• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a method for producing plastic profiles in an extrusion line consisting of a plurality of tools, in which a starting material is plasticized and shaped in an extruder (1), thereafter in at least one dry calibration unit (3; 3a, 3b) and at least one calibration tank (4 ) is cooled and calibrated, and then divided into individual profile sections (101). An improvement dere profile quality is achieved in that a central control unit (10) is provided, which is in communication with the tools and on the one hand receives data for unambiguous identification of the tool and on the other hand data about the state of the tool and adjustment data for this and others Tools returned.
    公开号:AT519283A1
    申请号:T50946/2016
    申请日:2016-10-19
    公开日:2018-05-15
    发明作者:Stadlhuber Thomas
    申请人:Stadlhuber Thomas;
    IPC主号:
    专利说明:

    The invention relates to a method for producing plastic profiles in an extrusion line consisting of several tools, in which a starting material is plasticized and shaped in an extruder, then cooled and calibrated in at least one dry calibration unit and at least one calibration tank, and then divided into individual profile sections ,
    Plastic profiles are produced in extrusion lines, in which an extruder first extracts a profile strip that is initially hot and plastically deformable, which is then processed in calibration tools to form a plastic profile with precisely defined geometric properties. The setting of such an extrusion line is very complex since a large number of parameters have to be defined for the individual tools. These parameters work together in complex ways to produce a product with certain properties. The operation of such extrusion lines requires qualified personnel in order to keep the rejects as low as possible. Nevertheless, it often happens that slightly changed environmental conditions result in undesirable properties of the plastic profile produced, so that large quantities of defective plastic profiles may be produced if the need for an improved setting is not immediately noticed and appropriate corrective measures are not initiated.
    A particularly difficult task is the readjustment of an extrusion line, which is necessary when significant changes are made, especially when another plastic profile is to be produced. Even if there are already empirical values about cheap setting parameters under similar circumstances, it is often difficult to achieve a stable manufacturing process quickly and efficiently.
    The object of the present invention is to avoid the disadvantages mentioned above and to provide a method which makes it possible, on the one hand, to optimally use existing experience values about extrusion processes in order to be able to carry out the initial setting process quickly and efficiently, and on the other hand to optimally manage a running extrusion process.
    / 18th
    According to the invention, these tasks are solved in that a central control unit is provided which is connected to the tools and receives data from them on the one hand for uniquely identifying the tool and on the other hand data about the condition of the tool, which retransmits and setting data for this and other tools ,
    One aspect of the present invention is the immediate use of measurement values determined on the tools and data about the tool to determine setting data. It has been found that tools of the same type do not necessarily behave in the same way due to imperceptible differences in real operation in an extrusion line. It is therefore essential for the invention that each tool can be clearly identified and that all relevant setting data relating to this tool are managed accordingly.
    In the context of the present invention, all components of the extrusion line are referred to as tools. The measured values which give the data are, for example, temperature, pressure, flow rates and the like at various points on the extruder, the dry calibration units, the calibration tanks and the like.
    The setting data here are, for example, the extrusion speed, and generally all settings of valves, pumps and the like, which enable the control of an extrusion line.
    An important aspect of the present invention is that the tools are connected as directly and reliably as possible with the supply devices for water or vacuum and with the control unit, so that the integrity of the data is guaranteed.
    According to a particularly advantageous embodiment variant of the present invention, it is provided that the control device has a database in which a large number of setting data are stored and that this database is used when determining the setting data. This database is continuously expanded and supplemented as part of the use of the corresponding tools, so that the amount of usable experience increases continuously.
    / 18th
    A particularly clear and comprehensible determination of the setting data can be achieved by creating an extrusion model from the data stored in the database, which is used in determining the setting data. The extrusion model depicts the basic relationships between the setting data and the measurement values ultimately resulting from it, thus making it possible to carry out targeted interventions if the extrusion process is in an unsatisfactory state.
    Setting data are preferably output in the form of correction values. Such correction values consist, for example, of a specific increase in the amount of cooling water at a specific point on a specific tool. For example, it can be provided that a correction value relates to the extrusion speed. It is also possible, for example, that a correction value relates to the selective cooling of parts of the profile cross section in the region of the extrusion die or that a correction value relates to the control of the cooling water flow in at least one section of the calibration tank.
    The present invention also relates to a device for producing plastic profiles in an extrusion line consisting of several tools, in which at least one dry calibration unit and at least one calibration tank are provided downstream of an extruder and are arranged on a calibration table.
    According to the invention, a control unit connected to a plurality of tools is provided.
    It is particularly advantageous if at least one tool is connected to the calibration table via direct connections. In conventional extrusion lines, for example, the dry calibration units are connected by hoses to water or vacuum connections of a supply device, which is typically arranged in the calibration table. As a result, a clear assignment between the tool and the supply device is not possible or at least prone to errors.
    The direct connection preferably includes both water and vacuum as well as data communication. This not only reduces the risk of faulty connections, it can also be used to convert an extrusion line / 18 particularly quickly and efficiently, since essentially only a mechanical connection of a tool to the calibration table is required to ensure full functionality.
    A structurally particularly favorable solution provides that at least one dry calibration unit has a contact surface with standardized connections, which correspond to the associated connections on the calibration table.
    The flexibility of the device can be increased in particular in that the calibration table identifies a detection device for unused connections. Not every tool necessarily has the same number of connections and a different number of tools is also used depending on the profile geometry. The detection device thus ensures that, for example, water cannot flow out, since unused connections are automatically shut off. The same applies to vacuum.
    A particularly high level of energy efficiency can be achieved in that at least one dry calibration unit has a plurality of separate water circuits. The cooling channels of the dry calibration units typically have different cross sections. It is therefore necessary to design the pressure with which the cooling water is made available to the most unfavorable section. There is also only one temperature level available for the cooling water. Within the framework of the solution according to the invention, several water circuits are now provided, in which both the quantities and the temperatures of the cooling water flowing through can be set differently. It is thus possible, in particular, to cool certain large areas of the profile by means of adjacent cooling water bores with a large cross section, cooling water having a relatively low flow rate and a moderately low temperature being used. Critical profile sections, such as extremities with sealing grooves and the like, on the other hand, are surrounded by comparatively fine cooling water bores which are acted upon by cooling water at high pressure and very low temperature. Since only a small amount of cooling water has to be provided with high pressure and low temperature, considerable energy savings can be achieved.
    A particularly practical solution is provided in that a cooling device is provided in the calibration table, which provides water with particularly low temperatures for at least one cooling circuit. This makes it possible to take the main part of the cooling water from a general supply device and to condition only a small part in the system itself, namely in the calibration table.
    It is advantageous if the calibration tank can be moved in the longitudinal direction on the calibration table. This allows the extrusion line to be adapted very easily if a different number of dry calibration units is used.
    The present invention is explained in more detail below on the basis of the embodiment variants shown in the figures. Show it:
    Fig. 1 shows schematically an extrusion line according to the invention;
    2 shows a detail of a calibration table together with a dry calibration unit in an oblique view;
    3 shows a detail of an extrusion die;
    4 is an end view of a dry calibration unit;
    5 is an end view of an extrusion die;
    6 schematically shows a cooling device installed in the calibration table; and
    Fig. 7 schematically shows the water flow in the calibration table and the calibration tools.
    1 consists of an extruder 1 with an extrusion nozzle 1a, a calibration table 2 arranged downstream thereof, on which a number of dry calibration units 3 and a number of calibration tanks 4 (the calibration tools) are arranged in order to cool and close the plastic profile 100 ejected by the extruder 1 calibrate.
    The calibration tanks 4 can be moved in the longitudinal direction on the calibration table 2 in order to adapt quickly to a different number of / 18
    To enable dry calibration units 3, since it is desirable that the calibration tanks 4 connect directly to the dry calibration units 3.
    Subsequently, the plastic profile 100 arrives in a caterpillar take-off 5, which provides the necessary tensile forces to pull the plastic profile 100 through the calibration tools. The plastic profile 100 is measured in a measuring station 6 and then separated in a saw 7 to form profile sections 101, which are placed on a tilting table 8.
    The extrusion line is controlled via a control unit 10 which is connected to the individual components of the extrusion line via control lines 11, 12. A scale 13 is schematically indicated in the tilting table 8, which determines the weight of each profile section 101 and transmits it to the control unit 10.
    In the same way, the data on the profile geometry and the like are output from the measuring station 6 to the control unit 10. The type of this data is indicated at 15, namely geometric measured values, color, gloss and scratches. In addition, all relevant data of the other components are transmitted in a manner not shown here, such as the pulling force exerted by the caterpillar puller 5, measured values of pressure and temperature from the calibration tools, and the like, and above all identification data with which each tool is unique can be identified.
    During operation of the extrusion line, the control unit 10 not only accepts data and issues control commands in order to optimally guide the extrusion process, but also records are made in a database in order to gain empirical values for subsequent extrusion processes.
    It is shown in FIG. 2 that the dry calibration units 3a, 3b can be set up on the calibration table 2 in a simple manner, since only a mechanical connection via quick locks 16 has to be established. All connections are provided on the support surface (not visible here) on the underside of the dry calibration units 3a, 3b. They interact with connections that are likewise not visible here at the receiving positions of the calibration table 2. There are therefore no hoses to connect the calibration tools / 18
    3a, 3b, 4 with the calibration table 2, which minimizes the risk of confusion or errors.
    It is also possible within the scope of the invention to continue to use existing calibration tools in an extrusion line designed according to the invention. A base plate is firmly attached to the underside of these tools, which has the required connections on its underside and laterally connects to other connections via internal connecting lines. These further connections are then connected via connection hoses to the connections of conventional calibration tools, which are also typically located on the side. The original tool subsequently forms a unit with the base plate and the connecting hoses, which is no longer separated when the tool is removed and assembled. In the sense of the present invention, this unit is regarded as a calibration tool. Here, too, there is no risk of confusion, since after the initial assembly there is no further manipulation of the connecting hoses.
    Fig. 3 shows a quick change system for the extrusion die 1a, which can be folded away to the side. An extremely short cycle time of less than 10 minutes when changing the extrusion nozzle 1a can be achieved by quick-release fastenings in conjunction with preheating the extrusion nozzle 1a.
    4 shows the end face of a dry calibration unit 3, with a nozzle plate 18a, 18b being magnetically fastened on both sides of the opening 19 through which the plastic profile 100 passes. Several nozzles not visible here can be supplied with compressed air via connections 20 in order to selectively cool the plastic profile 100 entering the opening 19. The amount of air is measured to create reproducible conditions. In this way, the wall thickness of the outer areas of the plastic profile 100 can be individually adjusted, and the weight of the plastic profile produced can be precisely controlled with the (meter weight).
    A similar solution is shown in FIG. 4, in which eight nozzle plates 21a, 21b, 21c, 21d, 21e, 21f, 21g and 21h are likewise magnetically attached to the end face of an extrusion die 1a. The nozzle plates 21a and 21e are directed towards visible surfaces of the plastic profile 100, while the nozzle plates 21b, / 18
    21c, 21d, 21f and 21h are aimed at extremities that are always a challenge in the extrusion process.
    6 shows a cooling device arranged in the calibration table 2, which cools the general cooling water which is made available to the extrusion line from the outside to a lower temperature of, for example, 5 ° C. to 8 ° C. A distributor 23 is supplied via a feed line 24 and a return line 25, via which special cooling circuits in the calibration tools are fed.
    7 shows the general cooling water flow for the dry calibration units 3a, 3b. The distributor 23 is supplied with general cooling water via a supply line 29 via a water tank 26. In addition, the cooling device 22 supplies low temperature water as shown above.
    General cooling water at a first pressure level is led to certain circuits in the dry calibration units 3a, 3b via a first supply line 26a with a small cross section. A low-temperature cooling water is led to further circuits via a second supply line 26b with a small cross-section. General cooling water at a further pressure level is supplied via a third supply line 26c with a large cross section. Return lines 27, 28 return the used cooling water.
    权利要求:
    Claims (17)
    [1]
    P A T E N T A N S P R Ü C H E
    1. A method for producing plastic profiles in an extrusion line consisting of several tools, in which a starting material is plasticized and shaped in an extruder (1), then cooled in at least one dry calibration unit (3; 3a, 3b) and at least one calibration tank (4) and is calibrated, and then divided into individual profile sections (101), characterized in that a central control unit (10) is provided which is connected to the tools and on the one hand data for uniquely identifying the tool and on the other hand data about the tool Receives the condition of the tool and sends back setting data for this and other tools.
    [2]
    2. The method according to claim 1, characterized in that the control device (10) has a database in which a large number of setting data are stored and that this database is used in determining the setting data.
    [3]
    3. The method according to claim 2, characterized in that an extrusion model is created from the data stored in the database, which is used in the determination of the setting data.
    [4]
    4. The method according to any one of claims 1 to 3, characterized in that setting data are output in the form of correction values.
    [5]
    5. The method according to claim 4, characterized in that a correction value relates to the extrusion speed.
    [6]
    6. The method according to any one of claims 4 to 5, characterized in that a correction value relates to the selective cooling of parts of the profile cross section in the region of the extrusion nozzle (1a).
    [7]
    7. The method according to any one of claims 1 to 6, characterized in that a correction value relates to the control of the cooling water flow in at least a section of the calibration tank.
    10/18
    [8]
    8. Device for producing plastic profiles in an extrusion line consisting of several tools, in which at least one dry calibration unit (3; 3a, 3b) and at least one calibration tank (4) are provided downstream of an extruder and are arranged on a calibration table (2), characterized in that a control unit (10) connected to a plurality of tools is provided.
    [9]
    9. The device according to claim 8, characterized in that at least one tool is connected via direct connections to the calibration table (2).
    [10]
    10. The device according to claim 9, characterized in that the direct connection comprises both the supply of water and vacuum as well as data communication.
    [11]
    11. Device according to one of claims 9 or 10, characterized in that at least one dry calibration unit (3; 3a, 3b) has a support surface with standardized connections, which correspond to the associated connections on the calibration table (2).
    [12]
    12. Device according to one of claims 9 to 11, characterized in that the calibration table identifies a detection device for unused connections.
    [13]
    13. Device according to one of claims 9 to 12, characterized in that at least one dry calibration unit (3; 3a, 3b) has a plurality of separate water circuits.
    [14]
    14. The apparatus according to claim 13, characterized in that the water circuits can be regulated to different temperatures.
    [15]
    15. Device according to one of claims 13 to 14, characterized in that a cooling device (22) is provided in the calibration table (2), which provides water with particularly low temperatures for at least one cooling circuit.
    11/18
    [16]
    16. Device according to one of claims 9 to 15, characterized in that the calibration tank (4) on the calibration table (2) can be moved in the longitudinal direction.
    [17]
    17. Device according to one of claims 9 or 16, characterized in that at least one calibration tank (2) has a support surface with standardized connections, which correspond to the associated connections on the calibration table (2).
    类似技术:
    公开号 | 公开日 | 专利标题
    DE3315184C1|1984-06-28|Method and extrusion device for monitoring the production of profiles from one or more rubber or plastic mixtures
    DE102008021240B4|2012-11-22|Apparatus for thermal treatment of workpieces and method for determining the thermal process stability in such a device
    DE2246679B2|1980-03-20|Device for extruding an extruded profile consisting of thermoplastics with a core profile and a cover layer
    EP0418681B1|1993-06-23|Coextrusion adaptor
    EP3006186B1|2021-02-17|Coextrusion device for producing a film of plastic material and corresponding method with the measurement of a layer thickness
    AT519283B1|2019-03-15|METHOD FOR PRODUCING PLASTIC PROFILES
    DE2506517B2|1977-08-11|DEVICE FOR INTERNAL LIQUID COOLING OF EXTRUDED PIPES OR HOSES
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    AT410195B|2003-02-25|METHOD AND DEVICE FOR ADAPTING AN EXTRUSION TOOL TO AN EXTRUDER
    DE4307568A1|1993-09-16|Premixed fibre composite blanks of good uniformity - prepared under nitrogen using extrusion press with controlled orifice
    EP3529037A1|2019-08-28|Method and device for producing plastic profiles
    EP1227925B1|2003-04-09|Device for determining the operational state of an extruder
    DE3417316A1|1985-11-14|Device for extruding a film web comprising thermoplastics
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    DE102010037091B4|2013-10-17|Device for post-coextrusion and use of the device
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    DE102012112830A1|2014-06-26|Tool for checking components of injection mold, has connection device enabling arrangement of inspection device inlet at section keeping at moderate temperature, and connection device enabling arrangement of inspection device
    DE102019215876A1|2021-04-15|Extrusion device and extrusion process
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    DE4001479C1|1991-02-21|Thermoplastic material extruding appts. - has two or more extruders to form melt streams, co-extrusion adaptor, with two or more inlets, side channels, co-extrusion nozzle, etc.
    DE102013114678A1|2015-06-25|Method and device for producing three-dimensional objects
    AT507720A1|2010-07-15|CALIBRATION BLOCK FOR EXTRUSION DEVICE
    同族专利:
    公开号 | 公开日
    CN109843544A|2019-06-04|
    US20200055228A1|2020-02-20|
    EP3529036A1|2019-08-28|
    AT519283B1|2019-03-15|
    WO2018071940A1|2018-04-26|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP0950498A1|1998-02-27|1999-10-20|Gebrüder Kömmerling Kunststoffwerke GmbH|Calibrating device|
    DE102004043060A1|2003-09-10|2005-04-07|Engel Austria Gmbh|injection molding machine|
    US20050194705A1|2004-03-03|2005-09-08|Smith Roger P.|Plastic forming process monitoring and control|
    WO2006060837A1|2004-12-10|2006-06-15|Gruber & Co Group Gmbh|Device for calibrating an extruded plastic profile|
    DE2535286C3|1975-08-07|1979-01-25|Dynamit Nobel Ag, 5210 Troisdorf|Method for calibrating a coextruded profile strip made of thermoplastics|
    US5340295A|1993-07-19|1994-08-23|The Conair Group, Inc.|Vacuum sizing apparatus with controlled vacuum|
    EP1105278B1|1998-08-19|2003-02-19|Greiner Extrusionstechnik GmbH|Method for producing elongated objects made of plastic material|
    AT6407U1|2002-12-12|2003-10-27|Technoplast Kunststofftechnik|METHOD FOR REGULATING THE VACUUM SUPPLY OF CALIBRATION TOOLS|
    CA2831940A1|2010-03-11|2011-09-15|Smi Service Management Immobilien Gmbh|Device for precisely controlling negative pressure|DE102017119334B4|2017-08-24|2022-01-20|Troester Gmbh & Co. Kg|Method of operating an extrusion device|
    法律状态:
    2021-10-15| REJO| Opposition accepted [patent revoked]|Effective date: 20210909 |
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50946/2016A|AT519283B1|2016-10-19|2016-10-19|METHOD FOR PRODUCING PLASTIC PROFILES|ATA50946/2016A| AT519283B1|2016-10-19|2016-10-19|METHOD FOR PRODUCING PLASTIC PROFILES|
    PCT/AT2017/060272| WO2018071940A1|2016-10-19|2017-10-19|Method and device for producing profiled plastic sections|
    CN201780064860.3A| CN109843544A|2016-10-19|2017-10-19|Method and apparatus for producing moulding plastics section|
    EP17791540.2A| EP3529036A1|2016-10-19|2017-10-19|Method and device for producing profiled plastic sections|
    US16/342,928| US20200055228A1|2016-10-19|2017-10-19|Method and device for producing profiled plastic sections|
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