Title of Invention	EXTRUDER
Abstract	In the case of an extruder with at least two parallel, rotating shafts turning in the same direction, the shafts are equipped with interlocking feed screw segments (24) and working segments (26). The working segments (26), which lead to a greater spread between the two shafts than the feed screw segments (24), are formed as a single piece as a combined element (22) using the feed screw segment (24).

Title of Invention

EXTRUDER

Abstract

In the case of an extruder with at least two parallel, rotating shafts turning in the same direction, the shafts are equipped with interlocking feed screw segments (24) and working segments (26). The working segments (26), which lead to a greater spread between the two shafts than the feed screw segments (24), are formed as a single piece as a combined element (22) using the feed screw segment (24).

Full Text	Extruder The invention refers to an extruder for the continuous processing and/or treatment of free-flowing materials with at least two shafts rotating in the same direction, which are equipped with interlocking feed screw segments and working segments and guided in circle segment-shaped recesses in the extruder housing parallel to the shafts. The shafts equipped with the feed screw segments and the working segments can also be arranged in a hollow space in the extruder housing along a circle with the same central angle (EP 0 788 867 Bl). Whilst the feed screw segments formed from individual elements feed the material to be processed in the extruder from the material feed opening to the material exit opening at the other end of the extruder, at the same time the working segments shaped as individual elements have a braking and, if necessary, a reversing function. As the working elements, kneading blocks, as known from EP 0 422 272 Al, for example, can be used, or so-called blisters, i.e. baffle plates with a diameter of the same size as the outer diameter of the screw, which can also be equipped as a so-called toothed disk with external teeth. Instead of such working elements that compress the material, pressure relieving working elements are also used. For example, from DE 102 33 213 Al, a screw element is known that 2 has a feed-neutral, pressure-relieving section which is formed through wearing of the screw at the screw cog. The working elements, which have different surfaces for different process tasks, can be combined with each other in almost any way to optimally take into account the respective total technical process requirements. The feed screw elements and working elements are lined up tightly to each other and are placed on the carrier shafts in a torque-proof manner and, positioned accurately both radially and axially, are driven in a co-ordinated manner by the drive. Due to special technical process requirements, working elements are frequently reduced in length to up to one sixth of the screw diameter and are almost always shorter than the screw diameter. On the other hand, high pressure can occur between the interlocking working elements of two adjacent shafts, particularly if these elements, such as reversing screw elements, kneading blocks, blisters or toothed disks, have a diameter that corresponds to the external sectional diameter. In this way, forces occur in double screw extruders around such working elements that lead to a considerable spread between the shafts. These forces also lead to considerable wear in multiple shaft extruders where the shafts are arranged around a circle with the same central angle. The task of the invention is to reduce the above-average wear around the working elements. In the invention, this is achieved by the working segments, which lead to a larger spread between two shafts than feed screw segments, being formed by a single-piece combined 3 element comprising at least one feed screw segment and/or at least one further working segment. The working segment which is united with a feed screw segment to form a combined element made as one piece can be a reversing working segment with a diameter corresponding to the screw diameter, particularly a screw segment with a greater pitch than the feed screw segment or a pitch direction counter to the feed screw segment or a kneading block, a blister or a toothed disk. However, two working segments can also be united as an element made as one piece, e.g. two kneading blocks with opposing pitch directions or a screw segment with an opposing pitch direction and a kneading block. By uniting a feed screw segment and a working segment, or two working segments into a longer combined element in accordance with the invention, the bending strength of the shafts is significantly improved. At the same time, the spreading forces are distributed over a larger, generally better lubricated surface and thus the surface load and therefore the wear are significantly reduced. In addition, the combination of several different technical process requirements that can be located in a segment over a relatively short length brings with it a decisive reduction in the number of parts, which results in a significant simplification of the equipment and maintenance of the shafts as well as their storage. In order to simplify the equipping of the shafts, the face surfaces of the combined elements in the invention are delimited by circular arcs, which correspond to the feed 4 screw diameter, the feed screw core diameter and are no larger than the centre distance of the axes of the shafts. The combined elements can then simply be placed on the shafts in such a way that the face surfaces delimited by the circular arcs align with each other. Thus fault-free mounting of the combined elements that interlock with the combined elements of the adjacent shaft is made significantly easier. So that the benefits of the combined elements take effect with regard to bending, strength and wear, the combined element has a length greater than the diameter of the screw, and specifically, more than double the diameter of the screw. The feed screw segment of the combined element is preferably designed with a double lead, as a double-lead screw leads to a larger feed quantity than a triple-lead screw, but compared to a single-lead screw has a greater bending strength. If a working segment of the combined element also has a screw-shaped surface, i.e. a screw segment with a greater pitch or counter pitch direction, this is also preferably designed with a double lead. The surface of the working segment can also simply have a spiral shaped progression similar to a screw, for example in the case of kneading blocks. So in accordance with the invention, a kneading block segment with double-lead cam plates arranged in a spiral that have a pitch direction in accordance with the feed screws, for example, can be combined with a double-lead kneading block segment with an opposing pitch direction to form one element. 5 With the high temperatures to which the material being processed is subjected, the shafts and the feed and working elements sitting on them expand differently. This results in the formation of a gap between the shaft and the elements sitting on them, into which the molten material, such as plastic, can penetrate and possibly combust, and in any case can bind the shaft with the elements so firmly that the elements can only be withdrawn from the shaft after cooling with the greatest of difficulty. This problem is accentuated in the long combined elements used in the invention to such an extent that at times the elements cannot be withdrawn at all and the whole shaft has to be discarded. In accordance with the invention therefore, each shaft is preferably divided into several shorter shaft sections, whereby the shaft sections are formed to be able to be axially distorted in the shaft core. For the axial distortion ability, an axially fixed rotating element is preferably pivoted at one end of the shaft section in the shaft core, which is equipped in a torque-proof manner with an external thread, which engages in the inner thread in the core of the adjacent shaft section. For this, the shaft section can have at one end a rotating element with an external thread and on the other end the inner thread in the core. There can also be shaft sections that at both ends have such rotating elements with external threads and which are connected to shaft sections that have internal threads in the core at both ends. In the shaft core of the shaft section, there is preferably an axial bore hole or similar recess so that the rotating 6 element can be activated. For this, the rotating element can be equipped on its side facing the axial recess of the shaft section with a polygon or polygonal recess, for example a hexagonal recess or peg, which is operated through a rod inserted in the axial bore hole of the shaft core, equipped at its end with a corresponding opposing polygon. Instead of a polygonal recess or a polygonal peg, naturally another activating recess or activating projection can be designed on the rotating element which is activated through a rod correspondingly designed at its end, inserted in the axial bore hole in the shaft core. Each shaft section with the torque-proof elements arranged on it is connected in a torque-proof manner with the adjacent shaft section. To do this, there is an interlocking, torque- proof connection between two adjacent shaft sections, for example using serrated or wedge-shaped teeth on the external perimeter of the end of the shaft core, to which the rotating element is pivoted, whereby the teeth work together on the external perimeter using serrated or wedge-shaped teeth in a hub bore hole at the end of the adjacent shaft section, where the internal thread is located into which the external thread on the rotating element of the adjacent shaft section engages. The combined element with a working segment and at least one feed screw segment and/or at least one additional working segment can be formed with the shaft core of the shaft segment as one piece. However, it is also possible to design the screw core of the shaft section for mounting one or more combined elements in a torque-proof manner. 7 Through the elements combined as one piece in the invention, the bending strength of the shaft is significantly increased to a certain length so that transverse forces that are produced are better distributed over a larger surface area and thus wear is reduced. In addition, in the invention the number of components is reduced, which has a beneficial effect on both storage and assembly and dismantling. Furthermore, short working segments are integrated, for example working segments with a length that is smaller than one half of the feed screw diameter, and also those that are not covered by the type charts, e.g. through their structural length and/or placement position. Placement errors can also be safely avoided in the case of complicated arrangements. The number of tight spots is also drastically reduced and the process space is radially close on a certain machine length to an internally guided shaft. The extruder in the invention can be formed as a double shaft extruder. However, it will preferably have three or more shafts arranged in a cavity in the extruder housing along a circle or circular arc with the same central angle. Below, the invention is described in more detail using the enclosed drawings. They show the following: Figure 1 shows a longitudinal section through a multi-shaft extruder; Figure 2 shows a cross-section along line II-II in Figure 1; Figures 3 and 4 show a side view and a face view of a combined feed screw and working element 8 Figures 5 and 6 show a side view and a face view of a combined element in accordance with Figure 1, but with a short working segment and thus a different face wall; Figures 7 and 8 show a perspective view and face view of an element combined from one kneading block element with a pitch and one kneading block segment with an opposing pitch; Figure 9 shows a cross-section through a two-shaft extruder with closely interlocking screw segments around the whole perimeter; Figure 10 shows a longitudinal section through a shaft section with the element combined with it and formed as one piece; Figure 11 shows a view of the right end of the shaft section according to Figure 10; Figure 12 shows a view corresponding to Figure 11, but of a shaft section with a combined element placed on the shaft core; Figure 13 shows a cross-section along the line XIII-XIII in Figure 11; and Figure 14 shows a longitudinal section through a shaft made from several shaft sections with combined elements in place. In accordance with Figures 1 and- 2, an extruder in a housing 1 has a space 2 which extends along a circle 3. In the space 9 2 are a number of shafts 4 arranged parallel to the axis around a core 5. The housing 1 is closed at the face sides with end plates 6 and 7. The shafts 4 extending through the end plate 6 are driven in the same direction by a drive that is not shown. The material feed opening is identified as 8 and the material exit opening in the end plate 7 is identified as 9. There are several elements 11, 12, 13, 14 placed in a torque- proof manner on each shaft 4 using wedge-shaped teeth. Whilst elements 11 and 13 are formed by a feed screw segment, element 12 consists of a feed screw segment 15 and a kneading block 16, and element 14 of a feed screw segment 17 with a greater pitch than that of the feed screw elements 11 and 13, as well as a short screw segment 18 with an opposing pitch. The kneading block segment 16 and the short screw segment 18 with an opposing pitch represent the working segments. On the inner side of the housing 1 and on the core 5 are recesses 19 and 20, parallel to the axis and shaped as circular segments, in which the feed screw elements 11 and 13 and the combined elements 12 and 14 engage with limited play, i.e. to the greatest degree of tightness. At the same time, the feed screw elements 11 and 13 and the combined elements 12 and 14 interlock tightly in each other to a large extent. Figures 3 and 4, as well as 5 and 6, show two other combined elements 22, 23 made from one feed screw segment 24 or 25 and one working segment 26 or 27, which are each formed through a screw segment with a greater pitch than that of the feed screw segment 24 or 25, whereby the working segment 27 is designed to be shorter than the working segment 26. 10 Figures 7 and 8 show a combined element 28, which consists of a kneading block segment 29 made from cam disks which, as indicated by the dotted line 29', is arranged with a pitch direction in accordance with a feed screw element, and a kneading block segment 30 made from can disks, which, as indicated by the dotted line 30', are arranged with opposing pitch directions. This means that in this design form, two kneading block segments 29 and 30 as working segments with different functions are combined into one element 28. As shown in Figure 9, two interlocking combined elements 22 have a face 10 which is delimited by the circular arcs A-B, E-F and A-E. The circular arc A-B has a diameter that corresponds to the screw diameter D, the circular arc E-F has a diameter that corresponds to the screw core diameter d, and the circular arc A-E has a diameter the radius of which corresponds to the axis distance Ax of both combined elements 22 (see also EP-B-0002131). In the same way, the face 10 of the combined elements 22 and 2 8 is formed in accordance with Figures 3 and 4 and/or 7 and 8. The combined element 23 in accordance with Figures 5 and 6 also has a face 20 which is delimited by the circular arcs A- B, E-F' and A-E, but additionally by the circular arc 32, which corresponds to a semicircle with the diameter of the screw core. Through the combined elements' faces formed from these circular arcs, the equipping of the shafts is significantly simplified, as the elements only have to be equipped so that their faces align with each other. 11 Each shaft 4 is divided into several short shaft sections that can be different formed. Thus with the shaft section 33 according to Figures 10 and 11, the shaft core 37 and the schematically depicted combined element 36 are formed as one piece, whilst in the case of the shaft sections 34, 35 in Figures 12 and 14, the schematically represented combined elements 36 are placed on the shaft core 37 in a torque-proof way using wedge-shaped teeth 38. The shaft sections 33, 34, 35 are designed to be able to be axially deformed under tension in the shaft core 37. For this, a cylindrical rotating element 41 pivots at the end of each shaft section 33, 34, 35 in an axial recess 39 in the shaft core 37. At its end that protrudes from the axial recess 39, the rotating element 41 has an external thread 42. To axially attach the rotating element 41, there is a wire ring 43 which engages on one side in a perimeter groove 44 in the cylindrical axial recess 39 in the shaft core 37 and on the other in a perimeter groove 45 in the external perimeter of the cylindrical rotating element 41. The wire ring 43 is formed, as can be seen in Figure 13, by a wire being pushed between the perimeter grooves 44, 45 through a tangential bore hole 48 in the shaft core 37 from the side. As can be seen in Figure 10, to connect the shaft sections there is a coaxial internal thread 49 on the other end of the shaft section 33 in the shaft core 37, into which the coaxial external thread 42 of the adjacent shaft section 33 can be screwed. 12 In order to increase the bending strength, the shaft core 37 protrudes at the end of the shaft section 33 on which the rotating element 41 is arranged, whereby the axial peg formed by the protruding shaft core end 4 6 is inserted in the end of the adjacent shaft recess 33 where, on the inner side of the axial recess 47, the axial recess has an internal thread 49. To activate the rotating element 41, the shaft core 37 has a continuous axial bore hole or similar recess 51. The rotating element 41 can, for example, have a hexagonal recess 52, in which a hexagon, which is not shown, is attached to a rod which is inserted through the axial bore hole 51 in order to turn the rotating element 41 and thus screw the external thread 42 either in or out of the internal thread 49 of the adjacent shaft section 33, in order to connect or detach the adjacent shaft section. Each shaft section 33 is formed in a torque-proof manner using the adjacent shaft section 33. For this, there are wedge-shaped teeth 53 on the peg 4 6 in accordance with Figure 11, which engage with the wedge-shaped teeth 50 in the axial recess 47 of the adjacent shaft recess 33. In the case of the design form in accordance with Figure 12, the wedge-shaped teeth 38 on the shaft core 37 used for the elements 36 are additionally used. In Figure 14, the direction of extrusion is indicated with an arrow 54. The direction for assembling the shaft from the shaft sections 34, 35 also corresponds to the direction of the arrow 54, whilst the direction of dismantling runs counter to the direction of the arrow 54. It can be seen that the ends of the shaft sections 34, 35 are each equipped on 13 their upstream end with a rotating element 41 with reference to the direction of extrusion 54. 14 Patent claims 1. Extruder for the continuous processing and/or treatment of free-flowing materials, with at least two parallel shafts that turn in the same direction, equipped with interlocking feed screw segments and working segments and guided in recesses in the extruder housing that are parallel to the shaft and shaped as circle segments, characterized in that the working segments (16, 18, 26, 27, 29, 30) that lead to a greater spread between two shafts (4) than do the feed screws (11, 13, 15, 24, 25), form single-piece combined elements (12, 14, 22, 23, 28, 36) with at least one feed screw segment (15, 24, 25) and/or at least one additional working segment (30, 29). 2. Extruder according to claim 1, characterized in that the working segment formed in one piece with at least one feed screw segment (12, 24, 25) and/or at least one working segment (30, 29) is a screw element (24, 25) with a greater pitch than the feed screw segments (11, 13, 15, 24, 25), a screw segment (18) with an opposing pitch direction, a kneading block (16, 29, 30), a blister or a toothed disk. 3. Extruder according to claims 1 or 2, characterized in that the faces (10, 20) of the combined elements (22, 23) are delimited by circular arcs (A-B, E-F, E-F', A- E), which correspond to the feed screw diameter (D), the 15 screw core diameter (d) and are no larger than the axis distance (Ax) of the shafts (4). 4. Extruder according to claim 3, characterized in that at least one part of the combined elements (23) is additionally delimited on at least one face (20) by a circular arc (32) which corresponds to a semicircle with the screw core diameter (d). 5. Extruder according to one of the above claims, characterized in that the combined element (14, 22, 23, 28) is formed as a double lead. 6. Extruder according to one of the above claims, characterized in that the combined element (12, 14, 22, 23, 28, 36) has a length that is greater than the feed screw diameter (D). 7. Extruder according to one of the above claims, characterized in that each shaft (4) is divided into several short shaft sections (33, 34, 35) and the shaft sections (33, 34, 35) of the shaft (4) are designed to be able to deform under axial tension in the shaft core (37) . 8. Extruder according to claim 7, characterized in that an axially fixed rotating element (41) is pivoted on at least one end of the shaft sections (33, 34, 35) in the shaft core (37) and is equipped in a torque-proof manner with an external thread (42), which engages in an internal thread (49) in the core (37) of the adjacent shaft section (33, 34, 35). 16 9. Extruder according to claim 8, characterized in that the shaft core (37) is equipped with an axial recess (51) for activating the rotating element (41). 10. Extruder according to claim 9, characterized in that the rotating element (41) is equipped with a polygon (52) for activating an opposing polygon introduced into the axial recess (51). 11. Extruder according to claim 7, characterized in that a wire ring (43) which engages between a perimeter groove (45) in the rotating element (41) and a perimeter groove (44) in the shaft core (37) is provided for the axial fixing of the rotating element (41). 12. Extruder according to claim 11, characterized in that each shaft section (33, 34, 35) is connected in a torque-free manner with the adjacent shaft section (33, 34, 35) . 13. Extruder according to claims 7 to 12, characterized in that the shaft core (37) axially protrudes at least on one end of the shaft section (33, 34, 35) over the combined element (36) and the protruding shaft core end (46) engages in an axial recess (47) in the adjacent shaft recess (33, 34, 35). 14. Extruder according to claim 13, characterized in that the protrusion of the protruding shaft core end (46) is at least one half of the diameter of the feed screw (D). 17 15. Extruder according to one of the claims 12 to 14, characterized in that for interlocking, torque-proof connection, the protruding shaft core end (46) has wedge-shaped teeth (38, 53) that engage in the wedge- shaped teeth (50) in the axial recess (47) in the adjacent shaft section (33). 16. Extruder according to one of the claims 7 to 15, characterized in that the shaft core (37) and the combined element (36) are formed as a single piece. 17. Extruder according to one of the claims 7 to 15, characterized in that the combined element (36) is formed on the shaft section (35) for torque-proof placement. 18. Extruder according to one of the claims 7 to 17, characterized in that the rotating element (41) is arranged at the upstream end of the shaft section (33, 34, 35) . 19. Extruder according to one of the above claims, characterized by at least three shafts (4) arranged in a space (2) in an extruder housing (1) along a circle (3) or circular arc with the same central angle. In the case of an extruder with at least two parallel, rotating shafts turning in the same direction, the shafts are equipped with interlocking feed screw segments (24) and working segments (26). The working segments (26), which lead to a greater spread between the two shafts than the feed screw segments (24), are formed as a single piece as a combined element (22) using the feed screw segment (24).

Full Text

Extruder
The invention refers to an extruder for the continuous
processing and/or treatment of free-flowing materials with at
least two shafts rotating in the same direction, which are
equipped with interlocking feed screw segments and working
segments and guided in circle segment-shaped recesses in the
extruder housing parallel to the shafts.
The shafts equipped with the feed screw segments and the
working segments can also be arranged in a hollow space in
the extruder housing along a circle with the same central
angle (EP 0 788 867 Bl). Whilst the feed screw segments
formed from individual elements feed the material to be
processed in the extruder from the material feed opening to
the material exit opening at the other end of the extruder,
at the same time the working segments shaped as individual
elements have a braking and, if necessary, a reversing
function. As the working elements, kneading blocks, as known
from EP 0 422 272 Al, for example, can be used, or so-called
blisters, i.e. baffle plates with a diameter of the same size
as the outer diameter of the screw, which can also be
equipped as a so-called toothed disk with external teeth.
Instead of such working elements that compress the material,
pressure relieving working elements are also used. For
example, from DE 102 33 213 Al, a screw element is known that

2
has a feed-neutral, pressure-relieving section which is
formed through wearing of the screw at the screw cog.
The working elements, which have different surfaces for
different process tasks, can be combined with each other in
almost any way to optimally take into account the respective
total technical process requirements. The feed screw elements
and working elements are lined up tightly to each other and
are placed on the carrier shafts in a torque-proof manner
and, positioned accurately both radially and axially, are
driven in a co-ordinated manner by the drive.
Due to special technical process requirements, working
elements are frequently reduced in length to up to one sixth
of the screw diameter and are almost always shorter than the
screw diameter. On the other hand, high pressure can occur
between the interlocking working elements of two adjacent
shafts, particularly if these elements, such as reversing
screw elements, kneading blocks, blisters or toothed disks,
have a diameter that corresponds to the external sectional
diameter. In this way, forces occur in double screw extruders
around such working elements that lead to a considerable
spread between the shafts. These forces also lead to
considerable wear in multiple shaft extruders where the
shafts are arranged around a circle with the same central
angle.
The task of the invention is to reduce the above-average wear
around the working elements.
In the invention, this is achieved by the working segments,
which lead to a larger spread between two shafts than feed
screw segments, being formed by a single-piece combined

3
element comprising at least one feed screw segment and/or at
least one further working segment.
The working segment which is united with a feed screw segment
to form a combined element made as one piece can be a
reversing working segment with a diameter corresponding to
the screw diameter, particularly a screw segment with a
greater pitch than the feed screw segment or a pitch
direction counter to the feed screw segment or a kneading
block, a blister or a toothed disk. However, two working
segments can also be united as an element made as one piece,
e.g. two kneading blocks with opposing pitch directions or a
screw segment with an opposing pitch direction and a kneading
block.
By uniting a feed screw segment and a working segment, or two
working segments into a longer combined element in accordance
with the invention, the bending strength of the shafts is
significantly improved. At the same time, the spreading
forces are distributed over a larger, generally better
lubricated surface and thus the surface load and therefore
the wear are significantly reduced. In addition, the
combination of several different technical process
requirements that can be located in a segment over a
relatively short length brings with it a decisive reduction
in the number of parts, which results in a significant
simplification of the equipment and maintenance of the shafts
as well as their storage.
In order to simplify the equipping of the shafts, the face
surfaces of the combined elements in the invention are
delimited by circular arcs, which correspond to the feed

4
screw diameter, the feed screw core diameter and are no
larger than the centre distance of the axes of the shafts.
The combined elements can then simply be placed on the shafts
in such a way that the face surfaces delimited by the
circular arcs align with each other. Thus fault-free mounting
of the combined elements that interlock with the combined
elements of the adjacent shaft is made significantly easier.
So that the benefits of the combined elements take effect
with regard to bending, strength and wear, the combined
element has a length greater than the diameter of the screw,
and specifically, more than double the diameter of the screw.
The feed screw segment of the combined element is preferably
designed with a double lead, as a double-lead screw leads to
a larger feed quantity than a triple-lead screw, but compared
to a single-lead screw has a greater bending strength.
If a working segment of the combined element also has a
screw-shaped surface, i.e. a screw segment with a greater
pitch or counter pitch direction, this is also preferably
designed with a double lead. The surface of the working
segment can also simply have a spiral shaped progression
similar to a screw, for example in the case of kneading
blocks. So in accordance with the invention, a kneading block
segment with double-lead cam plates arranged in a spiral that
have a pitch direction in accordance with the feed screws,
for example, can be combined with a double-lead kneading
block segment with an opposing pitch direction to form one
element.

5
With the high temperatures to which the material being
processed is subjected, the shafts and the feed and working
elements sitting on them expand differently. This results in
the formation of a gap between the shaft and the elements
sitting on them, into which the molten material, such as
plastic, can penetrate and possibly combust, and in any case
can bind the shaft with the elements so firmly that the
elements can only be withdrawn from the shaft after cooling
with the greatest of difficulty.
This problem is accentuated in the long combined elements
used in the invention to such an extent that at times the
elements cannot be withdrawn at all and the whole shaft has
to be discarded.
In accordance with the invention therefore, each shaft is
preferably divided into several shorter shaft sections,
whereby the shaft sections are formed to be able to be
axially distorted in the shaft core. For the axial distortion
ability, an axially fixed rotating element is preferably
pivoted at one end of the shaft section in the shaft core,
which is equipped in a torque-proof manner with an external
thread, which engages in the inner thread in the core of the
adjacent shaft section. For this, the shaft section can have
at one end a rotating element with an external thread and on
the other end the inner thread in the core. There can also be
shaft sections that at both ends have such rotating elements
with external threads and which are connected to shaft
sections that have internal threads in the core at both ends.
In the shaft core of the shaft section, there is preferably
an axial bore hole or similar recess so that the rotating

6
element can be activated. For this, the rotating element can
be equipped on its side facing the axial recess of the shaft
section with a polygon or polygonal recess, for example a
hexagonal recess or peg, which is operated through a rod
inserted in the axial bore hole of the shaft core, equipped
at its end with a corresponding opposing polygon. Instead of
a polygonal recess or a polygonal peg, naturally another
activating recess or activating projection can be designed on
the rotating element which is activated through a rod
correspondingly designed at its end, inserted in the axial
bore hole in the shaft core.
Each shaft section with the torque-proof elements arranged on
it is connected in a torque-proof manner with the adjacent
shaft section. To do this, there is an interlocking, torque-
proof connection between two adjacent shaft sections, for
example using serrated or wedge-shaped teeth on the external
perimeter of the end of the shaft core, to which the rotating
element is pivoted, whereby the teeth work together on the
external perimeter using serrated or wedge-shaped teeth in a
hub bore hole at the end of the adjacent shaft section, where
the internal thread is located into which the external thread
on the rotating element of the adjacent shaft section
engages.
The combined element with a working segment and at least one
feed screw segment and/or at least one additional working
segment can be formed with the shaft core of the shaft
segment as one piece. However, it is also possible to design
the screw core of the shaft section for mounting one or more
combined elements in a torque-proof manner.

7
Through the elements combined as one piece in the invention,
the bending strength of the shaft is significantly increased
to a certain length so that transverse forces that are
produced are better distributed over a larger surface area
and thus wear is reduced. In addition, in the invention the
number of components is reduced, which has a beneficial
effect on both storage and assembly and dismantling.
Furthermore, short working segments are integrated, for
example working segments with a length that is smaller than
one half of the feed screw diameter, and also those that are
not covered by the type charts, e.g. through their structural
length and/or placement position. Placement errors can also
be safely avoided in the case of complicated arrangements.
The number of tight spots is also drastically reduced and the
process space is radially close on a certain machine length
to an internally guided shaft.
The extruder in the invention can be formed as a double shaft
extruder. However, it will preferably have three or more
shafts arranged in a cavity in the extruder housing along a
circle or circular arc with the same central angle.
Below, the invention is described in more detail using the
enclosed drawings. They show the following:
Figure 1 shows a longitudinal section through a multi-shaft
extruder;
Figure 2 shows a cross-section along line II-II in Figure 1;
Figures 3 and 4 show a side view and a face view of a
combined feed screw and working element

8
Figures 5 and 6 show a side view and a face view of a
combined element in accordance with Figure 1, but with a
short working segment and thus a different face wall;
Figures 7 and 8 show a perspective view and face view of an
element combined from one kneading block element with a pitch
and one kneading block segment with an opposing pitch;
Figure 9 shows a cross-section through a two-shaft extruder
with closely interlocking screw segments around the whole
perimeter;
Figure 10 shows a longitudinal section through a shaft
section with the element combined with it and formed as one
piece;
Figure 11 shows a view of the right end of the shaft section
according to Figure 10;
Figure 12 shows a view corresponding to Figure 11, but of a
shaft section with a combined element placed on the shaft
core;
Figure 13 shows a cross-section along the line XIII-XIII in
Figure 11; and
Figure 14 shows a longitudinal section through a shaft made
from several shaft sections with combined elements in place.
In accordance with Figures 1 and- 2, an extruder in a housing
1 has a space 2 which extends along a circle 3. In the space

9
2 are a number of shafts 4 arranged parallel to the axis
around a core 5. The housing 1 is closed at the face sides
with end plates 6 and 7. The shafts 4 extending through the
end plate 6 are driven in the same direction by a drive that
is not shown. The material feed opening is identified as 8
and the material exit opening in the end plate 7 is
identified as 9.
There are several elements 11, 12, 13, 14 placed in a torque-
proof manner on each shaft 4 using wedge-shaped teeth. Whilst
elements 11 and 13 are formed by a feed screw segment,
element 12 consists of a feed screw segment 15 and a kneading
block 16, and element 14 of a feed screw segment 17 with a
greater pitch than that of the feed screw elements 11 and 13,
as well as a short screw segment 18 with an opposing pitch.
The kneading block segment 16 and the short screw segment 18
with an opposing pitch represent the working segments.
On the inner side of the housing 1 and on the core 5 are
recesses 19 and 20, parallel to the axis and shaped as
circular segments, in which the feed screw elements 11 and 13
and the combined elements 12 and 14 engage with limited play,
i.e. to the greatest degree of tightness. At the same time,
the feed screw elements 11 and 13 and the combined elements
12 and 14 interlock tightly in each other to a large extent.
Figures 3 and 4, as well as 5 and 6, show two other combined
elements 22, 23 made from one feed screw segment 24 or 25 and
one working segment 26 or 27, which are each formed through a
screw segment with a greater pitch than that of the feed
screw segment 24 or 25, whereby the working segment 27 is
designed to be shorter than the working segment 26.

10
Figures 7 and 8 show a combined element 28, which consists of
a kneading block segment 29 made from cam disks which, as
indicated by the dotted line 29', is arranged with a pitch
direction in accordance with a feed screw element, and a
kneading block segment 30 made from can disks, which, as
indicated by the dotted line 30', are arranged with opposing
pitch directions. This means that in this design form, two
kneading block segments 29 and 30 as working segments with
different functions are combined into one element 28.
As shown in Figure 9, two interlocking combined elements 22
have a face 10 which is delimited by the circular arcs A-B,
E-F and A-E. The circular arc A-B has a diameter that
corresponds to the screw diameter D, the circular arc E-F has
a diameter that corresponds to the screw core diameter d, and
the circular arc A-E has a diameter the radius of which
corresponds to the axis distance Ax of both combined elements
22 (see also EP-B-0002131). In the same way, the face 10 of
the combined elements 22 and 2 8 is formed in accordance with
Figures 3 and 4 and/or 7 and 8.
The combined element 23 in accordance with Figures 5 and 6
also has a face 20 which is delimited by the circular arcs A-
B, E-F' and A-E, but additionally by the circular arc 32,
which corresponds to a semicircle with the diameter of the
screw core.
Through the combined elements' faces formed from these
circular arcs, the equipping of the shafts is significantly
simplified, as the elements only have to be equipped so that
their faces align with each other.

11
Each shaft 4 is divided into several short shaft sections
that can be different formed. Thus with the shaft section 33
according to Figures 10 and 11, the shaft core 37 and the
schematically depicted combined element 36 are formed as one
piece, whilst in the case of the shaft sections 34, 35 in
Figures 12 and 14, the schematically represented combined
elements 36 are placed on the shaft core 37 in a torque-proof
way using wedge-shaped teeth 38.
The shaft sections 33, 34, 35 are designed to be able to be
axially deformed under tension in the shaft core 37. For
this, a cylindrical rotating element 41 pivots at the end of
each shaft section 33, 34, 35 in an axial recess 39 in the
shaft core 37. At its end that protrudes from the axial
recess 39, the rotating element 41 has an external thread 42.
To axially attach the rotating element 41, there is a wire
ring 43 which engages on one side in a perimeter groove 44 in
the cylindrical axial recess 39 in the shaft core 37 and on
the other in a perimeter groove 45 in the external perimeter
of the cylindrical rotating element 41.
The wire ring 43 is formed, as can be seen in Figure 13, by a
wire being pushed between the perimeter grooves 44, 45
through a tangential bore hole 48 in the shaft core 37 from
the side.
As can be seen in Figure 10, to connect the shaft sections
there is a coaxial internal thread 49 on the other end of the
shaft section 33 in the shaft core 37, into which the coaxial
external thread 42 of the adjacent shaft section 33 can be
screwed.

12
In order to increase the bending strength, the shaft core 37
protrudes at the end of the shaft section 33 on which the
rotating element 41 is arranged, whereby the axial peg formed
by the protruding shaft core end 4 6 is inserted in the end of
the adjacent shaft recess 33 where, on the inner side of the
axial recess 47, the axial recess has an internal thread 49.
To activate the rotating element 41, the shaft core 37 has a
continuous axial bore hole or similar recess 51. The rotating
element 41 can, for example, have a hexagonal recess 52, in
which a hexagon, which is not shown, is attached to a rod
which is inserted through the axial bore hole 51 in order to
turn the rotating element 41 and thus screw the external
thread 42 either in or out of the internal thread 49 of the
adjacent shaft section 33, in order to connect or detach the
adjacent shaft section. Each shaft section 33 is formed in a
torque-proof manner using the adjacent shaft section 33. For
this, there are wedge-shaped teeth 53 on the peg 4 6 in
accordance with Figure 11, which engage with the wedge-shaped
teeth 50 in the axial recess 47 of the adjacent shaft recess
33. In the case of the design form in accordance with Figure
12, the wedge-shaped teeth 38 on the shaft core 37 used for
the elements 36 are additionally used.
In Figure 14, the direction of extrusion is indicated with an
arrow 54. The direction for assembling the shaft from the
shaft sections 34, 35 also corresponds to the direction of
the arrow 54, whilst the direction of dismantling runs
counter to the direction of the arrow 54. It can be seen that
the ends of the shaft sections 34, 35 are each equipped on

13
their upstream end with a rotating element 41 with reference
to the direction of extrusion 54.

14
Patent claims
1. Extruder for the continuous processing and/or treatment
of free-flowing materials, with at least two parallel
shafts that turn in the same direction, equipped with
interlocking feed screw segments and working segments
and guided in recesses in the extruder housing that are
parallel to the shaft and shaped as circle segments,
characterized in that the working segments (16, 18, 26,
27, 29, 30) that lead to a greater spread between two
shafts (4) than do the feed screws (11, 13, 15, 24, 25),
form single-piece combined elements (12, 14, 22, 23, 28,
36) with at least one feed screw segment (15, 24, 25)
and/or at least one additional working segment (30, 29).
2. Extruder according to claim 1, characterized in that the
working segment formed in one piece with at least one
feed screw segment (12, 24, 25) and/or at least one
working segment (30, 29) is a screw element (24, 25)
with a greater pitch than the feed screw segments (11,
13, 15, 24, 25), a screw segment (18) with an opposing
pitch direction, a kneading block (16, 29, 30), a
blister or a toothed disk.
3. Extruder according to claims 1 or 2, characterized in
that the faces (10, 20) of the combined elements (22,
23) are delimited by circular arcs (A-B, E-F, E-F', A-
E), which correspond to the feed screw diameter (D), the

15
screw core diameter (d) and are no larger than the axis
distance (Ax) of the shafts (4).
4. Extruder according to claim 3, characterized in that at
least one part of the combined elements (23) is
additionally delimited on at least one face (20) by a
circular arc (32) which corresponds to a semicircle with
the screw core diameter (d).
5. Extruder according to one of the above claims,
characterized in that the combined element (14, 22, 23,
28) is formed as a double lead.
6. Extruder according to one of the above claims,
characterized in that the combined element (12, 14, 22,
23, 28, 36) has a length that is greater than the feed
screw diameter (D).
7. Extruder according to one of the above claims,
characterized in that each shaft (4) is divided into
several short shaft sections (33, 34, 35) and the shaft
sections (33, 34, 35) of the shaft (4) are designed to
be able to deform under axial tension in the shaft core
(37) .
8. Extruder according to claim 7, characterized in that an
axially fixed rotating element (41) is pivoted on at
least one end of the shaft sections (33, 34, 35) in the
shaft core (37) and is equipped in a torque-proof manner
with an external thread (42), which engages in an
internal thread (49) in the core (37) of the adjacent
shaft section (33, 34, 35).

16
9. Extruder according to claim 8, characterized in that the
shaft core (37) is equipped with an axial recess (51)
for activating the rotating element (41).
10. Extruder according to claim 9, characterized in that the
rotating element (41) is equipped with a polygon (52)
for activating an opposing polygon introduced into the
axial recess (51).
11. Extruder according to claim 7, characterized in that a
wire ring (43) which engages between a perimeter groove
(45) in the rotating element (41) and a perimeter groove
(44) in the shaft core (37) is provided for the axial
fixing of the rotating element (41).
12. Extruder according to claim 11, characterized in that
each shaft section (33, 34, 35) is connected in a
torque-free manner with the adjacent shaft section (33,
34, 35) .
13. Extruder according to claims 7 to 12, characterized in
that the shaft core (37) axially protrudes at least on
one end of the shaft section (33, 34, 35) over the
combined element (36) and the protruding shaft core end
(46) engages in an axial recess (47) in the adjacent
shaft recess (33, 34, 35).
14. Extruder according to claim 13, characterized in that
the protrusion of the protruding shaft core end (46) is
at least one half of the diameter of the feed screw (D).

17
15. Extruder according to one of the claims 12 to 14,
characterized in that for interlocking, torque-proof
connection, the protruding shaft core end (46) has
wedge-shaped teeth (38, 53) that engage in the wedge-
shaped teeth (50) in the axial recess (47) in the
adjacent shaft section (33).
16. Extruder according to one of the claims 7 to 15,
characterized in that the shaft core (37) and the
combined element (36) are formed as a single piece.
17. Extruder according to one of the claims 7 to 15,
characterized in that the combined element (36) is
formed on the shaft section (35) for torque-proof
placement.
18. Extruder according to one of the claims 7 to 17,
characterized in that the rotating element (41) is
arranged at the upstream end of the shaft section (33,
34, 35) .
19. Extruder according to one of the above claims,
characterized by at least three shafts (4) arranged in a
space (2) in an extruder housing (1) along a circle (3)
or circular arc with the same central angle.

In the case of an extruder with at least two parallel, rotating shafts turning in the same direction, the shafts are equipped with interlocking feed screw segments (24) and working segments (26). The working segments (26), which lead to a greater spread between the two shafts than the feed screw segments (24), are formed as a single piece as a combined element (22) using the feed screw segment (24).

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Patent Number

269669

Indian Patent Application Number

1653/KOLNP/2007

PG Journal Number

45/2015

Publication Date

06-Nov-2015

Grant Date

30-Oct-2015

Date of Filing

09-May-2007

Name of Patentee

BLACH VERWALTUNGS GMBH & CO. KG

Applicant Address

HOHER STEG 10, D-74348 LAUFFEN

Inventors:

#	Inventor's Name	Inventor's Address
1	BLACH JOSEF A	POSTPLATZ 3, 74348 LAUFFEN A.N.

PCT International Classification Number

B29C 47/60,B29C47/40

PCT International Application Number

PCT/EP2005/010791

PCT International Filing date

2005-10-07

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	10 2004 052 055.0	2004-10-26	Germany