Author: M. M. Oberai
Publisher:
ISBN:
Category : Reynolds number
Languages : en
Pages : 28
Book Description
Kinetic Theory Approach to the Study of a Curved Shock-wave
Author: M. M. Oberai
Publisher:
ISBN:
Category : Reynolds number
Languages : en
Pages : 28
Book Description
Publisher:
ISBN:
Category : Reynolds number
Languages : en
Pages : 28
Book Description
Shock-wave Structure Based in Ikenberry-Truesdell Approach to Kinetic Theory of Gases
Author: Robert E. Street
Publisher:
ISBN:
Category : Integro-differential equations
Languages : en
Pages : 64
Book Description
Publisher:
ISBN:
Category : Integro-differential equations
Languages : en
Pages : 64
Book Description
Shock-wave Structure Based on Ikenberry-Truesdell Approach to Kinetic Theory of Gases
Author: Robert E. Street
Publisher:
ISBN:
Category : Integro-differential equations
Languages : en
Pages : 68
Book Description
Publisher:
ISBN:
Category : Integro-differential equations
Languages : en
Pages : 68
Book Description
NASA Technical Note
A Kinetic Theory Approach to the Structure of Shock Waves in a Fully Ionied Gas
Author: Yun Chow Whang
Publisher:
ISBN:
Category : Shock waves
Languages : en
Pages : 152
Book Description
Publisher:
ISBN:
Category : Shock waves
Languages : en
Pages : 152
Book Description
Propagation of a Curved Shock and Nonlinear Ray Theory
Author: Prasad
Publisher: CRC Press
ISBN: 9780582072534
Category : Mathematics
Languages : en
Pages : 140
Book Description
Phoolan Prasad's book contains theoretical developments in the study of the propagation of a curved nonlinear wave front and shock front, particularly in the caustic region. It should be an invaluable reference source for researchers in nonlinear waves; fluid dynamics (especially gas dynamics); mathematical physics; aeronautical, chemical and mechanical engineering.
Publisher: CRC Press
ISBN: 9780582072534
Category : Mathematics
Languages : en
Pages : 140
Book Description
Phoolan Prasad's book contains theoretical developments in the study of the propagation of a curved nonlinear wave front and shock front, particularly in the caustic region. It should be an invaluable reference source for researchers in nonlinear waves; fluid dynamics (especially gas dynamics); mathematical physics; aeronautical, chemical and mechanical engineering.
NASA Scientific and Technical Reports
Author: United States. National Aeronautics and Space Administration Scientific and Technical Information Division
Publisher:
ISBN:
Category : Aeronautics
Languages : en
Pages : 1440
Book Description
Publisher:
ISBN:
Category : Aeronautics
Languages : en
Pages : 1440
Book Description
Shock Wave Structure in a Fully Ionized Gas Based on Multi-component Fluid Theory
Author: Huon Li
Publisher:
ISBN:
Category : Differential equations
Languages : en
Pages : 132
Book Description
The multi-component continuous approach for the investigation of the gasdynamics of a plasma is presented. More information about the flow properties of a plasma can be obtained than from the classical magnetohydrodynamic approach. Also, the resulting equations appear to be more easily solved than the Blotzmann equation of classical kinetic theory. The basic macroscopic conservation equations for a non-reacting multi-component plasma are presented. The fluid properties of each component are referred to the mean velocity of that component. Therefore, no limitations are placed on the magnitude of the diffusion velocities. The effects of electric and magnetic fields are included. The equations for a two-component mixture are used to study the structure of a shock wave in a fully-ionized hydrogen gas. It is assumed that the momentum exchange and energy exchange between the ions and electrons are important because of the strong Coulomb forces present. (Author).
Publisher:
ISBN:
Category : Differential equations
Languages : en
Pages : 132
Book Description
The multi-component continuous approach for the investigation of the gasdynamics of a plasma is presented. More information about the flow properties of a plasma can be obtained than from the classical magnetohydrodynamic approach. Also, the resulting equations appear to be more easily solved than the Blotzmann equation of classical kinetic theory. The basic macroscopic conservation equations for a non-reacting multi-component plasma are presented. The fluid properties of each component are referred to the mean velocity of that component. Therefore, no limitations are placed on the magnitude of the diffusion velocities. The effects of electric and magnetic fields are included. The equations for a two-component mixture are used to study the structure of a shock wave in a fully-ionized hydrogen gas. It is assumed that the momentum exchange and energy exchange between the ions and electrons are important because of the strong Coulomb forces present. (Author).
Shock Wave Science and Technology Reference Library, Vol. 3
Author: Yasuyuki Horie
Publisher: Springer Science & Business Media
ISBN: 3540770801
Category : Science
Languages : en
Pages : 294
Book Description
This book is the second volume of Solids Volumes in theShockWaveScience and Technology Reference Library. These volumes are primarily concerned with high-pressure shock waves in solid media, including detonation and hi- velocity impact and penetration events. This volume contains four articles. The ?rst two describe the reactive behavior of condensed-phase explosives, and the remaining two discuss the inert, mechanical response of solid materials. The articles are each se- contained, and can be read independently of each other. They o?er a timely reference, for beginners as well as professional scientists and engineers, cov- ing the foundations and the latest progress, and include burgeoning devel- ment as well as challenging unsolved problems. The ?rst chapter, by S. She?eld and R. Engelke, discusses the shock initiation and detonation phenomena of solids explosives. The article is an outgrowth of two previous review articles: “Explosives” in vol. 6 of En- clopedia of Applied Physics (VCH, 1993) and “Initiation and Propagation of Detonation in Condensed-Phase High Explosives” in High-Pressure Shock Compression of Solids III (Springer, 1998). This article is not only an - dated review, but also o?ers a concise heuristic introduction to shock waves and condensed-phase detonation. The authors emphasize the point that d- onation is not an uncontrollable, chaotic event, but that it is an orderly event that is governed by and is describable in terms of the conservation of mass, momentum, energy and certain material-speci?c properties of the explosive.
Publisher: Springer Science & Business Media
ISBN: 3540770801
Category : Science
Languages : en
Pages : 294
Book Description
This book is the second volume of Solids Volumes in theShockWaveScience and Technology Reference Library. These volumes are primarily concerned with high-pressure shock waves in solid media, including detonation and hi- velocity impact and penetration events. This volume contains four articles. The ?rst two describe the reactive behavior of condensed-phase explosives, and the remaining two discuss the inert, mechanical response of solid materials. The articles are each se- contained, and can be read independently of each other. They o?er a timely reference, for beginners as well as professional scientists and engineers, cov- ing the foundations and the latest progress, and include burgeoning devel- ment as well as challenging unsolved problems. The ?rst chapter, by S. She?eld and R. Engelke, discusses the shock initiation and detonation phenomena of solids explosives. The article is an outgrowth of two previous review articles: “Explosives” in vol. 6 of En- clopedia of Applied Physics (VCH, 1993) and “Initiation and Propagation of Detonation in Condensed-Phase High Explosives” in High-Pressure Shock Compression of Solids III (Springer, 1998). This article is not only an - dated review, but also o?ers a concise heuristic introduction to shock waves and condensed-phase detonation. The authors emphasize the point that d- onation is not an uncontrollable, chaotic event, but that it is an orderly event that is governed by and is describable in terms of the conservation of mass, momentum, energy and certain material-speci?c properties of the explosive.