Embed Size (px)
Citation preview
Bastian BrenkenGraduate Student » [email protected] » 562-606-4159
https://www.purdue.edu/cmsc/
purd
ue.e
du/c
msc BIO
Purdue UniversityPhD program in the School of Aeronautics and Astronautics, major in Structures and Materials with focus on Composite Additive Manufacturing Aug 2014–present
Technical University BraunschweigMaster program of Aerospace Engineering, Oct 2011–Jan 2014
KTH Royal Institute Of TechnologyStudy abroad within the masters program, January–May 2013
Purdue UniversityStudent research project for the masters program about short fiber composite materials, August–December 2012
Technical University BraunschweigBachelor program of Mechanical Engineering, October 2008–June 2011
PRACTICAL EXPERIENCECFK Valley StadeContinuation of the Master Thesis’ project: development of carbon fiber based aircraft fuselage stiffening concepts, March–August 2014
Technical University BraunschweigScientific assistant of research at the School of Aircraft Design and Lightweight Structures–Responsible for the development of an impact test machine for composites, October 2011–February 2012
Physikalisch-Technische BundesanstaltInternship, April–May 2011 and September–Oct 2010
Responsible for a technical construction project to optimize a calibration machine, Main focus on Computer-aided design and quality management.
Airbus Germany, Hamburg (Germany)Internship, September–Oct 2009
Engaged in the aircraft assembly line of the A320 series, in the development division of the A350 and in the quality management section.
RESEARCH INTERESTSBastian’s research focuses on Composite Additive Manufacturing. The Extrusion Deposition Additive Manufacturing (EDAM) method is utilized to print high temperature tooling and molds using carbon fiber reinforced high temperature thermoplastics like Polyphenylene Sulfide (PPS). Bastian’s research topic is the development of simulation tools to predict the process induced warpage and internal stresses of these printed tools. Here, the focus is on modeling the solidification behavior of the deposited material, including the heat transfer problem, crystallization kinetics of the polymer and the material transition from a molten, viscous fluid to a viscoelastic solid.
PUBLICATIONSB. Brenken, A. Favaloro, E. Barocio, N. M. DeNardo and R. B. Pipes,
“Development of a Model to Predict Temperature History and
Crystallization Behavior of 3D Printed Parts Made From Fiber-Reinforced
Thermoplastic Polymers,” in Proceedings of the SAMPE conference,
Long Beach, CA, 2016.
B. Brenken, A. Favaloro, E. Barocio, N. M. Denardo, V. Kunc and R. B. Pipes,
“Fused Deposition Modeling of Fiber-Reinforced Thermoplastic
Polymers: Past Progress and Future Needs,” in Proceedings of the
American Conference on Composite Materials, Williamsburg, VA, 2016.
RESEARCH FIGURES
Figure 1: Printed autoclave tool (left) and laid up prepreg composite part (right)
Figure 2: Simulated temperature distribution of the printed autoclave tool during the extrusion deposition process
Purdue University » Composites Manufacturing & Simulation Center
