EP1068068A1 - Method and device for producing an extrusion profile - Google Patents

Abstract

The invention relates to extrusion profiles and extrusion tubular profiles made of small parts with or without bonding agents which do not or which slightly flow under compression. During production, compression is generated by pressing spirals. According to the invention, a spiral is used whose transport path enlarges up to the end thereof which is located on the extruded section side. Control of the compression can additionally be improved in an advantageous manner by changing the insertion depth of the spindle or of a mandrel into the extruded section. The mixture from idling is prevented from rotaring the spirals are prevented from turning by the cross-section of the mandrel and by the gaps which expand in the direction of pressing and which are situated between the pressing spirals. The insertion depth of the spirals, worms or mandrel is preferably computer controlled in order to limit compression.

Description

 Method and device for producing an extruded profile

The invention relates to a method and an apparatus for producing an extruded profile from a batch of small parts, in particular a batch of wood chips.

In known devices for the production of extruded profiles, a suitably prepared mixture of small parts is forced through a heated channel by means of a pressing device and largely hardens in this channel. The length of the heated duct determines the resistance of the strand to its movement through the duct and thereby also the compression.

It has been shown that the extruded profiles produced in a conventional manner have considerable irregularities with regard to the structural density over their entire length and that the mechanical properties of these extruded profiles are therefore possibly uneven over the entire length of the profile. In addition, especially in the production of more highly compressed profiles, there is a risk that the resistance of the strand as it moves through the heated duct increases to an impermissibly high value and the extrusion device stalls.

Under the impression of this problem, the invention has for its object to provide a method and an apparatus for extrusion through which or by which extruded profiles with largely constant mechanical properties can be produced in a reliable manner.

With regard to a method for producing an extruded profile, this object is achieved according to the invention by a method with the features specified in claim 1. As a result, it is advantageously possible to ensure trouble-free production of extruded profiles with high structural uniformity over a comparatively long operating period.

According to a particularly preferred embodiment of the method, the batch is continuously conveyed into the press space by means of a conveyor spindle which has at least one spatially convoluted groove. This advantageously makes it possible to form a profile whose structure does not have any irregularities such as can occur in piston presses.

A particularly advantageous control of the compression pressure of the strand can be achieved by controlling the axial depth of penetration of the conveyor spindle into the press chamber as a function of the current compression pressure. The instantaneous compression pressure can be determined, for example, by detecting the axial forces acting on the conveyor spindle or also by means of the spindle torque.

As an alternative to this, or in a particularly advantageous manner in combination with these measures, the cross section of the baling chamber or of the following channel is also advantageously changed via a channel wall which can be moved in a controlled manner as a function of a predetermined compression ratio. Suitable control values can advantageously be determined using a computer. Hydraulic cylinders with lever transmission, if necessary, are particularly suitable as corresponding actuators.

According to a further particularly preferred embodiment of the invention, the axial penetration depth of a mandrel element passed through the conveyor spindle is changed in a controlled manner as a function of the compression of the strand. This makes it possible to control the compression pressure via the frictional forces acting on the mandrel element.

With regard to a device for producing an extruded profile from a batch of small parts, the object specified at the outset is achieved by a device solved the features specified in claim 6. As an alternative to this or in combination with these measures, the object specified at the outset is also achieved by a device having the features specified in patent claim 23 or 30. Advantageous developments of the invention are the subject of the dependent claims.

The device for producing an extruded profile from a batch of small parts with a pressing device formed by a spiral or spindle element for pressing the batch of small parts through a press space into an at least sectionally heated channel, the cross section of the channel corresponding to the cross section of the profile to be manufactured and the compressed batch at least partially sets in the channel to form the profile, is characterized in a particularly advantageous manner in that the cross section of the press space widens to the cross section of the channel in the extrusion direction. This makes it possible to control the density of the strand forming in a reliable manner.

In an advantageous manner, the press space is designed such that it essentially expands continuously to the cross section of the channel. As an alternative to this, or in combination with it, it is also possible to design the press space in such a way that it widens in steps to the cross section of the channel.

An embodiment of the invention which is advantageous with regard to a particularly favorable compression of the mixture to form the strand and avoidance of excessive particle movement is provided in that the cross section of the pressing space in its initial region facing away from the strand is adapted to the cross section of the spindle or spiral element.

According to a particularly preferred embodiment of the invention, Spindelbzw. Spiral element and the baling chamber are matched to one another in such a way that in the initial region of the baling chamber the smallest distance of the baling chamber wall from the spindle or spiral element is in the range from 1 mm to 10 mm. A particularly even supply of the batch can be achieved according to a particularly preferred embodiment of the invention in that the batch is preceded by a batch feed section, the cross section of which widens in the conveying direction to the initial region of the batch.

Adequate sealing of the batch feed section can advantageously be achieved by adapting the initial area of the batch feed section facing away from the baling chamber at least over a circumferential range of 150 ° to the envelope surface of the spiral or spindle element.

In a transition area between the batch feed section and the press chamber, an inlet surface is advantageously formed which is inclined in the extrusion direction towards the axis of the spindle or spiral element. The angle of inclination of the inlet surface is preferably in the range from 10 to 60 ° with respect to the axis mentioned. It is also possible to round the inlet surface in a convex manner.

A particularly effective support of the conveying action of the spiral or spindle element can be achieved in that the wall of the batch inlet section adjacent to the spindle or spiral element is designed in such a way that it supports the conveyance of the batch into the press space. It is also possible to provide the corresponding wall sections with thread groove-like grooves.

The spiral or spindle element has at least one or more spatially helically wound screw threads for conveying the batch into the press space. The use of several screw threads results in a particularly even load on the spiral or spindle element.

The Schraubengaπg is preferably designed such that its cross-section decreases to a lesser extent in its course to the end of the spindle on the strand side than the specific volume of the increasingly compressed mixture accommodated in the screw passage on its way to the end of the spindle. The cross section of the screw thread can in terms of its cross-sectional area be substantially uniform. A particularly advantageous conveyance of the batch can be achieved if the cross section of the screw groove widens in area in the direction of the spindle end. According to a particularly preferred embodiment of the invention, the surrounding gap of the spindle or spiral element in the region of a transition zone between a batch inlet section and the pressing chamber is larger than the surrounding gap between the upstream wall of a spindle trough and the spiral or spindle element.

An advantageous embodiment with regard to a particularly uniform compression of the strand of a device for producing an extruded profile from a batch of small parts with a pressing device formed by a spiral or spindle element for pressing the batch of small parts through a pressing chamber into an at least partially heated channel, the cross section of the Channel corresponds to the cross section of the profile to be manufactured and the compacted mixture in the channel binds to form the profile is characterized in a particularly advantageous manner in that a front end face of the spiral or spindle element pointing towards the strand has a flattened pressure zone for formation an enlarged pressure area of the spindle or spiral end face on the strand.

The slope of the pressure zone can essentially be approximately 0 °. However, the slope of the pressure zone is preferably selected such that its slope corresponds to the strand feed achieved at the optimum operating point per spindle revolution. This results in a particularly smooth running of the foremost spindle or spiral end on the strand.

The pressure distribution in the line can be influenced by designing the pressure zone with a view to the desired profile cross section. The pressure zone can, for example, have a concave profile, as a result of which a reduction in the forces radially expanding the strand is achieved. The forces radially expanding the strand can be increased by a convex configuration of the pressure zone. In a particularly advantageous manner, the pressure zone is formed by a tongue section which forms a spring element whose bending resistance moment and, if necessary, protrusion is coordinated in such a way that a uniform pressure distribution results over the pressure zone in the form of hard metal inserts

According to a particularly preferred embodiment of the invention, the flattened pressure zone extends over a circumferential angle in the range from 30 to 270 °. The larger the pressure zone, the lower the surface pressure between the pressure zone and the corresponding initial area of the strand being built up

An advantageous embodiment with regard to a particularly uniform structure of the profile of a device for producing an extruded profile from a batch of small parts with a pressing device formed by a spiral or spindle element for pressing the batch of small parts through a press space into an at least partially heated channel, the cross section of the Channel corresponds to the cross-section of the profile to be manufactured and the compacted batch sets in the channel to form the profile, according to a particularly preferred embodiment of the invention, is characterized in that the batch of small parts is fed to the spiral or spindle element in the area of a batch feed section, the batch feed section comprises a spindle trough, and in the spindle trough a gap between the spiral or spindle element widens in the direction of the press chamber

Advantageously, as already stated, the pressing device comprises a front spindle with a spiral or helically wound screw groove for conveying the batch into the pressing chamber and for compacting the same

The cross-section of the screw groove or the screw thread means the free passage cross-section allowing the batch passage in a cut surface that is perpendicular to a screw groove axis. The screw groove axis connects the focal points of the surface of the individual Cut surfaces and thus also extends spatially wound around the longitudinal axis of the spindle.

According to a preferred embodiment of the invention, the cross section of the screw thread is selected such that it decreases in its course to the end of the spindle to a lesser extent than the specific volume of the mixture received in the screw thread and increasingly compressed on its way to the spindle end.

It is also possible to keep the cross-section of the screw thread essentially constant with regard to its cross-sectional area. A particularly reliable conveyance of the batch can be achieved by the cross-sectional area of the screw groove widening in the course towards the end of the spindle. In the present case, a spiral is to be understood as a conveying element with spatially tortuous passages, the windings of which extend in the axial direction in the manner of a helical spring without being axially supported by a core section. Spindle is to be understood as a conveying element, the windings of which are axially supported by a core section designed as a full cross section or possibly hollow. The measures proposed for spirals can also be advantageously implemented in spindles and vice versa.

Further details and features of the invention result from the following description of preferred exemplary embodiments in conjunction with the drawing. Show it:

Fig. 1 is a simplified axial sectional view through a

Extrusion device with a conveyor spindle and extended press room;

2a shows a simplified section through a batch feed section with a subsequent pressing chamber; 2b shows a section along the plane XX in FIG. 2a, however, additionally with an inserted spiral or spindle element which has a flattened pressure zone;

2c shows a side view of the device according to FIG. Fig.2a, from the right;

Fig. 3 is a perspective view of a spindle housing with in

Conveying direction of the diverging press chamber and wall sections adapted to the spindle envelope surface in the lower region of the batch inlet section;

4a shows a simplified plan view of the front end pressure zone of a spindle element;

4b shows a detailed view of the foremost pressure tongue section of the spindle element.

The illustration according to FIG. 1 shows an extrusion device in which a spiral is used to convey and compress the batch. The slope 139 remains constant until the end of the inlet 140. The helix width 141 is manufactured to the same extent over the entire length. From the end of the inlet 140 to the end of the spiral, the gradient increases from dimension 143 to dimension 144. The increase in the gradient per revolution can amount to approximately 15% of the outer screw diameter. In the exemplary embodiment, the immersion depth 145 is approximately 2.5 helical revolutions. Depending on the type of small parts, the immersion depth can be 0.3 to about 4 spiral turns. The increase in the slope does not have to be continuous, but can also take place disproportionately. In general, a helical pitch of about 8 to 15 ° is chosen. However, it can be over 20 °. The decisive factor here is the slope of the last turn of the spiral. The pressing space 147 connects to the filling space 146. It extends from the dimension of the filling space 148 to the dimension 149.

Immediately on the edge 140 of the filling area located at the front in the pressing direction the baling chamber closes and extends to the front end of the spindle

The expansion carried out in the press room is selected with a view to the required immersion depth, taking into account the type of small parts and the amount of compression. It can be about 0.5 to about 5 mm over the entire press room length. The ideal value can be determined empirically Part of the press room with the wedge-shaped extension 150 is designed here as an inserted wear part, which is easily exchangeable and, if necessary, renewable the spiral usually rotates faster than the batch is transported, small parts squeeze into the gap 152 between the spiral 153 and the inner walls 154 of the press space 147. If the gap dimension is sufficiently small, for example between 0.2 and about 2 mm, and the small parts have one sufficient size, they do not reach or only one small part in the gap 151 If, on the other hand, the gap dimension is significantly larger, for example more than 5 to 15 mm, the edge zone is compressed only by a moderate amount of about 0.1 to 0.3 kg / dm ³ higher than the inner zone of the strand with a higher flexural strength, this gap dimension should be chosen so that the small parts in the edge zone are oriented longitudinally to the strand. In this area, the invention provides for the regulation of the compression by a computer which is sufficiently quick and reliable to change the compression by adjusting the immersion depth of the dome in the strand responds and thereby enables a uniform compression

A channel section, referred to as a reactor, adjoins the pressing chamber, via which a hot gas, in particular superheated steam, can be applied to the already compressed mixture

The immersion depth of the spindle in the press chamber is changed with regard to the desired degree of compression or depending on the current compression pressure using a computer and actuators (not shown in more detail here). The same applies to the coaxial arrangement of the spindle polygonal mandrel, the depth of immersion in the strand is also controlled controlled. In the case of a diverging baling chamber, the strand density is increased by moving the spindle deeper into the baling chamber. The strand density is reduced in this baling chamber configuration by pulling it back against the conveying direction. In the case of a cylindrical press room or a press room with the same cross section over its entire length, this control effect is reversed.

The spindle and / or the mandrel can be moved back and forth with a possibly small amplitude during the continuous pressing process. The movement of the mandrel and spindle is advantageously in phase opposition.

The representations according to FIGS. 2a, 2b and 2c show a further preferred embodiment of a headstock according to FIG. the invention.

The headstock here comprises a batch feed section a which has a filling opening 1 for supplying the batch, for example of the wood chips, to a spindle element 3 accommodated in a spindle trough 2 (FIG. 2b).

The spindle trough 2 forms a groove widening in cross section in the conveying direction and, in the embodiment shown here, is adapted to the spindle in its initial region facing away from the strand, leaving a small gap.

A transition zone b adjoins the batch feed section a, via which the conveyed batch reaches a press chamber 4. The transition zone b comprises an inlet surface 5 widening from the press chamber 4 to the filling opening and an extension wall 6 extended towards the press chamber 4. The inlet surface 5 can also be designed as a preferably convexly rounded surface. The angle of inclination ß with respect to the spindle axis is in the range from 10 to 60 °. The length of the transition zone b is matched to the spindle pitch and is preferably in the range from 1/15 to approximately ^Λ A of the spindle pitch.

The transition zone b is followed by the cross section in Conveying direction of diverging press chamber 4 The cross section of the downstream end area of the press chamber, which is downstream in the extrusion direction, merges with the cross section of the following channel surrender

The spindle element 3 shown in Fig. 2 protrudes by about 1/3 of the baling chamber length into the diverging baling chamber 4. The baling chamber divergence angle is in the range of approximately 0.5 ° to approximately 25 ° depending on the wall section Combinations of step-like extensions and continuously expanded sections are also possible.The front end area of the spindle is flattened.This flattening forms an enlarged pressure zone, which reduces the maximum surface pressure.The flattening here has an angle δ with respect to the front the inclined surface of the conveyor helix has a reduced slope. The flattening can be essentially completely flat or also have a slight curvature

Fig. 2c shows a view of the headstock like Fig. 2a from the right. Here you can see the upper, diverging wall 7, the lower diverging wall 8 and the two lateral, also diverging walls 9 and 10 of the press chamber 4. Furthermore, the extension walls 6 are also axial on the same length as the inlet surface 5 (not visible here), can be seen The wall of the spindle trough 2, which tapers here conically against the direction of travel, is indicated in the foot area of the spindle element 3, a passage opening is provided, the inner contour of which is essentially the hollow surface of the corresponding section corresponds to the spindle element

The simplified perspective illustration according to FIG. 3 shows a headstock with the forward path sections gradually transitioning to the profile cross section in the conveying direction. Shown are the batch inlet section a, which is attached to it adjoining transition zone b and the subsequent press space section and an adjoining duct section whose cross section corresponds to the cross section of the profile to be manufactured

In the batch supply section a there is the spindle trough 2, which is initially essentially semi-cylindrical in cross section and which merges into the transition zone b, with it expanding slightly

In the transition zone b, a first widening of the channel cross section into the press space 4 takes place below the convexly curved inlet surface 5. The end region of the press chamber 4 lying downward in the direction of the strand already corresponds in cross section to the cross section of the following channel section. The transitions are largely continuous and only indicated by light edges

As already explained in connection with FIG. 2b, the front end area of the spindle element is advantageously provided with a special detail geometry in the form of a flattening. This enables a particularly inexpensive and uniform compression of the strand that forms, with significantly reduced friction and damage to the fiber structure of the small parts In In a particularly preferred manner, the spindle is designed so that the pressure area acting on the strand is as large as possible

According to the details shown in FIGS. 4a and 4b, the flattened portion 10 formed on the end face of the spindle extends over an angular range γ which is determined as a function of the axial thickness of the helix and is in the range from approximately 30 to 270 °

In the area of the flattening 10, the slope of the pressure zone formed in this way is significantly less than the slope of the helix in the area adjacent upstream 4b, which shows a simplified development of the last end section of the helix, as the angle ε characterized. This angle ε is significantly smaller than the pitch angle α in the end region of the spindle or spiral element 3. The end edge of the end section of the helix can be designed with a corresponding contour in view of a desired chip orientation. The flattening can be concave or convex at least in sections. The optimal course of a corresponding roof or valley line 12 can be determined empirically and can deviate from a circular line.

Claims

claims

1 Process for producing an extruded profile from a batch of small parts in which the batch of small parts is forced through an at least sectionally heated channel by means of a rotary-driven spiral or spindle element, the batch compressed here forming a strand complementary to the cross section of the channel and on its way through binds the channel to form a profile, characterized in that the mixture is compressed in a press chamber upstream of the channel and diverging in cross-section with respect to its cross-section, the cross-section of which extends in the direction of extrusion to the cross-section of the channel

2 The method according to claim 1, characterized in that the batch is continuously required by means of the spiral or spindle element in the press room

3 The method according to claim 2, characterized in that the current compression pressure is controlled by the axial depth of penetration of the spiral or spindle element in the press chamber

4 The method according to at least one of claims 1 to 3, characterized gekennzeichent that the cross section of the baling chamber or the subsequent channel is changed via a controlled movable channel wall depending on a predetermined compression ratio

5 The method according to at least one of claims 1 to 4, characterized in that the axial depth of penetration of a mandrel element passed through the spiral or spindle element is changed in a controlled manner as a function of the compression of the strand

6 Device for producing an extruded profile from a batch of small parts with a pressing device formed by a spiral or spindle element for pressing the batch of small parts through a press space into at least one Sectionally heated duct, the cross-section of the duct corresponding to the cross-section of the profile to be produced and the compacted mixture in the duct at least partially sets to form the profile, characterized in that the cross-section of the pressing space widens in the extrusion direction to the cross-section of the duct

7 Apparatus according to claim 6, characterized in that the press space extends substantially continuously to the cross section of the channel

8 Apparatus according to claim 6, characterized in that the press space extends in steps to the cross section of the channel

9. The device according to at least one of claims 6 to 8, characterized in that the cross section of the press chamber is adapted in its initial region facing away from the strand to the cross section of the spindle or spiral element

10 Device according to one of claims 6 to 9, characterized in that in the initial region of the baling chamber, the smallest distance between the baling chamber wall and the spindle or spiral element is in the range of 1 mm to 10 mm

11 Device according to at least one of claims 6 to 10, characterized in that the batch is preceded by a batch feed section whose cross section widens towards the start region of the press chamber in the direction of travel

12 Device according to at least one of claims 6 to 11, characterized in that the starting area of the batch feed section facing away from the pressing space is adapted at least over a circumferential area of 150 ° to the hollow surface of the spiral or spindle element

13 Device according to at least one of claims 6 to 12, characterized in that in a transition region between the Batch inlet section and the press chamber an inlet surface is formed which is inclined in the extrusion direction to the axis of the spindle or spiral element.

14. The apparatus according to claim 13, characterized in that the angle of inclination of the inlet surface is in the range of 10 to 60 ° with respect to said axis.

15. The apparatus according to claim 13 or 14, characterized in that the inlet surface is convexly rounded.

16. The device according to at least one of claims 6 to 15, characterized in that the wall of the batch inlet section adjacent to the spindle or spiral element is profiled in such a way that it supports the conveyance of the batch into the press space.

17. The device according to at least one of claims 6 to 17, characterized gekennzeichent that the spiral or spindle element has at least one or more spatially helically wound screw flights to promote the batch in the press room.

18. The apparatus according to claim 17, characterized in that the cross section of the screw thread is selected such that it decreases in its course to the end of the spindle to a lesser extent than the specific volume of the increasingly compressed mixture accommodated in the screw thread on its way to Spindle end.

19. The apparatus according to claim 17, characterized in that the cross section of the screw thread is substantially constant with respect to its cross-sectional area.

20. The apparatus according to claim 17, characterized in that the cross section of the screw groove expands in area in the course of the spindle end.

21. The device according to at least one of claims 6 to 20, characterized in that the surrounding gap of the spindle or spiral element in the region of a transition zone (b) between a batch feed section (a) and the press chamber (4) is larger than the surrounding gap between the upstream lying wall of a spindle trough (2) and the spiral or spindle element (3).

22. Device for producing an extruded profile from a batch of small parts with a pressing device formed by a spiral or spindle element for pressing the batch of small parts through a press space into an at least sectionally heated channel, the cross section of the channel corresponding to the cross section of the profile to be manufactured and compressing it Batch binds in the channel to form the profile, characterized in that a front end face of the spiral or spindle element facing the strand has a flattened pressure zone to form an enlarged pressure surface on the spindle or spiral end face on the strand.

23. The device according to claim 22, characterized in that the slope of the pressure zone is substantially 0 °.

24. The device according to claim 22, characterized in that the slope of the pressure zone corresponds to the strand feed reached at the optimum operating point per spindle revolution.

25. Device according to one of claims 22 to 24, characterized in that the pressure zone is concavely profiled, to reduce the radially expanding forces or convex, to increase the radially expanding forces.

26. Device according to one of claims 22 to 25, characterized in that the pressure zone is formed by a tongue section which forms a spring element whose bending resistance moment and optionally protrusion is coordinated such that there is a uniform pressure distribution over the pressure zone.

27. The device according to at least one of claims 22 to 26, characterized in that the spindle or spiral element is provided in the region of the pressure zone with wear-reducing agents.

28. The device according to at least one of claims 22 to 27, characterized in that the flattened pressure zone extends over a circumferential angle in the range of 30 to 270 °.

29. Device for producing an extruded profile from a batch of small parts with a pressing device formed by a spiral or spindle element for pressing the batch of small parts through a press space into an at least sectionally heated channel, the cross section of the channel corresponding to the cross section of the profile to be produced and compressing it Batch sets in the channel to form the profile, the batch of small parts being fed to the spiral or spindle element in the area of a batch inlet section and the batch inlet section comprising a spindle trough (2), a gap between the spiral or spindle element (3) in the spindle trough. expanded in the direction of conveyance to the press chamber (4).