PREPARATION OF MICROPOROUS ULTRA HIGH MOLECULAR WEIGHT POLYETHYLENE (UHMWPE) BY THERMALLY INDUCED PHASE SEPARATION OF A UHMWPE/LIQUID PARAFFIN MIXTURE

Ultra-high molecular weight polyethylene (UHMWPE) with a microporous structure was prepared via thermally induced phase separation (TIPS).Liquid paraffin (LP) was used as a diluent in the preparation of microporous UHMWPE. Small angle laser light scattering (SALLS) and differential scanning calorimetry (DSC) were used to determine the phase separation temperatures,i.e.the cloud points and the dynamic crystallization temperatures,respectively.It was found that the cloudI points were coincident with the cryst...

Structure and Properties of Self-reinforced Material Made from Ultra-high Molecular Weight Polyethylene-montmorillonite Nanocomposite

High-strength and high-modulus ultra-high molecular weight polyethylene(UHMWPE), named self-reinforced material, was obtained by the elongation of UHMWPE-montmorillonite nanocomposite at melting temperature. According to the scanning electron microscope(SEM) analysis, a great deal of fibrillar texture formed in the direction of elongation, and the tensile fractured surface was similar to that of highly oriented fiber. The transmission electron microscope(TEM) and selective area electron diffraction(SAED) analyses reveal that the reinforced phase of the self-reinforced material is an extended chain crystal and its size is about 50_200 nm wide and several microns long, and the montmorillonite layers are broken up to pieces in the size from 100 to 10 nm. The broken layers which have a huge surface area interacting strongly with macromolecules reduces the entanglement density of UHMWPE and induces the chain orientation in flow field. It is supposed that the astriction of montmorillonite layers to polyethylene chains is not only end-tethered but also side-tethered. The differential scan calorimetry(DSC) analysis shows that there are two endothermal peaks for the self-reinforced material, of which the peak at a higher temperature(136.4 ℃) is ascribed to the melting of the reinforced phase.

Ultra-High Molecular Weight Polyethylene Tape Applied for Distal Humeral Condyle Fracture around Total Elbow Arthroplasty in Patients with Rheumatoid Arthritis: Report of Two Cases

Managing fractures of distal humerus in patients with rheumatoid arthritis (RA) is technically challenging. Total elbow arthroplasty (TEA) is one of the treatment options for these fractures. While elbow motion is largely regained by TEA, comminuted condyle fragments are often ignored. Although numerous approaches for repair of condylar fragments around TEA are described, any universal fixation strategy for these fractures has not been established. This report describes, for the first time, application of an ultra-high molecular weight polyethylene (UHMWPE) tape for the treatment of distal humerus fracture in 2 patients with rheumatic elbow arthropathy. The post-operative clinical courses were good. Radiographs showed bony union of the condylar fragments without loosening in two cases. Because of its flat configuration, softness, and flexibility, UHMWPE tape is a promising material for stabilizing fracture of the distal humerus associated with TEA.

Manufacturing of Ultra-high Molecular Weight Polyethylene Fiber Reinforced Tape and the Loss of Strength

Due to the low density and excellent mechanical proper-ties,high performance fiber reinforced materials have aconsiderable application in the area of high technologyand dally usage.In this paper,the Ultra-high Molecu-lar Weight Polyethylene(UHMWPE)fiber reinforcedPE tape prepared with the method of powder impregnat-ion was studied.The effect of impregnate length and thetensile force of the yarn on the fiber content as well as on the strength and modulus of the tape were discussed.Calculation shows that the strength and the modulus ofthe ULMWPE fiber can keep about 85％ after it undergothe process.

PREPARATION AND CHARACTERIZATION OF ULTRA-HIGH MOLECULAR WEIGHT POLY(ETHYLENE TEREPHTHALATE)(PET)FIBER

This paper reports the spinning and drawing behavior of Ultra-high Molecular Weight polyethylene Terephthalate) (UHMW-PET) fibers. The as-spun fibers were produced by dry-jet wet spinning of a 15%-17% solution in 50:50(v:v) trifluroroacetic acid and dichloromethane. Both molecular weight and polymer solution concentration have marked effect on the drawability of the as-spun-fibers. The maximum extension drawing ratio (EDRmax) of as-spun fiber increases with increasing molecular weight, whereas optimal concentration to achieve the EDRmax of as-spun fibers decreases with increasing molecular weight. Drawing speed and temperature during the first step have remarkable effect on the drawability of these fiber during the second step. Relatively lower drawing temperature and drawing speed (19 ℃ , 60 mm/min) during the first drawing step was beneficial to mechanical properties of ultimate fibers. At the range of 210 ℃ to 230 ℃, the draw ratio (DR) during the second step increases with increasing temperature.

乙烯-丙烯酸共聚物改性环氧树脂/UHMWPE纤维复合材料的制备与性能研究

使用乙烯-丙烯酸共聚物(EAA)与环氧树脂复配作为基体,利用水基乳液浸渍超高分子量聚乙烯(UHMWPE)纤维制备了复合材料,通过在树脂浸润性、树脂耐热性能、复合材料力学性能、界面结合情况以及微观形貌等方面的测试表征,对比了不同EAA含量的基体树脂对UHMWPE纤维复合材料性能的影响。结果表明,EAA与环氧树脂质量比为25∶75的共混体系一方面可发挥EAA组分与UHMWPE纤维间亲和力强的优势,另一方面还能凭借环氧树脂的刚性交联网络保持较高的耐热性能,体系的层间剪切强度达到8.7 MPa,在60℃下弯曲强度保持率接近80%,表现出优异的综合性能。

Optimum Combination of Femoral Head Size, Femoral Head Material, and Acetabular Cup Liner’s Highly-Cross-Linked Polyethylene Brand for Hip Implant

Clinical two-dimensional linear wear rate data for acetabular cup liners fabricated using approved brands of highly cross-linked ultra-high-molecular-weight polyethylene, as reported in 39 articles in the literature, were analyzed using a statistical technique called response surface methodology. The output was a series comprising16 acceptable combinations of femoral head diameter (HD), femoral head material (HM), and HXLPE brand (PB), each of which would yield the optimum wear rate (herein taken to be a wear rate of practically zero). An example of such a combination is 28- mm-diameter Oxinium? femoral head articulated against an acetabular cup liner fabricated from ReflectionTM HXLPE. The findings in this work may guide an orthopaedic surgeon’s selection of the combination of HD, HM, and PB to use in a primary total hip joint replacement.

HDPE-g-GMA增容PC/UHMWPE的形态结构和力学性能

研究了增容剂HDPE－g-GMA对PC/UHMWPE共混体系的形态结构和力学性能的影响。HDPE-g-GMA的加入有效提高了PC/UHMWPE共混体系的相容性,分散相的尺寸得以降低,两相之间的结合力提高。共混物的冲击断面呈明显的韧性断裂特征,冲击强度较未增容体系提高60%以上;当共混体系中UHMWPE的用量不变时,增容剂用量增加将产生更多的、较容易屈服的局部单元,共混物的屈服强度随之降低;增容剂用量增加,共混物的拉伸强度略有下降。

弹丸侵彻陶瓷-UHMWPE复合材料靶板分析模型

该文将弹丸侵彻陶瓷-超高分子量聚乙烯(UHMWPE)复合材料靶板的过程分解为弹丸与陶瓷锥的相互作用和陶瓷锥与复合材料背板的相互作用,并建立了相应的分析模型。假设塑性流动区的应力满足Aleksevskii-Tate公式,通过动量定理得到了弹丸、陶瓷锥的运动方程。假设背板变形后的锥角不变,根据能量守恒建立了背板的运动方程。研究结果表明,由该模型可得到弹丸的侵蚀长度、陶瓷锥对背板的侵彻深度、背板的鼓包半径和鼓包高度,7.62普通弹撞击防弹衣插板的实验值与模型预测值的相对误差小于25%。

HDPE-g-GMA反应性增容PA66/UHMWPE共混合金性能研究

以甲基丙烯酸缩水甘油酯接枝高密度聚乙烯(HDPE-g-GMA)作为聚酰胺66/超高摩尔质量聚乙烯(PA66/UHMWPE)共混合金的增容剂,采用熔融法制备了PA66/UHMWPE/HDPE-g-GMA共混合金。通过Molau试验、SEM观察和力学性能测试,研究了HDPE-g-GMA在熔融共混过程中对PA66/UHMWPE共混合金的增容作用。结果表明:HDPE-g-GMA与PA66发生了化学反应,所生成的接枝共聚物对PA66/UHMWPE共混合金有较好的增容作用;PA66/UHMWPE共混合金的界面形态和力学性能均有较大改善,吸水率也有所降低。

基于UHMWPE/nano-ZnO复合材料摩擦特性的正交试验及回归分析

用热压成型法制备了纳米ZnO填充超高分子量聚乙烯(UHMWPE)复合材料,用销盘式摩擦磨损试验机测定了复合材料的摩擦学性能,采用四水平正交表设计试验,运用多元线性回归方法处理试验数据,分别得到了复合材料的摩擦系数和磨损率与载荷、纳米粒子含量和相对滑动线速度3个试验因素间的回归方程。结果表明,载荷对复合材料摩擦系数的影响最大,纳米粒子含量和相对滑动线速度的影响相对较小。复合材料摩擦系数随着载荷的增加而减小;试验因素对磨损率的影响程度由大到小依次为相对滑动线速度、载荷和纳米粒子含量,复合材料磨损率随着相对滑动线速度和载荷的增加而增大,随着纳米粒子含量的增加而减小。

双水杨醛缩1,6-己二胺Schiff碱铜配合物改性UHMWPE新型耐磨材料的研究

分别对含不同质量分数(2.5wt%、5wt%、10wt%、15wt%)的双水杨醛缩二胺型Schiff碱Cu(Ⅱ)配合物的改性UHMWPE与45#钢配副进行了干摩擦条件下的销-盘摩擦磨损试验,并采用SEM观察试样磨损表面形貌,采用EDS分析销试样未磨损及磨损表面的主要元素组成,探讨其磨损机理.结果表明:在15wt%质量分数范围内,随着双水杨醛缩1,6-己二胺Schiff碱铜配合物添加量的增加,改性UHMWPE与钢配副的摩擦系数逐步降低,耐磨性逐步提高,其中磨损最轻的是含10wt%双水杨醛缩1,6-己二胺Schiff碱Cu(Ⅱ)配合物的改性UHMWPE;磨损机制均为磨粒磨损,并发现Schiff碱Cu(Ⅱ)配合物添加剂中的Cu元素发生了选择性转移效应.

人工关节CoCrMo-UHMWPE配副在不同接触应力下的摩擦、磨损和磨屑特征

因磨屑引起的假体骨溶解现象是导致人工关节临床失效的关键因素之一。为了解假体材料的摩擦磨损和摩屑特征并优化假体摩擦学设计,选用人工关节最常用的钴铬钼-超高分子量聚乙烯(CoCrMo-UHMWPE)配副,采用新生牛血清溶液作为润滑介质,分别在22,35,48,60 MPa点面接触应力下开展了5万次往复滑动摩擦实验,通过多功能摩擦磨损试验机、金相显微镜、扫描电子显微镜等仪器研究了CoCrMo-UHMWPE配副的摩擦系数、磨损量和磨损形貌,进而表征了其摩擦磨损特性,并采用酸分解方法研究了磨屑的数量、尺寸、形貌及分布特征。结果表明:接触应力对CoCrMo-UHMWPE配副的摩擦、磨损和磨屑特征均有显著影响。随着接触应力逐渐增大,CoCrMo-UHMWPE配副的摩擦系数变化不大但具有降低趋势,磨损量则显著增加且具有一定线性关系,磨损形貌也显示出更严重的犁沟和划痕现象。在磨屑特征方面,接触应力增大会使尺寸小于5μm的磨屑的数量显著增加,但磨屑数量总量先增加后降低,典型磨屑形貌则以块状为主,同时伴随少量尺寸更小的球状和片状磨屑。

新型高效UHMWPE催化剂QTE-1的研究

利用过程强化技术制备了UHMWPE催化剂QTE-1,并进行了小试聚合评价,重点考察了过程强化技术以及聚合温度、聚合压力等工艺条件对其性能的影响。研究结果表明,QTE-1催化剂具有聚合活性高、反应动力学曲线平稳、活性衰减缓慢等特点,聚合所得树脂性能优异。

低逾渗MWCNTs-CB/UHMWPE导电复合材料的制备及性能

采用溶液法及机械共混法分别制备了均匀结构的炭黑(CB)/超高分子量聚乙烯(UHMWPE)及隔离结构的多壁碳纳米管(MWCNTs)-CB/UHMWPE复合薄膜。扫描电镜分析显示,虽然大部分CB均匀分散于UHMWPE基体中,但依然存在明显的局部团聚,而隔离结构中的MWCNTs-CB分布于UHMWPE界面间,更易形成导电通道。导电测试结果表明,复合材料的导电逾渗值由均匀分布的4.91%(体积分数)下降到隔离结构的0.42%。MWCNTs的加入完善了CB间的导电网络,使复合材料的逾渗值进一步下降,当CB∶MWCNTs=15∶1时,复合薄膜的逾渗值由0.42%(体积分数)下降到0.24%,然而混合填料中MWCNTs含量的进一步增加几乎对逾渗值没有影响。力学性能研究表明,隔离型复合材料的拉伸强度和断裂伸长率随填充剂含量的增加呈现出先上升后下降的趋势。

UHMWPE的接枝改性及其与Nano-PTFE复合材料的摩擦学性能

通过紫外光引发聚合将全氟烷基乙基甲基丙烯酸酯共聚物(PFAMAE)单体接枝到超高摩尔质量聚乙烯(UHMWPE)上,制备出超高摩尔质量聚乙烯接枝全氟烷基乙基甲基丙烯酸酯共聚物(UHMWPE-g-PFAMAE)。再采用热压成型法制备出UHMWPE-g-PFAMAE/纳米聚四氟乙烯(nano-PTFE)复合材料。采用红外光谱(FTIR)对接枝前后的UHMWPE进行表征,并借助磨损试验机和扫描电子显微镜(SEM)考察了UHMWPE、UHMWPE-g-PFAMAE和UHMWPE-g-PFAMAE/nano-PTFE复合材料的摩擦学性能和机理。结果表明,PFAMAE单体已成功接枝到UHMWPE上;与纯UHMWPE相比,UHMWPE-g-PFAMAE的摩擦因数和磨损率均明显减小;在UHMWPE-g-PFAMAE中加入nano-PTFE后,复合材料的摩擦因数和磨损率进一步降低,当nano-PTFE质量分数为1%时,复合材料的性能最佳。接枝改性有效抑制了纯UHMWPE的磨粒磨损和塑性变形,加入适量的nano-PTFE,UHMWPE-g-PFAMAE/nano-PTFE复合材料仅表现为轻微的疲劳磨损。

面向人工关节用UHMWPE模塑料冲击韧性的影响因素

人工关节用模塑料的冲击韧性要求达到180 kJ/m^(2),随着人工关节使用寿命需求的提高,对作为人工关节垫片上游材料的超高分子量聚乙烯(UHMWPE)的韧性提出了更高的要求。本文选用不同分子量(w)的树脂粉料,从粉料结构和加工方式的角度对UHMWPE的增韧原因进行探讨。发现特殊的粉料结构带来了更高的冲击韧性。通过对结晶相、非晶相和中间相的比例分析知道晶区的大小及分布和中间相含量会影响制品的冲击韧性。等温结晶这种后处理方式,能够明显增加样品的韧性。研究发现等温结晶提高冲击韧性的主要原因是用于传递应力的中间相含量提高,起到了提高能量吸收的作用。两个角度均论证了具有高中间相含量的制品具有更高的冲击韧性。研究结果为发展高韧性的人工关节用UHMWPE模塑料提供了有益参考。

双向同性自增强UHMWPE板材的制备

在室温条件下,对超高分子量聚乙烯(UHMWPE)模压板双向辊压,以实现双向自增强。探究了双向均匀提升模压板性能的技术可行性,考察了辊压比对模压板球晶形变的影响以及自增强板材聚集态结构与其力学性能的关联性。结果表明,辊压使原模压板约71.2 nm的球晶细化至39.4 nm的微晶,结晶度从45.2%降至40.2%,部分正交晶系转变为单斜晶系。辊压比达36.6%的自增强板材,两个方向的拉伸强度分别达到了62、60 MPa。

捻度对渔用UHMWPE裂膜纤维线股拉伸性能与耐磨性能的影响研究

为促进超高分子量聚乙烯裂膜纤维(简称UHMWPE裂膜纤维)在渔用绳网中的应用,以膜裂法制备渔用UHMWPE裂膜纤维为原料,通过加捻制备渔用UHMWPE裂膜纤维线股,在此基础上,考察了加捻对UHMWPE裂膜线股的线密度、直径、拉伸性能和耐磨性能的影响。结果显示:UHMWPE裂膜纤维线股随捻度的增加表现出直径逐渐减小、实际线密度先增大后减小以及捻回角逐渐增加等特征;对于不同线密度规格的UHMWPE裂膜纤维线股,随着捻度的增加,其断裂强力均呈现降低的趋势,且纤维线密度越低,加捻对线股断裂强度的影响越小;1600 D的UHMWPE裂膜纤维线股的磨损次数随捻度的增加而降低,而3200和4800 D线股的磨损次数随捻度的增加呈现先降低后升高的变化趋势,且4800 D的不同捻度的线股之间的磨损次数无显著性差异(P<0.05),显示出纤维线密度越大,加捻对其耐磨性能的影响越小。1600、3200和4800 D的UHMWPE裂膜纤维线股的结节强力随捻度的增大呈现先升高后降低的变化趋势,当预加捻度为120 T·m^(-1)时,3种线密度线股的结节强力达到最大值,分别为204.15、373.5、562.41 N,较未加捻UHMWPE裂膜纤维分别提高了50.14%、37.13%和30.22%。在本实验捻度设置范围内,1600 D裂膜线股的结节强度随捻度的增加而增大,较未加捻裂膜纤维结节强度提高了32.49%。研究表明,无捻或低捻度、低线密度UHMWPE裂膜纤维线股可用于UHMWPE裂膜纤维无结网的制备;无捻或低捻度的高线密度UHMWPE裂膜纤维线股则具有较好的耐磨性能;中高捻度、低线密度UHMWPE裂膜纤维线股可用于UHMWPE裂膜纤维有结网的制备。研究结果可为渔用UHMWPE裂膜纤维绳网材料的加工、开发与应用提供参考。

电子束和γ-ray对UHMWPE纤维的辐照效应对比研究

γ-ray和电子束是高能辐照源,高能射线不仅可以处理被加工物表面,同时可深入其内部,且工艺控制简单,可进行常温或者低温加工,具有节能、无环境污染等特点.分别采用γ-ray和电子束辐照超高相对分子质量聚乙烯(UHMWPE)纤维,采用电子自旋共振(ESR)、红外光谱(IR)、差示扫描量热法(DSC)、X射线衍射(XRD)、扫描电镜(SEM)、凝胶含量和拉伸实验等表征手段对不同的辐照效应进行研究,旨在改善纤维表面惰性,探索合理使用两种辐射源辐照改性材料的适用范畴,为更好地利用辐照技术对UHMWPE纤维表面改性提供理论依据.