奥地利专利AT511362A1 DEVICE FOR PREPARING PLASTIC MATERIAL

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专利摘要:
The invention relates to a device and a method for processing plastic material with at least one receptacle (1) in which at least one about a rotational axis (10) rotatable mixing and / or crushing tool (3) for mixing and heating of the plastic material is arranged, and with at least one conveyor (5) for discharging the plastic material from the receptacle (1) with at least one worm (6) rotating in a housing (16), the conveyor (5) at its material inlet side via one in a side wall (9) of the receptacle (1) formed opening (8) for the entry or the feeding of the material with the interior of the receptacle (1) is connected, wherein the opening (8) in the region of the height of the mixing and / or crushing tool (3) is arranged , The invention is characterized in that the imaginary extension of the central longitudinal axis (15) of the conveyor (5) or the screw (6) counter to the conveying direction of the conveyor (5) on the axis of rotation (10) of the receptacle (1) without this the longitudinal axis (15) of the conveyor (5) relative to the rectified or parallel radials (11) of the receptacle (1) on the drain side or in the direction of rotation or movement (12) of the opening (8). passing mixing and / or crushing tool (3) or of the plastic material moved past the opening (8) is offset by a distance (18).
公开号:AT511362A1
申请号:T600/2010
申请日:2010-04-14
公开日:2012-11-15
发明作者:
申请人:Erema；
IPC主号:

专利说明:

The invention relates to a device according to the preamble of claim 1.
Numerous devices are known from the prior art, comprising a receptacle or cutting compactor for comminuting, heating, softening and processing a plastic material to be recycled and an extruder connected thereto for melting the material prepared in this way. The aim is to obtain a high quality end product, usually in the form of granules.
Thus, for example, EP 123 771 describes a device having a receptacle and an extruder connected thereto, wherein the plastic material supplied to the receptacle is comminuted by rotating the comminuting and mixing tools and brought into thrombus circulation and heated simultaneously by the introduced energy. This forms a mixture with sufficiently good thermal homogeneity. This mixture is discharged after appropriate residence time from the receptacle on the screw extruder while plasticized or melted. The screw extruder is arranged approximately at the height of the crushing tools and radially attached to the receptacle. In this way, the softened plastic particles are actively pressed into the extruder by the mixing tools.
Furthermore, numerous devices are known from the prior art, in which the extruder is connected tangentially to the receptacle.
All these devices have in common that the conveying or rotating direction of the mixing and crushing tools and thus the direction in which the material particles circulate in the receptacle, and the conveying direction of the extruder are substantially equal or in the same direction, this deliberately chosen arrangement guided by the desire to stuff the material as possible in the screw or forcibly feed it. In the process, and in the case of further developments, the aim was always to create as high a level of auger filling as possible and to reinforce this stuffing effect. For example, attempts have also been made to conically expand the intake area of the extruder or to curve the shredding tools in a sickle-shaped manner so that they can feed the softened material into the screw in a spatula-like manner.
For this purpose, for example, in WO 88/02684 a device has been described in which the extruder screw has been moved away from the radial position and offset radially, but not tangentially, has been connected to the receptacle. As a result of this lateral displacement, the force component of the axial force acting on the extruder screw in the axial direction exerted by the rotating tool 2: ♦ ♦ becomes greater in comparison to an arrangement in which the screw axis is arranged radially on the receiving container. By this inflow-side displacement of the stuffing effect is further enhanced and the plastic material is conveyed even better by the rotating tool in the extruder or -pressed.
Such devices are quite advantageous for some materials, especially for stretched or very strong plastics and for hard, small-sized flakes.
However, it has now been found in experiments that such devices are surprisingly not advantageous for all recyclable plastic materials to the same extent used and on the contrary may even have disadvantages in some areas.
Thus, for example, with materials having a low energy content, such as PET fibers or films, or with materials having an early stickiness or softening point, e.g. Polylactic acid (PLA), repeatedly observed the effect that the deliberate plugging of the plastic material in the intake area of the extruder under pressure leads to premature melting of the material. As a result, on the one hand reduces the conveying effect of the extruder or the Nutenbuchse by the lower toothing of the material with the grooves. In addition, there may also be a partial reflux of this melt in the area of the cutting compressor or receiving container, which means that still unmelted flakes adhere to the melt, thereby the melt cools again and partially solidifies and thus a schwulstartiges structure or conglomerate of partially solidified melt and solid plastic particles forms. As a result, the intake of the extruder clogged and stick the mixing and crushing tools. As a result, the throughput of the extruder is reduced because there is no longer sufficient filling of the screw. In addition, the mixed and
Lock in shredding tools. As a rule, in such cases, the system must be shut down and completely cleaned.
Additionally, problems arise with those polymeric materials that have been heated in the cutter compactor to near their melting range. If in this case the slot bushing is overfilled, the material melts and the feeder diminishes.
Even with, usually stretched, striped, fibrous materials with a certain length and a small thickness or stiffness, so for example in cut into strips of plastic films, problems arise. This primarily by the fact that the elongated material adheres to the downstream end of the feed opening of the screw, wherein one end of the strip protrudes into the receptacle and the other end in the catchment area. Since both the mixing tools and the worm run in the same direction or exert the same Förderrichtungs- and pressure component on the material, both ends of the strip in the same direction tensile and pressurized and the strip can not solve. This in turn leads to an accumulation of the material in this area, to a narrowing of the cross section of the intake opening and to a poor intake behavior and subsequently to loss of revenue. In addition, it may be due to the increased feed pressure in this area to melt, which in turn occur the problems mentioned above.
It is therefore an object of the present invention to provide a device with which the disadvantages mentioned above can be avoided and with which even sensitive or strip-like materials can be fed easily from the screw.
This object is achieved in a device of the type mentioned by the characterizing features of claim 1.
It is provided that the imaginary extension of the central longitudinal axis of the conveyor or the screw against the conveying direction of the conveyor on the axis of rotation of the receptacle passes without cutting them. The longitudinal axis of the conveyor is displaced relative to the rectified or parallel radials of the receptacle on the outlet side or, in the direction of rotation or movement of the mixing and / or comminuting tool passing past the opening or the plastic material passing past the opening by a certain distance. Thus, the conveying direction of the mixing tools and the conveying direction of the extruder is no longer, as known from the prior art, in the same direction, but at least slightly in opposite directions, whereby the initially mentioned Stopfeffekt is reduced. By deliberately reversing the direction of rotation of the mixing and crushing tools compared to previously known devices, the feed pressure decreases to the retraction position and reduces the risk of overfilling. Excess material is not stuffed or filled in this way with excessive pressure in the catchment area of the extruder, but on the contrary excess material is even tending to be removed from there, so that while there is always sufficient material in the catchment area, but almost no pressure or only a small amount Pressure is applied. In this way, the extruder screw can be filled sufficiently and always draw sufficient material without causing local pressure peaks, where the material could melt.
In this way, melting of the material in the area of the extruder feeder is prevented, which increases the operational efficiency, lengthens the maintenance intervals and reduces the downtimes due to any repairs and cleaning time increments.
By reducing the feed pressure and the pressure on any closing the intake opening slide is reduced, with which the degree of filling of the screw can be regulated in a known manner. The valves react more sensitively and the degree of filling of the screw can be set even more precisely. Especially for heavier materials, such as high-density polyethylene (HDPE) or PET regrind, it is easier to find the optimum operating point of the system.
In addition, it has proved to be surprisingly advantageous that materials which have already been softened to near melt, are better fed in the counter-rotating operation according to the invention. In particular, when the material is already in doughy or softened state, the screw cuts the material from the doughy ring. In a direction of rotation in the conveying direction of the extruder screw, this ring would rather be pushed past and there could be no scraping, whereby the feeder would cease. This is avoided by reversing the direction of rotation according to the invention.
In addition, in the processing of the above-described streaky or fibrous materials, the formed impurities or accumulations are easily solved or are not even formed because of the direction of rotation of the mixing tools downstream or downstream edge of the opening of the direction vector of the mixing tools and the directional vector of the extruder in almost opposite or at least slightly opposite directions, whereby an elongated strip can not bend around this edge and impose, but is entrained by the Mischtrombe in the receptacle again.
Overall, the inventive design improves the intake behavior and increases the throughput. The overall system of cutter compactor and extruder is thus more stable.
Further advantageous embodiments of the invention are described by the following dependent claims:
According to an advantageous development of the invention it is provided that the conveyor is arranged on the receptacle, that the scalar product from the tangential to the circle of the mixing and / or crushing tool or at the
Opening vorbeistreichenden plastic material and normal to the radial of the receptacle aligned, pointing in the direction of rotation or movement of the mixing and / or crushing tool direction vector and the direction vector of the conveying direction of the conveyor in each individual point or in the entire region of the opening or in each individual point or in the entire area immediately before the opening is zero or negative. In this way, the advantages mentioned above are achieved. In particular, it does not depend on the spatial arrangement of the mixing tools and the extruder to each other, for example, the mixing tools and the extruder screw or the opening need not necessarily lie on a common plane or the axis of rotation not be aligned normal to the bottom surface or the longitudinal axis of the extruder ,
A further advantageous embodiment results from the fact that the direction vector of the mixing and / or crushing tool with the direction vector of the conveying direction of the conveyor includes an angle greater than or equal to 90 ° and less than or equal to 180 °, wherein the angle at the intersection of the two directional vectors on upstream edge of the opening, in particular at the most upstream point on that edge or opening. This describes the angle range in which the extruder must be arranged on the receptacle in order to achieve the advantageous effects. In the entire region of the opening or in each individual point of the opening, an at least slight opposing orientation of the forces acting on the material or, in the extreme case, a pressure-neutral transverse alignment occurs. At no point in the opening is the scalar product of the directional vectors of the mixing tools and the screw conveyor positive, not even in a portion of the opening thus occurs too much stuffing effect.
A further advantageous embodiment of the invention provides that the direction vector of the direction of rotation or movement with the direction vector of the conveying direction includes an angle between 170 ° and 180 °, measured at the intersection of the two directional vectors in the middle of the opening. Such an arrangement applies, for example, when the extruder is arranged tangentially on the cutting compressor.
To ensure that no excessive stuffing occurs, it may be advantageously provided that the distance is greater than or equal to half the inner diameter of the housing of the conveyor or the piebald.
Furthermore, it may be advantageous in this sense, the distance greater than or equal to 7%, more advantageously greater than or equal to 20%, to measure the radius of the receptacle. . '* 6
· «* * 4 * * *« 4 · ·
In radially offset, but not tangentially arranged, extruders is advantageously provided that the imaginary extension of the longitudinal axis of the conveyor opposite to the conveying direction the interior of the receptacle passes through at least in sections.
In this context, it is advantageous if it is provided that the opening is arranged immediately in front of the rear end face of the screw in the conveying direction.
For extruders with an extended draw-in area or a grooved bush or extended pocket, it may be advantageous if the distance is greater than or equal to the radius of the receptacle. In particular, this applies to cases in which the conveyor is connected tangentially to the receptacle.
The reversal of the direction of rotation of the circulating in the container tools is by no means arbitrary, and you can not rotate the mixing tools in the opposite direction, either in the known devices or in the device according to the invention, especially not because the mixing and crushing tools in certain Are arranged asymmetrically or directionally oriented so that they act only on one side or in one direction. If one turned such an apparatus in the wrong direction, then neither a good Mischtrombe would develop, nor would the material be sufficiently crushed or warmed up. Each cutter compressor thus has its fixed predetermined direction of rotation.
In this connection, it is particularly advantageous if it is provided that the front regions or front edges of the mixing and / or comminution tools, which act on the plastic material and are oriented in the direction of rotation or movement, are differently shaped, curved, adjusted or arranged in comparison to in the direction of rotation or movement rear or trailing areas.
An advantageous arrangement provides that tools and / or knives are arranged on the mixing and / or comminution tool, which in the direction of rotation or movement on the plastic material crushing and possibly also acting warming, the blades preferably on one, in particular parallel to the bottom surface, arranged rotatable support disc are arranged.
Basically, the effects mentioned above are relevant not only in compressing screw extruders but also in non-compressing screw conveyors.
Again, local overfeeding should be avoided.
In a further advantageous embodiment, it is provided that the receptacle is substantially cylindrical with a flat bottom surface and a cylinder jacket-shaped side wall oriented vertically thereto.
It is also structurally simple if the axis of rotation coincides with the central center axis of the receptacle.
In a further advantageous embodiment, it is provided that the axis of rotation or the central center axis are aligned vertically or normal to the bottom surface.
These special geometries optimize the intake behavior in a structurally stable and simply constructed device.
In this context, it is also advantageous to provide that the lowest mixing and / or crushing tool and / or the opening are arranged at a small distance to the bottom surface, in particular in the region of the lowest quarter of the height of the receptacle.
Furthermore, it is advantageous for processing when the outer edges of the mixing and / or crushing tools reach close to the side wall.
The invention also provides a method of operating such a device.
On the one hand, the direction of rotation or movement of the mixing and / or comminution tool must be adjusted and the mixing and / or comminution tool designed or the knives arranged and the mixing and / or comminution tool in the receptacle so arranged and aligned be done that a proper mixing and processing of the polymer material. It must form a proper Mischthrombe and the mixing and / or crushing tool must be able to act on the material correctly, i. mixing, heating and optionally comminuting.
In addition, it should be noted that the rotating or moving direction of the mixing and / or crushing tool is set so that the imaginary extension of the central longitudinal axis of the conveyor or the screw counter to the conveying direction of the conveyor on the axis of rotation of the receptacle without the latter passes, wherein the longitudinal axis of the conveyor relative to the rectified or parallel radials of the receptacle on the drain side or in the direction of rotation or movement of the opening at the opening passing mixing and / or crushing tool or moved past the opening of the plastic material offset by a distance is. Thereby, the above advantageous effects are achieved.
This method can be further developed by the features of the dependent claims to the device.
Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings.
The invention is illustrated schematically by means of embodiments in the drawings and will be described below with reference to the drawings, for example.
Fig. 1 shows a vertical section through a device according to the invention.
Fig. 2 shows a horizontal section through a slightly modified
Embodiment in the direction of the arrow II of Fig. 1st
Fig. 3 shows a further embodiment with greater radial displacement.
Fig. 4 shows another embodiment with approximately tangentially connected
Extruder.
Fig. 5 shows a further embodiment with approximately tangentially connected
Extruder and curved mixing tools.
Fig. 6 shows a device known from the prior art.
The advantageous apparatus for recycling plastic material shown in Fig. 1 comprises a receptacle 1, such as that known in the art, e.g. from EP 123 771, is well known. The receptacle 1 is cylindrical with a flat bottom surface 2 and a vertically oriented cylinder jacket-shaped side wall. 9
At a small distance to the bottom surface 2, in about 10 to 20%, possibly less, the height of the side wall 9 - measured from the bottom surface 2 to the top edge of the side wall 9 - a parallel to the bottom surface 2 aligned, planar support plate 13 is arranged around a central axis of rotation 10, which is also the central center axis of the receptacle 1, in the marked with an arrow rotation or. Movement direction 12 is rotatable. The carrier disk 13 is driven by a motor 21, which is located below the receptacle 1. On the carrier plate 13, knives 14 are arranged, which together with the carrier plate 13 form the mixing and / or shredding tool 3.
As indicated schematically in FIG. 2, the knives 14 are not arranged regularly on the carrier disk 13, but are specially designed, set or arranged on the front edge pointing in the direction of rotation or movement 12 in order to be able to act on the plastic material , As a result, a mixing drum is formed in the receptacle 1, in which the material is swirled both from top to bottom and in the direction of rotation 12. Such a device can thus be operated only in the predetermined direction of rotation or movement 12 due to the special arrangement of the mixing and crushing tools 3 and the knife 14
* · · * *
If the direction of rotation 12 is and can not be reversed without further ado or changes, it can not be reversed.
Furthermore, deflectors can be mounted on the container circumference or on the side wall 9 for better feeding of the material to the opening 8.
The mixing and comminution tools 3 shown in FIGS. 3 and 4 are also shown only schematically. The knives 14 are disposed on the leading edges 22 acting on the material (Figure 3).
Theoretically, it is also possible that the mixing and crushing tools 3 are constructed regularly or symmetrically. Even then, however, the direction of rotation or movement 12 is not arbitrarily reversible, but either predetermined by the engine or determined by special geometries of the receptacle 1 and / or the catchment area of the extruder 5.
In comparison, a device known from the prior art is shown in FIG. This has two levels of mixing and crushing tools 3, which rotate in the direction of the arrow 12, that is not in the direction of the invention. In the vicinity of the bottom 2 circumferential blades 14 are arranged in the lower level, which are aligned radially and straight. In the overlying level 13 knives 14 are arranged with front cutting edges 22 on a support plate, which are curved or angled against the direction of rotation 12. In operation, this results in the circulation of these tools the desired and necessary Mischthrombe. A simple change of the direction of rotation 12 is therefore not possible here.
At the height of the single crushing and mixing tool 3 in the present case an opening or inlet or, feed opening 8 is formed in the side wall 9 of the receptacle 1, to which the housing 16 of a conveyor 5 is connected. In the housing 16, a compressing extruder screw 6 is rotatably mounted, which is driven by a shaft from the motor 21.
The outer edges of the mixing and crushing tools 3 reach the side wall 9 until they are relatively close, about 5% of the radius. The screw 6 and the housing 16 of the extruder 5 are adapted in the region of the opening 8 to the contour of the inner wall of the receptacle 1 and set back. No part of the extruder 5 projects into the interior of the receptacle 1. The mixing and / or comminution tools 3 or the knives 14 are located at almost the same height or plane as the central longitudinal axis 15 of the extruder 5. However, the outermost ends of the blades 14 are sufficiently spaced from the end face 7 of the extruder 5.
In the examples shown in the figures, it is always a compressing single-screw or single-screw extruder. Alternatively, however, it is also possible to use the «« so :: * · · «« «« * * «« ·· * * * * * * * * * * *
Provision of twin or multi-screw extruders possible or the installation of non-compressing screw conveyors.
In operation, the plastic material to be reprocessed, usually in the form of plastic waste, bottles or films, is introduced into the receptacle 1 via an open feed hopper. Alternatively it can be provided that the receptacle 1 is closed and at least a technical vacuum can be evacuated. The introduced plastic material is comminuted by the circulating mixing and comminution tools 3, mixed and thereby heated by the introduced mechanical friction energy and softened, but not melted. After a certain residence time in the receiving container 1, the softened, but not molten material is introduced into the intake area of the extruder 5 or into the opening 8, where it is captured by the screw 6 and subsequently melted.
FIG. 2 shows a section through an embodiment which is very similar to FIG. 1 on the level of the extruder screw 6. It can be seen that the axis of rotation 10 and the central center axis of the receptacle 1 coincide and the cross section of the receptacle 1 is circular. Alternatively, elliptical shapes or an eccentric arrangement of the axis of rotation 10 would be possible.
The extruder 5 is a known conventional extruder, in which the softened plastic material is melted in a first zone, then a compression takes place and the melt then emerges on the opposite side. The extruder 5 promotes in the direction of the arrow 17. The housing 16 and the screw 6 are slightly widened conically in the catchment area on the outlet side. The opening 8 is arranged immediately in front of the rear end face 7 of the screw 6.
In the embodiment of FIG. 2, the extruder or conveyor 5 is not connected radially to the receptacle 1, but offset on the outlet side. The imaginary extension of the central longitudinal axis 15 of the conveyor 5 and the screw 6 against the conveying direction 17 of the conveyor 5 to the rear leads left next to the axis of rotation 10 over without cutting them. The longitudinal axis 15 is offset relative to the rectified or parallel radials 11 of the receptacle 1 by a distance 18 in the direction of rotation or movement 12. The imaginary extension of the longitudinal axis 15 of the conveyor 5 passes through the interior of the receptacle first
The distance 18 in Fig. 2 corresponds to about 15 to 20% of the radius of the receptacle 1. The distance 18 corresponds in the present case about half the inner diameter of the housing 16 and thus provides a first limiting case or
Extreme value with the smallest possible offset or distance 18 is, in which the rotational or movement direction 12 of the mixing and / or crushing tools 3 of the conveying direction 17 of the conveyor 5 is at least slightly opposite, over the entire surface of the opening 8. Under the terms "Opposite" or "opposite" here means any orientation of the vectors to each other which is not acute-angled, as will be explained in detail below.
In other words, the scalar product of a direction vector 19 of the direction of rotation 12, which is tangent to the circle of the mixing and / or
Crushing tool 3 or tangentially to the opening 8 vobeistreichenden plastic material is aligned and in the direction of rotation or movement 12 of the mixing and / or crushing tools 3, and a direction vector 17 of the conveying direction of the conveyor 5, in the conveying direction parallel to the central longitudinal axis 15 runs everywhere zero or negative in each individual point of the opening 8 or in the area immediately in front of the opening 8, but nowhere positively.
The scalar product is exactly zero in FIG. 2 in the borderline, most upstream, point 20 located at the most upstream edge of the orifice 8. The angle α between the direction vector 17 of the conveying direction and the direction vector 19 is, measured in point 20 of Fig. 2, exactly 90 °. If one proceeds along the opening 8 to the left, that is to say in the direction of rotation 12, the angle α becomes ever larger and becomes an obtuse angle, and the scalar product simultaneously becomes negative. At no point or area of the opening 8, however, is the scale product positive or the angle α less than 90 °. As a result, local overfeeding can not take place even in a partial region of the opening 8 or, in any region of the opening 8, there can be no harmful inflated tamping action. This also makes a decisive difference to a radial arrangement, since point 20 or the edge 20 in the case of a radial arrangement of the extruder 5 has an angle σ < 90 ° and those areas of the opening 8, which are located to the right of the radial 11 and upstream or upstream, would have a positive scalar product. This can accumulate locally melted plastic goods in these areas.
In Fig. 3, an alternative embodiment is shown in which the conveyor 5 on the outlet side is even further radially offset than in Fig. 2 and the distance 18 is correspondingly larger. The angle α measured at point 20 is about 145 °, which compared to the device of Fig. 2, the stuffing effect is reduced even further, which may be even more advantageous for certain sensitive polymers. The seen from the receptacle 1 from right edge of the housing 16 connects tangentially to the receptacle 1, whereby, in contrast to Fig. 2 no blunt transitional edge is formed, at the material could catch.
4, a further alternative embodiment is shown, in which the extruder 5 is connected tangentially to the receptacle 1. The angle α measured at point 20 between the directional vector 19 and the directional vector 17 is, almost maximum, about 160 °. In the present case, the rearward extension of the longitudinal axis 15 of the conveyor 5 no longer penetrates the interior of the receptacle 1, but runs past it. The distance 18 is further increased and even larger than the radius of the receptacle 1. The extruder 5 is thus offset in a pocket-like extension to the outside or the catchment area is slightly deeper. An angle β, not shown in FIG. 4, measured in the middle or in the center of the opening 8 between the directional vector 19 and the directional vector 17 is approximately 175 °. The device according to FIG. 4 presents the second limiting case or extreme value with the relatively lowest stuffing effect. With such an arrangement, a particularly pressureless feeding is possible and such a device is particularly suitable for sensitive materials which are processed near the melting region or for long streaks It's good.
Fig. 5 shows a further alternative embodiment with tangentially connected extruder 5 and curved on the support plate 13 and mutually offset knives or tools 14, wherein seen in the direction of rotation 12 front cutting edges 22 cause comminution and heating of the material.

权利要求:
Claims (17)
[1]
1. A device for processing, in particular thermoplastic, plastic material, with at least one receptacle (1) in which at least one mixing element rotatable about an axis of rotation (10) is provided. and / or comminution tool (3) for mixing and heating and optionally comminution and / or softening of the plastic material, and with at least one conveyor (5) for dispensing the plastic material from the receptacle (1) with at least one in a housing (16 ), wherein the conveyor (5) at its material inlet side via a in a side wall (9) of the receptacle (1) formed opening (8) for the entry or feeding of the material with the interior of the receptacle (1 ), wherein the opening (8) in the region of the height of the mixing and / or crushing tool (3) is arranged, characterized in that the imaginary extensions the longitudinal axis (15) of the conveyor (5) or the screw (6) against the conveying direction of the conveyor (5) on the axis of rotation (10) of the receptacle (1) passes without cutting them, with the longitudinal axis (15) of the conveyor (5) relative to the rectified or parallel radials (11) of the receptacle (1) on the outlet side or in the direction of rotation or movement (12) of the mixing and / or comminution tool (3) passing the opening (8) ) or of the plastic material moved past the opening (8) is offset by a distance (18).
[2]
2. Apparatus according to claim 1, characterized in that the conveyor (5) is arranged on the receptacle (1), that the scalar product from the tangential to the circle of the mixing and / or crushing tool (3) or at the opening ( 8) moved past plastic material and normal to the radial (11) of the receptacle (1) aligned in the direction of rotation or movement (12) of the mixing and / or crushing tool (3) facing direction vector (19) and the direction vector (17) of the conveying direction the conveyor (5) in each individual point or in the entire region of the opening (8) or immediately before the opening (8) is zero or negative.
[3]
3. Apparatus according to claim 2, characterized in that the direction vector (19) of the mixing and / or crushing tool (3) and the direction vector (17) of the conveying direction of the conveyor (5) an angle (a) of greater than or equal to 90 ° and less than or equal to 180 °, measured at the intersection of the two directional vectors (17,19) located on the upstream of the rotational or movement direction (12) ». 24 * • * · inlet-side edge of the opening (8), in particular in furthest upstream point (20) on this edge or the opening (8).
[4]
4. Apparatus according to claim 2 or 3, characterized in that the direction vector (19) of the rotational or movement direction (12) and the directional vector (17) of the conveying direction an angle (ß) between 170 ° and 180 ° include, measured in Intersection of the two directional vectors (17,19) in the middle of the opening (8).
[5]
5. Device according to one of claims 1 to 4, characterized in that the distance (18) is greater than or equal to half the inner diameter of the housing (16) of the conveyor (5) or the Schecke (6), and / or > 7%, preferably > 20%, of the radius of the receptacle (1).
[6]
6. Device according to one of claims 1 to 5, characterized in that the imaginary extension of the longitudinal axis (15) of the conveyor (5) opposite to the conveying direction the interior of the receptacle (1) at least partially passes through.
[7]
7. Device according to one of claims 1 to 6, characterized in that the opening (8) immediately in front of the conveying direction (17) rear end face (7) of the screw (6) is arranged.
[8]
8. Device according to one of claims 1 to 7, characterized in that the distance (18) is greater than or equal to the radius of the receptacle (1).
[9]
9. Device according to one of claims 1 to 8, characterized in that the conveyor (5) is connected tangentially to the receptacle (1).
[10]
10. Device according to one of claims 1 to 9, characterized in that the mixing and / or crushing tool (3) tools and / or knives (14), which in the rotational or movement direction (12) comminuting the plastic material and optionally acting warming, wherein the tools or knives (14) are preferably arranged on a, in particular parallel to the bottom surface (12), rotatable carrier disc (13).
[11]
11. Device according to one of claims 1 to 10, characterized in that acting on the plastic material in the direction of rotation or movement (12) facing the front areas or leading edges (22) of the mixing and / or crushing tools (3) or Knife (14) are formed differently, employed, curved and / or arranged in comparison to the in the direction of rotation or movement (12) rear or trailing areas.
[12]
12. Device according to one of claims 1 to 11, characterized in that the conveyor (5) is a non-compressing screw conveyor or a compressing screw extruder.
[13]
13. Device according to one of claims 1 to 12, characterized in that the receptacle (1) is substantially cylindrical with a flat bottom surface (2) and a vertically oriented cylinder jacket-shaped side wall (9) and / or the axis of rotation (12) the central central axis of the receptacle (1) coincides and / or the axis of rotation (12) or the central central axis are aligned vertically or normal to the bottom surface (2),
[14]
14. The device according to one of claims 1 to 13, characterized in that the lowermost mixing and / or crushing tool (3) and / or the opening (8) at a small distance to the bottom surface (2), in particular in the region of the bottom of the Height of the receptacle (1) are arranged.
[15]
15. Device according to one of claims 1 to 14, characterized in that the outer edges of the mixing and / or Zerkieinerungswerkzeuge (3) close to close to the side wall (9).
[16]
16. Use of a device according to one of claims 1 to 15 for the treatment or recycling of, in particular thermoplastic, plastic material,
[17]
17. A method for operating a device according to one of claims 1 to 15, characterized in that in particular by using a device according to one of claims 1 to 15, the rotational or movement direction (12) of the mixing and / or crushing tool (3 ) is set and the mixing and / or crushing tool (3) designed and aligned in the receptacle (1) and aligned so that a proper mixing and processing of the polymer material takes place, wherein the rotational or movement direction (12) of the Mixing and / or crushing tool (3) is also adjusted so that the imaginary extension of the central longitudinal axis (15) of the conveyor (5) and the screw (6) against the conveying direction of the conveyor (5) on the axis of rotation (10) of the receiving container (1) passes without cutting, wherein the longitudinal axis (15) of the conveyor (5) relative to the rectified or parallel radials (11) of the Receiving container (1) on the outlet side or in the direction of rotation or movement (12) of the mixing and / or comminuting tool (3) or of the plastic material moved past the opening (8) by a distance (18) is offset. Vienna, April 14, 2010

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公开号 | 公开日 | 专利标题

EP2689908B1|2016-02-10|Device and method for processing plastic materials

EP2766158B1|2015-12-16|Apparatus for processing plastic material

EP2766157B1|2015-12-16|Apparatus for processing plastic material

EP2766161B1|2015-12-16|Apparatus for processing plastic material

EP2768645B1|2015-12-16|Apparatus for processing plastic material

EP2766159B1|2015-12-16|Apparatus for processing plastic material

EP2766165B1|2016-02-10|Apparatus for processing plastic material

DE202012012586U1|2013-05-28|Device for processing plastic material

DE202012012568U1|2013-06-10|Device for processing plastic material

DE202012012589U1|2013-07-05|Device for processing plastic material

EP2766167A1|2014-08-20|Apparatus for processing plastic material

EP2766163A1|2014-08-20|Apparatus for processing plastic material

AT512207A1|2013-06-15|DEVICE FOR PREPARING PLASTIC MATERIAL

同族专利:

公开号 | 公开日

DK2689908T3|2016-05-23|

SI2558263T1|2014-05-30|

AU2011241454B2|2014-09-04|

CL2012002860A1|2013-08-09|

EP2558263B1|2014-01-22|

RU2012148284A|2014-05-20|

KR20130051941A|2013-05-21|

HUE027765T2|2016-11-28|

SI2689908T1|2016-06-30|

MX2012011687A|2012-12-17|

WO2011127508A1|2011-10-20|

PT2558263E|2014-03-06|

ZA201206639B|2013-04-24|

BR112012026196B8|2020-02-18|

DE202011108491U1|2012-03-14|

CA2795962A1|2011-10-20|

HRP20140310T1|2014-05-09|

BR112012026196A2|2016-07-05|

UA106277C2|2014-08-11|

ES2568061T3|2016-04-27|

ES2450050T3|2014-03-21|

BR112012026196B1|2020-01-28|

TWI545000B|2016-08-11|

RS54657B1|2016-08-31|

RU2532570C2|2014-11-10|

AU2011241454A1|2012-10-18|

EP2689908A1|2014-01-29|

KR101525381B1|2015-06-03|

US20160096287A1|2016-04-07|

US9216521B2|2015-12-22|

RS53232B|2014-08-29|

CN102933360A|2013-02-13|

JP2013527051A|2013-06-27|

DK2558263T3|2014-04-07|

TW201206671A|2012-02-16|

PL2558263T3|2014-06-30|

EP2558263A1|2013-02-20|

US10173346B2|2019-01-08|

US20130113139A1|2013-05-09|

PL2689908T3|2016-08-31|

JP5530559B2|2014-06-25|

CA2795962C|2017-05-09|

AT511362B1|2014-01-15|

EP2689908B1|2016-02-10|

HRP20160456T1|2016-06-03|

CN102933360B|2016-07-06|

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AT512209B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512147B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512146B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512149B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512145B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512207B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512223B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512208B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512205B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512148B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512222B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

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AT511362B1|2010-04-14|2014-01-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512208B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512149B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512146B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512223B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512205B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512212B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512207B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512148B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512145B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT512209B1|2011-10-14|2015-02-15|Erema|DEVICE FOR PREPARING PLASTIC MATERIAL|

AT515363B1|2014-01-28|2018-12-15|Erema Eng Recycling Maschinen & Anlagen Gmbh|chopping tool|

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AT522425B1|2019-03-20|2022-01-15|Erema Eng Recycling Maschinen & Anlagen Gmbh|peeling screw|

CN110549517B|2019-10-16|2021-09-21|苏州乐米凡电气科技有限公司|PVC wire casing recycling processing system|

法律状态:

优先权:

申请号 | 申请日 | 专利标题

ATA600/2010A|AT511362B1|2010-04-14|2010-04-14|DEVICE FOR PREPARING PLASTIC MATERIAL|ATA600/2010A| AT511362B1|2010-04-14|2010-04-14|DEVICE FOR PREPARING PLASTIC MATERIAL|

RS20160234A| RS54657B1|2010-04-14|2011-04-13|Device and method for processing plastic materials|

TW100112809A| TWI545000B|2010-04-14|2011-04-13|Device for processing plastic material, use of the device and method for operating the device|

RU2012148284/05A| RU2532570C2|2010-04-14|2011-04-13|Device for polymer preparation, application of device for preparation or secondary processing of thermoplastic polymer and method of its application|

UAA201212790A| UA106277C2|2010-04-14|2011-04-13|Apparatus for processing plastics material, its use and method of operation|

PCT/AT2011/000180| WO2011127508A1|2010-04-14|2011-04-13|Apparatus for processing plastics material|

PT11718234T| PT2558263E|2010-04-14|2011-04-13|Apparatus for processing plastics material|

DK11718234T| DK2558263T3|2010-04-14|2011-04-13|Apparatus for processing plastic material|

PL11718234T| PL2558263T3|2010-04-14|2011-04-13|Apparatus for processing plastics material|

SI201130141T| SI2558263T1|2010-04-14|2011-04-13|Apparatus for processing plastics material|

DE201120108491| DE202011108491U1|2010-04-14|2011-04-13|Device for processing plastic material|

KR1020127029870A| KR101525381B1|2010-04-14|2011-04-13|Apparatus for processing plastics material|

PL13189929T| PL2689908T3|2010-04-14|2011-04-13|Device and method for processing plastic materials|

MX2012011687A| MX2012011687A|2010-04-14|2011-04-13|Apparatus for processing plastics material.|

AU2011241454A| AU2011241454B2|2010-04-14|2011-04-13|Apparatus for processing plastics material|

EP13189929.6A| EP2689908B1|2010-04-14|2011-04-13|Device and method for processing plastic materials|

EP20110718234| EP2558263B1|2010-04-14|2011-04-13|Apparatus for processing plastics material|

DK13189929.6T| DK2689908T3|2010-04-14|2011-04-13|An apparatus and method for processing plastic material|

BR112012026196A| BR112012026196B8|2010-04-14|2011-04-13|device for processing plastic material, use and method for driving it|

RSP20140143| RS53232B|2010-04-14|2011-04-13|Apparatus for processing plastics material|

ES13189929.6T| ES2568061T3|2010-04-14|2011-04-13|Device for processing synthetic material|

US13/641,087| US9216521B2|2010-04-14|2011-04-13|Apparatus for processing plastics material|

JP2013504057A| JP5530559B2|2010-04-14|2011-04-13|Plastic material processing equipment|

ES11718234T| ES2450050T3|2010-04-14|2011-04-13|Device for processing synthetic material|

SI201130816A| SI2689908T1|2010-04-14|2011-04-13|Device and method for processing plastic materials|

CN201180018841.XA| CN102933360B|2010-04-14|2011-04-13|For preparing the device of plastic material|

CA2795962A| CA2795962C|2010-04-14|2011-04-13|Device for processing plastic material|

ZA2012/06639A| ZA201206639B|2010-04-14|2012-09-05|Apparatus for processing plastics material|

CL2012002860A| CL2012002860A1|2010-04-14|2012-10-12|Device for processing synthetic material, it has at least one collecting vessel, at least one mixing and / or crushing tool, at least one conveyor that has at least one worm that rotates inside a housing, where the imaginary extension of the shaft longitudinal center of the conveyor passes along the axis of rotation of the container without being cut with it; use; and associated procedure.|

HRP20140310| HRP20140310T1|2010-04-14|2014-04-01|Apparatus for processing plastics material|

US14/965,538| US10173346B2|2010-04-14|2015-12-10|Device for processing plastic material|

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