High-velocity compaction of titanium powder and process characterization

Powder Technology

Volumn 208, Issue 3, 2011, Pages 596-599

  Yan, Zhiqiao ^a   Chen, Feng ^b   Cai, Yixiang ^a  

^a Guangzhou Research Institute of Non ferrous Metals   (China)

^b HONG KONG POLYTECHNIC UNIVERSITY   (Hong Kong)

Author keywords

Green density; High velocity compaction (HVC); Huang Pei yun equation; Impact energy per unit mass; Titanium powder

Indexed keywords

CYLINDERS (SHAPES);

GREEN DENSITIES; HIGH VELOCITY COMPACTION; HUANG PEI-YUN EQUATION; IMPACT ENERGY; TITANIUM POWDERS;

COMPACTION;

TITANIUM;

ARTICLE; BULK DENSITY; COMPRESSION; CONTROLLED STUDY; DENSITY GRADIENT; HARDNESS; METALLURGY; MOLECULAR WEIGHT; PARTICLE SIZE; POWDER; PRESSURE CHAMBER; PROCESS OPTIMIZATION; RELATIVE DENSITY; TENSILE STRENGTH;

EID: 79952736938     PISSN: 00325910     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.powtec.2010.12.026     Document Type: Article

References (17)

1. Skoglund P. High density PM parts by high velocity compaction. Powder Metall 2001, 44:199-201.
2. Skoglund P., Kejzelman M., Hauer I. HVC punches PM to new mass production limits. Met Powder Rep 2002, 57:26-30.
3. Grant C.E. Höganäs promotes potential of high velocity compaction. Met Powder Rep 2001, 56:6.
4. Sethi G., Hauck E., German R.M. High velocity compaction compared with conventional compaction. Mater Sci Technol 2006, 22:955-959.
5. Wang J.Z., Yin H.Q., Qu X.H., Johnson J.L. Impact of multiple impacts on high velocity pressed iron powder. Powder Technol 2009, 195:184-189.
6. Barendvanden B., Christer F., Tomas L. Industrial implementation of high velocity compaction for improved properties. Powder Metall 2006, 49:107-109.
7. Jonsén P., Häggblad H.Å., Troive L., Furuberg J., Allroth S., Skoulund P. Green body behaviour of high velocity pressed metal powder. Mater Sci Forum 2007, 534-536:289-292.
8. Ericsson T., Luukkonen P. Residual stresses in green bodies of steel powder after conventional and high speed compaction. Mater Sci Forum 2002, 404-407:77-82.
9. Troive L., Furuberg J., Skoglund P., Allroth S. High-density PM components by high velocity compaction a comparison with conventional compaction. Euro PM 2005 October 2005, Prague, Czech Republic.
10. Souriou D., Goeuriot P., Bonnefoy O., Thomas G., Doré F. Influence of the formulation of an alumina powder on compaction. Powder Metall 2009, 1-2:152-159.
11. Dore F., Lazzarotto L., Bourdin S. High velocity compaction: overview of materials, applications and potential. Mater Sci Forum 2007, 534-536:293-296.
12. Jauffrès D., Lame O., Vigier G., Doré F. Microstructural origin of physical and mechanical properties of ultra high molecular weight polyethylene processed by high velocity compaction. Polymer 2007, 48:6374-6383.
13. Azhdar B., Stenberg B., Kari L. Determination of dynamic and sliding friction, and observation of stick-slip phenomenon on compacted polymer powders during high-velocity compaction. Polym Test 2006, 25:114-123.
14. Eriksson M., Andersson M., Adolfsson E., Carlström E. Titanium-hydroxyapatite composite biomaterial for dental implants. Powder Metall 2006, 49:70-77.
15. Wang J.Z., Qu X.H., Yin H.Q., Yi M.J., Yuan X.J. High velocity compaction of ferrous powder. Powder Technol 2009, 192:131-136.
16. Abkowitz S., Abkowitz S.M., Fisher H., Schwartzl P.J. CermeTi® discontinuously reinforced Ti-matrix composites: manufacturing, properties, and applications. JOM 2004, 56:37-41.
17. Doremus P., Guennec Y.L., Imbault D., Puente G. High-velocity compaction and conventional compaction of metallic powders; comparison of process parameters and green compact properties. Proc. ImechE, Part E: J. Process Mechanical Engineering 2010, 224:177-185.