IR. DR. TAN CHIN JOO
Department of Mechanical Engineering
Faculty of Engineering
tancjum.edu.myView CV | |
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Biography | |
Tan Chin Joo is currently a Senior Lecturer in the Department of Mechanical Engineering, Faculty of Engineering, UM. He obtained both his Bachelor of Engineering degree and Master of Engineering Science degree from UM in year 1999 and 2003, respectively. He was a tutor in UM 1999 and later be promoted to a lecturer in 2003. In 2005, he was offered a scholarship by JICA for his doctoral study in Toyohashi University of Technology, Japan. After completing his study in 2008, he joined TOPY Industries Limited, Japan. After 3 years of working in TOPY (2 years in R&D Dept. and 1 year in Production Dept.), he returned to Malaysia and joined Universiti Tunku Abdul Rahman (UTAR). He joined UM in December, 2011. His research interests include stamping of lightweight parts, finite element analysis of metal forming processes, laser hardening, green forming processes, tube forming.
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Project Title | Progress | Status |
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Prediction Of Coil-break-free Uncoiling Conditions For Fully Annealed Low Carbon Steel Sheets Using Simulation Model |
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on going |
Correlation Among Mechanical Properties, Forming Conditions And Coil Break Defects During Uncoiling Process Of Fully Annealed Low Carbon Steel Sheets |
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on going |
Prevention Of Delayed Cracks In Deep Drawing Process Of Metastable Low-nickel Austenitic Stainless Steel Cups |
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This information is generated from Research Grant Management System |
Effect of meshing technique and time discretization size on thickness strain localization during hole-flanging simulation of DP980 sheet at high strain level
Weakening affinity of SUS304 asperities to die surface with TiN coating for preventing delayed cracks in deep-drawn cups
Estimating Forming Conditions for Deep Drawn SUS304 Square Cups Having no Delayed Cracks Using FE Simulation
Investigation of coil-break formation during uncoiling of fully annealed low carbon steel sheet using FE simulation
Estimating Forming Conditions for Deep Drawn SUS304 Square Cups Having no Delayed Cracks Using FE Simulation
Multi-Stage Stamping of Lightweight Steel Wheel Disks by Controlling its Wall Thickness Distribution