Tompkins et al., 1984 - Google Patents
Effects of thermal cycling on mechanical properties of graphite polyimideTompkins et al., 1984
- Document ID
- 5690048530317242636
- Author
- Tompkins S
- Williams S
- Publication year
- Publication venue
- Journal of Spacecraft and Rockets
External Links
Snippet
An experimental study to determine the effects of thermal cycling on residual mechanical properties of a graphite/polyimide composite has been conducted. Interlaminar shear, flexure, and compression strengths were measured at room temperature and 316 C on …
- 238000005382 thermal cycling 0 title abstract description 40
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Madhukar et al. | Fiber-matrix adhesion and its effect on composite mechanical properties: I. Inplane and interlaminar shear behavior of graphite/epoxy composites | |
| Ruggles-Wrenn et al. | Effect of frequency and environment on fatigue behavior of a CVI SiC/SiC ceramic matrix composite at 1200 C | |
| Tompkins et al. | Effects of thermal cycling on mechanical properties of graphite polyimide | |
| Adams et al. | Thermally induced transverse cracking in graphite-epoxy cross-ply laminates | |
| Bechel et al. | Limiting the permeability of composites for cryogenic applications | |
| Ruggles-Wrenn et al. | Effects of steam environment on creep behavior of Nextel™ 720/alumina ceramic composite at elevated temperature | |
| Shuart et al. | Compression Behavior of A= 45-Dominated Laminates with a Circular Hole or Impact Damage | |
| Longbiao | Micromechanical modeling for tensile behaviour of carbon fiber− reinforced ceramic− matrix composites | |
| Longbiao | Modeling of fatigue hysteresis loops in C/SiC composite under multiple loading stress levels | |
| Rotem | Load frequency effect on the fatigue strength of isotropic laminates | |
| Mahdavi et al. | Thermal cycling of composite laminates made of out-of-autoclave materials | |
| Aoki et al. | Mechanical performance of CF/polymer composite laminates under cryogenic conditions | |
| Sutter et al. | Comparison of autoclave and out-of-autoclave composites | |
| Reifsnider et al. | Delamination in quasi-isotropic graphite-epoxy laminates | |
| Schulte et al. | Damage mechanisms-including edge effects-in carbon fibre-reinforced composite materials | |
| Furrow et al. | Environmental effects on stitched RTM textile composites | |
| Ruggles-Wrenn et al. | Effects of steam environment on compressive creep behavior of Nextel™ 720/Alumina ceramic composite at 1200 C | |
| Haque et al. | Stress concentrations and notch sensitivity in woven ceramic matrix composites containing a circular hole—an experimental, analytical, and finite element study | |
| Lanser et al. | Tension-compression fatigue of a Nextel™ 720/alumina composite at 1200° C in air and in steam | |
| Akatsu et al. | Thermal‐shock fracture and damage resistance improved by whisker reinforcement in alumina matrix composite | |
| Le et al. | Interlaminar tensile strength of Alumina-Based Oxide/Oxide ceramic matrix composite at room temperature and 1200° C using diametral compression test method | |
| TOMPKINS et al. | Effects of thermal cycling on residual mechanical properties of C6000/PMR-15 graphite polyimide | |
| Terpiłowski et al. | A study of thermal diffusivity of carbon-epoxy and glass-epoxy composites using the modified pulse method | |
| Chawla | Effect of laminate stacking sequence on the high frequency fatigue behavior of SCS-6 fiber-reinforced Si3N4 matrix composites | |
| Van Hemelrijck et al. | The effects of motion on thermoelastic stress analysis |