9 research outputs found
Detailed spine modeling with LifeMOD™
10.1145/1592700.1592729ICREATE '09 - International Convention on Rehabilitation Engineering and Assistive Technology
Design and analysis of flexure-hinge parameter in microgripper
10.1007/s00170-009-2478-9International Journal of Advanced Manufacturing Technology499-121185-1193IJAT
Simulating dynamics of thoracolumbar spine derived from LifeMOD under haptic forces
World Academy of Science, Engineering and Technology64278-28
Development and validation of a discretised multi-body spine model in LifeMOD for biodynamic behaviour simulation
Computer Methods in Biomechanics and Biomedical Engineering182175-18
Development of a distributed collaborative design framework within peer-to-peer environment
10.1016/j.cad.2008.05.006CAD Computer Aided Design409891-904CAID
Collaborative fixture design and analysis using service oriented architecture
10.1109/TASE.2009.2038069IEEE Transactions on Automation Science and Engineering73617-62
Integrated fixture design and analysis system based on service-oriented architecture
4th IEEE Conference on Automation Science and Engineering, CASE 2008656-66
Analytical analysis of inclined three-layered composite channel with cobalt ferrite nanoparticles and Hall current in Darcy medium
The present study explores the influence of electromagnetic effects on the flow of a nanofluid in a saturated permeable medium, confined between a clear viscous fluid in an inclined channel. The nanofluid consists of cobalt ferrite nanoparticles dispersed in ethylene glycol. The governing equations are derived considering Darcy's law for the permeable medium and Tiwari's model for fluids containing nano-sized particles. Additionally, radiation and dissipation effects are incorporated into the energy equation. The equations are transformed into dimensionless form and solved analytically using the perturbation technique. The results are analyzed through graphs and tables for different material parameters. The findings reveal that higher electric and magnetic strengths have a significant impact on the fluid velocity at the interface of the two fluids, resulting in reduced shear both at the clear fluid surface and the interface between them. This highlights the crucial role played by electric and magnetic strengths in modifying flow phenomena. Consequently, combining electric and magnetic strengths with nanofluids can be utilized to achieve desired qualities in multi-fluid flow and enhance heat transfer characteristics