WO2001038012A2

WO2001038012A2 - Method and device for automatically sorting films according to type

Info

Publication number: WO2001038012A2
Application number: PCT/DE2000/003806
Authority: WO
Inventors: Christoph Bach; Lutz Priese
Original assignee: Der Grüne Punkt - Duales System Deutschland Ag
Priority date: 1999-11-25
Filing date: 2000-10-26
Publication date: 2001-05-31
Also published as: DE19956624A1; AR026564A1; WO2001038012A3; AU2149601A

Abstract

The invention relates to a method and to a device for automatically sorting films according to type. The films are conveyed through a three-dimensional measuring zone of an NIR measuring device in an air current at a known flow velocity and are identified. They are removed from the air current at a site different from that of the measuring device according to the nature of the identified material.

Description

Method and device for the automatic sorting of films

The invention relates to a method for the automatic sorting of films, in which the material properties of the films are detected by means of an NIR measuring device and the separation takes place as a function of the result of the spectroscopy. The invention also relates to a device with which the method can be carried out.

"Foils" are to be understood to mean in particular plastic foils, but also metal foils, metallized and metal-coated plastic foils, such as gift wrapping foils, and papers such as are collected, for example, in the form of light packaging in the yellow sack or the yellow bin from the collection of the dual system.

Films and lightweight packaging cannot yet be sorted optically fully automatically. They are usually separated from the other fractions by means of an air classifier or manually. It is currently not possible to separate films according to type from the material.

The degree of automation is well advanced in other areas of sorting. For example, WO 99/26734 describes a separation system in which all objects on a conveyor belt are analyzed by color image analysis for their visual properties and by NIR spectroscopy for their material properties, and are then automatically blown out into several individually adjustable fractions. In practice, conveyor speeds of around 2.5 m / s are achieved. With this technique, paper, tetrapack, polystyrene, polyethylene, polyethylene terephthalate, polypropylene, silicone cartridges and other hollow bodies can be sorted out, for example.

NIR spectroscopy has proven itself in the automatic sorting of packaging. With their help, it is possible to distinguish different materials from each other, which only enables a sort-specific separation. For this purpose, the object to be examined is irradiated with white light, depending on which material it is made of, certain wavelength ranges of the light are absorbed. By examining the spectral distribution of the light reflected from the object with the aid of an NIR spectrometer, determine what proportion has been absorbed. The spectra of packaging materials can be distinguished very well from one another.

Foils and light packaging are typically very light, but relatively large. At higher conveyor belt speeds, air resistance already affects them and causes movements of the objects to be sorted on the conveyor belt. Such movements, however, complicate a separation technique based on the principle of WO 99/26734 or even make it impossible if the color image recognition, NIR spectroscopy and separation take place at different locations and there are several uncontrolled moving objects on the conveyor belt.

It is the object of the present invention to provide a method and a device for the automatic sorting of films which work with NIR spectroscopy.

This object is achieved by a method according to claim 1 and an apparatus according to claim 4. Advantageous embodiments of the method and device are the subject of the respective dependent claims.

According to the invention, it is provided that the foils are transported in an air flow at a known flow speed through a three-dimensional measuring range of the NIR measuring device and are detected there, and are removed from the air flow depending on the measuring range depending on the detected material properties.

The invention therefore releases itself from the idea of arranging the objects to be analyzed on a conveyor belt, but makes use of the fact that the future location of an identified object can be predicted in the case of a specific air flow. Experiments can determine in advance which air flow is sufficient. The flow velocity of the air flow is also determined. Since the identification section, namely the measuring range, lies in front of the separation section, the identified foils must be tracked during transport to the separation section. For this purpose, it is advantageous if there is only a short distance between the measuring range and the tapping point. According to an advantageous embodiment of the method, the air flow is divided into a plurality of partial air flows, foils with the same recorded material properties being introduced into the same partial air flow.

The device according to the invention for the automatic sorting of films has an NIR measuring device for recording the material properties of the films, at least one removal point for films and a separating device which, depending on the recorded material properties of a film, directs it to one of these removal points which is assigned to the material , on, and is characterized by a wind tunnel in which there is an air flow with a known flow velocity, and by a three-dimensional NIR measuring area in the wind tunnel, the at least one removal point for foils with detected material properties being arranged in a location offset from the NIR measuring area in the wind tunnel.

These removal points are preferably removal channels which branch off from the wind tunnel, the control device guiding foils with the same detected material properties into the same removal channel. Films that are not recognized can be fed into a separate removal channel and disposed of from there.

According to a preferred embodiment, the control device controls blowing nozzles that blow foils with detected material properties to assigned removal points or into assigned removal channels. As an alternative or in support of the measure just mentioned, the control device can control guide plates, by means of which the air flow is to be directed in such a way that the foils fly to the assigned removal points or into assigned removal channels.

The wind tunnel in the three-dimensional measuring range is particularly preferably provided with a reflection wall, for example a reflective tube.

The invention will be explained in more detail below with reference to the accompanying drawing. The sole figure shows an embodiment of the device according to the invention.

The starting material is a film material to be sorted, as is typically the case with wind sifters after the previous screening process. Large films, such as the yellow sacks themselves or films from the yellow sack or from the construction or renovation of several buildings Square meters of space, which can also come from incorrect casts, for example, must be sorted out beforehand. In the case of an automated process, it is also conceivable to precede a dry and / or wet mechanical preparation, such as comminution, cleaning, removal of impurities, in order to homogenize the film material. It has been found that films up to a size of approximately A4 can be treated with the device according to the invention.

It is also expedient to free the film material from sticky impurities in order to prevent the material from sticking to the wind tunnel or from fusing or soiling of the measuring range or the transport device.

The foils must be safely inserted into the wind tunnel.

In the drawing figure, the wind tunnel 10 is shown schematically as a vertical cylindrical tube. The wind tunnel 10 opens into two sampling channels 12, 14. The number of sampling channels depends on the number of fractions to be separated, and is therefore not limited to two.

The air flow L is generated by one or more fans, not shown in the drawing. This fan or the fans are expediently located behind cyclones or other separators which are arranged at the end of each removal channel 12, 14 for film separation. The separators are also not shown in the drawing.

The air flow L in the wind tunnel 10 is thus divided into two partial air flows L1, L2 in the extraction channels 12 and 14, according to the embodiment.

The flow rate should be far greater than 10 m / s, for example 20 m / s, with the aim of achieving the highest possible throughput of foils, in which, for example, more than 10 foils are introduced individually per second into the measuring range to be described later , The flow or air flow depends on the diameter of the pipe system with which the wind tunnel and extraction channels are constructed. Pipe diameters on the order of 100 mm to 450 mm for wind tunnel 10 have proven to be suitable for certain film fractions. It is advantageous if the tube diameter is approximately the same or slightly larger than the diameter of the objects, since these will not be in the tube can overtake. Pre-shredding of the films for size homogenization is therefore advisable. With large pipe diameters it can be important to keep the flow laminar.

The material recognition of the foils which are carried through the wind tunnel 10 with the air flow L is determined by means of an NIR measuring device 20 which scans a three-dimensional measuring range 26 with a sensor 22. It is therefore not necessary to track the measuring spot. In order to make better use of the white light that occurs at 24, the wind tunnel 10 is provided with a reflective tube 28 in the measuring area 26.

A control device 30 correlates the evaluated measurements with the expected position of the film flowing through the wind tunnel 10, which in the meantime flies over a short distance W, which can be, for example, 50 cm or less, in order to blow blowers 32 via the control lines SI and S2, 34 and / or guide plates 36 and 38 act in such a way that the identified film is introduced into the correct removal channel 12 or 14.

Above the measuring range 26, a possibly rigid guide plate projecting into the wind tunnel 10 can be arranged, which ensures that the foils are carried close to the sensor 22.

The features of the invention disclosed in the above description, in the drawing and in the claims can be essential for realizing the invention both individually and in any combination.

Claims

claims

1. A method for the automatic sorting of films, in which the material properties of the films are detected by means of an NIR measuring device (20) and the separation is carried out as a function of the spectroscopic result, characterized in that the films in an air stream (L) at a known flow rate are transported through a three-dimensional measuring area (26) of the NIR measuring device (20) and are detected there and are removed from the air flow (L) depending on the material quality detected, offset from the measuring area (26).

2. The method according to claim 1, characterized in that the air flow (L) is divided into a plurality of partial air flows (Ll, L2), wherein foils with the same detected material properties are introduced into the same partial air flow.

3. The method according to claim 1 or 2, characterized in that the air flow (L) is substantially laminar.

4. Device for the automatic sorting of films, with an NIR measuring device (20) for recording the material properties of the films, at least one removal point (12, 14) for films and a separating device (30, 32, 34, 36, 38), which, depending on the detected material properties of a film, directs it to at least one removal point (12) which is assigned to the material, characterized by a wind tunnel (10) in which an air flow prevails with a known flow velocity; a three-dimensional NIR measuring area (26) in the wind tunnel (10); wherein the at least one removal point (12, 14) for films with a detected material procurement unit is arranged offset to the NTR measuring area (26) in the wind tunnel (10)

5. The device according to claim 4, characterized in that the wind tunnel opens into a plurality of removal channels (12, 14) and that the control device (30) conducts foils with the same detected material properties in the same removal channel.

6. Apparatus according to claim 4 or 5, characterized in that the control device (30) controls blowing nozzles (32, 34), blow the foils with detected material properties to assigned removal points or in assigned removal channels (12, 14).

7. Device according to one of claims 4 to 6, characterized in that the control device (30) controls baffles (36, 38) by means of which the air flow is to be directed so that foils with detected material properties at assigned removal points or in assigned removal channels ( 12, 14) fly.

8. Device according to one of claims 4 to 7, characterized in that the three-dimensional measuring region (26) is provided with a reflection wall (28).