Calibration element and calibration procedure

专利摘要:
The invention relates to a calibration element in a wet calibration of an extrusion device for a plastic profile, characterized by a mechanical and I or fluid mechanical means (30, 31, 40, 50) for removing and I or for keeping particles (3) away from a surface of the plastic profile ( 2) to prevent mechanical damage to the surface.
公开号:AT513892A1
申请号:T760/2013
申请日:2013-10-01
公开日:2014-08-15
发明作者:Bernhard Fischer；Gerhard Anders
申请人:Greiner Tool Tec Gmbh；
IPC主号:

专利说明:

PATENT ATTORNEY
Greiner Tool.Tec. GmbH N0011345 / 1 DIPL. I Nope .. P5TERITZE. , 1060WIEN * AMfl5LINp§Tn |, ^ E8 ·. ·. · .; CHW ^ .tA (j ^ 4 · · .. ·;
description
The invention relates to a calibration element having the features of claim 1 and a calibration method having the features of claim 10.
Plastic profiles made of thermoplastic materials are manufactured by extrusion. In this case, a nozzle and a calibration are used for the shaping of a plastic profile.
Calibrations for the production of plastic profiles, e.g. Window profiles, usually have a dry and a wet calibration device, the hot extrudate after exiting the nozzle first passes through the Trockenkalibrierungs- and then the Naßkalibrierungsvorrichtung. At the end of the calibration and after complete cooling of the plastic profile to room temperature, the plastic profile must have the desired contour.
The wet calibration device has a plurality of vacuum tanks arranged one behind the other for substantially cooling the plastic profile, after it has already been partially cooled in the dry calibration. In the wet calibration device, approximately 500 mm calibration elements (so-called short calibrators or diaphragms) are arranged at intervals of approximately 100 mm at the outset, each of which has a passage opening which largely corresponds to the geometry of the plastic profile.
The vacuum tanks are basically closed on all sides, and have openings for the entry and exit of the plastic profile only at the end faces. The vacuum tanks are subjected to suppression in the order of about 30 to 200 mbar, whereby the plastic profile is slightly "inflated" and applies to the Durchgangsöffiiungen the Kalibrierelemente.
The plastic profile thus cools in a defined shape, so that the shape retention is ensured. The cooling water flows through the vacuum tanks from a few supply lines to a few outlets. The suppression in the vacuum tanks only needs 1 2/28
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The manufacturing costs for the calibration elements are comparatively low, because they do not require supply and distribution bores for suppression and cooling water.
The wet calibration device upstream of the dry calibration device has up to eight calibration elements. These calibration elements each have running surfaces which correspond approximately to the contour of the plastic profile. However, there are in detail dimensional or geometric differences to follow the length reduction with decreasing temperature of the plastic and to compensate for the delay due to different cooling rates.
The dry calibration devices are supplied with vacuum and cooling water. The negative pressure applied to the running surfaces of the calibration elements causes the plastic profile to be sucked onto the running surfaces. The suppression acts e.g. via so-called vacuum slots between the plastic profile and the calibration and ensures that the plastic profile rests without play on the tread, so that the plastic profile occupies a defined outer contour. Via connection and distribution bores, a flow connection to vacuum pumps is established within the calibration device. Outside the dry calibration devices, the vacuum is transmitted by means of hoses and connection points.
Due to the close contact of the plastic profile with the running surfaces for Trockenkalibrierungs device heat transfer from the hot plastic profile is carried out on the cold Trockenkalibrierungsvorrichtung.
In order to prevent or at least minimize an increase in the temperature of the dry calibration devices, they are cooled, usually continuously. This is done by passing cooling water through cooling channels close to the tread. Each of these cooling channels requires a supply line and a discharge for the cooling water, but several cooling channels can be combined. Thus, for every 3/28 2
Greiner Tool.Tec. GmbH N0011345 / 1 ························································································································································································································ ··· ·· M · · Cooling circuit two water connections required, each for the supply line and for the discharge.
The cooling water is normally used in a refrigeration cycle, i. it absorbs heat in the area of the calibration and this is removed again by a cooling device.
The cooling water treatment (cooling unit, circulating pumps, cooling water central tank, filter systems, etc.) is summarized in one area of the extrusion plant, where there is usually a spatial separation between the cooling water treatment and the cooling water consumers (extrusion lines with calibration).
The cooling water supply includes closed or open connection pipes (pipelines and / or channel-like channels). In a storage tank, a larger amount of cooling water is stored. This storage tank is designed to supply multiple extrusion lines and, depending on the production requirements, only a few or even all extrusion lines can produce at the same time.
The storage capacity is usually about 10 to 200 m, depending on the number of extrusion lines to be supplied. In the sense of economical use of the cooling water, this is usually used for one to three months. Open cooling water circuits (water has contact with air, channel flow) are very common here.
Experience has shown that the cooling water is often contaminated by organic and / or inorganic contaminants (e.g., particles) due to the relatively long duration of use in the extrusion line. This is recognizable because the cooling water is usually slightly to very cloudy.
Especially in the field of vacuum tanks, the plastic profile has direct contact with the cooling water. Particles from the cooling water, e.g. Sand or lime particles can attach themselves to the sensitive running surfaces of the calibration elements or to their leading edge, which causes scratches on the plastic profile surface. Disturbing such scratches are mainly on the visible surfaces of plastic profiles. 4/28 3
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These are those surfaces of the plastic profiles, e.g. in the fully installed window are oriented inward in the room or outward to the outside.
The filter systems used for the cooling water are usually not sufficient to reliably avoid such scratches, because hardly all particles can be filtered out.
It is therefore an object to provide an apparatus and a method which minimizes these problems.
This object is achieved by a device having the features of claim 1.
By using a mechanical and / or fluid mechanical means for removing and / or holding particles from a surface of the plastic profile, mechanical damage to the surface is avoided.
In this case, the various mechanical and / or fluid mechanical means for removing and / or holding particles from a surface of the plastic profile can in particular be designed as additional devices to conventional diaphragms for shaping plastic profiles, which are used in a vacuum tank for calibration. This can be prevented that, e.g. particles floating in the cooling water (for example dirt) can be fixedly attached to running surfaces of the calibration elements, so that the particles can not leave scratches on the sensitive plastic profile surface.
It is advantageous if a nozzle device is used for the targeted flow of a surface of the plastic profile, wherein the flow has only directional components that point away from the calibration or parallel to him. It is particularly advantageous if the nozzle device can be flowed through by a cooling water flow (K) directed essentially against the extrusion direction, since in this way the already existing cooling water flow can be used to keep particles away from the calibration element. 5/28 4
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Due to the flow of a surface of the plastic profile with cooling water, in particular along the visible surface of the plastic profile particles deposited on the visible surface are stirred up before contact with the running surface of the diaphragm and / or rinsed away.
Additionally or alternatively, it is advantageous if at least one movable guide element is provided for a surface of the plastic profile, in particular for automatic unrolling on the surface. It is particularly advantageous if the at least one movable guide element is designed as a roller, in particular with a convex outer contour. In this case, the immersion depth of the at least one movable guide element relative to the plastic profile can be made adjustable.
Additionally or alternatively, the calibration element has a mechanical wiper for a surface of the plastic profile. It is advantageous if the at least one mechanical wiper has a soft elastic element for contacting the surface of the plastic profile.
The object is also achieved by a mechanical and / or fluid mechanical means for removing and / or holding particles from a surface of the plastic profile to prevent mechanical damage to the surface, particularly for use with a calibration element according to at least one of claims 1 to 8 is designed and furnished.
Furthermore, the object is also achieved by a method having the features of claim 10.
Exemplary embodiments of the invention will be explained with reference to figures. Showing:
Fig. 1 is a perspective sectional view of a vacuum tank a
Wet calibration; 6/28 5
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Fig.2
Figure 3
Fig. 3A
Fig. 4
Fig. 5
Fig. 6
Fig. 7
Fig. 8
Fig. 9
Fig. 10 ec Is a sectional view through the vacuum tank according to FIG. 1 with a plastic profile; FIG. a detailed sectional view of a vacuum tank with a first embodiment of a calibration device with a fluid mechanical means for holding and / or removing particles; a schematic representation of a flow in an embodiment of FIG. 3; a perspective view of the first embodiment of a calibration device; a front view of the first embodiment of a calibration device of FIG. 4; a sectional view through the first embodiment of the calibration device of FIG. 4 and 5; a perspective view of the second embodiment of a calibration device with a mechanical means in the form of a spherical roller for holding and / or removing particles; a front view of the second embodiment of a calibration device of FIG. 7; a sectional view through the second embodiment of the calibration device of FIG. 7 and 8; a perspective view of the third embodiment of a calibration device with a mechanical means in the form of a scraper for holding and / or removing particles; 7/28 6
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11 shows a sectional view through the third embodiment of the calibration device according to FIG. 11.
The present invention relates to calibrating elements 10, 11 (diaphragms) and / or measures on the running surfaces of these calibrating elements 10, 11, whereby scratches on the plastic profiles 2 (see FIG. 2) are largely avoided despite the presence of interfering impurities in the cooling water. The objective is to avoid jamming or depositing particles 3 (in particular hard particles) (see FIG. 3) on running surfaces 4 of the calibration elements 10, 11.
In this case, embodiments are described by way of example, which individually can be used individually or together in combination.
Washing away particles
In the embodiment according to FIG. 1, the wet calibration device has a plurality of vacuum tanks 1 arranged one behind the other. In the vacuum tank 1 several calibration elements 10,11 are arranged one behind the other, which largely seal against the walls of the vacuum tank 1 on the outer surfaces. Each calibration element 10.11 has on the inside an opening 20,21 for the plastic profile 2, not shown in FIG. The openings 20, 21 correlate with the outer contour of the plastic profile. 2
In Fig. 1, the extrusion direction E is provided from right to left.
The cooling water flow takes place here against the extrusion direction E, ie from left to right. The cooling water No is introduced into the leftmost chamber, flows through holes or openings in the calibration elements 10.11, which are not shown here, and thus passes through all the chambers to the extreme right chamber. In this right chamber, the cooling water Kaus (and possibly present air) is sucked out again. 8/28 7
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FIG. 2 shows a longitudinal section through the vacuum tank 1 according to FIG. 1 with a plastic profile 2. In the left-hand chamber, the feed opening for the cooling water None is shown, in the right-hand chamber the suction opening for the escaping cooling water Kaus and infiltrated air are shown.
The cooling water supply None is controlled by means of a tap or by the flow resistance in the supply line so that largely independent of the negative pressure in the vacuum tank, a certain throughput, for example in the range of 0.2 to 1 m3 / h per 1 m tank length occurs.
At the suction opening to the right, a negative pressure in the range of about 0.05 to 0.2 bar is applied, which is reduced from chamber to chamber to the left to the cooling water supply.
The pressure difference between adjacent chambers results from the cooling water flow rate and the flow resistance in the apertures of the aperture.
The requested air additionally has a small influence. The suppression or alternatively the supplied amount of cooling water are adjusted so that there is no overpressure in any chamber, because this would indeed "squeeze" the plastic profile and level surfaces in an inadmissible manner inward, which fundamentally contradicts the purpose of the calibration.
In Fig. 3, a chamber of the vacuum tank 1 is shown. This is formed by the four walls of the vacuum tank 1 and left and right by a calibration element 10,11. The plastic profile 2 moves in this representation from right to left in the extrusion direction.
A water flow may e.g. be directed against the extrusion direction E of the plastic profile 2, so that the particles 3 are washed away from the inlet to the calibration element 10,11. In alternative embodiments, the flow is oriented so that the targeted flow 5 of the surface of the plastic profile 2 has only directional components pointing away from the calibration element 10 (see FIGS
Greiner Tool.Tec. GmbH · ··**··**·.**. J; N0011345 / I * · · · ········ · · # 3 A). Thus, e.g. a cross flow before the entry of the plastic profile 2 in the calibration element 10,11 be used to rinse away particles 3. In Fig. 3, the flow 5 is directed obliquely downward on the plastic profile 5, so that no directional component is present, pointing to the calibration element 10. FIG. 3A shows an enlarged view of the opening 20 of the calibration element 10. Before the opening 20, the particles 3 accumulate. There are - depending on the orientation of the nozzle device 30 - shown schematically different directions of flow 5 of the cooling water. The flow directions 5 are all in a vertical plane and have no directional components pointing in the direction of the calibration element 10. In this case, the cooling water impinges on the plastic profile 2 obliquely from above at different angles. In an analogous manner, the flow 5 can also be formed in the horizontal direction, so that particles can be washed away transversely to the extrusion direction E (or also horizontally).
In the calibration elements 10,11 nozzle devices 30,31 are arranged for the cooling water. The nozzle devices 30, 31 are here designed as inclined slots or as oblique bores (see FIGS. 4, 5 and 6), so that the outflowing cooling water 5 has only directional components which do not face the opening 20, 21 in the calibration element 10. In principle, the nozzle cross-sections can have any shape, which in particular can be designed such that it generates a particularly strong flow at critical points of the surface of the plastic profile 2.
Due to the negative pressure applied in an upstream chamber, there is a pressure drop in the chambers: the absolute pressure P in the chambers decreases from left to right (i.e., counter to the extrusion direction), Pi < P2 < P3 · The cooling water is thus sucked through the oblique nozzles 30,31 and flows from left to right. For comparatively small pressure differences between two adjacent chambers are already sufficient, for example in the range of 0.01 to 0.05 bar.
In Fig. 4 and 5, the nozzle devices 30, 31 for generating the targeted flow 5 are shown in more detail. 10/28 9
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4 shows a front view of a calibration element 10, in which nozzles 30, 31 are arranged above and below the opening 20 for the plastic profile 2 (not shown here). The extrusion direction E points vertically into the plane of the paper, the cooling water K flows out substantially perpendicularly out of the plane of the paper. Through the nozzles 30,31, the cooling water is directed to the plastic profile 2 and applies obliquely to the plastic profile surface.
In Fig. 6, the plastic profile 2 is moved from right to left by the calibration element 10 and is pressed by the air pressure from the inside to the outside of the running surface 4 of the calibration element 10. If particles have settled on the plastic profile surface during passage through the chamber, they are not drawn into the gap between the plastic profile 2 and the running surface of the calibration element 10, but are swirled up and / or washed away as a result of the outflowing cooling water 5 in the vicinity of the running surface 4 , Hard impurities can thus not settle on the running surface 4 of the calibrating element 10, 11 or in the region of the rounded edge on the inlet side of these running surfaces 4 and consequently do not cause any disturbing scratches on the plastic profile surface.
In an analysis of the frequency of troublesome scratches on plastic profiles 2, it was found that the scratches increasingly occur on the upper surfaces of the plastic profiles 2, based on the position of the plastic profile 2 during the extrusion. This suggests that contamination of the water in the vacuum tank 1 and so forth is likely to occur. also settle on the plastic profile 2 and this therefore increasingly enriched on horizontal surfaces. As soon as such a settled particle 3 mitwandert with the plastic profile 2, it succeeded to a calibration element 10,11. Very large particles, e.g. sheared crumbs of PVC plastic profile from the startup process with dimensions of about 0.5 mm or larger, are stripped from the face of the calibration element 10, 11 and then can not cause scratches. Smaller particles with dimensions below about 1.0 mm can become wedged in the area of the rounded inlet edge of the calibration element 10, 11 or they are drawn into the narrow gap between the plastic profile and the calibration element 10, 11 and are deposited on the running surface of the calibration element due to small irregularities 10.11. 10 11/28
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In both cases, the plastic profile surface slides along these contaminants, causing scratches. The harder this particle is 3 (sand, lime or similar contamination of the water), the longer, both in terms of time as well as spatially based on the run length of the plastic profile, a scratch is caused - until the particle 3 in turn due to wear has been sanded.
Movable guide element
Alternatively or additionally, scratches can be avoided if the particles 3 can not accumulate on a stationary running surface 4 of the calibration element 10, 11.
This can e.g. be done by a movable guide member 40 which replaces a stationary tread 4 by a movable tread, in particular a rotating tread.
This is shown in FIGS. 7 to 9. 7 shows a perspective view of a calibration element 10. In the illustrated embodiment, the movable guide element 40 is designed as a roller, which is arranged in each case at the upper and lower edge of the opening 20 for the plastic profile 2 (see FIG. 8). The rollers 40 are formed as freely rotatable rollers, which is moved by the moving plastic profile 2.
If particles 3 or other impurities enter the narrow gap between the plastic profile surface and the rotatable roller 40, they will continue to be conveyed and, as a rule, will continue to remain suspended in the water as suspended particles. These particles 3 then leave less or no scratches on the plastic profile 2, but either cause no marking or perhaps only a small impression, which hardly affects the surface of the plastic profile 2.
7 to 9 show a calibration element 10 with two roller inserts 40, which are associated with the visible surfaces of the relevant plastic profile 2 (not shown here). These roller inserts 40 are mounted with a pin in a guide slot and are rotatable with little force application. The plastic profile 2 is pressed against this roller 40 by a force proportional to the negative pressure in the vacuum tank 1. The 12/28 11
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Roller 40 is not cylindrically shaped, but has a convex contour in longitudinal section, so that the plastic profile 2 is curved inwards in a manner similar to the normal calibration element 10. The position of the roller 40 in the axial direction (here horizontal) is determined by a respective stop collar opposite the opening 20 of the calibration element 10,11. The position relative to the distance to the plastic profile 2 (here vertical) is determined by the depth of the guide slot. Alternatively, the depth can also be through a
Be limited screw. This has the great advantage that the height of the
Plastic profiles 2 and or the flatness of the plastic profile 2 by appropriate
Adjusting the screws is adjustable, which is very easy while running
Extrusion operation can take place. It was found that hard dirt particles from the water did not attach to the rollers 40. If a dirt particle is drawn into the gap between the roller 40 and the plastic profile 2, then this is usually only further promoted and then remains floating again as an impurity in the cooling water. As a result, there is hardly any risk of scratching on the sensitive
Plastic profile surface.
Mechanical scraper
Furthermore, alternatively or additionally, a mechanical scraper 50 can be used. Embodiments of this are illustrated in FIGS. 10 to 11. FIG. 10 shows in a perspective view a mechanical scraper 50 which is arranged in the extrusion direction E in front of the calibration element 10.
The mechanical wiper 50, similar to a windshield wiper rubber, can prevent the particles 3 from entering the calibration element 10, 11.
If a particle 3 has settled on the plastic profile surface and reaches this scraper 50, it is stopped or, if the scraper 50 is arranged obliquely to the extrusion direction E, laterally derived. Even if a particle 3 attaches to the scraper 50, this causes no scratch, because the soft elastic scraper 50 can not selectively exert a large force, which is a prerequisite for a scratch. 13/28 12
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In Fig. 10 to 11, the calibration element 10,11 is shown, which is provided with scrapers 50, whose function is comparable to a windshield wiper. The squeegee is made of a soft elastic plastic, e.g. made of foam rubber, this is easily pressed by means of metal bracket to the visible surface of the plastic profile 2 to be calibrated. The wiper surface takes on the contour of the plastic profile 2 and therefore strips off the continuous plastic profile surface.
If particles 3 are attached to this plastic profile surface, they are retained or stripped off. These particles 3 can also be deposited in the pores of the wiper blade rubber. Since the squeegee in turn can not exert a large pressing force on such dirt particles, the dirt particles can not be pressed firmly against the plastic profile surface and therefore can not leave scratches on this. The squeegee can be arranged directly in front of the end face of the calibration element 10, 11 or with a short distance in front, as well as transversely to the extrusion direction of the plastic profile 2 or at an oblique angle to this. Such scrapers 50 can also be used in combination with the obliquely directed against the plastic profile surface flow-through openings 30, 31 for the cooling water and / or with the roller inserts 40. FOR D. ANMfLf) ER (IN): 0 1. ml 2013 PATENT / # WAL i
© IPLlNuficTER ITZE 14/28 13 N0011345 / 1
Greiner Tool.Tec. GmbH
1 Vacuum tank 2 Plastic profile 3 Particles 4 Tread in calibration element 5 targeted flow to the plastic profile 10, 11 Calibration (aperture) in vacuum tank 20, 21 opening in calibration for the plastic profile 30, 31 nozzle for cooling water in calibration 40 movable guide element for the plastic profile 50th mechanical scraper E extrusion direction K cooling water flow
No cooling water inflow
Kaus Kuhlwasserabfluss 15/28 14

权利要求:
Claims (10)
[1]
Greiner Tool.Tec. GmbH PATENT OFFICER DIPL IfcJG .. BETBB ΠΖΕ. 1060 WIEtt α * δ / ω <} Α6βΕβΦ.'m. 1. Calibration element in a wet calibration of an extrusion device for a Kunststoffpro fil, characterized by a mechanical and / or fluid mechanical means (30, 31,40, 50) for the removal and / or the holding of particles (3) of a surface of the plastic profile (2) for preventing mechanical damage to the surface.
[2]
2. Calibration element according to claim 1, characterized by a nozzle device (30, 31) for the targeted flow (5) of a surface of the plastic profile (3), wherein the flow (5) has only directional components pointing away from the calibration element (10, 11) or parallel to him.
[3]
3. Calibration element according to claim 2, characterized in that the nozzle device (30, 31) of a substantially against the extrusion direction (E) directed cooling water flow (K) can be flowed through.
[4]
4. Calibration element according to at least one of the preceding claims, characterized by at least one movable guide element (40) for a surface of the plastic profile (2), in particular for automatic rolling on the surface.
[5]
5. Calibration element according to claim 4, characterized in that the at least one movable guide element (40) is designed as a roller, in particular with a convex outer contour.
[6]
6. Calibration element according to claim 4 or 5, characterized in that the immersion depth of the at least one movable guide element (40) relative to the plastic profile (2) is adjustable.
[7]
7. Calibration element according to at least one of the preceding claims, characterized by at least one mechanical scraper (50) for a surface of the plastic profile (2). 16/28 1 Greiner Tool.Tec. GmbH

• · N0011345 / 1 • ·
[8]
8. Calibration element according to claim 7, characterized in that the at least one mechanical scraper (50) has a soft elastic element for contacting the surface of the plastic profile (2).
[9]
9. Mechanical and / or fluid mechanical means (30, 31, 40, 50) for removing and / or holding particles (3) from a surface of the plastic profile (2) to prevent mechanical damage to the surface, especially for use with a calibration element formed and arranged according to at least one of claims 1 to 8.
[10]
10. A method for calibrating a plastic profile, characterized in that during the extrusion of the plastic profile (2) particles (3) by a mechanical and / or fluid mechanical means (30, 31,40, 50) from a surface of the plastic profile (2) femgehalten and / or removed. PÖR D. ANMFLDER (IW):

uze 2 17/28

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公开号 | 公开日

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引用文献:

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公开号 | 申请日 | 公开日 | 申请人 | 专利标题

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DE2456986A1|1974-12-03|1976-06-16|Barmag Barmer Maschf|DEVICE FOR CALIBRATING AND COOLING OF EXTRUDED PLASTIC PIPES|

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GB2313570A|1994-02-22|1997-12-03|Greiner & Soehne C A|Apparatus and process for cooling extruded objects|

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DE102013209703B4|2013-05-24|2017-03-30|Greiner Tool.Tec Gmbh|Calibration device, calibration method and method for producing a calibration device|

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DE102014010000B4|2014-07-05|2018-06-14|Bach Maschinenbau Gmbh|Calibration device for the calibration of extruded bodies|

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AT523215A1|2019-11-20|2021-06-15|Extrunet Gmbh|EXTRUSION NOZZLE FOR THE PRODUCTION OF A PLASTIC PROFILE|

法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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DE201210218140|DE102012218140A1|2012-10-04|2012-10-04|Calibration element e.g. diaphragm for use in wet calibration device of extrusion apparatus for extruding plastic profile for window, has mechanical scraper which is arranged in extrusion direction of plastic profile|

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