DE19936922A1 - Tubular internal mixer for a plastics extruder, forms an initial core and annular flows whose positions are interchanged at the outlet - Google Patents

Abstract

A housing contains a mixing element and has an inlet for a melt stream and an outlet for mixed material. The mixing element divides the incoming melt flow into a central core flow and an annular flow surrounding it. At the outlet the two flows are interchanged with the initial core flow becoming an annular flow and the initial annular flow becoming a core flow.

Description

The invention relates to a mixer for an extruder for Thermoplastic processing according to the in the preamble of the An say 1 specified genus.

Extruders enable through a continuous Ferti the process of manufacturing semi-finished products like Voll rods, tubes, hoses, sheets and other profiles, but also of finished parts such as blown hollow bodies. Extruder essentially have the task of being pourable, as Powder, granules and the like applied thermopla Plastic, mixed with stabilizers, sliding agents and possibly dyes and fillers to promote compress and degas, homogenize and finally through the nozzle into the profile tool press. The molding compound must be heated by a cylinder as evenly as possible up to the processing temperature to be brought.

Due to the process, quality-reducing factors occur flows on the continuously flowing plastic melt on, so B. thermal and / or material inhomogeneities or undesirably long color change times. The quality of the  The end product is crucial in terms of quality and ho depending on the molten plasticity.

The present invention is based on the object an extruder mentioned in the preamble of claim 1 To further develop the genus in such a way that a well mixed one Plastic melt is provided on the profile tool.

This task is performed by an extruder with the features of claim 1 solved.

The art provided at the mixer outlet opening molten material is before entering the mold opening thoroughly mixed transversely to the direction of flow, so that when Entry into the tool material and thermal inhomo genetics of the plastic melt largely excluded can be. Material adhering to the wall is avoided, which also gives the surface a uniform appearance End product is guaranteed.

Due to the modular structure of the mixer, which essentially from a housing with screw flanges and inside inserted mixing elements, this can easily being repaired.

The mixing elements in a workpiece are advantageous too summarized. The mixing element is effective in two compartments divided by a locking element are partially delimited from each other fluidically. Moreover the locking element serves as a stop to the mixing form-fitting element in the mixer.

The plastic melt entering the mixer is in Flow direction seen through a first compartment of the  Mixing element in a central core stream and one surrounding ring current divided. The compartment is in essentially sleeve-shaped and passes through the core current the locking element in the second, also sleeve-shaped Compartment where this core flow is radial in tangential Direction emerges as a ring current. The ring current in the first Compartment is bundled on the locking element and into one Transferred nuclear power in the second compartment, where it Mixer exits as such. The core flows and the ring flows indicate adjustable volumes due to the design split up. The mixer is advantageously with heating surrounding elements, resulting in optimal physical Material properties of the plastic melt before entering let the tool adjust.

Further features of the invention result from the white ter claims, the description and the drawing, in which is an embodiment described in detail below example is shown. Show it:

Fig. 1 shows a schematic representation of a longitudinal section through an extruder,

Fig. 2 is a longitudinal section through an inventive mixer,

Fig. 3 is a plan view of the mixing element in Fig. 2,

Fig. 4 is an end view of the mixing element of FIG considered. 3 in the flow direction X,

Fig. 5 shows a longitudinal section through a mixer according to the invention with a plurality of mixing elements connected in series.

In Fig. 1, an extruder 1 for processing thermoplastic is shown. This consists of a filling funnel 4 for the intermediate storage of the raw material 5 and for its introduction into the extruder housing 29 . The granular or powdered raw material 5 is moved by means of the rotating screw 8 away from the hopper 4 to the extruder outlet opening 9 . During the conveying process, the heating elements 6 , which surround the extruder housing 29 , heat the raw material and convert it into a liquid melt. The thermoplastic melt 7 enters the mixer 2 at the extruder outlet opening 9 . The mixer 2 consists of a cylindrical housing 19 in the exemplary embodiment, which is surrounded by heating elements 17 . The heating elements 17 supply heat to the thermoplastic melt 7 inside the mixer 2 . The mixer 2 is fixed by means of a screw connection 18 on the extruder housing 29 . In the interior of the mixer 2 , a mixing element 3 is arranged, which is provided for mixing the thermoplastic melt 7 transversely to the flow direction X. The thermoplastic melt 7 emerges from the extruder 1 at the mixer outlet 16 and is fed to a tool (not shown).

Fig. 2 shows a longitudinal section through a mixer 2. The mixer 2 is fixed on the extruder housing 29 by means of a screw connection 18 . The thermoplastic melt 7 enters the mixer 2 at the mixer inlet 11 . The mixer 2 in the embodiment shown consists essentially of a cylindrical mixer housing 19 , which may be surrounded by the heating elements 17 for supplying heat to the thermoplastic melt 7 . Inside the mixer 2 , a mixing element 3 is positively and radially and axially fixed by means of the sleeves 31 and 32 . The mixing element 3 is formed in one piece and preferably a cylindrical rotating part with functionally different compartments 24 and 25 . In the flow direction X lie the first compartment 24 and the second compartment 25 in series and are separated from one another by the blocking element 26 . The first compartment 24 of the mixing element 3 has in its interior a preferably inclined towards the longitudinal axis Z of the mixing element 3 , substantially straight flow channel 27 . The first compartment 24 thus divides the thermoplastic melt stream 7 at the mixer inlet 11 into a central core stream 12 and a ring stream 14 . The volume flows of core flow 12 and ring flow 14 can be adjusted in relation to one another due to the design. The central core flow 12 flows through the first flow channel 27 , which opens into the second compartment 25 via a radial opening 39 . The central core flow 12 exits there as a ring flow 15 and is distributed over the circumference of the second compartment 25 of the mixing element 3 under the action of the flow curve channels 22 , 22 '( FIG. 3).

The mixing element 3 has at the mixer inlet 11 a ge ringiger outer diameter than the inner diameter of the ra dial surrounding sleeve 31 , so that a ring stream 14 can initially form over the entire circumference of the mixing element. An increase in the diameter of the first compartment 24 to the inside diameter of the sleeve 31 along the flow curve channels 21 , 21 ′ leads the ring stream 14 into a second flow channel 28 . The flow curve channels 21 , 21 'are each formed in the exemplary embodiment shown by a groove which is preferably rectangular in cross section and which, viewed in the direction of flow X, increases in depth. The groove extends symmetrically to the sectional plane in FIG. 2 on both sides of the mixing element 3 and opens into the second flow channel 28 in the flow direction X viewed in front of the blocking element 26 . The locking element 26 is used on the one hand for me mechanical fixation of the mixing element 3 between the sleeves 31 and 32 and on the other hand as a seal to prevent that from the ring flow 14 parts on the outer circumference of the compartment 25 of the mixing element 3 can flow off. The ring stream 14 flows as a central core stream 13 through the flow channel 28 and emerges from the interior of the mixing element 3 on the mixer outlet side 16 . On the mixer outlet side 16 , the core stream 12 on the mixer inlet side and the ring stream 14 on the mixer inlet side are thus reversed as ring stream 15 and core stream 13 .

FIG. 3 shows a top view of the mixer element 3 from FIG. 2. In the exemplary embodiment, the mixer element 3 is machined from one piece. The first Kompar time 24 has a central flow channel 27 , which extends in the embodiment in the form of a bore towards the second compartment 25 to the opening 39 . Two flow curve channels 21 , 21 'with lance-shaped edges and semicircular cross-section extend on both sides of the first compartment 24 and open into a second flow channel 28 which extends from the first compartment 24 inside the mixing element 3 to its mixer outlet openings. The second flow curve channels 22 , 22 ′ with a rectangular cross section are lance-shaped to the side of the mixer element 3 facing the mixer outlet. These second flow curve channels 22 , 22 'serve to distribute the central core stream 12 emerging from the opening 39 of the second compartment 25 over the circumference.

Fig. 4 shows a view of the mixer element 3 in the flow direction X viewed in Fig. 2. Each compartment 24 , 25 of the mixer element 3 is divided into regions of different diameters C, D by the edges of the flow curve channels. With the outer surfaces of the areas with the diameter C, the mixing element 3 is radially guided, while the mixer 11 and passing the mixer output passage 16 facing regions tes 3 have the Mischerelemen the diameter D. The radial gap that arises between the areas with the diameters D and C is used to form the respective ring currents 14 and 15 .

The mixing element 3 can also be designed as a welded tube construction. It is then also conceivable that the blocking element 26 takes over the separation of the ring currents 14 and 15 in such a constructive embodiment. The mixing element 3 can also be formed as a casting from different materials depending on the physical and chemical properties of the plastic melt.

Fig. 5 shows a longitudinal section through a mixer 2 having a plurality of series-connected mixing elements 3. In the exemplary embodiment shown, the mixing elements 3 are designed in the same way. However, the mixing elements 3 can nevertheless be designed differently in the shape of the flow curve channels and in their dimensions. The mixing elements 3 are arranged in the cylindrical mixer housing 19 one behind the other in the direction of flow. The mixing elements 3 are radially and axially positively fixed by means of the sleeves 31 , 32 , 43 and 44 . Otherwise, the same reference numerals apply to the same components as in FIG. 2.

Claims (16)

1. Mixer, in particular inner tube mixer, for arrangement at the outlet of an extruder ( 1 ) for thermoplastic processing with at least one housing-fixed mixing element ( 3 ), with an inlet ( 11 ) for the thermoplastic melt flow and a mixer outlet opening ( 16 ) a tool, characterized in that the mixing element ( 3 ) divides the incoming thermoplastic melt stream ( 7 ) into a central core stream ( 12 ) and a ring stream ( 14 ) surrounding it and the streams ( 12 , 14 ) at the mixer outlet ( 16 ) are interchanged, such that the input-side core stream ( 12 ) emerges as a ring stream ( 15 ) and the input-side ring stream ( 14 ) emerges as a core stream ( 13 ). 2. Mixer according to claim 1, characterized in that the mixer ( 2 ) connects an ex truder outlet opening ( 9 ) with a tool inlet opening ( 10 ). 3. Mixer according to claim 1, characterized in that the core flow ( 12 ) and the ring flow ( 14 ) have constructionally adjustable volume fractions. 4. Mixer according to claim 1, characterized in that on the housing ( 19 ) heating elements ( 17 ) are arranged. 5. Mixer according to claim 1, characterized in that the mixing elements ( 3 ) are designed as a one-piece component. 6. Mixer according to one of claims 1 to 5, characterized in that the housing ( 19 ) is zy-cylindrical and the mixing element ( 3 ) can be inserted from one end face ( 20 ). 7. Mixer according to one of claims 1 to 6, characterized in that the central core stream ( 12 ) via a flow curve channel ( 22 ) in a ring stream ( 15 ) is formed. 8. Mixer according to one of claims 1 to 6, characterized in that the outer ring stream ( 14 ) through at least one flow curve channel ( 21 ) in a central core stream ( 13 ) is formed. 9. Mixer according to one of claims 1 to 8, characterized in that the streams ( 12 , 13 , 14 , 15 ) forming mixing elements ( 3 ) in the flow direction (X) are arranged in a row in a row. 10. Mixer according to one of claims 1 to 9, characterized in that the housing ( 19 ) in the flow direction (X) of the thermoplastic melt ( 7 ) by means of a locking element ( 26 ) in a first compartment ( 24 ) and a second compartment ( 25 ) is divided. 11. Mixer according to claim 10, characterized in that the compartments ( 23 , 24 ) via flow channels ( 27 , 28 ) are interconnected. 12. Mixer according to claim 10 or 11, characterized in that the first and second compartments ( 24 , 25 ) of the mixing element ( 3 ) are each surrounded by a sleeve ( 31 , 32 ) which axially abuts the locking element ( 26 ). 13. Mixer according to claim 7 or 8, characterized in that the flow curve channels ( 21 , 21 ', 22 , 22 ') are rectangular in cross section. 14. Mixer according to claim 13, characterized in that the flow curve channels ( 21 , 21 ') in the first compartment ( 24 ) in the flow direction (X) of the thermoplastic stream deepen and the flow curve channels ( 22 , 22 ') in the second compartment ( 25 ) to flatten out. 15. Mixer according to one of claims 13 or 14, characterized in that the flow curve channels ( 21 , 21 ', 22 , 22 ') run symmetrically on both sides on the mixing element ( 3 ). 16. Mixer according to one of claims 1 to 5, characterized in that several, preferably differently designed mixing elements ( 3 ) are connected in series.