金刚石热损伤抑制技术研究现状

张建华; 李昂; 胡婷婷; 杜全斌; 崔冰; 张黎燕; 王蕾; 毛望军

doi:10.13394/j.cnki.jgszz.2023.0166

金刚石热损伤抑制技术研究现状

doi: 10.13394/j.cnki.jgszz.2023.0166

张建华¹,
李昂^{1, 2},
胡婷婷²,
杜全斌^2, ,,
崔冰³,
张黎燕²,
王蕾²,
毛望军²

1.
郑州华晶金刚石股份有限公司, 郑州 450001
2.
河南机电职业学院, 河南省超硬材料智能制造装备集成重点实验室, 河南新郑 451191
3.
安徽工业大学, 教育部先进金属材料绿色制造与表面技术重点实验室, 安徽马鞍山 243002

基金项目: 河南省科技攻关计划（222102230111; 222102220114; 202102210072; 232102220058）。

详细信息

通讯作者:
杜全斌，男，1983年生，博士、副教授。主要研究方向：先进焊接材料与装备、超硬工具制备技术与装备、金刚石热界面材料开发、激光增材表面修复再制造。E-mail：paperduqb@126.com

中图分类号: TH16; TQ164; TG42; TG74; TG14
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- 文章访问数: 548
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- 被引次数: 0
出版历程
- 收稿日期: 2023-08-21
- 修回日期: 2023-11-22
- 录用日期: 2023-12-06
- 网络出版日期: 2023-12-11
- 刊出日期: 2024-10-01

Research status of thermal damage inhibition technology for diamond

1.
Zhengzhou Sino-Crystal Diamond Co., Ltd., Zhengzhou 450001, China
2.
Henan Key Laboratory of Intelligent Manufacturing Equipment Integration for Superhard Materials, Henan Mechanical and Electrical Vocational College, Xinzheng 451191, Henan, China
3.
Key Laboratory of Green Fabrication and Surface Technology of Advanced Metal Materials, Ministry of Education, Anhui University of Technology, Ma'anshan 243002, Anhui, China

摘要

摘要: 金刚石工具制备过程中的金刚石热损伤主要包括金刚石的石墨化、金刚石的破损开裂和金刚石的化学侵蚀等。针对金刚石热损伤问题，分别从金刚石表面镀覆、胎体材料性能调控和成型技术优化3个方面，介绍了目前金刚石热损伤的抑制技术，并对未来研究方向进行了展望，以期为高性能金刚石工具制备提供参考和指导。
- 金刚石 /
- 金刚石工具制备 /
- 热损伤 /
- 抑制技术
Abstract: Significance: As the hardest material, diamond is widely used in various cutting and grinding tools. During the preparation process of diamond tools, thermal damage to diamonds is almost inevitable. The thermal damage to diamonds primarily includes graphitization, breakage, cracking, and chemical erosion. Graphitization of diamonds is a lattice transformation process of C atoms essentially, which requires sufficient energy to overcome the energy barrier. Consequently, during the preparation process of diamond tools, diamonds undergo varying degrees of graphitization due to high temperatures and catalyst elements. Breakage and cracking of diamonds primarily orginate from thermal mismatch between the diamond and the matrix metal, including its carbides, where carbides act as inducers of local residual stress, facilitating crack propagation. Chemical erosion of diamonds mainly refers to the process in which C atoms on the surface of diamonds react with active elements through diffusion during the sintering process, therefore deteriorating the diamonds. However, due to the poor wettability of diamonds, it often necessitates the addition of active elements such as Ti, Cr, V, etc., to react with diamonds and improve the holding force. Current suppression technologies for diamond thermal damage can be roughly divided into surface coating of diamonds, adjustment of matrix material properties, and optimization of forming technology. Progress: Diamond surface coating utilizes the unbonded atoms present on the diamond surface, which can react with certain elements at sufficiently high temperatures to form carbides, thereby enhancing the wettability between the matrix metal and the diamonds. Depending on the type of coating, it can generally be classified into metal and non-metal coatings. Metal coatings not only fill and repair defects in diamonds but also improve the bonding strength between the metal and diamonds. Common coating metals include Ni, Ti, W, Cr, and alloys are also selected as coating materials. For non-metal coatings, elements such as B and Si are typically chosen, as they can form carbide layers on the diamond surface, protect the diamond structure, reduce diamond oxidation, and prevent diamonds from being eroded and damaged by strong carbon elements in the matrix material. The choice of matrix material plays a crucial role in mitigating thermal damage to diamonds. Low-melting-point matrix materials can effectively reduce sintering temperature and inhibit the graphitization of diamonds consequently. Furthermore, incorporating appropriate active elements into the matrix material can enhance the interfacial strength between diamond and the matrix, thereby improving the performance of diamond tools. Currently, the modulation of matrix material properties is primarily focused on alloy optimization and composite material development. Alloy optimization aims to reduce diamond thermal damage by refining the alloy composition of the matrix material. Researchers have experimented with elements such as Si, Hf, and Zr, discovering that these elements can mitigate the erosion of diamonds by active elements and reduce diamond thermal damage. Additionally, amorphous Ni-based alloys, due to their low melting point and narrow melting range, have been used as brazing materials to enhance the performance of diamond tools. Composite material development seeks to improve mechanical properties while utilizing suitable reinforcing phases to absorb catalytic elements within the matrix, thereby reducing diamond graphitization. Additionally, reinforcing phases could optimize the diamond interface condition, leading to both increased interfacial strength and reduced diamond thermal damage. Molding technology significantly impacts the lifespan and performance of diamond tools, particularly through parameters such as molding temperature, soaking time, molding pressure, and atmosphere. Molding temperature and soaking time determine grain growth in the matrix, diamond thermal damage, and the interfacial growth between diamond and the matrix. Molding pressure affects the density of the matrix material, which in turn influences its mechanical properties. The atmosphere, typically vacuum or protective, must be carefully controlled, as even trace amounts of moisture or oxygen could lead to diamond oxidation, degrading tool performance and lifespan. Diamond tools are typically manufactured through methods such as hot-press sintering and brazing, while additive manufacturing is emerging as a promising direction in tool fabrication. Conclusions and Prospects: Future research to mitigate diamond thermal damage could focus on three main areas: theoretical analysis of diamond interfaces at the microscale, the establishment of a guidance system matching diamond tool matrix materials with service environments, and investigation of the mechanical behavior of diamonds interfaced during the molding process.
- diamond /
- diamond tool /
- thermal damage /
- inhibition technology

HTML全文

图 1 Ni沿金刚石晶界诱导的石墨化过程^[6]

Figure 1. Graphitization process induced by Ni along diamond grain boundaries^[6]

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图 2 非受控冷却下钎焊连接处的应力计算分析^[13]

Figure 2. Calculation analysis of stress developed with brazed joints during uncontrolled cooling^[13]

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图 3 界面处与金刚石的裂纹扩展^[13]

Figure 3. Crack expansion on interface and diamond^[13]

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图 4 金刚石表面的反应产物Cr₃C₂形貌^[14]

Figure 4. Morphology of reaction product Cr₃C₂ on diamond surface^[14]

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图 5 金刚石表面的生成物形貌^[32]

Figure 5. Morphology of reaction product on diamond surface^[32]

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图 6 Hf元素对金刚石热损伤机制的影响^[47]

Figure 6. Effect of the Hf element on thermal damage mechanism of diamond^[47]

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图 7 不同GNPs添加量时的复合钎料钎焊金刚石表面碳化物形貌^[55]

Figure 7. Morphologies of carbide on diamond surface brazed by composite filler metal with different GNPs contents^[55]

下载: 全尺寸图片幻灯片

图 8 不同GNPs添加量时的复合钎料钎焊金刚石表面石墨化程度^[56]

Figure 8. Graphitization degree of diamond surface brazed by composite brazing filler metal with different GNPs contents^[56]

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图 9 激光钎焊过程金刚石界面元素扩散反应示意图^[68]

Figure 9. Schematic diagram of element diffusion reaction on diamond interface during laser brazing process^[68]

下载: 全尺寸图片幻灯片

图 10 真空钎焊过程金刚石界面元素扩散反应示意图^[68]

Figure 10. Schematic diagram of element diffusion reaction on diamond interface during vacuum brazing process^[68]

下载: 全尺寸图片幻灯片

表 1 各类金刚石镀层方法的特点^[17]

Table 1. Characteristics of various diamond coating methods^[17]

技术特征	镀层成分	结合状态	镀覆温度t / ℃	金刚石热损伤
CVD	Ti、Mo、W、Cr 及对应碳化物	冶金结合	>850	有
PVD	Ti、Mo、W、 Cr、Ni、B	物理结合	< 400	无
电镀	Ni、Ni-W合金、 W-Co合金	机械包覆	< 100	无
熔盐法	Ti、Mo、W、Cr 及对应碳化物	冶金结合	850～1 100	有
预钎焊	Ni基合金、Cu基合金、Ag基合金	冶金结合	> 850	有
真空微蒸镀	Ti、Mo、W、Cr 及对应碳化物	冶金结合	650～750	无

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