Investigation of fatigue behaviour of warp knitted fabrics under cyclic tension

Abstract

In this investigation, the relationships between the warp knitted fabric fatigue behaviour and its structural parameters are examined as these are important factors influencing the mechanical properties of the fabric. For the experimental work, a uniaxial tensile fatigue tester with a single station has been designed and constructed. Cycling was continuously variable to a maximum of 115 cycles min^-1, and the maximum stroke was adjustable up to 10 cm. A series of experiments was conducted to study the effect of stroke on the performance of various warp knitted structures with a view to changing the underlap length of the front guide bar or back guide bar (Tricot, Locknit, Reverse Locknit, Satin and Sharkskin) under cyclic tension. During fatiguing at different cycles and for various strokes, it was found that only insignificant differences were produced in the breaking tenacity of the polyester yarns and fabric samples, whereas their deformation and tensile modulus values increased and breaking extension decreased. The increase in front guide bar underlap, and simultaneously the increase in the underlap angle to the tensile direction, cause an increase in fabric deformation. In most samples, with the increase in underlap length in the front guide bar or back guide bar, the percentage of tensile modulus and the breaking extension % variations are greater than in Tricot fabric, but this change is more pronounced for samples with a longer front guide bar. These variations were attributed to the existence of space for yarn movement inside the fabric structure as the main fabric structural parameter, and also to the underlap length as the other parameter.     

Tensile Properties of Arenga pinnata Fiber-Reinforced Epoxy Composites

The aim of this study is to determine the tensile properties of Arenga pinnata fiber as a natural fiber and epoxy resin as a matrix. The Arenga pinnata fibers were mixed with epoxy resin at the various fiber weight percentages of 10%, 15%, and 20% Arenga pinnata fiber and with different fiber orientations such as long random, chopped random, and woven roving. Hand lay-up processes in this experiments were to produce specimen test with the curing time for the composite plates is in the room temperature (25–30°C). Results from the tensile tests of Arenga pinnata fiber reinforced epoxy composite are that the 10 wt.% woven roving Arenga pinnata fiber showed the highest value for maximum tensile properties. The tensile strength and Young's modulus values for 10 wt.% of woven roving Arenga pinnata fiber composite are 51.725 MPa and 1255.825 MPa, respectively. The results above indicate that the woven roving Arenga pinnata fiber has a better bonding between its fiber and matrix compared to long random Arenga pinnata fiber and chopped random Arenga pinnata fiber. Scanning electron microscopy (SEM) tests were carried out after tensile tests to observe the interface of fiber and matrix adhesion.     

基于树脂膜溶渗经编多轴向复合材料成型及性能分析

详细阐述了四轴向经编玻璃纤维织物树脂膜溶渗成型工艺,测试了成型后的复合材料性能,并与同样条件下手糊成型工艺进行对比。结果表明:由于树脂膜溶渗成型工艺复合材料中的纤维体积含量要高于手糊成型工艺,因此其试样的断裂强力、断裂伸长率要高于手糊成型;另外,树脂膜溶渗成型复合材料试样沿不同取向断裂强力由高到低分别是经向、斜向、纬向;经真空辅助成型制备的材料相比手糊成型具有较优异的韧性。     

Mechanical Properties of Talc Filled i-PP/CSM Rubber Composites

ABSTRACT

Tensile and impact properties of talc-filled i-PP/CSM rubber (20 phr, 0.13 vol fraction) blends were studied in the talc concentration range 0–0.149 vol fraction (0–50 phr). The tensile modulus increased whereas the tensile breaking strength and the strain-at-break decreased with increase in the talc concentration. The modulus increase and the strain decrease were due to enhanced mechanical restraint imposed by the talc particles on the polymer blend decreasing its deformability. Formation of stress concentration points explained the decrease in the tensile strength. The Izod impact strength showed a significant decrease with increase in the filler content. Surface treatment of the talc particles with a titanate coupling agent LICA 12 increased the wetting of the talc by the polymer blend, further modifying the strength properties. Scanning electron microscopic studies showed enhanced dispersion of the filler particles sequential to the surface treatment, effecting modifications of the composite strength properties.     

MEASUREMENTS OF DELAYED WARP IN EASTERN SPRUCE STUDS

ABSTRACT

Nearly eighty percent of the lumber manufactured in the United States is softwood dimension lumber used for the manufacture of housing. The principal quality related problem with softwood dimension lumber is that it is subject to warp related degradation. Much of the degradation occurs during the initial drying process, however, residual stresses and moisture content changes that occur after kiln drying can either reduce or increase the amount of warp. The magnitude of post kilning warp change, here termed delayed warp, has not been well quantified. Measurements of twist, bow, crook and moisture content were taken from eastern spruce (Picea spp) studs immediately after drying and planing. The wood was allowed to sit without restraint for a period of two weeks after which the measurements were repeated. Of the 1224 studs measured, over 76 percent experienced changes in twist, over 84 percent experienced changes in bow and over 73 percent experienced changes in crook. Increases in warp generally exceeded decreases, although a surprising percentage of the studs showed decreases in warp. Attention was focused on finding a correlation between moisture content and the changes in warp, but the correlation coefficients were low for both the increases and the decreases. The most likely cause of the warp was the high percentage of juvenile wood present in the raw material. The most likely causes for the changes in warp during the two-week period were stress relaxation aggravated by a change in the moisture gradient.     

Deformation Behavior of Ceramic Slabs by Nonuniform Drying

ABSTRACT

The presenr paper is to study the transient deformation characteristics of molded ceramics undergoing nonunifom drying. The linear viscoelasticity was assumed for the strain-stress analysis. Three dimensional equations of the strain-stress as well as heat and moisture transfer werc solved numerically by the Galerkln finlle element melhod using isoparametric parameters of twenty-nodes so to allow easily the application to any feature of ceramics. Both the analysis and experiments were carried out to be compared on the behavior of drying and deformation for a slab clay in preheating and constant drying rare periods. When the bottom surface of the slab uras shielded to model the nonuniform drying. a warp phenomrnon to the opposite side of the shielded surface was observed experimentally as drying by hot air heating proceeds. The behavior could be successively simulaled by the present theoretical model. The degree of warp became rcmarkabel with a rise in air temperature or nonuniformity of drying. The surface area exposed to the atmosphere was subjected to a comparatively large tensional stress through drying. The tensile sltresses on the top surface were significantly larger than on the bottom surface.     

等离子体处理对芳纶针织物复合材料性能的影响

将芳纶织成纬平针织物,再进行等离子体处理;将未处理及处理的芳纶纬平针织物与E44环氧树脂复合制成芳纶针织物复合材料,测试了复合材料的抗拉强度和抗压强度,结果显示:相比处理前,经等离子体处理过的复合材料的经向抗拉强度和纬向抗拉强度分别提高了49%和33%;经向抗压强度和纬向抗压强度分别提高了40%和39%;经向的抗拉强度和抗压强度均大于纬向的。     

The Mechanical Properties of Wood Fiber-reinforced Polymethylmethacrylate

Abstract

The mechanical properties, e.g. tensile modulus (at 0.1% strain), tensile strength at maximum point and corresponding elongation and breaking energy, as well as impact strength, of compression molded PMMA and PMMA filled with wood fibers (10%-40% by weight of composite) have been investigated. Optimization of molding conditions, (e.g. temperature, time, pressure and mixing aids) was carried out. In optimum conditions of mixing and molding, the effect of different parameters, (e.g. nature and concentration of coupling agents (isocyanates), coating treatment, nature of wood species in the form of various pulps) on the mechanical properties of the resulting composites were evaluated. PMPPIC having 2%-4% (by weight of polymer) was found to behave as a true coupling agent because modulus as well as the tensile and impact strengths were improved. Moreover, PMPPIC acted as a coupling agent even when it was used for treatment of PMMA and fiber or to precoat the fiber. A distinct effect of the morphology of wood species and fiber-making techniques on the mechanical properties of wood fiber-filled composites was also observed.     

XLA包芯纱-棉交织物试织研究

以XLA-棉包芯纱为经纱、纯棉纱为纬纱,在Y002S型小样织机上试织了4种XLA包芯纱-棉交织物,并测试了织物的断裂强力、断裂伸长率、耐磨性和褶皱回复性。测试结果表明:相同经纱密度下,斜纹组织织物的断裂强力和断裂伸长率大于平纹组织的;经纱密度越大,织物的耐磨性和褶皱回复性越好。     

Mechanical Properties of Impact i-PP/CSM Rubber Blends

ABSTRACT

The impact strength and the tensile behavior of an impact grade of isotactic polypropylene (impact i-pp)/chlorosulfonated polyethylene (CSM) rubber blends are studied at the CSM rubber concentrations 0 to 23.4 vol%. The impact strength, which increased with CSM rubber concentration, has been analyzed on the basis of the interphase adhesion and crazing mechanisms. Tensile modulus and strength decreased whereas breaking elongation increased with increase in CSM rubber content. Predictive models have been used to explain the tensile modulus and strength properties. Scanning electron microscopy has been employed to study the phase structure.     

制备工艺对亚麻增强聚丙烯复合材料拉伸性能的影响

以亚麻纤维为增强体,与聚丙烯（PP）长丝进行丝束级共混,形成PP包覆亚麻的纱线结构,利用机织工艺织成二维机织布,作为复合材料的预制件。采用层合热压方法制备PP／亚麻复合材料板材。通过对板材拉伸性能测试及扫描电镜（SEM）拉伸断口形貌分析,研究了不同纤维体积分数、织造密度及织造组织等因素对复合材料拉伸性能的影响。结果表明,在选取最优热压温度与压力的条件下,纤维体积分数为50％的板材性能最优;经向密度相同时,拉伸性能随着纬向密度的增加而提高;经、纬向密度均相同时,斜纹3／1组织的板材性能最优,纬向最大拉伸强度可达92．42 MPa。     

Effect of low UD carbon fibre content on mechanical properties of in situ polymerised cyclic butylene terephtalate

Abstract

Carbon fibre reinforced cyclic butylene terephtalate were produced by a low pressure method, the impregnating temperature and the cooling speed were investigated using plate–plate rheometry and differential scanning calorimetry. The effects of low fibre volume fraction of carbon fibre reinforcement (～20?vol.‐%) on the mechanical properties were examined by tensile and flexural tests and Charpy dynamic impact test. The results showed a significant increase in Young’s modulus and ultimate strength and were supported by scanning electron microscopy pictures of the broken surfaces to study fibre wet‐out.     

Characterization of Short Glass Fiber–Reinforced Castor Oil–Based Polyurethane Polystyrene Interpenetrating Networks

ABSTRACT

Chopped strand glass fiber–reinforced particle-filled castor oil–based polyurethane polystyrene composites with varying weight fractions of glass fibers were investigated for morphology, tensile strength, and absorption of various chemicals. The short glass fiber fraction was varied from 1% to 16% (by wt.) of the total composite system. The tensile strength of these composites was much higher than that of unfilled IPNs for the same concentration of polystyrene. The tensile strength of the IPN composites increases with the increase in fiber content up to a fiber percentage of 9%. After that, there is a sharp decline in tensile modulus as well as elongation at break. The chemical absorption showed an increase with increasing glass fiber content.     

Mechanical properties of i-PP/CaCO3 composites

Tensile and impact behavior of CaCO₃-filled polypropylene was studied in the composition range 0–60 wt % filler. Tensile modulus increased while tensile strength and breaking elongation decreased with increase in CaCO₃ content. The modulus increase and elongation decrease were attributed to increased filler–polymer interaction resulting in reduction in molecular mobility, while increased amorphization and obstruction to stress transfer accounted for the tensile strength decrease. Analysis of tensile strength data showed introduction of stress concentration in the composites. Izod impact strength at first increased up to a critical CaCO₃ content, beyond which the value decreased. Surface treatment of CaCO₃ with a titanate coupling agent LICA 12 enhances the adhesion of the filler and polymer, which further modifies the strength properties. Scanning electron microscopic studies indicated better dispersion of CaCO₃ particles upon surface treatment, which effected the changes in the strength properties of the composites.     

Cellulose/casein blend membranes from NaOH/urea solution

Cellulose membranes and cellulose/casein blend membranes were successfully prepared from a new solvent system (6 wt % NaOH/4 wt % urea aqueous solution) by coagulation with a sulfuric acid aqueous solution. The structures and properties of the membranes were characterized by Fourier transform infrared spectroscopy, scanning electron microscopy (SEM), wide-angle X-ray diffraction, differential scanning calorimetry, and a tensile test. The experimental results showed that the suitable coagulation condition was 5 wt % H₂SO₄ for 5 min. When the casein content of the mixture was less than 15 wt %, the blend membranes were miscible because of the interactions between the hydroxyl groups of cellulose and the peptide bonds of casein. The blend membranes with 10 wt % casein had good miscibility, higher crystallinity, and the highest mechanical properties and thermal stability. In this case, the tensile strength and breaking elongation of the blend membranes were 109 MPa and 16%, respectively, and its pore size, obtained by SEM, was 290 nm, which suggests that the blend membranes provide a potential application for the field of separation technology. © 2001 John Wiley & Sons, Inc. J Appl Polym Sci 81: 3260–3267, 2001     

Effect of Alkaline Hemicellulose Extraction on Kraft Pulp Fibers from Eucalyptus Grandis

Abstract

The alkaline extraction of hemicelluloses from hardwoods prior to pulping, for further conversion to value-added products, seems to be a promising pathway for paper mills to increase profit and improve sustainability. However, the amount of hemicellulose extracted will be limited by the requirement to maintain pulp quality and pulp yield in comparison to existing pulping processes. The effects of NaOH concentration, temperature, and time on hemicellulose extraction of Eucalyptus grandis were studied using a statistical experimental design. Extracted wood chips were subjected to kraft pulping to evaluate the effect of the extraction on cooking chemicals, pulp quality, and handsheet paper strengths. The selective xylan recovery (12.4% dry mass) from E. grandis combined with low-cooking, active alkali charge, and less cooking time advantaged the xylan extraction and subsequent modified kraft pulping process under the studied conditions. Pulp viscosity, breaking strength, and tensile index of handsheets were slightly improved.     

Effect of tensile strain rate on the mechanical properties of constrained-uniaxially and simultaneous-biaxially drawn poly(ethylene terephthalate) sheets

The dependency of the mechanical properties (Young's modulus, yield strength, breaking strain, and breaking energy) of preoriented poly(ethylene terephthalate) (PET) sheets on the tensile deformation speeds was examined and discussed in relation to changes of density and birefringence. The procedures for preorientation were constrained-uniaxially (CU) and simultaneous-biaxially (SB) drawings at 65°C. The performance characteristics of the present tensile testing at room temperature were obtained over a wide range of extension rates (1.7 × 10^?4?13.1 m/s = 0.29–2.3 × 10⁴%/s) without changing the mode of deformation and the shape of the test pieces. The CU drawn PET is strain-rate-independent and mechanically superior in structure in the preextended direction with draw ratio λ > 2.5. In the SB drawn PET such a structure comes into existence at λ > 3, which has, furthermore, no dependency on draw direction (mechanically isotropic). The draw ratio of the latter case corresponded to the birefringence (?Δn/d) of about 5 × 10^?2. These results imply a possibility of producing the strain rate (from low to impact speeds) independent, anisotropy-free, and mechanically superior molded products of PET if adequate extrusion or blow molding methods which induce multiaxial orientation with ?Δn/d > 5 × 10^?2 are developed.     

Electric field-driven preparation of elastomer/plastic nanoparticles gradient films with enhanced damping property

Polymeric gradient film consisting of the plastic nanoparticles in addition to an elastomer matrix was created by driving the charged sulfonated polystyrene (PS) nanoparticles in polydimethylsiloxane (PDMS) matrix under direct-current electric field. The gradient morphology was frozen by thermal curing. The morphology, composition, damping, and mechanical properties of cured PS/PDMS gradient film containing 10 wt % of PS nanoparticles were measured with scanning electron microscopy, energy-disperse spectroscopy, and dynamic thermal mechanic analysis and tensile test, respectively. In comparison with the isotropic PS/PDMS film, the gradient film shows a better damping property, and a higher tensile strength and elongation at breaking. The interpretation in terms of deformation and fracture mechanism of gradient structure was proposed. © 2019 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2020 , 137, 48401.     

化学气相渗透2.5维C/SiC复合材料的拉伸性能

采用等温减压化学气相浸渗(isothermal low-pressure chemical vapor infiltration,ILCVI)工艺制备了在厚度方向上具有纤维增强的2.5维(2.5 dimensional,2.5D)碳纤维增强碳化硅多层陶瓷基复合材料,从而使一端封口的防热结构部件的制备成为可能.ILCVI致密化后,复合材料的密度、孔隙率分别为1.95～2.1 g/cm3和16.5%～18%.沿经纱和纬纱两个方向对2.5D C/SiC复合材料进行室温拉伸实验.结果表明:复合材料在纵向和横向的拉伸应力-应变均表现为明显的非线性行为.复合材料具有较高的面内拉伸性能,纵横向的拉伸强度分别为326MPa和145MPa,断裂应变分别为0.697%和0.705%.复合材料的拉伸断裂为典型的韧性断裂,经纱和纬纱的断裂都表现为纤维的多级台阶式断裂以及纤维的大量拔出.