Computational Mechanics, Manufacturing Simulation, Design and Optimisation Group
The CoMManDO research group spans research interests in all forms of computational mechanics, including design, geometry representation, solid mechanics, fluid dynamics and multiphysics analysis software, CAD/CAM, manufacturing simulation, and design optimization and optimization methods.
Our research themes cover simulation and analysis, including fluid-structure interaction, fatigue and fracture mechanics, and system dynamics; and computational methods including algorithm development and application, computational intelligence and optimisation.
Members of the CoMManDO research group use the software packages Abaqus, Catia V5, Isight, Ansys and ANSYS FLUENT.
We apply our research to many industry sectors, from aerospace and bio-mechanics through to nuclear, rail and marine and offshore structures.
We also work closely with research partners at Monash University, University of Ulster, Moscow Bauman State Technical University, TU Dresden and Samara University.
Areas where CoMManDO has undertaken research recently include:
- Simulation of ultrasound NDT of composites with regions of damage.
- Modelling and simulation of corrosion and surface roughness effects on fatigue life.
- Optimization algorithm development applied to MEMS design.
- Volume of fluid modelling of viscous and non-Newtonian thin film flow.
We are currently working on research in the following areas: MEMS (Micro-Electro-Mechanical Systems), space and bio-medical design challenges.
Areas of continued interest are in:
- The application of evolutionary algorithms and surrogate models to mechanical engineering systems.
- Coupled fluid/solid/heat/electromagnetic analysis using co-simulation techniques.
- Analysis of novel structured material.
- Computational analysis of manufacturing and metrology processes.
- Computational geometry modelling.
Below are some of our recent research posters:
- Optimisation of an actuator with a tongue
- Modelling Contact and Tribology
- A Vision for Simulia: What analysis opportunities can be opened up by HPC capabi
Ali, K., et al. "Composite repairs to bridge steels demystified." Composite Structures (2016).
McMillan, A. J. and Holeczek, K., "Explicit Finite Element Modelling as a Development Tool for New Ultrasound Testing Methodologies for Detection and Characterization of Porosity and Defects in Composites," Materials Performance and Characterization, Vol. 5, No. 1, 2016, pp. 78-98.
Miah, Md Salim, et al. "Thin film flow on a vertically rotating disc of finite thickness partially immersed in a highly viscous liquid." Chemical Engineering Science 143 (2016): 226-239.
Ali, K., Peng, D., Jones, R., Singh, R. R. K., Zhao, X. L., McMillan, A. J., and Berto, F. (2016) Crack growth in a naturally corroded bridge steel. Fatigue Fract Engng Mater Struct, doi.
Bracken, C., et al. "Quasi-optical analysis of a far-infrared spatio-spectral space interferometer concept." Infrared Physics & Technology 77 (2016): 171-178.
C. Bracken ; C. O'Sullivan ; A. Donohoe ; A. Murphy ; G. Savini, et al.
"Optical and quasi-optical analysis of system components for a far-infrared space interferometer", Proc. SPIE 9362, Terahertz, RF, Millimeter, and Submillimeter-Wave Technology and Applications VIII, 93620N (March 14, 2015); doi:10.1117/12.2076385.
McMillan, Alison J. "Material strength knock-down resulting from multiple randomly positioned voids." Journal of Reinforced Plastics and Composites 31.1 (2012): 13-28.
McMillan, A. J., C. Monroy Aceves, and M. P. F. Sutcliffe. "Moderate energy impact analysis combining phenomenological contact law with localised damage and integral equation method." International Journal of Impact Engineering 43 (2012): 29-39.
Conference Proceedings edited by us
International Conference on Advanced Composites and Materials Technologies for Arduous Applications 2011 - 2015
Advanced Materials for Demanding Applications 2014
Professor Alison McMillan