Author(s)

Chaoran Tong ¹, Lei Que ¹, Xuesong Zhang ²

Affiliation(s)

¹ School of Fine Arts and Design, Guangzhou University, Guangzhou, Guangdong, 510006, China
² College of Art and Design, Guangzhou City Construction College, Guangzhou, Guangdong, 510925, China

Corresponding Author

Lei Que

ABSTRACT

In today's engineering and industrial fields, the application of composite materials is no longer uncommon, and ceramic and fiber composite materials, as the main ones, can combine the advantages of the two materials and have a wider range of applications. In order to better prepare this material, further improve its performance, or reduce its preparation cost, this article proposes a method of using high-temperature sintering. Moreover, this article also conducts comparative experiments at the end to verify this method. Taking the material strength comparison experiment as an example, the average strength of the materials in the experimental group using high-temperature sintering is 288.9Mpa, while the average strength of the materials in the control group using ordinary sintering is 272.3Mpa. The obvious experimental gap fully demonstrates the effectiveness of this method.

KEYWORDS

High Temperature Sintering, Ceramic Materials, Composite Materials, Material Strength, High Temperature Resistance

CITE THIS PAPER

Chaoran Tong, Lei Que, Xuesong Zhang, The Impact of High-Temperature Sintering on the Properties of Ceramic and Fiber Composite Materials and Its Optimization Strategies. Modern Physical Chemistry Research (2024) Vol. 4: 1-8. DOI: http://dx.doi.org/10.23977/mpcr.2024.040101.

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