Instantaneous Creep in Face-centered Cubic Metals at Ultra- low Strain Rates by a High-resolution Strain Measurement

Instantaneous creep in face-centered cubic metals, 5N Al（99.999%）, 2N Al （99%） and 4N Cu （99.99%） with different grain sizes, was firstly investigated by sudden stress-change experiments at ultra- low strain rates ε ≤10-10 s-1 and temperature T 〈 0.32 Tn. The experimental results indicate that the observed instantaneous creep is strongly dependent on grain size, the concentration of impurity, and stacking fault energy. Creep in high-purity aluminum, 5N Al, with a very large grain size, d 〉 1600μm, shows non-viscous behavior, and is controlled by the recovery of dislocations in the boundary of dislocation cells. On the other hand, for 5N A1 with a small grain size, d=30μm, and low-purity aluminum, 2N A1, with d8= 25μm, creep shows viscous behavior and may be related to ＇low temperature grain boundary sliding＇. For high-purity copper, 4N Cu, with d= 40 grn and lower stacking fault energy, creep shows a non-viscous behavior, and is controlled by the recovery process of dislocations. For all of the samples, creep shows anelastic behavior.

Creep rate sensitivities of materials by a depth-sensing indentation technique

The strain rate sensitivity to creep of single crystal Cu（110）, metal tantalum, and 128°Y-X LiNbO3 piezoelectric single crystal were measured at room temperature by MTS Nanoindenter XP. Among the three kinds of materials studied, Cu showed the highest degree of resistance to creep-induced deformation, which is followed by Ta, while the LiNbO3 single crystal deformed more readily than the others. The values of the steady-state strain rate sensitivities determined by the indentation methods are in the range of 0.002-0.006, 0.02-0.06 and 0.02-0.03 for Cu, Ta, and LiNbO3, respectively. The mechanisms for the indentation-induced creeping behavior and the factors that influenced the creeping are discussed.

Creep resistance of as-cast Mg-5Al-5Ca-2Sn alloy

In the present study, creep properties of as-cast Mg-5Al-5Ca-2Sn(AXT552) alloy were investigated by means of a GWT304 creep testing machine at temperatures of 175 °C and 200 °C in the stress range of 35-90 MPa. Results show that creep rates increase with applied stress at an identical temperature. Creep strain at 100 hours is 0.0518% and 0.083% at creep conditions of 175°C/75 MPa and 200°C/60 MPa, respectively, which is comparable to MRI230 D and much lower than most of AX series alloys. By the observation and analysis for samples before and after creep tests using a Shimadzu XRD-7000 type X-ray diffractometer(XRD) and a Hitachi S-3400 N type scanning electron microscope(SEM), it was found that Al_2Ca(C15) phase precipitated out of C36 phase or matrix. The cavity formation and connection at the interface of soft matrix and hard intermetallics caused the propagation of cracking along the eutectic phase during creep process and dislocation accommodated grain/phase boundary sliding is expected to be the dominant creep mechanism.

Superplasticity-like creep behavior of coarse grained ternary Al alloys

Enhanced tensile ductilities in coarse grained Al-Mg-Zn and Al-Mg-Fe materials were studied.The materials were Al-2Mg-5Zn,Al-3Mg-5Zn,Al-4Mg-5Zn,Al-3Mg-0.11Fe,Al-3Mg-0.27Fe,and Al-3Mg-0.40Fe.Tensile elongation-to-failure tests were conducted at constant cross-head speed and constant temperatures from 300 to 450℃.Strain rate change tests were conducted at a constant temperature from 300 to 450℃and in strain-rate range from 4.31×10-5to 1.97×10-2s-1.Experimental results show that over 100%ductilities are consistently achieved in these materials.This superplasticity-like behavior is rate-controlled by solute-drag creep.Although ternary Zn and Fe additions do not have an adverse effect on solute-drag creep and ductility,they increase stress exponent and its sensitivity to Mg content during solute-drag creep.

Design and Performance Evaluation of a Sustained Load Dual Grip Creep Testing Machine

The design and performance evaluation of a sustained load creep testing machine was undertaken in this research. The design was motivated by the need to make locally available, a cost effective, technically efficient, and easily operated creep testing facility;for creep behaviour studies of materials. Design drawings and purchase of materials and components for the design were undertaken after thorough evaluation of the following design and materials selection criteria: design principle and theory, local availability of raw materials and components required for the design, material properties, cost of materials and design, ease of utilization and maintenance, and basis of testing and data capture. The machine casing and frame, heating chamber (consisting of the furnace and a dual specimen mounting stage), load lever and hanger system, and the electro-technical components;were fabricated and coupled following the produced design specifications. The machine was tested and its performance was assessed using its heating efficiency, repeatability and reproducibity of experimental test results, maintainability and cost-effectiveness as criteria. It was observed from repeat tests that the machine has the capacity of generating reliable data for computing creep strain-time results. The efficiency and temperature regulating capacity of the heating unit of the machine were also observed to be very satisfactory. The cost of the design was about 112,000 Naira ($700.00) which is cheaper in comparison to similar commercial creep testing machines from abroad. The machine was also found not to pose maintenance or repairs challenges.

DZ411定向凝固镍基合金蠕变性能的快速评估方法

研究了预应变(0.5%,1.0%,1.5%,2.0%,2.5%)、加载应变速率(4.0×10^(-5),1.2×10^(-4),4.0×10^(-4)s^(-1))和连续温度应力松弛试验的初始温度(750,900℃)对DZ411定向凝固镍基合金应力松弛行为的影响;基于加工硬化和回复软化动态平衡的稳态变形,假设稳态松弛应变速率与传统蠕变持久试验的最小蠕变速率随应力的变化规律一致,通过短时应力松弛试验对最小蠕变速率进行预测,并进行验证。结果表明:试验合金在加工硬化和回复软化动态平衡时开始松弛,当预应变不低于1.0%时能快速达到稳态松弛;初始温度对稳态松弛行为的影响较小;加载应变速率会影响起始松弛应变速率,但对稳态松弛应变速率随应力变化的影响较小;通过稳态松弛应变速率主曲线可以预测不同温度、应力下的最小蠕变速率,蠕变持久试验结果均落在稳态松弛应变速率主曲线的99%可靠度曲线内。

超慢应变速率腐蚀蠕变试验机的研制

超慢应变速率腐蚀蠕变试验机主要用于检测金属材料在超慢的拉伸速度和腐蚀介质环境双重作用下的腐蚀蠕变性能。为满足超慢应变速率腐蚀蠕变性能测试需求,研制了多级传动系统、腐蚀蠕变装置、腐蚀溶液补液装置。超慢应变速率腐蚀蠕变试验机的研制成功,不仅满足了超慢应变速率试验的需求,同时能够进行材料腐蚀蠕变性能测试,为相关试验提供了稳定可靠的试验装置,具有一定的工程实用价值。

加载速率变化条件下砂土的黏塑特性及本构模型

分析并研究饱和的、风干的砂土在平面应变压缩试验条件下的弹黏塑性特征,尤其是黏性特性。加载速率效应、蠕变以及应力松弛都是砂土材料本身黏性的反映,而与超孔隙水压力的消散无关。试验不仅实现了应变率逐步变化加载过程,同时也实现了蠕变加载和应力松弛过程。试验结果表明,在加载应变率发生突变时,对砂土应力–应变关系有明显的影响,呈现出刚性很高、近似于弹性的特性,而后随着应变的进一步增加,在明显屈服之后黏性应力逐渐衰减至基本惟一的应力–应变曲线。类似现象同样也发生在蠕变加载或应力松弛后以一恒定应变率突然重新加载的情况。基于非线性三要素模型框架,针对所观察到的砂土黏性特性,提出一种弹黏塑性本构模型。该模型可以描述砂土在任意加载历史下的黏性效应,包括加载应变率发生任意变化时的应力–应变响应、蠕变以及应力松弛。最后,利用该模型对上述砂土平面应变压缩试验结果进行模拟,所提案的三要素弹黏塑性本构模型能够很好地模拟砂土的黏性特性。

软岩的强度-变形-时间之间关系的试验分析

对软岩和有不连续面的软岩试样进行一系列的固结不排水三轴压缩和蠕变试验，测定并分析了它们在正常团结和超固结状态下的应变软化性状、蠕变特性和残余强度的变化规律。探讨了软岩中存在的不连续面对应力一应变关系、残余强度特性和蠕变应变速率的影响。

Sn-Cu-Ni焊点纳米压痕试验分析

为研究金属间化合物与无铅焊点力学性能之间的关系,采用纳米压痕法测定了Sn-Cu-Ni焊点中金属间化合物及钎料基体的弹性模量和压痕硬度等力学性能参量.结果表明,Sn-Cu-Ni焊点中(Cu,Ni)6Sn5金属间化合物的弹性模量为113.2 GPa±4.8GPa,压痕硬度为5.59 GPa±0.32 GPa,均与钎料基体有较大差异.并基于Mayo-Nix方法计算得到Sn-Cu-Ni,Sn-Cu-Ni-0.05Ce和Sn-Pb钎料基体的蠕变应变速率敏感指数m分别为0.128 6,0.124 8和0.183 2,蠕变应力指数n分别为7.776 0,8.012 8和5.458 5,表明Sn-Cu-Ni系列抗蠕变性能优于Sn-Pb钎料,且微量Ce元素的添加有利于提高Sn-Cu-Ni焊点的抗蠕变性能.

纳米压痕法测量Sn-Ag-Cu无铅钎料BGA焊点的力学性能参数

对Sn-3.0Ag-0.5Cu无铅体钎料和Sn-4.0Ag-0.5Cu无铅钎料BGA(ball grid array)焊点进行了Berkovich 纳米压痕法实验,通过改变不同的加载速率研究了钎料的蠕变特征.钎料压痕载荷-位移曲线蠕变部分表现出了明显的加载速率相关性.基于Oliver-Pharrr法确定的体钎料和BGA焊点的Young’s模量分别为9.3和20 GPa.基于压痕做功概念确定的体钎料和BGA焊点的应变速率敏感指数分别为0.1111和0.0574.钎料的力学性能有着明显的尺寸效应.

2524铝合金的蠕变时效行为及本构方程

通过在电子蠕变试验机上进行蠕变时效试验,研究了2524铝合金在时效温度为453～473K、试验应力为140～210MPa条件下的蠕变时效行为;采用包含双曲正弦函数的方程,通过对试验数据的线性回归分析,建立了2524铝合金稳态蠕变速率与试验应力及时效温度之间的关联本构模型。结果表明:随着试验应力增大和时效温度升高,2524铝合金的稳态蠕变速率增大,且蠕变曲线在第二阶段持续的时间缩短;依据本构方程计算出该铝合金在各条件下的稳态蠕变速率的数值和试验值的平均相对误差为6.9%,该本构方程可为2524铝合金蠕变时效成形工艺的制定提供依据。

盐岩蠕变特性温度效应的实验研究

对经历不同温度后的盐岩蠕变特性进行了实验研究,研究了应力水平和温度对盐岩蠕变特性的影响,通过实验获得的蠕变曲线和岩石参数,回归出了其稳态蠕变率本构方程。分析结果表明:偏应力和温度对盐岩稳态蠕变率影响较大;稳定蠕变应变率本构方程是作用在盐岩上的应力偏量的幂次函数和能量与温度的指数函数。并从盐岩蠕变模量随蠕变时间的变化规律入手,导出了以蠕变时间为自变量的损伤率演化方程和用损伤表示的蠕变模量演化方程。

不同含水率粘土在不同试验条件下的应力-应变特性

采用单轴固结试验和三轴剪切试验对饱和、湿润、风干以及烘干的藤森粘土进行了应力-应变特性研究。在试验过程中,进行了不同轴向应力水平下的恒应变率加载试验、蠕变试验以及卸载与重复加载试验。局部变形测量传感器(LDT)被用于三轴剪切试验中的轴向变形测量以提高小应变测量的精度。试验结果表明,不同含水率与饱和度的藤森粘土在单轴固结试验与三轴剪切试验条件下都表现出明显的粘塑性。它们的加载速率效应、蠕变效应都相似;而且在蠕变结束后的一小段邻域内藤森粘土的强度有明显的提高。笔者提出用参数β来描述藤森粘土的粘性。对试验结果的计算分析表明,在单轴和三轴试验条件下不同含水率与饱和度的藤森粘土的β值介于0.034到0.064之间;而且,含水率高的藤森粘土的β值大于含水率低的藤森粘土的β值,单轴试验条件下的β值大于三轴试验条件下的β值。

基于变参数的含水岩石弱化流变模型研究

基于不同含水率的岩石蠕变试验,分别考虑岩石时效劣化效应和含水弱化效应,分析不同应力状态下和不同含水率状态下的蠕变曲线。根据试验蠕变曲线得到岩石弹性模量随时间和含水率的变化关系,拟合得到岩石的时间衰减指数和含水衰减指数。在假设岩石时效损伤和含水损伤为各向同性损伤的基础上建立了岩石时效蠕变损伤模型,并对不同含水率下的岩石蠕变损伤开展了数值模拟研究。数值模拟结果同岩石蠕变试验曲线很好地相吻合,模拟结果表明了该蠕变损伤模型的合理性。本文所开展的岩石时效劣化和含水弱化蠕变损伤模型的研究工作,将为岩石流变特性的研究提供一定的理论依据。

岩石时间硬化损伤蠕变特性

分析岩石蠕变过程中的非线性损伤特征,在各向同性的蠕变方程中引入时间硬化,采用应变等效原理,推导出时间硬化条件下的岩石蠕变方程,利用该方程可以同时描述岩石蠕变曲线的初始蠕变、等速蠕变和加速蠕变三个阶段,并进行了参变曲线数值求解和参数特性分析,利用该方程拟合了某页岩三轴蠕变实验数据,同时揭示了蠕变现象的非线性本质.结果表明:利用该方程可以较好地模拟岩石蠕变曲线的3个阶段.

自然与饱水状态下深部斜长角闪岩蠕变特性

通过金川深部斜长角闪岩单轴压缩蠕变实验,选取典型蠕变曲线,发现该岩石黏弹性、黏塑性变形较瞬时变形偏小,卸载后弹性后效不显著。在5.1 MPa轴向应力下,自然状态的岩样近似纯弹性特征。饱水状态下岩样瞬时强度σ′b和长期强度σ′∞总体低于自然状态,且σ′∞已接近深部高地应力,因此,对于深部节理、裂隙很发育的岩体,应特别注意巷道排水,防止围岩因长期强度降低而导致巷道变形和破坏。自然与饱水状态下岩样瞬时弹性应变εme、瞬时塑性应变εmp随应力增大而增加,但增速逐渐放缓,饱水状态下塑性变形更显著;相同应力下,饱水状态岩样蠕变量大于自然状态,应变速率也总体快于自然状态,2种状态的蠕变速率在20~30 h时都逐渐稳定,且速率曲线随应力增大,微裂隙压密,彼此逐渐靠近,岩样处于相对硬化阶段;当轴向应力达到66.3 MPa后,饱水状态蠕变速率有相对加速趋势,速率曲线随应力增大先往左下移动,再朝右上移动,而自然状态蠕变速率曲线总体向右上移动。最后,通过蠕变数据分析,推导γ=ασk型经验方程,对蠕变试验数据进行回归拟合,拟合结果证明该蠕变经验模型的正确性。金川矿区斜长角闪岩蠕变实验研究为分析深部巷道该类围岩流变稳定性及支护方案优化等提供有效帮助。

加筋土挡墙试验研究

加筋土结构是国内外正在研究和发展的一项新兴技术.为了研究和推广以粘性土为填料、以聚丙烯塑料带为筋带的加筋土挡墙,探讨其受力状态和变形特点,本文对衡阳湘江公路大桥引道加筋土挡墙的现场测试资料进行了分析,并对这种结构的设计、施工提出了一些具体的建议.

横观各向同性岩石蠕变性质与本构模型研究

层理的存在使得炭质板岩呈现出横观各向同性性质。开展了水平层理试样和竖直层理试样的三轴压缩蠕变试验,研究了不同层理的炭质板岩在不同加载路径下的蠕变特性,分析了蠕变流动方向特征,发现水平层理试样和竖直层理试样蠕变流动方向差异明显;根据蠕变试验结果,提出了横观各向同性岩石蠕变本构模型,该本构模型由基于广义八面体剪应力的蠕变势函数和非关联流动法则构成,蠕变方程采用基于不可恢复应变的内变量蠕变方程;采用不可恢复应变为内变量来描述炭质板岩的蠕变特性,考虑了初始加速蠕变对初始蠕变的影响;提出了模型参数确定方法,并采用试验数据和文献数据对所提模型与参数求解方法进行了验证。研究结果为了解岩石横观各向同性蠕变特性和丰富岩石力学基本理论提供了基础。

不排水循环加载作用下饱和软粘土的蠕变特性

为了探讨珠江三角洲饱和软粘土在交通行车荷载作用下的变形特性,在K0固结状态下进行了一系列不排水的单向循环加载蠕变试验.研究表明:根据循环荷载的大小,饱和软粘土的累积变形可分为衰减型和破坏型;衰减型循环蠕变的累积应变速率与循环次数的关系可用幂函数来表示,引入相对偏应力水平参数,可综合考虑动偏应力、初始静偏力和围压的影响,累积应变速率可用相对偏应力水平的指数函数来表示.文中还基于流动理论,建立了珠江三角洲饱和软粘土的应变速率状态方程,该模型较好地表达了衰减型循环蠕变的应变速率?应力水平?循环次数关系.