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Try not to have a good time...this is supposed to be educational

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Presentation on theme: "Try not to have a good time...this is supposed to be educational"— Presentation transcript:

1 Try not to have a good time...this is supposed to be educational
-Peanuts

2 Example - 718 Ni-base superalloy
Composition: 52.5Ni 19Cr Mo 19Fe 0.4Al Nb-1Ti 0.04C

3 Example - 718 Ni-base superalloy

4 Example - 718 Ni-base superalloy

5 Example - 718 Ni-base superalloy
Possibilities for strengthening 718:

6 Example - 718 Ni-base superalloy

7 Example - 718 Ni-base superalloy
52.5Ni Provides friendly matrix for alloying elements 19Cr Oxidation and corrosion resistance, solid solution strengthening 3Mo Solid solution strengthening, stabilizes chromium oxide film, carbide formation for Hi T strength 19Fe Solid solution strengthening 0.4Al Increases oxidation resistance, forms strengthening pptates 5Nb-1Ti Form strengthening pptates 0.04C Carbide formation for creep resistance

8 Movement of atoms (or molecules) down a concentration gradient
Diffusion Movement of atoms (or molecules) down a concentration gradient concn distance concn distance concn distance concn distance How??

9 One way - vacancy movement
Diffusion One way - vacancy movement Vacancies occur naturally in materials vacancy No. fract. of vacancies = exp (-Q/RT)

10 One way - vacancy movement
Diffusion One way - vacancy movement Vacancies occur naturally in materials vacancy No. fract. of vacancies = exp (-Q/RT) For rm T: 1080°C: 1/1600

11 Diffusion Vacancy movement

12 Movement of atoms (or molecules) down a concentration gradient
Diffusion Movement of atoms (or molecules) down a concentration gradient concn distance concn distance concn distance concn distance I lied

13 Diffusion Movement of atoms (or molecules) over a hump Where do we get the activation energy?

14 Diffusion Where do we get the activation energy? From energy stored as thermal vibrations # jumps/sec = A exp (-Q/RT) For Cu: # jumps/sec = 1015 exp (-29/RT) = 1.1 x rm T = 2.2 x 1080° C

15 Diffusion Diffusion coefficient: flux J = D(T) dC/dx D(T) = Do exp (-Q/RT) For C diffusing in Fe: D(T) = 0.21 exp (-33.8/RT) = 6.7 x ° C = 4 x ° C

16 Diffusion For C diffusing in Fe: D(T) = 0.21 exp (-33.8/RT) = 6.7 x ° C = 4 x ° C Ex - carburizing a steel shaft: how long to carburize to depth of 1 mm x2 = D t D(1000° C) = 3 x 10-7 cm2/sec t = 10 hr D(1200° C) = 1.8 x 10-6 cm2/sec t = 1.5 hr

17 Assignments for next class:
1. review today's classnotes a. vacancies & vacancy motion b. rates of diffusion in solids c. effect of temperature on diffusion rates d. carburization example 2. Read text: chapter 5


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