Kostenloser Creep Rate Rechner
Schätzen Sie steady-state creep rate unter Verwendung von the power-law Arrhenius equation. Geben Sie stress, temperature, and material constants.
Steady-State Creep Rate
4,743.353 1/s
Steady-State Creep Rate vs Applied Stress (sigma)
Formel
## Steady-State Creep Rate Creep is the slow, time-dependent deformation of materials under sustained load at elevated temperatures. The secondary (steady-state) creep rate follows a power-law Arrhenius equation. ### Formula **epsilon_dot = A × sigma^n × exp(-Q / (R × T))** where A is a material constant, sigma is the applied stress, n is the stress exponent (3-8 for metals), Q is the activation energy for creep, R = 8.314 J/(mol·K) is the gas constant, and T is absolute temperature.
Lösungsbeispiel
A nickel alloy at 800 K under 100 MPa (A=1e10, n=5, Q=250 kJ/mol).
- 01sigma^n = 100^5 = 1 × 10^10
- 02Q/(RT) = 250000 / (8.314 × 800) = 37.57
- 03exp(-37.57) = 4.83 × 10^-17
- 04Creep rate = 1e10 × 1e10 × 4.83e-17 = 4.83 × 10^3 s^-1 ... (values depend on actual A)
Häufig Gestellte Fragen
When does creep become significant?
Creep is generally significant at temperatures above about 40% of the melting point (in Kelvin). For steel (Tm ≈ 1800 K), creep matters above about 720 K (450°C). For aluminum (Tm ≈ 933 K), above about 370 K (100°C).
What is the stress exponent n?
The stress exponent indicates the creep mechanism. n ≈ 1 for diffusion creep (Nabarro-Herring or Coble), n ≈ 3-5 for dislocation creep, and n > 6 for power-law breakdown. Most engineering metals show n = 3-8.
How does creep lead to failure?
Creep damage accumulates through void nucleation at grain boundaries, void growth, and eventual coalescence into cracks. Tertiary creep shows accelerating strain rate before final rupture.
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