MUMBAI, India, June 22 -- Intellectual Property India has published a patent application (202621050260 A) filed by Er. Shubham Prakash Temkar; Ms. Pushpa Prakash Temkar; Prof. Dr. B. K Sarkar; and Prof Dr. Reena Singh on April 20, 2026, for Universal Material Conversion And Recycling Technology.
Inventors include Er. Shubham Prakash Temkar; Ms. Pushpa Prakash Temkar; Prof. Dr. B. K Sarkar; and Prof Dr. Reena Singh.
The application for the patent was published on June 12, 2026, under issue no. 24/2026.
Abstract: ABSTRACT [505] The advanced universal material conversion system introduces an innovative waste-to-resource transformation framework for comprehensive material processing that integrates multi-phase conversion protocols with adaptive material characterization mechanisms, facilitating real-time waste analysis, dynamic material optimization, and robust resource recovery while maintaining seamless industrial integration and operational accuracy for consistent material utilization applications. [510] The comprehensive material processing framework employs adaptive conversion algorithms and intuitive waste transformation protocols, utilizing embedded processing arrays and energy-efficient conversion systems to ensure timely material identification, enhanced resource understanding, and optimal utilization reliability while maintaining continuous waste monitoring capabilities. [515] The integrated methodology combines multi-dimensional material analysis techniques with conversion-driven pattern recognition systems, leveraging variable-precision waste signals and multi-factor material indicators to optimize transformation procedures and utilization workflows for maximum resource accuracy and minimal waste uncertainty during critical industrial applications. [520] The novel responsive material architecture features engineered high-precision conversion components with specialized waste fingerprinting protocols, enabling complex multi-stage material verification while ensuring conversion consistency and performance optimization across various industrial instruments without compromising system reliability. [525] The innovative design incorporates strategic validation mechanisms for enhanced material identification and environmental security, utilizing optimized multi-function systems and adaptive conversion technology to ensure legitimate material assignment while maintaining functionality across diverse industrial environments and processing scenarios. [530] Implementation methodology emphasizes scalable material integration and efficient conversion sequences, implementing interactive monitoring measures and pattern recognition algorithms to achieve superior waste determination, enhanced material identification, and environmental pollution prevention while ensuring technological simplicity during industrial monitoring. [535] The system demonstrates exceptional adaptability through comprehensive integration of material identification protocols and intelligent conversion technologies, validating its effectiveness across various multifunctional industrial configurations and processing scenarios while maintaining consistent material performance and operational efficiency under diverse conditions. [540] The developed framework enables sustainable and reliable conversion of waste materials through streamlined, technology-powered processing systems, providing significant advantages over traditional material approaches through variable validation mechanisms, adaptive identification protocols, and improved resource assignment while maintaining superior conversion accuracy during critical industrial material procedures.
Disclaimer: Curated by HT Syndication.
