section 4 could thereby be effectively compensated. In this context, it may also be advantageous to form the support arm 9 by two adjacent holding portions 14, between which the doctor blade 10 is held.

Finally, the extruder unit 1 can have one or more brush elements (s) 13 in addition to the scraper blade (s) 10 or the crusher element (s) 11. The brush element 13 shown by way of example in FIG. 5 should in turn bear against the surface section 4 (compare the position of the doctor blade 10 in FIG. 3) and finally causes clogging or other fibrous impurities or impurities not covered by the doctor blade 10 which are already partially present in the perforations 3 of the surface portion 4 are again pulled out of these and the surface portion 4 (as it were in a further start-up) pass elsewhere or from the doctor blade 10 (which may be formed, for example, blade-shaped) can be crushed.

The present invention is not limited to the illustrated and described embodiment. Variations within the scope of the claims are just as possible as a combination of features, even if they are shown and described in different embodiments.

LIST OF REFERENCES

extruder unit

drying plant

perforation

surface section

base support

connecting portion

driving element

axis of rotation

Beam

doctor blade

breaker element

mud

brush element

holding section

Longitudinal axis of the drive element

perforated plate

drive axle

thrust bearing

drying surface

air supply

passage

blade unit

drilling

guideway

wave

mother

thread

fixation

pivot bearing

Claims

P a n t a n s p r e c h e

1 . Extruder unit for a drying plant (2) for biomass, in particular sludge (12),

- wherein the extruder unit (1) has to be passed by the biomass and a plurality of openings (3) having surface portion (4),

- wherein the extruder unit (1) comprises a base support (5) which is connected via a connecting portion (6) with a drive element (7) and via the drive element (7) about an axis of rotation and relative to the surface portion (4) is drivable,

- wherein the base support (5) comprises at least one support arm (9) with at least one scraper blade (10) following the rotation of the base support (5) of the shape of the doctor blade (10) facing surface of the surface portion (4),

characterized in that the base support (5) further comprises at least one breaker element (1 1), which also follows the shape of the doctor blade (10) facing surface of the surface portion (4) during rotation of the base support (5) and during rotation of the base carrier (5) causes comminution of components contained in the biomass, which are retained by the surface portion (4).

2. Extruder unit according to the preceding claim, characterized in that the breaker element (1 1) is cylindrical.

3. extruder unit according to one or more of the preceding claims, characterized in that the crusher element (1 1) about a rotational axis (8) is rotatably mounted on the base support (5). Extruder unit according to the preceding claim, characterized in that the axis of rotation (8) extends parallel to the respectively the crusher element (1 1) adjacent region of the surface portion (4).

Extruder unit according to one or more of claims 3 and 4, characterized in that the breaker element (1 1) has a perpendicular to the axis of rotation (8) having game, so that the distance between the breaker element (1 1) and the adjacent surface portion (4 ) is changeable.

Extruder unit according to one or more of the preceding claims, characterized in that the doctor blade (10) with the surface portion (4) forms an angle, the amount of a value between 75 ° and 105 °, preferably a value between 80 ° and 100 °, especially preferably has a value between 85 ° and 95 °, has.

Extruder unit according to one or more of the preceding claims, characterized in that the base support (5) comprises at least one brush element (13), which upon rotation of the base support (5) also the shape of the doctor blade (10) facing surface of the surface portion (4 ) and during the rotation causes a cleaning of the surface portion (4), wherein the brush element (13) is preferably also mounted on a support arm (9) of the base support (5).

Extruder unit according to one or more of the preceding claims, characterized in that the doctor blade (10) and / or the breaker element (1 1) and / or the brush element (13) are releasably secured to the base support (5).

9. extruder unit according to one or more of the preceding claims, characterized in that the doctor blade (10) and / or the brush element (13) in each case between two adjacent holding portions (14) of a support arm (9) of the base support (5) are mounted.

10. extruder unit according to one or more of the preceding claims, characterized in that the support arms (9) with respect to a longitudinal axis (15) of the drive element (7) extend radially outward.

1 1. Extruder unit according to one or more of the preceding claims, characterized in that the surface portion (4) is formed as a perforated plate (16).

12. extruder unit according to one or more of the preceding claims, characterized in that the drive element (7) as drive axle (17) is formed, which preferably penetrates the surface portion (4) centrally, and that the surface portion (4) by means of a thrust bearing ( 18) against the doctor blade (10) is pressed, wherein the thrust bearing (18) on the doctor blade (10) facing away from the surface portion (4) is placed.

13. Drying plant for biomass, in particular sludge (12),

- wherein the drying plant (2) has at least one drying surface (19) with a plurality of passages (21),

- wherein the drying plant (2) comprises at least one air supply (20) for supplying drying air in the region of the drying surface (19), and

- wherein the drying plant (2) has at least one extruder unit (1), with the aid of which the biomass is applied to the drying surface (19) can be applied, wherein the drying surface (19) and the extruder unit (1) are mounted to move relative to each other,

characterized in that the extruder unit (1) is designed according to one or more of the preceding claims.