SE508021C2 - Process for processing plastic materials - Google Patents

Abstract

The device comprises a cylindrical chamber (2) fitted with a loading hopper (4) and with a discharging well (5). A rotor (6) fitted with blades (31, 32) is driven in rotation by an electric motor (7) via a clutch (18). The chamber (2) and the bearings (22) of the rotor (6) are surrounded by a protective shroud (26). In the chamber (2), a mixture containing at least two different thermoplastic polymers is subjected to stirring (agitation) by the blades (31, 32) of the rotor (6), and this treatment is stopped after the appearance of a rapid increase in the energy consumed. A homogeneous thermoplastic is thus obtained.

Description

40 508 021 2 based waste material is considerably reduced, especially with regard to materials which are included in household waste.

The present invention seeks to provide a solution to the problem of recycling thermoplastic polymer waste, enabling the provision of a homogeneous thermoplastic material, which can be used using the same methods used for the original thermoplastic polymers, while eliminating the need to separate or sort the waste in question in advance on the basis of the chemical nature of the polymers on which the waste is based.

The present process is characterized in that at least two different thermoplastic polymers or copolymers in the atomized state are subjected to processing in the form of mixing and stirring in a manner according to which a product which predominantly consists of homogeneous thermoplastic material is obtained.

The treatment is advantageously carried out in a closed chamber, which is provided with a mechanical stirring device. The mechanical stirring device in question preferably cooperates with a device for measuring the energy which is absorbed by the material undergoing the treatment, and the device comprises at least one stirrer component, which comprises, for example, a rotor, which is provided with a plurality of blades.

The chemical or physico-chemical process or processes which occur throughout the process by which conversion from the original mixture with different thermoplastic polymers to homogeneous material is ensured are not at present fully understood, and the invention is not fully understood. in some respect limited by the mechanisms of the processes, nor in the order in which they proceed or the corresponding time required.

However, during the mixing and stirring processing of the mixture with thermoplastic polymers or copolymers, it is probable that solid particles simultaneously undergo a rapid separate heating due to mutual friction and / or friction against agitator components and walls in the treatment vessel, whereby virtually all particles are heated simultaneously to a temperature corresponding to the respective softening intervals of the materials. It is also probable that a reduction in the average size of the particles also occurs at a certain stage of the processing, whereby at least a subset of the particles still retains the solid nature or in which at least a subset of the particles are at least partially liquid or solid. Although the underlying causes are not entirely clear, a relatively sudden transition can be observed from a stage at which the various separate thermoplastic polymer particles or copolymer particles in the original mixture are separated from each other, and can be observed separately, and a later stage at which it is no longer possible to distinguish separate interfaces between these parts, whereby in turn the mass as a whole has changed to a homogeneous nature, with the exception of the possible presence of particles with materials which are not miscible with the thermoplastic polymers.

These phenomena are completely unexpected, given that one is dealing with, for example, polymer particles with a relatively low melting point such as polyolefins and with polymer particles with a relatively high melting point, for example polyamides.

The temperature reached in the mixture with thermoplastic polymers or copolymers undergoing processing according to the present process is normally in the range 150 ° -300 ° C.

The homogeneous mass obtained by the processing in the form of stirring and mixing is normally obtained in the form of a paste with rheological properties corresponding to the so-called "pseudoplastic state".

The homogeneous pasty pulp in question can advantageously be subjected directly to granulation treatment, which is designed for transferring the pulp to granules of normal type, and which is suitable for use in machines for manufacturing molded or injection molded parts, according to known industrial methods.

All granulation machines that are available can be used, for example based on extrusion under pressure.

It is also advantageous, in accordance with what is known per se, to filter off the paste which is discharged during the granulation process, for example through a sieve with wire mesh, in a manner according to which the particles are separated from solid material, which _ possibly included in the pasta. The particles of solid material may comprise heat-crosslinkable polymers, metals, inorganic materials, for example fragments of stone, glass, etc., and in general all substances which are not miscible with the thermoplastic polymers.

The invention is particularly applicable with respect to the processing of starting materials which contain at least two different thermoplastic polymers or copolymers in finely divided form and at least one solid material which is immiscible with the thermoplastic polymers or copolymers. In this case, at least one filtration step of the obtained product is taken to separate from the product particles of material which are of a type other than the homogeneous thermoplastic material and which are dispersed in the latter material.

The process according to the invention can be carried out continuously or non-continuously, i.e. by treating the original mixture with thermoplastic polymers or copolymers in successive subsets.

The device for carrying out the process is characterized in that it comprises a chamber which is provided with components for mixing and stirring, a device for supplying the starting materials intended for treatment into the chamber and a device for outflow from the chamber of the product obtained by the treatment. of the starting materials in the chamber.

The treatment components preferably comprise at least one propeller or rotor, which is provided with blades and rotates at high speed, for example at a rotational speed between 1000 and 2800 rpm.

However, it is possible to use any other suitable shaking device and / or stirrer and / or mixing device of mechanical or non-mechanical type.

According to a particularly preferred construction of the device, the chamber is cylindrically shaped and has a horizontal axis, and the shaking and stirring device consists of a rotor which is provided with a plurality of blades, the rotor being mounted coaxially with respect to the axis of the chamber and through the chamber and is connected to an outside chamber. located drive means for rotation of the rotor in question. The object of the invention is likewise an application of the stated process with regard to the provision of articles of plastic material, and is characterized in that the product is transferred to articles obtained by injection molding.

The invention is illustrated on the basis of a more detailed description which follows in connection with non-delimited approaches according to the invention and in connection with exemplification, also without delimitation, with respect to device for carrying out the method, reference being made to the accompanying drawings, in which Fig. 1 refers to a schematic view Fig. 2 is a schematic view from the front of a part of the device shown in Fig. 1, Fig. 3 is a schematic view from the same part of the device as Fig. 2, but with certain components and elements shown in cross section, Fig. 4 refers to a schematic cross-sectional view of the device and Fig. 5 in partial schematic view shows a rotor in the form of a component in the device.

The device shown in Figures 1 to 5 comprises a cylindrical chamber 2 with a horizontal axis and which is provided with a hopper 4, which is placed at the top together with a drum 5 for emptying. A rotor 6, which is coaxially mounted inside the chamber 2, is driven by the electric motor 7. The walls of the chamber 2 consist of a unit 10, which is manufactured by joining two semi-cylindrical housings 11 and 12, which are mounted by means of a hinge along a side edge 13, and a safety wire 14 is located along the edge 15 on the opposite side of the edge 13.

The upper housing 12 is connected to a pneumatic device 16 of a per se known type, which enables the housing to be opened by being allowed to pivot about the hinge 13. The driving movement of the rotor 6 through the motor 7 is transmitted by means of a pneumatically controlled clutch 18. The movement to the rotor 6 can be interrupted if necessary by means of a brake member 21, which is also pneumatically controlled.

The rotor 6 is supported at each end by a bearing 22, which is mounted on a pillar 23. A threaded seam 24 enables tight fitting of each end of the shaft to the rotor 6 via the wall of the chamber 2.

IJ u: 40 508 021 6 A protective housing 26 (Fig. 1) surrounds the part of the device which comprises the chamber 2 together with the rotor shafts 22.

As will most clearly be seen from Fig. 5, the rotor 6 comprises a cylindrical shaft 30, which is provided with a plurality of radial blades 31, 32, which are designed in two different ways. In particular, the orientation of the blades 32, which are mounted near each end of the shaft 30, is such that the charge of the material processed in the chamber 2 obtains a movement which tends to push the material away from the chamber wall which is in connection with the ends of the shaft 30, so that the material is returned towards the chamber via the area which is subject to mixing as well as stirring with the blades 31.

The diameter of the chamber 2 together with the length of the blades 31 and 32 are such that when the rotor 6 has room temperature or almost room temperature the distance between the outer ends of the blades 31 and 32 and the inner wall 40 of the chamber 2 is of the order of 0.5 to 1 mm.

It has proved advantageous to dimension the rotor 6 together with the drive motor 7 in relation to the internal volume of the chamber 2, so that the maximum transferable mechanical power to the processed material in the chamber 2 through the rotor 6 is of the order of 1 to 2 kW per 1 of the material .

At a total internal volume in the chamber 2 of 85 l (for an experimental prototype) it was found that the maximum power from the engine can advantageously be of the order of 128 kw.

Example 1 The starting material used is a mixture of thermoplastic polymers in the form of irregular fragments, however, all dimensions below 5 mm derive from the extraction of plastic-based waste material in household waste, and which after corresponding separation from other components in the waste have simply been washed with water. accompanied by drying. 40 50 CO 021 7 The average composition of the mixture is as follows (in% by weight): ABS polymer: 50 Polyvinyl chloride: 20 Polypropylene: 15 Polyethylene Polyamide: Polymethyl methacrylate (PMMA) For processing the mixture used a device of the specified type, wherein the chamber for stirring and mixture has an internal volume of 85 l, the motor used for driving the rotor consists of an electric three-phase motor with pole changer and the maximum power 140 kw, the power supply being 380 V / 50 hertz with a cosine value of 0.85. After the rotation time of about 3 minutes for the rotor, a steep increase is obtained, immediately followed by stabilization, of the power consumption due to the mass undergoing agitation as well as mixing, which is manifested in the form of a jump for the current which loads the motor, and which reaches a maximum value of the order of 270-280 A at the highest part of the peak. The time required for the increase in current between the initial value and the upper peak value as well as for the subsequent decrease in current (to a stabilized value above the original value) is in both cases approx. 5 sec.

The rotation time of the rotor is extended by about 10-20 seconds after stabilization of the current which loads the rotor drive motor, after which the rotor is stopped, and the homogeneous, gel-like pasty mass obtained in the treatment of the polymer mixture is recovered immediately.

The pulp in question may undergo granulation treatment either immediately after provision from the treatment chamber or after solidification by cooling by means of an extruder of known construction, together with filtration by means of a wire grid screen. Granules of thermoplastic material with the dimension about 3 mm are then obtained with a visibly perfectly homogeneous nature even during ocular inspection via a magnifying glass. The granules in question are extremely suitable for use in an injection molding machine for industrial use in the same way as granules based on a pure thermoplastic ABS polymer, enabling the production of high quality molded components which show perfect isotropy with respect to the mechanical and physical properties.

Example 2 The procedure is similar to Example 1 except that the mixture with thermoplastic polymers is used as raw material with the average composition as follows (weight percent): Polyethylene (mixture of equal parts high density and low density polyethylene): 45 Polystyrene: 20 Polyvinyl chloride: 20 Mixture of two equal parts polyester and polyamide: 12 Polymethyl methacrylate (PMMA) h) After a rotation time for the rotor of about 90 sec you can observe a peak for the current which loads the motor, and which reaches a maximum value of the order of 230 A. The rotation time is extended as in Example 1 with about 10-20 seconds after the peak in question before recovering the homogeneous, gel-like pasty mass with pseudoplastic consistency, which is obtained by the processing.

Granulation is then performed by extrusion along with filtration of the paste as in Example 1.

Homogeneous granules of thermoplastic material are obtained, which are suitable for use in an injection molding machine for industrial purposes in the same way as when using granules of pure high-density polyethylene plastic.

It is emphasized in particular that the process described therein is extremely suitable for providing thermoplastic material with predetermined properties and which constitutes a transitional form between the properties of the various original polymers and copolymers and enables the properties of the final product to be kept constant even in cases where the average composition fluctuates for the mixtures used as raw materials.

As will be apparent to those skilled in the art, in reality only analysis of starting material and final product is required to determine the amounts of thermoplastic polymers or copolymers of one kind or another to be added to the starting mixtures in order to achieve the necessary corrections for providing an end product with intended properties and to maintain these properties in such a case when the composition of the raw materials varies.

Of course, in the mixtures with the thermoplastic polymers or copolymers can be added in a manner known per se all substance mixtures or substances capable of improving the properties of the final thermoplastic material, eg plasticizers, stabilizers, color additives, fillers, etc., and it should be clear that depending on the type of action taken in carrying out the process, which includes stirring as well as mixing, which are particularly effective, a perfect, homogeneous distribution of the substances in question in the final product can be obtained.

Claims (8)

10 15 20 25 30 508 021 Patent claims Process for the treatment of heterogeneous plastic materials comprising the steps of: preparation of at least two different thermoplastic polymers or copolymers in a distributed form, treatment of the polymers or copolymers by stirring and mixing in apparatus with mixing and stirring function, characterized in that the energy consumption by the apparatus with mixer and stirring function is measured and the treatment is stopped, after a marked increase in the energy consumption has occurred through the apparatus with mixer and stirring function. 2. A method according to claim 1, characterized in that the treatment in the form of mixing and stirring is interrupted, after an almost constant value has been reached of the energy output after the marked increase of the energy output. 3. A method according to claim 1, characterized in that the treatment in the form of mixing is carried out in a chamber which is provided with mechanical stirring components. 4. A method according to claim 3, characterized in that the stirring components comprise a rotor, which is provided with a plurality of blades. Process according to Claim 1, for treating a raw material which contains at least two different thermoplastic polymers or copolymers in the distributed state and at least one solid material which is immiscible with the thermoplastic polymers or copolymers, characterized in that at least one Filtration steps are taken with respect to the homogeneous, thermoplastic material product obtained, so that particles of material which deviate from the product are separated and dispersed therein. Process according to Claim 1 or 5, characterized in that the product is subjected to granulation treatment. Plastic material component prepared by injection molding the homogeneous thermoplastic material obtained by the process according to claim 1. O: \ users \ RME \ DOK \ word-dok \ p324l 8.kra.doc