纤维材质对UHMWPE水润滑轴承复合材料摩擦学性能的影响

超高分子量聚乙烯(Ultra-high molecular weight polyethylene, UHMWPE)在水润滑轴承领域具有巨大的发展潜力,然而单一的UHMWPE难以满足水润滑轴承的耐磨性需求,尤其是在低速重载工况下.通过纤维改性的方法可以提高其摩擦学性能,但是纤维材质的不同特性对于复合材料摩擦学性能的影响存在差异.通过热压模具分别制备剑麻纤维(Sisal fiber,SF)、碳纤维(Carbon fiber,CF)和聚酯纤维(Polyester fiber,PETF)与UHMWPE混合的定向纤维复合材料,并与纯UHMWPE做对照试验.利用R-tec往复摩擦试验机模拟不同载荷(5和10 N)和不同速度(20、40和60 mm/s)下铜球与不同复合材料的摩擦过程,通过邵氏硬度和极限抗弯强度试验对复合材料力学性能进行表征测试,采用接触角测试复合材料的浸润性,试验结束后用扫描电子显微镜观察表面磨损形貌.结果表明:纤维的力学性能,尤其是硬度和抗弯强度是影响定向纤维复合材料摩擦学性能的关键因素,所添加纤维在复合材料中强有力的支撑作用使摩擦学性能显著提高,纤维的耐磨性和浸润性是次要因素.试验工况下,CF/UHMWPE摩擦系数最低,且在低速重载(载荷10 N,速度20 mm/s)时的摩擦系数与纯UHMWPE相比降低了36.92%;添加耐磨性强的PETF纤维后,复合材料磨损体积与纯UHMWPE相比降低了30.56%.

铝合金/UHMWPE组合靶板高弹速撞击防护特性研究

为了对某种圆柱形铝合金弹丸1.8~2.0 km/s高弹速撞击进行防护,使用了一种包含两层铝合金板和防护板的组合靶板结构。分别以面密度同为20 kg/m^(2)的氧化铝(Al_(2)O_(3))/超高分子量聚乙烯(UHMWPE)板、碳化硼(B_(4)C)/UHMWPE板和单一UHMWPE板作为防护板,开展了二级轻气炮高速撞击实验。在AUTODYN软件中,针对UHMWPE板建立了一种分层式数值模型,对该弹丸1.92 km/s撞击单一UHMWPE板作为防护板的组合靶板进行了数值模拟。研究结果表明,在组合靶板中,以单一UHMWPE板作为防护板,其性能好于同等面密度下的Al_(2)O_(3)/UHMWPE防护板,对后续二次撞击的防护能力好于同等面密度下的B_(4)C/UHMWPE防护板。所建立的UHMWPE板分层式数值模型可以获得与实验状态较为一致的仿真结果。

Comparison of Biotribology of Swine Compact Bone Against UHMWPE

A pin-on-disk tribometer was used, in a comparative test to observe the tribological behavior of the swine femoral bone against UHMWPE with dry friction, physiological water and human plasma lubrication. The wear mechanisms of swine bones and UHMWPE were investigated by SEM. The experimental results of these wear tests demon- strated that both the friction coefficient and wear rate of UHMWPE were the lowest when human plasma lubrication was used. The wear mechanism of the compact bone was mainly fatigue wear with dry friction, corrosive wear under physiological water lubrication and abrasive wear with human plasma lubrication. For UHMWPE, the wear mecha- nism was adhesive wear and plastic deformation with dry friction, serious ploughing and fatigue fracture wear under physiological water lubrication, fine ploughing and plastic deformation with human plasma lubrication. An analysis of nitrogen elements on the wear surface of UHMWPE indicated that the content of nitrogen in worn areas was 16 times higher than that in unworn areas, which proved that serum protein deposition occurred on worn areas.

UHMWPE薄板抗轻武器杀伤元斜侵彻研究

为解决高性能轻质防弹插板受轻武器杀伤元侵彻防护问题,对超高分子量聚乙烯(ultra-high molecular weight polyethylene,UHMWPE)层压薄板进行了侵彻实验,分析了侵彻后UHMWPE薄板的变形失效特征并对比了轻武器杀伤元的破坏形貌。利用有限元软件LS-DYNA建立了UHMWPE薄板抗轻武器杀伤元侵彻数值模型,通过靶板破坏形态、凹陷深度以及弹头变形的实验结果对数值模型的有效性进行了验证。在此基础上,通过数值模拟方法研究了UHMWPE薄板受弹体斜侵彻失效模式,揭示了3种轻武器杀伤元侵彻下入射角度对跳弹现象和UHMWPE薄板破坏形态的影响规律。结果表明:7.62 mm×25 mm的钢芯弹和7.62 mm×39 mm的普通弹(钢芯)斜侵彻UHMWPE薄板的跳弹角均位于45°~50°范围内;7.62 mm×25 mm的铅芯弹在入射角大于70°时才可完整跳出,其余均以破损弹片形式飞溅,弹体破坏会对跳弹状况产生影响;入射角较小时,斜侵彻子弹会产生面积较大且具有一定深度的弹坑,连续击发的下一枚子弹会更容易击穿弹坑薄弱处的纤维板,斜侵彻作用对薄板受二次侵彻产生不利影响;入射角较大时,子弹会较完整地发生跳弹并具有高剩余速度,会对人员产生二次杀伤。研究成果可为UHMWPE薄板用于轻量化军用防弹插板设计提供参考。

UHMWPE层合板抗侵彻性能的一种等效数值分析方法

为了提高超高分子量聚乙烯纤维(ultra high molecular weight polyethylene fiber,UHMWPE)层合板抗弹体侵彻数值分析的建模和计算效率,基于三维等效弹性常数理论,建立了UHMWPE层合板的等效力学模型,发展了一种适用于纤维复合材料层合板抗侵彻性能的三维等效数值分析方法。经UHMWPE层合板抗侵彻试验数据验证,该等效方法考虑了纤维铺层角度对层合板力学性能的影响,可以准确模拟预测层合板的阶段性侵彻破坏特征,对9.1~60.0 mm厚度范围内层合板弹道性能的平均预测误差小于10%。该方法与纤维尺度的细观数值模拟方法相比,无须对纤维束及基体单独建模;与片层尺度的准细观数值模拟方法相比,无须单独指定纤维/树脂片层铺层方向,且无须在片层间插入大量黏结层单元。

多孔钛合金夹芯层陶瓷/UHMWPE复合结构的抗侵彻性能

陶瓷/纤维复合装甲的纤维背板由于其刚度较低,无法为陶瓷面板提供足够的支撑,削弱了陶瓷面板对弹丸的侵蚀作用。为了增强复合装甲的整体结构刚度,在陶瓷/纤维复合装甲中加入了金属夹芯层材料,通过试验和数值模拟研究了夹芯复合装甲对12.7 mm穿燃弹的抗弹性能。试验结果表明,穿燃弹弹芯表现出脆性断裂的失效模式,复合材料装甲表现出多种失效模式,包括夹芯层的花瓣形扩孔,UHMWPE(ultra-high molecular weight polyethylene)层压板的分层和凸起变形。建立了三维数值模型来分析整个弹道响应的演变,通过试验结果验证了模拟的准确性。模拟结果表明,12.7 mm穿燃弹的被甲会对陶瓷造成损伤,同时陶瓷会侵蚀弹芯的尖卵形头部,使弹芯头部变钝从而削弱弹芯对UHMWPE背板的侵彻能力。残余弹体的动能大部分由UHMWPE层吸收,UHMWPE层压板的失效模式会随着层数的增加由剪切失效转变为拉伸失效占主导地位。此外,作为夹芯层的多孔TC4板能够为陶瓷面板提供支撑,提高陶瓷面板的吸能效果以及弹体的侵蚀作用,并且12 mm孔径的TC4夹芯层能够提供更大的刚度支撑,使整体复合结构的吸能效率提升10%。

UHMWPE/HDPE/LP共混体系相容性的多尺度模拟

采用多尺度模拟与实验相结合的方法,分析了UHMWPE/HDPE/LP共混体系的相容性和微观相互作用机制。基于分子动力学(MD)模拟和耗散粒子动力学(DPD)模拟研究了高密度聚乙烯(HDPE)对超高分子量聚乙烯(UHMWPE)与白油(LP)共混体系相容性的影响,对MD模拟得到的结合能和径向分布函数及DPD模拟得到的等密度进行分析。模拟结果表明,UHMWPE/HDPE/LP体系的结合能为8978.23 kJ/mol,大于UHMWPE/LP体系的结合能(8013.39 kJ/mol);UHMWPE/HDPE/LP体系中不同类分子间C—C原子对的g(r)高于UHMWPE/LP体系中不同类分子间C—C原子对的g(r),并且,特征峰均在5?处出现,范德华作用为分子间的主要相互作用形式;DPD模拟的结果表明,UHMWPE/HDPE/LP体系中分散相的相畴尺寸较小,2种体系均没有相分离的情况。上述结果表明,与UHMWPE/LP体系相比,UHMWPE/HDPE/LP体系的相容性得到显著改善。为证明模拟结果的准确性,对UHMWPE/HDPE/LP原料采用熔融共混方法制备了2种样品,并且,采用扫描电镜(SEM)对样品进行检测,分析了HDPE对共混材料微观形貌的影响,实验结果与模拟结论匹配性较好。

耐热抗蠕变UHMWPE纤维的结构与性能研究

采用广角X射线衍射、小角X射线散射、透射电子显微镜以及固体核磁等手段对采用紫外交联技术制得的耐热抗蠕变超高分子质量聚乙烯(UHMWPE)纤维的结构与性能展开系统研究,结果表明耐热抗蠕变UHMWPE纤维兼具高交联、高结晶、高取向三大特性。对比未交联UHMWPE纤维,耐热抗蠕变UHMWPE纤维的晶态结构、熔点及热分解温度基本无变化,而热断裂温度和强度保持率有显著提高,蠕变伸长率大幅下降,表明通过紫外交联可高效提升纤维的耐热抗蠕变性能。

原液着色UHMWPE纤维用炭黑色浆的制备工艺

探讨了不同种类炭黑、超分散剂的选择及用量对炭黑色浆分散稳定性的影响,优化了炭黑色浆的工艺配方,并对色浆的可纺性进行验证,分析了炭黑粒子在纤维中的粒径大小、分散状态和相容性。结果表明:以质量分数为10%的4#炭黑和质量分数为20%的超分散剂A所制备出的炭黑色浆具有良好的耐热贮存稳定性,颜料粒子尺寸可达到纳米级别,且与超高分子质量聚乙烯(UHMWPE)纺丝原液相容性好;该色浆适用于原液着色UHMWPE纤维的生产。

UHMWPE纤维增强防弹复合材料研究

UHMWPE纤维由于分子链上没有不饱和基团,对酸、碱和有机溶剂有很强的抗腐蚀性,耐光、热、老化性能优良,比强度和模量都很高,且能量吸收性和耐磨损性好,特别适合作为防护材料。文中UHMWPE纤维防弹复合材料,是由改性聚苯乙烯树脂和UHMWPE纤维复合而成,针对其力学性能进行表征并根据实验结果优化组分配比及合成工艺,结果显示组分配比为EVA∶ST=15∶85、ABIN=0.5%和TAIC=2%时制备的树脂复合材料具有合适的拉伸、剥离强度,这一配比的树脂复合材料可以获得最佳的抗冲击能力。研究成果为改性聚苯乙烯树脂和UHMWPE纤维复合材料用作防弹材料提供了实验基础和数据支撑。

UHMWPE织物增强TPU防刺大底复合材料的防刺性能研究

为探究超高分子量聚乙烯(UHMWPE)织物增强热塑性聚氨酯弹性体橡胶(TPU)防刺大底复合材料的防刺性能,以UHMWPE为原料制备4种斜纹织物作为增强体,采用热压工艺制备了UHMWPE织物增强TPU防刺大底复合材料。探究热压工艺、织物组织等因素对材料防刺性能的影响规律,并揭示材料的防刺机理。结果表明:UHMWPE织物增强TPU防刺大底复合材料的防刺性能在一定条件下(150℃织物熔融)随着热压温度的增加呈现增大的趋势,热压温度为140℃时防刺性能最好;防刺性能随着热压时间的增加总体呈先增大后减小的趋势,热压时间为2min时防刺性能最好。织物组织对材料防刺性能的影响依次为2/2右斜纹>3/1右斜纹>32/12加强斜纹>山形斜纹。UHMWPE织物增强TPU防刺大底复合材料的防刺机理主要是纤维剪切破坏、纤维拉伸断裂和织物组织局部变形。

不同成型方式下UHMWPE耐热改性进展

介绍了近年来超高分子量聚乙烯(UHMWPE)在模压成型、挤出成型、注塑成型方面的耐热改性研究进展,分析了采用不同成型方法对UHMWPE耐热改性的方法及改性效果。关于UHMWPE模压与挤出成型的耐热改性方法主要包括物理改性(填充改性、共混改性、共混填充改性)、化学改性(过氧化物交联、偶联剂交联、辐射交联)、聚合填充复合改性,而UHMWPE的注塑成型耐热改性研究较少。对UHMWPE进行耐热改性,加入的改性材料后,能显著提高复合材料耐热性,但是,部分材料的加入却降低了UHMWPE耐磨性、抗冲击性等性能,需要对UHMWPE注塑成型的耐热改性及改性材料的选用进一步研究。最后,对UHMWPE的耐热改性的发展趋势进行了展望。

UHMWPE背板厚度对铝复合板抗侵彻增强效应分析

为研究超高分子聚乙烯(ultra-high molecular weight polyethylene,UHMWPE)背板厚度对铝复合板抗钨球侵彻效果的影响,利用数字图像相关方法(digital image correlation method,DIC)与X射线电子计算机断层扫描(computed tomography,CT)得到UHMWPE受到冲击后的动态响应及局部破坏。建立钨球以不同速度侵彻Al/UHMWPE复合板的有限元模型,研究不同冲击速度下UHMWPE背板厚度对复合靶板吸能性能的影响,所用背板厚度为1.6~20 mm。结果表明:铝板在冲击作用下发生绝热剪切破坏,正交铺设纤维层产生纤维凸起和分叉应变带。随着背板厚度增大,纤维层由剪切破坏向拉伸破坏过度,纤维层应变带由十字形转变为X形。UHMWPE板厚度的增大有效地阻碍了铝块塞体运动,从而增加了破片侵彻铝板的时间与动能消耗。UHMWPE背板厚度对吸能性能影响呈先快速上升至阈值,后缓慢下降的趋势,说明PE板到达一定厚度后,通过增加厚度的方法来提升其吸能性能的作用有限。

Effects of Additives on the Microstructure and Tribology Performance of Ta-12W Alloy Micro-Arc Oxidation Coating

Oxide ceramic coatings were fabricated on tantalum alloys by micro-arc oxidation (MAO) to improve their hardness and tribological properties. The MAO coatings were manufactured in a mixed silicatephosphate electrolyte containing NaF and/or EDTA (ethylene diamine tetraacetic acid). The surface morphology,cross-sectional view, chemical composition, hardness, and wear performance of the coatings were analysed. As revealed by the scanning electron microscopy, silica-rich nodules appear on the MAO coating obtained in the silicate-phosphate electrolyte, but the formation of nodules is inhibited with NaF and/or EDTA in the electrolyte.Also, they reduce the roughness and improve the compactness of the coatings, which are composed of Ta_(2)O_(5),(Ta, O), and TaO. A thick and hard coating is obtained in the NaF-containing electrolyte, and the tribology performance is effectively improved. With additives, the nodule structure is detached from the coating surface and dissolved in the electrolyte. By using NaF as an electrolyte additive, the abrasion performance of the MAO coating is enhanced by decreasing the nodule structure, increasing the size of micropores, and improving the coating hardness.

Ballistic Penetration Damage of Hybrid Thermoplastic Composites Reinforced with Kevlar and UHMWPE Fabrics

Polymer matrix types of fiber hybrid composites are key factors to improve ballistic impact damage tolerances.Here we report ballistic penetration damages of Kevlar/ultra-high molecular weight polyethylene(UHMWPE)hybrid composites with thermoplastic polyurethane(PU)matrix.The hybrid composites were penetrated by fragment-simulating projectiles(FSPs)using an air gun impact system.The effects of stacking sequences on the ballistic performance of hybrid composites were analyzed.Two types of specific energy absorption(the energy absorption per unit area density and the energy absorption per unit thickness)were investigated.It was found that the main damage modes of PU hybrid composites were fiber breakage,matrix damage,fiber pullout and interlayer delamination.The instantaneous deformation could not be used as a reference index for evaluating the ballistic performance of the target plate.The energy absorption process of the PU hybrid composites showed a nonlinear pattern.The hybrid structure affected the specific energy absorption of the materials.

Effect of solidification cooling rate on microstructure and tribology characteristics of Zn-4Si alloy

The main objective of this work was to modify the microstructure and enhance the tribological properties of a new Zn-4Si al-loy through a high solidification cooling rate(SCR).According to the results,by increasing the SCR from 2.0 to 59.5℃/s the average size of primary Si particles and that of the grains reduced from 76.1 and 3780μm to less than about 14.6 and 460μm,respectively.Augment-ing the SCR also enhanced the microstructural homogeneity,decreased the porosity content(by 50%),and increased the matrix hardness(by 36%).These microstructural changes enhanced the tribological behavior.For instance,under the applied pressure of 0.5 MPa,an in-crease in the SCR from 2.0 to 59.5℃/s decreased the wear rate and the average friction coefficient of the alloy by 57%and 23%,respect-ively.The wear mechanism was also changed from the severe delamination,adhesion,and abrasion in the slowly-cooled alloy to the mild tribolayer delamination/abrasion in the high-cooling-rate-solidified sample.

UHMWPE隔膜挤出成型工艺的实验研究

研究了挤出成型工艺参数如螺杆转速、螺杆温度等对超高分子质量聚乙烯(UHMWPE)湿法隔膜加工过程中冻胶液压力及预制膜厚度的影响。结果表明:随着螺杆转速的增加,相同时间内冻胶液挤出量增加,导致冻胶液压力增加;挤出膨胀率随剪切速率的增加而增加,从而造成挤出胀大现象更加明显;随着熔融段温度梯度的增加,网前、网后压力及预制膜的厚度增加,制品厚度尺寸稳定性降低。

Paving continuous heat dissipation pathways for quantum dots in polymer with orangeinspired radially aligned UHMWPE fibers

Thermal management of nanoscale quantum dots(QDs)in light-emitting devices is a long-lasting challenge.The existing heat transfer reinforcement solutions for QDs-polymer composite mainly rely on thermal-conductive fillers.However,this strategy failed to deliver the QDs’heat generation across a long distance,and the accumulated heat still causes considerable temperature rise of QDs-polymer composite,which eventually menaces the performance and reliability of lightemitting devices.Inspired by the radially aligned fruit fibers in oranges,we proposed to eliminate this heat dissipation challenge by establishing long-range ordered heat transfer pathways within the QDs-polymer composite.Ultrahigh molecular weight polyethylene fibers(UPEF)were radially aligned throughout the polymer matrix,thus facilitating massive efficient heat dissipation of the QDs.Under a UPEF filling fraction of 24.46 vol%,the in-plane thermal conductivity of QDs-radially aligned UPEF composite(QDs-RAPE)could reach 10.45 W m^(−1) K^(−1),which is the highest value of QDs-polymer composite reported so far.As a proof of concept,the QDs’working temperature can be reduced by 342.5℃ when illuminated by a highly concentrated laser diode(LD)under driving current of 1000 mA,thus improving their optical performance.This work may pave a new way for next generation high-power QDs lighting applications.

碳化硼陶瓷/UHMWPE纤维复合靶板防弹性能仿真与实弹验证

目的:为实现防弹靶板的轻量化和高防护性,对碳化硼陶瓷/超高分子量聚乙烯(ultra-high molecular weight polyethylene,UHMWPE)纤维复合靶板的防弹性能进行仿真优化与实弹验证。方法:首先,基于ANSYS/LS-DYNA建立碳化硼陶瓷/UHMWPE纤维复合靶板的有限元模型。其次,对子弹侵彻不同厚度搭配的防弹靶板过程进行仿真,分析防弹靶板对100 m处56式7.62 mm普通枪弹的防护效果。最后,基于仿真结果,以靶板的防护性和质量作为主要指标,对靶板进行优化设计,并通过实弹射击验证设计靶板的防弹性能。结果:仿真结果表明,不同厚度搭配的防弹靶板都可以实现对100 m处56式7.62 mm普通枪弹的有效防护;实弹验证结果表明,仿真结果准确,设计的防弹靶板具有较好的防护性。结论:对碳化硼陶瓷和UHMWPE纤维设置合理的配比可以满足防弹靶板的高防护性和轻量化需求,该研究可为轻质、高防护性防弹靶板的研发提供参考。

基于3D-DIC 技术的老化UHMWPE 无纬布准静态拉伸性能研究

目的通过研究老化后的超高分子量聚乙烯(UHMWPE)无纬布力学特性,了解防弹衣在自然环境下的抗老化性能,为防弹装备使用和存储提供科学指导。方法采用三维数字图像相关技术(3D-DIC)和万能材料试验机开展了其准静态拉伸力学性能测试。结果十年自然老化后的UHMWPE无纬布应力应变曲线仍呈近似线性特征,但平均拉伸模量仅为18.0 GPa。结合试验过程中的全场应变变化过程,分析了UHMWPE无纬布试件的变形特性,发现拉伸过程中应变在分析区域内的分布较均匀。结论十年自然老化后的UHMWPE无纬布软质防弹衣平均拉伸模量明显降低,防弹性能无法满足使用要求。