ME 501 Final Project: Analysis of Ford Expedition Frame Crossmember

1. ME 501 Final Project:Analysis of Ford Expedition Frame Crossmember June 20, 2001 John Smart Andy Stansel Courtesy Ford Motor Company Used without permission

2. Presentation Outline • Project Background and Objective • Modeling—meshing, boundary conditions. • 3 loading conditions • Results • Conclusions

3. Project Objective

4. Modeling—ProE Model New crossmenber dimensions OEM Crossmember New crossmember Frame rails • Both crossmembers were created in Pro/E

5. Modeling—Ansys Model • Export Pro/E model as an IGES file • Import the IGES file into ANSYS • Set element type as “Shell 63” (3D, 4 node element, 6 DOF per node) • Set shell thickness to .125” • Material properties of steel (E=30 Mpsi, n=.27)1040 Steel, Sy = 86 kpsi

6. Modeling—Meshing Coarse & fine free meshing 4 elements thick • Several different meshes were tested Fine mapped meshing 2,544 elements 2,546 nodes 15,276 DOF (unconstrained)

7. Modeling—Boundary Conditions #1 Fixed symmetry #2 Chase boundary OEM crossmember • Two separate boundary conditions were tested Difference of 8 kpsi

8. Modeling—Boundary Conditions #1. Fixed, fixed #2. Quasi-simply supported Difference of 2 psi! Therefore, we used fixed-fixed conditions New crossmember • Two separate boundary conditions were tested

9. Loading Condition #1 OEM crossmember New crossmember 1,000 lbs. Fixed Rollers 1,000 lbs 1,000 lbs. Fixed Fixed • Vehicle at rest, or driving straight, or landing from jump.

10. Loading #1— Results OEM crossmember New crossmember Maximum deflection=.022” Maximum deflection=.0335” Y-displacement Bulges out here

11. Loading #1— Results OEM crossmember New crossmember Max eq. stress: 47 kpsi Factor of safety: 1.8 Max eq. stress: 34 kpsi Factor of safety: 2.5

12. Loading Condition #2 OEM crossmember New crossmember fixed fixed 500 ft-lbs 500 ft-lbs • Frame rails twist due to terrain. This induces torsion in the crossmember.

13. Loading #2—Results OEM crossmember New crossmember Max deflection: 0.0308” Max deflection: 0.0325”

14. Loading #2—Results OEM crossmember New crossmember Max eq. stress: 7.6 kpsi Factor of Safety: 11.3 Max eq. stress: 8.8 kpsi Factor of Safety: 9.7

15. Loading Condition #3 1,000 lbs 1,000 lbs fixed fixed • Pure bending in crossmember OEM crossmember New crossmember

16. Loading #3—Results OEM crossmember New crossmember Max deflection: 0.897” Max deflection: 0.972”

17. Loading #3—Results OEM crossmember New crossmember Mad stress concentration Max eq. stress: 59.1 kpsi Factor of safety: 1.4 Max eq. stress: 92.8 kpsi Factor of safety: 0.92

18. Loading #3—Results sZ (normal) OEM crossmember New crossmember Neutral axis

19. Summary of Results

20. Model Limitations • Difficult to model frame rail interaction—boundary conditions • Difficult to know magnitude of loading conditions • No detailed models of weld joints, body mounts, gussets, or rounds

21. Conclusion Our simple analysis shows: • The new crossmember is less stressed than the OEM version for typical “around town” loading conditions (load case 1) • However, for extreme off-road type load conditions, the new crossmember is inferior to the OEM (load cases 2,3) • Further analysis and prototype testing should be done before going into production.

22. What we learned • 3D importing • 3D meshing • Effects of different boundary conditions • FEA is not a “black box”