Materials Technology & Metallurgy: Heat Treatment | شرح المعالجات الحرارية скачать в хорошем качестве

Materials Technology & Metallurgy: Heat Treatment | شرح المعالجات الحرارية

#metallurgy #MaterialsScience #MaterialsEngineering #HeatTreatment Exploring the Types of Heat Treatments mostly used with Steels. We'll cover everything from annealing to normalizing, hardening and tempering, case hardening, and the effect of alloying elements. By the end of this video, you'll have a solid understanding of heat treatments and their impact on steel. So, sit back, relax, and let's begin! معالجات الحرارة في المعادن 🔹 المعالجات الحرارية التقليدية: • التخمير (Annealing): يلين المعدن، يحسن قابليته للتشغيل، ويخفف الإجهادات الداخلية. • التطبيع (Normalizing): يحسن الخواص الميكانيكية ويُنعّم البنية الحُبيبية. • التقسية (Hardening): تبريد سريع من درجات حرارة مرتفعة لزيادة الصلادة. • المراجعة (Tempering): يقلل الإجهادات الداخلية ويحسن المتانة والليونة. 🔹 المعالجات الحرارية الكيميائية (تقنيات تصليد السطح): • الكربنة (Carburizing): إدخال الكربون في الطبقة السطحية لزيادة الصلادة ومقاومة التآكل. • النتردة (Nitriding): إدخال النيتروجين لتكوين نتريدات صلدة تعزز صلادة السطح ومقاومة التآكل. • الكربونتردة (Carbonitriding): دمج عمليتي الكربنة والنتردة لتحسين خصائص السطح بشكل متكامل Don't forget to like, comment, and subscribe to our channel for more videos like this one. And if you found this video helpful, be sure to share it with your friends and classmates. Thank you for watching! 1. Thermal Heat Treatments: • Annealing: Softens the material, improves machinability, and relieves internal stresses. • Normalizing: Improves mechanical properties and refines grain structure. • Hardening: Rapidly cools the material from elevated temperatures to increase hardness. • Tempering: Relieves internal stresses and improves toughness and ductility. 2. Thermochemical Heat Treatments (Case Hardening Methods): • Carburizing: Introduces carbon into the surface layer to increase hardness and wear resistance. • Nitriding: Introduces nitrogen into the surface layer to form nitrides, enhancing surface hardness and wear resistance. • Carbonitriding: Combines carburizing and nitriding processes to achieve enhanced surface properties. 3. Thermomechanical Heat Treatments: • Austempering: Controls the transformation of austenite to achieve a combination of high strength and ductility. • Martempering: Harden the material while minimizing distortion and internal stresses. • Thermoforming and Rolling: Involves simultaneous heating and deformation during forming and rolling processes to refine grain structure, enhance mechanical properties, and achieve desired shape and dimensions. 4. Structure of Martensite: • Martensite is a metastable phase formed during rapid quenching from austenitic temperatures. • It has a unique needle-like or plate-like microstructure, characterized by high hardness and brittleness (acicular microstructure). • Crystal structure (atoms arrangements and symmetry): BCT structure (Body-Centered Tetragonal) • The transformation to martensite is diffusionless, resulting in high internal stresses and potential for distortion. Effect of Various Alloying Elements on the Phase Diagrams of Steel and Properties: • Carbon: Increases hardenability and strength, but excessive amounts can lead to brittleness. • Chromium: Enhances corrosion resistance, hardenability, and wear resistance. • Manganese: Improves hardenability, strength, and toughness. • Nickel: Increases toughness, ductility, and corrosion resistance. • Molybdenum: Enhances hardenability, strength, and creep resistance. • Vanadium: Improves hardenability, wear resistance, and strength. • Silicon: Increases hardenability and strength, and aids in deoxidation. • Boron: Facilitates the formation of hard surface layers during case hardening. These categories encompass various heat treatment methods and their effects on the microstructure and properties of steel, including the influence of alloying elements on phase diagrams and resultant material properties. Additionally, thermomechanical heat treatments during forming and rolling processes are highlighted for their significance in steel manufacturing.