Advanced TidGen Power System - Composites Structural Testing
Seawater aging response was investigated in marine-grade glass/epoxy, glass/vinyl ester, carbon/epoxy and carbon/vinyl ester composites with respect to water uptake, interlaminar shear strength, flexural strength, tensile strength, and tensile fracture surface observations. The reduction of mechanical properties was found to be higher in the initial stages which showed saturation in the longer durations of seawater immersion. The flexural strength and ultimate tensile strength (UTS) dropped by about 35% and 27% for glass/epoxy, 22% and 15% for glass/vinyl ester, 48% and 34% for carbon/epoxy 28%, and 21% carbon/vinyl ester composites respectively. The water uptake behavior of epoxy-based composites was inferior to that of the vinyl system.
This is an investigation into the mechanical properties of fiber/resin composites and the effects of water saturation on them. State of the technology research was reviewed to select candidates for further testing. Shear strength and shear modulus of different combinations of commercial fibers, resins, and coating systems were determined.
Citation Formats
ORPC Inc.. (2020). Advanced TidGen Power System - Composites Structural Testing [data set]. Retrieved from https://mhkdr.openei.org/submissions/316.
Krumpe, Andrew. Advanced TidGen Power System - Composites Structural Testing. United States: N.p., 06 Jan, 2020. Web. https://mhkdr.openei.org/submissions/316.
Krumpe, Andrew. Advanced TidGen Power System - Composites Structural Testing. United States. https://mhkdr.openei.org/submissions/316
Krumpe, Andrew. 2020. "Advanced TidGen Power System - Composites Structural Testing". United States. https://mhkdr.openei.org/submissions/316.
@div{oedi_4020, title = {Advanced TidGen Power System - Composites Structural Testing}, author = {Krumpe, Andrew.}, abstractNote = {Seawater aging response was investigated in marine-grade glass/epoxy, glass/vinyl ester, carbon/epoxy and carbon/vinyl ester composites with respect to water uptake, interlaminar shear strength, flexural strength, tensile strength, and tensile fracture surface observations. The reduction of mechanical properties was found to be higher in the initial stages which showed saturation in the longer durations of seawater immersion. The flexural strength and ultimate tensile strength (UTS) dropped by about 35% and 27% for glass/epoxy, 22% and 15% for glass/vinyl ester, 48% and 34% for carbon/epoxy 28%, and 21% carbon/vinyl ester composites respectively. The water uptake behavior of epoxy-based composites was inferior to that of the vinyl system.
This is an investigation into the mechanical properties of fiber/resin composites and the effects of water saturation on them. State of the technology research was reviewed to select candidates for further testing. Shear strength and shear modulus of different combinations of commercial fibers, resins, and coating systems were determined.}, doi = {}, url = {https://mhkdr.openei.org/submissions/316}, journal = {}, number = , volume = , place = {United States}, year = {2020}, month = {01}}
Details
Data from Jan 6, 2020
Last updated Jun 1, 2020
Submitted Jan 7, 2020
Organization
ORPC Inc.
Contact
Andrew Krumpe
603.969.4295
Authors
Original Source
https://mhkdr.openei.org/submissions/316Research Areas
Keywords
MHK, Marine, Hydrokinetic, energy, power, material properties, mechanical properties, shear strength, shear modulus, technology research, fluid forces, inertial froces, reactive forces, water immersion, testing, material selection, composite structural testing, ORPC, Ocean Renewable Power Company, structural, test, tidal, mechanical, technology, TidGen, composite, lab test, cross flow turbine, CEC, lab data, fatigue, composites, material, modeling, tensile strength, tensile fracture, flexural strengthDOE Project Details
Project Name Advanced TidGen Power System
Project Lead Yana Shininger
Project Number EE0007820