Job Description – Structural Simulation & Multiphysics Engineer (R&D)
Position: Structural Simulation & Multiphysics Engineer (Static, Dynamic, Fatigue, Creep, Wear & FSI Analysis)
Department: Research & Development (R&D)
Experience: 1–2 Years (Industry, Research, Internship, or Project Experience)
Education: M.Tech / M.S. (Research) in Mechanical Engineering, Structural Engineering, Computational Mechanics,
Aerospace Engineering, Design Engineering, Materials Engineering, or related discipline from a reputed institute.
Strong academic performance in Bachelor's and Master's degrees is preferred.
Position Summary
We are seeking a highly motivated Structural Simulation & Multiphysics Engineer to join our R&D team focused on
developing advanced ceramic products, manufacturing systems, and digital engineering solutions. The selected
candidate will leverage Finite Element Analysis (FEA), Multibody Dynamics (MBD), Fluid-Structure Interaction (FSI),
and AI-assisted simulation techniques to improve product reliability, durability, safety, and performance.
The role involves simulation-driven design, failure analysis, material characterization, virtual testing, and
optimization of ceramic products used in construction, infrastructure, and industrial applications.
Key Responsibilities
Structural Analysis
Perform finite element simulations for:
Static structural analysis
Linear and nonlinear analysis
Contact mechanics
Large deformation analysis
Buckling analysis
Stress and strain evaluation
Failure prediction
Evaluate:
Strength
Stiffness
Safety factors
Structural integrity
Design optimization opportunities
Dynamic Analysis
Develop simulation models for:
Modal analysis
Harmonic response
Random vibration
Shock loading
Impact loading
Seismic loading
Operational vibration studies
Assess:
Natural frequencies
Mode shapes
Dynamic amplification
Resonance risks
Vibration-induced failures
Fatigue & Durability Analysis
Perform:
High-cycle fatigue (HCF)
Low-cycle fatigue (LCF)
Thermal fatigue
Multiaxial fatigue
Fatigue crack initiation assessment
Support life prediction of:
Ceramic tiles
Roofing systems
Façade elements
Structural ceramic components
Manufacturing equipment
Creep & Long-Term Performance Analysis
Evaluate:
Time-dependent deformation
Stress relaxation
Thermal creep
High-temperature material degradation
Long-term durability
Develop predictive models for:
Kiln components
Refractory systems
Structural ceramic products
Impact & Crash Analysis
Conduct virtual testing for:
Product drop tests
Transportation loading
Impact resistance
Packaging validation
Fragmentation behavior
Simulate:
Brittle fracture
Failure propagation
Energy absorption mechanisms
Support compliance with industry standards and customer requirements.
Wear & Tribology Analysis
Investigate:
Abrasive wear
Sliding wear
Erosive wear
Contact pressure distribution
Surface degradation
Evaluate durability of:
Ceramic coatings
Industrial ceramic components
Wear-resistant products
Fluid-Structure Interaction (FSI)
Develop coupled simulations involving:
Wind loading on building products
Thermal-fluid interactions
Airflow-induced vibration
Pressure loading
Fluid-driven deformation
Analyze:
Structural response to fluid forces
Aeroelastic effects
Thermal-mechanical-fluid coupling
Product Development Support
Collaborate with:
Materials scientists
Manufacturing engineers
Product designers
Process engineers
Support:
New product development
Product qualification
Failure investigations
Root-cause analysis
Digital Engineering & AI Applications
Apply AI/ML techniques to:
Accelerate simulation workflows
Create surrogate models
Predict material performance
Automate design optimization
Enable virtual testing
Contribute to:
Digital twins
Physics-informed AI models
Predictive maintenance systems
Smart manufacturing initiatives
Required Qualifications
Education
Essential:
M.Tech / M.S. (Research) in:
oMechanical Engineering
oComputational Mechanics
oStructural Engineering
oAerospace Engineering
oDesign Engineering
oMaterials Engineering
oApplied Mechanics
Preferred:
Strong academic record in both Bachelor's and Master's studies.
Technical Skills
Finite Element Analysis (FEA)
Hands-on experience with one or more:
ANSYS Mechanical
ABAQUS
Analysis Expertise
Knowledge of:
Linear FEA
Nonlinear FEA
Contact mechanics
Fracture mechanics
Dynamic analysis
Fatigue analysis
Creep analysis
Wear modeling
Explicit dynamics
Impact simulation
Multiphysics coupling
Programming & Automation
Proficiency in:
Python
Scientific Computing
Experience in:
Simulation automation
Data analytics
Numerical methods
Workflow scripting
AI/ML Skills (Preferred Add-On)
Exposure to:
Machine Learning
Surrogate Modeling
Bayesian Optimization
Tools:
PyTorch
TensorFlow
Preferred Research Experience
Candidates with thesis or research experience in any of the following are highly desirable:
Structural mechanics
Fracture mechanics of brittle materials
Ceramic material behavior
Computational mechanics
Contact mechanics
Fatigue and durability
Crashworthiness
Tribology and wear
Fluid-structure interaction
Digital twins
Physics-based AI
Key Competencies
Strong engineering fundamentals.
Excellent analytical and problem-solving skills.
Ability to interpret experimental and simulation data.
Scientific writing and technical documentation.
Cross-functional collaboration.
Innovation mindset and research orientation.
Ability to independently execute simulation projects.
Key Performance Indicators (KPIs)
Accuracy of simulation predictions.
Correlation with experimental results.
Reduction in product failures and defects.
Improvement in product durability and reliability.
Simulation-led design optimizations implemented.
Development of reusable simulation methodologies.
Publications, patents, and technical disclosures.
AI-enabled productivity improvements in engineering workflows.
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