Information Notice 2026-01, Degradation of Carbon Fiber Reinforced Polymer Composite Used for Piping Repair: Difference between revisions

ML25251A088 UNITED STATES

NUCLEAR REGULATORY COMMISSION

OFFICE OF NUCLEAR REACTOR REGULATION

WASHINGTON, DC 20555-0001

January 9, 2026

NRC INFORMATION NOTICE 2026-01: DEGRADATION OF CARBON FIBER REINFORCED

POLYMER COMPOSITE USED FOR PIPING

REPAIR

ADDRESSEES

All holders of an operating license or construction permit for a nuclear power reactor under

Title 10 of the Code of Federal Regulations (10 CFR) Part 50, Domestic Licensing of

Production and Utilization Facilities, except those who have permanently ceased operations

and have certified that fuel has been permanently removed from the reactor vessel, and all

holders of a power reactor combined license under 10 CFR Part 52, Licenses, Certifications, and Approvals for Nuclear Plants.

All holders of or applicants for an early site permit, standard design certification, standard

design approval, manufacturing license, or combined license under 10 CFR Part 52, Licenses, Certifications, and Approvals for Nuclear Power Plants.

PURPOSE

The U.S. Nuclear Regulatory Commission (NRC) is issuing this information notice (IN) to inform

addressees of the operating experience regarding the degradation of the carbon fiber reinforced

polymer (CFRP) composite that was installed for piping repair. It is expected that recipients will

review the information for applicability to their facilities and consider actions, as appropriate, to

avoid impacts to the operability of structures, systems, and components important to safety. INs

may not impose new requirements, and nothing in this IN should be interpreted to require

specific action.

DESCRIPTION OF CIRCUMSTANCES

In October 2021, at Arkansas Nuclear One, Unit 2, degradation was found in the CFRP

composite that was installed on the inner diameter of the circulating water return piping. The

purpose of the CFRP repair was to mitigate corrosion in the non-safety-related piping. In the

degraded condition, a portion of the CFRP composite was detached from the pipe and

entangled in a downstream screen, causing back pressure to build in the pipe. Some of the

material entangled in the screen was easily removed. However, one piece had to be broken

before removal.

Some sections of the topcoat were also found to be missing. In addition, the licensee found that

the CFRP composite was starting to delaminate at one of the terminal ends. The CFRP

composite for piping repair did not include a terminal-end compression ring. In CFRP composite

applications, the purpose of a terminal-end compression ring is to provide an extra layer of protection for damage to terminal ends by applying compressive forces between the composite

and the substrate (i.e., the base metal of the repaired piping).

DISCUSSION

A CFRP composite is composed of reinforcing carbon fibers saturated in a polymer matrix. In

piping repair using a CFRP composite to provide structural integrity or corrosion resistance, the

composite material is installed on site by wet lay-up and cure-in-place processes. The quality

and integrity of the CFRP repair depend on its material qualification, installation process, quality

control, verification testing for the installed composite, and inspections.

The specific piping associated with the operating experience presented above is

non-safety-related piping. However, when degradation of CFRP composites causes debonding

or delamination in non-safety-related piping, this may create a foreign material hazard with

potential impacts on the operability of safety-related systems and components that are relied

upon for plant safety.

Currently, there is no NRC staff-approved generic approach for CFRP repair in the American

Society of Mechanical Engineers (ASME) Boiler and Pressure Vessel Code or code cases. The

NRC staff is working with ASME and industry stakeholders to develop a generically approved

approach for CFRP repair for ASME code class piping (e.g., development of a later version of

ASME Code Case N-871-1, Repair of Buried Class 2 and 3 Piping Using Carbon

Fiber-Reinforced Polymer Composite,Section XI, Division 1, to be included in Regulatory

Guide 1.147, Inservice Inspection Code Case Acceptability, ASME Section XI, Division 1).

Within the past 10 years, the NRC staff received and approved licensees proposed alternatives

regarding the application of CFRP composite (also called CFRP repair system) for

safety-related piping. Of those approved, only one plant has installed the CFRP composite for

safety-related piping, and limited operating experience has not shown such degradation as

discussed above. This specific CFRP repair system (i.e., specific vendor, material, installation

process, etc.) has been also used in the piping systems of nonnuclear plants and municipal

water systems. In addition, this specific CFRP repair system has been used in nuclear plant

non-safety-related piping systems. The licensees operating experience evaluation of these

nonnuclear applications and nuclear plant non-safety-related applications further indicates that

there was no failure due to degradation associated with this specific CFRP repair system.

However, the operating experience related to the CFRP composite degradation in the

non-safety-related piping and the CFRP repair approach, which maintained the integrity of

piping repair, suggests that the following approaches are important to ensure the integrity of

CFRP repair systems:

Adequate materials (e.g., carbon fiber fabric and epoxy resin) are selected based on the

material qualification tests for tensile strength, tensile elastic modulus, bond strength, and glass transition temperature to ensure that the design criteria are met.

A proper installation process is conducted with quality control using in-process

inspections to ensure that qualified materials are used in the installation; the surface of

the substrate (host piping) is properly prepared and clean; the substrate pipe has a

proper thickness at the terminal end regions; the carbon fiber fabric is properly saturated with the polymer resin; and the installation temperature is monitored and controlled to

achieve the specified cure condition, degree of cure, and glass transition temperature.

Verification testing is performed by using witness panels or samples, which are prepared

at the installation and represent the installation process, to confirm that the properties of

the installed CFRP composite (e.g., tensile strength and modulus, degree of cure and

glass transition temperature) meet the design criteria.

Preservice and in-service inspections are conducted to ensure that the installed CFRP

composite does not have defects (e.g., matrix cracking, delamination, blisters, and wear)

that may affect the integrity of the CFRP repair, and the CFRP composite continues to

be free of degradation during the service.

Technical personnel involved in the CFRP repair installation have sufficient training and

qualification to adequately conduct the installation processes, including in-process and

quality control inspections.

Although this IN does not require specific actions of licensees, the approaches discussed above

can help to ensure that the CFRP repair maintains its structural integrity and performs its

intended functions.

Recently, the NRC staff used the agencys probabilistic risk assessment (PRA) software and

plant-specific Standardized Plant Analysis Risk models to evaluate the potential impact of CFRP

failures on plant systems and components. This risk analysis was conducted for sites where the

NRC staff has received and approved the proposed alternatives involving the application of

CFRP composite for safety-related piping. Analysts examined plant drawings, system

descriptions, and abnormal operating procedures for each plant to understand how specific

plant design specifications could mitigate potential failures.

The following insights were identified based on the NRCs review of the issue:

Verification testing, using witness panels to confirm that the margin between the cure

temperature and the glass transition temperature is sufficient, would reduce uncertainty

in the risk analysis.

Licensees that analyze the effects of potential failures of CFRP on downstream

components and systems, and how operators and systems would respond to such

failures, can identify vulnerabilities before installation.

CONTACT

S

Please direct any questions about this matter to the technical contacts listed below.

/RA/

Philip McKenna, Acting Director

Division of Reactor Oversight

Office of Nuclear Reactor Regulation

Technical Contacts: Ali Rezai, NRR

Ching Ng, NRR

301-415-1328

301-415-8054 e-mail: Ali.Rezai@nrc.gov

e-mail: Ching.Ng@nrc.gov

Seung Min, NRR

301-415-2045 e-mail: Seung.Min@nrc.gov SUBJECT: NRC INFORMATION NOTICE 2026-01, DEGRADATION OF CARBON FIBER

REINFORCED POLYMER COMPOSITE USED FOR PIPING REPAIR

DATE: JANUARY 9, 2026

ADAMS Accession No.: ML25251A088 EPID No.: L-2025-GEN-0002

OFFICE

NRR/DNRL/NPHP

NRR/DNRL/NPHP

NRR/DRA/APOB

NRR/DNRL/NPHP

OCIO

NAME

SMin

ARezai

CNg

MMitchell

KBenney

DATE

9/19/2025

9/16/2025

9/17/2025

9/19/2025

12/18/2025 OFFICE

OE

NRR/DRO/IOEB

NRR/DRA

NRR/DRO/IOEB

OGC

NAME

JPeralta

GSpaulding

RPascarelli

BBenney

DATE

12/16/2025

12/30/2025

9/19/2025

1/5/2026

12/30/25 OFFICE

OIRA

NRR/DRO/

NAME

PMcKenna

DATE

12/30/25

1/9/2026