Healable Coatings as a Mechanism to Repair Leading Edge Erosion in Wind Energy

Amber M Hubbard; Matthew Korey; Meghan E Lamm; Katie Copenhaver; Jim Tobin; Vlastimil Kunc

doi:10.1002/we.70119

Healable Coatings as a Mechanism to Repair Leading Edge Erosion in Wind Energy

Amber M Hubbard
, Matthew Korey
, Meghan E Lamm
, Katie Copenhaver
, Jim Tobin
, Vlastimil Kunc

Research output: Contribution to journal › Article › peer-review

Abstract

Wind turbine blades are highly engineered structures designed to face temperature extremes and high winds. However, erosion of the blade's leading edge and subsequent repair remains a significant and costly challenge for the wind energy industry. Repair of these leading edges can lead to large amounts of downtime for the turbine and significant operational inefficiencies. In this work, the strength of adhesion and healing ability of a commercially available vitrimer (Mallinda's VITRIMAX) was compared to that of a thermoplastic resin, which has previously been demonstrated in wind energy applications (Arkema's Elium) to evaluate their efficacy as surface coatings for wind turbine blades, particularly their leading edges. Vitrimers are a class of inherently reprocessable thermosets, and it was theorized that vitrimer-based leading edge coatings could enable more robust and efficient wind turbine blades with decreased operational downtime and safer maintenance practices. It was found that the VITRIMAX adhered better to the wind blades' surfaces than both the manufacturer's paint and Elium, with increases in pull-off strength of adhesion ranging from 24% to 83% above that of the original paint. Furthermore, the VITRIMAX adhered strongly to the underlying composite of each blade with strength of adhesion values increasing in ranges from 42% to 97% above that of the original paint. Finally, the vitrimer coating showed an 88% decrease in surface roughness compared to end-of-life blade materials, and initial healing demonstrations in which coatings were manually scratched and subsequently healed exhibited an ~84.5% decrease in scratch depths.

Original language	English
Article number	e70119
Journal	Wind Energy
Volume	29
Issue number	5
DOIs	https://doi.org/10.1002/we.70119
State	Published - May 2026

Funding

This research has been funded by the U.S. Department of Energy Wind Energy Technologies Office (WETO) through the VitriEdge Repairable & Durable Vitrimer Coatings for Wind Turbine Blade Leading Edges WETO incubator project. Oak Ridge National Laboratory is operated by UT‐Battelle LLC. under Contract No. DE‐AC05‐00OR22725 with the U.S. Department of Energy. This paper describes objective technical results and analysis. Any subjective views or opinions that might be expressed in the paper do not necessarily represent the views of the U.S. Department of Energy or the US Government. The US government retains and the publisher, by accepting the article for publication, acknowledges that the US government retains a nonexclusive, paid‐up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript, or allow others to do so, for US government purposes. The authors would also like to acknowledge the Re‐Wind Network at the Georgia Institute of Technology for supplying the end‐of‐life wind turbine blades and Mallinda for supplying the VITRIMAX material. In addition, the authors would like to acknowledge Philip Gray for his assistance in generating the diagram shown in Figure 1 . This work was supported by the U.S. Department of Energy Wind Energy Technologies Office (WETO) (DE-AC05-00OR22725). This research has been funded by the U.S. Department of Energy Wind Energy Technologies Office (WETO) through the VitriEdge Repairable & Durable Vitrimer Coatings for Wind Turbine Blade Leading Edges WETO incubator project. Oak Ridge National Laboratory is operated by UT-Battelle LLC. under Contract No. DE-AC05-00OR22725 with the U.S. Department of Energy. This paper describes objective technical results and analysis. Any subjective views or opinions that might be expressed in the paper do not necessarily represent the views of the U.S. Department of Energy or the US Government. The US government retains and the publisher, by accepting the article for publication, acknowledges that the US government retains a nonexclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript, or allow others to do so, for US government purposes. The authors would also like to acknowledge the Re-Wind Network at the Georgia Institute of Technology for supplying the end-of-life wind turbine blades and Mallinda for supplying the VITRIMAX material. In addition, the authors would like to acknowledge Philip Gray for his assistance in generating the diagram shown in Figure 1. This work was supported by the U.S. Department of Energy Wind Energy Technologies Office (WETO) (DE‐AC05‐00OR22725).

Keywords

functional coatings
healable resins
leading edges
vitrimers
wind energy

Access to Document

10.1002/we.70119

Cite this

@article{02c62a0bd440415b8846af5ef8db2c79,

title = "Healable Coatings as a Mechanism to Repair Leading Edge Erosion in Wind Energy",

abstract = "Wind turbine blades are highly engineered structures designed to face temperature extremes and high winds. However, erosion of the blade's leading edge and subsequent repair remains a significant and costly challenge for the wind energy industry. Repair of these leading edges can lead to large amounts of downtime for the turbine and significant operational inefficiencies. In this work, the strength of adhesion and healing ability of a commercially available vitrimer (Mallinda's VITRIMAX) was compared to that of a thermoplastic resin, which has previously been demonstrated in wind energy applications (Arkema's Elium) to evaluate their efficacy as surface coatings for wind turbine blades, particularly their leading edges. Vitrimers are a class of inherently reprocessable thermosets, and it was theorized that vitrimer-based leading edge coatings could enable more robust and efficient wind turbine blades with decreased operational downtime and safer maintenance practices. It was found that the VITRIMAX adhered better to the wind blades' surfaces than both the manufacturer's paint and Elium, with increases in pull-off strength of adhesion ranging from 24\% to 83\% above that of the original paint. Furthermore, the VITRIMAX adhered strongly to the underlying composite of each blade with strength of adhesion values increasing in ranges from 42\% to 97\% above that of the original paint. Finally, the vitrimer coating showed an 88\% decrease in surface roughness compared to end-of-life blade materials, and initial healing demonstrations in which coatings were manually scratched and subsequently healed exhibited an \textasciitilde{}84.5\% decrease in scratch depths.",

keywords = "functional coatings, healable resins, leading edges, vitrimers, wind energy",

author = "Amber M Hubbard and Matthew Korey and Meghan E Lamm and Katie Copenhaver and Jim Tobin and Vlastimil Kunc",

note = "Publisher Copyright: {\textcopyright} 2026 Oak Ridge National Laboratory. Wind Energy published by John Wiley \& Sons Ltd.",

year = "2026",

month = may,

doi = "10.1002/we.70119",

language = "English",

volume = "29",

journal = "Wind Energy",

issn = "1095-4244",

publisher = "wiley",

number = "5",

}

TY - JOUR

T1 - Healable Coatings as a Mechanism to Repair Leading Edge Erosion in Wind Energy

AU - Hubbard, Amber M

AU - Korey, Matthew

AU - Lamm, Meghan E

AU - Copenhaver, Katie

AU - Tobin, Jim

AU - Kunc, Vlastimil

PY - 2026/5

Y1 - 2026/5

N2 - Wind turbine blades are highly engineered structures designed to face temperature extremes and high winds. However, erosion of the blade's leading edge and subsequent repair remains a significant and costly challenge for the wind energy industry. Repair of these leading edges can lead to large amounts of downtime for the turbine and significant operational inefficiencies. In this work, the strength of adhesion and healing ability of a commercially available vitrimer (Mallinda's VITRIMAX) was compared to that of a thermoplastic resin, which has previously been demonstrated in wind energy applications (Arkema's Elium) to evaluate their efficacy as surface coatings for wind turbine blades, particularly their leading edges. Vitrimers are a class of inherently reprocessable thermosets, and it was theorized that vitrimer-based leading edge coatings could enable more robust and efficient wind turbine blades with decreased operational downtime and safer maintenance practices. It was found that the VITRIMAX adhered better to the wind blades' surfaces than both the manufacturer's paint and Elium, with increases in pull-off strength of adhesion ranging from 24% to 83% above that of the original paint. Furthermore, the VITRIMAX adhered strongly to the underlying composite of each blade with strength of adhesion values increasing in ranges from 42% to 97% above that of the original paint. Finally, the vitrimer coating showed an 88% decrease in surface roughness compared to end-of-life blade materials, and initial healing demonstrations in which coatings were manually scratched and subsequently healed exhibited an ~84.5% decrease in scratch depths.

AB - Wind turbine blades are highly engineered structures designed to face temperature extremes and high winds. However, erosion of the blade's leading edge and subsequent repair remains a significant and costly challenge for the wind energy industry. Repair of these leading edges can lead to large amounts of downtime for the turbine and significant operational inefficiencies. In this work, the strength of adhesion and healing ability of a commercially available vitrimer (Mallinda's VITRIMAX) was compared to that of a thermoplastic resin, which has previously been demonstrated in wind energy applications (Arkema's Elium) to evaluate their efficacy as surface coatings for wind turbine blades, particularly their leading edges. Vitrimers are a class of inherently reprocessable thermosets, and it was theorized that vitrimer-based leading edge coatings could enable more robust and efficient wind turbine blades with decreased operational downtime and safer maintenance practices. It was found that the VITRIMAX adhered better to the wind blades' surfaces than both the manufacturer's paint and Elium, with increases in pull-off strength of adhesion ranging from 24% to 83% above that of the original paint. Furthermore, the VITRIMAX adhered strongly to the underlying composite of each blade with strength of adhesion values increasing in ranges from 42% to 97% above that of the original paint. Finally, the vitrimer coating showed an 88% decrease in surface roughness compared to end-of-life blade materials, and initial healing demonstrations in which coatings were manually scratched and subsequently healed exhibited an ~84.5% decrease in scratch depths.

KW - functional coatings

KW - healable resins

KW - leading edges

KW - vitrimers

KW - wind energy

UR - https://www.scopus.com/pages/publications/105035002714

U2 - 10.1002/we.70119

DO - 10.1002/we.70119

M3 - Article

AN - SCOPUS:105035002714

SN - 1095-4244

VL - 29

JO - Wind Energy

JF - Wind Energy

IS - 5

M1 - e70119

ER -

Healable Coatings as a Mechanism to Repair Leading Edge Erosion in Wind Energy

Abstract

Funding

Keywords

Access to Document

Other files and links

Fingerprint

Cite this