Tobias Völker scite author profile

Closed material cycles and unmixed material fractions are required to achieve high recovery and recycling rates in the building industry. In construction and demolition waste (CDW) recycling, the preference to date has been to apply simple but proven techniques to process large quantities of construction rubble in a short time. This is in contrast to the increasingly complex composite materials and structures in the mineral building materials industry. Manual sorting involves many risks and dangers for the executing staff and is merely based on obvious, visually detectable differences for separation. An automated, sensor-based sorting of these building materials could complement or replace this practice to improve processing speed, recycling rates, sorting quality, and prevailing health conditions. A joint project of partners from industry and research institutions approaches this task by investigating and testing the combination of laser-induced breakdown spectroscopy (LIBS) with near-infrared (NIR) spectroscopy. Joint processing of information (data fusion) is expected to significantly improve the sorting quality of various materials like concrete, main masonry building materials, organic components, etc., and may enable the detection and separation of impurities such as SO3-cotaining building materials (gypsum, aerated concrete, etc.) Focusing on Berlin as an example, the entire value chain will be analyzed to minimize economic / technological barriers and obstacles at the cluster level and to sustainably increase recovery and recycling rates. First measurements with LIBS and NIR spectroscopy show promising results in distinguishing various material types and provide an understanding about the mutual supplementation of both methods. Their spectral information is further compared with X-ray fluorescence (XRF) spectroscopy. Future works will apply the developed sorting methodology in a fully automated measurement setup with CDW on a conveyor belt.

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Investigation of grain sizes in cement-based materials and their influence on laser-induced plasmas by shadowgraphy and plasma imaging

Gottlieb

Gojani

Völker

et al. 2020

Spectrochimica Acta Part B: Atomic Spectroscopy

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Tobias Völker

Extension and investigation by numerical simulations of algorithm for calibration-free laser induced breakdown spectroscopy

Importance of physical units in the Boltzmann plot method

Identification of type of cement through laser-induced breakdown spectroscopy

Sorting of construction and demolition waste by combining LIBS with NIR spectroscopy

Investigation of grain sizes in cement-based materials and their influence on laser-induced plasmas by shadowgraphy and plasma imaging

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