International Conference on Manufacturing Research (ICMR 2013)
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11th International Conference on Manufacturing Research (ICMR2013)
19th - 20th September 2013
Editors: Essam Shehab, Peter Ball, Benny Tjahjono
Organised by: Cranfield University
ISBN: 978-1-907413-23-0
ISSN: 2053-3373
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Browsing International Conference on Manufacturing Research (ICMR 2013) by Author "Abhyankar, Hrushikesh"
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Item Open Access Effect of fibre treatments on mechanical properties of flax/tannin composites(Cranfield University Press, 2013-09-19) Zhu, Jinchun; Zhu, Huijun; Abhyankar, Hrushikesh; Njuguna, JamesDue to the inherent environmental benefits of using natural resin (tannin) and natural fibre (flax), flax/tannin composites could be potentially used for vehicle applications. One of the main limitations is the hydrophilic property of flax, resulting in the poor fibre/hydrophobic matrix interface quality. Alkali, acetylation, silane treatment and enzymatic treatment were selected to modify non-woven flax mats to prepare the composites. The fibre morphology was studied through scanning electronic microscopes (SEM). The effects of fibre pre-treatments on dynamic and static mechanical properties of composites were investigated through adequate experiments, such as dynamic mechanical analysis (DMA) and static tensile testing. The modified rougher fibre surface broadened the glass transition peaks of composites due to the improved surface adhesion. However, there is no big improvement of tensile strength after modifications. The pure NaOH (sodium hydroxide) treated composites remain the tensile properties and offer good flax/tannin wettability.Item Open Access The effect of temperature changes on to quasi-static tensile and flexural performance of glass fibre reinforced PA66 composites(Cranfield University Press, 2013-09-19) Butterworth, Ian; Abhyankar, Hrushikesh; Westwood, Keith; Njuguna, James; Brighton, James; Mouti, ZakariaA significant method of reducing CO2 emissions in road vehicles is to reduce the vehicle mass. One means in which this can be achieved is to adopt lightweight materials such as thermoplastic composites. Thermoplastics offer advantages in term of weight when compared to conventional steel and aluminium casting. In this study thermal mechanical testing has been conducted on two types of commercial polyamide 66 (PA66) with 35 wt.% short glass fibre reinforcement. One of the materials was impact modified with an elastomer to increase material toughness. Experimental results showed both the reinforced PA66 materials to be temperature dependent. All test results demonstrated the trade-off in the mechanical properties of the two materials especially the impact modified. PA66 with 35 wt.% short glass fibre exhibits the best tensile strength, flexural strength and modulus for each temperature tested. Whereas the impact modified PA66 with 35 wt.% short glass fibre exhibits the higher strain and toughness for each temperature tested.Item Open Access Mechanical properties of three-phase polyamide 6 nanocomposites(Cranfield University Press, 2013-09-19) Gendre, Laura; Abhyankar, Hrushikesh; Njuguna, James; Ermini, ValentinaThis work focus on the mechanical properties of three-phase nanocomposites using multiscale reinforcements. The influence of the nano-fillers content, as well as the temperature were studied. Polyamide-6 reinforced with short glass fibre 30 wt.% and with an addition of nanoclay (montmorillonite) and/or nanosilica (SiO2) were tested in order to characterise their tensile properties at room temperature and at 65oC just above the polyamide 6 glass transition temperature. SEM analysis were conducted on the fracture surface of the tensile bars. SEM investigations showed the importance of the interaction matrix/filler for the material behaviour. Our study also shows that the increase of OMMT percentage in polyamide-6/glass fibre composite made the material more brittle and had a negative effect on the tensile properties. Further, for the silica-based nanocomposites, an optimum was found for a nanofillers content of 1wt.%.