Using PyC modified 3D carbon fiber to reinforce UHTC under low temperature sintering without pressure

Du, Baihe; Cheng, Yuan; Xun, Liancai; Zhang, Shuchang; Tong, J.; Lv, Qingrong; Zhou, Shanbao; Hu, Ping; Zhang, Xinghong

doi:10.1007/s40145-021-0495-9

Cited by 28 publications

(5 citation statements)

References 48 publications

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“…The fracture toughness for the (Ti 0.2 Zr 0.2 Hf 0.2 Nb 0.2 Ta 0.2 )B 2 ceramics could be increased by about 30% after adding 20 vol% SiC particles [17]. Similar improvements in the fracture toughness of (Ti 0.2 Zr 0.2 Hf 0.2 Nb 0.2 Ta 0.2 )B 2 -SiC were achieved by Liu et al [16] and Zhang et al [18]. Although SiC can significantly promote the densification and improve the intrinsic strength of HEBs, the flaw tolerance and capacity of energy dissipation of HEBs cannot be effectively improved by the introduction of SiC [19,20].…”

Section: Introductionsupporting

confidence: 62%

Improved damage tolerance and oxidation resistance of (Ti _0.2Zr _0.2Hf _0.2Nb _0.2Ta _0.2)B ₂–SiC by introducing chopped carbon fibers

Huang,

Wang,

Fang

et al. 2024

Journal of Advanced Ceramics

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High-entropy diborides (HEBs) are considered as promising high-temperature structure materials owing to their high melting point and excellent thermal stability. However, the intrinsic brittleness is the main obstacle that seriously limits their practical applications. To overcome with this obstacle, carbon fibers (C f ) with outstanding mechanical properties are used in the present work as a first attempt to improve the damage tolerance of HEBs. The as-prepared C f /(Ti 0.2 Zr 0.2 Hf 0.2 Nb 0.2 Ta 0.2 )B 2 -SiC composite (C f /HEB-SiC) shows high relative density (97.9%) and good mechanical properties with flexural strength of 411±3 MPa and fracture toughness of 6.15±0.11 MPa•m 1/2 . More importantly, the damage tolerance parameter (D t ) has increased from 0.10 m 1/2 for HEB-SiC to 0.29 m 1/2 for C f /HEB-SiC. Through microstructural analysis and Vickers indentation of the composite, the toughening mechanisms are disclosed. The carbon fibers coated with carbon coatings demonstrate unique capacity for prolonging the crack propagation path, which promotes the reliability of the composite effectively. Moreover, the C f /(Ti 0.2 Zr 0.2 Hf 0.2 Nb 0.2 Ta 0.2 )B 2 -SiC composite also exhibits good static oxidation resistance in the temperature range of 1100-1500 ℃ in air due to the formation of the protective oxide layer constituting of multicomponent oxides (Zr)HfTiO 4 and (Zr)Hf 6 Ta 2 O 17 embedded in a continuous SiO 2 glass. These results are promising, and this primary work can be used as a reference to the synthesis of C f /HEBs for thermal protection materials under hightemperature serving conditions.

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Section: Introductionsupporting

confidence: 62%

Improved damage tolerance and oxidation resistance of (Ti _0.2Zr _0.2Hf _0.2Nb _0.2Ta _0.2)B ₂–SiC by introducing chopped carbon fibers

Huang,

Wang,

Fang

et al. 2024

Journal of Advanced Ceramics

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“…Figure 13 shows the schematic diagram of the crack extension of the C f /SiC composite during the three‐point bending test. The bending strength and fracture toughness of C f /SiC composites are mainly improved by the pullout, debonding, and breakage of C f to enable the material to absorb more energy 31,38 . Figure 14 shows the bending strength, porosity, and density of the green bodies with different C f contents.…”

Section: Resultsmentioning

confidence: 99%

Additive manufacturing of continuous carbon fiber–reinforced silicon carbide ceramic composites

Liu,

Qiu,

Zhang

et al. 2023

Int J Applied Ceramic Tech

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A material extrusion (MEX) technology has been developed for the additive manufacturing of continuous carbon fiber–reinforced silicon carbide ceramic (Cf/SiC) composites. By comparing and analyzing the rheological properties of the slurries with different compositions, a slurry with a high solid loading of 48.1 vol% and high viscosity was proposed. Furthermore, several complex structures of Cf/SiC ceramic composites were printed by this MEX additive manufacturing technique. Phenolic resin impregnation–carbonization process reduces the apparent porosity of the green body and protects the Cf. Finally, the reactive melting infiltration (RMI) process was used to prepare samples with different Cf contents from 0 to 2 K (a bundle of carbon fibers consisting of 1000 fibers). Samples with Cf content of 1 K show the highest bending strength (161.6 ± 10.5 MPa) and fracture toughness (3.72 ± 0.11 MPa·m1/2) while the thermal conductivity of the samples with the Cf content of 1 K reached 11.0 W/(m·K). This study provides a strategy to prepare Cf/SiC composites via MEX additive manufacturing and RMI.

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“…Lots of effort has been made to alleviate the brittle failure of ceramic materials. Such as phase change toughening, [3][4][5] particle dispersion toughening, 6,7 whisker toughening, [8][9][10] long fiber toughening, 11,12 and bionic structure toughening 2,13,14 developed to overcome the sensitivity to defect. Among them, the long fiber toughening and bionic structure composite ceramics achieve the optimal nonbrittle failure manner with high toughness and work of fracture together with considerable strength.…”

Section: Introductionmentioning

confidence: 99%

High damage tolerant Al₂O₃ composite ceramics constructed with short Al₂O₃ fibers

Zhou

et al. 2023

Int J Applied Ceramic Tech

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The catastrophic fracture characteristics of ceramic materials have become one of the most serious factors limiting their application in critical areas, as a result, it is urgent to overcome the brittleness and improve the damage tolerance of ceramic materials. Herein, a series of Al2O3 composite ceramics developed with short Al2O3 fibers and a compound interface phase composed of Al2O3 and h‐BN powders, followed by investigating their fracture behaviors and damage tolerance. Results show that these composites present progressive fracture manners with the rising resistance curve (R‐curve) behaviors, and the maximum crack growth toughness of the sample with 15% compound interface phase reaches above 10 MPa·m1/2 (135% increase with respect to the reference alumina). Meanwhile, the composite ceramic exhibits an excellent ability to resist catastrophic failure with a large critical crack size (105.47 ± 19.11 μm) and high damage tolerance parameter (0.71 ± 0.06 m1/2), which are close to 14.57 times and 5.92 times higher than those of the reference alumina. The superior performances are mainly attributed to the precise combination of compound interface phase for inducing crack and interlocking Al2O3 fibers for load capacity.

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Using PyC modified 3D carbon fiber to reinforce UHTC under low temperature sintering without pressure

Cited by 28 publications

References 48 publications

Improved damage tolerance and oxidation resistance of (Ti _0.2Zr _0.2Hf _0.2Nb _0.2Ta _0.2)B ₂–SiC by introducing chopped carbon fibers

Improved damage tolerance and oxidation resistance of (Ti _0.2Zr _0.2Hf _0.2Nb _0.2Ta _0.2)B ₂–SiC by introducing chopped carbon fibers

Additive manufacturing of continuous carbon fiber–reinforced silicon carbide ceramic composites

High damage tolerant Al₂O₃ composite ceramics constructed with short Al₂O₃ fibers

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Using PyC modified 3D carbon fiber to reinforce UHTC under low temperature sintering without pressure

Cited by 28 publications

References 48 publications

Improved damage tolerance and oxidation resistance of (Ti 0.2Zr 0.2Hf 0.2Nb 0.2Ta 0.2)B 2–SiC by introducing chopped carbon fibers

Improved damage tolerance and oxidation resistance of (Ti 0.2Zr 0.2Hf 0.2Nb 0.2Ta 0.2)B 2–SiC by introducing chopped carbon fibers

Additive manufacturing of continuous carbon fiber–reinforced silicon carbide ceramic composites

High damage tolerant Al2O3 composite ceramics constructed with short Al2O3 fibers

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Improved damage tolerance and oxidation resistance of (Ti _0.2Zr _0.2Hf _0.2Nb _0.2Ta _0.2)B ₂–SiC by introducing chopped carbon fibers

Improved damage tolerance and oxidation resistance of (Ti _0.2Zr _0.2Hf _0.2Nb _0.2Ta _0.2)B ₂–SiC by introducing chopped carbon fibers

High damage tolerant Al₂O₃ composite ceramics constructed with short Al₂O₃ fibers