Abstract
Squids in nature generate pulsed jet to be able to move by expelling high pressure water through funnel in a short period of time. In this study, unsteady jet flow of squids was investigated during its fast swimming phase. Numerical model has been generated from a real squid’s computer tomography images. 2D axisymmetric jet flow has been simulated by using dynamic mesh to mimic the motion of squid’s mantle cavity wall. Specifically, diameter of the squid’s mantle cavity decreases from 13 cm to 4 cm and a periodic sine velocity profile has been defined for squid’s mantle cavity wall. Besides, the funnel of squid seems to be a 3 cm long nozzle which has about 3 cm and 0.5 cm diameters at the inlet and outlet, respectively. Physical behaviors of jet flow has been investigated to be able to calculate change of ejected fluid’s momentum and flow energy in this study
Keywords
References
- Anderson, E. J., Grosenbaugh, M. A., 2005. Jet Flow in
- Steady Adult Squid. The Journal of Experimental Biology, 208, 1125-1146.
- Bartol, L. K., Krueger, P. S., 2009. Hydrodynamics of pulsed jetting in juvenile and adult brief squid
- Lolliguncula brevis: evidence of multiple jet ‘modes’ and their implications for propulsive efficiency. The Journal of Experimental Biology, Vol. 376212, 1889- 190
- Bera,J. C., Michard, M., Grosjien, N., Comte-Bellot, G., 200 Flow analysis of two-dimensional pulsed jets by particle image velocimetry. Experiments in Fluids, 31, 519-532 00E+06 Reynolds number 0.002 0.00E+00 00E+05 00E+06 50E+06 00E+06 50E+06 00E+06 Reynolds number
Abstract
Squids in nature generate pulsed jet to be able to move by expelling high pressure water through funnel in a short period of time. In this study, unsteady jet flow of squids was investigated during its fast swimming phase. Numerical model has been generated from a real squid's computer tomography images. 2D axisymmetric jet flow has been simulated by using dynamic mesh to mimic the motion of squid's mantle cavity wall. Specifically, diameter of the squid's mantle cavity decreases from 13 cm to 4 cm and a periodic sine velocity profile has been defined for squid's mantle cavity wall. Besides, the funnel of squid seems to be a 3 cm long nozzle which has about 3 cm and 0.5 cm diameters at the inlet and outlet, respectively. Physical behaviors of jet flow has been investigated to be able to calculate change of ejected fluid's momentum and flow energy in this study
Keywords
References
- Anderson, E. J., Grosenbaugh, M. A., 2005. Jet Flow in
- Steady Adult Squid. The Journal of Experimental Biology, 208, 1125-1146.
- Bartol, L. K., Krueger, P. S., 2009. Hydrodynamics of pulsed jetting in juvenile and adult brief squid
- Lolliguncula brevis: evidence of multiple jet ‘modes’ and their implications for propulsive efficiency. The Journal of Experimental Biology, Vol. 376212, 1889- 190
- Bera,J. C., Michard, M., Grosjien, N., Comte-Bellot, G., 200 Flow analysis of two-dimensional pulsed jets by particle image velocimetry. Experiments in Fluids, 31, 519-532 00E+06 Reynolds number 0.002 0.00E+00 00E+05 00E+06 50E+06 00E+06 50E+06 00E+06 Reynolds number
Details
| Primary Language | English |
|---|---|
| Subjects | Engineering |
| Journal Section | SI: BioMechanics2014 |
| Authors | |
| Publication Date | December 30, 2014 |
| Submission Date | January 2, 2015 |
| Published in Issue | Year 2014 Volume: 2 Issue: 3 |
