Your search keyword '"Benedictus R."' showing total 8 results

1. Study of the fire resistant behavior of unfilled and carbon nanofibers reinforced polybenzimidazole coating for structural applications

Author

Iqbal, H.M.S., Stec, A.A., Patel, P., Bhowmik, S., and Benedictus, R.

Subjects

carbon nanofibers, fire resistant coating, structural composite

Abstract

With increasing interest in epoxy-based carbon fiber composites for structural applications, it is important to improve the fire resistant properties of these materials. The fire resistant performance of these materials can be improved either by using high performance epoxy resin for manufacturing carbon fiber composite or by protecting the previously used epoxy-based composite with some fire resistant coating. In this context, work is carried out to evaluate the fire resistance performance of recently emerged high performance polybenzimidazole (PBI) when used as a coating material. Furthermore, the effect of carbon nanofibers (CNFs) on fire resistant properties of inherently flame retardant PBI coating was studied. Thermogravimetric analysis of carbon/epoxy composite, unfilled PBI and nano-filled PBI shows that the carbon/epoxy composite maintained its thermal stability up to a temperature of 400°C and afterwards showed a large decrease in mass, while both unfilled PBI and nano-filled PBI have shown thermal stability up to a temperature of 575°C corresponding to only 11% weight loss. Cone calorimeter test results show that unfilled PBI coating did not improve the fire retardant performance of carbon/epoxy composite. Conversely, nano-filled PBI coating has shown a significant improvement in fire retardant performance of the carbon/epoxy composite in terms of increased ignition time, reduced average and peak heat release rate and reduced smoke and carbon monoxide emission. These results indicate that addition of carbon nanofibers to inherently flame retardant coating can significantly be helpful for improving the fire resistance performance of composite materials even with low coating thickness.

Published

2013

2. Optical Coherence Tomography for the Study of Polymer and Polymer Matrix Composites

Author

Liu, P., primary, Groves, R. M., additional, and Benedictus, R., additional

Published

2014

3. Study of the fire resistant behavior of unfilled and carbon nanofibers reinforced polybenzimidazole coating for structural applications

Author

Iqbal, H.M.S. (author), Stec, A.A. (author), Patel, P. (author), Bhowmik, S. (author), Benedictus, R. (author), Iqbal, H.M.S. (author), Stec, A.A. (author), Patel, P. (author), Bhowmik, S. (author), and Benedictus, R. (author)

Abstract

With increasing interest in epoxy-based carbon fiber composites for structural applications, it is important to improve the fire resistant properties of these materials. The fire resistant performance of these materials can be improved either by using high performance epoxy resin for manufacturing carbon fiber composite or by protecting the previously used epoxy-based composite with some fire resistant coating. In this context, work is carried out to evaluate the fire resistance performance of recently emerged high performance polybenzimidazole (PBI) when used as a coating material. Furthermore, the effect of carbon nanofibers (CNFs) on fire resistant properties of inherently flame retardant PBI coating was studied. Thermogravimetric analysis of carbon/epoxy composite, unfilled PBI and nano-filled PBI shows that the carbon/epoxy composite maintained its thermal stability up to a temperature of 400°C and afterwards showed a large decrease in mass, while both unfilled PBI and nano-filled PBI have shown thermal stability up to a temperature of 575°C corresponding to only 11% weight loss. Cone calorimeter test results show that unfilled PBI coating did not improve the fire retardant performance of carbon/epoxy composite. Conversely, nano-filled PBI coating has shown a significant improvement in fire retardant performance of the carbon/epoxy composite in terms of increased ignition time, reduced average and peak heat release rate and reduced smoke and carbon monoxide emission. These results indicate that addition of carbon nanofibers to inherently flame retardant coating can significantly be helpful for improving the fire resistance performance of composite materials even with low coating thickness., Aerospace Structures & Materials, Aerospace Engineering

Published

2013

4. Study of the fire resistant behavior of unfilled and carbon nanofibers reinforced polybenzimidazole coating for structural applications

Author

Iqbal, H. M. S., Stec, Anna A, Patel, Parina, Bhowmik, S., Benedictus, R., Iqbal, H. M. S., Stec, Anna A, Patel, Parina, Bhowmik, S., and Benedictus, R.

Abstract

With increasing interest in epoxy-based carbon fiber composites for structural applications, it is important to improve the fire resistant properties of these materials. The fire resistant performance of these materials can be improved either by using high performance epoxy resin for manufacturing carbon fiber composite or by protecting the previously used epoxy-based composite with some fire resistant coating. In this context, work is carried out to evaluate the fire resistance performance of recently emerged high performance polybenzimidazole (PBI) when used as a coating material. Furthermore, the effect of carbon nanofibers (CNFs) on fire resistant properties of inherently flame retardant PBI coating was studied. Thermogravimetric analysis of carbon/epoxy composite, unfilled PBI and nano-filled PBI shows that the carbon/epoxy composite maintained its thermal stability up to a temperature of 400°C and afterwards showed a large decrease in mass, while both unfilled PBI and nano-filled PBI have shown thermal stability up to a temperature of 575°C corresponding to only 11% weight loss. Cone calorimeter test results show that unfilled PBI coating did not improve the fire retardant performance of carbon/epoxy composite. Conversely, nano-filled PBI coating has shown a significant improvement in fire retardant performance of the carbon/epoxy composite in terms of increased ignition time, reduced average and peak heat release rate and reduced smoke and carbon monoxide emission. These results indicate that addition of carbon nanofibers to inherently flame retardant coating can significantly be helpful for improving the fire resistance performance of composite materials even with low coating thickness. © 2013 John Wiley & Sons, Ltd.

Published

2013

5. Thermal, morphological, and mechanical characterization of novel carbon nanofiber‐filled bismaleimide composites

Author

Faraz, M. I., primary, Bhowmik, S., additional, De Ruijter, C., additional, Laoutid, F., additional, Benedictus, R., additional, Dubois, Ph., additional, Page, J. V. S., additional, and Jeson, S., additional

Published

2010

6. Effect of plasma treatment and electron beam radiations on the strength of nanofilled adhesive-bonded joints

Author

Iqbal, H.M.S., primary, Bhowmik, S., additional, Poulis, J.A., additional, and Benedictus, R., additional

Published

2010

7. Fatigue crack growth in fibre metal laminates under selective variable‐amplitude loading

Author

PLOKKER, H. M., primary, KHAN, S. U., additional, ALDERLIESTEN, R. C., additional, and BENEDICTUS, R., additional

Published

2009

8. Crack closure in fibre metal laminates

Author

PLOKKER, H.M., primary, ALDERLIESTEN, R.C., additional, and BENEDICTUS, R., additional

Published

2007