DE4339822C1 - Sorting used glass, used in mfr. of imaging tubes of different compsn. - Google Patents

Abstract

Glass fragments formed by breaking up waste glass object, are conveyed along a path past an optical system which analyses the reflection and absorption of light from the surface of the glass fragments. According to the spectral analysis, the fragments are sorted into various storage containers.

Description

The invention relates to a method and a device for the sorting of inorganic non-metallic Materials, in particular glasses, according to the preamble of Claims 1 and 12. Preferably to be recycled Picture tubes sorted by their glass ingredients. The invention also includes the use of sorted out Picture tube glasses according to claim 1.

Color picture tubes consist of three types of glass. The Front glass, also referred to as a screen, is barium / strontiumhaltig, while the cone glass and the Picture tube neck are leaded. In terms of quantity are especially screen and cone glass. The screen is continue with a luminescent layer of mostly sulphidic or oxidic phosphorescent metal compounds the inside covered. The consul glass is with Fe oxide and / or graphite coated.

As part of electronic scrap recycling reaches the pre-mounted picture tube in the picture tube preparation, where it is crushed and freed of internals.

Depending on the country of origin and picture tube manufacturers vary the contents of Ba / Sr / Pb in the glasses. There are in the Usually the following assignments of the contents to the Picture tubes (salary fluctuations):

• - Shield glass: Ba / Sr-containing Ba | 5-11% Sr 5-10% pb <0.3%
• - Cone glass: Pb-containing Pb | 10-20% Ba 0.6-1.2% Sr <0.5%

For a recycling of such glasses in the Glass industry must adhere to these with defined levels above elements are provided for this the production of new picture tubes of molten glass can be added.

So far, however, no methods are known which a Sorting of such materials according to their ingredients enable.

At the moment, the glasses are still used as filler, Offset material, landfill, for foam glass production or for shielding slightly radioactive substances (Pb Glasses) used. A limited utilization of the Pb Glasses in lead sheds is also known. The preparation The glasses is currently limited to the separation of the Cone and screen glasses as well as the metal separation and Stripping of the separated glasses (EP 0 524 578 A1, DE 41 24 595 A1, G 92 06 668.2, DE 40 03 497 A1, DE 39 01 842 A1, US 005 089 743 A, EP 0 525 266 A1).

In DE 36 18 173 A1 a glass sorting plant described. However, this is only for screening of non-glass or non-glass residues Glass parts.

EP 0 493 239 A1 describes a machine for Sorting of plastic bottles after the Plastic composition and not after Plastic ingredients.

The peculiarity of the content determination in glasses lies in the fact that it is a material matrix  (SiO₂ matrix) doped with elements / compounds is. On the other hand, known methods identify Chemism ago different materials, such. B. Identification of various metal parts, identification various plastics, glass-ceramic separation Metals. A separation of glasses after different colors is also known, with at This sorting task on glass ingredients no relation is taken.

The object of the invention is therefore a Method and to develop a suitable device which allows inorganic non-metallic Materials, in particular glasses, according to their To recognize glass ingredients and in defined Grade grades and picture tubes different manufacturers with different Reprocess glass recipes.

According to the invention, the glasses are after a appropriate processing and crushing and a Exemption of non-glass components via a Separated conveyor and with the fracture surfaces to aligned with an optical system. About the optical System will be the glass fragments according to their Glass ingredients analyzed and over a Discharge device according to the glass ingredients deflected into suitable containers.

The optical analysis, d. H. the determination of Glass ingredients, can be made by exploiting the Substance properties Reflection and absorption occur and For detection, reflection spectra are in the near UV range used. To determine the Glass ingredients may, according to a preferred feature of Invention, the UV fluorescence can be used. there are the concentrations of BaO, SrO and PbO means diffuse fluorescence emission continuously detected.

The selection of the excitation wavelengths takes place after a further feature of the invention by means Interference filter with wavelengths between 200 nm and 400 nm.

The interference filters are in one Interference filter wheel integrated with chopper, which the Use of a lock-in amplifier allowed and that Receive signal triggers at the detector.

The exiting fluorescence radiation is in  Wavelength range of 300 to 600 nm detected.

According to a further feature of the invention, the Signal acquisition by means of light-sensitive detectors, such as B. photodiodes or photomultipliers.

The wavelength range to be detected for detection is by means of an edge filter from the range of Excitation wavelengths delimited.

A particularly preferred feature of the invention is in that the analyzed glass fragments from one to the Discharge trigger required photocell detected and with the discharge device in the corresponding Containers are sorted.

The above description of the sorting process leaves already the essential components of the associated Detect device.

Moreover, in this regard, the following Description of the figures referenced, so far as well contains general characteristics.

The invention will be described below with reference to a Example of coarse glasses (50 mm) be described in more detail.

In the pictures show

Fig. 1 is a schematic representation of the method

Fig. 2 shows the design of the conveyors

Fig. 3 sectional views of the conveyor

Fig. 4 identification system.

The content determination shown in Fig. 1 is provided for pre-shredded and freed of metal parts picture tube glasses (television picture tubes, PC monitors, etc.). The glass parts are from a storage container 1 a, placed on a chute 1 c via a Vibrorinne with built-baffles 1 c due to the inertia of the parts and the geometry of the conveyor isolated, aligned and the identification of a measuring slot 1 d of the chute 1 c supplied , After identification by the optical system 2 a, the parts are placed on a trough-shaped conveyor belt 3 , detected by a photocell required for the removal of light 2 b and later in the then flat trained conveyor belt 4 by means of the discharge device 6 (compressed air nozzles, plunger or flaps) sorted into the designated containers. The data processing, control of the discharge device and the triggering are realized by means of a computer unit 5 .

Fig. 2 shows the conveyor system and assigns the conveyor system to the sectional views, which are shown explicitly in Fig. 3. On the vibrating trough AA, the glass parts are separated. The following chute is formed on the input side as a trough BB, at the outlet asymmetric angled CC and takes over the alignment of the glasses with respect to the fracture surfaces. As a result, the picture tube glasses do not have to be decoated prior to identification. In addition, there is no influence of scratching on the fracture surfaces caused by stripping methods. The identification path DD contains a measuring slot 1 d in the edge. The identified parts arrive on the conveyor belt, where the discharge takes place in the corresponding collection container.

The designated in Fig. 1 with 2 a identification unit is explained in Fig. 4. The method is based on a recognition of the different UV excitation bands for BaO, SrO and PbO. The emission at about 300-600 nm serves as a measure of the absorption and can be assigned to a concentration. For the identification of the shards passing the measuring system an on-line measurement is provided, which reduces the effect of the irregular glass edges. The maximum signal at the detector caused by a glass part is assigned to a concentration in the computer. A UV light source 2 a-1, whose intensity fluctuations are detected by a reference detector 2 a-0, throws the light through a lens optics 2 a-2 on an interference filter with chopper 2 a-3. The narrow-band light leaving the filter of the wavelength significant for the respective excitation is focused by means of another lens system 2 a-4 onto the glass piece located behind the measuring slit, see Fig. 3, DD. The fluorescence radiation emerging diffusely from the sherd reaches the detector 2 a-7 via a lens system 2 a-5 and an approximately 400 nm edge filter 2 a-6. The content of BaO, SrO and PbO can be determined from the chopper lock-in signal of the interference filter wheel, the reference detector signal and the fluorescence signal by means of the lock-in amplifier and EDP system 5 using the calibration values for the concentration-dependent fluorescence. If the concentration is evaluated, the discharge is controlled via a computer interface, taking into account the light barrier trigger signal. The used glass industry is thus provided Altglaschargen with defined levels of the compounds BaO, SrO and PbO available, which are mixed in the picture tube production according to the glass formulation and thus recycled material.

Claims (16)

1. A method for sorting inorganic non-metallic materials, in particular glasses, after glass ingredients, wherein these are pre-crushed and freed of non-glass components, characterized in that

• - the glass fragments on a conveyor isolated glass fragments are aligned with the fracture surface to form an optical system,
• - The aligned glass fragments are analyzed for their glass ingredients
• - And via a discharge device, the glass ingredients according to be deflected into suitable containers.

2. The method according to claim 1, characterized in that the optical analysis by exploiting the Substance properties Reflection and absorption takes place and used for the detection of optical spectra become. 3. Process according to claims 1 and 2 characterized in that the detection of reflection spectra in the near UV range occurs. 4. The method according to claim 1, characterized in that the UV fluorescence for the determination of Glass ingredients is used. 5. The method according to claim 4, characterized in that the concentration of BaO, SrO and PbO by means of diffuse emerging fluorescence radiation continuously  is detected. 6. Process according to claims 4 and 5 characterized in that the selection of the excitation wavelengths by means of Interference filter with wavelengths between 200 nm and 400 nm. 7. The method according to claim 6, characterized in that the interference filters in an interference filter wheel integrated with chopper, which is the use a lock-in amplifier allowed and the Receive signal from the detector triggers. 8. The method according to claim 4, characterized in that the exiting fluorescence radiation in the 300-600 nm Wavelength range is detected. 9. The method according to claim 8, characterized in that the signal acquisition by means of photosensitive Detectors, in particular photodiodes and / or Photomultiplier, takes place. 10. The method according to claim 4, characterized in that the wavelength range to be detected for the Detection by means of an edge filter from the area of Excitation wavelengths is delimited. 11. The method according to claim 1, characterized in that the analyzed glass fragments after the Identification of one for discharge triggering required photocell can be detected and with the discharge device in the corresponding Containers are sorted.   12. An apparatus for sorting inorganic, non-metallic materials, in particular glasses, wherein these are pre-crushed and freed of non-glass components, characterized in that

• - on a conveyor (1) scattered glass fragments with the fractured surface to an optical system (2 a) are aligned,
• - The aligned glass fragments are analyzed by means of the optical system ( 2 a) and an evaluation unit ( 5 ) for their glass ingredients
• - And via conveyor units ( 3 , 4 ) of a discharge device ( 6 ) are fed, which deflects the glass fragments in accordance with the glass ingredients in suitable containers ( 7 ).

13. The apparatus according to claim 12, characterized in that the conveyor ( 1 ) from a storage container ( 1 a), a vibrating chute with baffles ( 1 b) and a chute ( 1 c) composed. 14. The apparatus according to claim 12, characterized in that a conveyor unit ( 3 ) is formed trough-shaped. 15. The apparatus according to claim 12, characterized in that along a conveyor unit ( 4 ) arranged discharge device ( 6 ) consists of compressed air nozzles and / or flaps and / or tappets. 16. Use of taking advantage of Substance properties Reflection, absorption and UV fluorescence sorted by glass ingredients from Picture tube glasses for the production of new picture tubes according to the glass formulation of the molten glass.