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upper bainite 1 µm lower bainite Surface 1 Surface 2 50 µm Srinivasan & Wayman, 1968.

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Presentation on theme: "upper bainite 1 µm lower bainite Surface 1 Surface 2 50 µm Srinivasan & Wayman, 1968."— Presentation transcript:

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4 upper bainite 1 µm

5 lower bainite

6 Surface Surface 2 50 µm Srinivasan & Wayman, 1968

7 s d c r 1

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10 50 µm

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12 Carbon supersaturated plate
Carbon diffusion into Carbon diffusion into austenite austenite and carbide precipitation in ferrite Carbide precipitation from austenite UPPER BAINITE LOWER BAINITE (High Temperature) (Low Temperature)

13 1 2 Fe-0.4C wt% Decarburisation time / s 500 400 300 Temperature / °C

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15 Temperature Ae3' T' o x Carbon in austenite

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17 Summary The mechanism of transformation is displacive.
Transformation temperature higher than martensite. Bainite grows without diffusion. But carbon then escapes into the residual austenite. Shape deformation plastically accommodated. Sub-unit mechanism of growth

18 DISPLACIVE RECONSTRUCTIVE

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24 Watson and McDougall, 1973

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28 Summary Mechanism displacive but carbon must partition during growth.
Pairs of plates grow together to minimise strain.

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