Thermomechanical Modeling of the Stabilization Process for Carbon Fiber Production

zu Verbundenen Objekten

Abstract: Within carbon fiber manufacturing, the stabilization process is the most time‐ and energy‐intensive process due to the complexity of chemical structure transformation. Therefore, optimization is strictly required to enable cost‐efficient stabilization processes. For the first time, a hybrid semi‐parametric model for continuous stabilization is developed to prognose stabilization progress and density of the stabilized fiber. The proposed model takes the process parameters like dwell time, stabilization temperature, and fiber stretching as well as precursor properties, such as fiber density, into account. Finally, the proposed hybrid semi‐parametric model offers a novel plant‐transferable optimization solution for model‐based energy optimization in the stabilization process.

Standort
Deutsche Nationalbibliothek Frankfurt am Main
Umfang
Online-Ressource
Sprache
Englisch

Erschienen in
Thermomechanical Modeling of the Stabilization Process for Carbon Fiber Production ; day:29 ; month:08 ; year:2023 ; extent:7
Chemical engineering & technology ; (29.08.2023) (gesamt 7)

Urheber
Wolf, Jan
Peters, Romy
Mädler, Jonathan
Wolz, Daniel S.
Behnisch, Thomas
Sadeghi Bogar, Mohsen
Urbas, Leon
Gude, Maik

DOI
10.1002/ceat.202300316
URN
urn:nbn:de:101:1-2023082915161574507152
Rechteinformation
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
Letzte Aktualisierung
14.08.2025, 10:54 MESZ

Datenpartner

Dieses Objekt wird bereitgestellt von:
Deutsche Nationalbibliothek. Bei Fragen zum Objekt wenden Sie sich bitte an den Datenpartner.
Original beim Datenpartner anzeigen

Beteiligte

  • Wolf, Jan
  • Peters, Romy
  • Mädler, Jonathan
  • Wolz, Daniel S.
  • Behnisch, Thomas
  • Sadeghi Bogar, Mohsen
  • Urbas, Leon
  • Gude, Maik

Ähnliche Objekte (12)

Investigation of temperature effect on thermo-mechanical property of carbon fiber/PEEK composites

Investigation of temperature effect on thermo-mechanical property of carbon fiber/PEEK composites

Enhanced stabilization of cellulose-lignin hybrid filaments for carbon fiber production

Enhanced stabilization of cellulose-lignin hybrid filaments for carbon fiber production

Modeling a thermomechanical NC-simulation

Modeling a thermomechanical NC-simulation

Thermomechanical modeling of magmatic systems

Thermomechanical modeling of magmatic systems

Framework for active stabilization of thermomechanical distortions in space structures

Framework for active stabilization of thermomechanical distortions in space structures

Thermomechanical Mean-Field Modeling and Experimental Characterization of Long Fiber-Reinforced Sheet Molding Compound Composites

Thermomechanical Mean-Field Modeling and Experimental Characterization of Long Fiber-Reinforced Sheet Molding Compound Composites

Thermo‐Mechanical Modeling of Pre‐Consolidated Fiber‐Reinforced Plastics for the Simulation of Thermoforming Processes

Thermo‐Mechanical Modeling of Pre‐Consolidated Fiber‐Reinforced Plastics for the Simulation of Thermoforming Processes

Thermomechanical modeling of silicon carbide coated graphite

Hochschulschrift

Thermomechanical modeling of silicon carbide coated graphite

Thermo-mechanical modeling for selective laser melting

Hochschulschrift

Thermo-mechanical modeling for selective laser melting

Thermo-mechanical modeling for selective laser melting

Hochschulschrift

Thermo-mechanical modeling for selective laser melting

Thermo-mechanical coupling behavior of needle-punched carbon/carbon composites

Thermo-mechanical coupling behavior of needle-punched carbon/carbon composites

Structure evolution in polyethylene‐derived carbon fiber using a combined electron beam‐stabilization‐sulphurization approach

Structure evolution in polyethylene‐derived carbon fiber using a combined electron beam‐stabilization‐sulphurization approach

Verbundene Objekte