DE102015111000A1 - Process for cleaning plastics, in particular plastic chips and apparatus for carrying out the process - Google Patents

Abstract

A method for cleaning plastic, in particular Kunststoffschnipseln, in the course of plastic recycling in a refiner with two facing refining tools of which at least one is rotationally driven and define a working gap between them, wherein the plastic to be cleaned is entered into the input end of the working gap, in the working nip pulp and other adhering substances are abraded from the plastic, and the cleaned plastic is discharged together with the abraded pulps and other adhesive substances at the outlet end of the working gap via an outlet, wherein before or in the region of the inlet end of the working gap by means of nozzles water jets be injected under pressure into the supplied plastic.

Description

The invention relates to a method for cleaning plastics, in particular plastic chips in the course of plastics recycling in a refiner according to claim 1 and to an apparatus for carrying out the method according to claim 4.

Out DE 10 2013 111 365 B4 is a method of a device for cleaning plastic, in particular Kunststoffschnipseln in the course of plastic recycling, comprising a refiner, become known. The refiner is known to have two facing refining tools, of which at least one is driven. Between the discs there is a working gap for rubbing off pulps and other adhering substances. The working gap has an inlet. An entry device carries the plastic to be cleaned in the inlet, wherein the refiner also has an outlet connected to the working gap, through which the plastic cleaned in the working gap is removed together with the abraded pulps and other adhering substances to an outlet. The outlet of the refiner comprises an outlet tube connected to the working gap and leading to the outlet, the outlet tube being connected to a water pump for pumping water through the outlet tube. In operation, a suction effect on the working gap is exerted by the water pumped by the water pump through the outlet pipe so that cleaned plastic is conveyed from the working gap into the outlet pipe, the water pumped by the water pump through the outlet pipe into the plastic located in the outlet pipe promotes the exit.

The plastic to be cleaned is in particular waste plastic to be recycled. It may in particular be pre-shredded plastic shreds, so-called plastic flakes. The plastic chips may be plastic film chips. The plastic to be cleaned is conveyed through the entry device via the inlet into the working gap of the disc refiner. The plastic is fed together with water. But it is also possible to realize a dry supply of the plastic, for example, if a screw conveyor of the entry device has a core tube as a hollow tube is introduced through the water to adjust the cleaning consistency in the working gap. The consistency of entry before reaching the working gap would in this case be 100% solids. It is also possible to supply with steam, in particular in the case of a steam-operated pressure refiner. The working gap is limited by the mutually facing working surfaces of the refining tools. On the work surfaces suitable friction elements are arranged. At least one of the refining tools is driven in rotation (rotor). The other refining tool can also be driven in rotation or it can be fixed (Startor). For example, in the case of a disc refiner, in which the refining tools are refining discs, the facing working surfaces of the refining discs may be circular or circular or annular. Accordingly, a circular or annular working gap is formed in plan view. The introduced in the working gap suspension of plastic and water to be cleaned is rotationally accelerated by the rotation of the at least one refining tool and pulp and other adhering substances are abraded from the plastic. Due to the rotational acceleration of the suspension, the plastic in the working gap is transported together with the abraded impurities and the water to an outlet of the refiner.

A refiner for cleaning plastic of the type described is approximately out DE 10 2011 108 062 A1 known. It includes two cleaning discs with opposite cleaning surfaces, which define a cleaning gap between them. The cleaning surfaces each have a plurality of cleaning ribs extending between an inner and an outer edge of the cleaning surfaces, wherein at least one flank of the cleaning ribs is inclined or curved with respect to the axial direction of the respective cleaning disk, with at least a plurality of mutually adjacent cleaning ribs therebetween extending at least transversely to the direction of extension of the cleaning ribs Cleaning ribs extending cleaning webs are arranged.

The invention has for its object to provide a method for cleaning plastic, in particular Kunststoffschnipseln, indicate that has a reduced energy requirements and allows additional resolution of foil packages or the like. In addition, the throughput, especially of Folienschnipseln be increased by the refiner.

This object is solved by the features of claim 1.

In the method according to the invention, water jets are injected under pressure into the supplied plastic before or in the region of the inlet end of the working gap by means of nozzles. The supplied, to be cleaned plastic can be fed more or less water, or the plastic is supplied more or less dry.

In known methods is to be cleaned via a so-called entry screw Plastic fed to the refiner. The water required for this purpose is injected into the screw so that the required solid consistency, which is required in the working gap, is already set in the screw. In the method according to the invention, either completely or for the most part, water is no longer introduced via the entry device, but at high pressure via nozzles directly into the working gap or into the region in front of it. In this way, the solid is entrained by the water jets. These thus represent an entry aid. In addition, the water pressure can dissolve foil balls or foil packets. Stretch films often remain as small foil packages after comminution. These can be dissolved by the water jets. Another advantage occurs through a pre-cleaning effect, by loosening sand adhering to the plastic chips. This then passes through the working gap in the mixture of water and foils and Kunststoffschnipseln and therefore contributes only slightly to Abbrasion on the refining tools. If the sand were only detached from the plastic chips in the working gap, this leads to a more or less large abrasion of the tools.

Another advantage of the method according to the invention is the reduction of the energy requirement by pre-accelerated water. Furthermore, the energy requirement is reduced by dissolving foil packages, which otherwise has to be done mechanically in the refiner tools. The invention also makes it possible to increase the throughput of plastic film chips (very low bulk density) through the refiner.

The invention also relates to a device for carrying out the method according to the invention. It comprises a refiner with two refining tools facing each other, of which at least one is rotationally driven and delimiting therebetween a working gap for abrading pulp and other adhering substances from the plastic, the refiner having an inlet opening into the working gap, further comprising one inlet means connected to the inlet for introducing the plastic to be cleaned in the inlet and wherein the refiner also has an outlet connected to the working gap, through which the plastic cleaned in the working gap is removed together with the abraded pulps and other adhering substances to an outlet. According to the invention, a nozzle arrangement with several nozzles is provided in the region of the inlet, the axis of which is directed in the direction of the inlet. The nozzles are connected to a pump. The pump delivers water under pressure to the nozzles whose jets of water are directed towards the stream of plastic chips which are listed in the inlet.

According to one embodiment of the invention, the nozzles are arranged on a circle concentric to the feed direction of the plastic to the inlet. According to a further embodiment of the invention, the axis of the nozzles may have a tangential component. Through this, a rotation of the water jets is achieved and thus a pre-acceleration of the water in the direction of rotation. According to another embodiment of the invention, the supply to the working gap is ring-cylindrical or annular-conical and the axis of the nozzles is directed towards the inlet. In this case, the inlet is at a disc refiner at the radially inner end of the Refinerscheiben or the working gap.

According to a further embodiment of the invention, the nozzles are formed in an annular body which is flanged to the housing of the refiner. If the entry device has a conveyor screw, according to a further embodiment of the invention, the annular body is arranged between the housing, the conveyor screw and the housing of the refiner.

A refiner is designed for a specific throughput, and furthermore, for the purpose of effective cleaning according to the invention, a specific ratio of plastic to water (solid consistency) is desired. Therefore, the number of nozzles or the amount of water injected from the nozzles depends on the desired throughput and solids consistency.

An embodiment of the invention will be explained in more detail with reference to drawings.

1 schematically shows a section through a refiner and an entry device in an embodiment of the invention.

2 shows the top view of the arrangement 1 ,

3 shows the front view of a nozzle having annular body between refiner and auger housing after 1 ,

According to 1 and 2 is a disc refiner 10 shown with a housing 12 , The refiner 10 has a first refining disc 14 on, which is rotatably mounted in the housing about its axis and driven in rotation by means of a rotary drive, not shown. The refiner disc 14 has a circular work surface on which for example a plurality of teeth can be formed. The refiner 10 has a second refining disc 16 , which can also be driven in rotation or with respect to the housing 12 is stationary. This also has a circular Work surface. The working surfaces of both refiner discs 14 . 16 are facing each other and define an annular working gap. The working surface of the second refiner disc 16 can be identical to the working surface of the first refiner disc 14 be educated. Thus, the refiner shown is a so-called disc refiner equipped with toothed disks as refining tools.

The first refiner disc 14 has a cone centrally 18 on that together with a wall 20 of the housing 12 a ring conical channel 22 forms. The around a vertical axis 24 folding wall 22 has a pipe socket 26 on, at the end of a flange 28 Has. Such a foldable wall is known per se and allows a modular structure of the refiner.

The ring conical channel 22 flows within the refiner 10 at the entrance end of the working gap. The outlet end of the working gap opens into a circular space 30 inside the case 12 into which the purified material leaving the working gap enters together with water and impurities. From this mixture gets into an outlet 32 ,

To the flange 28 is a ring body 34 flanged. The ring body is located between the flange 28 and a housing 38 a screw conveyor 40 with a screw conveyor 42 , The screw conveyor 42 is from a suitable drive 44 set in rotation, which should not be discussed further. To be cleaned plastic is via a filling opening 46 fed.

As in 1 to recognize, the ring body has 34 jet 50 on. The ring body is in 3 shown in front view. It is recognized that four nozzles 50 are formed in the ring body and that at a circumferential distance of 90 °. holes 52 serve to fasten the ring body 34 between flange 28 and housing 38 , An annular groove 54 serves to receive a sealing ring, not shown.

How out 1 To recognize the nozzles are inclined in such a way that their axes converge and approximately in the direction of the channel 22 point. The nozzles 50 are connected to a pressure pump 56 connected.

During operation, shredded plastics pass through the inlet 54 entered in the screw conveyor. The snail 52 transports the more or less dry material into the space inside the pipe socket 26 , There it gets under the relatively high pressure of the jets of water coming from the jets 50 be generated. The nozzles are used to record the water that is responsible for the consistency of the solids inside the refiner 10 is required. The water pressure acts directly on the working gap, so that the water jets is an entry aid for the plastic, which is entrained by the water. The water pressure can dissolve foil balls or foil packets. Stretch films often remain as small foil packages after comminution and can therefore be dissolved by the water jet.

The jets of water can also be used to remove abrasive material that adheres to the plastic chips. It then passes with the suspension from the refiner without producing any special removal action on the refining tools.

Overall, the water entry behind the entry device immediately before the working gap allows a reduction in energy requirements by pre-dissolution of film packages, which would otherwise be done mechanically. Also, the printing rate is increased by the refiner in films.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102013111365 B4 [0002]
• DE 102011108062 A1 [0004]

Claims (10)

Process for cleaning plastics, in particular plastic chips, in the course of plastics recycling in a refiner ( 10 ) with two facing refining tools ( 14 . 16 ) of which at least one rotationally driven and limit a working gap between them, wherein the plastic to be cleaned is registered in the input end of the working gap, in the working gap pulp and other adhering substances are abraded by the plastic, and the cleaned plastic together with the abraded pulps and other adhering substances is discharged at the outlet end of the working gap via an outlet, characterized in that before or in the region of the inlet end of the working gap by means of nozzles ( 50 ) Water jets are injected under pressure into the supplied plastic. A method according to claim 1, characterized in that the water jets is given a rotational component. A method according to claim 1, characterized in that the water jets in a feed ( 22 ) are directed towards the entrance end of the working gap. Device for cleaning plastics, in particular plastic chips, in the course of plastics recycling, comprising a refiner ( 10 ) with two facing refining tools ( 14 . 16 ), at least one of which is rotationally driven and defining therebetween a working gap for abrading pulp and other adhering substances from the plastic, the refiner ( 10 ) has an inlet opening into the working gap, further comprising an inlet device connected to the inlet for introducing the plastic to be cleaned into the inlet and wherein the refiner ( 10 ) has an outlet also connected to the working gap, through which the plastic cleaned in the working gap is discharged together with the abraded pulps and other adhering substances to an outlet, characterized in that in the area of the inlet a nozzle arrangement with a plurality of nozzles ( 50 ) whose axes are directed in the direction of the inlet and the nozzles ( 50 ) with a pump ( 56 ) are connected. Device according to claim 4, characterized in that the nozzles ( 50 ) are arranged on a circle concentric to the feed direction of the plastic to the inlet. Device according to claim 5, characterized in that the axis of the nozzles ( 50 ) has a tangential component. Device according to claim 4 or 6, characterized in that the feeder ( 22 ) is formed annular cylindrical or conical and the axis of the nozzle ( 50 ) to the feeder ( 22 ) is directed. Device according to one of claims 4 to 7, characterized in that the nozzles ( 50 ) in a ring body ( 34 ) formed on the housing ( 12 ) of the refiner ( 10 ) is flanged. Apparatus according to claim 8, characterized in that the entry device a screw conveyor device ( 40 ), wherein the annular body ( 34 ) between the housing ( 38 ) of the screw conveyor and the housing ( 12 ) of the refiner ( 10 ) is arranged. Device according to one of claims 4 to 9, characterized in that four spaced at a circumferential distance of 90 ° nozzles ( 50 ) are provided.

Images