Development of high bending stresses due to a sudden gust of wind is a significant cause for the failure of wind turbine blades. Self-healing provides a fool proof safety measure against catastrophic failure by healing the damages autonomously, as they originate. In this study, biomimetic, vascular channel type of self-healing was implemented in glass fiber reinforced polymer matrix composite that is used in wind turbine blades. Microscale borosilicate tubes are used to supply the healing agent to the epoxy type of thermoset polymer matrix, and the healing was very effective. However, 25% decrease in tensile strength and 9% decrease in three-point bending flexural strength were imminent with the inclusion of a single layer of vascular vessels in the composite material. Three-point bending tests were performed before and after self-healing of flat specimens to find the extent of recovery of flexural strength on using vascular channel type of self-healing. An average recovery of flexural strength of 84.52% was obtained using a single layer of vascular vessels on the tensile stress side of three-point bending. Breakage and bleeding of the healing agent within the composite specimens during three-point bending tests were observed in real-time. Based on the encouraging findings, the above self-healing feature was successfully implemented in a prototype wind turbine.
Skip Nav Destination
Article navigation
September 2017
Research-Article
Self-Healing of Wind Turbine Blades Using Microscale Vascular Vessels
Arun Kumar Koralagundi Matt,
Arun Kumar Koralagundi Matt
Department of Mechanical Engineering,
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: koralag2@uwm.edu
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: koralag2@uwm.edu
Search for other works by this author on:
Saman Beyhaghi,
Saman Beyhaghi
Department of Mechanical Engineering,
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: beyhagh2@uwm.edu
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: beyhagh2@uwm.edu
Search for other works by this author on:
Ryoichi S. Amano,
Ryoichi S. Amano
Life Fellow ASME
Department of Mechanical Engineering,
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: amano@uwm.edu
Department of Mechanical Engineering,
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: amano@uwm.edu
Search for other works by this author on:
Jie Guo
Jie Guo
Department of Mechanical Engineering,
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: jieguo@uwm.edu
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: jieguo@uwm.edu
Search for other works by this author on:
Arun Kumar Koralagundi Matt
Department of Mechanical Engineering,
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: koralag2@uwm.edu
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: koralag2@uwm.edu
Saman Beyhaghi
Department of Mechanical Engineering,
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: beyhagh2@uwm.edu
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: beyhagh2@uwm.edu
Ryoichi S. Amano
Life Fellow ASME
Department of Mechanical Engineering,
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: amano@uwm.edu
Department of Mechanical Engineering,
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: amano@uwm.edu
Jie Guo
Department of Mechanical Engineering,
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: jieguo@uwm.edu
University of Wisconsin-Milwaukee,
115 E. Reindl Way,
Glendale, WI 53212
e-mail: jieguo@uwm.edu
1Corresponding author.
Contributed by the Advanced Energy Systems Division of ASME for publication in the JOURNAL OF ENERGY RESOURCES TECHNOLOGY. Manuscript received November 12, 2016; final manuscript received February 20, 2017; published online March 16, 2017. Assoc. Editor: Bengt Sunden.
J. Energy Resour. Technol. Sep 2017, 139(5): 051208 (7 pages)
Published Online: March 16, 2017
Article history
Received:
November 12, 2016
Revised:
February 20, 2017
Citation
Matt, A. K. K., Beyhaghi, S., Amano, R. S., and Guo, J. (March 16, 2017). "Self-Healing of Wind Turbine Blades Using Microscale Vascular Vessels." ASME. J. Energy Resour. Technol. September 2017; 139(5): 051208. https://doi.org/10.1115/1.4036052
Download citation file:
Get Email Alerts
Cited By
Related Articles
Mechanical and Heat Transfer Performance Investigation of High Thermal Conductivity, Commercially Available Polymer Composite Materials for Heat Exchange in Electronic Systems
J. Thermal Sci. Eng. Appl (September,2017)
Surface Pressure Distribution on a Blade of a 10 m Diameter HAWT (Field Measurements versus Wind Tunnel Measurements)
J. Sol. Energy Eng (May,2005)
Active Load Control for Airfoils using Microtabs
J. Sol. Energy Eng (November,2001)
Self-Healing Performance Comparison Between Two Promising Vascular Vessel Systems of the Wind Turbine Blade
J. Energy Resour. Technol (November,2019)
Related Proceedings Papers
Related Chapters
Section III: Subsections NC and ND — Class 2 and 3 Components
Companion Guide to the ASME Boiler and Pressure Vessel Code, Volume 1, Fourth Edition
Introduction and Definitions
Handbook on Stiffness & Damping in Mechanical Design
Basic Concepts
Design & Analysis of ASME Boiler and Pressure Vessel Components in the Creep Range