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Dynamic transition from Mach to regular reflection of shock waves in a steady flow

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dc.contributor.author Naidoo, Kavendra
dc.contributor.author Skews, BW
dc.date.accessioned 2014-12-03T07:03:37Z
dc.date.available 2014-12-03T07:03:37Z
dc.date.issued 2014-07
dc.identifier.citation Naidoo, K and Skews, B.W. 2014. Dynamic transition from Mach to regular reflection of shock waves in a steady flow. Journal of Fluid Mechanics, vol. 750, pp 385-400 en_US
dc.identifier.issn 0022-1120
dc.identifier.uri http://journals.cambridge.org/download.php?file=%2FFLM%2FFLM750%2FS0022112014002882a.pdf&code=5f5e5c3ffa340f9391f4e05f6aebbcf2
dc.identifier.uri http://hdl.handle.net/10204/7806
dc.description Copyright: 2014 Cambridge University Press. This is an ABSTRACT ONLY. The definitive version is published in Journal of Fluid Mechanics, vol. 750, pp 385-400 en_US
dc.description.abstract The steady, two-dimensional transition criteria between regular and Mach reflection are well established. Little has been done on the dynamic effect on transition due to a rapidly rotating wedge. Results from experiments and computations done on steady and unsteady shock wave transition from Mach reflection to regular reflection, MR RR, are described. The measured motion and the initial shock incidence was used to mimic the experiment with a two-dimensional numerical code. The maximum rotation speed achieved at transition was approximately 2500°s(sup-1). Rapid wedge rotation was shown to have a significant measurable effect on transition. The code was also applied to the dependence of dynamic MR RR transition on other variables in the parameter space. These include rotation about the leading or trailing edge, initial incidence and rotation speed at two free-stream conditions. Impulsively started rotation in these cases was used with the rotation specified by M(subE)= c/a(sub8) where is constant angular velocity (negative anticlockwise), c the distance from the edge considered to the pivot point and a8 the free-stream sound speed. For the Mach numbers and range of rotation speeds tested, both the wedge and shock angle at transition decreased with increased rotation speed. The sensitivity of the transition angle to changing the rotation point from the trailing edge to the experimental model pivot point was investigated briefly at a free-stream Mach number of M=2.98 with M(subE)=-0.1. The wedge angle at transition increased by 1.5° and the shock angle at transition decreased by 1.5°, a significant variation. The effect of the initial incidence was also investigated. By reducing the initial wedge angle from 24.5 to 23.5° for these initial conditions the shock angle at transition decreased by approximately 1.8°, also a marked sensitivity. The flow field development for impulsive rotation about the wedge trailing and leading edges at M=1.93 for M(subE)=-0.075 was analysed in some detail. The flow field development is very sensitive to the rotation centre, more especially at large rotation rates. Four phases of the Mach stem development were identified in both cases. For rotation about the wedge leading edge the Mach stem height remains constant until the expansion waves arrive at the triple point. This is followed by an increase in Mach stem height, which then remains constant for a short period after which it decreases until transition to RR. For rotation about the wedge trailing edge the impulsive start generates a disturbance on the incident wave which propagates down the wave, through the triple point and down the Mach stem. The stem height is constant until the arrival of the incident wave disturbance. This causes a sudden decrease in Mach stem height. Subsequently, the Mach stem height remains constant for a short time, before it decreases until transition to RR. Similar effects in the variation of stem height with wedge angle occur at the higher Mach number of 2.98. It was demonstrated that MR can be maintained for a while at zero wedge incidence with a sufficiently large rotation rate of M(subE)=-0.1, with M=1.93, for both leading and trailing edge pivot points. en_US
dc.language.iso en en_US
dc.publisher Cambridge University Press (CUP) en_US
dc.relation.ispartofseries Workflow;13784
dc.subject Compressible flows en_US
dc.subject Gas dynamics en_US
dc.subject Shock waves en_US
dc.title Dynamic transition from Mach to regular reflection of shock waves in a steady flow en_US
dc.type Article en_US
dc.identifier.apacitation Naidoo, K., & Skews, B. (2014). Dynamic transition from Mach to regular reflection of shock waves in a steady flow. http://hdl.handle.net/10204/7806 en_ZA
dc.identifier.chicagocitation Naidoo, Kavendra, and BW Skews "Dynamic transition from Mach to regular reflection of shock waves in a steady flow." (2014) http://hdl.handle.net/10204/7806 en_ZA
dc.identifier.vancouvercitation Naidoo K, Skews B. Dynamic transition from Mach to regular reflection of shock waves in a steady flow. 2014; http://hdl.handle.net/10204/7806. en_ZA
dc.identifier.ris TY - Article AU - Naidoo, Kavendra AU - Skews, BW AB - The steady, two-dimensional transition criteria between regular and Mach reflection are well established. Little has been done on the dynamic effect on transition due to a rapidly rotating wedge. Results from experiments and computations done on steady and unsteady shock wave transition from Mach reflection to regular reflection, MR RR, are described. The measured motion and the initial shock incidence was used to mimic the experiment with a two-dimensional numerical code. The maximum rotation speed achieved at transition was approximately 2500°s(sup-1). Rapid wedge rotation was shown to have a significant measurable effect on transition. The code was also applied to the dependence of dynamic MR RR transition on other variables in the parameter space. These include rotation about the leading or trailing edge, initial incidence and rotation speed at two free-stream conditions. Impulsively started rotation in these cases was used with the rotation specified by M(subE)= c/a(sub8) where is constant angular velocity (negative anticlockwise), c the distance from the edge considered to the pivot point and a8 the free-stream sound speed. For the Mach numbers and range of rotation speeds tested, both the wedge and shock angle at transition decreased with increased rotation speed. The sensitivity of the transition angle to changing the rotation point from the trailing edge to the experimental model pivot point was investigated briefly at a free-stream Mach number of M=2.98 with M(subE)=-0.1. The wedge angle at transition increased by 1.5° and the shock angle at transition decreased by 1.5°, a significant variation. The effect of the initial incidence was also investigated. By reducing the initial wedge angle from 24.5 to 23.5° for these initial conditions the shock angle at transition decreased by approximately 1.8°, also a marked sensitivity. The flow field development for impulsive rotation about the wedge trailing and leading edges at M=1.93 for M(subE)=-0.075 was analysed in some detail. The flow field development is very sensitive to the rotation centre, more especially at large rotation rates. Four phases of the Mach stem development were identified in both cases. For rotation about the wedge leading edge the Mach stem height remains constant until the expansion waves arrive at the triple point. This is followed by an increase in Mach stem height, which then remains constant for a short period after which it decreases until transition to RR. For rotation about the wedge trailing edge the impulsive start generates a disturbance on the incident wave which propagates down the wave, through the triple point and down the Mach stem. The stem height is constant until the arrival of the incident wave disturbance. This causes a sudden decrease in Mach stem height. Subsequently, the Mach stem height remains constant for a short time, before it decreases until transition to RR. Similar effects in the variation of stem height with wedge angle occur at the higher Mach number of 2.98. It was demonstrated that MR can be maintained for a while at zero wedge incidence with a sufficiently large rotation rate of M(subE)=-0.1, with M=1.93, for both leading and trailing edge pivot points. DA - 2014-07 DB - ResearchSpace DP - CSIR KW - Compressible flows KW - Gas dynamics KW - Shock waves LK - https://researchspace.csir.co.za PY - 2014 SM - 0022-1120 T1 - Dynamic transition from Mach to regular reflection of shock waves in a steady flow TI - Dynamic transition from Mach to regular reflection of shock waves in a steady flow UR - http://hdl.handle.net/10204/7806 ER - en_ZA


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