Zhang et al., 2013 - Google Patents
The residual compressive strength of impact-damaged sandwich structures with pyramidal truss coresZhang et al., 2013
- Document ID
- 12898767898466787390
- Author
- Zhang G
- Wang B
- Ma L
- Xiong J
- Yang J
- Wu L
- Publication year
- Publication venue
- Composite Structures
External Links
Snippet
A combined experimental and numerical study is conducted to assess the effects of impact energy, impact site and core density on the compression-after-impact (CAI) strength of pyramidal truss core sandwich structures. It is found that the severity of impact damage …
- 238000011068 load 0 abstract description 35
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Zhang et al. | The residual compressive strength of impact-damaged sandwich structures with pyramidal truss cores | |
| He et al. | Effect of structural parameters on low-velocity impact behavior of aluminum honeycomb sandwich structures with CFRP face sheets | |
| He et al. | Experimental and numerical research on the low velocity impact behavior of hybrid corrugated core sandwich structures | |
| He et al. | Low-velocity impact response and post-impact flexural behaviour of composite sandwich structures with corrugated cores | |
| He et al. | Residual flexural properties of CFRP sandwich structures with aluminum honeycomb cores after low-velocity impact | |
| Zangana et al. | Behaviour of continuous fibre composite sandwich core under low-velocity impact | |
| Mei et al. | A novel fabrication method and mechanical behavior of all-composite tetrahedral truss core sandwich panel | |
| Yang et al. | Low velocity impact behavior of carbon fibre composite curved corrugated sandwich shells | |
| He et al. | Low-velocity impact behavior of X-Frame core sandwich structures–experimental and numerical investigation | |
| Caputo et al. | Numerical study for the structural analysis of composite laminates subjected to low velocity impact | |
| Zhang et al. | Response of sandwich structures with pyramidal truss cores under the compression and impact loading | |
| Lv et al. | Low-velocity impact response of composite sandwich structure with grid–honeycomb hybrid core | |
| Steeves et al. | Collapse mechanisms of sandwich beams with composite faces and a foam core, loaded in three-point bending. Part II: experimental investigation and numerical modelling | |
| Li et al. | Repeated low-velocity impact response and damage mechanism of glass fiber aluminium laminates | |
| Asaee et al. | Low-velocity impact response of fiberglass/magnesium FMLs with a new 3D fiberglass fabric | |
| Tan et al. | Impact response of fiber metal laminate sandwich composite structure with polypropylene honeycomb core | |
| Foo et al. | A model to predict low-velocity impact response and damage in sandwich composites | |
| Caputo et al. | Numerical study of the structural behaviour of impacted composite laminates subjected to compression load | |
| Hashin et al. | A fatigue failure criterion for fiber reinforced materials | |
| Meo et al. | Numerical simulations of low-velocity impact on an aircraft sandwich panel | |
| Klaus et al. | Experimental and numerical investigations of residual strength after impact of sandwich panels | |
| Palanivelu et al. | Parametric study of crushing parameters and failure patterns of pultruded composite tubes using cohesive elements and seam, Part I: Central delamination and triggering modelling | |
| Laliberte et al. | Post-impact fatigue damage growth in fiber–metal laminates | |
| Sy et al. | Numerical simulation correlating the low velocity impact behaviour of flax/epoxy laminates | |
| Ahmadi et al. | Analytical and experimental investigation of transverse loading on grid stiffened composite panels |