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The purpose of this paper is to investigate the relationship between the formability of cotton and cotton/polyester woven fabrics and their selected properties: weft density, weave and a way of finishing. It shows how the mentioned properties influence fabric formability and analyze a statistical significance of investigated relationships.

In paper two groups of cotton and cotton/polyester woven fabrics of different structure and a way of finishing have been measured in the range of their basic structural properties as well as bending rigidity and initial Young’s modulus. Formability of investigated fabrics has been calculated on the basis of bending rigidity and initial Young’s modulus. Next, ANOVA has been performed in order to analyze the relationships between the weft density, weave and a way of finishing of woven fabrics and their formability.

The paper shows that all selected properties of woven fabrics significantly influence their formability as well as that there is statistically significant interaction between mentioned independent factors. It provides empirical results confirming that the influence of raw material composition of investigated cotton and cotton/polyester woven fabrics on the formability of fabrics is statistically insignificant.

Results of investigations can be applied for cotton and cotton-like woven fabrics.

The paper includes implications for woven fabric engineering from the point of view of achieving the expected fabric formability.

The results enables the choice of appropriate fabric for the given clothing.

This paper fulfills an identified need to study how the formability of woven fabrics can be shaped by an appropriate selection of their structure and a way of finishing.

Observes that the formability of woven fabric has a major effect on the appearance of garments, in that seams sewn from fabrics with low formability are more likely to pucker than those sewn from fabric with high formability. Describes the concept of formability and illustrates the relationship between this parameter and seam pucker, the difficulty of a particular sewing operation and the appearance of structured jackets. Notes that the formability of wool fabrics is most appropriately controlled in finishing by modifying the extensibility of the fabric. Discusses the difficulties associated with engineering, the extensibility of woven fabrics and the implications for other fabric properties, such as relaxation shrinkage.

Formability is an important property of automotive pre-coated metals (PCMs). The purpose of this study is to investigate the effect of long alkyl chains of polycarbonatediol to control the formability of polyester coatings.

Polyester resins with long alkyl chains were synthesized using different contents of polycarbonatediol. These resins were characterised by gel permeation chromatography (GPC), ¹H nuclear magnetic resonance (¹H NMR) and fourier transform infrared spectroscopy (FT-IR). The polyester coatings were characterised according to their viscoelastic behaviour, formability, flexibility and anti-corrosion property.

The tensile strength of PCM should be larger than 5.6 MPa of the compressive stress at a strain of 23.4 per cent to overcome the harsh condition of deep drawing. To analyse the formability, F_ε (forming coefficient based on strain) and F_U (forming coefficient based on strain energy) were calculated. When F_ε and F_U were larger than 1, the polyester coatings exhibited good formability.

Long alkyl chains of polycarbonatediol gave flexibility and good formability to the polyester coatings.

There are two conditions that lead to the good formability of PCM. One is tensile strength and the other is forming coefficients based on strain and strain energy.

Long alkyl chains of polyester were a major factor to improve flexibility and formability. Thus, to have good formability, the tensile strength of PCM should be larger than 5.6 MPa, and the forming coefficients should be larger than 1.

The purpose of this paper is to analyze theoretically the influence of normal stress on the formability of aluminum alloy sheets in non-linear strain paths.

Four loading modes of non-linear strain paths are investigated in detail to consider the effect of normal stress on formability of aluminum alloy sheets.

Results show that the influence of normal stress in the first stage can be ignored. However, the normal stress in the second stage enhances the formability of aluminum alloy sheets obviously. Besides, the normal stress in the second stage is found to have larger effect on forming limit stress than that in the first stage.

Maybe more experiment data should be obtained to support the theoretical findings.

This current study provides a better understanding of normal stress effect on the formability of aluminum alloy sheets in non-linear strain paths. Since the reacting stage of normal stress play important roles in normal stress effect on the formability of aluminum alloy sheets, the insight obtained in this paper will help to judge the instability of aluminum alloy sheets in complex forming processes with normal stress reacting on the sheet or tube.

This paper aims to optimize the single-point incremental forming process variables for realizing higher formability in Inconel 625 components and to plot the forming limit diagram for Inconel 625 aviation-grade superalloy.

The formability of Inconel 625 components has been measured in terms of major strain, minor strain and minimum sheet thickness. Response surface methodology with desirability function analysis has been used to achieve maximum formability. The finite element analysis has been conducted at optimal parametric setting.

The derived forming limit diagram proves that the maximum forming limit for Inconel 625 is 57.5° at the optimal parametric setting, achieved with desirability of 0.995. The outcomes of finite element analysis conducted at optimal parametric setting show excellent agreement with confirmation experiment results.

Inconel 625 superalloy is frequently used in aircraft and other high-performance applications for its superior strength.

It has been suggested that to enhance formability, higher tool rotation speed, minimum step-size, larger tooltip diameter and higher wall angle must be used. Wall angle is the governing parameter among all the parameters.

The mechanical and physical properties of fusible interlinings and fabrics depend on their constructional parameters, but fused panel properties depend on all of them. A new approach is presented for analysing the dependence of the constructional parameters of fabrics on the properties of fused panels. This study was carried out on the basis of a knowledge base for predicting the formability of fused panels made from wool fabrics suitable for upper clothes. This knowledge base was constructed using program package RETIS for machine learning from examples. This knowledge was presented in the form of regression trees. Using regression trees it is possible to predict the properties of a fused panel as well as to analyse the influence of parameters on the properties of a fused panel. Furthermore the results of analysis gained by regression trees were compared and confirmed using experimental measurements.

This paper investigates the relationships between fabric formability (a fundamental measure of fabric tailorability), bias extension and shear resistance. The experimental investigation has been performed on a range of thirty-one (fifteen pure wool, twelve wooVpolyester blends, one wooVrayon blend and three pure linen) suiting and trousering materials varying in mass per unit area from 125 to 258 g/m². Low stress mechanical properties measurements of fabric bending, shear and tensile deformations were obtained using the KES (Kawabata Evaluation System) testers. Furthermore, the 45-degree bias extension behaviour of these fabrics was measured using an Instron extensometer. Following Spivak and Treloar's analysis [12], the bias load-extension and recovery curves were analysed to obtain equivalent shear stress/strain hysteresis curves. The two measures of shear rigidity, one obtained from the KES shear hysteresis curves and the other calculated from the bias extension tests, have been compared for the series of 31 fabrics. Relationships between fabric formability (defined as the product of tensile extensibility under low load and the bending rigidity) and its shear resistance are analysed. In addition, the work also covers the investigation on the relationships between fabric shear properties and formability in bias direction.

This paper investigates the relationships between fabric formability (a fundamental measure of fabric tailorability), bias extension and shear resistance. The experimental investigation has been performed on a range of thirty-one (fifteen pure wool, twelve wool/polyester blends, one wool/rayon blend and three pure linen) suiting and trousering materials varying in mass per unit area from 125 to 258 g/m². Low stress mechanical properties measurements of fabric bending, shear and tensile deformations were obtained using the KES (Kawabata Evaluation System) testers. Furthermore, the 45-degree bias extension behaviour of these fabrics was measured using an Instron extensometer. Following Spivak and Treloar's analysis [12], the bias load-extension and recovery curves were analysed to obtain equivalent shear stress/strain hysteresis curves. The two measures of shear rigidity, one obtained from the KES shear hysteresis curves and the other calculated from the bias extension tests, have been compared for the series of 31 fabrics. Relationships between fabric formability (defined as the product of tensile extensibility under low load and the bending rigidity) and its shear resistance are analysed. In addition, the work also covers the investigation on the relationships between fabric shear properties and formability in bias direction.

A test method and instrumentation have been developed to facilitate the identification of potential appearance problems and for the development of improved fabric pressing performance. The method determines the fabric pressing performance with a greater degree of certainty than using a steam press. The weft “pressing performance” crease angle, as measured by the test method developed by CSIRO, in cooperation with IWS (Biella Technical Centre) and the Italian industries, combined with warp formability, as measured by SIROFAST, were found to be the two fabric properties most important for the prediction of the acceptability and appearance of a range of high quality men’s suits. It also appears that a good pressing performance can partly compensate for the seam pucker symptoms of low formability.

This paper aims to present a solid freeform fabrication-based in situ three-dimensional (3D) printing method. This method enables simultaneous cross-linking alginate at ambient environmental conditions (temperature and pressure) for 3D-laden construct fabrication. The fabrication feasibility and potentials in biomedical applications were evaluated.

Fabrication feasibility was evaluated as the investigation of fabrication parameters on strut formability (the capability to fabricate a cylindrical strut in the same diameter as dispensing tip) and structural stability (the capability to hold the fabricated 3D-laden construct against mechanical disturbance). Potentials in biomedical application was evaluated as the investigation on structural integrity (the capability to preserve the fabricated 3D-laden construct in cell culture condition).

Strut formability can be achieved when the flow rate of alginate suspension and nozzle travel speed are set according to the dispensing tip size, and extruded alginate was cross-linked sufficiently. A range of cross-linking-related fabrication parameters was determined for sufficient cross-link. The structural stability and structural integrity were found to be controlled by alginate composition. An optimized setting of the alginate composition and the fabrication parameters was determined for the fabrication of a desired stable scaffold with structural integrity for 14 days.

This paper reports that in situ 3D printing is an efficient method for 3D-laden construct fabrication and its potentials in biomedical application.