Performance gradient distribution of (Ti,W)C cermet by skin effects of high‐frequency spark plasma sintering

Abstract: A (Ti,W)C cermet with graded properties was prepared using high‐frequency spark plasma sintering (HF‐SPS). The effects of the sintering process on the microstructure and mechanical properties of the prepared cermet material were studied, and the densification behavior of the material was analyzed using scanning electron microscopy and energy‐dispersive X‐ray spectroscopy. Owing to the skin effect and pulse current discharge in HF‐SPS, the experimental results showed different sintering effects, as indicated by… Show more

“…To overcome these limitations, it is critical to develop a rapid and innovative method for preparing AlON ceramics with small grain sizes to improve their mechanical properties. Spark plasma sintering (SPS) is a promising powder metallurgy sintering technology with a wide range of applications, including the preparation of ceramic materials, metal matrix composites, and fiber‐reinforced composites 9–11 . Unlike traditional sintering methods, SPS generates heat, an electric field, and plasma by pulse current inside the sample to provide a sintering driving force 12,13 .…”

“…Spark plasma sintering (SPS) is a promising powder metallurgy sintering technology with a wide range of applications, including the preparation of ceramic materials, metal matrix composites, and fiber-reinforced composites. [9][10][11] Unlike traditional sintering methods, SPS generates heat, an electric field, and plasma by pulse current inside the sample to provide a sintering driving force. 12,13 SPS has many advantages, such as a high heating rate, short sintering time, low sintering temperature, and rapid cooling, leading to a high densification of the sintered body in a short time and smaller grains compared to their conventionally sintered counterparts.…”

Effects of sintering aids on microstructure, mechanical, and optical properties of AlON ceramics synthesized by SPS

“…To overcome these limitations, it is critical to develop a rapid and innovative method for preparing AlON ceramics with small grain sizes to improve their mechanical properties. Spark plasma sintering (SPS) is a promising powder metallurgy sintering technology with a wide range of applications, including the preparation of ceramic materials, metal matrix composites, and fiber‐reinforced composites 9–11 . Unlike traditional sintering methods, SPS generates heat, an electric field, and plasma by pulse current inside the sample to provide a sintering driving force 12,13 .…”

“…Spark plasma sintering (SPS) is a promising powder metallurgy sintering technology with a wide range of applications, including the preparation of ceramic materials, metal matrix composites, and fiber-reinforced composites. [9][10][11] Unlike traditional sintering methods, SPS generates heat, an electric field, and plasma by pulse current inside the sample to provide a sintering driving force. 12,13 SPS has many advantages, such as a high heating rate, short sintering time, low sintering temperature, and rapid cooling, leading to a high densification of the sintered body in a short time and smaller grains compared to their conventionally sintered counterparts.…”

Effects of sintering aids on microstructure, mechanical, and optical properties of AlON ceramics synthesized by SPS

Progress in processing of porous titanium: a review

Low-temperature sintering mechanization of high-entropy (W,Nb,Mo,Ta,Ti)C cermet via spark plasma coupled high-frequency induction sintering