Apptronik is a human-centered robotics company developing AI-powered robots to support humanity in every facet of life. Our flagship humanoid robot, Apollo, is built to collaborate thoughtfully with people, starting with critical industries such as manufacturing and logistics, with future applications in healthcare, the home, and beyond. We operate at the cutting edge of embodied AI, applying our expertise across the full robotics stack to solve some of society's most important problems. You will join a team dedicated to bringing Apollo to market at scale, tackling the complex challenges like safety, commercialization, and mass production to change the world for the better.
JOB SUMMARY
We are seeking a Staff Mechanical Engineer to lead the structural design and architecture of a next-generation robotic hand for a humanoid platform. This role goes beyond traditional end effectors—focusing on highly dexterous, human-like manipulation in unstructured environments.
As the technical lead for hand structures, you will define and drive the mechanical design of complex, multi-DOF systems that must balance strength, compliance, weight, and tactile interaction. You will work at the intersection of biomechanics, precision engineering, and robotics to create a hand capable of robust, versatile, and safe interaction with the world.
ESSENTIAL DUTIES AND RESPONSIBILITIES or KEY ACCOUNTABILITIES
- Own the robotic hand structural architecture Define the mechanical architecture of a multi-fingered humanoid hand, including finger topology, joints, palm structure, and load paths, balancing dexterity, strength, and weight.
- Lead design of fingers and joints Develop robust, multi-DOF mechanisms with appropriate joint types, ensuring durability under off-axis loads, impacts, and real-world use.
- Co-design with actuation systems Partner with actuation team on tendon-driven or remote actuation designs, including cable routing, transmission efficiency, and wear reduction.
- Engineer for contact-rich, human-like interaction Design for grasping, pinching, sliding, and tool use, balancing compliance and stiffness for both precision and safe interaction.
- Drive structural analysis and durability Own FEA and validation for stress, fatigue, and impact. Design for high cycle life and address failure modes like wear, loosening, and material fatigue.
- Enable compact, integrated designs Build high-density mechanical systems that integrate actuation, sensing, and wiring within tight space constraints.
- Lead prototyping and iteration Rapidly prototype, test, and refine designs based on hands-on evaluation and system-level feedback.
- Own manufacturability and scale-up Drive DFM/DFA, process selection, tolerancing, and supplier collaboration to ensure production-ready designs.
- Collaborate cross-functionally Work closely with controls, perception, electrical, and software teams to deliver a cohes