The application of assembly robots (usually referring to modular truss robots or composite robotic
arm systems) in industrial production is primarily reflected in the following core scenarios and technical
advantages:
I. Core Application Areas
CNC Machine Tool Automation
Automated workpiece grasping, loading, positioning, clamping, flipping, and unloading, replacing manu
al repetitive operations. Suitable for production lines of machining centers, lathes, and other equipment.
Precise positioning (accuracy up to ±0.5mm) ensures consistent processing and significantly reduces
scrap rates.
Automotive Manufacturing
Handling heavy components (such as engine blocks), precisely installing modules such as seats and
doors, and supporting body welding and painting processes.
In engine block processing workshops, they can stably handle workpieces weighing hundreds of
kilograms and complete multiple process flows.
Precision Assembly of Electronic Products
Light-load truss robots are used for the placement of tiny components (such as mobile phone mother
board chips), ensuring high-precision assembly consistency.
Combined with vision systems, they perform product inspection and sorting on packaging lines,
improving product yield.
Intelligent Logistics and Warehousing
Perform high-speed picking, stacking, and sorting of goods in automated warehouses, optimizing
storage space utilization.
In e-commerce warehousing scenarios, automatically identify and deliver ordered goods to the sorting
line.
Metal Processing and Specialty Works
Automate the cutting, bending, and welding of sheet metal, adapting to high-temperature or high-risk
environments.
The explosion-proof design supports hazardous chemical handling in the chemical industry, and the
high-temperature-resistant coating is suitable for foundries (resistant to temperatures exceeding 300°C).
