Changda Li
About Changda Li
Changda Li is a 仿真应用开发工程师 at ExxonMobil in 上海, specializing in simulation methods for tire air tightness and structural optimization.
Current Role at ExxonMobil
Changda Li serves as a 仿真应用开发工程师 (Simulation Application Development Engineer) at ExxonMobil. His role involves the development and optimization of simulation methods, specifically focused on enhancing product design and structural integrity. He has been with ExxonMobil in 上海 (Shanghai) since 2016.
Educational Background
Changda Li holds a Master of Science (理学硕士) in Mechanical Engineering from Northwestern University, where he studied from 2013 to 2015. He also earned a Bachelor of Engineering (工学学士) in Mechanical Engineering and Automation from Nanjing Tech University, completing his studies there from 2009 to 2013. His education has provided a solid foundation in mechanical engineering principles and simulation techniques.
Simulation Method Development for Tire Air Tightness
Changda Li has developed a simulation method aimed at optimizing tire air tightness. This method allows for improvements in the structural design of tires, ensuring better performance and reliability. His approach employs advanced simulation techniques to provide practical and efficient solutions for the tire industry.
Integration of X-ray Tomography with Finite Element Simulation
Changda Li has integrated X-ray tomography with finite element simulation to enhance the microstructural analysis in polymer material development. This integration allows for a more detailed and accurate representation of material properties, benefiting the development and optimization of new polymer materials.
Optimization of Drop Test Simulation for Home Appliances
Changda Li has optimized the drop test simulation process for home appliances. His efforts have led to the enhancement of structural impact strength without the need to increase weight or alter materials. This optimization is crucial in ensuring the durability and reliability of household products while maintaining efficiency in design and material use.