IBEX 2002 - Session 602 Finite Element Analysis

1. IBEX 2002 - Session 602Finite Element Analysis Paul H. Miller, D. Engr. Assistant Professor of Naval Architecture United States Naval Academy IBEX 2002 - SESSION 602

2. Presentation Overview • What is FEA and what will it do for us • What FEA will not do for us • Limitations of FEA • Working with Finite Element Analysts • Case Studies IBEX 2002 - SESSION 602

3. Getting started with a simple exampleA new mast step for an old wooden sailboat • Designer: L. Francis Herreshoff, 1955 • Built: 1962 Lunenberg, N.S. • Original Mast Step was Red Oak (not designed that way) • It broke at a bad moment! t=0.5” IBEX 2002 - SESSION 602

4. The grain is longitudinal The Mast StepAs it’s thickness is about the same dimension as its width, we must use solid elements. • Loads – 7000 lb down • Geometry – 24”x4”x4” • Material – Black Locust • Boundry Conditions – supported by 3 oak floors IBEX 2002 - SESSION 602

5. Black Locust mast step • The actual boundary conditions with the three floors. Floor grain is vertical Forward White Oak floors t=0.5” IBEX 2002 - SESSION 602

6. Deformation (300x) IBEX 2002 - SESSION 602

7. Displacement Maximum displacement is 0.0084” IBEX 2002 - SESSION 602

8. Stress with vertical grain floors Max Stress = -1889 psi IBEX 2002 - SESSION 602

9. Stress with transverse grain floors Max Stress = -2706 psi 43% higher! But floor loads are more even IBEX 2002 - SESSION 602

10. Rolling Shear Stress Maximum shear stress is 559 psi IBEX 2002 - SESSION 602

11. Mast Step Analysis Results • The analysis took 5 hours • The predicted weight was 7.5 pounds • The minimum factor of safety for bending was 10.2 • The minimum factor of safety for shear was 4.4 • The recommended minimum FOS is 4 • Therefore LFH over-designed it by 3/8”! • I built it to LFH’s drawing… IBEX 2002 - SESSION 602

12. Deform – strain (in/in) If the strains are always proportional to the load it is “linear deformation” If not, then “non-linear” Have internal stress (psi) Are made of materials Which could be linear or non-linear themselves Discrete Forces Pressures Vibrations (or fatigue) Accelerations Gravity Dynamics Temperature Moisture What is Finite Element Analysis?In the real world of structural response… Loads include: Objects with loads on them: IBEX 2002 - SESSION 602

13. Stiffness matrix Loads Displacements and Rotations (DOFs) In the world of mathematics… • FEA divides the object up into multiple small parts (up to 100K+!) • Each part is represented by stiffness constants (like springs, f=k·x • All the parts are combined mathematically (by matrix algebra) into a global structure • The solution is found from equilibrium (ΣF=0, ΣM=0) IBEX 2002 - SESSION 602

14. Solving the basic equation for the unknown degrees of freedom… • Finding the final displacement gives us the elongation • Elongation gives us the strain • Strain and area gives us the stress • Stress and failure criteria give us the Factors of Safety! OK, Ready for the quiz?! IBEX 2002 - SESSION 602

15. Physical modeling of structures • An FEA model is made of simple structural “elements” connected at “nodes” • The basic building blocks (elements) are: • Beams (1 primary dimension) • Plates/shells (2 primary dimensions) • Solids (3 primary dimensions) “Primary” means “much bigger than the other dimensions” IBEX 2002 - SESSION 602

16. Just To Avoid Confusion! An element with 2 Primary Dimensions, a shell element, has a length and a width, but is thin compared to the other two dimensions. It can be either used in either 2-D analysis (x and y axes) or in 3-D analysis (x, y and z axes). IBEX 2002 - SESSION 602

17. Common Structural Element Types • Mass • Gap • Immersed pipe • Buoy • Magnetic • Fluid/heat • Solid • Shell • Beam • Cable • Truss • Radiation IBEX 2002 - SESSION 602

18. FEA can handle almost any structure • It’s greatest power (and cost) is with complex structures. • The structure needs to be envisioned in terms of element types which are available, and suitable. • The structure is then represented with many (often thousands) of these elements. IBEX 2002 - SESSION 602

19. Example of Beam/Cable/Truss Elements:What they are 2 nodes, Each node has up to 6 degrees of freedom, giving 12 per element • • IBEX 2002 - SESSION 602

20. Example of Beam Elements: A Mast tube is shells, spreaders are beams, rigging is cables IBEX 2002 - SESSION 602

21. Example of Shell Elements: What they are 4 nodes, Each node has up to 6 degrees of freedom, giving 24 DOF per element IBEX 2002 - SESSION 602

22. Example of Shell Elements: A 77-foot Hull Note the beam elements IBEX 2002 - SESSION 602

23. Example of Solid Elements: What they are 8 nodes, Each node has up to 3 degrees of freedom (translation only), giving 24 DOF IBEX 2002 - SESSION 602

24. Example of Solid Elements:The Mast Step (again) Solids are sometimes called “brick elements” IBEX 2002 - SESSION 602

25. What FEA does beautifully! • Handles complex geometry. (Indeterminate structures) • Isotropic materials (materials with consistent properties in all directions) • Static and simple dynamic problems • Examples • A steel keel, a bronze rudder shaft • Metal hulls (tanker fatigue) • Accuracy is within 0-5%! IBEX 2002 - SESSION 602

26. Complex materials Composites Wood Non-linear static deformation (x5) Buckling of isotropic materials (x2) Increased uncertainty From 1-5% potential error To 3-30% error HIGHER MIN FOS! Increased manhours required to prepare model What FEA does “OK”… This means: Examples: IBEX 2002 - SESSION 602

27. Model took 127 manhours to build Predicted deformations within 4% for static loads Static strains within 6% Example: A Composite Sailboat IBEX 2002 - SESSION 602

28. Composite Sailboat • Fatigue-influenced dynamic strains were predicted within 14% when compared to strain gages and coupons. IBEX 2002 - SESSION 602

29. Non-linear deformationHigh Aspect Ratio Rudder • 8 foot span/16 lb • 20” of tip deflection • High membrane stresses reduce predicted deflection and stress • 5% error in deflection IBEX 2002 - SESSION 602

30. Tsai- Wu Factors of Safety IBEX 2002 - SESSION 602

31. Non-linear Mast Deformation • Small dinghy mast • Used to size spreaders, wire and pretension • Input was gust spectrum • 8% error in deformation IBEX 2002 - SESSION 602

32. What FEA does not do well • Dynamic impact (slamming loads) • Joints ( composites or metal ) • Buckling of “real world” composites. • Misc details unaccounted for in element formulations. • Error can be 30-300%! IBEX 2002 - SESSION 602

33. Dynamic Analysis • FEA has great strengths in dynamic analysis for certain types of problems. • Standard FEA doesn’t handle slamming impacts well. • One of the major difficulties are in the definition of the loads. • The other is in the speed of the transient nature of the load. IBEX 2002 - SESSION 602

34. Joint Analysis with FEA • FEA is good for extracting loads at joints. • FEA is weak in micro analyzing joint designs • This is primarily due to difficulty with material properties and failure mechanisms. IBEX 2002 - SESSION 602

35. Joint Design with FEA(some variation with programs) • Normal FEA solution assumes joint is perfect • Either a) list nodal forces • b) use nodal stresses and area • Determine stress concentration factors for specific joint geometry • Calculate joint loads by spreadsheet (isotropic or wood) or • Use laminate analysis program and spreadsheet (for composites) IBEX 2002 - SESSION 602

36. Not all aspects of structres can be accounted for in FEA models IBEX 2002 - SESSION 602

37. Failure mode prediction is only as good as it’s modeling. This means realistic material testing to support the FEA. “Special” failure mode analysis (post-processing) using spreadsheets or macros IBEX 2002 - SESSION 602

38. Uncertain loads Slamming Impact Transient Unanalyzed loads! IACC cockpit example Uncertain materials Testing QA/QC from builder Model Errors Mesh density Linear or non-linear analysis Wrong elements Boundary conditions Results analysis Limitations of FEA= High Error Possibility! IBEX 2002 - SESSION 602

39. A Multiple Issue Problem! • Loads, materials and boundary conditions • FEA assumes “continuum mechanics” Eventually we got the deflections to match within 10%,But the strength was under predicted by 110%. IBEX 2002 - SESSION 602

40. Working with a Consultant- and getting good value from it -an overview • Choosing a consultant • What you’ll be asked to supply • Getting what you expect • Several projects outlined IBEX 2002 - SESSION 602

41. Choosing a ConsultantQuestions to Ask • Analyst versus engineer or designer • Their experience/education • Your relationship (micromanagement?) • Experience with similar projects • Loads • Materials (isotropic or orthotropic?) • Track record of success and failure • Rates and availability (current range is $25-275/hour) IBEX 2002 - SESSION 602

42. Information You’ll Be Asked To Supply: • Geometry • Loads (are they biased or real?) SES • Material types and properties (guess or test?) • Goals • Deliverables • Any guesses increase the error and may make using FEA uneconomical! IBEX 2002 - SESSION 602

43. Deliverables: • Do you expect guidence in making decisions? • Do you want a specifc question answered or do you want design work? • Do you expect formal documentation? • If so, then in what form? • Report, e-mail, spreadsheet, tables, drawings (dxf, dwg, igs, etc) • Do you want nice color stress plots? IBEX 2002 - SESSION 602

44. Extra hints to make your life easier • Be specific on the design criteria • Stiffness, deflection, strength, FOS • Be flexible on the geometry • Don’t be stuck on a particular design (just because it worked in the past doesn’t mean it is the best) • Keep the design simple! • Communicate! IBEX 2002 - SESSION 602

45. Another Case Study • A 77-foot performance cruiser • Designed by Carl Schumacher • Under Construction in Seattle IBEX 2002 - SESSION 602

46. Project Overview • Began in January 2000 • Structures to meet ABS and realistic loads if not specified • Multiple materials intended • Goal is “ULDB” cruiser • Light but strong with a deep bulb keel IBEX 2002 - SESSION 602

47. FEA work • Designer subcontracted out structural FEA design • Designer provided dxf files for all geometries (hull, appendages) • FEA consultants optimized and specified construction • Designer did hull structure drawings • Consultants did keel structure drawings and interfaced with keel and hull manufacturer to ease construction IBEX 2002 - SESSION 602

48. Design Limit Load Cases • Upwind in heavy air, wave height equal to freeboard, wave length equal to boat length • Slamming • Grounding • Lifting Each load case drove the design of different parts of the boat. IBEX 2002 - SESSION 602

49. Upwind in 30 knots on port tack Rig loads supplied by mast maker IBEX 2002 - SESSION 602

50. Displacements (25x) Maximum displacement = 3.32” Max rotation 0.5 degrees IBEX 2002 - SESSION 602