Surface Structure Modification and Hardening of Al-Si Alloys
Auteurs : Romanov Denis A., Moskovskii Stanislav. V., Gromov Viktor E.
Surface Structure Modification and Hardening of Al-SI Alloys explores the hardening of material surfaces using concentrated energy flows resulting in the nanostructuring of surface layers. The authors demonstrate how these methods achieve a reduction in plastic deformation of the surface and a more uniform distribution of elastic stresses near the surface during operational use, significantly reducing part failure. It presents results from research and scientific and technological enterprises involved with the modification of light alloy surfaces for use in the automobile and aerospace industries.
Additional key features include:
- Addresses theoretical and experimental research computer simulations of structural phase transformations at the nanolevel to create new materials
- Details and compares electroexplosion alloying, electron beam processing and electron-plasma alloying of an Al-Si Alloy
- Explains multiphase plasma jet treatment to obtain high-quality coatings with good and high functional properties
This reference is a valuable resource for specialists in the field of physical material science, condensed state physics, metal science and thermal treatment and will be of interest to undergraduate and post-graduate students in these fields.
Date de parution : 08-2022
15.6x23.4 cm
Disponible chez l'éditeur (délai d'approvisionnement : 14 jours).
Prix indicatif 74,82 €
Ajouter au panierDate de parution : 11-2020
15.6x23.4 cm
Disponible chez l'éditeur (délai d'approvisionnement : 14 jours).
Prix indicatif 184,47 €
Ajouter au panierThèmes de Surface Structure Modification and Hardening of Al-Si Alloys :
Mots-clés :
External mechanical loads; Al-Si alloy; plastic deformation; multiphase plasma jet treatment; external energy effect; surface layer alloy; concentrated energy flux; yttrium; electron beam processing; yttrium oxide; Titanium Borides; Arc Erosion; Electric Explosion; Dislocation Substructure; Scalar Dislocation Density; Titanium Diboride; Energy Density; Copper Inclusions; X-ray Microanalysis; Crystal Lattice Parameter; Composite Coating; Absorbed Power Density; Copper Substrate; Max Phase; Al Si Alloy; Typical SEM Image; Arc Ablation; SEM Study; Molybdenum Powder; Electrical Contact Materials; Peritectic Reactions; Group IIIA; Copper Foil; Strain Drawing