Aerospace materials (Coursera)

The course provides:

• key information about aerospace materials used in aircraft (classification, properties, etc.)
• description of the most common aerospace metallic materials such as aluminum and titanium alloys, high-strength steels and metal powders.

The course is intended for students of engineering specialties, for engineers of aviation and mechanical engineering enterprises, and other students wishing to study aerospace materials.

Syllabus

WEEK 1
Introduction to the course "Aerospace materials"
Module 1. Machining of metals
This module will introduce you to the classification of aerospace materials. You will learn about the requirements for these materials.
Technologies always affect the structure and properties of materials. You will learn about the main forming technologies (metal forming, hot and cold working, and machining) and their effects on the structure of aerospace materials. Phenomena that accompany the machining operations will be examined as well.

WEEK 2
Module 2. Aluminum and aluminum alloys
This module will introduce you to aluminum alloys, which are crucial aerospace materials. Aluminum alloys were the first to be used in the manufacture of aircraft. The use of aluminum in revolutionized the aircraft industry.
Its advantages are high manufacturability and specific strength (the ratio of maximum stresses to weight). We will study various classifications and designations of aluminum alloys as well as the basics of heat treatment. We will learn how alloying elements affect the structure and properties of aluminum alloys.

WEEK 3
Module 3. Titanium and titanium alloys
We will learn about the role of titanium in the aircraft industry, its advantages and disadvantages for aerospace applications, the structure and properties of titanium alloys. We will examine promising titanium aluminides and shape-memory titanium alloys.
Titanium alloys have unique properties and are very promising as aerospace materials Titanium alloys are used in heavily-loaded airframe sections, undercarriage parts, skins to high Mach speed aircraft, jet engines, and many other aircraft components requiring high strength, fracture toughness and resistance to fatigue, creep and corrosion. These mechanical properties are superior to lightweight structural materials, including aluminum alloys and magnesium alloys.

WEEK 4
Module 4. High strength steels
This module will introduce you to high strength steels. Steel is used as an aerospace material, but to a lesser extent than titanium, aluminum, and composites. High strength steel cannot be replaced with other materials.
Advantages of using steel in highly-loaded aircraft structures include high stiffness, strength, fatigue resistance and fracture toughness. In this part of the video course, we will deal with steels used in landing gear and other high-strength components, namely: maraging steels, medium-carbon low-alloy steels, and stainless steels.

WEEK 5
Module 5. Powder materials
This module will introduce you to powder metal materials and modern technologies used to manufacture them. Powders are used in the manufacture of complex parts or when increased heat resistance is required. "Sweating" highly porous materials are used to prevent icing on aircraft.
Metal powder compositions are of particular interest due to the rapid development of additive technologies. You will learn about the requirements for powders used in additive manufacturing.

WEEK 6
Summing-up
We told you about a variety of aerospace materials. Now imagine you are an aircraft designer. Do the final task.