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Mechanism of enhanced impulse and entrainment of a pulsed jet through a flexible nozzle

Published online by Cambridge University Press:  25 September 2024

Daehyun Choi
Affiliation:
Department of Mechanical Engineering, Seoul National University, Seoul 08826, Korea
Hyungmin Park*
Affiliation:
Department of Mechanical Engineering, Seoul National University, Seoul 08826, Korea Institute of Advanced Machines and Design, Seoul National University, Seoul 08826, Korea
*
Email address for correspondence: hminpark@snu.ac.kr

Abstract

The present experimental study shows that a nozzle with optimal flexibility can enhance the impulse and entrainment of a pulsed jet. Near the nozzle exit, vortex rings emanating from the flexible nozzle move faster because of the timely release of the elastic energy (stored during the expansion) to the jet, which is maximized at the structural stiffness that needs to be optimally tuned to the jet acceleration. The total circulation, hydrodynamic impulse and entrained fluid volume are enhanced substantially. Interestingly, we find that the same condition for optimal flexibility to maximize the hydrodynamic impulse and circulation of the primary vortex ring of the continuous jet (Choi & Park, J. Fluid Mech., vol. 949, 2022, A39) holds universally for the pulsed jet, indicating that abrupt jet termination is irrelevant to the impulse augmentation mechanism. Compared to the rigid counterpart, increments of the impulse (${\sim }400\,\%$) and entrainment (${\sim }220\,\%$) of a pulsed jet in the present study are considerably larger than those ($200\,\%$ and $50\,\%$, respectively) in a continuous jet from previous studies, which is attributed to the significant suppression of negative pressure at the nozzle exit by the collapsing motion of the flexible nozzle in the phase with the jet-driven upstream propagation of the surface wave on the nozzle. This universal mechanism provides a guideline for a novel jet propulsor using a flexible nozzle, for example, for small-scale underwater robots.

Information

Type
JFM Papers
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press.
Figure 0

Figure 1. (a) Schematic for the jet flow facility. (b) Installation set-up of the flexible nozzle. (c) Image processing procedure for obtaining the sub-pixel location of the nozzle. (d) Three histories of the centreline jet velocity at the nozzle exit, depending on an effective acceleration time ($\varPi _{0}=v_{m,r}T_{acc}/L$).

Figure 1

Figure 2. (a) Variation in the shape deformation of the most flexible nozzle ($Eh = 7.0\ {\rm N}\ {\rm m}^{-1}$) in time ($t^{*} = t/T_{acc}$), corresponding to $\varPi _{0} = 0.57$. (be) Temporal variations in the jet velocity vector at the centre of the nozzle exit ($x = y = 0$) depending on nozzle stiffness ($Eh$): (b) $Eh = \infty$ (rigid); (c) $Eh=43.2\ {\rm N}\ {\rm m}^{-1}$; (d) $Eh=14.4\ {\rm N}\ {\rm m}^{-1}$; (e) $Eh=7.0\ {\rm N}\ {\rm m}^{-1}$. The colour denotes the time.

Figure 2

Figure 3. (a,b) Evolution of the vorticity ($\hat {\omega } = \omega D/v_{m,r}$) contour and velocity vectors in a pulsed jet with the fastest acceleration ($\varPi _{0} = 0.48$) for (a) rigid and (b) flexible ($Eh = 14.4\ {\rm N}\ {\rm m}^{-1}$) nozzles. (ce) Temporal variation of: (c) the centreline velocity ($\hat {v}_{e} = v_{e}/v_{m,r}$) at the nozzle exit ($y = 0$) normalized with the maximum value for the rigid nozzle ($v_{m,r}$); (d) normalized total circulation ($\hat {\varGamma }=\varGamma /(v_{m,r}D)$); (e) normalized total jet volume ($\hat {V}=V/V_p$), where $V_p$ represents the displaced volume by piston. The dimensionless time is defined as $t^{*} = t/T_{acc}$.

Figure 3

Figure 4. Variation of (a) hydrodynamic impulse ($\hat {I}_{h} = I_{h}/(v_{m,r}D^{3})$) at $t^{*} = 4.0$, (b) maximum centreline velocity ($\hat {v}_{m} = v_{m}/v_{m,r}$), (c) total circulation ($\hat {\varGamma }=\varGamma / (v_{m,r}D)$) at $t^{*} = 4.0$, and (d) total jet volume ($\hat {V} = V/V_{p}$) at $t^{*} = 20.0$, depending on $\varPi _0$ and $Eh$. The shaded symbols in (a) correspond to cases used to further examine the nozzle deformation in figure 5.

Figure 4

Figure 5. (a) Schematic of nozzle displacement ($w_{n,r}$ for $x > 0$, and $w_{n,l}$ for $x < 0$) perpendicular to the original surface in the cross-sectional ($x$$y$) plane. (b,d,f) Overlay of nozzle edge profiles ($\hat {w}_n$) at various $t^*$, and (c,e,g) spatio-temporal variation of the nozzle deformation ($\hat {w}_n$) depending on $Eh$ and $\varPi _0$. Here, (b,c) $(Eh, \varPi _0) = (14.4\ {\rm N}\ {\rm m}^{-1}, 0.64)$, (d,e) ($7.0, 0.48$), (f,g) ($14.4, 0.57$). The normalized nozzle deformation is defined as $\hat {w}_n = 0.5(w_{n,r}+w_{n,l})/w_{n,m}$, in which the maximum value ($w_{n,m}$) is $0.016D$, $0.153D$ and $0.038D$ for (b,c), (d,e), and (f,g), respectively. In (b,d,f), the variation of $\hat {w}_n$ along the $y$-direction is shown at both sides for visualization.

Figure 5

Figure 6. Variation in (a) $I_h$ and (b) $V$ passing through $y/D = -1.0$ with $\hat {c}$: circle, $Eh = 7.0\ {\rm N}\ {\rm m}^{-1}$; triangle, $14.4\ {\rm N}\ {\rm m}^{-1}$; and square, $43.2\ {\rm N}\ {\rm m}^{-1}$. Closed and open symbols correspond to the pulsed jet (present study) and continuous jet (Choi & Park 2022), respectively, and $I_h$ and $V$ are normalized with values for the rigid nozzle.

Figure 6

Figure 7. Contours of the vertical flow velocity ($\hat {v}=v/v_{m,r}$) and velocity vectors for (a) rigid and (b) flexible ($Eh = 7.0\ {\rm N}\ {\rm m}^{-1}$) nozzles at the same jet condition $\varPi _{0} = 0.57$.

Figure 7

Figure 8. (a,b) Instantaneous jet flow (velocity vectors and vorticity $\hat {\omega } = \omega D/v_{m,r}$ contour) of (a) rigid and (b) flexible ($Eh = 14.4\ {\rm N} {\rm m}^{-1}$) nozzles, depending on the formation number ($F$), measured at $t^{*} = 3.6$. (c) Time history of the jet-exit velocity ($v_e$), depending on $F$. The data were taken at $y/D = -0.2$. (d) Hydrodynamic impulse from the flexible nozzle, depending on $F$. Here, $I_h$ was measured at $t^{*} = 4$ and normalized by the value of the rigid nozzle ($I_{h,rigid}$).

Supplementary material: File

Choi and Park supplementary movie 1

Evolution of vorticity (ω̂ = ωD/vm,r) contour and velocity vectors in a pulsed jet with the fastest acceleration (П0 = 0.48).
Download Choi and Park supplementary movie 1(File)
File 9.6 MB
Supplementary material: File

Choi and Park supplementary movie 2

Behavior of flexible nozzles responding to pulsed jets (same case with figure 4).
Download Choi and Park supplementary movie 2(File)
File 4.2 MB
Supplementary material: File

Choi and Park supplementary movie 3

Evolution of jet flow (velocity vectors and vorticity (ω̂ = ωD/ut) contour) of (a) the rigid and (b) flexible nozzle (Eh = 14.4 N/m) depending on the formation number (F).
Download Choi and Park supplementary movie 3(File)
File 2.5 MB