基于微观孔隙演变的Ti-6Al-4V粉末高速压制致密化机理研究

doi:10.3901/JME.2024.16.180

机械工程学报 ›› 2024, Vol. 60 ›› Issue (16): 180-189.doi: 10.3901/JME.2024.16.180

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基于微观孔隙演变的Ti-6Al-4V粉末高速压制致密化机理研究

周剑, 徐宏坤, 刘焜

合肥工业大学机械工程学院合肥 230009

收稿日期:2023-11-07 修回日期:2024-02-11 出版日期:2024-08-20 发布日期:2024-10-21
作者简介:周剑(通信作者),男,1989年出生,博士,副教授,硕士研究生导师。主要研究方向为粉末致密化、精密玻璃模压技术。E-mail:jianzhou@hfut.edu.cn
徐宏坤,男,1997年出生,硕士。主要研究方向为粉末压制的多颗粒有限元法。E-mail:2020170245@mail.hfut.edu.cn
刘焜,男,1963年出生,博士,教授,博士研究生导师。主要研究方向为制造摩擦学、颗粒流润滑。E-mail:liukun@hfut.edu.cn
基金资助:
国家自然科学基金(52375179，51905141)和中央高校条件建设经费(JZ2021HGTB0086)资助项目。

Study on the Densification Mechanism of Ti-6Al-4V Powder during High Velocity Compaction Based on the Evolution of Microscale Pores

ZHOU Jian, XU Hongkun, LIU Kun

School of Mechanical Engineering, Hefei University of Technology, Hefei 230009

Received:2023-11-07 Revised:2024-02-11 Online:2024-08-20 Published:2024-10-21

摘要/Abstract

摘要： 采用二维多颗粒有限元法模拟Ti-6Al-4V粉末高速压制成形过程，定量表征颗粒间孔隙的形态特征，详细分析压制过程中多种典型孔隙的形态和面积填充变化规律，从微观孔隙演变的角度研究粉末致密化机理。模拟结果发现，当宏观压制压力低于临界压力(约为1 500 MPa)，颗粒主要通过重排和塑性变形来填充孔隙，密度-压力曲线斜率较大，致密化较容易；超过临界压力后，曲线斜率逐渐减小，致密化越来越困难。微观上，在颗粒重排和塑性变形阶段，颗粒体系中存在大量面积比较大且压制角度较小的四边形孔隙，以及拱形结构容易被破坏的五边形孔隙。这些孔隙在压制过程中会转化为其他多边形孔隙，填充速率较快且具有较高的填充率，在粉末致密化的前中期起主要作用。高于临界压力值之后，大多数四边形和五边形孔隙均转化为三边形孔隙，此外还存在少量具有特殊堆积结构的多边形孔隙，这些难以填充的孔隙导致后期粉末致密化较为困难。研究结果建立不同类型孔隙的形态演变与粉末致密化难易程度之间的定性关联，为构建压制本构方程和优化成形质量提供理论指导。

关键词: Ti-6Al-4V, 高速压制, 粉末致密化, 多颗粒有限元法, 孔隙形态

Abstract: The high velocity compaction process of Ti-6Al-4V powder is simulated by using two-dimensional multi-particle finite element method. The morphological features of pores among particles are quantitatively characterized. The change laws regarding the morphology and area filling of various typical pores during the compaction process are analyzed in detail. The powder densification mechanism is studied from the aspect of the evolution of microscale pores. The simulation results show that when the compaction pressure is lower than a critical value (about 1 500 MPa), pores are mainly filled by particle rearrangement and plastic deformation, so that the slope of the density-pressure curve is steep, and the green powder assembly is easily densified. Above that critical pressure, the slope of the density-pressure curve gradually decreases, and powder densification becomes difficult. Microscopically, at the stage of particle rearrangement and plastic deformation, there are many quadrilateral pores with large area-ratios and small compression angles, as well as pentagon pores with arched structures that are easily damaged. Since these pores can be transformed into other polygonal pores during compaction, they have high filling ratios, and play a major role in the early and middle densification stages. When the compaction pressure is higher than the critical value, most of the quadrilateral and pentagonal pores has been transformed into triangular shapes. Additionally, there are a small number of polygonal pores with special packing structure. These pores that are hard to be filled lead to the difficult densification in the later stage. The research results establish a qualitative relationship between the morphological evolution of different types of pores and the difficulty of powder densification, which would provide theoretical guidance for both the construction of the compaction constitutive equation and the optimization of the forming quality.

Key words: Ti-6Al-4V, high velocity compaction, powder densification, multi-particle finite element method, pore morphology

中图分类号:

TF121

周剑, 徐宏坤, 刘焜. 基于微观孔隙演变的Ti-6Al-4V粉末高速压制致密化机理研究[J]. 机械工程学报, 2024, 60(16): 180-189.

ZHOU Jian, XU Hongkun, LIU Kun. Study on the Densification Mechanism of Ti-6Al-4V Powder during High Velocity Compaction Based on the Evolution of Microscale Pores[J]. Journal of Mechanical Engineering, 2024, 60(16): 180-189.

参考文献

[1] LEYENS C,PETERS M. Titanium and titanium alloys:Fundamentals and applications[M]. Weinheim:Wiley-VCH Verlag GmbH & Co.,2003.
[2] FANG Z,PARAMORE J,SUN P, et al. Powder metallurgy of titanium-past, present, and future[J]. International Materials Reviews,2018,63(7):407-459.
[3] CUI C,HU B,ZHAO L,et al. Titanium alloy production technology,market prospects and industry development[J]. Materials and Design,2011,32(3):1684-1691.
[4] 曲选辉. 粉末冶金原理与工艺[M]. 北京:冶金工业出版社,2016. QU Xuanhui. Principle and process of powder metallurgy[M]. Beijing:Metallurgical Industry Press,2016.
[5] ERIKSSON M,ANDERSSON M,ADOLFSSON E,et al. Titanium-hydroxyapatite composite biomaterial for dental implants[J]. Powder Metallurgy,2006,49(1):70-77.
[6] 马春宇,肖志瑜,李超杰,等. 粉末冶金高速压制成形技术最新研究进展[J]. 粉末冶金工业,2012,22(2):55-60. MA Chunyu,XIAO Zhiyu,LI Chaojie,et al. The latest research progress of powder metallurgy high speed press forming technology[J]. Powder Metallurgy Industry,2012,22(2):55-60.
[7] SETHI G,HAUCK E,GERMAN R. High velocity compaction compared with conventional compaction[J]. Materials Science and Technology,2006,22(8):955-959.
[8] YAN Z,CHEN F,CAI Y,et al. Preparation and properties of Ti-4.5Al-6.8Mo-1.5Fe alloy by high-velocity compaction[J]. Powder Technology,2013,246:345-350.
[9] XIA L,YE S,YUAN X,et al. Fabrication of biomedical Ti-24Nb-4Zr-8Sn alloy with high strength and low elastic modulus by powder metallurgy[J]. Journal of Alloys and Compounds,2018,772:968-977.
[10] ZHOU J,ZHU C,ZHANG W,et al. Experimental and 3D MPFEM simulation study on the green density of Ti-6Al-4V powder compact during uniaxial high velocity compaction[J]. Journal of Alloys and Compounds,2020,817:153226.
[11] YAN Z,CHEN F,CAI Y,et al. Influence of particle size on property of Ti-6Al-4V alloy prepared by high-velocity compaction[J]. Transactions of Nonferrous Metals Society of China,2013,23(2):361-365.
[12] 李静. 计算机仿真在粉末冶金过程的应用及研究进展[J]. 粉末冶金技术,2021,39(4):366-372. LI Jing. Application and research progress of computer simulation used in powder metallurgy process[J]. Powder Metallurgy Technology,2021,39(4):366-372.
[13] RANSING R,GETHIN D,KHOEI A,et al. Powder compaction modelling via the discrete and finite element method[J]. Materials and Design,2000,21(4):263-269.
[14] HAN P,AN X,WANG D,et al. MPFEM simulation of compaction densification behavior of Fe-Al composite powders with different size ratios[J]. Journal of Alloys and Compounds,2018,741:473-481.
[15] LEI X,WANG Y,LI C,et al. MPFEM simulation on hot-pressing densification process of SiC particle/6061Al composite powders[J]. Journal of Physics and Chemistry of Solids,2021,159:110259.
[16] ZHANG Y,AN X,ZHANG Y. Multi-particle FEM modeling on microscopic behavior of 2D particle compaction[J]. Applied Physics A-Materials Science & Processing,2015,118(3):1015-1021.
[17] WANG D,AN X,HAN P,et al. Multi-particle FEM modelling on hot pressing of TiC-316L composite powders[J]. Powder Technology,2020,361:389-399.
[18] GUNER F,CORA O,SOFUOGLU H. Numerical modeling of cold powder compaction using multi particle and continuum media approaches[J]. Powder Technology,2015,271:238-247.
[19] PROCOPIO A,ZAVALIANGOS A. Simulation of multi-axial compaction of granular media from loose to high relative densities[J]. Journal of the Mechanics and Physics of Solids,2005,53(7):1523-1551.
[20] HUANG F,AN X,ZHANG Y,et al. Multi-particle FEM simulation of 2D compaction on binary Al/SiC composite powders[J]. Powder Technology,2017,314:39-48.
[21] JIA Q,AN X,ZHAO H,et al. Compaction and solid-state sintering of tungsten powders:MPFEM simulation and experimental verification[J]. Journal of Alloys and Compounds,2018,750:341-349.
[22] JOHNSON G. A constitutive model and date for metals subject to large strains,high strain rate and high temperatures[C]//Proc. of 7th Int. Symp. on Ballistics,The Hague,1983:541-547.
[23] PENG K,ZHENG Z,PAN H,et al. Quasi-static and dynamic compaction of granular materials:A strain-activated statistical compaction model and its evaluation[J]. Mechanics of Materials,2022,167:104250.
[24] HECKEL R. Density-pressure relationship in powder compaction[J]. Transaction of the Metallurgical Society of AIME,1961,221(4):671-675.

基于微观孔隙演变的Ti-6Al-4V粉末高速压制致密化机理研究

Study on the Densification Mechanism of Ti-6Al-4V Powder during High Velocity Compaction Based on the Evolution of Microscale Pores

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