Menatap masa depan, teknologi ingot titanium sedang mengalami evolusi besar menuju kecerdasan, ramah lingkungan, dan kemampuan ekstrem. Kecerdasan tercermin dalam pembangunan proses penuh digital twin dan sistem pengambilan keputusan yang cerdas.
By integrating IoT sensing, multi physics numerical simulation, and big data analysis, virtual production and optimization of the entire process from melting, solidification to heat treatment can be achieved, and predictive control of internal structure and defects of ingots can be carried out, moving from "experience driven" to "data and model driven". The core of greenization is to develop efficient and high-value residual titanium recovery and recycling technologies. Through advanced processes such as EBCHM, high-value titanium shavings and waste generated during the processing are 100% recycled, producing high-end ingots with performance no different from raw materials. This is crucial for reducing costs and achieving sustainable development of the industry chain. Extreme manufacturing responds to major national demands, aiming to manufacture ingots and components with larger dimensions (single weight>50 ton), performa lebih tinggi (seperti ketangguhan ultra-tinggi, suhu ultra-tinggi), dan bentuk yang lebih kompleks (mendekati bentuk jaring). Ini bukan hanya persaingan kemampuan peralatan, tetapi juga tantangan besar bagi disiplin ilmu dasar seperti ilmu material, metalurgi, fisika, dan kimia. Masa depan industri titanium Tiongkok terletak pada apakah mereka dapat mencapai inovasi sistematis dan orisinal melalui ketiga jalur tersebut, sehingga mencapai lompatan bersejarah dari "kepemimpinan skala" menjadi "kepemimpinan teknologi".
