1 / 18

STRUCTURAL WRINKLING PREDICTIONS FOR MEMBRANE SPACE STRUCTURES

STRUCTURAL WRINKLING PREDICTIONS FOR MEMBRANE SPACE STRUCTURES. David W. Sleight, Alexander Tessler, and John T. Wang Analytical and Computational Methods Branch NASA Langley Research Center Hampton, VA d.w.sleight@larc.nasa.gov FEMCI Workshop 2002

leroykelly
Télécharger la présentation

STRUCTURAL WRINKLING PREDICTIONS FOR MEMBRANE SPACE STRUCTURES

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. STRUCTURAL WRINKLING PREDICTIONS FOR MEMBRANE SPACE STRUCTURES David W. Sleight, Alexander Tessler, and John T. WangAnalytical and Computational Methods Branch NASA Langley Research Center Hampton, VA d.w.sleight@larc.nasa.gov FEMCI Workshop 2002 Innovative FEM Solutions to Challenging Problems May 22-23, 2002

  2. Outline • Motivation • Objectives • Tension Field Theory for Predicting Wrinkling • Thin-Shell Theory for Predicting Wrinkling • Wrinkling Analyses • Summary

  3. Sunshield Membrane Optics Solar Sail Motivation • Future space missions enabled by large Gossamer systems • Understanding and predicting the behavior of membrane structures is essential for design and assessment of their performance

  4. Types of Wrinkles • Permanent deformations • Creases • Result from manufacturing or packaging Structural Wrinkles Material Wrinkles • Temporary deformations • Localized buckling • Result from loading or boundary conditions • Change load paths within a membrane structure

  5. Problems Due to Structural Wrinkling • Degraded performance • Affect maneuverability and stability • Poor surface accuracy NGST Test Solar Sail Inflatable Antenna

  6. 10 m, 2 Quadrant Solar Sail in LaRC 16m Vacuum Chamber

  7. Objectives • Develop effective and robust FEA capabilities to predict structural wrinkles in membrane space structures • Predict surface distribution of structural wrinkles using: • Membrane analysis • Shell analysis (with out-of-plane deformations)

  8. Tension Field Theory for Predicting Wrinkling • Originated by Wagner (1929) and Reissner (1938) • Membranes have negligible bending stiffness and cannot sustain compressive stresses • Wrinkles are treated as infinitesimally close to one another • Out-of-plane deformations of wrinkles cannot be determined • Tension field Theory (TFT) has been implemented by • varying linear elastic material properties • introducing a wrinkle strain • formulating a ‘relaxed’ strain energy density

  9. Wrinkle line s2=0 s10 Stein-Hedgepeth Theory (SHT) - 1961 • Membrane cannot carry compressive stress • Two types of regions: • Taut • Wrinkled • Effects of wrinkling are accounted for using a variable Poisson’s ratio that permits “over-contraction” in the direction of minor principal stresses • Wrinkles are aligned with the major principal stress axis

  10. Iterative Membrane Property (IMP) Method(Miller and Hedgepeth, 1982) • FE implementation of the SHT • Geometrically nonlinear analysis • Wrinkle criteria based on element stress/strain states • Taut: s2 > 0 (isotropic material) • Wrinkled: 1 > 0 & s2 ≤ 0 (orthotropic material) • Slack: 1 < 0 (zero stiffness material) • Finite element implementation into ABAQUS • Adler-Mikulas (2000)

  11. Thin-Shell Theory for Predicting Wrinkling • Membrane theory cannot predict the amplitude and shape of wrinkles • Shell theory includes both membrane and bending flexibilities • enables post-buckling response • can predict amplitude and shape of wrinkles • Geometrically nonlinear analysis is necessary to predict the structural behavior

  12. Thin-Shell Wrinkling Analyses Using ABAQUS • Geometrically nonlinear FE analysis • Using reduced integration thin-shell element (S4R5) • Imperfections are added to initial geometry • mode shapes from buckling analysis • random imperfections • Employ ABAQUS with STABILIZE parameter to automatically add damping for preventing unstable and singular solutions • for accuracy, use lowest possible value for which convergence can be achieved

  13. Wrinkling Analyses • Square Membrane Loaded in Tension • Rectangular Membrane Loaded in Shear

  14. Square Membrane Loaded in Tension(Blandino, Johnston, et al, 2002) Applied Load Applied Load Kapton membrane: 2.54 x 10-2 mm thick Applied Loads: 2.45 N (Isothermal)

  15. Wrinkling Results Wrinkled Region Experimental Results (Blandino, Johnston, et al) ABAQUS IMP Results 10,000 elements M3D3/M3D4 Membrane Elements

  16. Rectangular Membrane Loaded in Shear(Wong and Pellegrino, 2002) 380 mm d = 3 mm 128 mm Fixed Kapton foil: 25 mm thick

  17. Wrinkling Results 3960 elements 5% initial random imperfections Out-of-plane Deflection

  18. Summary • Future space missions enabled by Gossamer structures • Effective and robust analysis tools required • Structural wrinkles constitute a major concern • Affect surface topology and behavior/performance • FEA analyses using ABAQUS to predict structural wrinkling • Membrane analyses with IMP method • Thin-shell geometrically nonlinear analyses

More Related