5,425 research outputs found
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Modelling installed jet noise due to the scattering of jet instability waves by swept wings
Jet noise is a significant contributor to aircraft noise, and on modern aircraft it is considerably enhanced at low frequencies by a closely installed wing. Recent research has shown that this noise increase is due to the scattering of jet instability waves by the trailing edge of the wing. Experimentalists have recently shown that noise can be reduced by using wings with swept trailing edges. To understand this mechanism, in this paper, we develop an analytical model to predict the installed jet noise due to the scattering of instability waves by a swept wing. The model is based on the Schwarzschild method and Amiet’s approach is used to obtain the far-field sound. The model can correctly predict both the reduction in installed jet noise and the change to directivity patterns observed in experiments due to the use of swept wings. The agreement between the model and experiment is very good, especially for the directivity at large azimuthal angles. It is found that the principal physical mechanism of sound reduction is due to destructive interference. It is concluded that in order to obtain an effective noise reduction, both the span and the sweep angle of the wing have to be large. Such a model can greatly aid in the design of quieter swept wings and the physical mechanism identified can provide significant insight into developing other innovative noise-reduction strategies.</jats:p
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Temporal stability analysis of jets of lobed geometry
A 2D temporal incompressible stability analysis is carried out for lobed
jets. The jet base flow is assumed to be parallel and of a vortex-sheet type.
The eigenfunctions of this simplified stability problem are expanded using the
eigenfunctions of a round jet. The original problem is then formulated as an
innovative matrix eigenvalue problem, which can be solved in a very robust and
efficient manner. The results show that the lobed geometry changes both the
convection velocity and temporal growth rate of the instability waves. However,
different modes are affected differently. In particular, mode 0 is not
sensitive to the geometry changes, while modes of higher-orders can be changed
significantly. The changes become more pronounced as the number of lobes N and
the penetration ratio increase. Moreover, the lobed geometry can
cause a previously degenerate eigenvalue () to become
non-degenerate () and lead to opposite changes to
the stability characteristics of the corresponding symmetric (n) and
antisymmetric (-n) modes. It is also shown that each eigen-mode changes its
shape in response to the lobes of the vortex sheet, and the degeneracy of an
eigenvalue occurs when the vortex sheet has more symmetric planes than the
corresponding mode shape (including both symmetric and antisymmetric planes).
The new approach developed in this paper can be used to study the stability
characteristics of jets of other arbitrary geometries in a robust and efficient
manner.Cambridge Commonwealth European and International Trust and the China
Scholarship Counci
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An experimental study of the effects of lobed nozzles on installed jet noise
Abstract
Jet noise remains a significant aircraft noise contributor, and for modern high-bypass-ratio aero-engines the strong interaction between the jet and aircraft wing leads to intensified installed jet noise. An experiment is carried out in this paper to study the effects of lobed nozzles on installed jet noise. It is found that the lobed nozzles, compared to round nozzles, have similar effects on installed jet noise for all the plate positions and Mach numbers tested. On the shielded side of the plate, the use of lobed nozzles leads to a noise reduction in the intermediate- and high-frequency regimes, which is thought to be due to a combination of enhanced jet mixing and more effective shielding effects by the flat plate. On the reflected side of the plate, noise reduction is only achieved in the intermediate frequency range; the little noise reduction or a slight noise increase observed in the high-frequency regime is likely due to enhanced jet mixing. On both sides of the plates, little noise reduction is achieved for the low-frequency noise due to the scattering of jet instability waves. This is likely to be caused by the fact that lobed nozzles cause negligible change to the dominant mode 0 (axisymmetric) jet instability waves. That the jet mean flow quickly becomes axisymmetric downstream of the jet exit could also play a role.
Graphic abstract
The first author (B. Lyu) wishes to gratefully acknowledge the financial support provided by the Cambridge Trust and China Scholarship Council
On tuning a reactive silencer by varying the position of an internal membrane
A mode-matching method is used to investigate the performance of a two-dimensional, modified reactive silencer. The modification takes the form of a membrane which is attached to the internal walls of the expansion chamber parallel to the axis of the inlet/outlet ducts. The height of the membrane above the level of the inlet/outlet ducts can be varied and, by this means, the device is tuned. It is shown that the stopband produced by the silencer can be broadened and/or shifted depending upon the height to which the membrane is raised. Attention is focused on the efficiency of the device at low-frequencies - the regime where dissipative silencers are usually least effective. The potential use of the device as a component in a hybrid silencer for heating ventilation and air-conditioning (HVAC) ducting systems is discussed
On the connection between quantum nonlocality and phase sensitivity of two-mode entangled Fock state superpositions
In two-mode interferometry, for a given total photon number , entangled
Fock state superpositions of the form have been considered for phase
estimation. Indeed all such states are maximally mode-entangled and violate a
Clauser-Horne-Shimony-Holt (CHSH) inequality. However, they differ in their
optimal phase estimation capabilities as given by their quantum Fisher
informations. The quantum Fisher information is the largest for the
state and
decreases for the other states with decreasing photon number difference between
the two modes. We ask the question whether for any particular Clauser-Horne
(CH) (or CHSH) inequality, the maximal values of the CH (or the CHSH)
functional for the states of the above type follow the same trend as their
quantum Fisher informations, while also violating the classical bound whenever
the states are capable of sub-shot-noise phase estimation, so that the
violation can be used to quantify sub-shot-noise sensitivity. We explore CH and
CHSH inequalities in a homodyne setup. Our results show that the amount of
violation in those nonlocality tests may not be used to quantify sub-shot-noise
sensitivity of the above states.Comment: Published online in Quantum Information Processin
Problems in the Surgical Management of Crohn's Disease of the Colon
Differences in the natural history of ulcerative colitis and colonic Crohn's disease which influence the choice and type of surgical treatment are discussed. The progressive nature of Crohn's disease is stressed. Drugs employed in the medical management of the disease are described with particular attention being drawn to their importance during surgical treatment. The indications for surgical treatment are outlined. Important complications of the disease, which we have encountered, are described. The types of surgical treatment employed in 35 patients with Crohn's disease of the colon treated during the last 2% years are presented with some details of the operative technique we have found to be important. No patient has died and the results have been good
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Prediction of installed jet noise
A semianalytical model for installed jet noise is proposed in this paper. We argue and conclude that there exist two distinct sound source mechanisms for installed jet noise, and the model is therefore composed of two parts to account for these different sound source mechanisms. Lighthill’s acoustic analogy and a fourth-order space–time correlation model for the Lighthill stress tensor are used to model the sound induced by the equivalent turbulent quadrupole sources, while the trailing-edge scattering of near-field evanescent instability waves is modelled using Amiet’s approach. A non-zero ambient mean flow is taken into account. It is found that, when the rigid surface is not so close to the jet as to affect the turbulent flow field, the trailing-edge scattering of near-field evanescent waves dominates the low-frequency amplification of installed jet noise in the far-field. The high-frequency noise enhancement on the reflected side is due to the surface reflection effect. The model agrees well with experimental results at different observer angles, apart from deviations caused by the mean-flow refraction effect at high frequencies at low observer angles.The first author (B.L.) wishes to gratefully acknowledge the financial support co-funded by the Cambridge Commonwealth European and International Trust and the China Scholarship Council. The third author (I.N.) wishes to acknowledge the UK Turbulence Consortium (UKTC) for the high-performance computing time to carry out the LES simulation on ARCHER under EPSRC grant no. EP/L000261/1 and under a PRACE award on HERMIT
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