Creep is defined as the time-dependent strain that occurs under load at elevated temperature and operates in most applications of heat-resistant high-alloy castings at normal service temperatures.
The stress that produces a specified minimum creep rate of an alloy or a specified amount of creep deformation in a given time (for example, 1% of total 100,000 h) is referred to as the limiting creep strength, or limiting stress.
Creep is defined as the time-dependent strain that occurs under load at elevated
temperature and operates in most applications of heat-resistant high-alloy
castings at normal service temperatures. In time, creep may lead to excessive
deformation and even fracture at stresses considerably below those determined in
room temperature and elevated-temperature short-term tension tests.
When the rate or degree of deformation is the limiting factor, the design stress
is based on the minimum creep rate and design life after allowing for initial
transient creep. The stress that produces a specified minimum creep rate of an
alloy or a specified amount of creep deformation in a given time (for example,
1% of total 100,000 h) is referred to as the limiting creep strength, or
Stress rupture testing is a valuable adjunct to creep testing and is used to
select the section sizes necessary to prevent creep rupture of a component. It
should be noted that the long-term creep and stress-rupture values (For example,
100,000 h) are often extrapolated from short-term tests. Whether these property
values are extrapolated or determined directly, both methods will often provide
accurate information on the operating life of high-temperature parts.
The actual material behavior is often difficult to predict accurately because of
the complexity of the service stresses, variation in application relative to the
idealized conditions, uni-axial loading conditions in the standard tests, and
also because of the attenuating factors such as cyclic loading, temperature
fluctuations, and metal loss from corrosion. The designer and the metallurgist
should therefore be prepared to anticipate the synergistic effect of these
During creep testing, the tensile specimen is subjected to either a constant
load or stress at a constant temperature. Most creep tests conducted at constant
load are concerned with concerned with information relating to specific
engineering applications, whereas creep tests at constant stress are necessary
for the specific understanding of the mechanism of creep. During the creep test,
strain (change in length) is measured as a function of elapsed time. Creep test
data is presented as a plot between time and strain known as creep curve. The
slope of the creep curve is designated as creep rate dt/dε. A typical creep
curve is shown in Figure 1.
The curve may show the instantaneous elastic and plastic strain that occurs as
the load is applied, followed by the plastic strain which occurs over time.
Three stages to the creep curve may be identified:
Primary creep: in which the creep resistance increases with strain
leading to a decreasing creep strain rate.
Secondary (Steady State) creep: in which there is a balance between work
hardening and recovery processes, leading to a minimum constant creep rate.
Tertiary creep: in which there is an accelerating creep rate due to the
accumulating damage, which leads to creep rupture, and which may only be seen at
high temperatures and stresses and in constant load machines.
The minimum secondary creep rate is of most interest to design engineers, since
failure avoidance is commonly required and in this area some predictability is
possible. In general two Standards are commonly used:
- The stress to produce a creep rate of 0.0001% per hour (1% in 10,000 hours).
- The stress to produce a creep rate of 0.00001% per hour (1% in 100,000 hours
or approximately 11.5 years).
The first requirement would be typical of that for gas turbine blades, while the
second standard would be most typically seen in applications such as those for
Figure 1: A
typical creep curve
Secondary creep, which occurs as a linear function of time, is heavily dependent
on temperature and stress. Since creep is a thermally activated process,
the minimum secondary creep rate can be described by a fundamental Arrhenius
equation of the form:
ε= dε/dt = Kσn exp(- Q/RT); for T=const, dε/dt = Kσn
T - temperature [K];
tr - time to rupture, [h]
K - creep constant
n - creep exponent (varying from metal to metal n=3÷8; most common value
is n=5; determined experimentally determined by plotting the strain rate as a
function of stress)
σ - applied stress/nominal stress
Q - activation energy for creep
R - gas constant (8,314 J/mol K)
The critical temperature for creep is 40% of the melting temperature in Kelvin:
If T>0.40Tm then creep is likely.
For metallic materials most creep tests are conducted in uni-axial tensile mode.
However, uni-axial compression tests are also used for brittle materials to
avoid stress amplification and corresponding crack propagation. For most
materials creep properties are independent of loading direction.
The minimum creep rate is the most important design parameter derived from the
creep curve. This particular engineering design parameter is primarily
considered for long-life applications, e.g. nuclear power plant components.
Conversely, for short-life components (e.g. turbine blades, rocket motor
nozzles), time to rupture or rupture lifetime is the dominant factor in design.
Minimum creep rate is attained using the stress rupture test which tests the
material to the point of failure. This is basically similar to a creep test
except that the test is always carried out at higher loads. In a creep test
total strain is often less than 0.5%, while in stress-rupture tests it is
normally around 50%.
Rupture life time predictions
One of the most popularly used techniques in representing creep-rupture data is
Larson-Miller Time –temperature parameters. This parameter can be derived from
the stress and temperature dependence of the creep rate or time to rupture. The
rate equation generally can be written in the form of the Arrhenius equation and
expressed as PLM= T [21.577+ log (tr)].