- Docente: Carla Martini
- Credits: 6
- SSD: ING-IND/21
- Language: Italian
- Moduli: Carla Martini (Modulo 1) Alessandro Morri (Modulo 2)
- Teaching Mode: Traditional lectures (Modulo 1) Traditional lectures (Modulo 2)
- Campus: Bologna
- Corso: Second cycle degree programme (LM) in Mechanical Engineering (cod. 0938)
Learning outcomes
Upon successful completion of the course, students
will be able to evaluate in which application it is necessary or
convenient to modify the surface properties of materials in order
to enhance corrosion and/or friction/wear resistance, or to develop
specific chemical or physical properties. The students will be able
to choose among the main surface modification and coating
deposition technologies. Particular attention will be devoted to
deposition methods from the vapour, liquid and solid
phase.
Course contents
1. Introduction
1a. Basics on corrosion. Electrochemical (wet) corrosion: thermodynamic and kinetic aspects; protection methods. Chemical corrosion (high temperature oxidation): thermodynamic and kinetic aspects; protection methods. Coatings for corrosion protection.
1b. Basics on friction and wear: Real surfaces; Contact between surfaces; Friction; Wear processes and mechanisms; Surface treatments and coatings for tribological applications.
2. Coatings deposited from vapor phase (PVD, CVD and PA-CVD processes: deposition technologies, properties and structures). Duplex treatments, nanostructured and adaptive (smart) coatings, carbon-based coatings. Thermochemical diffusion treaments (carburizing, nitriding, carbonitriding and nitrocarburising, sulfurising, boriding, aluminising, chromising and sherardising).
3. Coatings deposited from liquid phase : Aqueous solution ((i) Electrodeposition of metallic protective coatings (chromium, nickel and zinc plating); Replacement of hard chromium coatings; Autocatalytic (electroless) deposition: Ni-P and Ni-B coatings, Ni-P matrix composite coatings. (ii) Conversion treatments (chromatising and alternative treatments; Phosphatising; Anodising; Plasma Electrolytic Oxidation)). Immersion in molten metal: hot-dip galvanizing, hot-dip aluminizing.
4. Coatings deposited from solid phase: thermal sprayed and welded coatings (hardfacing): deposition technologies, properties and structures. Cladding techniques.
5. Selection criteria for anti-friction/wear and anti-corrosion coatings and treatments: case studies and examples.
6. Methods for the characterization of coatings: morphology, roughness, composition, thickness, hardness, elastic modulus, adhesion, residual stress, fracture toughness, friction/wear and corrosion resistance.
Readings/Bibliography
Course material (all the slides used by the teacher are available in the AMS Campus repository). Slides in Italian.
1. L.L.Shreir et al., (Eds.), “Corrosion”, Vol.1 (Newnes –Butterworths) 2000
2. I.M. Hutchings (1992), “Tribology”, Edward Arnold
3. ASM Handbook vol.5, “Surface Engineering”, ASM International (2010).
4. C.Donnet, A. Erdemir, “Tribology of DLC Coatings: Fundamentals and Applications”, Springer (2008).
5. K.Holmberg, A.Matthews, ” Coatings Tribology: Properties, Mechanisms, Techniques and Applications in Surface Engineering”, Elsevier (2009).
6. J.W. Dini, “Electrodeposition”, Noyes (1993).
7. H.Dong (Ed.), “Surface engineering of light alloys: Aluminium, magnesium and titanium alloys”, Woodhead (2010).
8. S.Grainger, “Engineering coatings - design and applications”, Abington Publishing, Cambridge, UK (1989)
Teaching methods
The course consists of:
- Lectures according to the timetable (all the slides used by the teacher are available in the AMS Campus repository).
- Lab practicals (focusing on characterization of coated materials).
Assessment methods
Written examination with short oral discussion or completely written examination on request. Examination in English can be arranged by previous contact with the teacher.
The aim of the examination is to assess the knowledge of the main selection criteria for coatings and treatments of metallic substrates. The main criteria are based on deposition/treatment temperature, microstructure and thickness of the coating/treated layer, throwing and leveling power (ability to produce uniformly thick layers also on components with complex geometries), residual stress state (and its influence on fatigue behavior), hardness (and its influence on friction/wear behavior), adhesion, compactness, practical nobility (influence on corrosion behavior).
Teaching tools
Computer and videoprojector, blackboard.
Teaching lab (equipment for metallographic preparation; optical microscopes and scanning electron microscope (SEM) with energy dispersive spectroscopy (EDS) microprobe); Vickers micro-hardness tester; scratch tester and tribometers).
Office hours
See the website of Carla Martini
See the website of Alessandro Morri