introduced. This elementary theory of the shock tube can be described by

a simplified scheme of the physical processes (the assumptions are listed

below). This simplified physical picture of the thermophysical processes in

a shock tube is as follows:

— after the forced rupture of the diaphragm (using a special technical

device), the driver gas in the high pressure chamber expands (compressing

the test gas) into the low pressure chamber filled with the test (driven) gas

under low pressure.

— in the low pressure chamber, a generated shock wave is propagating

in the test gas, and in the high pressure chamber a rarefaction wave is

propagating in the expanding driver gas;

— after the shock wave has reached the end of the pipe, it is reflected

and comes back towards the driver gas;

— then this reflected shock wave is interacting with the contact

discontinuity that separates the driver gas and the test gas, which results in

shock wave partial reflection (in the form of a shock wave or a rarefaction

wave (the criterion identifying these two cases is given below) and partial

refraction and moving (in the form of a shock wave) into the compressed

layer of the driver gas.

Here the following should be noted:

•

if the shock wave interacting with the contact discontinuity escapes

from a denser medium into the less dense one, it is reflected from the

contact discontinuity in the form of a rarefaction waves fan;

•

if the shock wave escapes from a less dense medium into the denser

one, it is reflected in the form of a shock wave.

The course of flow in the aerodynamic shock tube can be conveniently

represented in the form of the so-called

x

−

t

-diagram (Fig. 1). In

x

−

t

-

diagram, area

1

corresponds to the unperturbed initial state of the test

(driven or accelerated) gas, area

2

corresponds to the gas compressed in

the shock wave, areas

3

and

4

are the areas of gas “piston” and unperturbed

initial state of the gas in the high presure chamber before the rarefaction

wave arrival.

The surface denoted by К and separating (between areas

2

and

3

) the

test (driven or accelerated) gas and the driver (accelerating) gas is referred

to as a contact surface (CS) or interface. The gas pressures and the flow

velocities on either side of the CS are equal

(

p

2

=

p

3

, u

2

=

u

3

)

. In the

subsequent instant of time, the shock wave and the rarefaction wave are

reflected from the end walls of the shock tube and begin to interact with

each other.

Experimental and theoretical research into generation and propagation

of the shock waves, rarefaction waves and contact discontinuities in

ISSN 0236-3941. HERALD of the BMSTU. Series “Mechanical Engineering”. 2014. No. 1 5