Raindrop Breakup in the Shock Layer of a High-speed Vehicle

Waldman, G. D.; Reinecke, W. G.; Glenn, Donald C.

doi:10.2514/3.50350

Cited by 45 publications

(9 citation statements)

References 4 publications

(3 reference statements)

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“…We frame this discussion in terms of questions-one of them was posed by one of the referees; the others naturally arose in a detailed consideration of past work, especially of some little-known reports of works summarized by Waldman et al 13 Why was multiwave piercing, which is readily discerned in shadowgraphs, not found in previous experiments? Past work was conducted at atmospheric pressure, so that the required range of We for RTP could only be accessed in a subsonic flow.…”

Section: Discussionmentioning

confidence: 98%

“…Waldman 26 (summarized but with omission of significant details by Waldman et al 13 ) and of Simpkins The corresponding We for these tests were 10 6 , 2.5 ϫ 10 5 , and 8 ϫ 10 4 , respectively, and the "early," "intermediate," and "late" timings of the catastrophic event correspond to T values of 1.5, 1.7, and 2.6 ͑21, 50, and 145 s͒, respec- tively. The suggestion, as noted already, found experimental ͑based on shadowgraphs͒ and theoretical support from Simpkins and Bales 12 and Harper et al, 11 respectively, which were both published in the same time frame.…”

Section: How Can the Experimental Observations Of Reinecke Andmentioning

confidence: 99%

“…In the discussion ͑Sec. IV͒, we elaborate on the experimental work of Simpkins and Bales 12 and that of Waldman et al, 13 which were carried out at conditions that reached shock Mach numbers of 11, and make the case for an experimental revisit.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

On the physics of aerobreakup

2008

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By using laser-induced fluorescence to visualize liquid drops that are suddenly exposed to supersonic gas streams, we show that the previously available experimental results, which are based on the shadowgraph method, allowed misinterpretations that have lead to inappropriate conceptualizations (and theory) of the physics that govern breakup at high Weber numbers (We>103)—instead of the Rayleigh–Taylor piercing, the dominant mechanism is shear-induced motion with a significant radial component and instabilities on the so-generated, stretched liquid sheet. At low Weber numbers (We<102), the new data reveal the quantitative features of multiwave piercing by Rayleigh–Taylor instabilities. The highly resolved images provide uniquely suitable benchmarks for direct numerical simulations of interfacial instabilities in general and of drop breakup in particular.

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Section: Discussionmentioning

confidence: 98%

Section: How Can the Experimental Observations Of Reinecke Andmentioning

confidence: 99%

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On the physics of aerobreakup

2008

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“…발표된 Adler and Mihora [1] 의 해석 기법에서는 물방 울의 변형 계산을 위해 Ranger and Nicholls 때문에 정확한 물방울의 형상을 관측하기 어렵다 [7] . [8] 가 도출한 경험적 모 델을 Wierzba and Takayama [7] 의 실험 결과에 맞게 아 래와 같이 수정하여 적용하였다. 나기 때문이다 [8,9] .…”

Section: 물방울의 이동unclassified

Empirical Analysis Research on Waterdrop's Deformation by Shock Wave

Hong¹,

Yeom²,

Moon³

2016

Journal of the Korea Institute of Military Science and Technolo

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In this research, theoretical study on empirical analysis method to estimate waterdrop's deformation by shock wave is presented. Flow field is calculated using theoretical and empirical relations. Waterdrop's deformation including movement, size, mass, and orientation is modeled using empirical relations derived from existing experimental data. Developed method is applied to specific flight examples with arbitrary flight speed and vehicle's configuration. The flight speed is assumed to Mach number of 2 and 4. The diameter of waterdrop is varied from 1 to 5 mm. Waterdrops along the stagnation line in front of hemispherical nose with the radius of 50 mm and around a cone-shaped side wall with the half angle of 20 degree are considered. It is found that the maximum diameter of the waterdrop is increased up to 2.77 times the initial diameter. The mass is conserved more than 66.7 %. In the case of a cone-shaped side wall, waterdrop's orientation angles defined from the flight direction when the Mach number is 2 and 4 are calculated as 33.0 and 25.6 degree, respectively.

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“…The time it takes a droplet to completely lose its mass via stripping is given by equatIons (2) and (6) .…”

Section: Effect Of Mach Number On Strippingmentioning

confidence: 99%