Investigation and Analysis of Properties of Magnesium Alloy for Suitability to Electric Vehicle Components

Thiagarajan, C.; Lakshminarayanan, N.; Anand, A.; Santhosh, M.; Anderson, Naveen J.

doi:10.1088/1757-899x/993/1/012007

Cited by 4 publications

(3 citation statements)

References 4 publications

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“…This weight reduction greatly affects emission reduction [ 1 ], which has a positive impact on environmental factors and, moreover, will also bring benefits from an economic perspective [ 2 ]. Reflecting on recent trends, the utilization of magnesium alloys has been used in automotive components [ 3 ], and it has even been reported that several types of magnesium alloys have begun to be used in the manufacturing industry for applications in electric vehicle chassis [ 4 ] and body structures [ 5 ]; this has attracted the attention of scientists worldwide to develop magnesium-based alloys and their composites for many applications. The choice of magnesium as a potential candidate for engineering applications is due to its good castability and machinability, high specific strength, and, more uniquely, well-controlled weldability [ 5 , 6 ].…”

Section: Introductionmentioning

confidence: 99%

LCF and HCF of Short Carbon Fibers Reinforced AE42 Mg Alloy

Alsaleh,

Ataya,

Latief

et al. 2023

Materials

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Lightweight magnesium alloys and magnesium matrix composites have recently become more widespread for high-efficiency applications, including automobile, aerospace, defense, and electronic industries. Cast magnesium and magnesium matrix composites are applied in many highly moving and rotating parts, these parts can suffer from fatigue loading and are consequently subjected to fatigue failure. Reversed tensile-compression low-cycle fatigue (LCF) and high-cycle fatigue (HCF) of short fibers reinforced and unreinforced AE42 have been studied at temperatures of 20 °C, 150 °C, and 250 °C. To select suitable fatigue testing conditions, tensile tests have been carried out on AE42 and the composite material AE42-C at temperatures of up to 300 °C. The Wohler curves σa (NF) have shown that the fatigue strength of the reinforced AE42-C in the HCF range was double that of unreinforced AE42. In the LCF range at certain strain amplitudes, the fatigue life of the composite materials is much less than that of the matrix alloys, this is due to the low ductility of this composite material. Furthermore, a slight temperature influence up to 150 °C has been established on the fatigue behavior of the AE42-C. The fatigue life curves Δεtotal (NF) were described using the Basquin and Manson–Coffin approaches. Fracture surface investigations showed a mixed mode of serration fatigue pattern on the matrix and carbon fibers fracturing and debonding from the matrix alloy.

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Section: Introductionmentioning

confidence: 99%

LCF and HCF of Short Carbon Fibers Reinforced AE42 Mg Alloy

Alsaleh,

Ataya,

Latief

et al. 2023

Materials

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“…The search for lightweight construction materials that are characterized by favorable strength parameters is a topical current area of interest among scientific circles, which invariably considers magnesium alloys to be among the most important of the group of materials mentioned above. Nowadays, since electric cars make up an increasing percentage of the manufactured assortment of cars, reducing the curb weight of cars and the consumption of energy or fuel is very important for manufacturers and consumers [1][2][3][4][5][6]. Magnesium alloys, as the lightest construction material exhibiting good heat dissipation and vibration damping, have been of interest to the automotive industry for over two decades [7][8][9][10][11][12][13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Analysis of the Effect of the Elongation Operation on the Welding of Internal Metallurgical Discontinuities

Banaszek,

Bajor,

Kawałek

et al. 2023

Materials

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This article discusses the results of our research into the effect of elongation on the welding of internal metallurgical discontinuities for two different geometrical shapes of a model feedstock of a selected magnesium alloy. Model discontinuities, specifically those of the metallurgical void type, were placed in various local zones of the modelled feedstock to check the influence of their location on their welding. The numerical modelling was carried out using the Forge®NxT2.1 application based on the finite element method. The results of the numerical tests were verified in laboratory conditions using the Gleeble simulator of metallurgical processes. Based on this research, it was found that the geometric shape of the feedstock material and the location of internal metallurgical discontinuities have a significant impact on the welding of discontinuities. The optimal values of the main process parameters of the elongation operation in flat dies were also determined for use in individual forging stages in order to eliminate internal metallurgical discontinuities. On the basis of the numerical studies carried out and their verification under laboratory conditions, it was concluded that a relative draft equal to 35% should be applied to weld the metallurgical discontinuities, which would result in a favorable hydrostatic pressure distribution within the discontinuities.

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“…The former can be accomplished by mixing in appropriate reinforcing particles with the current material. Thiagarajan et al [17] have discussed improving vehicle performance by lowering the rolling resistance and boosting the overall efficiency. Zouari et al [18], have investigated the transient hygroscopic behaviour of a 2/2 twill flax fabric-reinforced epoxy composite, a three-node membrane finite element was constructed.…”

Section: Introductionmentioning

confidence: 99%

On the Selection of a Composite Material for Two-Wheeler Foot Bracket Failure Prevention through Simulation and Mathematical Modeling

Sivagami¹,

Bejaxhin²,

Gayathri³

et al. 2022

Fluid Dynamics &Amp; Materials Processing

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A foot bracket is a metal panel bracket used to mount and support the footrest in two-wheeler systems. It holds the footrest in place while rigidly supporting it. In working conditions, this element has often been observed to fail when specific load-fluctuation conditions are established at its rear end. Appropriate materials therefore need to be identified to overcome such a recurring failure. To address these issues, the present study has been implemented with the specific objective to determine the response of selected Al6061-T6 and Al7075-T6 Hybrid Metal Matrix Composites (HMMC). The results, obtained using the ANSYS Software, show that the selected composites can withstand 636,962 N/m² of maximum stress and 8.88 × 10 −6 m of minimum displacement. These results are also compared with relevant mathematical models and it is concluded that the identified material combination provides the required improvement of structural stability that can withstand the load fluctuation on the foot bracket.

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Investigation and Analysis of Properties of Magnesium Alloy for Suitability to Electric Vehicle Components

Cited by 4 publications

References 4 publications

LCF and HCF of Short Carbon Fibers Reinforced AE42 Mg Alloy

LCF and HCF of Short Carbon Fibers Reinforced AE42 Mg Alloy

Analysis of the Effect of the Elongation Operation on the Welding of Internal Metallurgical Discontinuities

On the Selection of a Composite Material for Two-Wheeler Foot Bracket Failure Prevention through Simulation and Mathematical Modeling

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