CA2215947C

CA2215947C - Process and device for extruding plastic melts to form hollow bodies

Info

Publication number: CA2215947C
Application number: CA002215947A
Authority: CA
Inventors: Wilfried Ensinger
Original assignee: Individual
Current assignee: Individual
Priority date: 1995-03-25
Filing date: 1996-03-02
Publication date: 2006-05-16
Anticipated expiration: 2016-03-02
Also published as: DE59605444D1; WO1996030188A1; CA2215947A1; EP0817715B1; JPH11502784A; EP0817715A1; ATE193862T1; GR3034239T3; ES2146871T3; DK0817715T3; DE19510944C1; PT817715E

Abstract

In a process for extruding polymer melts (25) to form hollow chamber sections (21) by pressing the polymer melt through a shaping tool (24) with an internal shaping mandrel (26) and by subsequently sizing and cooling the hollow chamber section strand in a sizing and cooling unit (31) it is provided for the sizing and cooling of the hollow chamber section strand to be carried out in the sizing and cooling unit under extrusion pressure. A device for carrying out this process is characterized in that shaping tool (24) and sizing and cooling unit (31) are rigidly connected to form a closed system so that the strand extrusion pressure prevailing in the shaping tool can be propagated into the sizing and cooling unit, and that the shaping mandrel (26) protrudes out of the shaping tool (24) into the sizing and cooling unit (31).

Description

Process and ~ePlQQ fox Extruding Plastic Melts to Form Hollow~r Hodiee The invention relates to a pxocess for extrud~.ng polymer melts to form hollow chamber sections by pressing the polymer melt through a heated shaping tool with an internal shaping mandrel, wherein shaping tool and shaping mandrel determine the outer and inner contours of the hollow chamber section, and by subsequently sizing and cooling the hollow chamber section strand exiting from the shaping tool in a sxzixig and cooling unit. In addition, the invention relates to a device for ' carrying out such a process., comprising a shaping tool which contains an internal shaping mandrel and a sizing and cooling ' unit. , ~ . .
Economic aspects very cften require hollow chamber sections to be produced instead of solid sections because material can be saved by this and a greater production speed can be used.
However, iz~ the case of hollow chamber sections greater requirements have to be met with respect to measurement, shape and functional accuracy and these are not always easy~to fulfill. Tn the case of known processes and devices for extruding polymef melts to form hollow chamber sections - (Michaeli "Extrusiwnswerkzeuge fiat Kun.ststoffe", 1991, in particular pgs. 194 to 197) the following, restrictive conditions, in, particular, have to. be fulfilled inter~alia:
The profile crass'section is intended to be kept,as simple as -possible. wherein interior webs are to be avoided if.at all possible. The wall th~.ck~ress of interior webs should be selected to be around 20 to 30 o smaller than the wall thickness of the outer wall. The section should be designed such that it retains its shape for a short time after exiting from the tool, even in the plastic state. Material accumulations and cracks in the wall thickness are to be avoided since these make the control of the melt flow distribution in the tool difficult, and problems result during cooling (sunk spots on account of varying shrinkage and warping of the section). The cavities in the hollow chamber section should not be too small as, otherwise, the bodies (mandrels) displacing the melt are too small and cannot be adequately guided. Finally, the section axis is intended to be located in the worm shaft of the extruder used in order to keep flow path differences as small as possible.
For the production of the known hollow chamber sections, so-called monoextrusion tools are used, which are followed by sizing and cooling units as separate units in a spatially separated manner, wherein a vacuum is often used for the sizing. As a result of the spatial separation of shaping tool, on the one hand, and sizing and cooling unit, on the other hand, the shaped melt passes without pressure into the last-named unit and is there shaped and cooled without pressure and under vacuum. In the intermediate space between shaping tool and sizing and cooling unit, where ambient temperature and atmospheric pressure naturally prevail, the extruded hollow chamber section, which exits from the shaping tool and is intended to be as small as possible in order to be able to adjust it again in a simple manner in the sizing and cooling unit, will generally swell out.

All these restrictions and conditions result in the fact that up to now only relatively simple hollow chamber sections could be produced while, in the case of hollow chamber sections with complicated cross-sectional shapes, the requirements with respect to accuracy and dimensional stability could be met only with difficulty.
A process according to the preamble to patent claim 1 is known from DE-24 34 381A1. This publication relates to the production of a hollow chamber section with closed cells, i.e.
without axially continuous hollow chambers. The cooling obviously takes place not at strand extrusion pressure but at atmospheric pressure.
US-A-31 82 108 discloses a process for extruding tubes from polymers having only one single hollow chamber, wherein in a sizing and cooling unit a wall made porous, for example, by openings abuts either on the outer or inner side of the extruded pipe, a degasification of the extrudate taking place through this wall. On account of the difference in pressure required for the degasification, the extrudate cannot be subject to extrusion pressure in the sizing and cooling unit.
It is known from US-51 32 062 to extrude a foamed polymer material to form simple hollow sections, for example to form tubing without axially extending inner webs. A polymer material cannot, as is well known, foam under strand extrusion pressure. For foaming, it is, on the contrary, necessary to relieve the pressure to such an extent that the foam can form in the shaped cavities available for this. For this reason, US-51 32 062 also does not disclose any sizing and cooling of a hollow section strand under strand extrusion pressure since, in AMENDED SHEET

- 3a -this case, only foamed polymer material is used. Only simple profile cross sections, for example tubes, can be produced with this known process.
The object underlying the invention is to design a generic process and a generic device such that very complex, unsymmetric hollow profile cross sections, the section axes of which can also be located outside the worm shaft of the extruder used, and the outer walls and inner webs of which can AMENDED SHEET

have different dimensions and shapes, sharp edges, undercuts and thickness flaws, can also be produced with the greatest precision, i.e. without sunk spots and vacuoles.
The object is accomplished in an inventive process in that a hollow chamber section with axially continuous hollow chambers and, in particular, with different outer wall and inner web thicknesses is extruded and the sizing and cooling of the hollow chamber section strand is carried out in the sizing and cooling unit under extrusion pressure.
A device for carrying out this process is characterized in accordance with the invention in that the shaping tool containing the shaping mandrel is rigidly connected to the sizing and cooling unit to form a closed system such that the strand extrusion pressure prevailing in the shaping tool is propagated into the sizing and cooling unit, and that the shaping mandrel of the shaping tool protrudes into the sizing and cooling unit.
The following description of preferred embodiments of the invention serves to explain the invention in greater detail in conjunction with the attached drawings. These show:
Figure 1 a schematized sectional view of a conventional device for extruding polymer hollow chamber sections;
Figure 2 a sectional view along line 2-2 in Figure l;

Figure 2a a diagrammatic partial view of a hollow chamber section, produced with the device according to Figures 1 and 2;
Figure 3 a schematic sectional view of an inventive device for extruding polymer hollow chamber sections;
Figure 4 a sectional view along line 4-4 in Figure 3;
Figure 4a a diagrammatic partial view of a hollow chamber section, produced with the device according to Figures 3 and 4;
Figure 5 a modified device, similar to Figure 3, with a multiple-part shaping mandrel;
Figure 6 a different embodiment of a device similar to Figure 3 with attemperated shaping mandrel;
Figure 7 a sectional view along line 7-7 in Figure 6;
Figure 8 a schematic sectional view of a modified shaping mandrel with fingers of different lengths;
Figure 9 a device similar to Figure 3 with the possibility of introducing additional polymer into the hollow chamber section formed;
Figure 10 a sectional view along line 10-10 in Figure 9;

Figure 11 a device again modified in comparison with Figure 3 with the possibility of introducing an additional component into the cavity or cavities of the hollow chamber section;
Figure 12 a sectional view along line 12-12 in Figure 11 and Figure 13 a further modification of the device according to Figure 3.
A conventional device for extruding polymer melts to form hollow chamber sections is illustrated schematically in Figures 1 and 2. With this device, a hollow chamber section 1 having the cross-sectional shape illustrated in Figure 2a with outer walls 2 and inner webs 3 can, for example, be produced. The device comprises a shaping tool 4 (nozzle) which is arranged on an extruder (not illustrated), e.g. a worm extruder, proceeding from which a polymer melt 5 is pressed through the tool 4 with an extruding pressure which can be adjusted in a conventional manner. The shaping tool 4 has in its relatively spacious, rectangular exit opening, which determines the outer contour of the hollow chamber section 1, a shaping mandrel 6 which comprises three fingers 7 (Figure 2) which, for their part, determine the inner contour of the hollow chamber section 1, i.e., in particular, the three cavities 8 located next to one another. The shaping tool 4 is outwardly enclosed by a heating device 9. The heated, plasticized polymer melt 5 flows through the tool 4 in the direction of arrow A.

A sizing and cooling unit 11, into which the polymer melt 5 shaped to form the hollow chamber section 1 enters in order to be sized and cooled therein, is arranged at the exit side of the shaping tool 4, in spaced relationship thereto. The sizing takes place with the aid of a vacuum device 12, which is indicated only schematically and with the aid of which the outer walls 2 of the section 1 are held on the inner walls of the sizing and cooling unit 11 acting as a "slip mold" while the section 1 is advanced through the unit 11. With the aid of a cooling device 13 which is likewise indicated only schematically in Figure l, the hollow chamber section 1 is cooled in the sizing and cooling unit to approximately room temperature.
The finished hollow chamber section 1 is withdrawn by means of a take-up device 14 which is arranged behind the sizing and cooling unit 11 in flow direction (arrow A).
Room temperature and atmospheric pressure essentially prevail in the space between the shaping tool 4 and the sizing and cooling unit 11. As soon as the polymer melt 5 has left the shaping tool 4, it becomes "pressure-less" so that the hollow chamber section 1 passes through the space between shaping tool 4 and sizing and cooling unit 11 without pressure.
Furthermore, the sizing and cooling takes place in the unit 11 under vacuum without pressure.
The shaping mandrel 6 essentially reaches exactly as far as the exit opening of the shaping tool 4, from which the polymer melt shaped to form the hollow chamber section 1 exits. As illustrated, lines 15 are formed in the fingers 7 of the mandrel 6, via which air, where necessary compressed air, can _ g _ be introduced into the hollow chambers 8 of the hollow chamber section 1.
Figures 3 and 4 show the fundamental design of a device according to the invention for extruding polymer melts to form hollow chamber sections. A typical hollow chamber section 21 produced with the device according to Figures 3 and 4 is illustrated in Figure 4a. It comprises outer walls 22 and inner webs 23 which, together with the outer walls 22, enclose three continuous hollow chambers 28, wherein the inner webs 23 are designed to be thinner than the outer walls 22. Moreover, the section 21 has externally located webs 30, the cross-sectional shape of which is apparent from Figure 4a.
As is shown in Figures 3 and 4, the device comprises a shaping tool 24, in which a polymer melt 25 is shaped under strand extrusion pressure to form a hollow chamber section 21. The shaping tool 24 is again arranged on a conventional extruder.
The tool 24 contains in a cavity, the inner walls of which determine the outer contour of the hollow chamber section 21, a shaping mandrel 26 with three fingers 27 which are arranged in mutual spaced relationship to one another and are of equal length (Figure 4). The fingers 27 determine the inner contour of the hollow chamber section 21, wherein the webs 23 of the section 21 are formed in the spaces between the fingers 27.
The mandrel 26 consisting of the fingers 27 is rigidly anchored in the shaping tool 24. The polymer melt 25 can comprise unfoamed or non-foaming thermoplastic, duroplastic or elastomeric polymers, e.g. polyamide, polypropylene, polyester;
phenolic resin, polymers on an epoxy resin basis; polyurethane.
The strand extrusion pressure is always greater than l bar, e.g. between 2 and several hundred bars, preferably 20 to 200 bars, in particular 30-100 bars. It depends on the polymer used, on the wall thicknesses of the section produced and on fiber reinforcements and other fillers in the polymer. In particular in the case of fiber reinforcements (e.g. glass or carbon fibers), high pressures, e.g. 200 bars, are used.
With an insulating board 20 connected therebetween, which can also, where necessary, be left out, a sizing and cooling unit 31 is connected directly to the shaping tool 24 and is rigidly connected to the tool 24 to form a closed system. The actual design of the sizing and cooling unit 3l can be conventional, i.e., for example, such as in the case of the sizing and cooling unit 11 illustrated in Figure 1. In Figure 3, only a cooling through lines 33 is indicated, the sizing can take place with the aid of a vacuum in a manner which is not illustrated.
Since the sizing and cooling unit 31 is rigidly connected to the shaping tool 24, thereby forming a closed system, the strand extrusion pressure, to which the hollow chamber section 21 extruded from the shaping tool 4 is subject, propagates into the sizing and cooling unit 31 so that essentially the same pressure prevails in this unit, at least in the regions of the unit 31 and the board 20 adjacent to the tool 24, and the polymer melt is sized in this unit 31 at this pressure and caused to be shaped. This a first, essential difference to the conventional device shown in Figure 1, with which the shaping of the polymer melt takes place in the sizing and cooling unit without pressure. It has been shown that as a result of the hardening under pressure of the polymer melt 25 forming the hollow chamber section 21 in the sizing and cooling unit 31 a considerably greater shape retention and stability of this section can be achieved.
As is apparent, in addition, from Figure 3, the shaping mandrel 26 extends with its fingers 27 relatively far into the sizing and cooling unit 31 so that the shaping of the hollow chamber section 21 caused by the mandrel 26 and its fingers 27 also continues right into the sizing and cooling unit 31. This is an additional reason for the fact that essentially more complex, unsymmetric profile cross sections, the section axes of which can, for example, be located outside the worm shaft of an extruder, can be produced with the device according to Figures 3 and 4 precisely and without sunk spots and vacuoles and with very narrow tolerances, which was not previously possible. In the case of conventional hollow chamber sections, there was, for example, the difficulty of subsequently introducing insertions, e.g. wooden strips, into one or other of the hollow chambers 8 (Figure 2a) because considerable tolerances occurred in these hollow chambers. Hollow chamber sections 21 which are produced with the device according to Figures 3 and 4 have hollow chambers 28 with, overall, exact nominal dimensions so that insertions can be positioned in them without difficulty. The shaping tool 24 itself is again enclosed by a heating device 29 which corresponds to the heating device 9 in Figures 1 and 2.
The device according to Figure 5 differs from that according to Figures 3 and 4 only in that the shaping mandrel 26 with its fingers 27 is not of a one-piece design but consists of several parts. Figure 5 shows a point of separation 36, at which the parts of the fingers 27 located in the sizing and cooling unit 31 can be connected, e.g. by screws, to the part of the mandrel 26 which is arranged in the actual shaping tool 24. Insulating elements 37 can be inserted between the individual parts during the connection of these mandrel parts.
The device illustrated in Figures 6 and 7 again corresponds for the most part to the device according to Figure 3. In contrast to Figure 3, the mandrel 26 and its fingers 27 are, however, not designed in Figures 6 and 7 to be solid but they contain heating or cooling lines 38 (merely indicated schematically in Figures 6 and 7), via which the mandrel 26 with its fingers 27 can be attemperated in a selective manner, i.e. cooled or heated, with the aid of a suitable medium.
Figure 8 shows schematically in a sectional view of the sizing and cooling unit 31 (at right angles to the sectional view according to Figures 4 and 7) a mandrel, the fingers 27 of which have different lengths in the region of the unit 31. As a result of this, different section wall thicknesses can be produced, as well as extrusion pressures and cooling capacities, in a selective manner, whereby the accuracy of the hollow chamber section 21 produced is again increased.
In the case of the, again, modified embodiment of an extrusion device according to the invention, which is shown in Figures 9 and 10, an additional polymer melt, from which certain parts of the section 21 are formed, can be introduced under pressure via an auxiliary line 41 which is connected to a side or auxiliary extruder outside the shaping tool 24, wherein the pressure of this additional melt can be different to that of the polymer melt 25 forming the main strand. As illustrated schematically in Figures 9 and 10, the exit 19 of the auxiliary lines 41 is respectively designed and arranged such that the additional polymer melt exiting therefrom forms the intermediate walls or webs 23 of the hollow chamber section 21. In an analogous manner, other areas of the hollow chamber section 21 could also be formed from an additional polymer melt or also from a combination of this additional polymer melt with the polymer melt 25 supplied as main strand.
It is also possible to attach stationary flow obstacles in the flow path of the polymer melt in the region of the mandrel 26 and its fingers 27, these obstacles resulting in a selective anisotropy of the solidified polymer filled, in particular, with additional materials, e.g. glass fibers, whereby certain functional properties of the hollow chamber section 21 can likewise be regulated.
Figures 11 and 12 show an extrusion device 24, with which, in contrast to Figures 9 and 10, auxiliary lines 42 are not arranged between the fingers 27 of the shaping mandrel 26 but in the fingers 27 themselves. In this way, it is possible to introduce certain additional components, in particular, foamable polymer components as well, into the hollow chambers 28 of the hollow chamber section 21, namely into the gradually solidifying or already hardened hollow chamber section 21 and in the same operating step as the actual extrusion process, depending on the length of the line 42 which, as illustrated in Figure 11, can also protrude beyond the front end side of the mandrel 26. The additional component serving as filler need not be filled into all the hollow chambers 28 of the hollow chamber section 21. In certain cases, it may be sufficient to fill only one single hollow chamber 28 with such an additional component, e.g. a foamable polymer.

If a foamable component is used, the foam expansion forces occurring during foaming can be utilized as well in a selective manner for the shaping and sizing of the hollow chambers 28 of the hollow chamber section 21.
Finally, in the case of the extrusion device illustrated in Figure 13, which, again, essentially corresponds to the embodiment according to Figure 3, a first sizing and cooling device 31 has a second such unit 43 connected to its outlet side, this second unit comprising, as in Figure l, a vacuum device 44 as well as a cooling device 45 and likewise having the hollow chamber section 21 passing through it.
As is also apparent from Figure 13, the individual fingers 27 of the mandrel 26, like in Figure l, have lines 46 passing through them which serve to introduce compressed air, the same as in the case of Figure 1. This means that the sizing of the hollow chamber section 21 can be promoted from inside.
Moreover, the compressed air can also aid the cooling of the hollow chamber section 21.
It is possible to produce several hollow chamber sections 21 at the same time next to one another in the manner described in that several devices, consisting of shaping tool 24, shaping mandrel 26 as well as sizing and cooling unit 31, are arranged next to one another or a single device of this type is provided with several exit openings for hollow chamber sections 21.
In the case of the embodiments described thus far, the mandrel is designed as a special part and inserted into the shaping tool 24 as well as the sizing and cooling unit 31. The mandrel 26 could, however, also be formed in one piece out of the tool 24; namely, in particular, when the hollow chamber sections are relatively uncomplicated. The mandrel can also, like shaping tool 24 and sizing and cooling unit 31 by means of the insulating board 20, be thermally separated from the shaping tool 24 by means of a corresponding insulating insert. The same result could also be achieved with contact surfaces between mandrel 26 and tool 24 which are reduced in size. Such reduced contact surfaces can also be formed between shaping tool 24 and sizing and cooling unit 31 in order to reduce the transfer of heat. The mandrel 26 with its fingers 27 can also be designed to be displaceable and stoppable in extrusion direction A.

Claims

1. Process for extruding polymer melts (25) to form hollow chamber sections (21) by pressing the polymer melt through a heated shaping tool (24) with an internal shaping mandrel (26), wherein shaping tool and shaping mandrel determine the outer and inner contours of the hollow chamber section, and by subsequently sizing and cooling the hollow chamber section strand exiting from the shaping tool in a sizing and cooling unit (31), characterized in that a hollow chamber section with axially continuous hollow chambers (28) and, in particular, with different outer wall and inner web thicknesses is extruded and the sizing and cooling of the hollow chamber section strand is carried out in the sizing and cooling unit whilst maintaining the extrusion pressure.

2. Process as defined in claim 1, characterized in that additional polymer melts are introduced under pressure in the region of the shaping mandrel (26).

3. Process as defined in claim 1, characterized in that an additional component, in particular a foamable component, is introduced into the hollow chamber(s) of the hollow chamber section as filler in the region of the shaping mandrel (26).

4. Process as defined in claim 1, characterized in that compressed air is introduced into the hollow chamber(s) of the hollow chamber section in the region of the shaping mandrel (26).

5. Device for carrying out the process as defined in any one of claims 1 to 4, comprising a shaping tool (24) con-taining an interior shaping mandrel (26), and a sizing and cooling unit (31), characterized in that the shaping tool (24) containing the shaping mandrel (26) is rigidly connected to the sizing and cooling unit (31) to form a closed system such that the strand extrusion pressure prevailing in the shaping tool is propagated into the sizing and cooling unit, and that the shaping mandrel (26) of the shaping tool (24) protrudes into the sizing and cooling unit (31).

6. Device as defined in claim 5, characterized in that an insulating board (20) or contact surfaces reduced in size are arranged between shaping tool (24) and sizing and cooling unit (31).

7. Device as defined in claim 5, characterized in that the shaping mandrel (26) is composed of several parts.

8. Device as defined in claim 5, characterized in that the shaping mandrel (26) is adapted to be attemperated.

9. Device as defined in claim 5, characterized in that the shaping mandrel (26) comprises several fingers (27) of different lengths.

10. Device as defined in claim 5, characterized in that additional polymer melt is adapted to be introduced under pressure in the region of the shaping mandrel (26) via an auxiliary line (41).

11. Device as defined in claim 5, characterized in that a line (42) is formed in the shaping mandrel (26) for introducing additional components, in particular a foamable component, into the hollow chamber(s) (28) of the hollow chamber section (21).

12. Device as defined in claim 5, characterized in that a line (46) is formed in the shaping mandrel (26) for introducing compressed air into the hollow chamber(s) (28) of the hollow chamber section (21).

13. Device as defined in claim 1, characterized in that the shaping mandrel (26) is adapted to be displaced and stopped in extrusion direction (A).