Chemical & Process Industries
Transform Your Business with SimPhysx
In the dynamic realm of Chemical & Process Industries, precision, safety, and efficiency are paramount. We offer a deep reservoir of expertise to help organizations navigate complex regulatory landscapes, optimize production processes, and implement cutting-edge technologies. We work closely with our clients to refine operational workflows, enhance product quality, and achieve sustainable practices that meet both current demands and future challenges. Drawing from a history of successful collaborations and transformative projects, our tailored solutions are designed to drive innovation, reduce costs, and improve overall process reliability. Whether you are looking to streamline operations or embark on groundbreaking new initiatives, we are committed to guiding you through every phase of your journey towards excellence in this highly competitive industry.
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Past Projects & Collaborations
TUBITAK 1003 - DESIGN OF A SOLUTION BLOWING SYSTEM FOR INDUSTRIAL-SCALE NANOFIBER PRODUCTION - Completed (2021)
The project focuses on developing an efficient system for large-scale nanofiber fabrication. The study involved extensive nozzle flow simulations under various pressure conditions, exploring multiple nozzle types to identify the most suitable design. A comprehensive optimization study was conducted on four geometric parameters of the selected nozzle type, aimed at enhancing system performance. The optimized parameters were validated through CFD simulations, confirming their effectiveness as new dimensions for the nozzle design, thereby ensuring optimal functionality for industrial-scale applications.
RECUPERATIVE BURNER SIMULATIONS IN A TEST FURNACE FOR THERMAL FORMING PURPOSES
In this project, we conducted detailed recuperative burner simulations within a test furnace specifically designed for thermal forming purposes. Our analysis focused on optimizing burner performance and ensuring uniform temperature distribution while keeping the emission levels lower, and minimizing the waste heat by regaining it using recuperative design, key factors in achieving high-quality thermal forming results at minimal costs. By leveraging advanced simulation techniques, we were able to identify critical process parameters and potential areas for efficiency improvements. The insights gained from this study not only enhance operational performance but also contribute to energy savings and improved process reliability.
INVESTIGATING THE EFFECT OF AIR PRESSURE ON NOVEL NANOFIBER PRODUCTION TECHNIQUE: SOLUTION BLOWING
In this study, the effect of air pressure on fiber diameter was investigated for solution blowing as fiber production technique. For that purpose, computational fluid dynamics (CFD) analysis was applied via Ansys software. The results from the CFD analysis were further compared with experimental tests. Additionally, the nozzle design was discussed for further improvement of the fiber production method.
