Design optimization of precision casting for residual stress reduction

Keste, A. A.; Gawande, S. H.; Sarkar, Chandrani

doi:10.1016/j.jcde.2015.10.003

Cited by 14 publications

(7 citation statements)

References 7 publications

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“…The plastic deformation of the billet generates the flow stress at 350 °C [23]. The flow stress dominates within the range of 254.4 and 176.5 MPa (Figure 4a).…”

Section: Simulation Results For the Temperature Effects On The Flow S...mentioning

confidence: 99%

Temperature and Die Angular Effect on Tensile Strength, Hardness, Extrusion Load and Flow Stress in Aluminum 6063 Processed by Equal Channel Angular Extrusion Method

Azeez¹,

Mudashiru²,

Asafa³

et al. 2023

Adv. Sci. Technol. Res. J.

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Developing aluminum with good mechanical properties like hardness, tensile strength, and normal fl ow stress, Equal Channel Angular Extrusion (ECAE) method has been suggested as a suitable metal forming process. The load applied and extrusion temperature normally infl uences the fl ow stress behavior in extruded products and determine their mechanical properties. Consequently, how these factors aff ect mechanical behavior and fl ow stress of Al 6063 processed by ECAE was examined in this study. Extrusion temperatures were 350°C, 425°C, and 500°C with die angles of 130°, 140°, and 150°. 5 mm/s of ram speed was applied. Each extrudate's tensile strength and hardness were measured using a Universal Testing Machine and a Rockwell hardness tester. Samples with equal dimensions and properties were also modeled using the Qform software at the extended die angle and temperature for proper analysis of fl ow stress in the extrudates. According to experimental results, the temperature had a greater eff ect on the tensile strength and hardness of the billet than the die angle. The extrudates' grains also became fi ner as the billet temperature rose. Simulation fi ndings showed that higher billet temperature led to a decrease in the extrudates' fl ow stress. The simulation also demonstrated that billet temperature had a greater impact on extrusion load than die angle, with a maximum extrusion load of 5.5 MN being attained at 350 °C.

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“…The plastic deformation of the billet generates the flow stress at 350 °C [23]. The flow stress dominates within the range of 254.4 and 176.5 MPa (Figure 4a).…”

Section: Simulation Results For the Temperature Effects On The Flow S...mentioning

confidence: 99%

Temperature and Die Angular Effect on Tensile Strength, Hardness, Extrusion Load and Flow Stress in Aluminum 6063 Processed by Equal Channel Angular Extrusion Method

Azeez¹,

Mudashiru²,

Asafa³

et al. 2023

Adv. Sci. Technol. Res. J.

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“…Sand casting simulation is found to reduce defects, like shrinkage and porosity (Sun et al , 2008), improve directional solidification (Kermanpur et al , 2008), improve yield, reduce emission (Haapala et al , 2012; Zheng et al , 2020), improve dimensional accuracy (Ravi and Thiel, 2017), improve gating system (Sun et al , 2011), reduce internal stress (Keste et al , 2016) and improve yield by performing gating system modifications (Kotas et al , 2010).…”

Section: Modeling Of the Casting Processesmentioning

confidence: 99%

Critical parameters influencing the quality of metal castings: a systematic literature review

Suthar

Persis

Gupta

2021

IJQRM

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PurposeCasting is one of the well-known manufacturing processes to make durable parts of goods and machinery. However, the quality of the casting parts depends on the proper choice of process variables related to properties of the materials used in making a mold and the product itself; hence, variables related to product/process designs are taken into consideration. Understanding casting techniques considering significant process variables is critical to achieving better quality castings and helps to improve the productivity of the casting processes. This study aims to understand the computational models developed for achieving better quality castings using various casting techniques.Design/methodology/approachA systematic literature review is conducted in the field of casting considering the period 2000–2020. The keyword co-occurrence network and word cloud from the bibliometric analysis and text mining of the articles reveal that optimization and simulation models are extensively developed for various casting techniques, including sand casting, investment casting, die casting and squeeze casting, to improve quality aspects of the casting's product. This study further investigates the optimization and simulation models and has identified various process variables involved in each casting technique that are significantly affecting the outcomes of the processes in terms of defects, mechanical properties, yield, dimensional accuracy and emissions.FindingsThis study has drawn out the need for developing smart casting environments with data-driven modeling that will enable dynamic fine-tuning of the casting processes and help in achieving desired outcomes in today's competitive markets. This study highlights the possible technology interventions across the metal casting processes, which can further enhance the quality of the metal casting products and productivity of the casting processes, which show the future scope of this field.Research limitations/implicationsThis paper investigates the body of literature on the contributions of various researchers in producing high-quality casting parts and performs bibliometric analysis on the articles. However, research articles from high-quality journals are considered for the literature analysis in identifying the critical parameters influencing quality of metal castings.Originality/valueThe systematic literature review reveals the analytical models developed using simulation and optimization techniques and the important quality characteristics of the casting products. Further, the study also explores critical influencing parameters involved in every casting process that significantly affects the quality characteristics of the metal castings.

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“…Kwon et al [11] modified the gate/runner system and the configuration of overflows of their High Pressure Die Casting (HPDC) setup to reduce porosities induced by air entrapment. Gawande et al [12] performed design optimisation to minimise the residual stresses of a steel part induced during its solidification process using FEA. They performed multi-variable single-objective optimisation and proposed an optimal set of geometrical parameters minimising the maximum value of the residual stress.…”

Section: Introductionmentioning

confidence: 99%

Design Optimisation of the Feeding System of a Novel Counter-Gravity Casting Process

Papanikolaou

Pagone

Georgarakis

et al. 2018

Metals

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The appropriate design of feeders in a rigging system is critical for ensuring efficient compensation for solidification shrinkage, thus eliminating (shrinkage-related) porosity and contributing to the production of superior quality castings. In this study, a multi-objective optimisation framework combined with Computational Fluid Dynamics (CFD) simulations has been introduced to investigate the effect of the feeders’ geometry on shrinkage porosity aiming to optimise casting quality and yield for a novel counter-gravity casting process (CRIMSON). The weighted sum technique was employed to convert this multi-objective optimisation problem to a single objective one. Moreover, an evolutionary multi-objective optimisation algorithm (NSGA-II) has been applied to estimate the trade-off between the objective functions and support decision makers on selecting the optimum solution based on the desired properties of the final casting product and the process characteristics. This study is one of the first attempts to combine CFD simulations with multi-objective optimisation techniques in counter-gravity casting. The obtained results indicate the benefits of applying multi-objective optimisation techniques to casting processes.

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Design optimization of precision casting for residual stress reduction

Cited by 14 publications

References 7 publications

Temperature and Die Angular Effect on Tensile Strength, Hardness, Extrusion Load and Flow Stress in Aluminum 6063 Processed by Equal Channel Angular Extrusion Method

Temperature and Die Angular Effect on Tensile Strength, Hardness, Extrusion Load and Flow Stress in Aluminum 6063 Processed by Equal Channel Angular Extrusion Method

Critical parameters influencing the quality of metal castings: a systematic literature review

Design Optimisation of the Feeding System of a Novel Counter-Gravity Casting Process

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