Iijima Masahiro, Brantley William A, Kawashima Isao, Baba Naoki, Alapati Satish B, Yuasa Toshihiro, Ohno Hiroki, Mizoguchi Itaru
Department of Orthodontics, School of Dentistry, Health Sciences University of Hokkaido, Ishikari-Tobetsu, Hokkaido, Japan.
J Biomed Mater Res B Appl Biomater. 2006 Oct;79(1):137-41. doi: 10.1002/jbm.b.30523.
The microstructures and interdiffusion in brazed beta-titanium orthodontic wires were investigated by scanning electron microscopy and electron probe microanalysis, respectively. Beta-titanium wire (Ti-11Mo-6Zr-4Sn) with cross-section dimensions of 0.032 in. x 0.032 in., titanium-based braze alloy (Ti-30Ni-20Cu), and silver-based braze alloy (Ag-22Cu-17Zn-5Sn) were selected for the study. Brazing was performed using infrared radiation (RS-1) under an argon atmosphere. Specimens were etched with two solutions (2.5% HF + 2.5% HNO(3) + 95% H(2)O; 25% HN(4)OH + 30% H(2)O(2) + 45%H(2)O). It was found that the silver-based braze alloy has a eutectic structure. In the diffusion layer between the beta-titanium wire and this silver-based braze alloy, Cu and Ti were enriched on the wire side, and Sn and Ti were enriched on the braze alloy side. The titanium-based braze alloy has a dendritic structure. Beta-titanium wire specimens brazed with the titanium-based braze alloy had a thicker intermediate area compared to the silver alloy; Ti in the diffusion layer had an irregular concentration gradient, and the braze alloy side had higher Ti concentration. The original microstructure of the beta-titanium wire was not altered with the use of either braze alloy. Infrared brazing of beta-titanium orthodontic wire is acceptable for clinical use, since the wire microstructure did not deteriorate with either the titanium-based or silver-based braze alloy. The differing microstructures of the joint regions for the two braze alloys suggest that the joint strengths may also differ.
分别通过扫描电子显微镜和电子探针微分析研究了钎焊β钛正畸丝中的微观结构和相互扩散。选择横截面尺寸为0.032英寸×0.032英寸的β钛丝(Ti-11Mo-6Zr-4Sn)、钛基钎焊合金(Ti-30Ni-20Cu)和银基钎焊合金(Ag-22Cu-17Zn-5Sn)进行研究。钎焊在氩气气氛下使用红外辐射(RS-1)进行。用两种溶液(2.5%HF + 2.5%HNO₃ + 95%H₂O;25%NH₄OH + 30%H₂O₂ + 45%H₂O)对试样进行蚀刻。发现银基钎焊合金具有共晶结构。在β钛丝与这种银基钎焊合金之间的扩散层中,Cu和Ti在丝侧富集,而Sn和Ti在钎焊合金侧富集。钛基钎焊合金具有树枝状结构。与银合金相比,用钛基钎焊合金钎焊的β钛丝试样的中间区域更厚;扩散层中的Ti具有不规则的浓度梯度,钎焊合金侧的Ti浓度更高。使用任何一种钎焊合金都不会改变β钛丝的原始微观结构。β钛正畸丝的红外钎焊在临床上是可以接受的,因为无论是钛基还是银基钎焊合金,丝的微观结构都没有恶化。两种钎焊合金接头区域不同的微观结构表明接头强度也可能不同。