Study on mechanical properties of composite materials by in-situ tensile test

The mechanical properties of the SiC fiber-reinforced Mg-Al metal matrix composite materials have been studied on internal microstructure by (scanning electron microscopy) SEM in-situ tensile test. The emergence and propagation of the crack, and the fracture behavior in materials have been observed and studied. It is found that in the case of the tensile test, the crack emerged in SiC fiber initially. In the case of the strong cohesion of the fiber-metal interface, the crack propagated in the fiber, meanwhile the fibers in the neighborhood of the cracked fiber began to crack and the Mg-Al metal deformed plastically, and at last the material fractured. Otherwise the toughness of the materials grows in the case of the lower cohesion of the fiber-metal matrix interface.

In-situ X-ray computed tomography tensile tests and analysis of damage mechanism and mechanical properties in laser powder b e d fused Invar 36 alloy

Laser powder bed fusion(LPBF)is a potential additive manufacturing process to manufacture Invar 36 alloy components with complicated geometry.Whereas it inevitably introduces specific microstructures and pore defects,which will further influence the mechanical properties.Hence,aiming at exploring the LPBF process-related microstructures and pore defects,and especially their influences on the damage mechanism and mechanical properties,Invar 36 alloy was manufactured by LPBF under designed different laser scanning speeds.The microstructure observations reveal that higher scanning speeds lead to equiaxed and short columnar grains with higher dislocation density,while lower scanning speeds result in elongated columnar grains with lower dislocation density.The pore defects analyzed by X-ray computed tomography(XCT)suggest that the high laser scanning speed gives rise to numerous lamellar and large lack-of-fusion(LOF)pores,and the excessively low laser scanning speed produces relatively small keyhole pores with high sphericity.Moreover,the insitu XCT tensile tests were originally performed to evaluate the damage evolution and failure mechanism.Specifically,high laser scanning speed causes brittle fracture due to the rapid growth and coalescence of initial lamellar LOF pores along the scan-ning direction.Low laser scanning speed induces ductile fracture originating from unstable depressions in the surfaces,while metallurgical and keyhole pores have little impact on damage evolution.Eventually,the process-structure-property correlation is established.The presence of high volume fraction of lamel-lar LOF pores,resulting from high scanning speed,leads to inferior yield strength and ductility.Besides,specimens without LOF pores exhibit larger grain sizes and lower dislocation density at decreased scanning speeds,slightly reducing yield strength while slightly enhancing ductility.This understanding lays the foundation for widespread applications of LPBF-processed Invar 36 alloy.

Elastic and plastic deformation behavior analysis in small punch test for mechanical properties evaluation

In order to estimate deformation and mechanical properties of material accurately,elastic and plastic deformation behavior of small punch test was discussed in this paper.A two-dimensional finite element model was established based upon the Gurson-Tvergaard-Needleman(GTN)equation.According to the integration of load–displacement curves with different displacements,the evolution of elastic energy was obtained.The results show that the elastic energy increases quickly in the initial region and tends to be an approximate constant during the plastic bending phase.Meanwhile,an obvious change of the slope of load–displacement curve can be found in the elastic-plastic transition region.The macroscopic deformation and fracture feature were also discussed in order to verify the deformation analysis.Finally,the yield strength,tensile strength and elongation of AISI304 were obtained based on the analysis of deformation energy and percent fracture deflection.The results have a good agreement with that of conventional tensile tests,which may provide a theoretical basis of small punch analysis.

TENSILE TESTING OF C/C COMPOSITES AT HIGH TEMPERATURES

The tensile properties of three different carbonfiberreinforced carbon composites (C/C), mat C/C, 2D laminate and 4D C/C, were investigated under the combined influence of temperature and loading rate. From the experiments the following could be concluded: loading rate between 10-1-10 mm/min was valid; the fracture stress of the three kinds of C/C composites increased with increasing temperature in the range from room temperature to 1900, and the initial modulus of 2D laminate C/C composites increased with the increase of temperature up to 2000.

Assessment of mechanical properties of aluminium alloy welded joint using small punch test

The small punch test technique （SPT） was used to evaluate the mechanical properties of various materials and the basic method to test material tensile mechanics peqeormance from an inverse finite element （ FE） arithmetic with SPT was put forward. The research shows that specific tensile mechanical behavior and strain-stress distribution of each district of weld seam can be accurately determined by small punch test. Therefore, mechanical behavior of the inhomogeneous joint can be predicted by a numerical model. The simulation comes to good agreement with experimental data.

Using Small Punch Test to Investigate the Mechanical Properties of X42 Exposed to Gaseous Hydrogen:Effect of Pressure,Pre-charge Time,Punch Velocity and Oxygen Content

This study investigated the effect of pressure,pre-charge time,punch velocity and oxygen content on the mechanical properties of X42 pipeline steel in gaseous hydrogen environment by using small punch test.When exposed to nitrogen,the fracture mode of X42 pipeline steel undergoes ductile fracture,but in the presence of hydrogen,it shifts to brittle fracture.Moreover,an increase in hydrogen pressure or a decrease in punch velocity is found to enhance the hydrogen embrittlement susceptibility of X42 pipeline steel,as evidenced by the decrease of maximal load,displacement at failure onset and small punch energy.But the effect of pre-charge time on the hydrogen embrittlement susceptibility of X42 pipeline steel is not very obvious.Meanwhile,the presence of oxygen has been found to effectively inhibit hydrogen embrittlement.As the oxygen content in hydrogen increases,the hydrogen embrittlement susceptibility of X42 pipeline steel decreases.

Variation of the mechanical properties of tungsten heavy alloys tested at different temperatures

The high-temperature mechanical properties of 95W-3.5Ni-1.5Fe and 95W-4.5Ni-0.5Co alloys were investigated in the temperature range of room temperature to1100℃. The yield strength and tensile strengths declined gradually, and the ductility of both alloys increased as the testing temperature was increased to 300℃. All the three properties reached a plateau at temperatures between 300 and 500℃ in the case of 95W-3.5Ni-l.5Fe and at temperatures between 350 and 700℃ in the case of 95W-4.5Ni-0.5Co. Thereafter, the ductility as well as yield and tensile strengths decreased considerably.

BFRP复材的体育器械连接部用胶技术与粘接性能分析

为扩大BFRP在体育器械生产加工领域的应用范围,实现BFRP与传统铝合金材料之间的有效连接,研究提出了一项基于胶粘剂的基板材料连接方案。采用Araldite 2015高韧性胶粘剂和回天7130高模量脆性胶粘剂对BFRP和5052-H32铝合金2种基板材料进行胶粘连接处理,通过准静态加载试验的方式来测试该方案的应用效果。结果表明,具有高模量脆性的回天7130胶粘剂能够显著提升基板试件接头的力学性能,充分发挥5052-H32铝合金基板的初始刚度优势以及BFRP基板的峰值荷载优势,有助于BFRP基板在结构更加复杂的体育器械中广泛应用,推动体育器械朝向小型化、轻量化的方向发展。

基于小冲杆试验的管道钢断后伸长率研究

断后伸长率是表征管材塑性的典型指标,管道局部如焊接接头处受尺寸限制无法开展单轴拉伸试验,需要借助微试样试验方法完成取样及测试。小冲杆试验作为一种微试样试验方法,能够用于获取多种力学性能参数。当前研究中,主要通过经验关联方法将载荷-位移曲线中最大位移、最大载荷对应位移及试样断后弧长等关键参量关联至材料断后伸长率。然而,上述方法对管道钢的适用性不明确,使其对管道钢材料无法直接应用。针对这一问题,首先讨论了上述基于不同特征参量的经验关联方法对管道钢的适用性,之后提供了一种断后弧长简化计算方法,并形成了适用于管道钢的基于断后弧长的经验关联公式。在此基础上,进行厚度效应修正,建立了基于小厚度试样确定管道钢材料断后伸长率的经验公式并进行可靠性验证。结果表明,基于断后弧长简化计算方法的经验关联公式确定的断后伸长率最大误差为5.08%,厚度效应修正公式对小厚度试样计算结果的最大误差为5.53%,证明建立的经验关联公式拟合效果良好且对管道钢具有良好的适用性,可为其他钢级管道局部区域断后伸长率的计算提供理论基础。

碳纤维与玄武岩纤维网格增强ECC复合板的单轴抗拉性能研究

传统纤维网格增强水泥基复合材料以脆性材料为基体,开裂后裂缝宽度较大导致FRP网格强度无法充分发挥。为解决该问题,使用高延性水泥基复合材料(ECC)作为水泥基替代脆性材料,与FRP网格结合制备出适用于新土木的新型轻质高强材料纤维网格增强水泥基复合材料(FRCM),并通过对FRCM复合板进行单轴拉伸试验研究FRP类型及层数对纤维网格增强水泥基复合材料力学性能影响机制及其与ECC材料协同受力变形的能力。设计2种不同类型纤维网格(碳纤维CFRP与玄武岩纤维BFRP)增强的ECC复合材料拉伸试验,2种试验均考虑FRP网格层数和基体厚度对复合材料性能的影响。基于FRP网格和ECC材料本身的变形特点,探究FRP类型、层数和基体厚度对复合材料破坏模式、初始弹性模量、应变硬化模量、开裂应力、峰值应力和应变的影响规律。结果表明:1)在试验工况下,随着网格层数从1层增加到6层,试件的抗拉强度均表现出先增大后减小的特性,在配置5层网格时强度最高;2)基体厚度对试件弹性阶段的力学行为影响较小,但对应变硬化阶段的模量和峰值强度影响较大;3)2种FRP网格的强度和伸长率不同,且与短纤维的协同工作性能也存在差异,导致CFRP-ECC和BFRP-ECC复合材料的拉伸性能存在较大差异。

基于小冲杆试验评价钛合金的高温拉伸性能

基于能量密度等效理论,提出依据塑性弯曲阶段载荷-位移曲线,获取均匀连续、各向同性的钛合金圆片试样应力-应变曲线的小冲杆试验新方法;采用该方法预测得到不同名义屈服强度和硬化指数组合工况下假想材料的应力-应变数据,并与有限元预设曲线进行对比;基于小冲杆试验获得的TC4合金在室温、高温(400℃)下的载荷-位移曲线,采用上述方法获得该合金的真应力-真应变曲线,并与单轴拉伸真应力-应变曲线进行对比。结果表明:预测得到的假想材料应力-应变数据与有限元预设曲线之间的符合优度均高于0.96;预测获得的室温和400℃下TC4合金的真应力-真应变曲线与单轴拉伸曲线之间的符合优度均高于0.97,屈服强度和抗拉强度的最大相对误差分别为4.86%和4.63%,验证了该新方法的有效性。

高强度钢材低温力学性能试验研究与预测模型

在极地严寒地区工程中应用高强钢可节省用钢量,减少低温严酷环境下钢结构制作、运输和安装成本.为研究HG785高强钢在极地低温环境下的力学性能,对考虑2种厚度和5种低温环境的高强钢试样开展单轴拉伸试验.试验结果表明,极地低温环境下HG785高强钢的弹性模量、屈服强度和极限抗拉强度相较于其在25℃常温环境下有所提高,失效模式均为颈缩延性破坏并无脆断倾向.采用全子集法对试验结果进行回归分析,建立极地低温环境下高强钢力学性能指标预测模型,可指导高强钢在结构构件、节点与体系中的合理高效应用,为高强钢结构在极地低温地区服役与结构设计优化策略决策提供理论依据.

海洋环境下腐蚀后钢管桩材料性能退化研究

钢管桩作为钢栈桥的重要组成构件,在海洋环境下会受到严重的腐蚀威胁。研究了东海某钢栈桥经历5年海洋自然腐蚀后钢管桩的材料性能。从钢管桩的浪溅区、潮差区和全浸区共加工16个拉伸试件,分析各区域的退化力学性能,根据试验数据建立弹性模量、屈服强度、应变硬化指数和强度系数等参数与平均厚度剩余率相关的回归方程,依据三线型本构模型建立3个区域真实应力-应变曲线的拟合公式。结果表明:浪溅区受腐蚀影响最严重,各区域钢材力学性能均存在一定损失;回归方程可以较好地预测3个区域的屈服强度;通过比较各区域的平均厚度剩余率适用范围,可知三线型本构拟合公式适用于腐蚀较为严重的钢管桩。

基于切口梁弯曲响应的UHPC受拉性能反演分析

为了更加快速、准确地获取超高性能混凝土(UHPC)材料的拉伸性能,该文基于切口梁四点弯曲试验获得的荷载-切口张开位移(CMOD)响应,提出了一种UHPC拉伸性能简化反演分析方法。该方法采用了考虑裂纹局部化的非线性铰模型和可描述拉伸应变硬化或应变软化特征的多折线UHPC受拉应力-应变关系。通过5种钢纤维掺量的UHPC切口梁弯曲试验和轴拉试验的验证以及模型参数分析表明:在切口梁弯曲响应的离散性较低时,提出的计算模型能够准确地预测应变硬化和应变软化UHPC的受拉初裂强度和极限强度;随弯曲响应的离散性增大,轴拉应力的预测值与实测值的偏差越大;特征长度及特征点数量对应变软化UHPC受拉应力-缝宽曲线预测结果的影响较小,但对于应变硬化UHPC,特征长度的增大和特征点的减少都会导致其极限强度预测值偏高。通过应用表明:采用基于荷载-CMOD响应的非线性铰模型预测UHPC的受拉性能具有较好的可行性。

基于压痕法对高温合金GH3536单轴拉伸性能的评估研究

镍基高温合金GH3536因其优异的抗氧化和耐腐蚀性能及良好的蠕变强度,被广泛应用于高温气冷堆、石油化工设备、各类能源转换装置等能源化工行业的高温核心设备。以锻造态和增材制造GH3536为研究对象,探究了将王-张拟合系数模型用于球压头压入试验,从而实现GH3536单轴拉伸性能反演的可行性。研究结果表明,2种不同制造工艺GH3536的屈服强度与常规拉伸测试结果具有较好的一致性,而抗拉强度的预测则存在一定误差,但误差范围与结果稳定性同样能够基本满足工程应用需求。该研究为高温受监部件材质劣化的在线评定提供了重要技术手段,有助于保障相关能源化工行业高温核心设备的服役安全。

Biomechanical behavior of grass roots at different gauge lengths

Gauge length influences the biomechanical properties of herbaceous roots such as tensile resistance,tensile strength and Young’s modulus.However,the extent to which and how these biomechanical properties of herbaceous roots are influenced remain unknown.To better understand the behavior of roots in tension under different conditions and to illustrate these behaviors,uniaxial tensile tests were conducted on the Poa araratica roots as the gauge length increased from 20 mm to 80 mm.Subsequently,ANOVA was used to test the impact of the significant influences of gauge length on the biomechanical properties,nonlinear regression was applied to establish the variation in the biomechanical properties with gauge length to answer the question of the extent to which the biomechanical properties are influenced,and Weibull models were subsequently introduced to illustrate how the biomechanical properties are influenced by gauge length.The results reveal that(1)the variation in biomechanical properties with root diameter depends on both the gauge length and the properties themselves;(2)the gauge length significantly impacts most of the biomechanical properties;(3)the tensile resistance,tensile strength,and tensile strain at cracks decrease as the gauge length increases,with values decreasing by 20%-300%,while Young’s modulus exhibits the opposite trend,with a corresponding increase of 30%;and(4)the Weibull distribution is suitable for describing the probability distribution of these biomechanical properties;the Weibull modulus for both tensile resistance and tensile strain at cracks linearly decrease with gauge length,whereas those for tensile strength and Young’s modulus exhibit the opposite trend.The tensile resistance,tensile strength,and tensile strain at the cracks linearly decrease with increasing gauge length,while the tensile strength and Young’s modulus linearly increase with increasing gauge length.

不同融融连接方式对轨道车辆铝型材性能影响的研究

通过对多腔体铝型材不同融融连接方式样品进行宏/微观组织、拉伸性能、折弯性能、弯曲性能及硬度对比分析。研究表明,由挤压所形成的融融连接接头各项力学性能高于搅拌摩擦融融连接接头,在挤压过程中所形成的粗晶会降低材料的力学性能,所以应在挤压过程中严格控制粗晶的产生;在大结构铝型材产品中,由于同时存在多种融融连接方式(搅拌摩擦和挤压融合),所以建议在使用搅拌摩擦连接的焊接端头应适当的增加母材厚度,从而增加该位置的强度。

冷轧变形量对热处理后CoCrFeMnNi高熵合金退火孪晶及力学性能的影响

经冷变形与热处理后的CoCrFeMnNi高熵合金性能会受到在退火过程中产生退火孪晶的影响,而孪晶形貌与种类的变化与冷变形量和热处理条件相关。探究了高温短时热处理下,冷变形量对退火孪晶及力学性能的影响。采用真空中频感应熔炼炉制备了FCC单相CoCrFeMnNi高熵合金,样品经均匀化退火后使用两辊轧机沿同一方向进行多次冷轧,得到不同变形量的样品。样品在900℃条件下退火1 h,采用金相显微镜、X射线衍射与透射电子显微镜对样品的微观组织形貌进行表征以观察样品中退火孪晶的变化,在室温下对样品进行了静态单轴拉伸试验,研究了不同变形量对于退火孪晶的影响以及退火前后力学性能的变化。结果表明,退火孪晶的种类和数量会随变形量变化:变形量30%的样品内部晶粒尺寸大,退火孪晶的种类和数量最少;变形量80%的样品晶粒尺寸与30%的样品相近,但退火孪晶数量、种类多;变形量50%的样品晶粒尺寸最小,退火孪晶数量与种类中等。未经热处理的样品其抗拉强度与变形程度呈正相关,抗拉强度最高可达到1333.44 MPa,经900℃×1 h退火处理后,其抗拉强度与变形程度呈负相关,抗拉强度最高为585.81 MPa。结果表明,CoCrFeMnNi高熵合金在高温短时间的热处理条件下具有良好的相稳定性,轧制和退火后均为FCC单相结构,没有析出相产生。冷变形后的样品在热处理后样品内部发生了再结晶,晶粒的尺寸大小与退火孪晶的数量和种类以及样品的力学性能会随着变形量的不同产生变化。同时,合金内部产生的小尺寸退火孪晶起到了存储位错的作用。

不同针刺密度石英针刺毡复合材料的力学性能研究

为探究不同针刺密度对石英针刺毡及其复合材料力学性能的影响,采用叠层针刺方法,制作石英针刺毡。采用真空辅助树脂转移模塑成型(VARTM)工艺,以环氧树脂为基体,石英针刺毡为增强体,制作复合材料。力学性能测试结果表明:石英针刺毡和其机织布的拉伸性能随着针刺密度增加呈递减趋势,层间剥离强度呈先增后减趋势,在针刺密度30针/cm^(2)时层间性能最好;随着针刺密度增加,石英针刺毡复合材料的拉伸性能呈减少趋势,剪切性能和弯曲性能呈先增后减趋势,压缩性能呈增加趋势;剪切性能在针刺密度50针/cm^(2)时达到最高,弯曲性能在针刺密度30针/cm^(2)时最好。

EQNiCr-3带极堆焊材料的微观组织与力学性能研究

研究通过采用光学显微镜探究了EQNiCr-3带极堆焊材料中的微观组织特征,观察了EQNiCr-3合金堆焊层组织形貌及其晶粒尺寸,并进行力学性能试验,分析了不同热输入下堆焊金属的组织性能。试验结果表明,所研究的堆焊层中,γ-Ni基固溶体为主要的组成相,且在其内部分布有大量的弥散强化相,这些微观组织的协同作用显著提高了材料的硬度和抗拉强度。利用显微硬度测试和拉伸试验,评价了热处理状态下EQNiCr-3带极堆焊材料的力学性能。研究发现,经过多次焊接热循环后,材料硬度和抗拉强度较原始状态下分别提升了约10%,而断后伸长率略有下降。