finite element analysis (fea) of the taper-trunnion
TRANSCRIPT
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Cedarville UniversityDigitalCommons@Cedarville
The Research and Scholarship Symposium The 2015 Symposium
Apr 1st, 1:20 PM - 1:40 PM
Finite Element Analysis (FEA) of the Taper-Trunnion Interface in a Metal on Metal HipImplantKyle M. BradleyCedarville University, [email protected]
Timothy L. NormanCedarville University, [email protected]
Thomas K. Fehring
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Part of the Biomedical Engineering and Bioengineering Commons, and the Medicine and HealthSciences Commons
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Bradley, Kyle M.; Norman, Timothy L.; and Fehring, Thomas K., "Finite Element Analysis (FEA) of the Taper-Trunnion Interface in aMetal on Metal Hip Implant" (2015). The Research and Scholarship Symposium. 1.http://digitalcommons.cedarville.edu/research_scholarship_symposium/2015/podium_presentations/1
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Kyle BradleyT.L. Norman, PhDT.K Fehring, PhD
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The taper-trunnion interface has been identified as an area of material degradation in a metal on metal hip implant.
This has resulted in an increase in revision surgeries due to metal ions being released into tissue and the bloodstream.
Fretting corrosion is defined as repetitive, relative motion that removes the protective oxide layer of a material allowing the environment to corrode the material.
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Proximal No mismatch Distal
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Finite Element Analysis◦ A numerical method for solving problems in solid
mechanics, dynamics, thermodynamics, biomaterials, etc.
◦ A mesh is used to divide the material into nodes, creating smaller elements
◦ Input: boundary conditions, loading◦ Output: stresses, strains, and displacements at each
node
◦ Finds an approximate solution ◦ Abaqus (FEA Software) was used to run analysis.
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Model the taper-trunnion interface in Abaqus (FEA program)
Measure the contact stresses and the micromotionof the trunnion at the taper-trunnion interface after loading◦ Different angular mismatch values◦ Different roughness values
Compare the results to experimental current flow data
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Use simplified experimental model of a taper-trunnion interface.
Major point of emphasis is a correct model of the contact mechanics
Research the methods of modeling contact in Abaqus (select best one)
Analyze results
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Modeling surface-to-surface contact in Abaqus◦ Finite sliding vs. small
sliding◦ Surface-to-surface contact
vs. node to surface◦ Friction◦ Overclosure◦ Interference fit (shrink fit)
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Problem with previous models◦ Tie restricted motion at the
taper-trunnion interface, “gluing” the parts together
◦ Simulates no micromotionat the interface
◦ Inaccurate results
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Reason for the Tie◦ Abaqus has difficulty resolving surface to surface contact
situations◦ In this case, the surface of the taper and the trunnion were
not in proper contact at the beginning of the simulation.
Solution?◦ Applied an instantaneous concentrated force to the top of
the head on the trunnion axis to set the head onto the trunnion before applying the physiological load (using steps)
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Analysis◦ Initial Step◦ First Step Apply an instantaneous impaction force of 991 pounds in –z
direction. 1
◦ Second Step Apply a physiological ramp load of 444.99 pounds in the –z
direction and -110.95 pounds in the –x direction. This conforms to the ASTM standard #1875-98 loading parameters
for an electrochemical analysis of the fretting corrosion. 2
1J.P. Heiney, S. Battula, G.A. Vrabek, A. Parikh, R. Blice, A.J. Schoenfield, G.O. Njus. “Impact magnitues applied by surgeons and their importance when applying the femoral head onto the Morse taper for total hip arthroplasty.” Arch Orthop Trauma Surg (2009): 793-796.2”Standard Practice for Fretting Corrosion Testing of Modular Implant Interfaces: Hip Femoral Head-Bore and Cone Taper Interface.” ASTM International Designation: F1875-98(2009).
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Proximal Contact Distal Contact
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Fretting work done (FWD) is an arbitrary comparative value assigned to estimate the amount of fretting corrosion. It is directly proportional to estimates of wear depth. 3
FWD = friction coefficient * micromotion * max contact stress
By using both the comparative experimental analysis and the comparative numerical analysis, we had two different approaches that quantitatively compare the amount of fretting corrosion associated with each design configuration.
3F.E. Donaldson, J.C. Coburn, K.L. Siegel. “Total hip arthroplasty head-neck contact mechanics: A stochastic investigation of key parameters.” Journal of Biomechanics 47 (2014): 1634-1641.
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Angular Mismatch◦ Fretting work done (FWD) as a function of angular
mismatch
0
10
20
30
40
50
60
70
-1.5 -1 -0.5 0 0.5 1 1.5
Fret
ting
Wor
k D
one
(FW
D)
Angular Mismatch (degrees)
Fretting Work Done vs. Angular Mismatch
Distal Proximal
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Roughness◦ Fretting work done (FWD) as a function of
roughness
R² = 0.9706
55
57
59
61
63
65
0.2 0.25 0.3 0.35 0.4 0.45
Fret
ting
Wor
k D
one
(FW
D)
Friction Coefficient)
Fretting Work Done vs. Friction Coefficient
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Smaller angular mismatch values resulted in less FWD
Distal contact resulted in less FWD compared to proximal contact
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Changes in friction coefficient resulted in a linear relationship with FWD
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Future research◦ Results for entire trunnion surface◦ Optimal angular mismatch value◦ Further research on the correlation between
roughness and friction coefficient◦ More robust modeling
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Dr. Tim Norman Ph.D. (Academic Advisor)
Dr. Thomas K. Fehring Ph.D. (Clinical Advisor)
2012-13 Cedarville Biomedical Engineering Design Team