A focused review on the tribological behavior of C/SiC composites: Present status and future prospects

Diao, Quanwei; Zou, Hongbo; Ren, Xinyi; Chun-shen, Wang; Wang, Yan; Li, Hongyu; Sui, Tianyi; Lin, Bin; Yan, Shuai

doi:10.1016/j.jeurceramsoc.2023.03.002

Cited by 23 publications

(9 citation statements)

References 179 publications

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“…From the ANOVA results, we can see that the factor degrees of freedom f factor = 3 and the error degrees of freedom fe = 6. A check of the F-distribution table gives F0.01(f factor, fe) = F0.01 (3,6) Table 8 shows the ANOVA results for each of the orthogonal test results in Table 5. Figure 11 visualizes the F-value results of the significance analysis F-test for the effect of each process parameter on the grinding force of 2.5D-Cf/SiC fibers oriented at 0°, 45°, and 90°.…”

Section: Range Analysis Results Of Different Fiber Orientation Anglesmentioning

confidence: 99%

“…2.5D-Cf/SiC in addition to the advantages of silicon carbide such as high hardness, high-temperature resistance, corrosion resistance, wear resistance, low density, and ease of adapting to extreme environments [4] also greatly compensates for its disadvantages such as high brittleness [5] . 2.5D-Cf/SiC composites are currently recognized as one of the advanced high-temperature structural ceramic materials and friction and wear materials [6] , which are mainly used in the field of aerospace and automotive brake systems [7] . 2.5D-Cf/SiC composites are commonly used in the machining of high-temperature resistant structural components such as thermal shielding layers on spacecraft and nozzle-guided blades on aeroengines [8] , to be adapted to extremely high temperatures and high pressures in the operating environment [9] .…”

Section: Introductionmentioning

confidence: 99%

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Empirical formula model and process parameter optimization of two-dimensional ultrasonic assisted grinding force based on 2.5D-Cf/SiC fiber orientation

Wang,

Xin,

et al. 2024

Preprint

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Due to the anisotropic characteristic of carbon fiber-reinforced silicon carbide ceramics, the fiber orientation angle significantly affects the grinding force. Therefore, it is important to study the influence rule of different fiber orientations on the grinding force of 2.5D-Cf/SiC composites. To study the comprehensive influence of machine tool parameters and the anisotropy of carbon fiber reinforced ceramic matrix composites on the grinding force, two-dimensional ultrasonic plane grinding was studied by orthogonal test and single factor experiment. Based on the multi-exponential fitting analysis method of multiple linear regression equation, the empirical equations of power exponential grinding force prediction model of 2D ultrasonic assisted grinding and conventional grinding 2.5D-Cf/SiC composites at 0°, 45°, 90° fiber orientation and considering fiber orientation and ultrasonic amplitude were established respectively. To verify the empirical formula model in predicting the grinding force of 2.5D-Cf/SiC composites under various fiber orientation angles, the regression equation and regression coefficient of the model were examined. The influence of 2.5D-Cf/SiC grinding parameters on the grinding force was analyzed. The parameters of the grinding force model were optimized based on range analysis and variance analysis, and the optimal process parameter combination was obtained. The results show that the grinding force is negatively correlated with the linear speed, and positively correlated with the feed speed and grinding depth within the range of experimental parameters. The maximum reduction of the normal grinding force is 29.78% when the line speed is 10.48m/s, the feed speed is 100 mm/min, the grinding depth is 50µm, and along the 45° fiber direction. The optimal grinding parameter combination is a line speed of 23.60m/s, feed speed of 5mm/min, and grinding depth of 10µm along the 0° fiber orientation.

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Section: Range Analysis Results Of Different Fiber Orientation Anglesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Empirical formula model and process parameter optimization of two-dimensional ultrasonic assisted grinding force based on 2.5D-Cf/SiC fiber orientation

Wang,

Xin,

et al. 2024

Preprint

View full text Add to dashboard Cite

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“…Fiber reinforced ceramic matrix composites exhibit excellent properties including high damage tolerance, thermal shock resistance, satisfactory hardness, and excellent wear resistance, making them attractive in a wide range of applications in high-temperature structural and functional materials. [1][2][3] Among them, carbon fiber reinforced SiOC (C/SiOC) composites showed excellent mechanical performance, high-temperature stability, and oxidization resistance. 4,5 However, due to the escalating performance demands of ceramic matrix composites in aerospace, defense, and military industries, it is imperative to further enhance their capabilities.…”

Section: Introductionmentioning

confidence: 99%

Effects of in situ formed nanostructures on the structure and properties of C/SiOC composites

Zhao,

Guo,

2024

J Am Ceram Soc.

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In this paper, Ni was introduced into the matrix of carbon fiber reinforced SiOC (C/SiOC) composites by the precursor infiltration and pyrolysis method to catalyze the generation of in situ formed nanostructures including carbon nanotubes (CNTs), turbostratic carbon, and SiC. The effect of in situ formed nanostructures catalyzed by Ni on the properties of the C/SiOC composites was investigated. The results demonstrated that the presence of in situ formed nanostructures in the matrix improved the densification and mechanical properties of C/SiOC composites. In addition, the incorporation of in situ formed nanostructures facilitated the formation of thermal conductivity pathways within the composites, thereby enhancing the thermal conductivity of C/SiOC composites. Furthermore, in situ formed nanostructures‐containing C/SiOC composites developed a carbon friction layer comprising CNTs and turbostratic carbon, which significantly enhanced the abrasion resistance, endowing C/SiOC composites stable friction coefficients, and lower levels of wear.

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“…C/C-SiC composite materials are gradually being used in luxury cars, such as Ferrari and Porsche 911 [9,10]. With the improvements in production technology and the decrease in manufacturing costs, C/C-SiC brake materials are expected to be more widely used in new energy vehicles, armored vehicles, high-speed trains, and other fields in the future [9,11,12].…”

Section: Introductionmentioning

confidence: 99%

Investigation of Impact of C/Si Ratio on the Friction and Wear Behavior of Si/SiC Coatings Prepared on C/C-SiC Composites by Slurry Reaction Sintering and Chemical Vapor Infiltration

Zhao,

Cheng,

Chen

et al. 2024

Coatings

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Carbon/carbon (C/C)-SiC composite materials have a series of outstanding advantages, such as a light weight, resistance to thermal degradation, excellent friction performance, and good stability in complex environments. In order to improve the wear resistance of the C/C-SiC composite matrix, Si/SiC coatings were prepared by a combination of chemical vapor infiltration and reactive sintering. The wear performance of Si/SiC coatings with different amounts of silicon carbide was investigated. When the carbon silicon ratio in the slurry was 1:3, the SiC particle content in the coating was 93.0 wt.%; the prepared Si/SiC coating exhibited the lowest wear rate of 3.2 × 10−3 mg·N−1·m−1 among the four coatings; and its frictional coefficient was 0.95, which was higher than that of the substrate. As the residual Si content in the coating decreased, the continuity between SiC particles in the coating was improved. Both the high hardness of SiC and the dense coating contributed significantly to enhancing the coating’s wear resistance.

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A focused review on the tribological behavior of C/SiC composites: Present status and future prospects

Cited by 23 publications

References 179 publications

Empirical formula model and process parameter optimization of two-dimensional ultrasonic assisted grinding force based on 2.5D-Cf/SiC fiber orientation

Empirical formula model and process parameter optimization of two-dimensional ultrasonic assisted grinding force based on 2.5D-Cf/SiC fiber orientation

Effects of in situ formed nanostructures on the structure and properties of C/SiOC composites

Investigation of Impact of C/Si Ratio on the Friction and Wear Behavior of Si/SiC Coatings Prepared on C/C-SiC Composites by Slurry Reaction Sintering and Chemical Vapor Infiltration

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