Mechanics of Materials
Mechanics of materials is the cornerstone of engineering science, studying the behavior and properties of materials under force, heat and other physical influences. Whether in aerospace, automotive industry, or biomedical devices, understanding and optimizing material performance is essential to improving product safety, reliability and efficiency. Through our high-precision modeling and simulation services, customers can predict material performance, optimize design and reduce development costs. Our mission is to provide data-driven support for material research and engineering design, so that every product innovation is based on a solid scientific foundation.
Fig.1 Schematics of creating the multi-scale geometrical models of three textile structural composites. (Tao L, et al., 2019)
Our Services
- Material Performance Modeling and Simulation
Stress-strain analysis: Simulate the behavior of materials under loading conditions such as tension, compression, and shear, and predict the key points of deformation, yielding, and fracture.
Dynamic loading simulation: Study the performance of materials under impact, vibration, or other fast dynamic conditions, such as human fall protection equipment.
- Material Failure Analysis
Fatigue and fracture simulation: Analyze the crack propagation and final destruction of materials under cyclic loading to extend product life.
Corrosion and wear modeling: Simulate the impact of environmental factors on materials and design more durable material solutions.
- Microstructure Analysis and Optimization
Grain and microcrack modeling: Study the influence of the internal microstructure of the material on the overall performance through mesomechanical simulation.
Multi-scale modeling: Comprehensive prediction of mechanical properties from micro to macro to help optimize material formulation and process parameters.
- Material and Structure Collaborative Design
Lightweight structure optimization: Optimize the geometric structure to reduce weight and improve efficiency while maintaining material strength.
Biomaterial Simulation: Study the mechanical behavior of bone implants and simulate the interaction between materials and human tissue.
Advantages
High-precision tools
Use advanced tools such as finite element analysis (FEA) and molecular dynamics (MD) to ensure the reliability of simulation results.
Personalized Solutions
Tailor analysis strategies for specific materials, loading conditions and usage environments.
Interdisciplinary support
Combine materials science, engineering mechanics and biomechanics to provide comprehensive solutions for complex problems.
Result visualization
Provide intuitive 3D result display to help customers quickly understand the conclusions of simulation analysis.
Results Delivery
After completing the sports biomechanics modeling and simulation, we will provide comprehensive and easy-to-understand results delivery to ensure that users can make full use of the analysis results for optimization and decision-making.
At CD Biomodeling, material mechanics modeling services help customers accurately predict material properties, optimize design processes, and reduce subsequent experimental and R&D costs through personalized innovative solutions. Whether you want to develop high-performance materials, extend product life, or optimize structural design, we can provide you with professional support. If you want to know more about our service content or technical details, please feel free to contact us
Reference
- Tao Liu, et al. Comparisons of influence of random defects on the impact compressive behavior of three different textile structural composites. Materials & Design. 2019.
For Research Use Only!
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