LS-DYNA Compact: Simulation of fiber-reinforced plastics (3 Parts)

Increasing requirements on stiffness and strength together with the need
to reduce weight, lead to further developments of fiber reinforced
composites within the last decades. Nowadays, those materials are used
for structural relevant components of high-volume production
applications.  Therefore, it is necessary to develop procedures that allow
quantifying the complex load carrying and failure as well as damage
mechanisms of these materials with numerical simulations.

In the provided course series, we will discuss serveral aspects of
modeling short, long and continuous fiber reinforced plastic materials
with LS-DYNA, starting with a general discussion of the most important
keywords, integration rule definition and pre- and postprocessing. The
second course will cover material models commonly used for short and
continuous fiber reinforced composite modeling in LS-DYNA. Focus is put on the
different failure criteria and post-failure handling. The
third course will show possibilities to model delamination with either
cohesive elements or tiebreak contacts in LS-DYNA.

day 1) Composites Modeling in LS-DYNA
Important Keywords
Integration Rule Definition
Pre- and Postprocessing with LSPP
Differences btw. SFRP & CFRP

day 2) Composite Material Models in LS-DYNA
CFRP Material Models
*MAT_022
*MAT_054
*MAT_058
*MAT_261
*MAT_262
SFRP Material Models
*MAT_157
*MAT_215

day 3) Delamination Modeling
Cohesive Element Formulation
Cohesive material Models
Tiebreak Contacts

 

Dates:
Day 1: July 1st, 10:30 am - 12:30 pm
Day 2: July 2nd, 10:30 am  -12:30 pm
Day 3: July 3rd, 10:30 pm - 12:30 pm

 

Please register separately for each part.

Details
   
Date 01.07.2020 - 03.07.2020 (3 days)
Lecturers Christian Liebold
Location
Languages English
Price
Standard (600 € + VAT)
Employee of University (300 € + VAT)
Student (150 € + VAT)
ICal
Contact
contact Maik Schenke
  • Training Courses
  • Multiphysics
contact Carina Sieber
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