Surface modification technologies for enhancing the tribological properties of cemented carbides: A review

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

doi:10.1016/j.triboint.2023.108257

Cited by 24 publications

(8 citation statements)

References 242 publications

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“…The laser beam was focused by a convex lens [79]. Smart materials with laser-modified surfaces can be used in automotive components to improve the wear resistance and reduce the friction [80][81][82]. The results of various processes, such as laser remelting, laser texturing, and laser shock hardening, demonstrated that fluence was the most critical factor influencing the surface roughness and the microstructure.…”

Section: Laser Modification For Smart Materialsmentioning

confidence: 99%

Fabrication of Smart Materials Using Laser Processing: Analysis and Prospects

Murzin,

Stiglbrunner

2023

Applied Sciences

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Laser processing is a versatile tool that enhances smart materials for diverse industries, allowing precise changes in material properties and customization of surface characteristics. It drives the development of smart materials with adaptive properties through laser modification, utilizing photothermal reactions and functional additives for meticulous control. These laser-processed smart materials form the foundation of 4D printing that enables dynamic shape changes depending on external influences, with significant potential in the aerospace, robotics, health care, electronics, and automotive sectors, thus fostering innovation. Laser processing also advances photonics and optoelectronics, facilitating precise control over optical properties and promoting responsive device development for various applications. The application of computer-generated diffractive optical elements (DOEs) enhances laser precision, allowing for predetermined temperature distribution and showcasing substantial promise in enhancing smart material properties. This comprehensive overview explores the applications of laser technology and nanotechnology involving DOEs, underscoring their transformative potential in the realms of photonics and optoelectronics. The growing potential for further research and practical applications in this field suggests promising prospects in the near future.

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Section: Laser Modification For Smart Materialsmentioning

confidence: 99%

Fabrication of Smart Materials Using Laser Processing: Analysis and Prospects

Murzin,

Stiglbrunner

2023

Applied Sciences

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“…The use of superhard coatings is not only limited to enhancing hardness but also extends to increasing wear resistance, reducing friction, and ensuring long-term durability in various industrial applications. These coatings, owing to their mechanical properties, significantly contribute to the improved performance and lifespan of critical components through multiple sectors [1][2][3].…”

Section: Introductionmentioning

confidence: 99%

Tribological and Mechanical Performance of Hybrid Tisin/DLC Coatings Deposited Using the Filtered Cathodic Arc Technique

2024

Journal of Southwest Jiaotong University

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This study focuses on fabricating and enhancing the mechanical and tribological properties of novel hybrid TiSiN/DLC coatings deposited on tungsten carbide cutting tools using the filtered cathodic arc technique. The methodology involves incorporating DLC on the top surface and TiSiN as an interlayer, with a titanium interlayer used to ensure good adhesion of the coatings. XRD analyses indicate a preferred orientation of ( 111) and ( 200) with a high hardness phase. Raman spectroscopy confirms the presence of DLC nature through characteristic G and D bands. SEM and AFM analyses revealed reduced surface roughness and enhanced structural properties characterized by smooth and dense structures. The TiSiN/DLC coatings demonstrate a significant increase in hardness reaching up to 36.2 GPa and an elastic modulus of 320 GPa, along with excellent adhesion strength compared with individual DLC coatings. Furthermore, these hybrid coatings exhibit superior tribological properties, including remarkable wear resistance and a low coefficient of friction, surpassing TiSiN and DLC coatings. This research highlights the promising potential of TiSiN/DLC hybrid coatings for various industrial applications, such as cutting tools, automotive components, and medical implants, where superhard coatings and robust tribological performance are crucial. The comprehensive evaluation and characterization of these hybrid coatings, tailored specifically for tungsten carbide cutting tools, underscores their superiority over

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“…Direct energy deposition of metallic alloys can be realized by lasercladding in both powder-feeding and -bed configurations using the rapid heating and fast cooling characteristics of laser process [4][5][6][7][8][9]. Pressure waves generated from laser-induced plasma have been developed to laser-shock peening (LSP) for surface integrity enhancement and directly shape-forming of metallic alloys [10][11][12][13][14]. The precise power distribution and spot size of the laser beam as well as the pulse configurations of a pulsed laser, together with the digitalizable and programable control, have been recognized as an advanced technique for surface engineering, e.g., patterning, texturing, and hardening, of metallic alloys [15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Laser-treatment-induced surface integrity modifications of stainless steel

Gong

Wei

Meng

et al. 2023

Mater. Res. Express

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Scanning of high-power laser beam on surface of martensitic stainless steel (SS420) has been studied, addressing the effect of scanning rate V on integrity modifications in the near-surface regions. Structural, compositional, and crystallographic characterizations revealed the presence of ablations, surface melting/resolidification, surface oxidations, and austenite (γ-phase) precipitations when V ≤ 20 mm/s. Melt pool (MP), heat affected zone (HEA), and base material have been clearly distinguished at the cross-section of the slow-scanned samples. Adjacent MPs partially overlapped when V = 5 mm/s. The γ-phase precipitations solely occurred in the MPs, i.e., of ~ 400 μm deep for V = 5 mm/s, while oxidations dominantly occurred in the surface regions of shallower than ~30 μm within the MPs. Compositional analysis revealed increased Cr-, Mn-, and Si-to-Fe ratios at the laser-scanned surface but absence of variations along the surface normal direction. Hardened surface has been achieved up to 805 HV, and the hardening monotonically decreased when moving deeper (i.e., ~1000 μm) into the base material. These observations shed new lights on surface engineering of metallic alloys via laser-based direct energy treatments.

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Surface modification technologies for enhancing the tribological properties of cemented carbides: A review

Cited by 24 publications

References 242 publications

Fabrication of Smart Materials Using Laser Processing: Analysis and Prospects

Fabrication of Smart Materials Using Laser Processing: Analysis and Prospects

Tribological and Mechanical Performance of Hybrid Tisin/DLC Coatings Deposited Using the Filtered Cathodic Arc Technique

Laser-treatment-induced surface integrity modifications of stainless steel

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