Automated Tow Placed LARC™-PETI-5 Composites
| Autor: | H L Belvin, T H Hou, N J Johnston |
|---|---|
| Rok vydání: | 2001 |
| Předmět: |
Toughness
Materials science Fabrication Polymers and Plastics Organic Chemistry 02 engineering and technology 021001 nanoscience & nanotechnology 020303 mechanical engineering & transports Compressive strength 0203 mechanical engineering Flexural strength Autoclave (industrial) Ultimate tensile strength Materials Chemistry Adhesive Composite material 0210 nano-technology Damage tolerance |
| Zdroj: | High Performance Polymers. 13:323-336 |
| ISSN: | 1361-6412 0954-0083 |
| DOI: | 10.1088/0954-0083/13/4/310 |
| Popis: | LARC™-PETI-5 is a PhenylEthynyl-Terminated Imide resin developed at NASA Langley Research Center (LARC) during the 1990s. It offers a combination of attractive composite and adhesive properties. IM7/LARC™-PETI-5 composites exhibit thermal and thermo-oxidative stability typical of polyimides, superior chemical resistance and processability, excellent mechanical properties, toughness and damage tolerance. It was selected for study in the High Speed Research program aimed at developing technologies for a future supersonic aircraft, the High Speed Civil Transport, with a projected life span of 60 000 h at a cruise speed up to March 2.4. Robust autoclave processing cycles for LARC™-PETI-5 composites have been thoroughly designed and demonstrated, which involved hand lay-up of solvent-ladened ‘wet’ prepregs. However, this type of processing is not only costly but also environmentally unfriendly. Volatile management and shrinkage could become serious problems in the fabrication of large complex airframe structural subcomponents. Robotic tow placement technology utilizing ‘dry’ material forms represents a new fabrication process which overcomes these deficiencies. This work evaluates and compares mechanical properties of composites fabricated by heated head automated tow placement (dry process) with those obtained by hand lay-up/autoclave fabrication (wet process). Thermal and rheological properties of the robotically as-placed uncured composites were measured. A post-cure cycle was designed due to the requirement of the PETI-5 resin for a 370 °C/1 h hold to reach full cure, conditions which cannot be duplicated during heated head robotic placement. Mechanical properties such as 0° flexural strength and modulus, open hole tensile and compressive strength and moduli, reduced section compression dogbone compressive strength, and modified zippora-medium small (MZ-MS) tensile and compressive properties were obtained on the post-cured panels. These properties compared favourably with those obtained from the wet process. |
| Databáze: | OpenAIRE |
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