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- 繁體中文 |English
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TEL:02-29039203
FAX:02-29032558
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Customer service hours on weekdays except holidays
08:30~17:30
- Product Department of Industrial Machinery and Materials
- Product Division of Biochemical Medicine and Materials
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-
TEL:02-29039203
FAX:02-29032558
-
Customer service hours on weekdays except holidays
08:30~17:30
-
- Product Department of Industrial Machinery and Materials
- Product Division of Biochemical Medicine and Materials
German PET bottle flake laser spectrum color separation machine - UMPO-250
Spectrum technology color selection, thoroughly sorting mixed materials such as PET/PP/PU
Suitable for environmentally friendly recycling of PET plastics and bottle flakes, etc.
This enables the long-term recovery of high-value pure raw materials.
Plastics recycling - opportunities and perspectives
Plastic is everywhere nowadays, as PET bottles, as the housing for electronic and other equipment, inside cars, as food packaging and in many other areas.
It is made from valuable raw materials such as oil or natural gas.
One kilogram of polyethylene terephthalate (PET) requires around 1.9 kilograms of crude oil and a vast amount of energy, for instance.
However resources are finite, and what could be more obvious than to recycle plastics responsibly?
This will not only ensure the efficient use of resources, but will also help avoid giant landfill mountains.
Clean material sorting
The clean sorting of individual materials is a problem, however, since mixed plastic recycling streams not only contain valuable materials, but frequently also foreign plastics, plastics containing chlorine or heavy metal compounds as well as contaminants and additives.
Using visual, camera-based or other conventional methods, many of the unwanted foreign substances found in recycling cannot be identified, or can only be identified with difficulty, since they are frequently impossible to distinguish either by virtue of their color or by other common parameters.
Small particle sizes often also present a problem for conventional sorting systems.
If the proportion of foreign material in the recycled material remains too high, it is classed as being of lesser value and its opportunities for reuse are limited.
High-speed laser spectroscopy with
steps in where visual or other established systems and detection methods fail.
The system uses a highly efficient and accurate detection method based on high-speed laser spectroscopy: it identifies the good material in a plastic flake or granulate stream using its specific opto-electronic spectrum and sorts it from various foreign and contaminating materials in just a single process step.
The system was originally developed following a suggestion by a major drinks manufacturer who wanted to put all of the PET disposable bottles it sold in a closed recycling loop and avoid mountains of landfill.
PET recycling in food-grade quality, for example in the context of bottle-to-bottle recycling - with Machine screening, this is already possible.
The powerful, efficient system is also highly skilled in other areas of plastics recycling.
The previously unresolved sorting of dark or black plastic mixtures, of the type found on the inside of every car for example, is now possible.
The challenge of WEEE (Waste of Electrical and Electronic Equipment)
One major challenge for the immediate future is the recycling of shredded plastic waste from electrical and electronic equipment, such as the casings of computers, TVs or household appliances.
In Germany alone, several 100,000 tonnes of plastic waste are produced from the recycling of old electronic equipment.
Until now, the majority of this plastic waste has only been thermally disposed or exported to Asia.
To produce value-oriented recycling, the various types of polymer need to be identified and sorted.
It is also essential to separate old plastics that contain harmful substances, such as those that contain flame retardants, which cannot be used anymore.
Sorting using laser spectroscopy means that electronic scrap will in future be able to be reused in new electronic equipment.
So waste can now become a resource.
| Measuring principle | High-Speed Laser Spectroscopy |
| Measurement | Continuous throughout the process; 1,000,000 spectra/s |
| Measurable components | Material types, colors, contaminants which have migrated into the plastic |
| Capacity | up to 6,600 lbs. per hour (up to 3 tons per hour) |
| Particle size | 0.003 sq. in. to 0.8 sq. in. (2 mm² to 500 mm²) |
| Max. particle weight | 0.018 oz. (0.5 g) |
| Power supply | 230V +/- 10V,1-phase |
| Mains frequency | 50 Hz / 60Hz |
| Fuse | 1×32A |
| Compressed air supply | >= 87 psi, max. 790 gal./min. (>= 6 bar, max. 3,000 l/min) oil-free, pre-filtered, max. particle size40 µm |
| Water supply | 320 gal./h, 46 – 64 °F, 29 to 87 psi (1,200 l/h, < 12 °C, 2 to 6 bar) cooler rating: 8 kW |
| Ambient temperature | 50 – 104°F(10 – 40°C) |
| Power consumption | <6kW |
| Noise emission | < 80 db (A) |
| Dimensions (HxWxD) | 110" x 79" x 69" (2,800 x 2,000 x 1,750 mm) |
| Weight | 4,000 lbs. (1,800 kg) |
Precise sorting with a physical "fingerprint"
identifies different plastics using their characteristic spectrum, which corresponds to a physical fingerprint.
The system uses a special laser spectroscopy method and evaluates the material streams using spectral analysis.
The broad and highly differentiated spectrum permits the precise identification of materials and therefore an accurate distinction between good and foreign substances.
In principle, numerous material streams can be detected and sorted in this manner.
High-speed laser spectroscopy
uses high-speed laser spectroscopy and achieves a sorting capacity of 2.4 to 3 tons per hour, depending on the density of the material.
Thanks to the multi-spectral, bright optical configuration and extremely fast signal processing speed with powerful signal processors, up to a million spectra are generated and evaluated per second.
At this high resolution, even tiny particles of up to one square millimeter can be analyzed and sorted.
High sorting efficiency
If a particle is identified in the stream as foreign material, a variety of supersonic air jets ensure it is removed from the good material stream.
The path between the measuring field and the ejection mechanism is extremely short and, together with the ability to configure detection
thresholds and the blower unit with material-specific settings, leads to an extremely low false reject rate.
With UMPO-250, a rejection rate of over 98% is possible, depending on the material used, with minimal loss of good material.
© German Award
PET in food-grade quality
Recycled plastic contaminated with foreign substances can cause significant problems and quality issues when it is reprocessed. In the domain of PET recycling, for example, typical materials that are very difficult to distinguish visually from good PET include PVC, nylon, silicone, PET with TiO2, PLA, PC, glue / salt or paper and flakes containing barrier substances (such as scavengers, blends or multi-layers). They do however lead to lower transparency and discoloration. Cracks or inclusions can further reduce quality during subsequent processing, such as in the manufacture of new PET drinks bottles.
detects the foreign substances, separates them from the good material stream and ensures that the recycled material is of high quality - even up to food-grade standards. Conventional detection systems fail in this task, since transparent PET and PET contaminated with PVC, nylon or other substances is very difficult if not impossible to distinguish visually from pure PET, especially when in granulate form. It is only during the later processing stage, and in particular under the influence of high temperatures, that these foreign substances become visible as a result of discolorations in the final product. Brown wood and glue residue is hard to detect in brown PET, for example. With the different materials can be clearly detected and rejected by virtue of their specific spectrum or physical fingerprint.
