Smart Metallurgy: The Impact of Industry 4.0 on Materials Processing and Innovation
Abstract
This paper analyses the revolutionary effect of Industry 4.0 technologies on materials processing and innovation in the metallurgical industry. It extensively analyses how this new industrial revolution, defined by the widespread interconnection of digital systems, is systematically re-designing conventional processes into smart, networked and highly efficient systems. The study highlights the function of enabling technologies such as Internet of Things (IoT), Artificial Intelligence (AI) and Machine Learning (ML), Cyber-Physical Systems (CPS), Additive Manufacturing (AM) and Big Data analytics, revealing their cumulative ability to enhance energy efficiency, resource allocation, quality control, and predictive maintenance along the whole metallurgical value chain. While recognizing the industry’s current mid-term period of digital adoption, this analysis highlights how Industry 4.0 is already providing dramatic gains in efficiency, productivity, and sustainability, critically meeting both challenges of digitalization and decarbonization. Practical implementation highlighted includes real-time process monitoring, creation of digital twin prototypes for simulation, and the enablement of very high customization of manufacture. Theoretically, this research enriches the heavy industry discourse on digitalization by outlining technological adoption and industry-maturity interaction and discussing the novel concept of the “metallurgical Internet of Things” (m-IoT) of a globally networked, resourceefficient materials world.
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References
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