AMR Robots Accelerate Production Rhythm in Automotive Parts Manufacturing

 

Stable Production Rhythm in Automotive Parts Manufacturing

In the automotive parts manufacturing industry, production rhythm stability directly affects supply chain delivery performance. Factories typically handle a wide variety of components, frequent process changes, and dense work-in-progress flows.

In production models where assembly, sub-assembly, and inspection operate in parallel, material delivery between warehouses and production lines must be not only punctual but also flexible and traceable.

Logistics Bottlenecks During Capacity Expansion

During capacity expansion, an automotive parts factory in Guangdong found that manual material handling could no longer support increasing logistics demands. Frequent personnel movement, inefficient cross-floor transport, and slow response to urgent orders became key constraints on production rhythm.

To address these challenges, the factory introduced Reeman AMR transport robots from the Big Dog Series to systematically upgrade its internal logistics.

Optimized Design for Automotive Parts Material Handling

With a rated load capacity of 100 kg, Reeman Big Dog AMR robots are optimized for common automotive parts containers and turnover boxes. Their compact design enables flexible navigation through dense workstations and complex aisle layouts, supporting high-frequency material delivery between warehouses and multiple production lines.

Autonomous Navigation in Dynamic Factory Environments

Reeman AMR robots leverage autonomous navigation and intelligent obstacle avoidance to operate reliably in environments with mixed human-machine traffic and frequent tooling changes.

Even during peak production periods, the robots maintain stable performance, automatically avoiding personnel, forklifts, and temporary obstacles to ensure continuous and safe logistics operations.

Cross-Floor Delivery Through Elevator Integration

To support the factory’s multi-floor layout, Reeman AMR robots were deployed for cross-floor material delivery. The robots autonomously use elevators to transport materials between floors, creating direct point-to-point logistics links between the warehouse and different production lines.

This capability significantly reduces time consumption and management complexity associated with manual vertical transport.

On-Demand Material Delivery Aligned with Production Progress

Production lines can initiate delivery requests remotely through the system based on real-time production status. After receiving instructions, the robots automatically plan optimal routes, collect materials from the warehouse, and deliver them precisely to designated workstations.

This on-demand delivery model prevents material accumulation and shortages caused by fixed delivery schedules, ensuring logistics rhythm aligns closely with actual production needs.

Building a Flexible and Scalable Internal Logistics System

As multiple Reeman Big Dog AMR robots operate collaboratively, the factory’s internal logistics gradually form a standardized and scalable operating model. Warehouse-to-line coordination becomes smoother, manual intervention is reduced, and production rhythm stability continues to improve.

Through the deployment of Reeman AMR robots, the Guangdong automotive parts factory successfully established a flexible internal logistics system capable of supporting order fluctuations and product diversification, offering a practical reference for intelligent upgrades across the automotive manufacturing industry.

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