Groo et al., 2021 - Google Patents
Laser induced graphene for in situ damage sensing in aramid fiber reinforced compositesGroo et al., 2021
View PDF- Document ID
- 16237668848426680808
- Author
- Groo L
- Nasser J
- Inman D
- Sodano H
- Publication year
- Publication venue
- Composites Science and Technology
External Links
Snippet
In situ monitoring of strain and damage in fiber-reinforced composites provides critical information regarding the state of the material without requiring the structure to be removed from operation. In order to avoid the use of complex, heavy, and bulky sensor networks to …
- 239000004760 aramid 0 title abstract description 104
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Groo et al. | Laser induced graphene for in situ damage sensing in aramid fiber reinforced composites | |
| Groo et al. | Laser induced graphene in fiberglass-reinforced composites for strain and damage sensing | |
| Wang et al. | Structure dependent properties of carbon nanomaterials enabled fiber sensors for in situ monitoring of composites | |
| Gao et al. | Sensing of damage mechanisms in fiber‐reinforced composites under cyclic loading using carbon nanotubes | |
| Groo et al. | Transfer printed laser induced graphene strain gauges for embedded sensing in fiberglass composites | |
| Steinke et al. | Laser induced graphene for in-situ ballistic impact damage and delamination detection in aramid fiber reinforced composites | |
| Boztepe et al. | Novel carbon nanotube interlaminar film sensors for carbon fiber composites under uniaxial fatigue loading | |
| Nam et al. | Mechanical properties and piezoresistive sensing capabilities of FRP composites incorporating CNT fibers | |
| Romhany et al. | Interlaminar fatigue crack growth behavior of MWCNT/carbon fiber reinforced hybrid composites monitored via newly developed acoustic emission method. | |
| Datta et al. | Buckypaper embedded self-sensing composite for real-time fatigue damage diagnosis and prognosis | |
| Chen et al. | Single multifunctional MXene-coated glass fiber for interfacial strengthening, damage self-monitoring, and self-recovery in fiber-reinforced composites | |
| Wang et al. | An embedded non-intrusive graphene/epoxy broadband nanocomposite sensor co-cured with GFRP for in situ structural health monitoring | |
| Rabbi et al. | Strain and damage sensing in additively manufactured CB/ABS polymer composites | |
| Wang et al. | Perforated piezoresistive film-based flexible bidirectional strain sensors for large bending deformation detection and health monitoring of glass fiber-reinforced polymers | |
| Song et al. | Carbon nanotube sensor thread for distributed strain and damage monitoring on IM7/977-3 composites | |
| Zhang et al. | Embedded Pt-PVDF sensor without compromising mechanical properties of GFRP for on-line sensing | |
| Hao et al. | Carbon nanotubes for defect monitoring in fiber-reinforced polymer composites | |
| Lincon et al. | High strain rate damage sensing in intra-ply hybrid composites under dynamic shear loading | |
| Wan et al. | Low-velocity impact damage localization of GF/epoxy laminates by the embedded MWCNT@ GF sensor network | |
| Ahmed et al. | Additive manufacturing of flexible strain sensors based on smart composites for structural health monitoring with high accuracy and fidelity | |
| On et al. | Bimodal coaxial fiber sensor for simultaneous strain and temperature sensing for composite manufacturing process | |
| Doshi et al. | Self-sensing carbon nanotube composites: processing and characterization | |
| Raghavan et al. | Structural health monitoring using carbon nanotube (CNT) enhanced composites | |
| Han et al. | The synergetic relation of flexural strain behaviors and electrical signals of carbon nanotube-based polymer laminates | |
| Nauman et al. | Online measurement of structural deformations in composites |