Asymptotic stability and transient growth in pulsatile Poiseuille flow through a compliant channel
The time-asymptotic linear stability of pulsatile flow in a channel with compliant walls is studied together with the evaluation of modal transient growth within the pulsation period of the basic flow as well as non-modal transient growth. Both one (vertical-displacement) and two (vertical and axial...
| Main Authors: | , |
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| Format: | Journal Article |
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Cambridge University Press
2017
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| Online Access: | http://hdl.handle.net/20.500.11937/54533 |
| _version_ | 1848759395290185728 |
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| author | Tsigklifis, Konstantinos Lucey, Anthony |
| author_facet | Tsigklifis, Konstantinos Lucey, Anthony |
| author_sort | Tsigklifis, Konstantinos |
| building | Curtin Institutional Repository |
| collection | Online Access |
| description | The time-asymptotic linear stability of pulsatile flow in a channel with compliant walls is studied together with the evaluation of modal transient growth within the pulsation period of the basic flow as well as non-modal transient growth. Both one (vertical-displacement) and two (vertical and axial) degrees-of-freedom compliant-wall models are implemented. Two approaches are developed to study the dynamics of the coupled fluid-structure system, the first being a Floquet analysis in which disturbances are decomposed into a product of exponential growth and a sum of harmonics, while the second is a time-stepping technique for the evolution of the fundamental solution (monodromy) matrix. A parametric study of stability in the non-dimensional parameter space, principally defined by Reynolds number , Womersley number and amplitude of the applied pressure modulation , is then conducted for compliant walls of fixed geometric and material properties. The flow through a rigid channel is shown to be destabilized by pulsation for low , stabilized due to Stokes-layer effects at intermediate , while the critical approaches the steady Poiseuille-flow result at high , and that these effects are made more pronounced by increasing . Wall flexibility is shown to be stabilizing throughout the range but, for the relatively stiff wall used, is more effective at high . Axial displacements are shown to have negligible effect on the results based upon only vertical deformation of the compliant wall. The effect of structural damping in the compliant-wall dynamics is destabilizing, thereby suggesting that the dominant inflectional (Rayleigh) instability is of the Class A (negative-energy) type. It is shown that very high levels of modal transient growth can occur at low , and this mechanism could therefore be more important than asymptotic amplification in causing transition to turbulent flow for two-dimensional disturbances. Wall flexibility is shown to ameliorate mildly this phenomenon. As is increased, modal transient growth becomes progressively less important and the non-modal mechanism can cause similar levels of transient growth. We also show that oblique waves having non-zero transverse wavenumbers are stable to higher values of critical than their two-dimensional counterparts. Finally, we identify an additional instability branch at high that corresponds to wall-based travelling-wave flutter. We show that this is stabilized by the inclusion of structural damping, thereby confirming that it is of the Class B (positive-energy) instability type. |
| first_indexed | 2025-11-14T09:59:12Z |
| format | Journal Article |
| id | curtin-20.500.11937-54533 |
| institution | Curtin University Malaysia |
| institution_category | Local University |
| last_indexed | 2025-11-14T09:59:12Z |
| publishDate | 2017 |
| publisher | Cambridge University Press |
| recordtype | eprints |
| repository_type | Digital Repository |
| spelling | curtin-20.500.11937-545332019-02-19T05:36:26Z Asymptotic stability and transient growth in pulsatile Poiseuille flow through a compliant channel Tsigklifis, Konstantinos Lucey, Anthony The time-asymptotic linear stability of pulsatile flow in a channel with compliant walls is studied together with the evaluation of modal transient growth within the pulsation period of the basic flow as well as non-modal transient growth. Both one (vertical-displacement) and two (vertical and axial) degrees-of-freedom compliant-wall models are implemented. Two approaches are developed to study the dynamics of the coupled fluid-structure system, the first being a Floquet analysis in which disturbances are decomposed into a product of exponential growth and a sum of harmonics, while the second is a time-stepping technique for the evolution of the fundamental solution (monodromy) matrix. A parametric study of stability in the non-dimensional parameter space, principally defined by Reynolds number , Womersley number and amplitude of the applied pressure modulation , is then conducted for compliant walls of fixed geometric and material properties. The flow through a rigid channel is shown to be destabilized by pulsation for low , stabilized due to Stokes-layer effects at intermediate , while the critical approaches the steady Poiseuille-flow result at high , and that these effects are made more pronounced by increasing . Wall flexibility is shown to be stabilizing throughout the range but, for the relatively stiff wall used, is more effective at high . Axial displacements are shown to have negligible effect on the results based upon only vertical deformation of the compliant wall. The effect of structural damping in the compliant-wall dynamics is destabilizing, thereby suggesting that the dominant inflectional (Rayleigh) instability is of the Class A (negative-energy) type. It is shown that very high levels of modal transient growth can occur at low , and this mechanism could therefore be more important than asymptotic amplification in causing transition to turbulent flow for two-dimensional disturbances. Wall flexibility is shown to ameliorate mildly this phenomenon. As is increased, modal transient growth becomes progressively less important and the non-modal mechanism can cause similar levels of transient growth. We also show that oblique waves having non-zero transverse wavenumbers are stable to higher values of critical than their two-dimensional counterparts. Finally, we identify an additional instability branch at high that corresponds to wall-based travelling-wave flutter. We show that this is stabilized by the inclusion of structural damping, thereby confirming that it is of the Class B (positive-energy) instability type. 2017 Journal Article http://hdl.handle.net/20.500.11937/54533 10.1017/jfm.2017.163 Cambridge University Press fulltext |
| spellingShingle | Tsigklifis, Konstantinos Lucey, Anthony Asymptotic stability and transient growth in pulsatile Poiseuille flow through a compliant channel |
| title | Asymptotic stability and transient growth in pulsatile Poiseuille flow through a compliant channel |
| title_full | Asymptotic stability and transient growth in pulsatile Poiseuille flow through a compliant channel |
| title_fullStr | Asymptotic stability and transient growth in pulsatile Poiseuille flow through a compliant channel |
| title_full_unstemmed | Asymptotic stability and transient growth in pulsatile Poiseuille flow through a compliant channel |
| title_short | Asymptotic stability and transient growth in pulsatile Poiseuille flow through a compliant channel |
| title_sort | asymptotic stability and transient growth in pulsatile poiseuille flow through a compliant channel |
| url | http://hdl.handle.net/20.500.11937/54533 |