Effect of Heat Input on Microstructure and Mechanical Properties of Deposited Metal of E120C-K4 High Strength Steel Flux-Cored Wire

Wu, Wen; Zhang, Tianli; Chen, Haoxin; Peng, Jingjing; Yang, Kui; Lin, Sanbao; Wen, Peiyin; Li, Zhuoxin; Yang, Shanglei; Kou, Sindo

doi:10.3390/ma16083239

Cited by 3 publications

(1 citation statement)

References 31 publications

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“…The yield strength of the welding wire is 460 MPa, tensile strength is 550-670 MPa and elongation is 22%. The preferred welding wire is used to join high-strength steels by gas arc welding [32][33][34]. The chemical compositions of steel materials and welding wire are given in Table 1.…”

Section: Properties Of Steel Materials and Welding Wirementioning

confidence: 99%

Study of the Microstructure and Mechanical Property Relationships of Gas Metal Arc Welded Dissimilar Protection 600T, DP450 and S275JR Steel Joints

Elmas,

Koçar,

Anaç

2024

Crystals

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The need for combining dissimilar materials is steadily increasing in the manufacturing industry, and the resulting products are expected to always have high performance. While there are various methods available for joining such material pairs, one of the commonly preferred techniques is fusion welding. In this study, three different steel materials (Protection 600T, DP450, and S275JR) were joined using gas metal arc welding (GMAW) in different combinations (similar/dissimilar). The microstructure and mechanical properties of the joints were evaluated. Tensile test, Vickers microhardness (HV 0.1), bending, Charpy V-notch impact testing, and microstructure examinations were conducted to analyze the weld and heat-affected zone. The tensile strengths of the base metal materials Protection 600T, DP450, and S275JR were found to be 1524.73 ± 18.7, 500.8 ± 10.4, and 508.5 ± 9.5 MPa, respectively. In welded samples of similar materials, the highest efficiency was found to be 103.05% for DP450/DP450, while in dissimilar welded joints, it was 105.5% for the DP450/S275JR pair. Hardness values for the base materials Protection 600T, DP450, and S275JR were measured as 526.5 ± 10.5, 153.8 ± 1.8, and 162.5 ± 5.2, respectively. In all welded samples, there was an increase in hardness in the weld zone (due to the welding wire) and the heat-affected zone (due to grain size refinement). While the impact energy values of similar material pairs were close to the base material impact energy values, the impact energy values of dissimilar material pairs varied according to the base materials. In addition, in joints made with similar materials, the bending force was close to the base materials, while a decrease in bending force was observed in joints formed with dissimilar materials. As a result, the welding of DP450 and S275JR materials was carried out efficiently. Protection 600T was welded with other materials, but its welding strength was limited to the strength of the material with low mechanical properties.

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Section: Properties Of Steel Materials and Welding Wirementioning

confidence: 99%

Study of the Microstructure and Mechanical Property Relationships of Gas Metal Arc Welded Dissimilar Protection 600T, DP450 and S275JR Steel Joints

Elmas,

Koçar,

Anaç

2024

Crystals

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Effect of Heat Input on the Metal Microstructure and Mechanical Properties of Q960 High‐Strength Steel Solid Core Welding Wire

Zhu,

Min,

Xiao

et al. 2024

steel research int.

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The self‐developed Q960 high‐strength steel solid wire with different heat input is welded by MIG welding to solve the problem of insufficient low‐temperature toughness of Q960 steel weld. The effect of heat input on the microstructure and mechanical properties of butt welding deposited metal is studied in depth. The results show that the microstructure of deposited metal is composed of granular bainite (GB), degenerate upper bainite (DUB), martensite (M), and acicular ferrite (AF). DUB and M play key roles as strengthening phases, whereas GB and AF serve as primary toughening phases. Elevated heat input leads to a progressively rougher microstructure in the deposited metal. AF and DUB increase first and then decrease, GB increases and M decreases slightly. The inclusions conducive to AF nucleation are mainly composed of oxides of Mn, Si, Ti, and Mn sulfide with sizes between 100 and 500 nm. At a 14 kJ cm−1 heat input, the complex phase microstructure effectively refines the grain, and the high‐angle grain boundaries and ferrite interlocking structure optimize the strength and toughness balance of the deposited metals. The tensile strength measures 958 MPa, with the highest elongation at 19% and an average impact toughness of 50 J at −40 °C.

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Thermodynamic aspects of WO3 tungsten oxide reduction by carbon, silicon, aluminum and titanium

Bashchenko,

Bendre,

Kozyrev

et al. 2024

Izv. vysš. učebn. zaved., Čern. metall.

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The development and research of new materials for machine parts of the mining and metallurgical complex by the method of surfacing with flux cored wire has a lot of attention nowadays. Flux cored wires are widely used for surfacing of steels with high wear resistance, in which reduced tungsten in the form of ferroalloys, ligatures and metal powder of various degrees of purity are used as fillers. However, due to the scarcity and high cost of tungsten, its rational use is an urgent task. For practical application, the technology of surfacing with tungsten-containing flux cored wire is of interest; using it the maximum extraction of tungsten into the deposited layer is achieved due to reduction processes in the arc. In order to increase the beneficial use of tungsten, the technologies of indirect alloying with tungsten during surfacing under the flux of flux cored wires, in which tungsten oxide is used as a filler on the one hand, and reducing agent – on the other, deserve consideration. It can be expected that during arc discharge, tungsten and (or) chemical compounds of tungsten with reducing agents can be formed during the surfacing process. This paper presents the results of a comparative analysis of the thermodynamic processes of tungsten oxide reduction by carbon, silicon, aluminum and titanium during arc discharge occurring during surfacing with flux cored wires under a layer of flux. The thermodynamic analysis of 41 reactions in standard states showed that the presence of reducing agents (carbon, silicon, aluminum, titanium) in the flux cored wire used for surfacing will contribute to the formation of silicides and tungsten carbides, and, possibly, tungsten itself. It was determined that the best state for the participation of tungsten oxide in reactions in the arc is WO3(g) gaseous state.

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Effect of Heat Input on Microstructure and Mechanical Properties of Deposited Metal of E120C-K4 High Strength Steel Flux-Cored Wire

Cited by 3 publications

References 31 publications

Study of the Microstructure and Mechanical Property Relationships of Gas Metal Arc Welded Dissimilar Protection 600T, DP450 and S275JR Steel Joints

Study of the Microstructure and Mechanical Property Relationships of Gas Metal Arc Welded Dissimilar Protection 600T, DP450 and S275JR Steel Joints

Effect of Heat Input on the Metal Microstructure and Mechanical Properties of Q960 High‐Strength Steel Solid Core Welding Wire

Thermodynamic aspects of WO3 tungsten oxide reduction by carbon, silicon, aluminum and titanium

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