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    Material Treatment in the Pulsation Reactor—From Flame Spray Pyrolysis to Industrial Scale

    New search for: Stefan Heidinger
    New search for: Felix Spranger
    New search for: Jakub Dostál
    New search for: Chunliang Zhang
    New search for: Christian Klaus

    Current challenges in the areas of health care, environmental protection, and, especially, the mobility transition have introduced a wide range of applications for specialized high-performance materials. Hence, this paper presents a novel approach for designing materials with flame spray pyrolysis on a lab scale and transferring the synthesis to the pulsation reactor for mass production while preserving the advantageous material properties of small particle sizes and highly specific surface areas. A proof of concept is delivered for zirconia and silica via empirical studies. Furthermore, an interdisciplinary approach is introduced to model the processes in a pulsation reactor in general and for single material particles specifically. Finally, facilities for laboratory investigations and pulsation reactor testing in an industrial environment are presented.

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    Material Treatment in the Pulsation Reactor—From Flame Spray Pyrolysis to Industrial Scale

    New search for: Stefan Heidinger
    New search for: Felix Spranger
    New search for: Jakub Dostál
    New search for: Chunliang Zhang
    New search for: Christian Klaus

    Current challenges in the areas of health care, environmental protection, and, especially, the mobility transition have introduced a wide range of applications for specialized high-performance materials. Hence, this paper presents a novel approach for designing materials with flame spray pyrolysis on a lab scale and transferring the synthesis to the pulsation reactor for mass production while preserving the advantageous material properties of small particle sizes and highly specific surface areas. A proof of concept is delivered for zirconia and silica via empirical studies. Furthermore, an interdisciplinary approach is introduced to model the processes in a pulsation reactor in general and for single material particles specifically. Finally, facilities for laboratory investigations and pulsation reactor testing in an industrial environment are presented.

    Access

    Download

    Material Treatment in the Pulsation Reactor—From Flame Spray Pyrolysis to Industrial Scale

    New search for: Stefan Heidinger
    New search for: Felix Spranger
    New search for: Jakub Dostál
    New search for: Chunliang Zhang
    New search for: Christian Klaus

    Current challenges in the areas of health care, environmental protection, and, especially, the mobility transition have introduced a wide range of applications for specialized high-performance materials. Hence, this paper presents a novel approach for designing materials with flame spray pyrolysis on a lab scale and transferring the synthesis to the pulsation reactor for mass production while preserving the advantageous material properties of small particle sizes and highly specific surface areas. A proof of concept is delivered for zirconia and silica via empirical studies. Furthermore, an interdisciplinary approach is introduced to model the processes in a pulsation reactor in general and for single material particles specifically. Finally, facilities for laboratory investigations and pulsation reactor testing in an industrial environment are presented.

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    Download

    Access

    Download

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    Title:

    Material Treatment in the Pulsation Reactor—From Flame Spray Pyrolysis to Industrial Scale

    Contributors:

    Stefan Heidinger (author) / Felix Spranger (author) / Jakub Dostál (author) / Chunliang Zhang (author) / Christian Klaus (author)

    Published in:

    Sustainability, Vol 14, Iss 6, p 3232 (2022)

    Publication date:

    2022

    ISSN:

    2071-1050

    DOI:

    https://doi.org/10.3390/su14063232

    Type of media:

    Article (Journal)

    Type of material:

    Electronic Resource

    Language:

    Unknown

    Keywords:

    mobility transition , pulsation reactor , flame spray pyrolysis , flame spray synthesis , material treatment , catalysts , Environmental effects of industries and plants , TD194-195 , Renewable energy sources , TJ807-830 , Environmental sciences , GE1-350

    Metadata by DOAJ is licensed under ​CC BY-SA 1.0

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