Add to ORKGThe action of the hot and compressed propellant gas flow in the bore behind a projectile on heat transfer into the barrel wall is investigated by experimental and theoretical methods. For theoretical description of the in-bore flow development two interior ballistic models will be applied: a numerical model for solving the full Navier-Stokes equations, and an analytical boundary layer model using the boundary layer equations of Prandtl. For verification the results of both models describing the development of the compressible, turbulent boundary layer at the inner tube wall are compared with heat transfer measurements performed by means of thermocouples in the ISL 20-mm test gun
A single-stage gas gun driven by mixtures of H2, O2, and He or H2, O2, He, and CO has been used to s...
Experiments have been performed to assess the utility of unsteady one-dimensional heat con-duction m...
This paper focused on the 12.7 mm gun barrel stress response caused by the pressure of the gunpowder...
The results of numerical simulations of transient heat transfer in the barrel wall of a 35 mm calibe...
Understanding the heat transfer phenomenon during interior ballistics and consequently presenting a ...
The compressible, viscous, turbulent gas expansion flow behind an accelerating projectile moving in ...
The compressible, viscous, turbulent gas expansion flow behind an accelerating projectile moving in ...
Accurate determination of burning characteristics of the propellant and thermo-mechanical loads acti...
On the basis of the conjugate gradient method, an inversion model of the transient convective heat t...
A single stage gas gun driven by the combustion of hydrogen with oxygen has been used to produce rea...
The calculation of gas flow during the motion of a projectile in the gun barrel is a complicated com...
The compressible, viscous, turbulent gas expansion flow behind an accelerating projectile moving in ...
This paper presents a numerical and an analytical approach for calculation of internal ballistics pa...
In this study, an attempt to calculate the characteristics of gas flow around a projectile during th...
A uniformly heated hollow circular cylinder is instantaneously brought in contact with another holl...
A single-stage gas gun driven by mixtures of H2, O2, and He or H2, O2, He, and CO has been used to s...
Experiments have been performed to assess the utility of unsteady one-dimensional heat con-duction m...
This paper focused on the 12.7 mm gun barrel stress response caused by the pressure of the gunpowder...
The results of numerical simulations of transient heat transfer in the barrel wall of a 35 mm calibe...
Understanding the heat transfer phenomenon during interior ballistics and consequently presenting a ...
The compressible, viscous, turbulent gas expansion flow behind an accelerating projectile moving in ...
The compressible, viscous, turbulent gas expansion flow behind an accelerating projectile moving in ...
Accurate determination of burning characteristics of the propellant and thermo-mechanical loads acti...
On the basis of the conjugate gradient method, an inversion model of the transient convective heat t...
A single stage gas gun driven by the combustion of hydrogen with oxygen has been used to produce rea...
The calculation of gas flow during the motion of a projectile in the gun barrel is a complicated com...
The compressible, viscous, turbulent gas expansion flow behind an accelerating projectile moving in ...
This paper presents a numerical and an analytical approach for calculation of internal ballistics pa...
In this study, an attempt to calculate the characteristics of gas flow around a projectile during th...
A uniformly heated hollow circular cylinder is instantaneously brought in contact with another holl...
A single-stage gas gun driven by mixtures of H2, O2, and He or H2, O2, He, and CO has been used to s...
Experiments have been performed to assess the utility of unsteady one-dimensional heat con-duction m...
This paper focused on the 12.7 mm gun barrel stress response caused by the pressure of the gunpowder...