Explosion systems with inert high-modulus components : increasing the efficiency of blast technologies and their applications
Describes in one volume the data received during experiments on detonation in high explosive charges This book brings together, in one volume, information normally covered in a series of journal articles on high explosive detonation tests, so that developers can create new explosive technologies. It...
Saved in:
| Main Authors | , , |
|---|---|
| Format | Electronic eBook |
| Language | English |
| Published |
Hoboken, NJ :
Wiley,
2019.
|
| Subjects | |
| Online Access | Full text |
| ISBN | 9781119525424 111952542X 9781119525394 111952539X 9781119525448 (hardback) 9781119525462 1119525462 1119525446 |
| Physical Description | 1 online resource |
Cover
Table of Contents:
- Cover; Title Page; Copyright Page; Contents; Preface; Chapter 1 Examples of Nonstationary Propagation of Detonation in Real Processes; 1.1 Channel Effect; 1.2 Detonation of Elongated High Explosive Charges with Cavities; 1.3 The Effects of Wall and Shell Material, Having Sound Velocity Greater Than Detonation Velocity, on the Detonation Process; 1.4 Summary; References; Chapter 2 Phenomena in High Explosive Charges Containing Rod-Shaped Inert Elements; 2.1 "Smoothing" of Shock Waves in Silicon Carbide Rods; 2.1.1 Experiments with Ceramic Rods
- 2.1.2 Numerical Simulation of Shock Wave Propagation in Silicon Carbide Rods2.2 Desensitization of Heterogeneous High Explosives After Loading by Advanced Waves Passing Through Silicon Carbide Elements; 2.2.1 The Experiments on Detonation Transmission; 2.2.2 Modeling of the Detonation Transmission Process Under Initiating Through Inert Inserts; 2.3 The Phenomenon of Energy Focusing in Passive High Explosive Charges; 2.3.1 Characterization of Steel Specimens Deformed in Experiments on Energy Focusing; 2.3.2 Optical Recording in Streak Mode; 2.3.3 Optical Recording in Frame Mode
- 2.3.4 Numerical Modeling of the Energy Focusing Phenomenon2.4 Summary; References; Chapter 3 Nonstationary Detonation Processes at the Interface Between High Explosive and Inert Wall; 3.1 Measurements with Manganin Gauges; 3.2 Optical Recording in Streak Mode; 3.3 Modeling of Detonation in High Explosive Charges Contacting with Ceramic Plates; 3.4 Summary; References; Chapter 4 Peculiar Properties of the Processes in High Explosive Charges with Cylindrical Shells; 4.1 Nonstationary Detonation Processes in High Explosive Charges with Silicon Carbide Shells
- 4.2 Numerical Analysis of the Influence of Shells on the Detonation Process4.3 Summary; References; Chapter 5 Hypervelocity of Shaped Charge Jets; 5.1 Experimental Investigation of Ceramic Tube Collapse by Detonation Products; 5.2 Modeling of Jet Formation Process; 5.3 The Effect of Hypervelocity Jet Impact Against a Steel Target; 5.4 Modeling of Fast Jet Formation Under Explosion Collision of Two-Layer Alumina/Copper Tubes; 5.5 Summary; References; Chapter 6 Protective Structures Based on Ceramic Materials; 6.1 Detonation Transmission Through Dispersed Ceramic Media
- 6.2 Applications of the Protective Properties of Ceramic Materials6.3 Summary; References; Chapter 7 Structure of the Materials Loaded Using Explosion Systems with High-Modulus Components; 7.1 Materials Behavior at High Strain Rate Loading; 7.2 Postmortem Investigation of Materials Structure for Indirect Evaluation of Explosive Loading; 7.3 Structure of Materials Loaded Under Conditions of Energy Focusing; 7.4 Effect of High-Velocity Cumulative Jets on Structure of Metallic Substrates; 7.5 Summary; References; Conclusions; List of the Main Publications of Authors on the Theme of Monograph