Experimental Investigations of Leading Edge Bluntness in Shock Boundary Layer Interactions at Hypersonic Speeds

Lakshman, Srinath

January 2015

Shock Boundary Layer Interactions (SBLIs) and shock-shock interactions are some of the most fundamental problems in high speed aerodynamics. These interactions are of particular importance in scramjet intakes at hypersonic speeds. In hypersonic own with strong SBLI accompanied by own separation, large separation bubbles can form due to high impinging shock strengths. While experiments involving large separation lengths for the impinging shock boundary layer interactions near sharp leading edge are well documented in the literature, only few investigations on the effect of leading edge bluntness on the interactions are studied. In the present study, experiments were carried out to study the role of leading edge bluntness on the impinging shock boundary layer interactions. An oblique shock generated by a wedge (wedge angle 31 degrees) is made to impinge on a at plate (length 200 mm) over which a boundary layer develops. Different leading edge inserts were used on a at plate to get either a sharp or a blunt (radii from 2 to 8 mm) leading edge. The position of the at plate was moved horizontally with respect to the wedge to vary the shock impingement location relative to the leading edge. Experiments were carried out at two freestream conditions - Mach 5.88 (total enthalpy of 1.26 MJ/kg and freestream Reynolds number of 3.85 million per meter) and Mach 8.54 (total enthalpy of 1.85 MJ/kg and freestream Reynolds number of 1.41 million per meter). The various features of the interaction along with different parameters were obtained from schlieren visualizations and surface pressure measurements. The schlieren visualization was used to obtain the separation length, while the reattachment pressure was obtained from the surface pressure distribution. From the present experimental study, a reduction in separation length was observed with an increase in leading edge bluntness. It was also seen that the sharp leading edge had the maximum separation length. Correlations for the separation length and the reattachment pressure have been proposed for these experimental conditions. Numerical simulations were also carried out using commercial software and they had a qualitative agreement with the experiments.

Hypersonic Speeds

Shock Boundary Layers

Shock Boundary Layer Interaction

Hypersonic Shock Tunnel 2 (HST2)

Schlieren Visualisations

Shock-shock Interactions

Shock Polars

Free Interaction Theory

Aerospace Engineering

Design And Development Of Diaphragmless Hypersonic Shock Tunnel

Hariharan, M S

11 1900

The growing requirements to achieve hypersonic flights, as in the case of reentry vehicles, pose a serious challenge to the designers. This demands an understanding of the features of hypersonic flow and its effect on hypersonic vehicles. Hypersonic shock tunnels are one of the most widely used facilities for the purpose of obtaining valuable design data by conducting experiments on scaled down models. They are operated by conventional shock tubes by rupturing metal diaphragms placed between the driver and driven sections of the shock tube. Shock tunnels are being extensively used in spite of some of the drawbacks they possess. Due to the varying nature of metal diaphragm rupture, reproducibility of the experiment results is difficult to obtain. Damage to model and inner surface of the shock tube can happen when the diaphragm petal breaks away from the diaphragm. Lastly the time consuming diaphragm replacement process is not desired in applications which require quick loading of shock waves on the specimen. All these disadvantages call for the replacement of the diaphragm mode of operation with a diaphragmless mode of operation for the generation of shock waves. The main objective of the present study is to design and demonstrate the working of a diaphragmless hypersonic shock tunnel. The motivation for the present study comes from the fact that the diaphragmless operation of a shock tunnel has not been reported so far in the open literature. All the research works carried out deal with diaphragmless drivers operating only a shock tube. In the present work, the conventional metal diaphragm is substituted by fast acting pneumatic valves which serve the purpose of quickly opening the driven section of the shock tube to allow the driver gas to rush in, resulting in the formation of a shock wave. To design a diaphragmless driver, a detailed study of the shock formation process is accomplished which helps in understanding the effect of valve opening time on the shock formation distance. Also the theoretical basis for the design of a pneumatic cylinder is understood. Following the theoretical studies, three types of diaphragmless drivers are designed and tested. The first setup incorporates a rubber membrane, which acts as a valve. The rubber membrane when bulged closes the mouth of the driven section and on retraction the driven section is opened to the driver gas. The second and the third setups utilise two different types of double acting pneumatic cylinders. Experimental results of the three diaphragmless drivers operating a shock tube are analysed and compared with the ideal shock tube theory. Better repeatability in terms of shock Mach number is shown with all three diaphragmless shock tubes when compared with a conventionally operated shock tube. Finally, the best among the three systems is identified to operate the hypersonic shock tunnel 2 (HST2) facility of the Shock Waves laboratory, IISc. Demonstration of the working of the diaphragmless shock tunnel is shown by performing heat transfer measurements on a 3 mm backward facing step flat plate model. The experimental results are compared with those obtained in a conventional shock tunnel. CFD studies on diaphragmless shock tube model are done to have an idea on the flow in the shock tube there by identifying the shock formation distance. ANSYS-CFX package is used for this purpose. Further, results from the numerical simulation of hypersonic flow over the backward facing step model are compared with the experimental results thus validating the code.

Hypersonic Shock Tunnels

Hypersonic Flow

Shock Tubes

Diaphragmless Shock Tube Drivers

Diaphragmless Shock Tunnel

Shock Waves

Shock (Aerospace Engineering)

Hypersonic Shock Tunnel 2 (HST2)

Diaphragmless Shock Wave Generators

Aeronautics

Experimental Studies on Shock-Shock Interactions in Hypersonic Shock Tunnels

Khatta, Abhishek

January 2016

Shock-shock interactions are among the most basic gas-dynamic problem, and are almost unavoidable in any high speed light, where shock waves generating from different sources crosses each other paths. These interactions when present very close to the solid surface lead to very high pressure and thermal loads on the surface. The related practical problem is that experienced at the cowl lip of a scramjet engine, where the interfering shock waves leads to high heat transfer rates which may also lead to the damage of the material. The classification by Edney (1968) on the shock-shock interaction patterns based on the visualization has since then served the basis for such studies. Though the problem of high heating on the surface in the vicinity of the shock-shock interactions has been studied at length at supersonic Mach numbers, the study on the topic at the hypersonic Mach numbers is little sparse. Even in the studies at hypersonic Mach numbers, the high speeds are not simulated, which is the measure of the kinetic energy of the ow. Very few experimental studies have addressed this problem by simulating the energy content of the ow. Also, some of the numerical studies on the shock-shock interactions suggest the presence of unsteadiness in the shock-shock interaction patterns as observed by Edney (1968), though this observation is not made very clearly in the experimental studies undertaken so far. In the present study, experiments are carried out in a conventional shock tunnel at Mach number of 5.62 (total enthalpy of 1.07 MJ/kg; freestream velocity of 1361 m/s), with the objective of mapping the surface pressure distribution and surface convective heat transfer rate distribution on the hemispherical body in the presence of the shock-shock interactions. A shock generator which is basically a wedge of angle = 25 , is placed at some dis-dance in front of the hemispherical body such that the planar oblique shock wave from the shock generator hits the bow shock wave in front of the hemi-spherical body. The relative distance between the wedge tip and the nose of the hemispherical body is allowed to change in di erent experiments to capture the whole realm of shock-shock interaction by making the planar oblique shock wave interact with the bow shock wave at different locations along its trajectory. The study results in a bulk of data for the surface pressure and heat transfer rates which were obtained by placing 5 kulites pressure transducers, 1 PCB pressure transducer and 21 platinum thin lm gauges along the surface of the hemispherical body in a plane normal to the freestream velocity direction. Along with the measurement of the surface pressure and the surface heat transfer rates, the schlieren visualization is carried out to capture the shock waves, expansion fans, slip lines, present in a certain shock-shock interaction pattern and the measured values were correlated with the captured schlieren images to evaluate the ow build up and steady and useful test time thereby helping in understanding the ow physics in the presence of the shock-shock interactions. From the present study it has been observed that in the presence of Edney Type-I and Edney Type-II interaction, the heat transfer rates on the hemi-spherical body are symmetrical about the centerline of the body, with the peak heating at the centerline which drops towards the shoulder. For Edney Type-III, Edney Type-IV, Edney Type-V and Edney Type-VI interaction pattern, the distribution in not symmetrical and shifts in peak heat transfer rates being on the side of the hemispherical from which planar oblique shock wave is incident. Also, it is observed that for the interactions which appear within the sonic circle, Edney Type-III and Edney Type-IV, the heat transfer rates observe an unsteadiness, such that the gauges located close to the interaction region experiencing varying heat transfer rates during the useful test time of the shock tunnel. Few experiments were conducted at Mach 8.36 (total enthalpy of 1.29 MJ/kg; freestream velocity of 1555.25 m/s) and Mach 10.14 (total enthalpy of 2.67 MJ/kg; freestream velocity of 2258.51 m/s) for the con gurations representing Edney Type-III interaction pattern to further evaluate the unsteady nature observed at Mach 5.62 ows. The unsteadiness was evident in both the cases. It is realized that the short test times in the shock tunnels pose a constraint in the study of unsteady flow fields, and the use of tailored mode operation of shock tunnel can alleviate this constraint. Also, limited number of experiments in the present study, which are carried out in a Free Piston Shock Tunnel, helps to understand the need to conduct such study in high enthalpy test conditions.

Hypersonic Shock Tunnels

Shock Waves

Shock-Shock Interaction

Shock Wave Dynamics

Hypersonic Aerodynamics

Hypersonic Flows

High Speed Flows

Shock Tubes

Shock Tunnels

Bow Shock Wave

Hypersonic Shock Tunnel-2

HST2

Piston Shock Tunnel

Aerospace Engineering