A Quest for a New Hot Tearing Criterion

Eskin, Dmitry; Katgerman, L.

doi:10.1007/s11661-007-9169-7

Cited by 229 publications

(99 citation statements)

References 26 publications

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“…It is commonly assumed that the dendrites start to bridge together when the solid fraction reaches approximately 98 pct if the eutectic temperature is not yet reached. [5,15,16] Therefore, the integral limits for the A parameter in Eq. [5] are from the point where the solid fraction f s = 0.98, i.e., the so-called coherency temperature, to the liquidus temperature.…”

Section: E the Hot Cracking Susceptibility Modelmentioning

confidence: 99%

Process Optimization of Dual-Laser Beam Welding of Advanced Al-Li Alloys Through Hot Cracking Susceptibility Modeling

Tian

Robson

Riekehr

et al. 2016

Metall Mater Trans A

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Laser welding of advanced Al-Li alloys has been developed to meet the increasing demand for light-weight and high-strength aerospace structures. However, welding of high-strength Al-Li alloys can be problematic due to the tendency for hot cracking. Finding suitable welding parameters and filler material for this combination currently requires extensive and costly trial and error experimentation. The present work describes a novel coupled model to predict hot crack susceptibility (HCS) in Al-Li welds. Such a model can be used to shortcut the weld development process. The coupled model combines finite element process simulation with a two-level HCS model. The finite element process model predicts thermal field data for the subsequent HCS hot cracking prediction. The model can be used to predict the influences of filler wire composition and welding parameters on HCS. The modeling results have been validated by comparing predictions with results from fully instrumented laser welds performed under a range of process parameters and analyzed using high-resolution X-ray tomography to identify weld defects. It is shown that the model is capable of accurately predicting the thermal field around the weld and the trend of HCS as a function of process parameters.

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Section: E the Hot Cracking Susceptibility Modelmentioning

confidence: 99%

Process Optimization of Dual-Laser Beam Welding of Advanced Al-Li Alloys Through Hot Cracking Susceptibility Modeling

Tian

Robson

Riekehr

et al. 2016

Metall Mater Trans A

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“…Based on the alloy microstructure shown in Figure 6.7, it will be observed that the severity of shrinkage porosity and hot cracking may be reduced significantly upon the hot-tearing crack initiates from a pore or a series of pores in conditions of non-uniform thermal contraction of the coherent dendrites. 94 Such parallelism may also be explained by the deteriorating effect caused by the limited feedability and the diminished permeability of the mushy zone leading to the formation of high levels of porosity and to the difficulties It should be mentioned that the Bl Si-alloy is not covered by this equation. These results which were illustrated in the preceding three figures may help to explain the beneficial role of the grain refining additions, namely Zr-Ti and Ti, in reducing the hot-tearing susceptibility of the Al-2wt%Cu base alloy.…”

Section: Effects Of Mold Temperaturementioning

confidence: 99%

Influence of zirconium and scandium on the microstructure, tensile properties, and hot-tearing susceptibility of Al-2WT%Cu-based alloys /

Nabawy¹

2010

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In the second alloy category, seventeen alloy compositions were prepared, using different additions of Zr, Sc, Ti-B, Sr, Ag, and Si These alloys were further divided into four groups, namely, the Zr-Ti, Zr-Sr, Zr-Sc, and Si alloy groups. Tensile test bars (cooling rate 7°C/s) prepared from these alloys were solutionized for 8h at 490°C then age-hardened at temperatures of 180°C and 220°C for aging times of 2, 4, 6, 10,16, 24, and 48h, and 0.5,1, 1.5, 2, 4, 6, 10, 16, 24, and 48h, respectively. It was observed that combined additions of Zr-Ti Zr-Sr, or Zr-Sc refined the grain size of the base alloy considerably, from 219 um to 104-46 urn, since these elements form primary trialuminide intermetallics including Al3(Sci-x Zr x ), Al3(Sci-x -yZr x Tiy), and AlaZr which act as nucleation sites for o-Al grains, thereby producing fine non-dendritic structures. The refined non-dendritic morphology produced by the combined additions of Zr-Ti Zr-Sr, or Zr-Sc caused a reduction of about 65% in the amount of the AliCu phase in the base alloy, and a reduction in porosity of about 50%. The addition of 2 wt% Si also produced the same reduction levels in the amount of AfeCu and porosity, brought about by the increase in the Al-Si eutectic content. Age-hardening peaks were observed after aging for lOh and 24h at 180°C, and after aging for Ih and 2h at 220°C. The Zr-Sr and Zr-Ti alloy groups displayed the highest level of improvement in the tensile properties of the Al-2wt%Cu base alloy followed by the Zr-Sc and Si alloy groups, in that order. The 0.02wt%Sr-0.7wt%Zr containing alloy produced the highest ultimate tensile and yield strength values of 383 MPa and 326 MPa, respectively, after 4h of aging at 180°C. The strength of the base alloy increased in the Zr-Ti alloy group with an increase in Zr content from 0.15wt% to 0.7wt% after aging at 180°C for lOh. This increase may be variously attributed to Al$Zr and Al3(Zri. x Ti x ) dispersoids acting as heterogeneous nucleation sites for age-hardening phases; to the modifying action of Zr on the S' (AfeCuMg) phase; and to the action of Zr-Ti in producing a refined non-dendritic grain structure. Combined additions of Zr-Sr and Sr-Ti displayed the best elongation levels of all the alloys investigated, as witnessed by the 0.02wt%Sr-0.15wt%Ti-containing alloy and, 0.02wt%Sr-0.7wt%Zr-containing alloy. These improved levels may be the result of the modifying effects of Sr on o-Fe particles, as well as of the roles of Zr and Ti in producing a fine non-dendritic os-Al structure. The 0.02wt%Sr-0.15wt%Ti-containing alloy displayed the highest resistance to softening during aging at 220°C because of the respective modifying and refining effects of Sr and Ti on the microstructure.

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“…High cooling rates and non-equilibrium solidification conditions of the DC-casting result in the formation of nonequilibrium eutectics and intermetallics, which mainly precipitate on the grain boundaries and interdendritic spaces during final stages of solidification [2,3]. The formation of such phases coincides with the appearance of thermal stresses when the dendritic grains start to form a coherent network [4]. Due to their low melting point, the non-equilibrium eutectics provide potential nucleation sites and propagation paths for hot cracking (cracking above the solidus) while they are still in the liquid state.…”

Section: Introductionmentioning

confidence: 99%

Cold cracking in DC-cast high strength aluminum alloy ingots: An intrinsic problem intensified by casting process parameters

Lalpoor

Eskin

Ruvalcaba

et al. 2011

Materials Science and Engineering: A

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a b s t r a c tFor almost half a century the catastrophic failure of direct chill (DC) cast high strength aluminum alloys has been challenging the production of sound ingots. To overcome this problem, a criterion is required that can assist the researchers in predicting the critical conditions which facilitate the catastrophic failure of the ingots. This could be achieved at first glance by application of computer simulations to assess the level and distribution of residual thermal stresses. However, the simulation results are only able to show the critical locations and conditions where and when high stresses may appear in the ingots. The prediction of critical void/crack size requires simultaneous application of fracture mechanics. In this paper, we present the thermo-mechanical simulation results that indicate the critical crack size distribution in several DCcast billets cast at various casting conditions. The simulation results were validated upon experimental DC-casting trials and revealed that the existence of voids/cracks with a considerable size is required for cold cracking to occur.

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A Quest for a New Hot Tearing Criterion

Cited by 229 publications

References 26 publications

Process Optimization of Dual-Laser Beam Welding of Advanced Al-Li Alloys Through Hot Cracking Susceptibility Modeling

Process Optimization of Dual-Laser Beam Welding of Advanced Al-Li Alloys Through Hot Cracking Susceptibility Modeling

Influence of zirconium and scandium on the microstructure, tensile properties, and hot-tearing susceptibility of Al-2WT%Cu-based alloys /

Cold cracking in DC-cast high strength aluminum alloy ingots: An intrinsic problem intensified by casting process parameters

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