Your search keyword '"Poulaert, Bernard"' showing total 6 results

1. Thermoplastic as carrier for delivering carbon nanotubes and layered clay in epoxy resin for composite applications

Author

UCL - SST/IMCN/BSMA - Bio and soft matter, Devaux, Jacques, Daoust, Daniel, Gaigneaux, Eric, Pardoen, Thomas, Poulaert, Bernard, Bailly, Christian, Cinquin, Jacques, Verpoest, Ignaas, Dumont, David, UCL - SST/IMCN/BSMA - Bio and soft matter, Devaux, Jacques, Daoust, Daniel, Gaigneaux, Eric, Pardoen, Thomas, Poulaert, Bernard, Bailly, Christian, Cinquin, Jacques, Verpoest, Ignaas, and Dumont, David

Abstract

Thermoplastic and nanofiller additives have already shown their potential benefit on mechanical, thermal or electrical properties of composites. An original method to incorporate simultaneously a thermoplastic phase and nanoparticles in laminates processed by resin transfer molding is proposed in the present study. Introduction of nanocomposite prepared by melt blending in the dry composite preform intends to deliver both additives in the thermoset matrix during the process. This thesis investigates the concept to determine if a soluble thermoplastic can be exploited to disperse and distribute nanofillers in epoxy resin and understand the key parameters controlling the mechanism. First, this work focuses on solubility of poly(ether sulfone) and phenoxy in epoxide and diamine precursors and in reactive formulations like RTM6 resin qualified for aeronautics. Composition gradients and microstructures induced by these thermoplastics in epoxy resin are also detailed. Then, the second part of the study demonstrates that nanocomposite filaments prepared with unmodified multiwalled carbon nanotubes or organomodified layered clay allow to distribute both thermoplastic and nanofillers in epoxy resin. Interdiffusion occurring during thermal treatment leads to thermoplastic swelling by the resin precursors. Identical distribution profiles evidenced for thermoplastic and nanofillers in the resin shows that these amorphous polymers act as carriers for delivery of nanoparticles into epoxy resin. Once reaction induced phase separation takes place, a microstructure gradient is generated with, locally, thermoplastic nodules and nanofillers being dispersed in the epoxy resin continuous phase., (FSA 3) -- UCL, 2013

Published

2013

2. COMPOSITE RING MADE OF 3D WOVEN PREFORM INJECTED BY RTM:FROM DESIGN TO FULL SCALE TESTING.

Author

Fischer, Hermann, Poulaert, Bernard, Magerman, Jean-Louis, Bargeton, Etienne, de Lumley, Thibault, Valcke, André-Marie, Atkins, Thierry, Gokce, Hakan, and Bryn, Leon

Subjects

COMPOSITE materials, CRYOGENICS, TRANSFER molding, DEAD loads (Mechanics), CARBON fiber-reinforced plastics

Abstract

As part of the European Space Agency (ESA) Future Launchers Preparatory Programme (FLPP), SONACA (BELGIUM) and BRM (USA) companies joined their competences to develop a new concept of structural European launcher cryogenic upper inter-stage composite ring. This challenging program targeted the replacement of an ARIANE traditional aluminum ring by a lighter and affordable multi-functional composite structure. The ARIANE 5 aluminum specification was used as the basis of the design concepts, with adaptation to a future launcher 4.3 m diameter. After a preliminary design phase, involving selection of different manufacturing routes, material and processes by elementary tests made at coupon level, the 3D orthogonal weaving process was selected as the best candidate to realize a full scale ring demonstrator. The structure was designed, stressed and verified by test by SONACA, and the 3D weaving was optimized in close collaboration with BRM. Five 90° segment carbon fiber dry preforms were produced by BRM using the most advanced weaving automated technology. All these segments were injected by SONACA using their expertise in RTM process. The parts were controlled both geometrically and wrt internal defects by NDT. A 30° segment was successfully submitted to five static load cases up to failure, showing a TRL of 5. Four 90° segments were assembled by CFRP splices to exhibit a full ring demonstrator. [ABSTRACT FROM AUTHOR]

Published

2016

3. Le matériau polymère : de l'isolant au conducteur thermique

Author

Poulaert, Bernard, UCL - FSA/MAPR - Département des sciences des matériaux et des procédés, Issi, Jean-Paul, and Legras, Roger

Subjects

Conductivité thermique, Fibres, Noir de carbone, Polymères

Abstract

(FSA 3) -- UCL, 1987

Published

1987

4. Le matériau polymère : de l'isolant au conducteur thermique

Author

UCL - FSA/MAPR - Département des sciences des matériaux et des procédés, Issi, Jean-Paul, Legras, Roger, Poulaert, Bernard, UCL - FSA/MAPR - Département des sciences des matériaux et des procédés, Issi, Jean-Paul, Legras, Roger, and Poulaert, Bernard

Abstract

(FSA 3) -- UCL, 1987

Published

1987

5. Tailoring the thermal conductivity of polymers

Author

UCL - FSA/MAPR - Département des sciences des matériaux et des procédés, Issi, Jean-Paul, Nysten, Bernard, Jonas, Alain M., Demain, Axel, Piraux, Luc, Poulaert, Bernard, 21st Thermal Conductivity International Conference, UCL - FSA/MAPR - Département des sciences des matériaux et des procédés, Issi, Jean-Paul, Nysten, Bernard, Jonas, Alain M., Demain, Axel, Piraux, Luc, Poulaert, Bernard, and 21st Thermal Conductivity International Conference

Published

1989

6. Thermoplastic as carrier for delivering carbon nanotubes and layered clay in epoxy resin for composite applications

Author

Dumont, David, UCL - SST/IMCN/BSMA - Bio and soft matter, Devaux, Jacques, Daoust, Daniel, Gaigneaux, Eric, Pardoen, Thomas, Poulaert, Bernard, Bailly, Christian, Cinquin, Jacques, and Verpoest, Ignaas

Abstract

Thermoplastic and nanofiller additives have already shown their potential benefit on mechanical, thermal or electrical properties of composites. An original method to incorporate simultaneously a thermoplastic phase and nanoparticles in laminates processed by resin transfer molding is proposed in the present study. Introduction of nanocomposite prepared by melt blending in the dry composite preform intends to deliver both additives in the thermoset matrix during the process. This thesis investigates the concept to determine if a soluble thermoplastic can be exploited to disperse and distribute nanofillers in epoxy resin and understand the key parameters controlling the mechanism. First, this work focuses on solubility of poly(ether sulfone) and phenoxy in epoxide and diamine precursors and in reactive formulations like RTM6 resin qualified for aeronautics. Composition gradients and microstructures induced by these thermoplastics in epoxy resin are also detailed. Then, the second part of the study demonstrates that nanocomposite filaments prepared with unmodified multiwalled carbon nanotubes or organomodified layered clay allow to distribute both thermoplastic and nanofillers in epoxy resin. Interdiffusion occurring during thermal treatment leads to thermoplastic swelling by the resin precursors. Identical distribution profiles evidenced for thermoplastic and nanofillers in the resin shows that these amorphous polymers act as carriers for delivery of nanoparticles into epoxy resin. Once reaction induced phase separation takes place, a microstructure gradient is generated with, locally, thermoplastic nodules and nanofillers being dispersed in the epoxy resin continuous phase. (FSA 3) -- UCL, 2013

Published

2013