Compressive Behavior of Some Balls Manufactured by 3D Printing from Ceramic–Polymer Composite Materials

Hrițuc, Adelina; Ermolai, Vasile; Mihalache, Andrei Marius; Andrușcă, Liviu; Dodun, Oana; Nagîț, Gheorghe; Boca, Marius Andrei; Slătineanu, Laurențiu

doi:10.3390/mi15010150

Cited by 2 publications

(2 citation statements)

References 28 publications

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“…The recorded variations were Fx (material strength with respect to scratch force), CoF (friction coefficient), and AE (acoustic emission, representing the occurrence of acoustic (elastic) ripple propagation in solid materials) over a 10 mm distance. Variations in chemical composition (percentage of Be; Table 1) and material processing via hot rolling do not reveal large differences in the behavior of the surface mechanical properties [3,25].…”

Section: Scratch Tests Resultsmentioning

confidence: 94%

“…Variations in chemical composition (percentage of Be; Table 1) and material processing via hot rolling do not reveal large differences in the behavior of the surface mechanical properties [3,25]. CoF exhibits small surface fluctuations that may result from grain boundaries, stressinduced martensite zones, or various metal compounds with a lower friction coefficient than the copper-based solid solution [26].…”

Section: Scratch Tests Resultsmentioning

confidence: 97%

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Analysis of Chemical, Microstructural and Mechanical Properties of a CuAlBe Material Regarding Its Role as a Non-Sparking Material

Chelariu,

Cimpoesu,

Jurca

et al. 2024

Materials

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We developed and analyzed a novel non-sparking material based on CuAlBe for applications in potentially explosive environments. Using a master alloy of CuBe, an established material for anti-sparking tools used in oil fields, mines, or areas with potentially explosive gas accumulations, and pure Al, we used an Ar atmosphere induction furnace to obtain an alloy with ~10 wt% Al and ~2 wt% Be percentages and good chemical and structural homogeneity. The new material was tested in an explosive gaseous mixture (10% H2 or 6.5% CH4) under extremely strong wear for 16,000 cycles, and no hot sparks capable of igniting the environment were produced. The material was used in the form of hot-rolled plates obtained from melted ingots. The experimental results reflect the use of a suitable material for non-sparking tools. This material has good deformability during hot rolling, abnormal grain growth during deformation under heat treatment and special thermo-mechanical processing, and no high chemical composition variation. Additionally, there are slightly different corrosion resistance and mechanical properties between the melt and hot-rolled state of CuAlBe material. Through hot rolling, the material’s corrosion resistance increased, reducing the chances of generating sparks capable of causing explosions.

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Section: Scratch Tests Resultsmentioning

confidence: 94%

Section: Scratch Tests Resultsmentioning

confidence: 97%

Analysis of Chemical, Microstructural and Mechanical Properties of a CuAlBe Material Regarding Its Role as a Non-Sparking Material

Chelariu,

Cimpoesu,

Jurca

et al. 2024

Materials

View full text Add to dashboard Cite

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Research on a Support-Free Five-Degree-of-Freedom Additive Manufacturing Method

Han,

Wu,

Liu

et al. 2024

Micromachines

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When using traditional 3D printing equipment to manufacture overhang models, it is often necessary to generate support structures to assist in the printing of parts. The post-processing operation of removing the support structures after printing is time-consuming and wastes material. In order to solve the above problems, a support-free five-degree-of-freedom additive manufacturing (SFAM) method is proposed. Through the homogeneous coordinate transformation matrix, the forward and inverse kinematics equations of the five-degree-of-freedom additive manufacturing device (FAMD) are established, and the joint variables of each axis are solved to realize the five-axis linkage of the additive manufacturing (AM) device. In this research work, initially, the layered curve is obtained through the structural lines of the overhang model, and a continuous path planning of the infill area is performed on it, and further, the part printing experiments are conducted on the FAMD. Compared with the traditional three-axis additive manufacturing (TTAM) method, the SFAM method shortens the printing time by 23.58% and saves printing materials by 33.06%. The experimental results show that the SFAM method realizes the support-free printing of overhang models, which not only improves the accuracy of the parts but also the manufacturing efficiency of the parts.

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Compressive Behavior of Some Balls Manufactured by 3D Printing from Ceramic–Polymer Composite Materials

Cited by 2 publications

References 28 publications

Analysis of Chemical, Microstructural and Mechanical Properties of a CuAlBe Material Regarding Its Role as a Non-Sparking Material

Analysis of Chemical, Microstructural and Mechanical Properties of a CuAlBe Material Regarding Its Role as a Non-Sparking Material

Research on a Support-Free Five-Degree-of-Freedom Additive Manufacturing Method

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