Two New Humanoid Robots With 400 Nm Torque Joints Unveiled

⬤ BOSHIAC teamed up with Harbin Institute of Technology to launch two humanoid robots built for real-world industrial and service work. The lineup features a walking bipedal model designed to handle inspections and assistance in rough, unstructured terrain, plus a wheeled version optimized for indoor service tasks, precision work, and moving materials around. Both machines come with 7-DoF hybrid robotic arms that have full joint force control, giving them the ability to handle delicate manipulation with smooth, controlled movements.

⬤ These robots pack some serious mechanical muscle. They're built with custom cycloidal rotary joints delivering up to 400 Nm of torque and linear joints pushing 10,000 N of thrust. You can swap between two different dexterous hands depending on what the job needs: a high-performance 20-DoF model for complex tasks or a lighter 11-DoF version for simpler operations. This hardware setup gives the robots stable, precise movement and lets them interact accurately in demanding environments where flexibility and fine control really matter.

⬤ The brains behind the operation connect directly to Harbin Institute of Technology's Huozi-Rixin large language model. This system pulls together autonomous navigation, vision-based sensing, predictive control algorithms, whole-body coordination, and reinforcement learning to keep the robots moving intelligently through tricky situations. BOSHIAC brings over three decades of robotics experience across chemicals, metallurgy, logistics, food production, and construction materials to the table, with plans to slot these humanoid platforms straight into active industrial operations.

⬤ Rolling out these humanoid robots shows how quickly AI, precision robotics, and autonomous systems are coming together. These aren't lab prototypes anymore—they're machines designed to work in real facilities right now. The focus has clearly shifted toward building adaptable, AI-driven automation that can handle the messy, unpredictable conditions you actually find in working environments.