Full Ship Shock Test Modeling

1. Full Ship Shock Test Modeling Dr. Tom Moyer, NSWC/Carderock 15 April, 2008

2. Modeling & Simulation (M&S) Is Used By The Navy To Predict Ship Structure & Systems Response To Underwater Explosion Threats Design & Qualification Of Ship Systems Pre-Test Prediction Of Full Ship Shock Trial Response M&S Being Evaluated For More Extensive Use For Design & Qualification Of Ship Systems Major Component In FSST Alternative(s) M&S For Ship UNDEX Response

3. Surface Reflected Plume Wave Spray Dome Air SZ Water Surface Water Bulk Cavitation Region Bubble at first Minimum First Bubble Bottom Reflected Wave Pulse (Traveling entirely Direct Shock Burst through water) Waves Bottom Reflected Wave (Traveling partially through bottom material) Ocean Bottom Summary of Underwater Explosion Phenomena

4. DYnamic System Mechanics Advanced Simulation A fully-coupled hydrocode for simulating underwater explosion phenomena and their effects on naval structures DYSMAS

5. . GEMINI Euler solver Shock and Fluid Dynamics DYNA-N & PARADYN Lagrange solvers Structural Response Standard Coupler Interface Fully Coupled Fluid-Structure Interaction DYSMASDYnamic System Mechanics Advanced Simulation DFBEM BEM solver Bubble & Fluid Dynamics HYDROCODE FOR SIMULATION OF UNDERWATER EXPLOSION EFFECTS

6. Verification Procedure Documentation of the DYSMAS code and its capabilities Documentation of configuration management & model verification calculations Documentation of laboratory and small-scale validation calculations Comprehensive report applicable to UNDEX applications Validation Procedure (Phase I - General Validation) Acquire validation-quality UNDEX loading and hull response data for platform design and weapon lethality applications using surrogate ship Pre- and post-test comparisons of DYSMAS simulations vs test data Code validation against full-scale, realistic ship structure Validation Procedure (Phase II - Application-specific Validation) Design & acquire validation-quality UNDEX loading and response data for specific (local) platform structures Code validation against design-specific concepts DYSMAS V & V Approach

7. TYPICAL DATA ANALYSIS Full Record 1/e * Pmax Shock Wave Shock Wave (extended) 1st Bubble Pulse

8. EFSP

9. Lagrangian Model • 16,165 Nodes • 21,053 Elements

10. 8976 FWD Results – Innerbottom, Vertical Velocity Below FWD STBD Mount

11. Eulerian Simulation T: 5.0 msec T: 5.4 msec T: 5.9 msec T: 6.8 msec T: 8.3 msec T: 11.8 msec

12. Lagrangian Simulation T: 10.0 msec T: 6.2 msec T: 50.0 msec T: 13.2 msec

13. Innerbottom Vertical AccelerationDYSMAS vs EFSP Test FWD 60 lbs HBX, 20 ft Hrz Stdf

14. DYSMAS/SUMMARY • DYSMAS Is Widely Used In Navy Community For UNDEX Simulations • 2007 JASON Review Concluded • Good Agreement With Liquid Response • Good Agreement With Short-time Structural Response • Structural Response [After Initial Impulse] Can Be Improved • A validated M&S could evaluate/improve component-testing methodology

15. Beyond DYSMAS => CREATE • DYNA_N/PARADYN Lack Many Of The FEM Features Needed For Improved UNDEX Simulations • DYNA_N/PARADYN Employ Antiquated Software Constructs • Maintenance Difficult/Time Consuming • Adapting To Evolving Computer Hardware Challenging • Gemini Is Sufficiently Validated & Employs Modern Software Engineering Constructs • Standard Coupler Interface Limits Calculation Scaling On Parallel Platforms SOLUTION: Develop Gemini/Lagrange Solver With Parallel Coupling

16. CREATE Objectives For UNDEX Develop Robust Computational Capability To Predict Response Of Surface Ships & Submarines To UNDEX Loading System/Component Environments Structural Response & Damage Scenarios Stand-Off UNDEX Close-In UNDEX SURFEX Interface w/ Ship State Modeling ASAP/ARM FASST

17. Objective: Quantify ship response to standoff UNDEX shot geometries Problem Characteristics: Linear-elastic hull structure (no appreciable damage) Point-to-point non-linear elements (e.g., shock mounts) Linear-elastic equipment & system response End-User Products Quantify equipment location shock environments Specifications for isolation systems (mounts & rafts) Develop more-representative equipment qualification environments for component-level testing CREATE USE CASE IStandoff UNDEX Response

18. Capabilities from CREATE program: Integrated modal analysis capability Integrated (implicit) static pre-calculation capability Hydrostatic pre-stress, static bending moment Optimized explicit code solution procedure for pure linear-elastic problems Bulk of design cases Improved modal characteristics of equipment & systems Enables smoother, more accurate incorporation of vendor sub-models Results Synthesis => Design Requirements, Performance Assessments, Design Modifications Fully Integrated With Ship Design Tools Includes Integration w/ ASAP/ARM Development of “REPLAY” strategies Meets All Requirements For FSST Replacement Calculations CREATE USE CASE I Standoff UNDEX Response

19. Objective: Quantify equipment response and damage to more severe shot geometries Problem Characteristics: Non-linear hull structure response Point-to-point non-linear elements (including shock mount bottoming) Non-linear equipment and system response End-User Products Equipment and system damage and operability assessments Hull structural performance LFT&E Assessments (w/ limitations) CREATE USE CASE IISevere UNDEX Response

20. Capabilities from CREATE program: Includes list from Use Case I Multi-length scale modeling strategies All-up simulation capability Telescoping analysis strategies Applications using “REPLAY” functions Fragility assessment capability Enables design margins to be assessed Enhanced Mission Effectiveness Assessment Enhanced Results Synthesis Methodology Quantification Of Margin & Uncertainty CREATE USE CASE II Severe UNDEX Response

21. Objective: Quantify ship structural damage due to LFT&E UNDEX scenarios Problem Characteristics: Extremely Non-linear hull structure response Large hull deformations w/ Significant Contact & Significant Material Failure Time Evolutionary Structural Degradation End-User Products Primary structural damage Cascading structural damage effects Equipment and system damage and operability assessments CREATE USE CASE III LFT&E Assessments

22. Capabilities from CREATE program: Improved failure models & failure criteria Damaged based failure models More-accurate damage progression Energy conserving damage propagation More-accurate damage patterns Fracture based damage models (perhaps) Particle methods (perhaps) More-accurate contact algorithms No miss contact detection Energy/Momentum conserving forces CREATE USE CASE IIILFT&E Assessments

23. Technical Approach • Integrate Gemini Into Evolving SIERRA Architecture From SNL • Leverage Existing Substantial DOE Commitment • Evolve SIERRA To Address • More Efficient Parallel Workload Distribution • General, Scale-able Euler/Lagrange Coupling • Enhance Lagrange Capabilities In SIERRA For UNDEX Requirements • Robust Structural Element Library • Multi-Length Scale Modeling • Modal Sub-Structuring (CMS) • …

24. CREATE/UNDEX Development Team Organization CREATE UNDEX Navy Lead • Leveraged Related Programs • ONR • NAVSEA • OSD CREATE UNDEX M&S Development NSWC/CD Lead • Board Of Advisors • Navy Technical Authority • PEO Ships • PEO Carriers • PEO Submarines • OSD • Subject Matter Experts Software Design Working Group SNL Lead Langrange Element Working Group NSWC/CD Lead Euler Element Working Group NSWC/IH Lead Results Synthesis Working Group NSWC/CD Lead

25. CREATE/UNDEX Schedule

26. Summary • DYSMAS Provides Navy UNDEX Response M&S Capability Sufficient For • FSST Alternative • Limited System Design/Qualification Support • Limited Structural Damage Prediction Capability • CREATE/UNDEX Capability Will • Expand Application For System Design/Qualification • Enhance LFT&E Assessments • Support Design Of Cheaper & Safer Ships