Product details:
| ISBN13: | 9780443161513 |
| ISBN10: | 0443161518 |
| Binding: | Paperback |
| No. of pages: | 364 pages |
| Size: | 229x152 mm |
| Language: | English |
| 700 |
Category:
Mechanical Alloying of Ferrous and Non-Ferrous Alloys
Processing, Properties, and Applications
Publisher: Elsevier
Date of Publication: 1 July 2024
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Long description:
Mechanical Alloying of Ferrous and Non-Ferrous Alloys: Processing, Applications, and Properties provides an in-depth exploration of ferrous and non-ferrous alloys, including various methods of preparation and production, their mechanical properties, and applications. The advantages of the mechanical alloying processing approach over other traditional powder metallurgical techniques is explained as are the alloys that are best suited for this technique. Preparation steps, microstructures, properties, and applications for ferrous and non-ferrous alloys are compared, with insights on which alloys are best suited for preparation by alloying.
The advantages and disadvantages of wet and dry milling are outlined. Processing, properties, and applications of high entropy alloys, ODS stainless steel, shape memory alloys, cermets, iron, copper, zinc, tungsten, aluminum, titanium, magnesium, and ceramic-based alloys are also covered, as are different powder preparation techniques and sintering methods.
The advantages and disadvantages of wet and dry milling are outlined. Processing, properties, and applications of high entropy alloys, ODS stainless steel, shape memory alloys, cermets, iron, copper, zinc, tungsten, aluminum, titanium, magnesium, and ceramic-based alloys are also covered, as are different powder preparation techniques and sintering methods.
- Outlines the different types of mechanical alloying used to prepare powders, their mechanisms, factors affecting the process, and more
- Covers the manufacturing, characteristics, and applications of high entropy alloys, ODS stainless steel, shape memory alloys, magnesium, ceramic-based alloys, and more
- Compares preparation of ferrous and non-ferrous alloys, their microstructures, and properties
- Discusses the advantages and disadvantages of wet and dry milling
Table of Contents:
1. Evolution of Mechanical alloying
2. Types of ball milling and their mechanism
3. Overview of the dry milling vs. wet milling
4. Comparative study of mechanical alloying and other conventional powder metallurgical methods
5. Consolidation of mechanically alloyed powders
6. Secondary Processing of Sintered Compacts
7. How mechanical alloying facilitated the fabrication of tungsten heavy alloys
8. Fabrication of Cermets and Copper Alloys by Ball Milling and Investigation of their Properties and Applications
9. Processing of Titanium alloys by mechanical alloying
10. How mechanical alloying facilitated the preparation of intermetallic, ceramic, shape memory alloys, and high entropy alloys?
11. Role of Mechanically Alloyed Materials in Energy Storage and Automotive Applications
12. Current and Future Applications of mechanically alloyed materials
2. Types of ball milling and their mechanism
3. Overview of the dry milling vs. wet milling
4. Comparative study of mechanical alloying and other conventional powder metallurgical methods
5. Consolidation of mechanically alloyed powders
6. Secondary Processing of Sintered Compacts
7. How mechanical alloying facilitated the fabrication of tungsten heavy alloys
8. Fabrication of Cermets and Copper Alloys by Ball Milling and Investigation of their Properties and Applications
9. Processing of Titanium alloys by mechanical alloying
10. How mechanical alloying facilitated the preparation of intermetallic, ceramic, shape memory alloys, and high entropy alloys?
11. Role of Mechanically Alloyed Materials in Energy Storage and Automotive Applications
12. Current and Future Applications of mechanically alloyed materials
