Mechanical Strength Evaluation of a CuAlBe Shape Memory Alloy under Different Thermal Conditions

Oliveira, Danniel Ferreira de; Lima, Severino Jackson Guedes de; Brito, Ieverton Caiandre Andrade; Gomes, Rodinei Medeiros; Melo, Tadeu Antonio de Azevedo

doi:10.4028/www.scientific.net/msf.643.105

Cited by 11 publications

(8 citation statements)

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“…Cu-Al-Be system polycrystalline shape memory alloys (SMAs), modified with inoculant addition, have good shape memory and superelasticity properties, with a lower processing cost than conventional NiTi system SMAs, making them, attractive for technological applications [1][2][3][4][5] . In addition, Cu-Al-Be SMAs can be modified for use at low temperatures.…”

Section: Introductionmentioning

confidence: 99%

Effect of Hot Rolling on the Thermomechanical properties of a Superelastic Cu-Al-Be-Cr Alloy

et al. 2020

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Shape memory alloys are generally produced by casting processes and are subsequently homogenized. However, to obtain semifinished products on an industrial scale, the ingots from the casting process must be hot worked. In particular, final bar and sheet products can be obtained by hot rolling process. During intense hot work, surface oxidation of the material and microstructural changes may cause modifications to its original thermomechanical properties. In this sense, the present work aimed to study the correlation of the superelastic behavior in a Cu-Al-Be-Cr alloy before and after subjecting it to the hot rolling thermomechanical process. Abnormal grain growth was observed for a hot rolled sample with 30% reduction in initial alloy thickness. This abnormal growth in relation to non-rolled alloy caused an increase in phase transformation temperatures, a reduction in residual strain, a reduction in induction stress and an increase in alloy superelasticity.

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Section: Introductionmentioning

confidence: 99%

Effect of Hot Rolling on the Thermomechanical properties of a Superelastic Cu-Al-Be-Cr Alloy

et al. 2020

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“…The V-notch is the most important parameter to be considered in this kind of mechanical test and was machined using an electrical cutting tool specifically designed for this purpose. Finally, the samples were submitted to another heat treatment to obtain the shape memory effect [6,10]. Toughness of the samples was analysed at temperatures of −150, −100, −50, 0, 50, 100 and 150 • C. For temperatures lower than 50 • C, liquid nitrogen was used and the samples were stored in a thermal recipient.…”

Section: Methodsmentioning

confidence: 99%

“…From the studies that have been carried out, the most significant ones concern the quenching treatment effect on the reversible martensitic transformation [11], the stress analysis of the martensitic transformation [12], stabilization and hyper-stabilization [13], the microstructural characterization of precipitates [14], their superelastic behavior [15] and fatigue resistance [16] and the mechanomagnetic spectroscopy of ferromagnetic SMA [17]. Other studies are mainly related to the effect of the chemical composition of the alloys with and without the addition of grain refiner elements on the mechanical properties of the alloys, such as works presented in [4,6].…”

Section: Introductionmentioning

confidence: 98%

“…Other important characteristics include superelasticity, strong damping effect, excellent capacity to absorb sound, vibration and mechanical waves due to its coarse grain size [4], high mechanical strength, superior resistance to corrosion [5], low manufacturing costs, ease of manufacturing as well as its good usability at low temperatures. These outstanding characteristics justify its widespread use in numerous applications, such as pipe joining in the petroleum industry, as an efficient alternative to traditional pipe welding [6], and to attenuate the effects of seismic vibrations [7,8] and sonorous vibrations [4].…”

Section: Introductionmentioning

confidence: 99%

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Grain size and temperature influence on the toughness of a CuAlBe shape memory alloy

Albuquerque

Melo

Gomes

et al. 2010

Materials Science and Engineering: A

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“…Among different Cu-based shape memory alloys, the Cu-Al-Be exhibits a technological interest, due their properties such as mechanical damping capability [19,20], high mechanical strength [21] and resistance to corrosion [22,23]. This alloy has been considered for several applications such as petroleum industries [21,24] and design of seismic resistant structures, due to damping or internal friction, resulting in a significant quantity energy absorbed [25].…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Nb-Ni Influence on the Mechanical Behavior in a Cu-Al-Be Shape Memory Alloy

Santiago

Alcântara

Costa

et al. 2019

CJAST

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Aims:The objective was to investigate the modifications induced by grain refiners on microstructural and mechanical behaviour of Cu-Al-Be shape memory alloy. Study Design: The experiment was conducted in a completely randomized design. Place and Duration of Study: the experiment was carried out at Methodology: The alloys were prepared by induction melting and hot rolled into strips of 1.0 mm thickness at room temperature without protective atmosphere, followed of heat treatments. Subsequently the microscope analysis, differential scanning calorimetry (DSC), and mechanical Santiago et al.; CJAST, 32(4): 1-8, 2019; Article no.CJAST.46341 2 tests were carried out. Results: The shape memory alloys produced present phase transformations corresponding to the superelastic effect (SE). Grain size reduced considerably with increases content of Nb-Ni. Additionally, the mechanical tensile testing and hardness tests verified that the addition of Nb-Ni increases the stress of the alloy. Conclusion: The manufactured of Cu-Al-Be alloys by induction melting and hot rolled without protective atmosphere is viable. The microstructure analysis shows the grain refinement in Cu-Al-Be alloys containing 1.0 wt% and 1.5wt% of Nb-Ni alloy with considerable reduction in grain size. The reduction in the grain size shows the improvement in the hardness and mechanical tensile properties. Original Research Article

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Mechanical Strength Evaluation of a CuAlBe Shape Memory Alloy under Different Thermal Conditions

Cited by 11 publications

References 1 publication

Effect of Hot Rolling on the Thermomechanical properties of a Superelastic Cu-Al-Be-Cr Alloy

Effect of Hot Rolling on the Thermomechanical properties of a Superelastic Cu-Al-Be-Cr Alloy

Grain size and temperature influence on the toughness of a CuAlBe shape memory alloy

Evaluation of Nb-Ni Influence on the Mechanical Behavior in a Cu-Al-Be Shape Memory Alloy

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