Ümit Halis Erdoğan

The Mechanical Properties of γ-Methacryloxypropyltrimethoxy silane-treated Jute/Polyester Composites:

In this study, jute/polyester composites were fabricated. To improve the adhesion between jute fabric and polyester alkali-treated jute fabrics were treated with γ-methacryloxypropyltrimethoxysilane (γ-MPS). The effect of silane concentrations (0.1%, 0.3%, and 0.5%) on tensile properties, flexural properties, and interlaminar shear strength was investigated. Once jute fabrics were treated with 0.1% and 0.3% silane concentrations, the tensile properties of silane-treated jute polyester composites increased. However, when 0.5% γ-MPS was used in silane treatment, the tensile properties of jute/polyester composites decreased. 0.3% silane-treated jute/polyester composites exhibited superior improvements in terms of the flexure properties among the fabricated composites. Interlaminar shear strength measurements showed that best adhesion was provided by using 0.3% silane-treated jute/polyester composites. Good adhesion between silane-treated jute fabric and polyester was also confirmed by scanning electron microscope observations.

Effect of pile fiber cross section shape on compression properties of polypropylene carpets

Fiber cross section shapes, which have a direct influence on the physical properties of textile surfaces, are becoming more and more complex recently. There are also many important properties of the carpets such as luster, resilience, abrasion resistance which are impacted by the shape of the fiber cross sections. In this present paper, the influence of pile fiber cross section shape on compression properties of carpets was experimentally investigated under short and long-term static loadings. The material used was polypropylene carpets having two different pile fiber shapes: trilobal and hollow. The experimental results indicate that percentage thickness loss of carpets having hollow piles is slightly higher than carpets with trilobal piles in both short- and long-term static loadings. However, in the case of percentage recovery, similar values were obtained for the samples used in this study.

Effect of Different Surface Treatments on the Properties of Jute

In this study, effect of various surface treatment processes on waste jute fibers, which can be used for composite material production, was considered. For this purpose, jutes (J) were treated with NaOH as a pretreatment process before the other surface treatments. Then, alkali treated jutes (AJ) were modified with silane coupling agent (ASJ), fluorocarbon-based agent (AFJ), and also argon plasma (APJ). To investigate effects of the treatments on surface characteristics and physical properties of jutes; Fourier transform infrared spectroscopy (FTIR), x-ray photoelectron spectroscopy, thermogravimetric analysis, x-ray diffraction, and scanning electron microscopy (SEM) were used. The effects of treatments were also revealed by determination of moisture content and density of the jute particles. It is determined that alkali treatment increase hydrophilicity of jute particles with providing reactive hydroxyl groups by partially removal of surface impurities as supported by FTIR analysis. This surface cleaning is also confirmed by SEM which shows surface fibrillation of AJ particles. The crystallinity index of the jute particles increased with the surface treatments by improving the crystallite packing order. Thermal stability of the jute particles changed after all of the surface treatments. According to the findings obtained from surface characterizations and physical tests, the most hydrophobic surface was achieved after fluorocarbon treatment (with alkali pretreatment) by providing the highest C/O ratio on the surface of the jute particles and reduced moisture content, which can be benefits in short fiber or particulate reinforced composite manufacturing by preventing agglomeration of fillers.

Modeling the tensile behaviour of needle punched nonwoven geotextiles

Purpose – The purpose of this paper is to propose a theoretical model to predict the mechanical behaviour of needle punched heavy geotextiles in uniaxial tensile test.Design/methodology/approach – The model was constructed using theory of layered composite materials and finite element method. The properties of a reference fabric were used as initial data in theoretical calculations and a commercially available finite element program was chosen to carry out stress analysis. A comparison is made between theoretical calculations and experimental data to evaluate the deformation mechanism of geotextile fabrics in uniaxial tensile test.Findings – The results indicate that compatible data were predicted in terms of stress values and stress distribution of fabrics. The inconstant lateral contraction of nonwoven fabrics in tensile test is also successfully simulated by the model. However, in the case of elongations, the model could not predict the strains of heavy geotextiles accurately.Originality/value – The st...

Effect of polypropylene fiber cross sectional shapes on some structural/mechanical fiber properties and compressibility behaviour of plain knitted fabrics

Synthetic fibers are generally produced with circular cross sectional shapes. Other cross sectional shaped fibers such as trilobal, triangular, hollow and pentagonal fibers are also produced to improve some properties of fibers and fabrics such as lustre, handle, wicking rate, strength, stiffness and bulkiness. In this research we aimed to investigate compressional behaviours of fabrics knitted from polypropylene fibers having three different cross sectional shapes; namely circular, trilobal and triangular. Morphological, structural and mechanical properties of produced fibers were evaluated by using scanning electron microscopy, X-ray diffractometry, differential scanning calorimetry and tensile tester, respectively. In terms of structural and mechanical properties, no significant differences were found related to fiber cross sectional shapes. Then, plain knitted farbrics were produced and compressional properties of these fabrics were investigated. Fabrics knitted from trilobal fibers showed the highest compressibility properties and it is followed by fabrics which are produced from triangular and circular fibers.

Construction of polypropylene composite multifilaments filled with sodium perborate trihydrate-treated jute microparticles

Abstract Polypropylene composite multifilaments filled with surface-treated jute microparticles were successfully spun by melt spinning. To enhance the particle distribution, jute particleos were treated with 5–20% (w/v) aqueous solutions of sodium perborate trihydrate (SP). X-ray photoelectron spectroscopy (XPS) was used to confirm the surface treatment. XPS analysis indicated that the treatments improved the hydrophobicity of the jute by means of increasing the carbon/oxygen ratio of the surface; thus, the maximum increment was achieved after 10% (w/v) SP treatment. After determining the optimum SP concentration, the spinning of polypropylene composite multifilaments containing 0.3–1.4 wt% jute particles was employed. Differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA) revealed the nucleating agent effect of the particles during crystallization in the filaments. The addition of fillers did not result in significant changes in the functional groups of polypropylene. The main output of this research is that polypropylene multifilaments incorporating 1.4 wt% jute particles presented the highest moisture absorption and hydrophilic character as determined by TGA, moisture content, and vertical wicking tests. It was concluded that particle content >0.3 wt% showed a tendency to agglomerate in the filament. Consequently, this study provided a new polypropylene filament having moisture absorbability performance, which can create potential applications in the textile industry.