High-Temperature Indirect Compaction of Powder Materials with Active Action of an External Friction Force

被引:7
作者
Stolin, A. M. [1 ]
Stel'makh, L. S. [1 ]
Karpov, S., V [2 ]
机构
[1] Russian Acad Sci, Merzhanov Inst Struct Macrokinet & Mat Sci, 8 Academician Osipyan Str, Chernogolovka 142432, Russia
[2] Tambov State Tech Univ, 106 Sovetskaya Str, Tambov 392036, Russia
来源
JOURNAL OF ENGINEERING PHYSICS AND THERMOPHYSICS | 2020年 / 93卷 / 02期
关键词
indirect compaction; active external friction force; rheodynamics; self-propagating high-temperature synthesis; density distribution; compressive stress;
D O I
10.1007/s10891-020-02123-6
中图分类号
O414.1 [热力学];
学科分类号
摘要
On the basis of theoretical analysis of the rheodynamics of a powder material in the process of its indirect compaction with active action of an external friction force, the influence of this friction force on the density distribution of the material in the bulk of its sample was investigated. The advantages of the indicated compaction method over the one-side high-temperature compaction of powder materials, used most frequently in power metallurgy and in self-propagating high-temperature synthesis technologies, were substantiated.
引用
收藏
页码:317 / 323
页数:7
相关论文
共 50 条
[21]   Activation of self-sustaining high-temperature reactions by mechanical processing of Ti-C powder mixtures [J].
Delogu, Francesco .
SCRIPTA MATERIALIA, 2013, 69 (03) :223-226
[22]   SYNTHESIS OF NANOSTRUCTURE MoSi2 POWDER BY MECHANICALLY ASSISTED SELF-PROPAGATING HIGH-TEMPERATURE SYNTHESIS [J].
Meshkizadeh, R. ;
Abdollahpour, H. ;
Honarbakhsh-raouf, A. .
PROCEEDINGS OF THE ASME 10TH BIENNIAL CONFERENCE ON ENGINEERING SYSTEMS DESIGN AND ANALYSIS, 2010, VOL 5, 2010, :723-727
[23]   Self-Propagating High-Temperature Synthesis of Titanium Carbide Powder under Pressure-Shear Conditions [J].
Stolin, A. M. ;
Bazhin, P. M. ;
Alymov, M. I. ;
Mikheev, M. V. .
INORGANIC MATERIALS, 2018, 54 (06) :521-527
[24]   Structure and Phase Formation of a Ti-Al-Si Based Alloy Prepared by Self-Propagating High-Temperature Synthesis Compaction [J].
Lazarev, P. A. ;
Busurina, M. L. ;
Gryadunov, A. N. ;
Sytschev, A. E. ;
Boyarchenko, O. D. ;
Karpov, A., V .
INORGANIC MATERIALS, 2022, 58 (09) :1005-1010
[25]   Reaction of boron-containing materials with titanium during self-propagating high-temperature synthesis [J].
Zhunkovskii, G. L. ;
Evtushok, T. M. ;
Kotenko, V. A. ;
Mazur, P. V. ;
Gordienko, S. P. .
POWDER METALLURGY AND METAL CERAMICS, 2006, 45 (3-4) :163-167
[26]   Reaction of boron-containing materials with titanium during self-propagating high-temperature synthesis [J].
G. L. Zhunkovskii ;
T. M. Evtushok ;
V. A. Kotenko ;
P. V. Mazur ;
S. P. Gordienko .
Powder Metallurgy and Metal Ceramics, 2006, 45 :163-167
[27]   Ni-Al functionally graded materials by laser self-propagating high-temperature synthesis [J].
Chen, L ;
Hu, JD ;
Guo, ZX ;
Lou, QH ;
Wang, ZJ .
MATERIALS TRANSACTIONS, 2004, 45 (09) :2791-2793
[28]   Self-propagating high-temperature synthesis of Cd-In-Ga-O powder for GaN thin film substrate [J].
Lin, SC ;
Wilkins, R ;
Luss, D .
INTEGRATED THIN FILMS AND APPLICATIONS, 1998, 86 :73-85
[29]   Self-propagating high-temperature synthesis of TiB2-Ti(C, N) Cermets composite powder [J].
Yang, Fang ;
Guo, Zhimeng ;
Hao, Junjie ;
Shi, Yongliang .
AUTOMATION EQUIPMENT AND SYSTEMS, PTS 1-4, 2012, 468-471 :1247-1250
[30]   Production of B4C-TiB2 composite powder by self-propagating high-temperature synthesis [J].
Coban, Ozan ;
Bugdayci, Mehmet ;
Acma, M. Ercan .
JOURNAL OF THE AUSTRALIAN CERAMIC SOCIETY, 2022, 58 (03) :777-791
12345