modal analysis of rectangular simply-supported functionally graded plates by wes saunders final...
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Modal Analysis of Rectangular Simply-Supported Functionally
Graded PlatesBy Wes Saunders
Final Report
Purpose
• To use Finite Element Analysis (FEA) to perform a modal analysis on functionally graded materials (FGM) to determine modes and mode shapes.
Background• FGMs
– FGMs are defined as an anisotropic material whose physical properties vary throughout the volume, either randomly or strategically, to achieve desired characteristics or functionality
– FGMs differ from traditional composites in that their material properties vary continuously, where the composite changes at each laminate interface.
– FGMs accomplish this by gradually changing the volume fraction of the materials which make up the FGM.
• Modal Analysis– Modal analysis involves imposing an excitation into the
structure and finding when the structure resonates, and returns multiple frequencies, each with an accompanying displacement field.
Problem Description• Each Case
– Frequencies (4)– Mode Shapes (4)– Plates 1m x 1m, 0.025m and
0.05m thick• Case A
– Compare to theoretical values
• Case B-D– Compare to isotropic
• Select Cases– Compare to Efraim formula
Methodology
• FEA
• Modal analysis performed by COMSOL eigenfrequency module.
Methodology (cont.)• Mori-Tanaka estimation of
material properties for FGMs– Gives accurate depiction of
material properties at certain point in the thickness, dependent on volume fractions and material properties of the constituent materials
– Get density (ρ), shear (K) and bulk (μ) moduli
– Use elasticity to get expressions for E and ν
Results - Isotropic
• Isotropic results matched with theory
• Reasons for isotropic case– Verify FEA model– Check plate thickness
limit– Have baseline for
comparison to FGM
Results – Linear
• Represents, on average,a 50/50 metal-ceramic FGM
• h=0.05m frequencies were bounded by their constituent materials
• Mode shapes 2a and 2b swapped from where they were in isotropic cases
Results – Power Law n=2
• Represents, on average, a 67/33 metal-ceramic FGM
• Frequencies are bounded by their constituent materials
• Mode shapes are changed by addition of ceramic
Results – Power Law n=10
• Represents, on average, a 91/9 metal-ceramic FGM, or a metal plate with a thin ceramic coating
• Frequencies were very close to isotropic metal frequencies
• Mode shapes 2a and 2b highly distorted due to presence of ceramic
Comparison to Efraim
• Efraim formula is a simple method of determining FGM frequencies by knowing the isotropic frequencies of the constituent materials
• Method showed results that were 6-11% lower than the FEA results
Conclusions• Using the isotropic and MT checks, a great level of confidence
was achieved in the results. • When considering a FGM that is metal and ceramic, the
frequency seems to follow the metal while the mode shape seems to the follow the ceramic
• A FGM should be thick enough so that enough data is able to be extracted from the cross-section of the plate.
• The Mori-Tanaka estimate is heavy computationally, as demonstrated in Appendix C. For future use, the use of µ and K should stand to simplify the calculations.
• The FEA results were found to be within 6-11% of the computed values from Efraim. Efraim formula can be used as a starting point reference or sanity check on more complex FGM FEA models.