Microsoft Word - numero_34_art_10 C. Fischer et alii, Frattura ed Integrità Strutturale, 34 (2015) 99-108; DOI: 10.3221/IGF-ESIS.34.10 99 Focussed on Crack Paths Influence of local stress concentrations on the crack propagation in complex welded components C. Fischer, W. Fricke Hamburg University of Technology, Institute of Ship Structural Design and Analysis, Hamburg, Germany w.fricke@tuhh.de ABSTRACT. While a long stable crack propagation phase was observed during experiments of complex welded components, very conservative assessments of the fatigue life were achieved in the past. The difference was explained by the stress gradient occurring over the plate thickness. This paper deals with numerical crack propagation simulations which were performed for different geometrical variants. The variants differ related to global geometry, boundary conditions and weld shape. The analyses aim to investigate how the crack propagation is altered if the structural configuration gets more complex. In conclusion, the stress gradient over the plate thickness, the apparent plate thickness and the notch effect slows down the crack propagation rate if the same stress value being effective for fatigue appears at the weld toe. Thereby, the load-carrying grade of the weld, the weld flank angle and the geometrical configuration have an impact on both the notch effect and the local stress concentration. KEYWORDS. Crack propagation simulation; Fatigue life; Notch effect; Stress gradient. INTRODUCTION omplex welded components can have hot-spots showing high local stresses with steep stress gradients. These could be critical with respect to fatigue. An example is the three-dimensional intersection of plates shown as variant 5 in Fig. 1. Different variants of this detail were experimentally investigated by means of both large-scale and small-scale fatigue tests over the last decades, see e.g. [2, 11-15]. Dijkstra et al. [2] observed an early crack initiation, but a long period of stable crack propagation until the crack had grown through the loaded plate. However, very conservative fatigue assessments were discovered applying the common fatigue approaches to complex structures, see e.g. [6, 7]. Lotsberg and Sigurdsson [14] explained the disagreement by the stress gradient over the plate thickness which was not covered by the fatigue approach they had selected. Fischer and Fricke [5] established three additional reasons: the apparent plate thickness, the load-carrying grade of the weld and bending constraints of the detail. They supposed correction factors to account for these influences in the fatigue assessment. Generally, the approaches are based on the analysis of tests of small-scale specimens with more or less simple welded joints. Here, no three-dimensional complex stress distribution is on hand. This paper deals with different crack propagation analyses at both simple joints and complex welded structures in order to investigate further effects, besides the stress gradient, which affects the crack propagation, shape and fatigue life. At first, a comparison of a transverse attachment and its geometrical modifications with the intersection of plates is presented. Four effects which are identified on the basis of different stress distributions and geometry are validated by numerical and analytical crack propagation analyses. In the next step, the geometry is modified to vary the notch effect and the stress C C. Fischer et alii, Frattura ed Integrità Strutturale, 34 (2015) 99-108; DOI: 10.3221/IGF-ESIS.34.10 100 concentration at the weld toe which depend on the load-carrying-grade of the weld, the weld flank angle and the layout of the intersecting plates. CASE STUDY Selected Variants he two-sided transverse attachment (variant 1 in Fig. 1) under axial loading represents a simple welded joint. A crack would be initiated at one of the weld toes and would run through the loaded plate. The complex structure (variant 5) is the intersection of various plates joined by fillet welds. Here, the local hot-spot at the intersection point is critical since a crack would initiate at the weld toe on the surface of the horizontal plate in the loading condition shown. The other three variants are ‘intermediate’ geometries to separate the effects on crack propagation. They are described and used in the following. Corresponding three-dimensional finite element (FE) models taking advantage of the vertical symmetry plane were created in ANSYS® 13.0. The models consist of solid elements with quadratic shape function (SOLID186), and the welds were completely modelled in order to account for the local stiffness. The models are 200 mm long, 100 mm wide and 70 mm high. No axial and angular misalignments are present and only the critical weld toe was rounded by a radius rref = 1 mm for the determination of the stress field. The vertical nodal displacements of variants 1 and 5 were suppressed at the bottom. On the symmetry plane corresponding boundary conditions were applied, and the transverse nodal displacement was coupled on the opposite side to represent adjacent structures. The front and back face were loaded by uniform, axial stresses, whereas the axial nodal displacements were suppressed at the back face of the complex structure. F F crack at weld toe crack at weld toe F F M F M F M 100 variant 2 – transverse attachment w. gradient variant 4 – add. long. attachment variant 1 – transverse attachment crack at weld toe crack at weld toe variant 3 - supported transverse attachment crack at weld toe variant 5 – complex structure Figure 1: Selected geometrical variants (variants 1 to 4 are cut in the symmetry plane). Structural Hot-Spot Stress and Effective Notch Stress Both stresses are commonly used for fatigue assessment of welded joints (see e.g. [10]) and are the basis for comparing the variants. The structural hot-spot stress (HSS) σs which appears in front of the rounded weld toe on the symmetry plane consists of the sum of the membrane stress σm and bending stress σb. Both σm and σb are determined by linearizing the axial stress component over the plate thickness t = 10 mm according to [10]. Moreover, Dong [3] characterized a stress gradient occurring over the plate thickness by means of the degree of bending , Eq. (1). Here,  = 0 denotes pure axial loading and  = 1 pure bending. b m b       (1) T C. Fischer et alii, Frattura ed Integrità Strutturale, 34 (2015) 99-108; DOI: 10.3221/IGF-ESIS.34.10 101 The effective notch stress σeff accounts for the notch effect and the microstructural support of notches by means of rounding the weld toe or the weld root by a radius rref = 1 mm, see [8]. The highest 1st principal stress on that radius is assumed to be effective for fatigue assessment. The effective notch stress is linked with σs by the weld shape factor KW, Eq. (2), which considers the load-carrying grade of the weld and the local weld geometry. eff W sK  (2) Comparison of Stress Distributions In order to reach the same structural HSS σs = 176 MPa at the transverse attachment (1) and the complex structure (5), different levels of nominal stresses were required. A uniform axial loading of 100 MPa was sufficient at variant (5) because of the significant stress concentration at the hot-spot which is illustrated by the calculated distributions of the 1st principal stress in Fig. 2. x z y F 1st principal stress [MPa] <80 108 136 163 191 219 247 274 302 >330 F x z y F 1st principal stress [MPa] <80 108 136 163 191 219 247 274 302 >330 1 0 m m Figure 2: Calculated stress distribution at the transverse attachment (left) and the complex structure (right). Moreover, the stress distribution over the plate thickness is symmetric in case of transverse attachment (1) due to the weld toe on the opposite side, whereas the stress decreases monotonically for the complex structure (5). These characteristics were represented by different degrees of bending being  = 0 for variant 1 and  = 0.315 for the other. While the stress level is constant over the whole width of the transverse attachment (1), it decreases in variant 5 at first significantly and then slows down when the distance from the symmetry plane rises. The longitudinal plates of the complex structure cause differences as well. The lower plate increases the apparent plate thickness in the symmetry plane; i.e. the cross section is significantly larger than for the transverse attachment. The upper plate affects the load-carrying grade and the level of the effective notch stress. Moreover, the vertical support of the lower longitudinal plate results in a bending constraint which is also found in large plated structures. ‘Intermediate’ Variants Three additional variants 2 to 4 according to Fig. 1 were defined for the following crack propagation simulation so that the effects on crack propagation life can be separated. In variant 2, the transverse attachment is loaded such that  = 0.315 occurs at the weld toe, while variant 3 is modified by a longitudinal plate below the main plate. The plate is 10 mm thick and 30 mm high. The degree of bending  = 0.315 in the plate is realized by appropriate axial and bending loads. An additional longitudinal plate, having a length L = 100 mm, is added behind the upper transverse attachment in variant 4. Due to adjusted loads, the degree of bending is  = 0.315 again. This longitudinal plate increases the load-carrying grade of the welded joint and also the stress concentration in the symmetry plane. This led to a similarly high stress decrease along the weld line as for the complex structure. The C. Fischer et alii, Frattura ed Integrità Strutturale, 34 (2015) 99-108; DOI: 10.3221/IGF-ESIS.34.10 102 difference between variant 4 and 5 is only the support of the lower longitudinal plate changing also the kind of loading, but not s or eff and  at the hot-spot. COMPUTED FATIGUE LIVES Crack Propagation Analysis half-circular initial crack is assumed at the critical weld toe for all variants. The crack initiation phase was considered by choosing a small initial crack length ai = 0.15 mm. The crack growth increments da and dc were computed for a defined number of cycles dN via individual integrations of the law by Paris and Erdogan [16]:  , m I a da C K dN   (3) Eq. (3) links the crack propagation rate da/dN to the range of the stress intensity factor (SIF) KI,a at the deepest point of the crack by using the material parameter C = 3·10-13 and m = 3 (unit: N and mm). The integrations, however, must be done discretely because the SIF varies non-linearly and depends on the crack depth and crack shape. In order to avoid an under- or overestimation of cycles, the average value of the cyclic SIF was used when the crack grows from one stage (1) to the next (2):      ,1 ,2log 0.5 log logI I IK K K       (4) A separate block of elements was added to the FE models. It includes half of the semi-elliptical crack shape with half crack depth a and width c. The block was connected with the surrounding model by contact elements transferring all kinds of forces and moments (bonded conditions). The block is 10 mm long and high, whereas the width depends on the actual half crack width c. The 20-node solid elements size 0.1·a at the crack front, and the midsize nodes are shifted to the quarter points towards the crack front to improve the accuracy. No weld toe radius was considered to simplify the modelling, but this causes an additional stress singularity and a steep increase of the SIF. Due to this, the SIF KI,c at the plate surface was estimated by extrapolating the SIF values computed at the three previous nodes. Generally, KI at each node along the crack front was determined individually via the J-integral using six contour integrations. Fischer and Fricke [4] described the modelling of the crack and the estimation of KI,c in detail. They applied the procedure to a load-carrying cruciform joint and obtained a satisfying agreement with experimental results. 1) Transverse attachment 2) Transverse attachment w. gradient 3) Supported transverse attachment 4) Additional longitudinal attachment 5) Complex structure Degree of bending  0.0 0.315 0.315 0.315 0.315 Final crack depth af [mm] 8.48 8.51 8.43 8.44 8.45 Final crack width 2cf [mm] 36.1 49.2 42.3 39.8 38.3 Fatigue life NP 300,000 385,600 452,200 456,200 509,600 Rel. fatigue life 1.00 1.29 1.51 1.52 1.70 Table 1: Computed fatigue life Np for the same structural hot-spot stress s = 176 MPa. Fatigue Lives Referring to Same Structural Hot-Spot Stress Between nine and eleven integrations with up to 14 internal loops were performed until the crack had reached the final depth af ≈ 8.5 mm, being close to the opposite plate surface. In this process, smaller increments dN are considered for small cracks. Fig. 3 shows the evolution of the crack depth of the variants for the same structural HSS s = 176 MPa. Here, the additional longitudinal attachment (4) is omitted since the crack grows similarly as for the supported transverse A C. Fischer et alii, Frattura ed Integrità Strutturale, 34 (2015) 99-108; DOI: 10.3221/IGF-ESIS.34.10 103 attachment (3). First differences in crack growth occur at a small crack depth a ≈ 0.5 mm. This corresponds to ca. 105 cycles. Afterwards, faster crack propagation can be observed at variants 1 and 2. The curves of the other two variants deviate beyond a ≈ 1.5 mm. Finally, the transverse attachment (1) achieves the shortest fatigue life Np, see also Tab. 1. The next are the transverse attachment with stress gradient over the plate thickness (2), the supported transverse attachment (3), and, finally, the complex structure (5). Tab. 1 also lists in the last line the relative fatigue life referring to that of variant 1. The largest influence (29%) is caused by the stress gradient over the plate thickness (2). Both the apparent plate thickness (3) and the bending constraint (5) increase NP by about 12%, compared with the previous variants. It is worth noting that the stress gradient along the weld line does not affect the life since the same Np is computed for variants 3 and 4. Although the two variants differ with respect to the load-carrying grade of the weld, the same stress distribution over the plate thickness occurs. The gradient along the weld line, however, has an impact on the aspect ratios of the crack, see Tab. 1. The final ratio is relatively small at variant 2 because the stress level is constant along the weld line, whereas the level decreases over the plate thickness. The final aspect ratio increases from the supported transverse attachment (3) to the complex structure (5) as the stress gradient along the weld line gets more pronounced and slows down the crack growth in this direction. 0 2 4 6 8 0,E+00 1,E+05 2,E+05 3,E+05 4,E+05 5,E+05 Quersteife Quersteife mit Gradient unterstützte Quersteife komplexes Bauteil 0 105 2∙105 3∙105 4∙105 5∙105 c ra c k d e p th a [m m ] cycles N transverse attachment (1) transverse attachment w. gradient (2) supported transverse attachment (3) complex structure (5) Figure 3: Determined crack depth vs. applied cycles. 0 4 8 0 4 8 12 16 20 24 R is s tie fe a [m m ] halbe Rissbreite c [mm] 0 4 8 0 4 8 12 16 20 24 R is s ti e fe a [m m ] halbe Rissbreite c [mm] 0 4 8 0 4 8 12 16 20 24 R is s tie fe a [m m ] halbe Rissbreite c [mm] transverse attachment (1) Np = 300,000 N = 150,000 0 4 8 0 4 8 12 16 20 24 R is s tie fe a [m m ] halbe Rissbreite c [mm] supported transverse attachment (3) transverse attachment w. gradient (2) complex structure (5) N = 360,000 N = 150,000 N = 360,000 N = 150,000 N = 360,000 N = 150,000 Np = 385,000 Np = 510,000 Np = 452,000 half crack width c [mm] half crack width c [mm] half crack width c [mm] half crack width c [mm] c ra c k d e p th a [m m ] c ra c k d e p th a [m m ] c ra c k d e p th a [m m ] c ra c k d e p th a [m m ] Figure 4: Calculated crack shapes for variants 1 to 3 and 5. 1) Transverse attachment 2) Transverse attachment w. gradient 3) Supported transverse attachment 4) Additional longitudinal attachment 5) Complex structure Weld shape factor KW 2.41 2.24 2.17 2.35 2.43 Fatigue life NP 297,000 308,500 329,000 418,700 515,000 Rel. fatigue life 1.00 1.04 1.11 1.41 1.73 Table 2: Computed fatigue life Np for the same effective notch stress eff = 425 MPa. This influence is also visible when comparing the crack shapes for defined number of cycles, see Fig. 4 showing half crack shapes of variant 1 to 3 and 5 for the same number of cycles (Np = 150,000; Np = 360,000 and at final life) and σs = 176 MPa. The transverse attachment (1) does not reach Np = 360,000 since it has the highest crack propagation rate. While the crack shapes of the variants are almost similar for Np = 150,000, after this they start to differ obviously between the simple transverse attachments (1 and 2) and the more complex variants 3 and 5. Nevertheless, semi-elliptical crack shapes evolve in all cases and the more effects are present, the smaller the computed crack size is. Fatigue Lives Referring to Same Effective Notch Stress The computed life can be converted by adjusting the load level in order to consider the same effective notch stress σeff = 425.3 MPa on the radius rref at symmetry plane, see Tab. 2. Here, the stress gradient over the plate thickness (variant 2) as C. Fischer et alii, Frattura ed Integrità Strutturale, 34 (2015) 99-108; DOI: 10.3221/IGF-ESIS.34.10 104 well as the apparent plate thickness (variant 3) have only minor influence on fatigue life since the stress concentration factor is smaller for bending loads (see e.g. [17]) and the apparent plate thickness is included in the notch effect by the ratio rref/(h+t) as defined in Fig. 1. The lives for the supported transverse attachment (3) and the additional longitudinal attachment (4) differ by about 27% in this comparison. The reason is the load-carrying grade of the fillet weld which is increased by the additional longitudinal attachment. The different load-carrying grades can be seen in the rise of the weld shape factor KW from 2.17 to 2.34. Its effect on life can be assessed for e.g. the variants 3 and 4 by raising the ratio of KW to the power of three: 3 ,3 ,3 ,4 ,4 ,1 ,3 1.41 p p W p p W N N K N N K                (5) Here, the first term takes into account the increase with respect to the transverse attachment (1). The assessment agrees well with the computed relative lives of Tab. 2. Moreover, the complex structure reaches even longer life (variant 5 vs. 4), caused by an increased KW and the bending constraint. In general it can be stated that an increased weld shape factor KW results in a decreased crack growth due to the lower stress level in the plate. ASSESSMENT OF THE INDIVIDUAL INFLUENCES Stress Gradient over Plate Thickness nalytical crack propagation analyses, in which the degree of bending  was varied, were carried out for a transverse attachment having the dimensions of variant 1. By starting with a semi-circular initial crack of ai = ci = 0.15 mm, the life was counted until the crack had reached af = 3 mm. The following propagation phase was neglected since the aspect ratio was small and the increase in life, too. The crack growth increments da and dc were again determined individually via the integration of the Paris law. The required SIF for the deepest point and for the surface point were taken from [1]. The stress magnification factors Mk,c, referring to the surface point, were constant and correspond to the ones for a = 0.15 mm as suggested in [1]. The estimated lives were normalized with respect to the case of pure membrane loading ( = 0). Fig. 5 shows the crack depth as a function of the relative fatigue life for different degrees of bending. An increase of nearly 300% is found for  = 1, being in agreement with calculations in [14], and of about 30% for  = 0,315 as in the simulation. d = 0.0 d = 0.2 d = 0.4 d = 0.6 d = 0.8 d = 1.0 relative fatigue life 0 1 2 3 c ra c k d e p th a [m m ] 0 1 2 3 Figure 5: Computed crack depth at transverse attachment with different degrees of bending  vs. relative fatigue life. 0,6 0,9 1,2 1,5 0 2 4 6 8 Quersteife mit Gradient unterstützte Quersteife n o rm a li z e d S IF crack depth a [mm] transverse attachment w. gradient (2) supported transverse attachment (3) Figure 6: Influence of the remaining cross section on the SIF. Apparent Plate Thickness The SIF at the deepest point depends among others on the relative crack depth a/t, the effect of which is described by means of the geometry function. If an additional plate is existent, the apparent plate thickness is increased. A C. Fischer et alii, Frattura ed Integrità Strutturale, 34 (2015) 99-108; DOI: 10.3221/IGF-ESIS.34.10 105 Its influence on crack propagation can be illustrated when normalizing KI,a at the deepest point of variant 2 and 3 by means of the structural stress σs, multiplied by √πa, see Fig. 6. In the beginning, the normalized SIF increases because the semi-circular initial crack becomes flatter (semi-elliptical). With growing crack depth, the stress magnification Mk due to the weld toe notch vanishes and the increased apparent plate thickness gains influence. The SIF of the two variants show increasing deviations for a > 1 mm. Smaller values and a slower increase are obtained for the supported transverse attachment (3), leading to an extended life. In order to assess the effect, the geometry function Y for a single edge crack with a/c = 0 in a finite thickness according to Tada et al. [18] was integrated discretely from ai = 0.15 mm to af = 8.5 mm. Different relative heights h/t of the lower longitudinal plates were considered; see Fig. 1 for the definition of h. The influence of the magnification Mk was neglected because differences regarding KI,a and, consequently, the crack growth had been found for a > 1 mm, where the Mk factors are no more effective, see [9]. The analytical solution for h/t = 3 yields an increase of relative life by about 17% and agrees well with the difference between variant 2 and 3 on the basis of equal structural HSS (Tab. 1). Modified Notch Effect The local stress concentration at hot-spots and, consequently, the weld shape factor can be additionally affected by the layout of the transverse attachment and the flank angle α of the weld seam. Hence, the crack propagation is altered. The intersection of a sloped transverse attachment is a typical detail in cargo holds of bulk carriers, see e.g. [6]. Three configurations of the attachment (Fig. 7) are selected in the following. The critical weld toe is always arranged vertically above the weld toe on the opposite side. At first, the slope is set to 45° (Detail A) and the attachment is shifted so that the flank angle of the critical weld seam remains 45°. Thus, the center lines of the plates intersect each other eccentrically. At Detail B, the center lines are arranged aligned causing a smaller flank angle α = 25°. A steeper angle α = 33° occurs with a steeper slope of the transverse attachment and by still aligned center lines, see Detail C in Fig. 7. For each of the three details, FE models of the variants 1 to 3 and 5, shown in Fig. 1, are generated and crack propagation is simulated using the previously described conditions. The influence of the bending constraint applied to the complex structure (5) is determined approximatively by comparing variant 3 and 5 and considering the changed weld shape factor by Eq. (5) additionally. 7,93 10 10 1 0 7 ,3 Detail BDetail A Detail C 10 Figure 7: Considered configuration of a sloped upper transverse attachment: with slope angle of 45° and a) eccentric and b) aligned center lines as well as c) with slope angle of 60° and aligned center lines. 1) Transverse attachment 2) Transverse attachment w. gradient 3) Supported transverse attachment 5) Complex structure Degree of bending  0.0 0.316 0.316 0.316 Weld shape factor KW 2,36 2,21 2,15 2,39 Final crack depth af [mm] 8.45 8.48 8.49 8.51 Final crack width 2cf [mm] 36.1 46.6 44.9 40.1 Fatigue life NP 283,800 291,200 306,400 505,00 Rel. fatigue life 1.00 1.03 1.08 1.78 Table 3: Computed fatigue life Np for the same effective notch stress σeff = 425 MPa at Detail A. C. Fischer et alii, Frattura ed Integrità Strutturale, 34 (2015) 99-108; DOI: 10.3221/IGF-ESIS.34.10 106 The results referring to equal σeff = 425 MPa are listed in Tab. 3 to Tab. 5. At Detail A, the calculated final crack shapes as well as the weld shape factors are almost similar to the previous simulations (Tab. 2), despite of the sloped attachment. Additionally, the calculated fatigue lives of the transverse attachment with and without stress gradient (variant 1 and 2) agree with each other. Small deviations, however, are obtained for both the supported transverse attachment (3) and the complex structure (5). Here, the sloped layout affects the stress distributions over the complete cross section on the symmetry plane which can be recognized by the normalized SIF, as illustrated for the two configurations of the supported transverse attachment (3) in Fig. 8. Higher values appear at the eccentric, sloped layout beyond a > 1.75 mm and lead to faster crack propagation and shorter life finally. In Detail B, the weld flank angle is smaller at the same time and reduces the local stress concentration at the weld toe which becomes apparent in generally smaller weld shape factors KW. Hence, higher external loadings are required for eff = 425 MPa and the fatigue lives are shorter compared to the other two configurations, see Tab. 2 to Tab. 4. Additionally, the structural hot-spot stresses rise according to Eq. (2) since eff is constant and KW smaller. That effect in conjunction with the lower stress concentration decreases the degree of bending at Detail B. Moreover, the effect of the bending constraint at the complex structure (5) is highly reduced since the relative life rises by only about 21%. n o rm a li z e d S IF unterstützte Quersteife (C) Quersteife mit Gradient (B) 0,6 0,9 1,2 1,5 0 2 4 6 8 supported transverse attachment (3) with vertical layout supported transverse attachment (3) with eccentric and sloped layout, Detail B crack depth a [mm] Figure 8: Influence of the layout of the transverse attachment on the SIF. c o m p u te d fa ti g u e li fe N p (t h o u s a n d ) 350 250 150 transverse attachment (1) supported transverse attachment (3) 0.93 1.00 1.00 0.96 0.83 0.92  = 4 5 °  = 4 5 °  = 4 5 °  = 4 5 °  = 2 5 °  = 3 3 ° different weld flank angle different slope D e ta il A D e ta il A D e ta il B D e ta il C ve rt ic a l la yo u t ve rt ic a l la yo u t Figure 9: Influence of slope and weld flank angle on fatigue life, shown for selected variants for equal eff. 1) Transverse attachment 2) Transverse attachment w. gradient 3) Supported transverse attachment 5) Complex structure Degree of bending  0.0 0.266 0.266 0.266 Weld shape factor KW 2,11 2,00 1,93 1,98 Fatigue life NP 245,500 259,300 266,000 297,000 Rel. fatigue life 1.00 1.06 1.08 1.21 Table 4: Computed fatigue life Np for the same effective notch stress σeff = 425 MPa at Detail B. In detail, KW at the sloped transverse attachment (1) of Detail B, is about 12% smaller compared to the vertical attachment and would shorten fatigue life by about 40% due to increased external loadings. The flatter flank angle, however, compensates the effect partly as the relative lives differ by about 17%. A similar difference is obtained when the effects of the deviating weld shape factors and Mk factors referring to the flank angle are considered. At variant 2, the degree of bending decreases and shortens the fatigue life as shown in Fig. 5. At the last Detail C, the flank angle modifies the stress distribution over the plate thickness and increases weld shape factors but not as much that they agree with the vertical configuration. Hence, the required level of the external loading is changed and the fatigue lives of the variants are longer than for Detail B but shorter for the other, see Tab. 5, Tab. 4 and C. Fischer et alii, Frattura ed Integrità Strutturale, 34 (2015) 99-108; DOI: 10.3221/IGF-ESIS.34.10 107 Tab. 2. The different variants of the transverse attachment (variant 1 to 3), both referring to Detail C and the vertical layout, deviate from each other by about 10% being caused by a nearly constant difference between the weld shape factors. Again, the effect of the bending constraint is reduced. The influence of the flank angle is analytically considered by the stress magnification factor Mk being e.g. reported in the IIW guideline [10]. The integration of Mk from ai = 0.15 mm to af = 3 mm yields an increasing relative life of about 22% for α = 25° and a/c = 0 compared to α = 45°. The factor is equal one for crack depths a ≥ 3 mm and thus ineffective. The increase of life is about 14% for the steeper flank angle α = 33° of Detail C. Fig. 9 illustrates the influence of the sloped layout and the weld flank angle for two selected variants. The life of the supported transverse attachment (3) decreases at Detail A. The effect is overlaid by the smaller flank angle at the other two details and, hence, omitted. The stress concentration of the transverse attachment (1) is only affected by the flank angle, being smaller at Detail B and C. Thus, the computed life is reduced. 1) Transverse attachment 2) Transverse attachment w. gradient 3) Supported transverse attachment 5) Complex structure Degree of bending  0.0 0.3 0.3 0.3 Weld shape factor KW 2.27 2.12 2.04 2.18 Fatigue life NP 274,500 283,000 296,200 390,100 Rel. fatigue life 1.00 1.03 1.08 1.42 Table 5: Computed fatigue life Np for the same effective notch stress σeff = 425 MPa at Detail C. 1) Transverse attachment 2) Transverse attachment w. gradient 3) Supported transverse attachment 5) Complex structure Detail A fatigue life NP 304,800 382,000 437,300 521,900 rel. fatigue life 1.00 1.25 1.43 1.71 Detail B fatigue life NP 371,200 457,800 524,700 538,000 rel. fatigue life 1.00 1.23 1.41 1.45 Detail C fatigue life NP 329,100 416,600 491,300 529,600 rel. fatigue life 1.00 1.27 1.49 1.61 Table 6: Computed fatigue life Np for the same structural HSS σs = 176 MPa at three sloped configurations. The influences of both the layout and the flank angle is also directly included in the crack propagation simulation on the basis of the same structural HSS s, see Tab. 1 and Tab. 6, but not in the fatigue assessment using this type of stress. Due to the flatter flank angle at Detail B and C, the absolute fatigue life is increased by about 25% and 11%, respectively. This agrees with the assessment being based on the integrated Mk factor. The relative life of Detail A to C does not rise as much as for the vertically supported transverse attachment (3) because the apparent plate thickness is less effective due to the sloped layout. The different influences are suppressed at the complex structure (5) and nearly same absolute fatigue life is achieved. However, the increase of the relative life is rather different because of the sloped layout. CONCLUSIONS AND OUTLOOK he paper presents crack propagation simulations which were performed for different welded geometries – from a transverse attachment up to a complex structure. The determined fatigue lives were compared assuming equal structural HSS and alternatively effective notch stress in all variants. The complex structures showed longer fatigue life due to a higher stress concentration, resulting in changed stress distribution along the crack path. The following conclusion can be drawn: - Longer crack propagation phase observed in experiments of complex structures can be found also in numerical crack propagation simulation; T C. Fischer et alii, Frattura ed Integrità Strutturale, 34 (2015) 99-108; DOI: 10.3221/IGF-ESIS.34.10 108 - The crack propagation rate at complex structures is slowed down by: the stress gradient over the plate thickness, the apparent plate thickness, the notch effect and the bending constraint of the detail; - The stress gradient along the weld line does not affect the life but the aspect ratio of the semi-elliptical crack shape; - The notch effect depends on the load-carrying grade of weld, the flank angle and of the layout of the transverse attachment and it affects the local stress concentration, leading to longer life. The obtained influences should be investigated for further configurations, varying in particular the thickness of the axially loaded plate as well as of the attachments. This would lead to different local support of the critical weld toe, especially if the thicknesses are different. 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