Partially degradable friction-welded pure iron-stainless steel 316L bone pin
This article describes the development of a partially degradable metal bone pin, proposed to minimize the occurrence of bone refracture by avoiding the creation of holes in the bone after pin removal procedure. The pin was made by friction welding and composed of two parts: the degradable part that...
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2015
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my.utm.587582021-11-10T06:16:02Z http://eprints.utm.my/id/eprint/58758/ Partially degradable friction-welded pure iron-stainless steel 316L bone pin Nasution, A. K. Murni, N. S. Sing, N. B. Idris, M. H. Hermawan, H. Q Science (General) This article describes the development of a partially degradable metal bone pin, proposed to minimize the occurrence of bone refracture by avoiding the creation of holes in the bone after pin removal procedure. The pin was made by friction welding and composed of two parts: the degradable part that remains in the bone and the nondegradable part that will be removed as usual. Rods of stainless steel 316L (nondegradable) and pure iron (degradable) were friction welded at the optimum parameters: forging pressure 533.2 kPa, friction time525 s, burn-off length515 mm, and heat input54.58 J/s. The optimum tensile strength and elongation was registered at 666 MPa and 13%, respectively. A spiral defect formation was identified as the cause for the ductile fracture of the weld joint. A 40-μm wide intermetallic zone was identified along the fusion line having a distinct composition of Cr, Ni, and Mo. The corrosion rate of the pin gradually decreased from the undeformed zone of pure iron to the undeformed zone of stainless steel 316L. All metallurgical zones of the pin showed no toxic effect toward normal human osteoblast cells, confirming the ppb level of released Cr and Ni detected in the cell media were tolerable. John Wiley and Sons Inc. 2015 Article PeerReviewed Nasution, A. K. and Murni, N. S. and Sing, N. B. and Idris, M. H. and Hermawan, H. (2015) Partially degradable friction-welded pure iron-stainless steel 316L bone pin. Journal of Biomedical Materials Research Part B-Applied Biomaterials, 103 (1). pp. 31-38. ISSN 1552-4973 http://dx.doi.org/10.1002/jbm.b.33174 DOI: 10.1002/jbm.b.33174 |
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Q Science (General) Nasution, A. K. Murni, N. S. Sing, N. B. Idris, M. H. Hermawan, H. Partially degradable friction-welded pure iron-stainless steel 316L bone pin |
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This article describes the development of a partially degradable metal bone pin, proposed to minimize the occurrence of bone refracture by avoiding the creation of holes in the bone after pin removal procedure. The pin was made by friction welding and composed of two parts: the degradable part that remains in the bone and the nondegradable part that will be removed as usual. Rods of stainless steel 316L (nondegradable) and pure iron (degradable) were friction welded at the optimum parameters: forging pressure 533.2 kPa, friction time525 s, burn-off length515 mm, and heat input54.58 J/s. The optimum tensile strength and elongation was registered at 666 MPa and 13%, respectively. A spiral defect formation was identified as the cause for the ductile fracture of the weld joint. A 40-μm wide intermetallic zone was identified along the fusion line having a distinct composition of Cr, Ni, and Mo. The corrosion rate of the pin gradually decreased from the undeformed zone of pure iron to the undeformed zone of stainless steel 316L. All metallurgical zones of the pin showed no toxic effect toward normal human osteoblast cells, confirming the ppb level of released Cr and Ni detected in the cell media were tolerable. |
| format |
Article |
| author |
Nasution, A. K. Murni, N. S. Sing, N. B. Idris, M. H. Hermawan, H. |
| author_facet |
Nasution, A. K. Murni, N. S. Sing, N. B. Idris, M. H. Hermawan, H. |
| author_sort |
Nasution, A. K. |
| title |
Partially degradable friction-welded pure iron-stainless steel 316L bone pin |
| title_short |
Partially degradable friction-welded pure iron-stainless steel 316L bone pin |
| title_full |
Partially degradable friction-welded pure iron-stainless steel 316L bone pin |
| title_fullStr |
Partially degradable friction-welded pure iron-stainless steel 316L bone pin |
| title_full_unstemmed |
Partially degradable friction-welded pure iron-stainless steel 316L bone pin |
| title_sort |
partially degradable friction-welded pure iron-stainless steel 316l bone pin |
| publisher |
John Wiley and Sons Inc. |
| publishDate |
2015 |
| url |
http://eprints.utm.my/id/eprint/58758/ http://dx.doi.org/10.1002/jbm.b.33174 |
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1717093383800881152 |
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13.209306 |