Babysitter fea-structural

Deep integration with finite element analysis tools for structural simulation across static, dynamic, and nonlinear domains

install

source · Clone the upstream repo

git clone https://github.com/a5c-ai/babysitter

Claude Code · Install into ~/.claude/skills/

T=$(mktemp -d) && git clone --depth=1 https://github.com/a5c-ai/babysitter "$T" && mkdir -p ~/.claude/skills && cp -r "$T/library/specializations/domains/science/mechanical-engineering/skills/fea-structural" ~/.claude/skills/a5c-ai-babysitter-fea-structural-76a066 && rm -rf "$T"

manifest: library/specializations/domains/science/mechanical-engineering/skills/fea-structural/SKILL.md

Finite Element Analysis Skill

Purpose

The Finite Element Analysis skill provides deep integration with FEA tools for structural simulation, enabling systematic setup, execution, and post-processing of finite element models across static, dynamic, and nonlinear analysis domains.

Capabilities

ANSYS Mechanical, Abaqus, NASTRAN model setup and execution
Mesh generation strategies and quality assessment
Element type selection and convergence studies
Boundary condition specification and load case management
Linear and nonlinear static analysis configuration
Results post-processing and margin of safety calculation
Mesh independence and sensitivity studies
Report generation with stress/deflection contours

Usage Guidelines

Model Setup

Geometry Preparation

CAD Import and Cleanup
- Defeature small holes and fillets (analysis dependent)
- Remove unnecessary detail
- Verify watertight geometry
- Create symmetry conditions if applicable
Geometry Partitioning
- Partition for mesh control
- Create virtual topology for hex meshing
- Identify contact surfaces
- Define load application regions

Mesh Generation

Element Selection

Analysis Type	Recommended Elements
Static stress	Hex20, Tet10, Quad8
Thin structures	Shell (QUAD4/8, TRIA3/6)
Beam structures	BEAM/BAR elements
Contact	Linear elements preferred
Nonlinear	Reduced integration with hourglass control

Mesh Quality Criteria

Aspect ratio: < 5 (< 3 preferred)
Jacobian: > 0.6
Warpage: < 15 degrees
Skewness: < 0.8

Mesh Refinement
- Refine at stress concentrations
- Transition ratios < 1.5
- Multiple elements through thickness
- Convergence study requirements

Analysis Configuration

Boundary Conditions

Constraints
- Fixed (all DOF constrained)
- Pinned (translations fixed, rotations free)
- Symmetry (appropriate DOF constrained)
- Prescribed displacement
Best Practices
- Avoid over-constraint
- Use RBE2/RBE3 for load distribution
- Consider realistic support stiffness
- Document all assumptions

Load Application

Load Types
- Pressure (uniform, hydrostatic)
- Force (point, distributed)
- Moment/torque
- Thermal loads
- Inertial loads (gravity, acceleration)
Load Cases
- Define all operational load cases
- Include limit and ultimate factors
- Combine per applicable standards
- Document load derivation

Results Post-Processing

Stress Evaluation

Stress Quantities
- von Mises (ductile materials)
- Principal stresses (fatigue, brittle)
- Membrane + bending (shells)
- Interlaminar (composites)

Margin of Safety

MS = (Allowable / Applied) - 1
MS > 0 indicates positive margin

Reporting
- Maximum stress location and value
- Stress contour plots
- Deflection summary
- Reaction forces verification

Process Integration

ME-006: Finite Element Analysis (FEA) Setup and Execution
ME-007: Stress and Deflection Analysis
ME-009: Nonlinear Structural Analysis

Input Schema

{
  "geometry": "CAD file path or description",
  "material": {
    "name": "string",
    "E": "number (Pa)",
    "nu": "number",
    "yield": "number (Pa)",
    "ultimate": "number (Pa)"
  },
  "loads": [
    {
      "type": "pressure|force|moment|thermal",
      "magnitude": "number",
      "location": "string",
      "direction": "array [x,y,z]"
    }
  ],
  "constraints": [
    {
      "type": "fixed|pinned|symmetry",
      "location": "string",
      "dof": "array"
    }
  ],
  "analysis_type": "static|modal|nonlinear",
  "output_requests": ["stress", "displacement", "reactions"]
}

Output Schema

{
  "analysis_results": {
    "max_stress": {
      "von_mises": "number (Pa)",
      "location": "string",
      "element_id": "number"
    },
    "max_displacement": {
      "magnitude": "number (m)",
      "location": "string",
      "node_id": "number"
    },
    "reaction_forces": {
      "total": "array [Fx, Fy, Fz, Mx, My, Mz]"
    }
  },
  "margin_of_safety": {
    "yield": "number",
    "ultimate": "number",
    "critical_location": "string"
  },
  "mesh_quality": {
    "element_count": "number",
    "worst_aspect_ratio": "number",
    "convergence_status": "string"
  }
}

Best Practices

Always perform mesh convergence studies for critical analyses
Verify reaction forces match applied loads
Check for rigid body modes in modal analysis
Use appropriate element formulations for contact
Document all modeling assumptions and simplifications
Compare results with hand calculations where possible

Integration Points

Connects with CAD Modeling for geometry import
Feeds into Fatigue Life Prediction for durability assessment
Supports Test Correlation for model validation
Integrates with Thermal Analysis for coupled problems