High Cycle Fatigue: A Mechanics of Materials Perspective part 48 docx

The behavior of a cracked specimen that has a residual stress can be further understood with the aid of Figure 8.67 where compliance curves are shown for a material that exhibits no crac

and an effective stress ratio can then be defined as:

Reff=Kmin eff

Note that in this case, K does not change due to residual stresses, but Reff decreases

if Kres is a negative number Since the residual stresses are compressive, the computed

Kres is negative While it should be recognized that Kres being negative has no formal meaning, a negative Kres is used to represent the contribution of the compressive loading across the crack surfaces This, in turn, is added to the K of the applied loading If closure

is observed at a given crack length, then the measured value of Popen corresponds to the point where Kmin overcomes Kres

In the reported investigation, at the higher stress ratio test condition,

Rapplied=Kmin

and

Since closure was absent in the load-displacement traces at R= 08, with or without LSP, then,

and, therefore, combining Equations (8.18) and (8.19) yields:

Equation (8.20) implies that the magnitude of Kres is less than or equal to 80% Kmax during the R= 08 test For the case of R = 01 testing where Kmax is the same as the

R= 08 test, it follows from Equations (8.15) and (8.16) that:

Reff=01Kmax+ Kres

Kmax+ Kres

(8.21) and

Reff=01Kmax− 08Kmax

Kmax− 08Kmax

(8.22) or

Note that Reff equal to−35 is a limiting value or upper bound (in magnitude) because it

is based on the assumption of Kres= −08Kmax[Equation (8.20)] The above calculations imply an apparent closure level of≈ 80% during crack growth with Reff≈ −35 at the crack tip

It is important to point out that closure contributions at a certain value of K, and residual stresses producing a value of K at the crack tip, are different and independent concepts The effect of closure, quantified by Equation (8.14), reduces the range of K whereas residual stresses reduce the mean stress The behavior of a cracked specimen that has a residual stress can be further understood with the aid of Figure 8.67 where compliance curves are shown for a material that exhibits no crack closure in (a) and for

a material having a closure or opening value, Kop, as shown in (b) In both cases, curves denoted by “A” represent the cracked body with no residual compressive stresses Curves

“B” and “C” depict the behavior for two different degrees of residual stress producing

a calculated Kres of magnitudes Kres 1and Kres 2 From Equation (8.15), the compliance curves are shifted in the negative K direction by different magnitudes For the material with no closure in (a), the point where the resultant value of K is zero represents the point

in the compliance curve where the slope will change The portions of the compliance curves that are dashed, for “negative K,” have no meaning in terms of K and will have slopes in the dashed regions corresponding to a closed crack In terms of applied load, the apparent closure load will be some fraction of the total applied load If the material exhibits crack closure as depicted in (b), the superposition of residual K will produce compliance curves as shown In case B, the inherent closure of the specimen is at a higher

K than the closure produced by the residual stresses In case C, however, the residual

K

(b)

Kop

C

A

B

K

(a)

Kres,2

Kres,1

C

A

B

Figure 8.67. Schematic diagram of compliance curves for (a) closure free specimen, (b) specimen with crack

closure.

stress produces an apparent closure at Keff= 0 such that the material closure is at a lower load level and would not be detected In this case, as in the previous one, negative values

of K have no physical meaning and the compliance below K= 0 is simply that of an uncracked body It should be recognized that the superposition of Kres and Kapplied only has physical meaning if the crack is open at all points along the crack face If the crack is closed, the linear superposition of Equation (8.15) is no longer valid and the mathematical quantities obtained for negative values of K are incorrect The computations of negative values of R for crack growth analysis are also of dubious value or have little physical meaning Note also, in the compliance curves shown schematically in Figure 8.67, the top and bottom of each curve corresponds to the maximum and minimum applied load, respectively Thus, the point where the effective value of K becomes negative has to be considered with respect to where it occurs on the applied load cycle

In the discussion above of crack growth behavior, the load levels applied to obtain continuous crack growth were of a sufficient magnitude to avoid crack arrest as depicted earlier in Figure 8.48 In many of the experiments performed by Ruschau et al [64, 65], the crack growth behavior of an LSP sample indicated that cracking initiated under similar loading levels as those of the baseline samples, grew a short distance, then arrested

as shown in Figure 8.68 This crack arrest behavior for LSP samples required that the maximum cyclic stress had to be increased (5–10%) in order to re-initiate cracking Again, this re-initiated crack often arrested after minimal growth, forcing the continual process of increasing the peak cyclic stress to re-propagate the crack until steady state crack growth eventually took place and the crack propagated to failure

0 1 2 3 4 5 6 7

0 2,50,000 5,00,000 7,50,000 10,00,000

no LSP LSP

Cycles

Crack arrest

R = 0.1

Pmax= 2615 N

Figure 8.68. Crack length vs cycles data for baseline and LSP samples.

The crack arrest behavior can be attributed to large compressive residual stresses in the LSP region which display a steep gradient near the leading edge, increasing in intensity

a short distance from the leading edge as illustrated in Figure 8.63 For a propagating crack, as discussed above, this non-uniform stress field results in a residual compressive stress field at the crack tip and hence an effective compressive stress intensity, Kres, that increases in absolute value with increasing crack length, thus producing crack arrest For crack growth to continue, the applied maximum stress intensity, Kmax, at the crack tip must exceed Kres as well as the inherent threshold stress intensity range, Kth, of the material The sequential growth and arrest behavior can be explained with the aid of Figures 8.69 and 8.70 which were constructed using the stress intensity solution for the airfoil geometry, Equations (8.12) and (8.13), and an expression for Kres The latter could

be derived, in principal, from the residual stress profiles shown in Figures 8.63 and 8.64 and a lot of interpolation, taking into account the three-dimensional nature of the problem due to the increase in specimen thickness with increasing crack length (see Figure 8.61) Instead, Figures 8.69 and 8.70 are constructed using some numerical simulations that include a crude approximation of the residual stress profile deduced by Lykins and John [67] for the same airfoil geometry and the same material used by Ruschau et al These figures are discussed later

In [67], as in [64], crack arrest occurred when the crack was in the LSP processed region, requiring an increase in load to continue the crack growth The sequence of crack growth and arrest that was obtained with incremental increases in the applied load is shown in Figure 8.71, where the dashed line represents the experimental observations From numerous measurements of the applied load and crack length where arrest occurred, Lykins and John [67] were able to calculate the value of the applied K at that point Then, having data for the threshold stress intensity for the corresponding values of R, the

–3 –2 –1 0 1 2 3 4 5

K applied

K residual

K total

Crack length (mm)

σ * = 1.0

Figure 8.69. Dimensionless K for airfoil specimen for applied stress ∗= 1.

0 0.5 1 1.5 2 2.5

σ* = 1.0

σ* = 1.1

σ* = 1.2

σ* = 1.5

Crack length (mm)

Figure 8.70 Kvalues for several applied load levels in airfoil geometry.

0.0 1.0 2.0 3.0 4.0

0 1 × 107 2 × 107 3 × 107 4 × 107 5 × 107

Cycles, N

Measured Calculated

Pmax= 2.04 kN

4.6 kN

R= 0.1

Figure 8.71. Crack growth behavior in airfoil geometry with LSP.

value of Kreswas computed at that threshold condition From this, a curve of Kres against crack length was deduced and subsequently used to predict the growth rate behavior using a da/dN curve having the appropriate threshold value The approach taken and the numerical results are shown in Figure 8.72 which utilizes a value of Kth from other experiments The curve indicated as “calculated Kres” is a visual best fit to the computed values of Kres over the range in crack lengths for which data were obtained Using this curve and a fit to da/dN data, the growth rate/arrest behavior, shown in Figure 8.71, was well predicted

Using a very crude approximation to the shape of the Kres profile from [67] and the

K solution for the airfoil, Equations (8.12) and (8.13), some numerical simulations are presented to illustrate the growth/arrest behavior that can occur within a compressive residual stress field In Figure 8.69 the shape of the applied, residual, and total stress

–60 –40 –20 0 20 40 60

Crack length, a (mm)

Kth

Deduced Kres

Calculated

Kres

Figure 8.72. Maximum applied and residual K versus crack length.

intensity are shown The values of stress and K are presented in a dimensionless form and no attempt is made to use real numbers in this illustrative example Additionally, a dimensionless value of the threshold stress intensity is shown as a dashed line correspond-ing to an arbitrarily chosen value of K∗= 07 For the numbers chosen, the total stress intensity barely exceeds the threshold at a crack length in the vicinity of a= 1 mm At a slightly longer crack length, if the crack could have been started at that crack length with

a precrack or starter notch, the crack would be expected to arrest since the applied stress intensity then dips below the threshold The same scenario is depicted in Figure 8.70 in a slightly expanded scale Here, in addition to the total stress intensity at a dimensionless stress (or applied load) of ∗= 1, the total K is shown for values of ∗= 11, 1.2, and 1.5 At ∗= 1, crack arrest is expected at a length of approximately 0.8 mm If the load is increased to ∗= 11, the crack should resume propagation until it reaches a length “a” approximately 1.6 mm Further increase in load to ∗= 12 should produce continued crack propagation until a length of about 3 mm where the crack barely arrests

If the applied load is ∗= 15, no crack arrest should occur once the crack has been started This is equivalent to the case cited above where crack growth data were obtained throughout a test on an LSP sample

Another example of the use of compressive residual stresses to retard crack growth is found in the work of Kang et al [68] who used residual stresses from welding to retard crack growth in edge cracked specimens of a structural steel They evaluated two methods for evaluating Keff in the presence of a residual stress field The first, defined as the

R method, considers K and R to be determined from the applied K values and the

computed Kres as shown in Equations (8.15) and (8.16) The value of Kres as a function

of crack length, a, is found from the conventional weight function method as

Kresa= a

0

where px a is the weight function for the specific geometry used and resx is the initial residual stress field in an unflawed specimen It is important to point out that the computations are valid only when the entire crack is open under the total loading, that is the stress field due to the applied load plus the residual stress field

The second method used in [68] involved the use of experimental closure (or crack opening) measurements to determine the effective value of K The two methods, based

on calculations of Kres and Kop, were used to compare experimental crack growth rate measurements It was found that, in the region where the residual stresses changed sign from compression to tension, the R method gave non-conservative results in comparing experimental crack growth rates to predicted values The predictions, based on measured values of Kop, were also not very good unless the load-displacement traces, used to determine Kop, were interpreted to distinguish between the opening and the closing portion

of the cycle The authors concluded that the behavior of the crack, in the region where the residual stress field went from compression to tension, involved a partial opening of the crack This would violate the assumption of a fully open crack in the calculations

of the value of Kres as indicated above Their speculation centers around the correct determination of the opening load when the load-up and unload traces are slightly different

in the compliance measurements

In determining thresholds for high cycle fatigue, it is important to recognize the limitations of the approaches for determining the effective value of K in crack growth analysis This, in turn, creates concerns in applying these approaches to the threshold condition for long life (crack arrest) based on experimental measurements on a specimen

or component that has been subjected to a residual compressive stress field

We conclude the discussion of the use of compressive residual stresses in retarding or arresting cracks with some simple numerical examples of a two-dimensional body with

a crack growing from the edge from applied far-field loads In addition to the applied

K, a residual K will reduce the total K depending on the residual compression induced

in the specimen We specifically examine the effects of the depth of the residual stress field and the shape For this purpose, we take two depths, 0.1 and 1 mm, and two shapes, uniform and triangular, as depicted in Figure 8.73 The shallow depth is representative

of a typical magnitude imparted by conventional shot peening while the deeper residual stresses are representative of methods such as LSP or LPB or deep roller burnishing The triangular profile is a more realistic representation of what has been measured for the

0.1 mm 1mm

Uniform

Triangular

Figure 8.73. Profiles of residual stress fields used in numerical examples.

residual stress field rather than the uniform stress which is a mathematical approximation

in some analyses

The residual K values for the stress profiles of Figure 8.73 are shown in Figures 8.74 and 8.75 for a residual stress amplitude (maximum) of 100 MPa for the shallow and deep profiles, respectively Both stress and K are shown here as positive values but for residual compressive stresses, the stresses are negative as are the values of K These are only mathematical values of K and although they are negative, they are to be subtracted from the values of K for the applied stresses Figure 8.74, for the shallow residual stresses, shows that the residual K peaks at about the depth of the stress profile (0.1 mm) for the uniform stress while K peaks at a value of about half of that for the triangular profile For the deep stress profile, the identical trends are observed In fact, if the depth is made dimensionless by using a/t, where t is the total thickness, or by using a/d where d is

0 0.5 1 1.5 2

Uniform Triangular

Crack depth, a (mm)

σres = 100 MPa Shallow

Figure 8.74. Residual K from the residual stress fields of Figure 8.73 for shallow residual stress profile,

 = 100 MPa.

0 1 2 3 4 5 6 7 8

Uniform

Triangular

Crack depth, a (mm)

σres = 100 MPa Deep

Figure 8.75. Residual K from the residual stress fields of Figure 8.73 for deep residual stress profile,  res =

100 MPa.

the depth of the residual stresses, then the plots are identical For K, the numerical values are proportional to√

a Figures 8.74 and 8.75 are identical, then, if K values are reduced

by √

10 and “a” is normalized to a/d In both cases, the residual stresses continue to have an effect on the residual K for depths far beyond the depth of the stress profile

It is often (mistakenly) assumed in the literature that the crack is retarded only when it

is in the residual stress field These computations illustrate that it is the value of K, not the stress field at the crack tip, that retards crack growth As noted previously, the K calculations are valid only for a fully open crack and become invalid when the residual

K (compression) exceeds the applied K (tension)

We conclude the discussion of residual stresses with some comments and observations on autofrettage, a metal fabrication technique in which the stock is momentarily subjected

to enormous pressure Also known as strain hardening, the goal of autofrettage is to increase the resistance to fatigue, either crack initiation, or crack propagation, of the part The technique is commonly used in the manufacture of high pressure pump cylinders, battleship cannon barrels, and fuel injection systems for diesel engines Autofrettage became an important consideration during World War II when it was first used in the production of large numbers of cannon by the US Army

The pressurization of a cylinder can provide beneficial effects in fatigue by either inducing residual compressive stresses at the inner diameter or through the process of strain hardening the material in the same region In both cases, the material has to be deformed beyond the elastic limit The stresses in a cylinder due to internal pressure are easily computed for the elastic case from well-known equations in the theory of elasticity

b r

pi

Figure 8.76. Schematic diagram of hollow cylinder with nomenclature.

such as found in [69] Denoting the internal pressure by pi, the radial position by r, and the dimensions of the cylinder as shown in Figure 8.76, the hoop stresses are

= a2pi

b2− a2



1+b2

r2



(8.25)

Theses stresses are plotted in Figure 8.77 for several different ratios of b/a, the ratio

of the outer to inner diameter of the cylinder From both the plot as well as from the equation, it is readily seen that the maximum hoop stress is at the inner diameter The magnitude of this maximum stress is

 max=pia2+ b2

0 5 10 15 20 25

b /a= 1.05

b /a= 1.25

b /a= 1.5

b /a= 2

r /a

Figure 8.77. Normalized hoop stresses for cylinder with internal pressure.