Sr. Propulsion Engineer – Thermo-Mechanical Analysis

About The Position

Requirements

• Bachelor's degree in Mechanical Engineering, Aerospace Engineering, or a related field.
• Minimum of 8 years of experience in mechanical / structural / thermal analysis of rotating machinery or comparable high-performance hardware (or fewer years with demonstrated ownership of a whole-engine / 2D axisymmetric thermo-mechanical model).
• Hands-on experience with transient thermal and nonlinear structural finite element analysis in ANSYS (contact, plasticity, thermal-structural coupling).
• Demonstrated experience building (not just running) whole-engine / 2D axisymmetric thermo-mechanical models of rotating equipment.
• Ability to independently derive convective heat-transfer boundary conditions from engineering correlations (does not depend on a separate CFD team to populate a thermal model).
• Experience working in cross-disciplinary engineering teams.
• A track record of taking ownership, showing resilience in the face of challenges, and consistently delivering results.

Nice To Haves

• 10+ years of relevant industry experience.
• Experience working in aerospace.
• M.S. or Ph.D. in Mechanical or Aerospace Engineering or a related discipline.
• Experience producing tip-clearance / pinch-point predictions that informed clearance budgets or active clearance control.
• Life assessment experience: thermo-mechanical fatigue (TMF), creep, low-cycle and high-cycle fatigue (LCF / HCF).
• Rotordynamics literacy (Campbell diagrams, critical speeds, bearing support stiffness) sufficient to close the radial clearance budget.
• Experience correlating and calibrating thermo-mechanical models against rig or engine test data.
• Component design experience (bladed rotors / blisks, discs, casings, seals, bolted joints).
• Scripting and automation (Python, MATLAB, ANSYS APDL).
• Working knowledge of ASME Y14.5 GD&T and tolerance / stack-up analysis.
• Experience with 1D fluid-network tools (e.g., Flownex) and proprietary whole-engine-model toolchains.
• Background in gas turbines, steam turbines, APUs, turbochargers, or oil & gas dense-gas compressors / expanders.
• Demonstrated use of — or genuine enthusiasm to adopt — modern AI-assisted engineering tools (e.g., LLM-based coding/analysis assistants integrated into the daily development environment) to accelerate modeling, scripting, and documentation.
• Experience with LabVIEW and MATLAB.

Responsibilities

• Develop, maintain, and own 2D axisymmetric thermo-mechanical whole-engine / whole-pump models of rotating equipment, predicting metal temperatures, component deflections, and clearances across the full operating envelope.
• Translate 3D component and assembly geometry into efficient 2D axisymmetric representations that capture the governing thermal and structural features.
• Implement transient operating profiles (startup, acceleration, steady-state, throttle transients, shutdown, and cooldown / soak-back) and assess their effect on differential growth and clearances.
• Work closely with secondary-flow analysts to develop conjugate thermal-fluid models, translating internal-flow network outputs (cavity pressures, temperatures, leakage flows, windage) into convective boundary conditions using rotating-disc, gaspath, and cavity heat-transfer correlations; calibrate against rig and engine test data.
• Apply thermal boundary conditions to axisymmetric structural models to predict rotor stack, casing stack separation margin, radial fits, and critical radial / axial clearance closure across transients for critical flow area and rub margin assessment.
• Perform component structural margin, bolted-joint, and interference-fit assessments using 2D and 3D ANSYS, and feed results to life assessment (LCF / HCF / creep).
• Synthesize thermal and structural analysis results into actionable operability guidance, informing and negotiating system-level ConOps trades that balances hardware reliability and life against mission performance objectives.
• Collaborate across disciplines — design, aero / CFD, secondary flow, rotordynamics, materials, and test — to anchor analysis assumptions and resolve complex hardware issues.
• Develop and maintain analysis-driven design requirements and documentation; contribute technical artifacts to subsystem and program gated reviews (SRR, PDR, CDR, MRR, TRR).

Benefits

• Medical, dental, vision, basic and supplemental life insurance, paid parental leave, short and long-term disability, 401(k) with a company match of up to 5%, and an Education Support Program.
• Stock Options for all regular employees (working at least 20 hours/week)
• Paid Time Off: Up to four (4) weeks per year based on weekly scheduled hours, and up to 14 company-paid holidays.