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Fatigue Life Assessment of Cut Edges in High Strength Steel
In Cooperation With Volvo Construction Equipment AB
ILONA BARMICHO
Master of Science Thesis in Lightweight Structures Dept of Aeronautical and Vehicle Engineering
Stockholm, Sweden 2015
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Fatigue Life Assessment of Cut Edges in High Strength Steel
Ilona Barmicho
A Master Thesis Report written in collaboration with
Department of Aeronautical and Vehicle Engineering
Royal Institute of Technology
Stockholm, Sweden
And
Volvo Construction Equipment
Braås, Sweden
Aug 2015
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1
Master of Science Thesis ISSN 1651-7660 TRITA-AVE 2015:56
Fatigue life assessment of cut edges in high strength steel
Ilona Barmicho
Approved
Examiner
Stefan Hallström
Supervisor
Zuheir Barsoum
Commissioner
Volvo Construction Equipment AB
Contact person
Bertil Jonsson
Abstract The interests in more effective and lighter structures have increased the use of high strength
steels for higher performances. Plate materials are optimized so thinner structures and higher
material strengths are reached, this leads to the cut quality might be a new issue.
In this investigation steel thickness of 6 and 16 mm with minimum yield strength from 355 to
960 MPa are fatigue tested with constant amplitude tensile loading. The specimens were cut
using waterjet and also with thermally cut methods such as plasma and oxygen. Before fatigue
testing the cut surfaces were measured and roughness Rz values were obtained.
Empirical and analytical results of the surface roughness influencing the fatigue strength for
different steel strengths are presented.
Since thermal cutting methods have been developed over the years the FAT values are higher for
those IIW are recommending.
When the quality of the cut surface can be kept high the fatigue strength will also be higher than
those recommended. This means having a cutting process that provides smooth surfaces such as
waterjet and plasma cutting the fatigue life will be longer.
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ACKNOWLEDGMENT
I would like to extend my gratitude to my supervisors
- Zuheir Barsoum, PhD, Sr Lecturer, KTH – Lightweight Structures
- Thomas Stenberg, PhD, KTH – Lightweight Structures
- Bertil Jonsson, Expert Weld Strength, Volvo Construction Equipment AB
for their invaluable guidance, feedback and support through this master thesis.
I would also like to thank Mansoor Khurshid, PhD student at KTH Lightweight structures for his
inputs and help with the fatigue testing. A big thank to Torbjörn Narström at SSAB.
Lastly I want to thank my family for their love, support and patience.
Ilona Barmicho
Stockholm, Sep 2015
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NOMENCLATURE
Below are the symbols and abbreviations used in this report listed.
Notations
Symbol Description
C Capacity value in SN-curve
m Slope of SN-curve
t Thickness
K Stress intensity factor
Δσ Stress range
a Crack length
f Geometry function
C0 Crack propagation constant in Paris’ law
m0 Crack propagation exponent in Paris’ law
N Number of cycles
R Stress ratio
Abbreviations
LEFM Linear Elastic Fracture Mechanics
HAZ Heat Affected Zone
FEA Finite Element Analysis
FE Finite Element
SIF Stress Intensity Factor
SN curve Wöhler curve
FAT Characteristic Fatigue Strength
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TABLE OF CONTENTS
NOMENCLATURE 3
TABLE OF CONTENTS 4
1. INTRODUCTION 6
1.1 Background 6
1.2 Purpose 6
1.3 Delimitations 6
1.4 Method 6
2. THEORY 8
2.1 Materials and test specimen 8
2.2 Thermal cutting 10
Laser 10
Gas 11
Waterjet 11
Plasma 11
2.3 Fatigue life calculation 11
Roughness 11
LEFM – Linear Elastic Fracture Mechanics 12
Stress intensity factor (SIF) 13
S-N curve 13
3. METHOD 15
3.1 Materials and test specimens 15
3.2 Cutting 15
3.3 Surface roughness measurement 16
3.4 Fatigue test 17
3.5 Fracture Mechanics Analysis 18
4. RESULTS 20
4.1 Surface Roughness 20
4.2 Fatigue life 22
5. DISCUSSION AND CONCLUSIONS 27
5.1 Discussion 27
5.2 Conclusions 27
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6. RECOMMENDATIONS AND FUTURE WORK 29
REFERENCES 30
APPENDIX A: DIVISION OF SPECIMENS 31
APPENDIX B: TEST PROGRAM 32
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1. INTRODUCTION
This section contains the background of the thesis and the purpose, delimitations and used
methods.
1.1 Background Lately high strength steels have been applied for lightweight structures in order to reduce weight
and fabrication costs and to contribute to the performance. In many kind of structures there is a
need of achieving lighter and more optimized solutions. Since there are new weld treatment
methods that enhances the weld quality; plate materials may be optimized so that thinner
structures and higher material strength are reached. Consequently the quality of the cut sections
might become a new design issue. The roughness of the plate surface and the cut edges are the
main factors affecting the fatigue crack propagation, at least when large crack-like defects are at
hand. It has been seen that the fatigue strength of the base material increases by increasing the
yield strength of steel. It is important, both for internal communication in the producing
company, but also the outsourcing of cutting to suppliers, that there is a clear and concrete
regulations with scientific foundation that describes the quality of the cut edge. Describing the
quality level so that intended fatigue life targets are reached is one of the problems treated in this
thesis work.
1.2 Purpose
The purpose of this investigation is to see how cutting materials with different methods are
affected by the surface roughness and the fatigue life of the structures. The small surface defects
might have great impact on the product. What is not known is how big impact it actually has.
Specimens with geometry according to Figure 1 are in need to be developed and then fatigue
tested in order to study the distribution in fatigue life and crack initiation point to determine the
relationship between the surface roughness and the fatigue life. Linear elastic fracture
mechanics, LEFM, should be used to get results analytically and then be compared with the
experimental results. FE-simulations shall be made to determine the stress distribution of the
specimens. A similar study has already been made before by SSAB and can be found in SSAB
Plåthandbok [1] and in [2]. The reason why it is continued is because it is intended to
complement with thicker plates and also with waterjet cutting to avoid HAZ.
1.3 Delimitations
Delimitations have been summarized in a number of points, which follow:
This thesis project is part of a bigger research project, which means that only a small part
will be included within this scope.
No metallurgy studies are included in the project.
Residual stress measurement will not be included.
Only small-scaled specimens will be tested and analysed.
1.4 Method
A literary study should be performed in order to provide more background knowledge about:
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Cutting methods and how they are performed.
Surface roughness measurements, how it is performed.
Fatigue life assessment.
Measurements
Surface conditions (e.g. roughness)
Dimensions
Steel strength
FEA – Finite Element Analysis
Fracture mechanics
Fatigue
Fatigue testing
Tensile testing
Comparison with FEA
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2. THEORY
This section presents the theoretical reference frame that is necessary for the performed project,
such as the material, cutting methods and calculations.
2.1 Materials and test specimen
The tested specimens were manufactured from high strength steel with varied thicknesses from
16 to 40 mm with minimum yield strengths from 355 to 960 MPa. In order to distribute the stress
concentration to the middle, the specimens were shaped as dog bones with geometry according
to Figure 1 below.
Figure 1.”Dog bone” shaped specimen with geometry for fatigue test.
Due to limitations in fatigue test rig-capacity specimens should be small, there is also a possible
influence from HAZ – heat affected zone. Since the specimens were cut with different methods
that require heat it can cause severe damage to the work piece. Therefor 20 specimens were
produced with two different widths to compare the fatigue life of the two different kind of
specimen. According to Table 1 provided by SSAB the fatigue life should not be affected
considerably, which also showed when testing the specimens. The simulated geometry is
therefore acceptable.
Table 1. Heat affected zone for thermal cuttings.
t [mm] 15 30 50
Laser cut HAZ [mm] 1 - -
Gas cut HAZ [mm] 3 5 7
Plasma cut HAZ [mm] 1.5 2.5 4
The test specimens were manufactured from 6000×2500 mm steel plate, Table 2 below shows
how many of each steel grade, thickness and cutting method needed to be manufactured in order
to get proper amount of test specimens. How the specimens were cut out of each steel plate can
be found in Appendix A.
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Table 2. Amount of specimens for testing.
t [mm] Re 355 Re 700 Re 960
Laser Gas Plasma Laser Gas Plasma Waterjet Laser Gas Plasma
6 - - - - - - 15 - - -
16 45 45 45 30 30 30 - 30 30 30
25 - 15 15 - 15 15 - - 15 15
40 - 15 30 - 15 30 - - 30 30
Around ten specimens of every thickness, steel grade and cut method had to be tested to get
relevant and comparable results. The total amount of specimens tested at KTH was 180, since
limitations with the hydraulic fatigue test machine. All of these are not covered within this
thesis; the complete results will be published elsewhere. In Table 3 below it is shown which are
included in the thesis work and Table 4 shows the chemical composition of the steel used.
Table 3. Specimens included in this thesis project.
t [mm] Gas cut Waterjet cut Plasma cut
6 - S700 - 16 S355 - S355 16 S960 - S960
Table 4. Chemical composition of the steel tested.
Grade C Si Mn P S Cr Ni Mo V Ti Cu Al N Nb B
S355 0.15 0.34 1.41 0.006 0.001 0.04 0.07 0.021 0.037 0.008 0.01 0.034 0.008 - -
S700 0.14 0.30 1.14 0.014 0.001 0.30 0.05 0.169 0.014 0.008 0.01 0.040 0.003 0.001 0.002
S960 0.17 0.23 1.26 0.008 0.001 0.20 0.06 0.600 0.041 0.003 0.01 0.052 0.003 0.015 0.001
All specimens were named in one consistent way. They were marked with the yield strength, the
cut process and sample number according to Figure 2.
Figure 2. Naming of specimens.
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After the cutting, the edges were grinded from the plate side to ensure a sufficient connection
between the cut surface and the fatigue strength, without influence from the cut edges surface
conditions.
Waterjet cutting will also be investigated since no heat is added in the cutting process and
therefore there will be no HAZ in the material. The specimens cut by the waterjet were smaller
than the other specimens due to limitations in the cutting range in the waterjet machine. The
proportions are the same as for the other specimens, see Figure 3.
Figure 3. Geometry of specimen cut with waterjet.
2.2 Thermal cutting
Thermal cutting is most often used as preparation of the material before welding. It is a way of
cutting that has been developed considerably well, especially laser and plasma cutting [3]. In this
thesis only three different methods were used, gas, plasma and waterjet cutting. This to compare
in what extent the cut edge with its roughness is affecting the fatigue life. One significant
occurrence when cutting steel thermally is the phenomena denoted HAZ, heat affected zone as
mentioned before. It means that the material near the cut gets thermally damaged, the material is
not melted and its microstructure and properties has changed due to the heat. This is why
waterjet cutting will also be investigated since no heat is added in the cutting process and
therefore there will be no HAZ in the material. The methods are listed and explained below, for
this project the plasma and gas cutting was carried out at a supplier BE group and the waterjet
cut specimens at the mechanical department at KTH.
Laser
The laser beam with a diameter of 0.05-0.25 mm is focused by a lens or mirror against the work
piece where the beam is concentrated to a little point, which then melts, burns, vaporises or
blows away materials. During the laser cutting process an assisting gas is used to protect the
surface for oxidation reactions. The temperature gradient generated in the cutting section
becomes high during the process; which results in high residual stress levels while reducing the
end product quality. The advantages of laser are the accuracy, speed and flexibility [4]. Laser cut
edges also becomes straight, shiny and thin with small loss of material. The influence of the laser
cutting is characterized as the profile ratio of the striations formed in the cut edge surface and
this has a major influence.
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Gas
When cutting metal using gas, most often acetylene or propane is used. The gas combusts in
oxygen and the flame with high temperature is then used to preheat the work piece. When
sufficient high temperature is reached a beam of oxygen perform the actual cutting process by
combustion of the metal.
Waterjet
Waterjet cutting uses only water, when cutting in soft and porous materials, for harder materials
sand is added in order to cut through the material. No heat exposure or thermal stresses occur
that affect the results. What is important in this case is to realise that the water speed is affecting
the surface roughness and near edge stresses [5]. The angle of the surface striations depends on
the relationship between the traverse cutting speed and water pressure. Increasing the speed at
given pressure increases the angle of striation until a through cut is no longer achieved. Also if
the nozzle is holding straight above the work piece maximum surface roughness is obtained. [5].
For this case the specimens were cut with a cutting speed of approximately 5 m/s and a pressure
of 3400 Bar.
Plasma
Plasma cutting is a process used to cut steel using plasma torch. The temperature of the plasma
arc melts the metal and pierces through the work piece while the gas flow removes the molten
material of the cut. Two important parameters that can be changed in plasma cutting are the
current intensity and cutting speed, which is what determine the quality of the cut-edge surface
and the width of the HAZ [6].
2.3 Fatigue life calculation Parent material that has not been welded could be critical for the fatigue life, where the loading
capacity is limited by the maximum stress that requires for initiating a fatigue crack.
Roughness Since the fatigue strength for parent materials is increasing with increased yield strength the
surface quality is of importance. The fatigue life of thermally cut specimens are depended of the
different cutting methods and cut qualities. This is why the roughness of the cut edges needed to
be measured. Here the results from the measurements are expressed as peak to valley height Rz
and average height of the surface roughness Ra, see Figure 4 and Figure 5. They are calculated
according to in equation(1) and equation(2).
Figure 4. Explanation of Rz.
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5 5
,max ,min
1 1
1
5z i j
i j
R z z
(1)
Figure 5. Explanation of Ra.
0
1L
aR z dxL
(2)
LEFM – Linear Elastic Fracture Mechanics To predict crack growth in structures subjected to fatigue loads linear elastic fracture mechanics
(LEFM) is used. It is based on the assumption that there are defects in the structure and that the
stresses at the crack tip tend to infinity. This is the only method that takes the crack growth, from
the initial stage into the material, into account. A crack can be loaded in three different ways, see
Figure 6.
Figure 6. Crack modes: opening mode, in-plane shear and out-of-plane shear.
Only Mode I crack propagation will be considered within this project, since the expected crack
plane is perpendicular to the applied tensile loading. A disadvantage with LEFM is the extra
working effort needed since several different FE-simulations must be performed in order to get
enough points to describe the integration in Paris power law.
When calculating the number of cycles to failure the integration in Paris law, equation(3), is
used, where both C0 and m0 are material constants here 12
0 5 10 , /C MPa m m cycle and
0 3m with a failure probability Pf=50% according to IIW recommendations [7] the stress
intensity range ΔKI equation(4) is implemented. It depends on the length of the crack, a, stress
range, Δσ, and f which is the function of geometry loading, equation(5), with a width 18w mm
of the specimen.
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m
I
daC K
dN (3)
IK a f (4)
0
0 00 0
0
2tan cos 0.75 2.02 0.37 1 sin
2 2 2
ma aa aw
fa w w w w
(5)
When solving the fatigue life it becomes as follows, see equation(6).
1
( )
f
i
a
m m
a
daN
C a f a
(6)
The stress intensity factor describes the stress rate near the crack tip and is calculated both
analytically and with finite element analysis FEA.
Since SIF depends on the crack length a, the integration is solved numerically using MATLAB.
Stress intensity factor (SIF) The stress intensity factor, SIF, is important to determine in linear elastic fracture mechanics and
can be determined analytically with use of the equation(7) below.
I nomK a f (7)
Where σnom is the nominal stress, a crack length and f is the function of geometry and loading.
When calculating the number of cycles to failure the formula Paris law is used and the stress
intensity range ΔKI is implemented, this is explained below.
I,m ,minI ax IK K K (8)
The SIF’s describe the stress state near the crack tip for the three modes and can be calculated
both analytically and with the use of FEA.
S-N curve In order to plot the fatigue strength of a component an S-N diagram, also named Wöhler curve is
used. The logarithm of the fatigue strength as a function of the logarithm of number of cycles in
a measure point is plotted. Usually the test results are distributed and that is why the median is
formulated which gives a failure probability of 50 %. This means that half of the samples are
expected to fail for that specific stress range and corresponding number of cycles.
For fatigue analysis of weld it is more convenient to use the stress range to describe the fatigue
life since residual stresses close to the yield limit can be expected in both tension and
compression. When compressive stresses are applied to a weld where the residual stress is near
the yield limit in tension, the weld will experience a positive stress range even though the weld is
loaded in compression. The stress range is calculated according to equation (9) below and R the
load ratio according to equation(10).
max min (9)
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min
max
R
(10)
In order to calculate the number of cycles to failure the equation(11) below is used, where m0 in
this case is equal to 5 since it is parent materials.
0 0log log logN C m (11)
which gives the fatigue life
0
0
m
CN
(12)
and where C0 is
06
0 2 10m
C FAT (13)
it leads to fatigue life according to equation(14)
0
62 10
mFAT
N
. (14)
Where, according to IIW [7], the FAT-value gives the characteristic fatigue strength at 62 10
cycles. The characteristic fatigue strength is the stress range Δσ or σr for the mean fatigue
strength minus 2 standard deviations, 2.3 % failure probability.
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3. METHOD
It is investigated how great impact of surface defects has on the fatigue life of steel. Steel
specimens were cut with four different methods, laser, plasma, gas and waterjet. For each of
these methods the surface roughness was measured and then fatigue tested with a fatigue-testing
machine at KTH. The stress intensity factors were obtained and the fatigue life calculated as it
can be read below.
3.1 Materials and test specimens As already has been written there were some restrictions with the hydraulic machine, only a
small part of the project were included in this thesis. Therefor only some of the total amount of
specimens were tested and investigated. In the Table 3 it can be seen which specimens were
fatigue tested and included in the thesis, they all had thickness of 16 mm except for waterjet cut
S700 steel which was 6 mm thick. The results can be found in section 4. In Figure 7 the surfaces
of the specimens are shown.
Figure 7. Explanation of the surfaces and edges of the specimen.
3.2 Cutting As written before the specimens were cut with different methods and at different places. Volvo
CE in Braås performed the laser cutting while the plasma and gas cutting at a supplier BE group
and the waterjet at the mechanical engineering department at KTH. Edge inhomogeneities were
removed using a belt grinder, see Figure 8 below.
Plate surface
Cut surface
Cut edge, in M1
Cut edge, out M2
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Figure 8. Belt grinding the specimens.
3.3 Surface roughness measurement It is important to measure the surface roughness to be able to draw parallels between the
roughness and the fatigue life. The measuring was performed at Volvo Construction Equipment
in Eskilstuna with use of a Taylor Hobson profilometer with a two micrometre needle; see Figure
9.
Figure 9. Surface roughness measurement.
At first three positions along both cut edges where measured, see Figure 10. When noticing that
the roughness in the middle of the edge, M3, was too small compared to the sides, M1 and M2,
these results were excluded. It was considered that the outer parts near the edges would be the
most critical ones.
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Figure 10. Where on the specimens the measurements were made.
Ra is plotted against Rz later on in section 4.1 Figure 13 and Figure 14, where Ra is the profiles
arithmetical mean deviation for the reference length and Rz the average height of the surface
roughness. In this report Rz refers to an average of five measurements. According to [8] the cut
can be classified to range 1-4 depending on what method was used, see results in section 4.1.
3.4 Fatigue test The fatigue tests were performed in a 200 kN hydraulic testing machine at KTH, Figure 11, and
in an Amsler 1000 kN pulsator at SSAB. The test frequency at KTH was 20-30 Hz and the tests
were performed in tension with constant amplitude loading with R=0.05. Stress-life fatigue tests
that achieved 65 10 cycles were considered being run out tests. The stress was limited by the
yield strength of the material. The fatigue life calculations were done according to IIW
recommendations [7]. A 2.3% probability to failure using a dual sided confidence interval for 2
million cycles was calculated using an inverse slope of m=5. The results can be seen in section
4.2.
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Figure 11. Fatigue testing at KTH.
3.5 Fracture Mechanics Analysis To be able to compare the experimental results, analytical calculations were made. Fracture
mechanics formulas were used, such as Paris’ power law where plate thicknesses of 16 mm were
investigated. The initial defect in the integral was considered being the surface roughness values
Rz 10 – 400 μm and the life is assumed to be finished when the crack reaches half the plate
thickness. The formulas used are the same formulas presented in section 2.3.
AFGROW is a program used by the United States Department of Defence and used to validate
and predict the fatigue life of structures. This program has been used to determine the fatigue life
of an edge crack in a rectangular specimen with different thicknesses with loading in tension.
AFGROW defines an elliptical crack and together with the Walker equation(15), it confirms the
values from the FE-analysis. The thicknesses of the specimens were set the same as when
calculating with Paris’ law and with a width W = 18 mm. The crack shape ratio a/c was set to
vary from 1 to 10, where c = Rz same values as before and the tensile stress to 100 MPa, the
material constants where set to m=3 and n=0.5. In Figure 12 below it is shown how the geometry
in AFGROW is defined.
(1 )1
m
n
da KC
dN R
(15)
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Figure 12. How the geometry is defined in AFGROW.
The results computed with AFGROW were compared to the results computed with use of
Matlab. The same results were obtained and are presented as analytical FAT-value in section 4.
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4. RESULTS
In this chapter the results that are obtained with the methods described in the method chapter
are compiled, analysed and compared with the existing knowledge and theory presented in the
frame of reference chapter.
4.1 Surface Roughness The results from the surface roughness measurements can be seen in Figure 13 and Figure 14
below, where also the different ISO ranges for roughness are marked according to [7] for
thickness 16 mm. Figure 13 shows the roughness of the side where the cutting flames went in,
M1 in Figure 10, and Figure 14 shows the roughness of the opposite side, M2 in Figure 10.
Figure 13. Surface roughness for the tested specimens on side M1of the cut edge.
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Figure 14. Surface roughness for the tested specimens on side M2 of the cut edge.
Table 5 shows the ranges of the roughness, the maximum and minimum Rz value for each batch
that has been measured and tested.
Table 5. Measured Rz in μm.
Type Gas cut Waterjet cut Plasma cut
S355 S960 S700 S355 S960
Rz [μm] 20 - 140 45 - 200 23 - 37 20 - 170 15 - 56
In the Figure 15-17 below the roughness distributions have been plotted in box diagrams. The
middle lines in each box shows the median value of the roughness, the upper part of the box
represent the third quartile which is the number for which 75% of the data is less than that
number and the lower part of the box represent the first quartile which is the number for which
25% of the data is less than that number. “Edge in” corresponds to M1 and “edge out” to M2 in
Figure 10. It can be noticed by looking at the charts below that M2 is always rougher than M1.
Figure 15. Roughness distribution gas cut.
0
20
40
60
80
100
120
140
160
180
200
355 t16 edge in 355 t16 edge out 960 t16 edge in 960 t16 edge out
Roughness Gas cut
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Figure 16. Roughness distribution for waterjet cut.
Figure 17. Roughness distribution for plasma cut.
4.2 Fatigue life In this section the results from the fatigue testing and the analytical results are presented in
mainly the FAT-value.
The FAT-value at 50% means that there is a failure probability of 50% which is what it is
considered to be when testing experimentally. The evaluated fatigue classes refer to 62 10
cycles and are shown in Table 6.
0
20
40
60
80
100
120
140
160
180
200
700 t6 edge in 700 t6 edge out
Roughness Waterjet cut
0
20
40
60
80
100
120
140
160
180
200
355 t16 edge in 355 t16 edge out 960 t16 edge in 960 t16 edge out
Roughness Plasma cut
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Table 6. FAT-values from both experimental results and analytical.
Edge condition FAT 50% FATanalytical
Gas Cut S355 298 186
Gas cut S960 204 219
Waterjet cut S700 352 276
Plasma cut S355 225 183
Plasma cut S960 162 255
The results from the fracture mechanic analysis are presented in Figure 18 below, as written in
section 3.5 the initial defects are considered being the surface roughness values Rz 10 – 400 μm.
Six different curves are plotted depending on what Rz value is chosen. The life of the specimen
is considered finished when the crack reaches half the plate thickness, which in this case is 8
mm.
Figure 18. Curve from the fracture mechanical analysis.
Figure 19 to Figure 23 represents the SN-curves for each fatigue tested batch; the red crosses are
run out results specimens that did not crack before 5 million cycles. In the all plots the blue dots
represent the failures for each tested specimen and the red crosses are the run outs. The red lines
in the plots to the left at each row represent the analytical FAT values from each batch. The red
lines in each plot to the right represent the FAT values of both the minimum Rz value and the
maximum Rz value from each batch. Specimen number, stress range and corresponding amount
of cycles can be found in Appendix B.
100
1000
10000 100000 1000000 10000000
Stre
ss [
MP
a]
Cycles N [cycles]
Rz=10 µm
Rz=50 µm
Rz=100 µm
Rz=200 µm
Rz=300 µm
Rz=400 µm
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Figure 19. S-N curve for steel with Re 355 MPa and gas cut.
Figure 20. S-N curve for steel with Re 960 MPa and gas cut.
Figure 21. S-N curve for steel with Re 700 MPa and waterjet cut.
10
100
1000
10000 100000 1000000 10000000
No
min
al s
tre
ss r
ange
[M
Pa]
Cycles
S355 Gas cut
Failures
Run outs
Natural mean curve
Mean curve (m=5)
Char. curve (FAT)
FAT 18610
100
1000
10000 100000 1000000 10000000
No
min
al s
tre
ss r
ange
[M
Pa]
Cycles
S355 Gas cut
Failures
Run outs
Natural mean curve
Power (Analytical curve (Rzmin))
Power (Analytical curve (Rzmax))
10
100
1000
10000 100000 1000000 10000000
No
min
al s
tre
ss r
ange
[M
Pa]
Cycles
S960 Gas cut
Failures
Run outs
Natural mean curve
Mean curve (m=5)
Char. curve (FAT)
FAT 219
10
100
1000
10000 100000 1000000 10000000
No
min
al s
tre
ss r
ange
[M
Pa]
Cycles
S960 Gas cut
Failures
Run outs
Natural mean curve
Power (Analytical curve (Rzmin))
Power (Analytical curve (Rzmax))
10
100
1000
10000,0 100000,0 1000000,0 10000000,0
No
min
al s
tre
ss r
ange
[M
Pa]
Cycles
S700 Waterjet cut
Failures
Run outs
Natural mean curve
Mean curve (m=5)
Char. curve (FAT)
FAT 27610
100
1000
10000 100000 1000000 10000000
No
min
al s
tre
ss r
ange
[M
Pa]
Cycles
S700 Waterjet cut
Failures
Run outs
Natural mean curve
Power (Analytical curve (Rzmin))
Power (Analytical curve (Rzmax))
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Figure 22. S-N curve for steel with Re 355 MPa and plasma cut.
Figure 23. S-N curve for steel with Re 960 MPa and plasma cut.
10
100
1000
10000 100000 1000000 10000000
No
min
al s
tre
ss r
ange
[M
Pa]
Cycles
S355 Plasma cut
Failures
Run outs
Natural mean curve
Mean curve (m=5)
Char. curve (FAT)
FAT 18310
100
1000
10000 100000 1000000 10000000
No
min
al s
tre
ss r
ange
[M
Pa]
Cycles
S355 Plasma cut
Failures
Run outs
Natural mean curve
Power (Analytical curve (Rzmin))
Power (Analytical curve (Rzmax))
10
100
1000
10000 100000 1000000 10000000
No
min
al s
tre
ss r
ange
[M
Pa]
Cycles
S960 Plasma cut
Failures
Run outs
Natural mean curve
Mean curve (m=5)
Char. curve (FAT)
FAT 25510
100
1000
1000 10000 100000 1000000 10000000
No
min
al s
tre
ss r
ange
[M
Pa]
Cycles
S960 Plasma cut
Failures
Run outs
Natural mean curve
Power (Analytical curve (Rzmin))
Power (Analytical curve (Rzmax))
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In Figure 24Error! Reference source not found. below the FAT-values for each batch with
median surface roughness are presented. What are also plotted are the values from SSAB’s
investigation that can be found in SSAB Plåthandbok [1] in section 5.4. The plotted values are
the FAT-values of steel with yield strengths 355, 700 and 960 MPa and at each yield strength
three different surface roughness, 30, 60 and 120 MPa. As can be seen below the SSAB results
correspond quite well with the experimental and analytical results of steel with yield strength
700 MPa. The SSAB values correspond better to the analytical results than the experimental.
Figure 24. Median surface roughness for each batch.
Rz=50
Rz=50 Rz=110
Rz=110
Rz=30
Rz=30
Rz=60
Rz=30
Rz=30
80
130
180
230
280
330
380
0 200 400 600 800 1000 1200
FAT5
0%
[M
Pa]
Yield Strength [MPa]
355 GAS experimental
355 GAS analytical
960 GAS experimental
960 GAS analytical
700 WATER experimental
700 WATER analytical
355 PLASMA experimental
355 PLASMA analytical
960 PLASMA experimental
960 PLASMA analytical
SSAB Re=355 MPa
SSAB Re=700 MPa
SSAB Re=960 MPa
Rz=30
Rz=60
Rz=120
Rz=120
Rz=60
Rz=30
Rz=120
Rz=60
Rz=30
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5. DISCUSSION AND CONCLUSIONS
A discussion of the results and the conclusions that has been drawn during the Master of Science
thesis are presented in this chapter. The conclusions are based from the analysis.
5.1 Discussion
The purpose of this project was to investigate how the cut surfaces influence the fatigue life, this
in order to know in what extent and way it is possible to save weight.
Before measuring the surface roughness slag and other oxides from the cutting had to be
removed from the specimens. Because of the slag some surface roughness results might not have
been completely accurate; there are some uncertainties in the results. When measuring it was not
possible to get the roughness in the middle of the specimens since the needle couldn’t reach
down but this would probably not matter that much.
It was considered that this thesis would cover variable amplitude load testing but since the steel
with yield strength of 355 MPa is very ductile it was impossible to get any crack failures. Also
since the hydraulic machine only allowed dynamic load up to 200 kN. After some testing
without any failures the approach was change to constant amplitude instead. This would
probably have worked if the cut edges were rougher. It was also important to not load with
higher levels than the yield strength since the steel starts to plasticise and the properties changes.
The material behaves then differently than expected.
Since some of the specimen edges were ascut by the supplier the specimen started to crack at the
plate surface instead of the cut edge. This happened because the plate surface became rougher
than the cut edge, since it has an influence the surface of the plate should be investigated more
thoroughly. Edge preparation probably gives a bigger scatter in the roughness and it should
therefore be specified a requirement for the surface roughness of the plate surface and the edge
between the plate surface and the cut edge as well, see Figure 7.
During the thesis project some problems have occurred, such as machine breakdown and late
deliveries of specimens which has delayed the project. That is why there was no time to run
more tests. It is preferable to have more results to compare that would have given more reliable
results.
5.2 Conclusions
The surface roughness is generally rougher on the M2 side in Figure 10 and the scatter is also
larger. Increasing of the yield strength gives a rougher surface for the gas cutting method and
less rough for the plasma cutting.
Thus, if cutting thicker specimens and a high surface quality, i.e. less rough surface, is needed, it
is recommended to use Plasma cutting. The scatter in analytical and experimental fatigue
strength, see Figure 23, is probably influenced by the manual edge preparation. Further testing is
needed
Figure 19 to Figure 23 shows how well the analytical calculations correlate with the
experimental. The plasma cut steel regardless of yield strength correlate well and the gas cut
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28
steel with yield strength of 355 MPa also does. It is therefore not clear if it is only the high
strength or the low strength steels that correlate better than the other.
The results show that if the quality of cutting can be kept high the fatigue strength will be higher
than those recommended in by IIW. This means that having a cutting process that provides a
smooth surface the cracks will not initiate because of the surface roughness in first hand.
Therefore waterjet cutting and plasma cutting are good alternative in order to get high fatigue life
not affected by the surface roughness of the cut edges.
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6. RECOMMENDATIONS AND FUTURE WORK
In this chapter, recommendations on more detailed solutions and/or future work in this field are
presented.
Perform some more fatigue tests of the same batch as already been tested and with more
scattered loads, and re-measure the surface roughness of those. Since there was a lot of slag on
the surfaces there is probably in need of some more tests. Also continue with the fatigue tests of
the other batches. This in order to get more results to compare with and also more accurate once.
Be aware of where the crack starts and make sure that the cut edge has the roughest surface
otherwise it will not crack within right number of cycles.
One should also measure residual stresses in specimens of each batch to be able to set accurate
loads when testing and to be able to compare the right experimental and analytical results.
Fatigue testing with variable amplitude loading should be executed and compared with the
results from constant amplitude.
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REFERENCES
1. SSAB Plåthandbok
2. J-O. Sperle, “Influence of parent metal strength on the fatigue strength of parent material
with machined and thermally cut edges”, IIW Document XIII-2174-07
3. K. Weman, “Svetshandboken”, Stockholm: Liber, 2007.
4. K. Mäntyjärvi, A. Väisänen, J. A. Karjalainen, “Cutting method influence on the fatigue
resistance of ultra-high-strength steel”. Int J Mater Form Vol. 2 Suppl 1:547–550. Oulu,
2009
5. Daniel J. Thomas, “Characteristics of abrasive waterjet cut-edges and the affect on
formability and fatigue performance of high strength steels”. Journal of Manufacturing
Processes 11. 97_105, Port Talbot, 2009.
6. Daniel J. Thomas, “The influence of the laser and plasma traverse cutting speed process
parameter on the cut-edge characteristics and durability of Yellow Goods vehicle
applications”. Journal of Manufacturing Processes 13, 120–132, Swansea, 2011.
7. Hobbacher A., “Fatigue design of welded joints and components”, IIW doc. XIII-1539-96,
1996.
8. SS-EN ISO 9013:2002 Thermal cutting – Classification of thermal cuts – Geometrical
product specification and quality tolerances, Swedish Standards Institute, Stockholm, 2003.
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APPENDIX A: DIVISION OF SPECIMENS
This is how the specimens were cut out of each steel plate.
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32
APPENDIX B: TEST PROGRAM These are the tested specimen with the stress range and at how many cycles they failed or did not
fail. Run out was considered at 5 million cycles.
Specimen σr N
Specimen σr N
No [MPa] [cycles]
No [MPa] [cycles]
S355-G-03 291,65 Runout
S355-P-01 337,25 317849
S355-G-04 332,5 Runout
S355-P-02 275,5 Runout
S355-G-05 332,5 629027
S355-P-09 327,75 445716
S355-G-06 337,25 Runout
S355-P-10 323 513400
S355-G-07 327,75 Runout
S355-P-03 313,5 431958
S355-G-08 351,5 1872394
S355-P-06 285 455021
S355-G-09 365,75 290921
S355-P-07 304 1955000
S355-G-10 380 106698
S355-P-20 256,5 Runout
S355-G-11 356,25 59642
S355-P-21 332,5 355822
S355-P-22 285 702918
W960-G-02 608 100000 W960-G-03 380 414933
W960-P-04 654,55 86281
W960-G-04 475 167772
W960-P-05 617,5 86047
W960-G-05 427,5 302042
W960-P-07 408,5 231761
W960-G-06 332,5 483041
W960-P-02 570 110000
W960-G-07 522,5 151605
W960-P-03 475 100545
W960-G-08 446,5 259607
W960-P-06 437 201651
W960-P-08 475 214592
W700-W-01 665 147197
W960-P-10 408,5 246113
W700-W-02 380 Runout
W960-P-01 437 121498
W700-W-03 475 3113018
W960-P-11 475 922638
W700-W-04 570 352957
W960-P-12 475 247969
W700-W-05 522,5 345066 W700-W-06 617,5 102296 W700-W-07 641,25 178079 W700-W-08 617,5 144254 W700-W-09 522,5 Runout W700-W-10 593,75 171000