Solution
The three (3) basic types of stainless steels are ferritic, martensitic, austenitic.
2. What are some applications for ferritic and martensitic stainless steels?
Solution
Ferritic stainless steels are used mainly as general construction materials requiring good corrosion and/or heat resistance. Examples include range hoods, restaurant equipment and combustion chambers. Martensitic stainless steels have comparatively low corrosion resistance but high strength and are thus used in applications such as machine parts, pump shafts, bearings and bearing parts, cutlery, and surgical tools.
3. What are the cast irons? What is their basic range of composition?
Solution
Cast irons are a family of ferrous alloys intended to be cast into a desired shape rather than worked in the solid state. These alloys typically contain 2 to 4 percent C and 1 to 3 percent Si. Additional alloying elements may also be present to control or vary specific properties.
4. What are some of the properties of cast irons that make them important engineering materials? What are some of their applications?
Solution
Cast irons are easily melted and highly fluid and do not form undesirable surface films or shrink excessively; consequently, they make excellent casting irons. They also possess a wide range of strength and hardness values and can be alloyed to produce superior wear, abrasion, and wear resistance. In general, they are easy to machine. Their applications include engine cylinder blocks and gear boxes, connecting rods, valve and pump casings, gears, rollers, and pinions.
5. Why are ductile cast irons in general more ductile than gray cast irons?
Solution
Ductile cast irons are, in general, more ductile than gray cast irons because their spherical graphite nodules are surrounded by relatively ductile matrix regions which allow significant deformation without fracture. In contrast, the gray cast irons consist of an interlacing network of graphite flakes which can be fractured easily.
6. Why does the graphite form spherical nodules in ductile cast irons instead of graphite flakes as in gray cast irons?
Solution
Graphite forms spherical nodules in ductile cast irons because the levels of phosphorus and sulfur are reduced significantly compared to those in gray cast irons; these two alloying elements prevent the formation of nodules and thus promote the formation of graphite flakes.
7. How Steel & Cast Iron Differ?
Solution
| Steel | Cast Iron |
| § Iron with C still in solution | § Iron which some of the C has precipitate out & appears as flakes |
| § C content; 1.6 ~ 2.0% | § C content; 2.0 ~ 6.0%C |
| § Ductile compare to C. iron | § Brittle compare to steel |
| § High strength | § Poor Strength |
| § Hard to machine | § Easy to machine |
| § Hard to control casting | § Easy to cast |
| § Low damping capacity | § Good Damping Capacity |
8. What are some of the important properties of unalloyed copper that make it an important industrial metal?
Solution
Properties of unalloyed copper, which are important to industrial applications, include high thermal and electrical conductivity, good corrosion resistance, ease of fabrication, medium tensile strength, controllable annealing properties, and general soldering and joining characteristics.
9. What are some of the properties that make aluminum an extremely useful engineering material?
Solution
Aluminum is an extremely useful engineering material due to its low density (2.70 g/cm3), good corrosion resistance, good strength when alloyed, high thermal & electrical conductivities and low cost.
10. What are some of the properties that make aluminum to be high prospect for transportation materials?
Solution:
To be used as engineering materials for transportation to reduce fuel assumption because its specific strength, which is quantified by the tensile strength-specific gravity ratio. Its TS is inferior to a more dense material (such as steel), on weight basis it will able to sustain a larger load.
11. What advantages do magnesium alloys have as engineering materials?
Solution:
As engineering materials, the primary advantage of magnesium alloys is their lightness; magnesium has the low density value of 1.74 g/cm3.
12. Why are titanium and its alloys of special engineering importance for aerospace applications?
Solution:
Titanium and its alloys are of special engineering importance for aerospace applications because of their high strength-to-weight ratios.
13. Define a refractory metals. Name the metal elements that are considered to be refractory elements?
Solution:
Refractory metals are metals with exceptionally high melting points; above 2450oC for example; Niobium (columbium) (Nb), Tantalum (Ta), Molybdenum (Mo) and Tungsten (W)
14. Define a biometals. Name the metal/ alloys that are considered to be biometals and give examples.
Solution:
Biometals is a metal alloys that replace damaged biological tissues, restore function, and are constantly or intermittently in contact with body fluids.
| Biometals Group | Example |
| Stainless Steel (SS) | § 316 L SS |
| Cobalt-based alloys | § Co-28 Cr-6 Mo cast alloy § Co-20 Cr-15 W-10 Ni wrought alloy § Co-35 Ni-20 Cr-10 Mo wrought alloy § Co-28 Cr-6 Mo cast alloy |
| Ti alloys | § Pure Ti § α Ti alloy (Ti-Al, Sn, Zr) § α-β Ti alloy (Ti-6 Al-4 V, Ti-6 Al-7 Nb |
15. Metals/ alloys used as surgical instruments are not classified as a biometals. Briefly discuss this issue.
Solution:
Because metals/ alloys used as surgical instruments are used in external prosthesis. In addition this instrument is not exposed to body fluids in continuous or intermittent manner
16. A striker from Liverpool FC team was badly injured resulted by hard tackling from
i) Taking into consideration the function of knee in a footballer profession, analyse the factors that may affect on the biometal performance.
ii) Recommend the suitable materials that would satisfy your requirements.
Solution:
i) Considering knee function for a footballer that may experience million cycles of stress on his knee bone in daily activity. Thus, the metal/ alloys should be able to endure large & variable (cyclic) stress in the highly corrosive environment of the human body.
The internal knee environment is highly corrosive and could degrade the implant materials, resulting in the release of harmful ions or molecules. Thus the characteristic of a biometal is biocompatibility. Thus the additional characteristic for knee implant is chemical stability, corrosion resistance, non carcinogenic & nontoxic when used in the human body.
ii) Biometal that may satisfy the requirement must be strong, fatigue & wear resistance and biocompatibility in a highly corrosive environment such as;
a) Stainless steel
b) Cobalt based alloys
c) Titanium alloys
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