退火态TC4钛合金型材高温拉伸行为研究

刘昆; 黄海广; 秦铁昌; 李志敏; 肖寒; 周荣锋

doi:10.15980/j.tzzz.2019.08.029

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退火态TC4钛合金型材高温拉伸行为研究
High Temperature Tensile Behavior of Annealed TC4 Titanium Alloy
2019年39卷第8期页码：925-928
纸质出版日期： 2019 ，
DOI： 10.15980/j.tzzz.2019.08.029

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[1]刘昆,黄海广,秦铁昌,李志敏,肖寒,周荣锋.退火态TC4钛合金型材高温拉伸行为研究[J].特种铸造及有色合金,2019,39(08):925-928.

Liu Kun, Huang Haiguang, Qin Tiechang, et al. High Temperature Tensile Behavior of Annealed TC4 Titanium Alloy[J]. Special Casting & Nonferrous Alloys, 2019,39(8):925-928.
[1]刘昆,黄海广,秦铁昌,李志敏,肖寒,周荣锋.退火态TC4钛合金型材高温拉伸行为研究[J].特种铸造及有色合金,2019,39(08):925-928. DOI： 10.15980/j.tzzz.2019.08.029.

Liu Kun, Huang Haiguang, Qin Tiechang, et al. High Temperature Tensile Behavior of Annealed TC4 Titanium Alloy[J]. Special Casting & Nonferrous Alloys, 2019,39(8):925-928. DOI： 10.15980/j.tzzz.2019.08.029.

摘要

采用单向拉伸试验研究了热轧退火态TC4钛合金型材的高温变形行为

分析了变形温度和应变速率对TC4钛合金力学性能的影响。结果表明

当拉伸速率不变时（0.236～1mm/min）

抗拉强度随温度的升高而降低;当变形温度分别在773、993和1 093K下保持恒定时

合金的抗拉强度受拉伸速率的影响较小

抗拉强度基本保持不变;当变形温度为1 093K时

合金的抗拉强度随拉伸速率的增加而增加;随着变形温度提高或者拉伸速率降低

断口中韧窝数量越来越多

且韧窝的形状逐渐趋于规则

试样的断裂方式由脆性断裂和韧性断裂的混合型断裂转变为韧窝聚合型延性断裂

最后转变为韧性断裂。

Abstract

The high temperature deformation behavior of hot rolled annealed TC4 titanium alloy profiles was investigated by uniaxial tensile test.The effects of deformation temperature and strain rate on the mechanical properties of TC4 titanium alloy and tensile fracture behavior were analyzed.The results show that the tensile strength is decreased with the increase of temperature at the same tensile rate in range of 0.236～1 mm/min.When the deformation temperature is fixed at 773、993 and 1 093 K

the tensile strength of the alloy is less affected by the tensile rate

and the tensile strength remains basically unchanged.With the deformation temperature of 1 093 K

the tensile strengths increased with the increase of the stretching rate.With the increase of deformation temperature or the decrease of tensile rate

the number of dimples in the fracture is increased

and the shape of the dimple gradually becomes regular.The fracture mode of the specimen is transformed by the mixed fracture of brittle fracture and ductile fracture.It is a ductile polymerized ductile fracture and finally becomes ductile fracture.