The effect of stacking sequence and circumferential ply drop locations on the mechanical response of type IV composite pressure vessels subjected to internal pressure: A numerical and experimental study
Published 2022 View Full Article
- Home
- Publications
- Publication Search
- Publication Details
Title
The effect of stacking sequence and circumferential ply drop locations on the mechanical response of type IV composite pressure vessels subjected to internal pressure: A numerical and experimental study
Authors
Keywords
-
Journal
COMPOSITE STRUCTURES
Volume 294, Issue -, Pages 115585
Publisher
Elsevier BV
Online
2022-04-29
DOI
10.1016/j.compstruct.2022.115585
References
Ask authors/readers for more resources
Related references
Note: Only part of the references are listed.- Design of a 70 MPa type IV hydrogen storage vessel using accurate modeling techniques for dome thickness prediction
- (2020) Qian Zhang et al. COMPOSITE STRUCTURES
- Experimental and analytical analysis on the stacking sequence of composite pressure vessels
- (2020) M. Nebe et al. COMPOSITE STRUCTURES
- Analysis on the mechanical response of composite pressure vessels during internal pressure loading: FE modeling and experimental correlation
- (2020) M. Nebe et al. COMPOSITES PART B-ENGINEERING
- Acoustic emission based prediction of local stress exposure
- (2019) Markus G.R. Sause et al. COMPOSITES SCIENCE AND TECHNOLOGY
- Stochastic prediction of burst pressure in composite pressure vessels
- (2018) Roham Rafiee et al. COMPOSITE STRUCTURES
- Application of Complementary Optical Methods for Strain Investigation in Composite High Pressure Vessel
- (2018) Paweł Gąsior et al. COMPOSITE STRUCTURES
- Design and analysis of filament-wound composite pressure vessels based on non-geodesic winding
- (2018) Lei Zu et al. COMPOSITE STRUCTURES
- Evaluation of the mechanical performance of a composite multi-cell tank for cryogenic storage: Part II – Experimental assessment
- (2018) Ilias G. Tapeinos et al. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
- Micromechanics-based progressive failure analysis of carbon fiber/epoxy composite vessel under combined internal pressure and thermomechanical loading
- (2016) Liang Wang et al. COMPOSITES PART B-ENGINEERING
- Continuum damage modeling and progressive failure analysis of carbon fiber/epoxy composite pressure vessel
- (2015) Liang Wang et al. COMPOSITE STRUCTURES
- Acoustic emission analysis of composite pressure vessels under constant and cyclic pressure
- (2015) H.Y. Chou et al. COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING
- Optimisation of 700 bar type IV hydrogen pressure vessel considering composite damage and dome multi-sequencing
- (2015) D. Leh et al. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
- A progressive failure analysis of a 700-bar type IV hydrogen composite pressure vessel
- (2015) D. Leh et al. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
- 700 bar type IV high pressure hydrogen storage vessel burst – Simulation and experimental validation
- (2015) Juan Pedro Berro Ramirez et al. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
- Applied hydrogen storage research and development: A perspective from the U.S. Department of Energy
- (2015) Kathleen O’Malley et al. JOURNAL OF ALLOYS AND COMPOUNDS
- Optimization of carbon fiber usage in Type 4 hydrogen storage tanks for fuel cell automobiles
- (2013) H.S. Roh et al. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
- Micromechanical damage modeling and multiscale progressive failure analysis of composite pressure vessel
- (2012) P.F. Liu et al. COMPUTATIONAL MATERIALS SCIENCE
- Evaluation of modeling techniques for a type III hydrogen pressure vessel (70 MPa) made of an aluminum liner and a thick carbon/epoxy composite for fuel cell vehicles
- (2012) Dae-Sung Son et al. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY
Find Funding. Review Successful Grants.
Explore over 25,000 new funding opportunities and over 6,000,000 successful grants.
ExploreFind the ideal target journal for your manuscript
Explore over 38,000 international journals covering a vast array of academic fields.
Search