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Preface; Contents; About the Editors; Part IGas Gun; 1 Light Gas Gun; Abstract; 1 Introduction; 2 Requirements No. 1 and No. 2; 3 Requirement No. 3; 4 Requirement No. 4; 5 Requirement No. 5; 6 Requirement No. 6; 7 Requirement No. 7; 8 Use of the Light Gas Gun at the Ben-Gurion University; References; Part IIHypervelocity Test Facility; 2 Ballistic Range; 1 Introduction; 2 Working Principle of Hypervelocity Ballistic Range; 2.1 Two-Stage Light Gas Gun; 2.2 Test Chamber; 2.3 Measurement and Control System; 3 Representative Hypervelocity Ranges in the World; 3.1 AEDC Range G
3.2 HFFAF at NASA Ames Center3.3 Hypervelocity Ballistic Ranges at ARC-UAH [21
23]; 3.4 Hypervelocity Impact Ranges at NASA JSC [24]; 3.5 Hypervelocity Impact Ranges at EMI, Germany; 3.6 Hypervelocity Ballistic Range Complex of CARDC, China; 4 Application of a Hypervelocity Ballistic Range; 4.1 Hypervelocity Aerodynamics; 4.2 Hypervelocity Aerophysics; 4.3 Hypervelocity Impact; 5 Concluding Remarks; Acknowledgments; References; Part IIIShock Waves in Solids; 3 Experimental Methods of Shock Wave Research for Solids; 1 Introduction; 2 Hypervelocity Accelerators and High-Pressure Generation
3 Stress Wave in Solid4 Shock Equation of State; 5 Stability of Shock Wave; 6 Thermodynamics of Shock-Induced Phase Transition; 7 Shock Syntheses; 8 Laser Shock Experiments; 9 Concluding Remarks; References; Part IVRam Accelerator; 4 The Ram Accelerator: Review of Experimental Research Activities in the U.S.; Abstract; 1 Introduction; 2 Experimental Facilities and Results; 2.1 University of Washington (UW); 2.1.1 Operation at High Fill Pressures; 2.1.2 Baffled-Tube Ram Accelerator; 2.2 U.S. Army Research Laboratory (ARL); 2.3 UTRON, Inc; 3 Computational Modeling; 4 Future Work; 5 Conclusions
3 Smooth Bore Version3.1 RAMAC 30 Facility Set-Up; 3.2 Experimental Results; 3.3 Summary of the Smooth Bore Research; 4 Heating and Erosion of Ram-Projectiles; 4.1 Modeling of Surface Heating; 4.1.1 Computational Requirements; 4.1.2 Boundary Layer Solution; 4.1.3 Heat Conduction Solution; 4.2 Modeling of Melting Ablation; 4.2.1 Model Bases; 4.2.2 Ablation Model; 4.3 Model Applied to Smooth Bore Firings; 4.3.1 Surface Heating; 4.3.2 Surface Ablation; 4.4 Summary of Heat Considerations; 5 Conclusions; References
3.2 HFFAF at NASA Ames Center3.3 Hypervelocity Ballistic Ranges at ARC-UAH [21
23]; 3.4 Hypervelocity Impact Ranges at NASA JSC [24]; 3.5 Hypervelocity Impact Ranges at EMI, Germany; 3.6 Hypervelocity Ballistic Range Complex of CARDC, China; 4 Application of a Hypervelocity Ballistic Range; 4.1 Hypervelocity Aerodynamics; 4.2 Hypervelocity Aerophysics; 4.3 Hypervelocity Impact; 5 Concluding Remarks; Acknowledgments; References; Part IIIShock Waves in Solids; 3 Experimental Methods of Shock Wave Research for Solids; 1 Introduction; 2 Hypervelocity Accelerators and High-Pressure Generation
3 Stress Wave in Solid4 Shock Equation of State; 5 Stability of Shock Wave; 6 Thermodynamics of Shock-Induced Phase Transition; 7 Shock Syntheses; 8 Laser Shock Experiments; 9 Concluding Remarks; References; Part IVRam Accelerator; 4 The Ram Accelerator: Review of Experimental Research Activities in the U.S.; Abstract; 1 Introduction; 2 Experimental Facilities and Results; 2.1 University of Washington (UW); 2.1.1 Operation at High Fill Pressures; 2.1.2 Baffled-Tube Ram Accelerator; 2.2 U.S. Army Research Laboratory (ARL); 2.3 UTRON, Inc; 3 Computational Modeling; 4 Future Work; 5 Conclusions
3 Smooth Bore Version3.1 RAMAC 30 Facility Set-Up; 3.2 Experimental Results; 3.3 Summary of the Smooth Bore Research; 4 Heating and Erosion of Ram-Projectiles; 4.1 Modeling of Surface Heating; 4.1.1 Computational Requirements; 4.1.2 Boundary Layer Solution; 4.1.3 Heat Conduction Solution; 4.2 Modeling of Melting Ablation; 4.2.1 Model Bases; 4.2.2 Ablation Model; 4.3 Model Applied to Smooth Bore Firings; 4.3.1 Surface Heating; 4.3.2 Surface Ablation; 4.4 Summary of Heat Considerations; 5 Conclusions; References