With the rapid development of intelligent manufacturing and the digital economy, logistics robot technology, as a typical example
of the deep integration of new-generation information technology and the real economy, is profoundly transforming and reshaping the modern
logistics system. This paper focuses on the integrated application of logistics robot technology, exploring its key role in improving logistics efficiency, optimizing resource allocation, and promoting industrial intelligent transformation. It deeply analyzes how logistics robot technology
catalyzes and empowers new quality productive forces, uncovering its underlying mechanisms. New quality productive forces take scientific
and technological innovation as their core driving force, emphasizing the optimal allocation of factors and the leap in total factor productivity.
Through automated, intelligent, and collaborative operations, logistics robots effectively integrate production factors such as human resources,
equipment, and data, promoting the transformation of logistics systems from traditional labor-intensive to technology-, data-, and intelligencedriven models. Research findings show that the integration of logistics robot technology not only improves the operational efficiency of
warehousing, sorting, transportation, and other stages but also promotes overall supply chain collaboration and decision-making intelligence
through data closed loops and system integration, thereby catalyzing new production organization models and business models. Finally, this
paper proposes recommendations for promoting technical standard construction, strengthening cross-industry collaboration, and improving
policy support systems to accelerate the development of new quality productive forces empowered by logistics robot technology.

Logistics Robot; Technology Integration; New Quality Productive Forces; Intelligent Manufacturing; Automated Logistics

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