Clean and durable thick nanodiamond composite hard coating deposited on cemented carbide towards sustainable machining: Eco-friendly fabrication, characterization, and 3-E analysis

IF 5.3 Q2 ENGINEERING, ENVIRONMENTAL Cleaner Engineering and Technology Pub Date : 2024-09-03 DOI:10.1016/j.clet.2024.100804
Mohamed Egiza , Mohamed Ragab Diab , Ali M. Ali , Koki Murasawa , Tsuyoshi Yoshitake
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Abstract

This research explores a sustainable approach for fabricating high-performance nanodiamond composite (NDC) hard coatings for dry machining. Aiming to address limitations in conventional coatings, such as environmental concerns, restricted film thickness, and compromised performance. The study utilizes Coaxial Arc Plasma Deposition (CAPD), a clean and efficient technique, to deposit thick (10 μm) NDC films directly on WC−Co substrates without chemical etching. Compared to traditional Chemical Vapor Deposition (CVD), CAPD offers significant advantages: lower temperature deposition, faster growth rate, and precise control over film thickness and morphology. The resulting NDC films boast exceptional durability due to their unique nanostructure, diamond nanocrystallites embedded in an amorphous carbon matrix. The addition of Al-interlayers (100–500 nm thickness) optimizes film properties. The optimal interlayer at 100 nm thickness not only mitigates the catalytic effects of Co but also enhances film hardness (50.4–58 GPa), Young's modulus (516–613.75 GPa), and adhesion (13–18.5 N) compared to films without an interlayer. Notably, the 100 nm Al-interlayer triples the deposition rate to 3.3 μm/h, achieving the desired thickness for effective hard coatings. The high density of grain boundaries within the films allows for exceptional stress release, enabling this increased thickness. Furthermore, these grain boundaries and the graphitic phase contribute to the film's superior tribological performance – a low coefficient of friction (0.1) and minimal wear rate (1.5 × 10⁻7 mm³/N⋅m) under dry machining conditions. These findings demonstrate the immense potential of CAPD-deposited NDC films as a sustainable alternative for advanced cutting tools, promoting environmental responsibility, economic viability, and energy efficiency.

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在硬质合金上沉积清洁耐用的厚纳米金刚石复合硬涂层,实现可持续加工:生态友好型制造、表征和 3-E 分析
这项研究探索了一种可持续的方法,用于制造用于干式加工的高性能纳米金刚石复合材料(NDC)硬涂层。旨在解决传统涂层的局限性,如环境问题、膜厚受限和性能受损。该研究利用同轴电弧等离子体沉积(CAPD)这一清洁高效的技术,直接在 WC-Co 基底上沉积厚(10 μm)的 NDC 薄膜,而无需进行化学蚀刻。与传统的化学气相沉积 (CVD) 相比,CAPD 具有显著的优势:沉积温度更低、生长速度更快、可精确控制薄膜厚度和形态。生成的 NDC 薄膜具有独特的纳米结构,即在无定形碳基体中嵌入金刚石纳米晶体,因而具有超强的耐久性。添加铝中间膜(厚度为 100-500 纳米)可优化薄膜性能。100 nm 厚度的最佳夹层不仅能减轻钴的催化作用,而且与没有夹层的薄膜相比,还能提高薄膜硬度(50.4-58 GPa)、杨氏模量(516-613.75 GPa)和附着力(13-18.5 N)。值得注意的是,100 nm 的铝中间膜将沉积速率提高了三倍,达到 3.3 μm/h,达到了有效硬涂层所需的厚度。薄膜内高密度的晶界可释放出特殊的应力,从而实现厚度的增加。此外,这些晶界和石墨相还有助于提高薄膜的摩擦学性能--在干式加工条件下,摩擦系数低(0.1),磨损率小(1.5 × 10-7 mm³/N-m)。这些发现证明了 CAPD 沉积 NDC 薄膜作为先进切削工具的可持续替代品的巨大潜力,可促进环境责任、经济可行性和能源效率。
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来源期刊
Cleaner Engineering and Technology
Cleaner Engineering and Technology Engineering-Engineering (miscellaneous)
CiteScore
9.80
自引率
0.00%
发文量
218
审稿时长
21 weeks
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