Project: Research project (funded) › Research

- Prof Vladimir Vladimirov (Principal investigator)

There are two revolutionary results in this project:

1. For the very first time we have introduced a well-posed boundary conditions for a plane inviscid flow through a fixed domain, and investigated the broad classes of related flows. Qualitatively, new results include the trapping of vorticity and flows with self-oscillations (which is very unusual for inviscid flows).

The applications of the results are related to various practical situations when a fluid is coming to a flow domain through a part of its boundary, and leaving the domain from its other part.. The typical problem could be the ventilation of rooms.

2. The second result is really ground-braking: here we have introduced and adapted the Vishik-Lyusternik method to fluid dynamics. This method represents a powerful alternative to the Boundary Layer Theory (BLT) and to the Method of Matched Asymptotic Expansion (MMAE). Hence, almost all fluid dynamics of viscous fluid can be reconsidered with the use of this new method. The acceptance of such a revolutionary method by the academic community is not a easy process, most likely it will take tenths of years. This method could be broadly accepted after the majority of creators of the BLT and MMAE (which were intensely introduced manly in 60th and 70th) will retire.

1. For the very first time we have introduced a well-posed boundary conditions for a plane inviscid flow through a fixed domain, and investigated the broad classes of related flows. Qualitatively, new results include the trapping of vorticity and flows with self-oscillations (which is very unusual for inviscid flows).

The applications of the results are related to various practical situations when a fluid is coming to a flow domain through a part of its boundary, and leaving the domain from its other part.. The typical problem could be the ventilation of rooms.

2. The second result is really ground-braking: here we have introduced and adapted the Vishik-Lyusternik method to fluid dynamics. This method represents a powerful alternative to the Boundary Layer Theory (BLT) and to the Method of Matched Asymptotic Expansion (MMAE). Hence, almost all fluid dynamics of viscous fluid can be reconsidered with the use of this new method. The acceptance of such a revolutionary method by the academic community is not a easy process, most likely it will take tenths of years. This method could be broadly accepted after the majority of creators of the BLT and MMAE (which were intensely introduced manly in 60th and 70th) will retire.

Our main results are:

1. The perturbations of an inviscid flow in the form of point vortices are considered. It leads to the striking discovery of the trapping of a vortex: a point vortex can never leave a channel. Further asymptotic and numerical considerations show that the trapping also takes place for finite vortex patches, where only a part of vorticity can be trapped, while its other part leaves the domain. We believe that the trapping of vorticity represents a universal phenomenon for any outlet boundary conditions; it essentially determines the dynamics of vorticity in a gap. In particular, it makes the formation of recirculation zones or the self-oscillating flow regimes for the cases of large enough initial perturbations unavoidable.

2. The studies of smooth perturbations of an inviscid flow are performed with the use of Arnold’s functional. For two broad classes of flows they provide the decreasing of Arnold's functional that immediately leads to the general criterion of stability and to the nonlinear stability of these flows. Those results represent the generalizations of Rayleigh's inflection point theorem (and related stability theorems by Fjortoft and Arnold) on the channel flows with given inlet and outlet. Hence, they allow us to use Arnold’s stability theory for the essentially new classes of flows that are important in applications.

3. We have proven that for the finite smooth perturbations with small enstrophy (enstrophy=mean-square vorticity) the phenomenon of `washing-off' (i.e. the asymptotic stability) of a basic inviscid flow takes place. Here we have calculated the asymptotic stability threshold (more exactly—its low bound) with the non-dimensional enstrophy of perturbations of order 0.01. This step represents a keystone in our theory: it is the first known result of this kind and its value can be improved in future.

4. The high-Reynolds viscous flows in a duct (oscillating and non-oscillating) have been described with the use of the Vishik-Lyusternik method. The use of this powerful method leads to the global and uniformly valid solution in the whole flow domain. In particular, for steady flows it gives the complete description of the boundary layers at the inlet and outlet that are not accessible for the conventional boundary layer theory. Simultaneously it produces the flows outside the boundary layers. For the oscillating boundary conditions this procedure produces both vibrational boundary layers and the proper generalization of the steady streaming phenomena. An important advantage of our theory is: it does not produce any secular terms in a velocity field on the contrary to the known theory based on the conventional boundary layer equations. The inviscid oscillating flows are considered. Here we give the general theory of an inviscid oscillating flow through a duct including the derivation of the averaged equations of motion and their solutions. We have solved the generalized Bjorknes problem where a solid of arbitrary shape moves in the velocity field of a point source that possesses both constant and oscillating components.

5. We have developed and tested the effective numerical method for the description of the inviscid flows in a duct. It represents a version of the method of particles (or vortex method) adapted to the cases when material particles enter and leave the flow domain.

6. The decreasing of Arnold's functional allows us to establish the analogy with finite-dimensional dissipative systems. This analogy suggests that one can expect three qualitatively different scenarios (regimes) of the flow developments: (i) the evolution to a trivial equilibrium (i.e. the asymptotic stability or the `washing-off’ vorticity), (ii) the forming of steady structures (i.e. the trapping of vorticity with the forming of various recirculation zones), and (iii) self-oscillatory flows. We obtain several numerical solutions that explicitly show examples of all three listed scenarios.

1. The perturbations of an inviscid flow in the form of point vortices are considered. It leads to the striking discovery of the trapping of a vortex: a point vortex can never leave a channel. Further asymptotic and numerical considerations show that the trapping also takes place for finite vortex patches, where only a part of vorticity can be trapped, while its other part leaves the domain. We believe that the trapping of vorticity represents a universal phenomenon for any outlet boundary conditions; it essentially determines the dynamics of vorticity in a gap. In particular, it makes the formation of recirculation zones or the self-oscillating flow regimes for the cases of large enough initial perturbations unavoidable.

2. The studies of smooth perturbations of an inviscid flow are performed with the use of Arnold’s functional. For two broad classes of flows they provide the decreasing of Arnold's functional that immediately leads to the general criterion of stability and to the nonlinear stability of these flows. Those results represent the generalizations of Rayleigh's inflection point theorem (and related stability theorems by Fjortoft and Arnold) on the channel flows with given inlet and outlet. Hence, they allow us to use Arnold’s stability theory for the essentially new classes of flows that are important in applications.

3. We have proven that for the finite smooth perturbations with small enstrophy (enstrophy=mean-square vorticity) the phenomenon of `washing-off' (i.e. the asymptotic stability) of a basic inviscid flow takes place. Here we have calculated the asymptotic stability threshold (more exactly—its low bound) with the non-dimensional enstrophy of perturbations of order 0.01. This step represents a keystone in our theory: it is the first known result of this kind and its value can be improved in future.

4. The high-Reynolds viscous flows in a duct (oscillating and non-oscillating) have been described with the use of the Vishik-Lyusternik method. The use of this powerful method leads to the global and uniformly valid solution in the whole flow domain. In particular, for steady flows it gives the complete description of the boundary layers at the inlet and outlet that are not accessible for the conventional boundary layer theory. Simultaneously it produces the flows outside the boundary layers. For the oscillating boundary conditions this procedure produces both vibrational boundary layers and the proper generalization of the steady streaming phenomena. An important advantage of our theory is: it does not produce any secular terms in a velocity field on the contrary to the known theory based on the conventional boundary layer equations. The inviscid oscillating flows are considered. Here we give the general theory of an inviscid oscillating flow through a duct including the derivation of the averaged equations of motion and their solutions. We have solved the generalized Bjorknes problem where a solid of arbitrary shape moves in the velocity field of a point source that possesses both constant and oscillating components.

5. We have developed and tested the effective numerical method for the description of the inviscid flows in a duct. It represents a version of the method of particles (or vortex method) adapted to the cases when material particles enter and leave the flow domain.

6. The decreasing of Arnold's functional allows us to establish the analogy with finite-dimensional dissipative systems. This analogy suggests that one can expect three qualitatively different scenarios (regimes) of the flow developments: (i) the evolution to a trivial equilibrium (i.e. the asymptotic stability or the `washing-off’ vorticity), (ii) the forming of steady structures (i.e. the trapping of vorticity with the forming of various recirculation zones), and (iii) self-oscillatory flows. We obtain several numerical solutions that explicitly show examples of all three listed scenarios.

Status | Finished |
---|---|

Effective start/end date | 1/03/06 → 29/02/08 |

Links | http://gow.epsrc.ac.uk/ViewGrant.aspx?GrantRef=GR/S96616/02 |

EPSRC: £83,780.00

1/03/06 → 29/02/08

Award date: 16/09/05

Award: UK Research Councils › Award

- EPSRC: £83,780.00

## Viscous Flows in a Half Space Caused by Tangential Vibrations on Its Boundary

Research output: Contribution to journal › Article › peer-review

## Numerical study of an inviscid incompressible flow through a channel of finite length

Research output: Contribution to journal › Article › peer-review

## Planar inviscid flows in a channel of finite length: washout, trapping and self-oscillations of vorticity

Research output: Contribution to journal › Article › peer-review

## Viscous boundary layers in flows through a domain with permeable boundary

Research output: Contribution to journal › Article › peer-review

## Vibrational Frédericksz transition in liquid crystals

Research output: Contribution to journal › Article › peer-review

## On vibrodynamics of pendulum and submerged solid

Research output: Contribution to journal › Article › peer-review

## Asymptotic model for free surface flow of an electrically conducting fluid in a high-frequency magnetic field

Research output: Contribution to journal › Article › peer-review

## Dynamics of a Solid Affected by a Pulsating Point Source of Fluid.

Research output: Chapter in Book/Report/Conference proceeding › Chapter

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