AT503363B1 - DEVICE AND METHOD FOR DETERMINING THE FLOW BEHAVIOR OF A MELT - Google Patents

Description

Austrian Patent Office AT503 363B1 2010-01-15

Description: The invention relates to a device for determining the material flow over the cross-section of an extruder outlet, wherein the device can be mounted on an extruder, and to a method in this regard.

Extruder for the production of plastic profiles, such as those required for the production of plastic windows, are usually constructed so that the extruder cylinder, in which the screws are arranged, an adapter part connects, which forms the transition to the extrusion die. In the extrusion die, the so-called extrusion die, the cross-sectional profile of the relevant profile is already largely formed, in order to be finally determined in the subsequent dry and / or wet calibration. In order to increase the productivity of the extrusion process, increasingly higher extrusion speeds are being used. At the same time, the quality and tolerance requirements for the profiles produced increase. However, a high quality of the profiles can be achieved at higher extrusion speeds only with extremely careful coordination of the extrusion tools while maintaining a precisely defined operating state in the extruder. For this purpose, a careful theological design of the extrusion tools while maintaining a defined operating condition in the extruder with consequent homogeneous plastic melt is necessary. However, an optimal match between extruder and extrusion tool is often dependent on the raw material.

A particular difficulty is to use a tool on different extruders, since the extruder can provide the plastic different and different homogeneous available and then the tool would have to be re-tuned to the extruder each time, which is not practical in practice ,

Known approaches to the solution as for example from EP 1 108 464 relate either to additional built-in parts, which should ensure homogenization of the melt stream, or to the design and coordination of adapters and / or extrusion tools themselves. They are dealing with a subsequent Correction of inhomogeneity of the plastic melt from the extruder.

However, built-in components as described in EP 1 108 464 have the disadvantage that additional pressure is built up, so that in addition to costs for the insert and the disadvantage of a temperature increase and higher power requirements must be taken into account.

Other approaches are concerned with the review of the melt state during operation. EP 1 105 278 describes the determination of the viscosity by means of the dielectric constant and a method for this purpose.

From EP 1 260 348 it is known to measure the viscosity by means of a rheometer connected as a bypass.

The object of the invention is to provide a measuring tool and a measuring method available, which supports the screw and extruder development and the design of extrusion tools to the extent that measurement data can be determined that represent the flow properties of the plastic over the outlet cross-section of the extruder ,

The solution of the problem with respect to the device is characterized in connection with the preamble of claim 1, characterized in that the device comprises a main channel which terminates in a plurality of individual channels.

It is therefore proposed a type of nozzle, with which the mass provided by the extruder is divided into X partial streams. The nozzle consists of an inlet piece with a flange, which is fastened with screws directly to the extruder and ensures that the mass flow is divided into individual streams. For this purpose, each individual channel has an appropriately trained enema. This is followed by a corresponding number of nozzle plates which make the nozzle variable in such a way that a certain pressure consumption can be established. Furthermore, so that the required length can be achieved in order to provide a calming of the melt, as is common in extrusion tools.

Advantageously, these individual channels are geometrically equal and / or symmetrical, further, the arrangement is proposed annularly around the center of the device. With this type of arrangement, it becomes possible to achieve an evaluation over the entire cross section.

Further development is provided that this first device is followed by a further device by means of which the separated from the individual channels strands can be fixed and removed. By fixing the individual strands, the assignment of the strands to the individual outlet openings from the first device is thus also possible.

The solution of the problem with respect to the method is characterized in connection with the preamble of claim 8, characterized in that the emerging from the extruder melt is divided into several sub-strands and each sub-strands generated are compared. The method thus aims at characterizing the blowing behavior (mass flow distribution over the cross section) of the extruded strand under given conditions (extruder, screw, material, ejection, etc.). This is done by dividing into these individual streams, wherein preferably the device proposed here is used. The volume flow of a single strand represents the driving behavior of the main mass flow at this point. By comparison of the individual volume flows, it is thus possible to make a statement about the mass flow distribution of the main strand.

Ideally, the extrusion tool is supplied with plastic, if there is a steady course of the mass flow from the center to the edge of the extruder outlet and if flows on concentric circles at each point an equal part of the mass flow.

Advantageous developments are given in the dependent claims.

The partial strands generated with the proposed device and the proposed method can now be compared with each other and thus offer the possibility of determining the flow behavior and / or the melt quality over the cross section of an extruder outlet. In this case, the partial strands can be subjected to customary and known processes. Thus, e.g. a quality control carried out with microtome sections for dispersion measurement, determines the degree of gelation or the known methylene test are performed. Furthermore, it is thought to determine the diameter of the sub strands and to determine the weight. From these or part of the determined data, it is possible, for example, to evaluate the flow behavior of the melt across the cross section via a mathematical model and thus to design an extrusion tool accordingly in order to achieve the best possible quality of the product to be extruded.

For the particular user, it is important not to get the exact measurement of a physical factor dependent on many factors such as the viscosity, but to get by a simple measurement of the dependent effects on the distribution of the mass flow over the cross section at the extruder exit.

With the proposed invention, it is thus possible to compare different types of extruders and to make statements on which extruders a tool can be used without being retracted, for different extruders to develop that provide comparable measurement results, - to optimize the process parameters of an extruder so far, to comparable

Measurement results are achieved to optimize the plastic formulations so far until comparable measurement results are achieved, provide measuring results, which serve as a basis for the design of extrusion tools 2/7 Austrian Patent Office AT503 363 B1 2010-01-15

In the drawings, an embodiment of the invention is shown schematically.

1 shows a view of the device, FIG. 2 shows a section through the device according to FIG. 1, [0026] FIG. 3 shows the device with an attached further device and [0027 ] FIG. 4 shows the device according to FIG. 3 in a further method step.

In Fig. 1 is a plan view of the device according to the invention is shown. The flange shown is attached to the extruder by means of screws, via which the melt is conveyed via a main channel into a plurality of individual channels 2. The plurality of individual channels 2 is arranged in a ring around the center. The more individual channels 2 the device has, the more favorable the flow behavior of the melt over the cross section can be determined.

Fig. 2 shows a section through the apparatus of FIG. 1, in turn, the flange can be seen, in which the main channel 1 is arranged. At the flange a plurality of nozzle plates are arranged, which form the individual individual channels 2, wherein the first nozzle plate is formed as an inlet piece and the respective individual channels 2 have a specially formed inlet.

FIG. 3 shows a further device 3 arranged on the device according to FIG. 2. This further device 3 likewise forms the individual channels, into which the partial strands 4 produced are conveyed. This further device 3 has before each bore, which further develops the single channel, a blade, by means of which the sub-strand can be cut off. In a slot, a sliding element 5 is arranged, which may for example be a sheet, which shows the same hole pattern, by means of which the partial strands 4 can be fixed.

4, the sliding element 5 is shown in a shifted representation and the other device 3 is moved transversely. This ensures that the partial strands 4 are fixed in position, whereby an assignment of the strands is made possible. By shifting the entire further device 3, the sub-strand 4 is cut off via the blades, which ensures that all strands are separated at a defined time.

The further device may for example consist of one or two plates bolted together, which has a slot into which a metal sheet is inserted, wherein the holes are advantageously designed to be larger than the individual channels 2 of the device according to the invention according to claim 1. This has the Advantage that a passage of the partial strands 4 is ensured without pressure build-up. The further device is connected by means of a guide with the first device and can be positioned by a stop so that the holes come to lie directly below the corresponding holes of the first device. After separation, the sub-strands that are defined in the other device can be completely removed by means of this and subjected to the examination described above. Since an assignment of the partial strands over the cross section of the extruder outlet is ensured, the flow behavior over the cross section can be determined reliably.

In summary, an embodiment of the invention can be represented as follows: The invention relates to a device for determining the flow of material over the cross section of an extruder outlet, wherein the device is mountable on an extruder. According to the invention, it is provided that the device comprises a main channel which terminates in a plurality of individual channels. Furthermore, the invention relates to a method for determining the 3/7

Claims (15)

Austrian Patent Office AT503 363B1 2010-01-15 Melt quality and / or the flow behavior of the melt over the cross-section of an extruder outlet. Here, according to the invention, it is provided that the melt emerging from the extruder is divided into several sub-strands and the respective sub-strands produced are compared with one another. Reference symbol list: 1 main channel 2 single channel 3 further device 4 sub-strand 5 sliding element Claims 1. Device for determining the flow of material across the cross-section of an extruder exit, the device being mountable on an extruder, characterized in that the device comprises a main channel which is divided into several individual channels (2) expires. 2. Apparatus according to claim 1, characterized in that the individual channels (2) are designed geometrically equal. 3. Apparatus according to claim 1 or 2, characterized in that the individual channels (2) are arranged symmetrically. 4. Apparatus according to claim 1, 2 or 3, characterized in that the individual channels (2) are arranged annularly. 5. Device according to one of claims 1 to 4, characterized in that the device is constructed of a plurality of nozzle plates. 6. Device according to one of claims 1 to 5, characterized in that the first device, a further device (3) is connected downstream. 7. Apparatus according to claim 6, characterized in that from the individual channels (2) exiting partial strands (4) via the further device (3) are separable. 8. A method for determining the melt quality and / or the flow behavior of the melt over the cross section of an extruder outlet, characterized in that the emerging from the extruder melt is divided into several sub-strands and the respective generated sub-strands (4) are compared. 9. The method according to claim 8, characterized in that the partial strands (4) are separated after a defined time at the outlet of a device. 10. The method according to claim 8 or 9, characterized in that the temperature of the partial strands (4) is measured immediately after exiting the device. 11. The method according to claim 8 or 10, characterized in that the partial strands (4) are withdrawn at the same speed and whose cross-section is determined. 12. The method according to any one of the preceding claims, characterized in that the extrusion parameters are changed until largely identical partial strands (4) are produced. 4/7 Austrian Patent Office AT503 363 B1 2010-01-15 13. The method according to any one of the preceding claims, characterized in that the plastic formulation is changed until largely identical partial strands (4) are produced. 14. The method according to any one of the preceding claims, characterized in that the partial strands generated (4) are compared with each other and based on the determined data, an extrusion tool is designed. 15. The method according to any one of the preceding claims, characterized in that the determined data are evaluated by means of a mathematical model. For this 2 sheets drawings 5/7