TEAMER: Biofouling Analysis for Wave Energy Piston Design - Load Cell Data
Biofouling and corrosion are a major concern for all ocean-deployed components, especially when mechanical motion is involved. Triton has developed the concept of a biofouling mitigation seal as part of the piston sealing assembly for the Triton Wave Energy Converter (TSI-WEC). This mitigation seal has the purpose of preventing the formation of a biofilm on the inside of the piston cylinder. It is hypothesized that the prevention of a biofilm will reduce the amount of macro-biofouling that can occur in the piston assembly. The mitigation seal can also reduce the wear on the main dynamic seal, helping to maintain smooth operation and water-tightness. The cylinder is made from a thermoset composite epoxy, which is resistant to corrosion. However, no studies have researched the material's performance with biofouling.
Triton placed two prototype Power Take-Off (PTO) assemblies in a PNNL biofouling tank, one with a biofouling mitigation seal and one without, allowing for an evaluation of seal effectiveness at the prevention of biofouling.
In actual WEC operation, wave action would react against the piston, which would drive the linear actuator and electric generator, providing electrical power. In the test setup, this was reversed; a linear actuator was powered to drive the piston in a consistent motion within the cylinder.
There are two assemblies: one has a biofouling mitigation seal, the other (control) does not. The following data encompasses a 4 month test period, with load cells being used to monitor piston friction force.
Results from this testing will be used to improve seal design and material selection, mitigating risk of premature failure during open water testing and evaluation.
This project is part of the TEAMER RFTS 3 (request for technical support) program.
Citation Formats
Triton Systems, Inc.. (2021). TEAMER: Biofouling Analysis for Wave Energy Piston Design - Load Cell Data [data set]. Retrieved from https://dx.doi.org/10.15473/2315037.
Robertson, Tyler, Cavagnaro, Robertson, and Weicht, Linnea. TEAMER: Biofouling Analysis for Wave Energy Piston Design - Load Cell Data . United States: N.p., 01 Nov, 2021. Web. doi: 10.15473/2315037.
Robertson, Tyler, Cavagnaro, Robertson, & Weicht, Linnea. TEAMER: Biofouling Analysis for Wave Energy Piston Design - Load Cell Data . United States. https://dx.doi.org/10.15473/2315037
Robertson, Tyler, Cavagnaro, Robertson, and Weicht, Linnea. 2021. "TEAMER: Biofouling Analysis for Wave Energy Piston Design - Load Cell Data ". United States. https://dx.doi.org/10.15473/2315037. https://mhkdr.openei.org/submissions/534.
@div{oedi_6107, title = {TEAMER: Biofouling Analysis for Wave Energy Piston Design - Load Cell Data }, author = {Robertson, Tyler, Cavagnaro, Robertson, and Weicht, Linnea.}, abstractNote = {Biofouling and corrosion are a major concern for all ocean-deployed components, especially when mechanical motion is involved. Triton has developed the concept of a biofouling mitigation seal as part of the piston sealing assembly for the Triton Wave Energy Converter (TSI-WEC). This mitigation seal has the purpose of preventing the formation of a biofilm on the inside of the piston cylinder. It is hypothesized that the prevention of a biofilm will reduce the amount of macro-biofouling that can occur in the piston assembly. The mitigation seal can also reduce the wear on the main dynamic seal, helping to maintain smooth operation and water-tightness. The cylinder is made from a thermoset composite epoxy, which is resistant to corrosion. However, no studies have researched the material's performance with biofouling.
Triton placed two prototype Power Take-Off (PTO) assemblies in a PNNL biofouling tank, one with a biofouling mitigation seal and one without, allowing for an evaluation of seal effectiveness at the prevention of biofouling.
In actual WEC operation, wave action would react against the piston, which would drive the linear actuator and electric generator, providing electrical power. In the test setup, this was reversed; a linear actuator was powered to drive the piston in a consistent motion within the cylinder.
There are two assemblies: one has a biofouling mitigation seal, the other (control) does not. The following data encompasses a 4 month test period, with load cells being used to monitor piston friction force.
Results from this testing will be used to improve seal design and material selection, mitigating risk of premature failure during open water testing and evaluation.
This project is part of the TEAMER RFTS 3 (request for technical support) program.}, doi = {10.15473/2315037}, url = {https://mhkdr.openei.org/submissions/534}, journal = {}, number = , volume = , place = {United States}, year = {2021}, month = {11}}
https://dx.doi.org/10.15473/2315037
Details
Data from Nov 1, 2021
Last updated Feb 27, 2024
Submitted Feb 26, 2024
Organization
Triton Systems, Inc.
Contact
Tyler Robertson
978.856.1900
Authors
Original Source
https://mhkdr.openei.org/submissions/534Research Areas
Keywords
MHK, Marine, Hydrokinetic, energy, power, wave energy, Biofouling, WEC, wave energy converter, technology, raw data, processed data, code, MATLAB, RFTS 3, oscillating water columnDOE Project Details
Project Name Biofouling Analysis for Wave Energy Piston Design
Project Lead Lauren Ruedy
Project Number EE0008895