Fergana polytechnic insitute mechanical engineering faculty department of mechanical engineering and automation
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- 17. Elongation
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16. Yield Strength
The yield strength or yield point of a material is defined in engineering and materials science as the stress at which a material begins to deform plastically. Prior to the yield point the material will deform elastically and will return to its original shape when the applied stress is removed. Once the yield point is passed, some fraction of the deformation will be permanent and non-reversible. 17. Elongation Elongation is the percentage increase in original length (strain) of a rubber specimen as a result of tensile force (stress) being applied to the specimen. Elongation is inversely proportional to hardness, tensile strength, and modulus. 171 18. HSLA Those steel alloys known as high-strength low-alloy (HSLA) steels provide increased strength-to-weight ratios over conventional low-carbon steels for only a modest price premium. Because HSLA alloys are stronger, they can be used in thinner sections, making them particularly attractive for transportation-equipment components where weight reduction is important. HSLA steels are available in all standard wrought forms -- sheet, strip, plate, structural shapes, bar-size shapes, and special shapes. 172 Question lists from Material science 1. Goals and objectives of subject 2. Polymorphism & Allotropy 3. Superplasticity in Metals 4. Secondary Bonds 5. Industrial Applications of Diffusion Processes 6. Gibbs phase rule 7. Atomic Numbers, Mass Numbers & Atomic Masses 8. Crystalline Imperfections 9. Graphical representation of Creep - & Stress Rupture Time-Parameter Data Using the Larsen-Miller Parameter 10. Periodic Variations in Atomic Size, Ionization Energy & Electron Affinity 11. Rate processes in solids 12. Recent Advances & Future Directions in Improving the Mechanical Performance of Metals 13. Material Science and Engineering 14. Crystal Structure Analysis 15. Nanocrystalline Metals 16. The space lattice & Unit Cells 17. Effects of Temperature on Diffusion in Solids 18. Cooling curves 19. The Electronic Structure of Atoms 20. Experimental Techniques for Identification of Microstructure and Defects 21. A Case Study in Failure of Metallic Components 22. Crystal Systems & Bravais Lattices 23. The Processing of Metals and Alloys 24. Binary Isomorphous Alloy Systems 25. Atom Positions in Cubic Unit Cells 26. The Tensile test & Engineering Stress-Strain Diagram 27. Nonequilibrium Solidification of Alloys 173 28. Primary Bonds 29. Atomic diffusions in solids 30. Phase diagram of pure substances 31. Types of materials 32. Amorphous Materials 33. Fracture of Metals 34. Principal Metallic Crystal Structures 35. Stress & Strain in Metals 36. The Lever Rule 37. Comparison of FCC, HCP & BCC Crystal Structures 38. Solid-Solution Strengthening of Metals 39. Phase Diagram with Intermediate Phase & Compounds 40. Directions in Cubic Unit Cells 41. Hardness & Hardness Testing 42. Binary Eutectic Alloy Systems 43. Atomic Structure & Subatomic Particles 44. Metallic Solid Solutions 45. Creep & Stress Rupture of Metals 46. Miller Indices for Crystallographic Planes in Cubic Unit Cells 47. Plastic Deformation of Metal Single Crystals 48. Binary Peritectic Alloy Systems 49. Recent advances in Materials Science and Technology and Future Trends 50. Solidification of Metals 51. Fatigue of Metals 52. Volume, Planar, & Linear Density Unit-Cell Calculations 53. Recovery & Recrystallization of Plastically Deformed Metals 54. Ternary Phase Diagrams 55. Crystallographic Planes & Directions in Hexagonal Crystal Structure 56. Plastic Deformation of Polycrystalline Metals 57. Binary Monotectic Systems |