High Cycle Fatigue: A Mechanics of Materials Perspective part 7 ppsx

is the correct curve ” and sums up: “I submit that the proper thing to do is not to coin rules out of imagination, but to persevere in careful and patient experiments, and to watch na

0.8

0.6

0.4

0.2

–0.2

–0.4

Static breaking stress

Maximum stress

Minimum stress

Zero stress

Compression

Tension

Figure 2.22. Goodman diagram as shown in Goodman, 1899 [20] on p 455.

0 0.2 0.4 0.6 0.8 1

σ0= 1

σ0 = 0.75

σ0 = 0.25

Mean stress/ultimate stress

R= 0

Figure 2.23. L–W equation for R > 0 plotted on a Haigh diagram.

from the original Goodman equation at R= 0 where max= 05u The curve is closer to

a Gerber parabola than a straight line in that region but may not have any more physical significance than the other two representations of experimental data

It can be seen that the development of methods to represent fatigue limit data was based

on a combination of mathematically simple forms as well as graphical representations While there seemed to be a physical basis of some sort for all of the approaches, combined with simplicity, it should be pointed out that the choices of methods of representing data were scrutinized throughout their development A particularly insightful example of such a critique was made in 1880 [26], although similar words would be equally valid today Commenting on the W–L formula, used to fit Wöhler’s data, Smith writes, “In fact, the formula seems to be more the product of pure imagination than to be based

on the experiments.” He further points out that “the formula can, of course, be made to

agree with the extreme results of any particular set of experiments What I, and I dare

say some others, would like to know, is whether this formula agrees with even a rough

degree of approximation with the intermediate results.” He goes on to question “whether

the parabolic curve    is the correct curve    ” and sums up: “I submit that the proper thing to do is not to coin rules out of imagination, but to persevere in careful and patient experiments, and to watch narrowly and to study and analyze closely the results until the true intimate laws of the stress and fatigue of metals are revealed.”

In the final program on HCF material behavior [27], a Haigh diagram was constructed

data The stress-life behavior was characterized for each stress ratio, R, in terms of the alternating stress altusing a power law relationship:

Nf= km

Data were used only from <001> oriented specimens with the exception of eight spec-imens oriented at < 001+ 15> that were tested at R = 08 The <001 + 15> oriented data fall on top of the < 001> data and consequently were included in the data set to

tested value of R are shown in Table 2.1

Using the empirical S–N relationships, the curve was extrapolated to longer lives and

Figure 2.24

of the diagram is fairly conventional for low values of mean stress A gradual decrease

Table 2.1. Constants for S–N empirical fits at 1900F

0 10 20 30 40 50

59 Hz HCF data

Mean stress (ksi)

R= –1

R= –0.33

R= 0.8

R= 0.5

R= 0.1

46 Hr Rupture capability

Figure 2.24. 1900F Haigh diagram for PWA 1484, 10 7 cycles.

in alternating stress capability is accompanied by an increase in allowable mean stress

rupture capability is approached The stress rupture capability can be represented as an

planned frequency) For this material, there are both cycle-dependent and time-dependent modes of failure, the former normally associated with the value of the alternating stress and the latter associated primarily with the mean stress

To account for this more complex fatigue behavior, a Walker model was used to represent the behavior of the material In the Walker model, an equivalent alternating stress is defined to take into account different mean stress conditions This equivalent alternating stress, equivalent_alt, is then used in the stress-life power law relationship as shown below:

where the equivalent alternating stress is given by:

The Walker exponent, w, was determined by taking data from several values of R and iterating until the standard error in predicted life was minimized The Walker model collapsed the S–N response over a range of stress ratios While the Walker exponent is normally determined over the full range of stress ratio data that are available, in this case

fatigue mode Fractography showed that failure was dominated by fatigue only at low stress ratios or low mean stress loading conditions

Two approaches were considered for fitting the Walker model The first (termed

approach (Walker model C) was examined because despite the fatigue-based appearance

process is also present at this test condition [27] At a constant stress level at R= 01, fatigue life in cycles increased as the frequency was increased from 59 to 900 Hz

A linear line with a slope of 1:1 approximated the data fairly well indicating a fully time-dependent process up to the highest frequency that was tested, 900 Hz A transition

to time-independent behavior with cycles to failure maintaining a constant level may exist just beyond 900 Hz or could occur well beyond that frequency As a result, the estimate

of the Walker exponent for pure HCF may be affected by using the lower 59 Hz data

behavior Walker model constants for each subset of HCF data are shown in Table 2.2

In Figure 2.25, Walker model A approximates the 59 Hz HCF data fairly well up to

time-dependent failure mechanisms reduce the cyclic capability of the material

To account for the time-dependent behavior of the material, two approaches were used

of the two, assumes that only the applied mean stress contributes to rupture damage This approach is referred to as the Mean Stress Rupture Model The second method, the Cumulative Rupture Model considers the summation of rupture damage from applied stress over the entire fatigue cycle

Table 2.2. Constants for 1900F Walker models

Walker model HCF Data subset Number of tests k m Walker exponent, w

59 Hz R = 01

@ 370–400 Hz

0 10 20 30 40 50

Walker model A Walker model C

Mean stress (ksi)

Figure 2.25. Walker models A and C with 59 Hz 10 7 cycles Haigh diagram.

The Mean Stress Rupture Model is represented by the expression in Equation (2.11) that relates mean stress to time to rupture The expression was derived by fitting a power law relationship to four tests that were conducted until rupture The resulting equation is

where mean is the applied mean stress in ksi and tf is the time to failure in hours

In the Cumulative Rupture Model, the rupture damage due to the applied stress is integrated over the cyclic load and the applied stress is expressed as a sinusoidal function using as the period of the cycle in hours To do this, the load cycle is divided into the corresponding rupture life is determined using Equation (2.10) The rupture damage loading cycle The number of cycles to failure can be calculated using the assumption that failure occurs when the rupture damage equals one

When R is less than zero, a portion of the loading cycle is compressive Two scenarios were considered when applying the Cumulative Rupture Model: (a) compressive stress

is neither damaging nor beneficial to life, and (b) compressive stress is damaging to life Thus, in total, three rupture models were considered: Mean Stress Rupture Model, Cumu-lative Rupture without compressive damage, and CumuCumu-lative Rupture with compressive damage

59 Hz compared to the HCF test data Both cumulative rupture models approximate the shape of the Haigh diagram based on the experimental data The mean stress model predicts a mean stress of 32.5 ksi independent of R for 107cycles at 59 Hz since the model

is purely time-dependent and does not consider any cyclic contribution to the damage process It is worth noting that the cyclic models, Figure 2.25, seem to do a good job

0 10 20 30 40 50

59 Hz HCF data Cumulative rupture, no compressive damage

Cumulative rupture with compressive damage

Mean stress rupture model

Mean stress (ksi)

R= –1

R= –0.33

R= 0.8

R= 0.5

R= 0.1

Figure 2.26. 1900F 10 7 cycle Haigh diagram at 59 Hz with rupture model predictions.

of fitting the data at low values of mean stress They are derived, however, from fitting those very same data The rupture model predictions, on the other hand, are derived strictly from rupture data with no cyclic content The ability of the rupture models to represent data over the entire range of mean stresses, Figure 2.26, seems to indicate that

purposes, can be treated as such

The example cited above points out some of the considerations that are encountered when plotting data on a Haigh diagram and then trying to interpret the data or model the material fatigue limit when the material behavior includes time dependence Factors such as cyclic frequency become important considerations and, at a minimum, should be indicated in Haigh diagram plots

In dealing with data on FLSs, it is common to plot these stresses as a function of stress

Haigh diagram, incorrectly referred to as a Goodman diagram, is a common method of representing the fatigue limit or endurance limit stress of a material in terms of alternating stress, defined as half of the vibratory stress amplitude Thus, the maximum dynamic stress is the sum of the mean and alternating stresses For many rotating components, the mean stress is known fairly accurately, but the alternating stress is less well defined because it depends on the vibratory characteristics of the component Thus a Haigh diagram represents the allowable vibratory stress as the vertical axis as a function of mean or steady stress as the x axis While attempts have been made to define the equation which best represents the data on a Haigh diagram, as described earlier in this chapter,

variability from material to material, scatter in the data, and lack of sufficient data in many cases prevent the fitting of an equation to such data

When mean stress values are negative, or for values of R less than minus one, there are very few data and no general guidelines for extrapolating equations which were meant

to represent data on a Haigh diagram only for positive values of mean stress In cases such as contact fatigue, very high compressive stresses can be present, necessitating knowledge of fatigue behavior or fatigue limits for negative mean stresses One of the most important areas where negative mean stresses can occur is in the case of the introduction of compressive residual stresses into a material or component Shot peening, for example, is commonly used as a surface treatment to improve the fatigue properties

of a material by introducing residual compressive stresses into the material up to depths typically no greater than 0.1 mm While compressive stresses in the vicinity of the surface reduce the maximum stress from vibratory loading at the surface, they do not reduce the vibratory amplitude Thus, in effect, they drive the mean stress lower, often into the compressive regime While these residual compressive stresses are known to improve the fatigue characteristics in many materials and geometries, they are generally not taken into account in design and are used, instead, to improve the margin of safety If such

a condition is to be taken into account in design, a thorough understanding of material behavior and fatigue limits under negative mean stresses is required The subject of residual stresses and accounting for them in design is discussed in Chapter 8

Forrest [15] has assembled a large body of fatigue limit strength data on ductile metals and plotted them in dimensionless form as indicated in Figure 2.27 The thick straight

Mean stress/yield stress–1

2.0

1.5

1.0

0.5

Figure 2.27. Schematic of observed behavior at negative mean stress.

line represents the data (not shown) quite well and illustrates that extending the fit into the mean stress regime produces alternating stress values that continue to increase with decreasing mean stress The data chosen by Forrest [15] for this type of plot were filtered from available data to meet a criterion to accept only those results where special precautions were taken to insure axiality of loading The data covered a range of aluminum and steel alloys As noted earlier, when discussing the effects of compressive residual stress on fatigue limit strength, Forrest [15], in 1962, already recognized the importance

of the shape of the curve fit to the data by stating that the “behaviour is particularly significant with regard to the effect of residual stresses on fatigue strength.”

Representing compressive mean stress data on Haigh or other types of diagrams described above was never much of a consideration because data obtained at mean stresses

We now examine the capability of equations to represent negative mean stress data

In addition to the modified Goodman equation and the others described above, there have been many variations of straight lines and other curves to try to represent fatigue limit data for HCF design Additionally, there are fatigue equations that are used mainly

to fit data in the LCF regime, which try to account for the effects of mean stress or stress ratio by introducing a single parameter to consolidate such data Two such equations are the one due to Smith, Watson, and Topper (SWT) [28] and the commonly used Walker equation For the SWT equation, an effective stress is given in terms of maximum stress and strain range In HCF, elastic behavior is assumed, thus strain range and stress range can be used interchangeably when dealing with FLS conditions The SWT equation for elastic behavior is in the form



max 2

1/2

titanium bar material [29] The exponent in Equation (2.12) is taken as the one used most commonly, namely 0.5 For reference purposes, the Jasper equation, discussed later,

is plotted because it is found to describe the shape of the Haigh diagram for positive mean stress quite well Of greatest interest in Figure 2.28 is the shape of the curve for the SWT equation for negative mean stress, which shows an ever increasing alternating stress as mean stress becomes further negative As an alternative, if we choose to take half the strain range (or half the stress range) as that corresponding to positive stresses

= + in the figure), this changes the curve only slightly in the negative mean stress regime Note, finally, the symmetric shape of the Jasper equation about zero mean stress This also will be discussed later

200

400

600

800

1000

SWT

² σ = +

Jasper

Mean stress (MPa)

Figure 2.28. Haigh diagram representation of SWT and Jasper equations.

A similar treatment can be given to the Walker equation which, as for the SWT equation, is commonly used to consolidate LCF data obtained at different stress ratios, R The equation is similar to the SWT equation, but adds a degree of flexibility through the exponent w It has the form

where w is the Walker exponent With the exception of the value of the coefficient in

a plot of the Walker equation for various values of the exponent w, including extension

all forced to go through the same point at zero mean stress While some data are handled

by changing the value of w for negative values of R, it can be seen that the Walker equation has the same general characteristics as the SWT equation for negative mean stress, namely that alternating stress continues to increase as mean stress goes further negative Further, for both equations, the shape of the curves for positive mean stress is concave up over the entire region

Several attempts were made in the early days of fatigue modeling to account for the observed behavior of the FLS when the mean stress was negative In 1930, Haigh [30] pointed out that experimental data indicate that the constant life diagram is not symmetric

200

400

600

800

1000

w= 0.2

w= 0.4

w= 0.5

w= 0.6

w= 0.7

Mean stress (MPa)

Constant life diagram Walker equation

Figure 2.29. Haigh diagram representation of Walker equation.

suggested that the data can be represented by the generalized parabolic relation

a= −1



1− k1



m

u



− k2



m

u

2

(2.14)

constraining the curves to go through the ultimate stress point on the x axis and the alternating stress value at R= −1 on the y axis The case where k1= 0 k2= 1 represents

the modified Goodman line is obtained, extrapolated for negative mean stress

More complex equations have been proposed, such as that by Heywood [31], who used

an empirical cubic equation for representing constant life data His equation has the form

a=





m

u

 

−1+ u− −1



(2.15a)

∗

While the generalized Goodman equation [3] does not indicate symmetry with respect to  m , the formulation

in the first Edition of Goodman’s book [20] presents equations for the static load capability in terms of the dynamic theory If it is assumed that the strength is equal in tension and compression, the equations indicate that there is symmetry with respect to mean stress The lack of data for negative mean stresses prevented any substantial debate on this issue of symmetry The symmetry of the Goodman equation and its history are discussed in [18].