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Notices > 1999 > IN 9 UNITED STATES NUCLEAR REGULATORY
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===OFFICE OF NUCLEAR REACTOR REGULATION===
Who
WASHINGTON, D.C. 20555-0001 April 13, 1999 NRC INFORMATION


NOTICE DEGRADATION
e AreI Wat We Do


OF PRESTRESSING
Reactors


===TENDON SYSTEMS IN PRESTRESSED===
flMaterials
99-10: CONCRETE CONTAINMENTS


*
Waste


==Addressees==
11 Involvement
*


==Purpose==
Home > Electronic Reading Room > Document Collections > General Communications > Information Notices > 1999 > IN 9
* Description


of Circumstances
===UNITED STATES===
NUCLEAR REGULATORY COMMISSION


o Prestressing
===OFFICE OF NUCLEAR REACTOR REGULATION===
WASHINGTON, D.C. 20555-0001


Tendon Wire Breakage o Effects of High Temperature
===April 13, 1999===
NRC INFORMATION NOTICE


on the Prestressing
DEGRADATION OF PRESTRESSING TENDON SYSTEMS IN PRESTRESSED


Forces in Tendons o Companoadedf
99-10:


===Presressiore===
===CONCRETE CONTAINMENTS===
o ..prison and_Trending
*  
 
f_Pestr .FogErces* Discu$sion


==Addressees==
==Addressees==
All holders of operating
*
 
licenses for nuclear power reactors.


==Purpose==
==Purpose==
The U.S. Nuclear Regulatory
*


Commission (NRC) is issuing this information
==Description of Circumstances==
o Prestressing Tendon Wire Breakage


notice to alert addressees
o Effects of High Temperature on the Prestressing Forces in Tendons


to degradation
o Companoadedf


of prestressing
===Presressiore===
o ..prison and_Trending f_Pestr


systems components
.FogErces


of prestressed
* Discu$sion


concrete containments (PCCs). The specific items addressed
==Addressees==
All holders of operating licenses for nuclear power reactors.


are (1) prestressing
==Purpose==
 
The U.S. Nuclear Regulatory Commission (NRC) is issuing this information notice to alert addressees to
tendon wire breakage, (2) the effects of high temperature
 
on the prestressing


forces in tendons, and (3) trend analysis of prestressing
degradation of prestressing systems components of prestressed concrete containments (PCCs). The specific


forces. It is expected that recipients
items addressed are (1) prestressing tendon wire breakage, (2) the effects of high temperature on the


will review the information
prestressing forces in tendons, and (3) trend analysis of prestressing forces. It is expected that recipients will


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


to their facilities
problems. However, suggestions contained in this information notice are not NRC requirements; therefore, no


and consider actions, as appropriate, to avoid similar problems.
specific action or written response is required.


However, suggestions
==Description of Circumstances==
Results of inspections of PCCs and PCC tendons have identified a number of concerns related to the


contained
degradation of prestressing tendon systems in PCCs and the ability of the containment structure to perform its


in this information
function. The relevant findings associated with these concerns are discussed below.


notice are not NRC requirements;
===Prestressing Tendon Wire Breakage===
therefore, no specific action or written response is required.Description
Recent observations related to containment prestressing systems have revealed conditions that may


of Circumstances
precipitate tendon wire breakage. Conditions such as uneven shim stack heights on the anchor-heads, spalling


Results of inspections
and cracking of concrete beneath the anchor-head base plates, free water in the bottom grease caps, poorly


of PCCs and PCC tendons have identified
drained top anchorage ledges, and the absence of filler grease in various areas can lead to corrosion of


a number of concerns related to the degradation
tendons and eventually to wire breakage. Specific plant observations and instances of failure of tendons and


of prestressing
associated anchorages are detailed in Attachment 1.


tendon systems in PCCs and the ability of the containment
Effects of High Temperature on the Prestressing Forces in Tendons


structure
http://www.nrc.gov/reading-rm/doc-collections/gen-comrn/info-notices/1 999/in9901O.html


to perform its function.
03/13/2003


The relevant findings associated
Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... Ucensees at a number of plants have reported lower than predicted prestressing forces for vertical, hoop, and


with these concerns are discussed
dome tendons. Investigations and analyses have indicated that the prestressing tendon relaxation losses


below.Prestressing
range from 15.5 to 20 percent over 40 years at an average sustained temperature of 32 C (90 F) around


Tendon Wire Breakage Recent observations
the tendons. However, the tendon relaxation loss values used in PCCs vary between 4 to 12 percent. These


related to containment
values were determined at the presumed ambient temperature of 20 C (68 F). The relevant plant


prestressing
observations and discussions are reported in Attachment 2.


systems have revealed conditions
===Comparison and Trending of Prestressing Forces===
The use of the provisions of Regulatory Guide 1.35.1 ("Determining Prestressing Forces for Inspection of


that may precipitate
Prestressed Concrete Containments") or equivalent methods are important to maintaining the safety function


tendon wire breakage.
of the prestressing tendon system and the concrete containment. Moreover, proper comparison and trending


Conditions
analysis is critical in determining the future trends in prestressing force in PCCs. Licensees have reported


such as uneven shim stack heights on the anchor-heads, spalling and cracking of concrete beneath the anchor-head
losses using the average forces determined from the liftoff testing, thereby masking the true variation in the


base plates, free water in the bottom grease caps, poorly drained top anchorage
loss of prestressing forces. An analysis using the individual lift-off forces for regression analysis gives results


ledges, and the absence of filler grease in various areas can lead to corrosion
that are statistically valid. Attachment 3 contains the staffs discussion of the variation in trend analysis of


of tendons and eventually
tendon prestressing forces.


to wire breakage.
Discussion


Specific plant observations
As nuclear power plants continue to age, in particular, plants with a PCC, the management and mitigation of


and instances
effects of degradation as a result of aging become increasingly more important. The containment structure


of failure of tendons and associated
serves as the final barrier against the release of fission products to the environment under postulated design- basis accident conditions. Therefore, it is essential that its integrity be maintained. Focus on the prestressing


anchorages
tendon system for containment integrity is based on the vital role it plays. However, other components that


are detailed in Attachment
make up the system also need to be examined. The observations detailed in the three attachments, and the


1.Effects of High Temperature
observations made during the Oconee site visit (see Attachment 1), indicate that other contributions to the


on the Prestressing
degradation of containment could potentially compromise its effectiveness.


Forces in Tendons http://www.nrc.gov/reading-rm/doc-collections/gen-comrn/info-notices/1
PCC degradations, such as concrete spalling, water infiltration into tendon galleries, and concrete cracking in
999/in9901O.html


03/13/2003 Information
the containment and the containment dome, all affect the containment's ability to function properly. It


Notice No. 99-10: Degradation
remains important to ensure that the cumulative effects of degradation mechanisms do not compromise the


of Prestressing
safety of the containment. The attributes discussed in the three attachments will be useful in identifying the


Tendon Systems in Prestresse... Ucensees at a number of plants have reported lower than predicted
potential problem areas and in evaluating the results of the inservice inspections of containments.


prestressing
This information notice requires no specific action or written response. However, recipients are reminded that


forces for vertical, hoop, and dome tendons. Investigations
they are required to consider industry-wide operating experience (including NRC information notices), where


and analyses have indicated
practical, when setting goals and performing periodic evaluations under Section 50.65, "Requirements for


that the prestressing
Monitoring the Effectiveness of Maintenance at Nuclear Power Plants," of Part 50 of Title 10 of the Code of


tendon relaxation
Federal Regulations. If you have any questions about the information in this notice, please contact one of the


losses range from 15.5 to 20 percent over 40 years at an average sustained
technical contacts listed below or the appropriate Office of Nuclear Reactor Regulation (NRR) project manager.


temperature
/s/'d by S. F. Newberry


of 32 C (90 F) around the tendons. However, the tendon relaxation
For


loss values used in PCCs vary between 4 to 12 percent. These values were determined
===David B. Matthews, Director===
Division of Regulatory Improvement Programs


at the presumed ambient temperature
===Office of Nuclear Reactor Regulation===
Technical contacts:
H. Ashar, NRR


of 20 C (68 F). The relevant plant observations
===G. Hatchett, NRR===
 
301-415-2851  
and discussions
 
are reported in Attachment
 
2.Comparison
 
and Trending of Prestressing
 
Forces The use of the provisions
 
of Regulatory
 
Guide 1.35.1 ("Determining
 
Prestressing
 
Forces for Inspection
 
of Prestressed
 
Concrete Containments")
or equivalent
 
methods are important
 
to maintaining
 
the safety function of the prestressing
 
tendon system and the concrete containment.
 
Moreover, proper comparison
 
and trending analysis is critical in determining
 
the future trends in prestressing
 
force in PCCs. Licensees
 
have reported losses using the average forces determined
 
from the liftoff testing, thereby masking the true variation
 
in the loss of prestressing
 
forces. An analysis using the individual
 
lift-off forces for regression
 
analysis gives results that are statistically
 
valid. Attachment
 
3 contains the staffs discussion
 
of the variation
 
in trend analysis of tendon prestressing
 
forces.Discussion
 
As nuclear power plants continue to age, in particular, plants with a PCC, the management
 
and mitigation
 
of effects of degradation
 
as a result of aging become increasingly
 
more important.
 
The containment
 
structure serves as the final barrier against the release of fission products to the environment
 
under postulated
 
design-basis accident conditions.
 
Therefore, it is essential
 
that its integrity
 
be maintained.
 
===Focus on the prestressing===
tendon system for containment
 
integrity
 
is based on the vital role it plays. However, other components
 
that make up the system also need to be examined.
 
The observations
 
detailed in the three attachments, and the observations
 
made during the Oconee site visit (see Attachment
 
1), indicate that other contributions
 
to the degradation
 
of containment
 
could potentially
 
compromise
 
its effectiveness.
 
PCC degradations, such as concrete spalling, water infiltration
 
into tendon galleries, and concrete cracking in the containment
 
and the containment
 
dome, all affect the containment's
 
ability to function properly.
 
It remains important
 
to ensure that the cumulative
 
effects of degradation
 
mechanisms
 
do not compromise
 
the safety of the containment.
 
The attributes
 
discussed
 
in the three attachments
 
will be useful in identifying
 
the potential
 
problem areas and in evaluating
 
the results of the inservice
 
inspections
 
of containments.
 
This information
 
notice requires no specific action or written response.
 
However, recipients
 
are reminded that they are required to consider industry-wide
 
operating
 
experience (including
 
NRC information
 
notices), where practical, when setting goals and performing
 
periodic evaluations
 
under Section 50.65, "Requirements
 
for Monitoring
 
the Effectiveness
 
of Maintenance
 
at Nuclear Power Plants," of Part 50 of Title 10 of the Code of Federal Regulations.
 
If you have any questions
 
about the information
 
in this notice, please contact one of the technical
 
contacts listed below or the appropriate
 
Office of Nuclear Reactor Regulation (NRR) project manager./s/'d by S. F. Newberry For David B. Matthews, Director Division of Regulatory
 
Improvement
 
===Programs Office of Nuclear Reactor Regulation===
Technical
 
contacts:
H. Ashar, NRR G. Hatchett, NRR 301-415-2851  
301-415-3315 E-mail: hga@nrc.gov
301-415-3315 E-mail: hga@nrc.gov


Line 420: Line 223:


Attachments:  
Attachments:  
1. Prestressing
1. Prestressing Tendon Wire Breakage
 
Tendon Wire Breakage 2. Effects of High Temperature
 
on the Prestressing
 
Forces in Tendons 3. Comparison
 
and Trending of Prestressing
 
Forces 4. List of Recently Issued Information
 
Notices http://www.nrc.gov/reading-rmldoc-collections/gen-commlinfo-notices/1999fin99010.html
 
03/13/2003 Information
 
Notice No. 99-10: Degradation
 
of Prestressing
 
Tendon Systems in Prestresse... (NUDOCS Accession
 
Number 9904090219)
ATTACHMENT
 
1 IN 99-10 April 13, 1999 Prestressing
 
Tendon Wire Breakage During the 20th-year
 
surveillance
 
of the prestressing
 
system of Calvert Cliffs Nuclear Power Plant, Unit 1, in June-July
 
1997, the licensee (Baltimore
 
Gas & Electric Company--BG&E)
found a low lift-off value compared to the prestressing
 
force for one of the three randomly selected vertical tendons. The low lift-off value was attributed
 
to the uneven shim stack heights on the two opposite sides of the anchor-head.
 
In accordance
 
with the plant's Technical
 
Specifications (TSs) requirement, the licensee tested two additional
 
vertical tendons adjacent to this tendon. However, during the lift-off testing of one of these tendons, noises were heard that indicated
 
that some of the tendon wires might have broken. A visual examination
 
of the tendon indicated
 
that three wires had broken at 12.7-17.2 centimeters
 
(5-7 inches) below the bottom of the button-heads.
 
Further examination
 
of the wires at the top of other vertical tendons revealed additional
 
wire breakage.
 
The licensee expanded the lift-off testing and visual examination
 
to 100 percent of the vertical tendons. Similar degradation
 
of other vertical tendons was found. As a part of its corrective
 
action, the licensee is planning to replace 63 of the 202 vertical tendons in Unit 1 and 64 of the 204 vertical tendons in Unit 2.NRC's Information
 
Notice 85-10, dated February 1985, and its supplement
 
of March 1985, "Post-Tensioned
 
Containment
 
Tendon Anchor-Head
 
Failure," described
 
prestressing
 
tendon anchor-head
 
failures at both units of the Joseph M. Farley Nuclear Plant. The root cause analysis of that event indicated
 
that there were several factors contributing
 
to it, such as, free water in the grease caps at the bottom of the vertical tendons, high hardness of the anchorage
 
material, and high stresses in the anchor-heads.
 
The failures had resulted from hydrogen embrittlement
 
of the anchor-head
 
material.
 
The free water in the bottom grease caps of the vertical tendons may have accumulated (through a number of years) from the poorly drained top anchorage
 
ledge of the vertical tendons (similar to the condition
 
at the Calvert Cliffs containments).
 
However, at Farley, wire failures did not occur.In general, American Society for Testing and Materials (ASTM) A-421 ("Uncoated
 
Stress-Relieved
 
Wire for Prestressed
 
Concrete")
wires (used at both Farley and Calvert Cliffs) are not susceptible
 
to hydrogen-induced
 
cracking.
 
However, BG&E's engineering
 
evaluation
 
indicated
 
brittle hydrogen-induced
 
cracking on a third of the broken wires. All of the brittle fractures
 
were preceded by severe corrosion.
 
The engineering
 
evaluation
 
also indicates
 
that some of the brittle fractures
 
may have occurred earlier but were not found during the periodic inspections.
 
To ensure that the stressing
 
washers (anchor-heads)
are not affected, BG&E visually examined the anchor-heads
 
at both ends of the vertical tendons and found no visible cracks or fractures.
 
The lessons learned from these two events indicate that the prestressing
 
wires and anchor-heads
 
of the button-headed prestressing
 
systems are susceptible
 
to cracking from tensile stress and hydrogen-induced
 
corrosion.
 
The severity and the extent of corrosion
 
depend upon the ability of the moisture to reach unprotected
 
areas, the duration of exposure, and the material characteristics.
 
In April 1998, the NRC staff visited the Oconee Nuclear Station (OCN) to discuss issues related to the licensee's
 
license renewal technical
 
report. As part of the visit, the staff performed
 
a walkdown inspection
 
of the OCN containments
 
and other structures.
 
The following
 
observations
 
are related to the prestressing
 
system degradations
 
reported by the staff:* At Tendon 12V6, the concrete beneath the 5.1-centimeter
 
(2-inch) thick anchor-bearing
 
plate had spalled along the outer edge; a cavity existed below the plate. Cracks in the concrete beneath the outer edge of the bearing plates were observed for a number of tendons.* Tendon grease had leaked from a significant
 
number of hoop tendons in the containments
 
of all three units at OCN.* The Unit 1 tendon access gallery showed water infiltration
 
and standing water at several locations.
 
The licensee indicated
 
that the Unit 2 tendon access gallery at one time held as much as 51 centimeters
 
(20 http://www.nrc.gov/reading-rmldoc-collections/gen-comm/info-notices/1999/in99010.html
 
03/13/2003 Information
 
Notice No. 99-10: Degradation
 
of Prestressing
 
Tendon Systems in Prestresse... inches) of water. The licensee is periodically
 
purging the tendon galleries
 
of all three units to remove water.The licensee addressed
 
these and similar degradations
 
under the requirements
 
of its TSs or in accordance
 
with Criterion
 
XVI of 10 CFR Part 50, Appendix B.ATTACHMENT
 
2 IN 99-10 April 13, 1999 Effects of High Temperature
 
on the Prestressing
 
Forces in Tendons In 1979-1980, the licensee of the Robert E. Ginna Nuclear Power Plant, Rochester
 
Gas & Electric Corporation, reported lower than predicted
 
forces for several of the vertical tendons in its partially
 
prestressed
 
containment
 
structure.
 
Extensive
 
analysis and testing performed
 
by the licensee indicated
 
the cause of the consistently
 
lower prestressing
 
forces to be appreciably
 
higher (than estimated)
relaxation
 
of prestressing
 
steel as a result of the average high temperatures
 
around the tendons. The 1000-hour
 
and 10,000-hour
 
testing performed
 
at the Fritz Engineering
 
Laboratory
 
of Lehigh University
 
of the wires taken from some of the vertical tendons showed that the 40-year relaxation
 
could be between 15.5 and 20 percent at 32 Celsius (C) (90 Fahrenheit
 
[°F]), an average temperature
 
around the tendons during the summer. The wire relaxation
 
assumed in the design was 12 percent.During the fourth surveillance
 
of tendon forces in February 1990 at Virgil C. Summer Nuclear Station, the licensee, South Carolina Electric & Gas Co., discovered
 
that the forces in the 115 vertical tendons were lower than expected.
 
Because the wires used in the prestressing
 
tendons were of the same size, type, and relaxation
 
property as those used in the Ginna tendons, the licensee concluded
 
that the reason for low prestressing
 
forces was the higher (than considered)
relaxation
 
of prestressing
 
wires. As in the case of the Ginna containment, the average temperature
 
around the tendons was determined
 
to be 32 C (90 F). To remedy the situation, the licensee retensioned
 
the vertical tendons at an average lock-off force of 0.685 of the guaranteed
 
ultimate tensile strength of the wires.During the performance
 
of 20th-year
 
tendon surveillance
 
in November-December
 
1992 at Turkey Point Station, Units 3 and 4, the licensee, Florida Power & Light Co., found that the measured prestressing
 
forces of a number of randomly selected tendons in both units were appreciably
 
lower than the predicted
 
forces. The lower tendon forces were found in hoop, vertical, and dome tendons. The licensee, with the assistance
 
of its consultant, investigated
 
the root cause and implemented
 
necessary
 
corrective
 
actions. The root cause investigation
 
indicated
 
that the most probable cause for lower prestressing
 
forces (higher prestressing
 
losses)was an increased
 
tendon wire steel relaxation
 
resulting
 
from the sustained
 
high temperatures
 
around the tendons. Analysis of the meteorological
 
data indicated
 
that the average sustained
 
temperatures
 
around the tendons could be estimated
 
as 32 C (90 F). The supplier of the prestressing
 
wire had provided 8 percent as the wire relaxation
 
loss at 20 C (68 F) and had indicated
 
higher relaxation
 
losses at higher temperatures.
 
In estimating
 
prestressing
 
forces, the utility had used 8 percent of the prestressing
 
force in the tendons as the loss due to relaxation.
 
Many of the prestressed
 
concrete containments
 
in the United States are typically
 
subjected
 
to average tendon temperatures
 
greater than 32 C (90 F) during hot weather or year around. Although only three plants reported lower prestresssing
 
forces (than the predicted)
due to higher (than considered
 
in the design)relaxation, this condition
 
may exist at many other plants with PCCs. However, plants may not experience
 
more than projected
 
loss of prestressing
 
force due to (1) conservative
 
estimates
 
of losses in the design, (2)frequent unsystematic
 
retensioning
 
of tendons, (3) improper use of a method of trending measured tendon forces, or (4) a combination
 
of Items (1), (2), and (3).Regulatory
 
Guide (RG) 1.35.1, "Determining
 
Prestressing
 
Forces for Inspection
 
of Prestressed
 
Concrete Containments" (July 1990), provides a simple method of documenting


the installation
2. Effects of High Temperature on the Prestressing Forces in Tendons


forces, potential
3. Comparison and Trending of Prestressing Forces


initial losses in the prestressing
4. List of Recently Issued Information Notices


force, and a method of incorporating
http://www.nrc.gov/reading-rmldoc-collections/gen-commlinfo-notices/1999fin99010.html


the time-dependent
03/13/2003


losses. The basic concept recommended
Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... (NUDOCS Accession Number 9904090219)


in the guide is to establish
===ATTACHMENT 1===
IN 99-10


predicted
===April 13, 1999===
Prestressing Tendon Wire Breakage


forces for all the tendons at various times since the http://www.nrc.gov/reading-rmldoc-collections/gen-comm/info-notices1
During the 20th-year surveillance of the prestressing system of Calvert Cliffs Nuclear Power Plant, Unit 1, in
999/in9901 O.html 03/13/2003 Information


Notice No. 99-10: Degradation
June-July 1997, the licensee (Baltimore Gas & Electric Company--BG&E) found a low lift-off value compared to


of Prestressing
the prestressing force for one of the three randomly selected vertical tendons. The low lift-off value was


Tendon Systems in Prestresse... complete installation
attributed to the uneven shim stack heights on the two opposite sides of the anchor-head. In accordance with


of tendons. As the initial elastic shortening
the plant's Technical Specifications (TSs) requirement, the licensee tested two additional vertical tendons


losses could vary from tendon to tendon, the individual
adjacent to this tendon. However, during the lift-off testing of one of these tendons, noises were heard that


tendon predicted
indicated that some of the tendon wires might have broken. A visual examination of the tendon indicated that


forces can be tabulated
three wires had broken at 12.7-17.2 centimeters (5-7 inches) below the bottom of the button-heads. Further


for comparison
examination of the wires at the top of other vertical tendons revealed additional wire breakage. The licensee


with the measured lift-off forces.Sometimes
expanded the lift-off testing and visual examination to 100 percent of the vertical tendons. Similar


the measured lift-off forces are adjusted to account for the initial elastic shortening
degradation of other vertical tendons was found. As a part of its corrective action, the licensee is planning to


loss or the time-dependent
replace 63 of the 202 vertical tendons in Unit 1 and 64 of the 204 vertical tendons in Unit 2.


losses. This adjustment
NRC's Information Notice 85-10, dated February 1985, and its supplement of March 1985, "Post-Tensioned


defeats the purpose of making a correct comparison.
Containment Tendon Anchor-Head Failure," described prestressing tendon anchor-head failures at both units


Sometimes
of the Joseph M. Farley Nuclear Plant. The root cause analysis of that event indicated that there were several


the measured lift-off force is computed using the effective
factors contributing to it, such as, free water in the grease caps at the bottom of the vertical tendons, high


unbroken wires in the tendon, thus making the comparison
hardness of the anchorage material, and high stresses in the anchor-heads. The failures had resulted from


inappropriate.
hydrogen embrittlement of the anchor-head material. The free water in the bottom grease caps of the vertical


Calculation
tendons may have accumulated (through a number of years) from the poorly drained top anchorage ledge of


of the average effective
the vertical tendons (similar to the condition at the Calvert Cliffs containments). However, at Farley, wire


wire forces in the tendon from the measured tendon force is made only to ensure that it does not exceed 70 percent of the guaranteed
failures did not occur.


ultimate tensile strength of the wire.In the United States, the main cause for the lower than predicted
In general, American Society for Testing and Materials (ASTM) A-421 ("Uncoated Stress-Relieved Wire for


prestressing
Prestressed Concrete") wires (used at both Farley and Calvert Cliffs) are not susceptible to hydrogen-induced


forces has been identified
cracking. However, BG&E's engineering evaluation indicated brittle hydrogen-induced cracking on a third of


as the high relaxation
the broken wires. All of the brittle fractures were preceded by severe corrosion. The engineering evaluation


of the tendon steel. However, in France, where the prestressing
also indicates that some of the brittle fractures may have occurred earlier but were not found during the


tendons are grouted and their prestressing
periodic inspections. To ensure that the stressing washers (anchor-heads) are not affected, BG&E visually


forces could not be directly measured, the cause for the indirectly
examined the anchor-heads at both ends of the vertical tendons and found no visible cracks or fractures. The


estimated
lessons learned from these two events indicate that the prestressing wires and anchor-heads of the button- headed prestressing systems are susceptible to cracking from tensile stress and hydrogen-induced corrosion.


low prestressing
The severity and the extent of corrosion depend upon the ability of the moisture to reach unprotected areas, the duration of exposure, and the material characteristics.


forces has been identified
In April 1998, the NRC staff visited the Oconee Nuclear Station (OCN) to discuss issues related to the


as creep and shrinkage
licensee's license renewal technical report. As part of the visit, the staff performed a walkdown inspection of


of the containment
the OCN containments and other structures. The following observations are related to the prestressing system


concrete.
degradations reported by the staff:
* At Tendon 12V6, the concrete beneath the 5.1-centimeter (2-inch) thick anchor-bearing plate had


The basic creep of the concrete could also be higher (than estimated)
spalled along the outer edge; a cavity existed below the plate. Cracks in the concrete beneath the outer
at higher temperatures, giving rise to higher loss of the prestressing


force. These two effects on prestressing
edge of the bearing plates were observed for a number of tendons.


forces could not be separated
* Tendon grease had leaked from a significant number of hoop tendons in the containments of all three


without substantial
units at OCN.


research.
* The Unit 1 tendon access gallery showed water infiltration and standing water at several locations. The


On the basis of the results of the relaxation
licensee indicated that the Unit 2 tendon access gallery at one time held as much as 51 centimeters (20
http://www.nrc.gov/reading-rmldoc-collections/gen-comm/info-notices/1999/in99010.html


tests on the prestressing
03/13/2003


steel, it appears that the dominant contributing
Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... inches) of water. The licensee is periodically purging the tendon galleries of all three units to remove


factor is the higher relaxation
water.


of the prestressing
The licensee addressed these and similar degradations under the requirements of its TSs or in accordance with


steel. Nevertheless, the containment
Criterion XVI of 10 CFR Part 50, Appendix B.


integrity
===ATTACHMENT 2===
IN 99-10


has to be demonstrated
===April 13, 1999===
Effects of High Temperature on the Prestressing Forces in Tendons


on the basis of the availability
In 1979-1980, the licensee of the Robert E. Ginna Nuclear Power Plant, Rochester Gas & Electric Corporation, reported lower than predicted forces for several of the vertical tendons in its partially prestressed containment


of the minimum required prestressing
structure. Extensive analysis and testing performed by the licensee indicated the cause of the consistently


force.ATTACHMENT
lower prestressing forces to be appreciably higher (than estimated) relaxation of prestressing steel as a result


3 IN 99-10 April 13, 1999 Comparison
of the average high temperatures around the tendons. The 1000-hour and 10,000-hour testing performed at


and Trending of Prestressing
the Fritz Engineering Laboratory of Lehigh University of the wires taken from some of the vertical tendons


Forces In 1994, during the 20th-year
showed that the 40-year relaxation could be between 15.5 and 20 percent at 32 Celsius (C) (90 Fahrenheit


tendon surveillance
[°F]), an average temperature around the tendons during the summer. The wire relaxation assumed in the


of Three Mile Island Nuclear Station, Unit 1 (TMI-1), prestressed
design was 12 percent.


concrete containment (conforming
During the fourth surveillance of tendon forces in February 1990 at Virgil C. Summer Nuclear Station, the


to Regulatory
licensee, South Carolina Electric & Gas Co., discovered that the forces in the 115 vertical tendons were lower


Guide [RG] 1.35 [Revision
than expected. Because the wires used in the prestressing tendons were of the same size, type, and


3]) and TMI-1 Technical
relaxation property as those used in the Ginna tendons, the licensee concluded that the reason for low


Specifications, the licensee, General Public Utilities
prestressing forces was the higher (than considered) relaxation of prestressing wires. As in the case of the


Nuclear Corporation, subjected
Ginna containment, the average temperature around the tendons was determined to be 32 C (90 F). To


a total of 11 tendons (5 hoop, 3 vertical, and 3 dome) to lift-off testing. On the basis of the data from this lift-off testing, in conjunction
remedy the situation, the licensee retensioned the vertical tendons at an average lock-off force of 0.685 of the


with data from the previous surveillance
guaranteed ultimate tensile strength of the wires.


tests for each group of tendons, the licensee originally
During the performance of 20th-year tendon surveillance in November-December 1992 at Turkey Point


performed
Station, Units 3 and 4, the licensee, Florida Power & Light Co., found that the measured prestressing forces of


a trending analysis for each group of tendons and concluded
a number of randomly selected tendons in both units were appreciably lower than the predicted forces. The


that none of the tendon groups would go below each group's minimum required force during the 40-year plant life. However, the licensee subsequently
lower tendon forces were found in hoop, vertical, and dome tendons. The licensee, with the assistance of its


performed
consultant, investigated the root cause and implemented necessary corrective actions. The root cause


a linear regression
investigation indicated that the most probable cause for lower prestressing forces (higher prestressing losses)
was an increased tendon wire steel relaxation resulting from the sustained high temperatures around the


analysis using individual
tendons. Analysis of the meteorological data indicated that the average sustained temperatures around the


lift-off forces rather than the average of the lift-off forces and found that the hoop tendons would go below the minimum required force beginning
tendons could be estimated as 32 C (90 F). The supplier of the prestressing wire had provided 8 percent as


in the 25th year.The licensee of the Oconee Nuclear Station, Duke Power Company, performed
the wire relaxation loss at 20 C (68 F) and had indicated higher relaxation losses at higher temperatures. In


the sixth tendon surveillance
estimating prestressing forces, the utility had used 8 percent of the prestressing force in the tendons as the


on Oconee Unit 3 in the summer of 1995. The licensee, using the averages of the lift-off forces obtained to that date, plotted them on a graph on which the predicted
loss due to relaxation.


upper bound and lower bound are shown and concluded that the mean lift-off force for each group fell below the required values (i.e., the lower bound). A subsequent
Many of the prestressed concrete containments in the United States are typically subjected to average tendon


trending analysis on the basis of individual
temperatures greater than 32 C (90 F) during hot weather or year around. Although only three plants


lift-off forces indicated
reported lower prestresssing forces (than the predicted) due to higher (than considered in the design)
relaxation, this condition may exist at many other plants with PCCs. However, plants may not experience


that the dome tendon force began to go below the minimum required force about 8 years after the structural
more than projected loss of prestressing force due to (1) conservative estimates of losses in the design, (2)
frequent unsystematic retensioning of tendons, (3) improper use of a method of trending measured tendon


integrity
forces, or (4) a combination of Items (1), (2), and (3).


test (SIT). For other tendon groups in Unit 3, the tendon forces were not predicted
Regulatory Guide (RG) 1.35.1, "Determining Prestressing Forces for Inspection of Prestressed Concrete


to go below the minimum required value until 40 years or more after the SIT. Since Oconee Units 1 and 2 are identical
Containments" (July 1990), provides a simple method of documenting the installation forces, potential initial


to Oconee Unit 3, the licensee performed
losses in the prestressing force, and a method of incorporating the time-dependent losses. The basic concept


a trend analysis for each of these units and found that the vertical tendon forces in Unit 1 and Unit 2 were predicted
recommended in the guide is to establish predicted forces for all the tendons at various times since the


to go below the minimum value at 30 years and 10 years after the SIT, respectively.
http://www.nrc.gov/reading-rmldoc-collections/gen-comm/info-notices1
999/in9901 O.html


These results were caused by additional
03/13/2003


wire breakage of other vertical tendons. The licensee expanded the lift-off testing and visual examination
Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... complete installation of tendons. As the initial elastic shortening losses could vary from tendon to tendon, the


to 100 percent of the vertical tendons. Similar degradation
individual tendon predicted forces can be tabulated for comparison with the measured lift-off forces.


of other vertical tendons was found. As a part of the licensee's
Sometimes the measured lift-off forces are adjusted to account for the initial elastic shortening loss or the


corrective
time-dependent losses. This adjustment defeats the purpose of making a correct comparison. Sometimes the


action, the licensee used the same tendons for lift-off testing, thus subjecting
measured lift-off force is computed using the effective unbroken wires in the tendon, thus making the


the tendons to cyclic loading. A more appropriate
comparison inappropriate. Calculation of the average effective wire forces in the tendon from the measured


methodology
tendon force is made only to ensure that it does not exceed 70 percent of the guaranteed ultimate tensile


is the random selection
strength of the wire.


of tendons to be tested.In 1996, the V. C. Summer licensee, South Carolina Electric & Gas Co., performed
In the United States, the main cause for the lower than predicted prestressing forces has been identified as


the 15-year (fifth) tendon surveillance.
the high relaxation of the tendon steel. However, in France, where the prestressing tendons are grouted and


For each group of tendons, the licensee used the averages of the lift-off forces from each surveillance
their prestressing forces could not be directly measured, the cause for the indirectly estimated low


and plotted the five points from the five surveillances
prestressing forces has been identified as creep and shrinkage of the containment concrete. The basic creep of


on a graph. The five points are joined by http://www.nrc.gov/reading-rm/doc-collections/gen-conm/info-notices/1999/in990
the concrete could also be higher (than estimated) at higher temperatures, giving rise to higher loss of the
1 0.html 03/13/200?


Information
prestressing force. These two effects on prestressing forces could not be separated without substantial


Notice No. 99-10: Degradation
research. On the basis of the results of the relaxation tests on the prestressing steel, it appears that the


of Prestressing
dominant contributing factor is the higher relaxation of the prestressing steel. Nevertheless, the containment


Tendon Systems in Prestresse... line segments.
integrity has to be demonstrated on the basis of the availability of the minimum required prestressing force.


On the basis of this graph, the licensee concluded
===ATTACHMENT 3===
IN 99-10


that the tendon force levels in the three groups of tendons would be acceptable
===April 13, 1999===
Comparison and Trending of Prestressing Forces


beyond the 20-year surveillance.
In 1994, during the 20th-year tendon surveillance of Three Mile Island Nuclear Station, Unit 1 (TMI-1),
prestressed concrete containment (conforming to Regulatory Guide [RG] 1.35 [Revision 3]) and TMI-1 Technical Specifications, the licensee, General Public Utilities Nuclear Corporation, subjected a total of 11 tendons (5 hoop, 3 vertical, and 3 dome) to lift-off testing. On the basis of the data from this lift-off testing, in


A subsequent
conjunction with data from the previous surveillance tests for each group of tendons, the licensee originally


linear regression
performed a trending analysis for each group of tendons and concluded that none of the tendon groups would


analysis using individual
go below each group's minimum required force during the 40-year plant life. However, the licensee


lift-off forces, instead of the averages, indicated
subsequently performed a linear regression analysis using individual lift-off forces rather than the average of


that the dome and hoop tendons would not go below the minimum required forces until 32 years after the SIT. The vertical tendons that had been retensioned
the lift-off forces and found that the hoop tendons would go below the minimum required force beginning in


were predicted
the 25th year.


not to go below the minimum required force until 42 years after the SIT.In 1993, the licensee of the Crystal River Nuclear Plant, Unit 3, Florida Power Corporation, performed
The licensee of the Oconee Nuclear Station, Duke Power Company, performed the sixth tendon surveillance on


the fifth tendon surveillance.
Oconee Unit 3 in the summer of 1995. The licensee, using the averages of the lift-off forces obtained to that


A detailed study that considered
date, plotted them on a graph on which the predicted upper bound and lower bound are shown and concluded


both the average and the individual
that the mean lift-off force for each group fell below the required values (i.e., the lower bound). A subsequent


lift-off forces was performed.
trending analysis on the basis of individual lift-off forces indicated that the dome tendon force began to go


On the basis of the results of linear regression
below the minimum required force about 8 years after the structural integrity test (SIT). For other tendon


analysis, the licensee concluded
groups in Unit 3, the tendon forces were not predicted to go below the minimum required value until 40 years


that with the exception
or more after the SIT. Since Oconee Units 1 and 2 are identical to Oconee Unit 3, the licensee performed a


of the vertical tendons' result, which gave a slightly steeper slope for the individual
trend analysis for each of these units and found that the vertical tendon forces in Unit 1 and Unit 2 were


data points, there was no difference
predicted to go below the minimum value at 30 years and 10 years after the SIT, respectively. These results


between the two methods for the hoop and dome tendons. The prestressing
were caused by additional wire breakage of other vertical tendons. The licensee expanded the lift-off testing


forces in the three groups of tendons were indicated
and visual examination to 100 percent of the vertical tendons. Similar degradation of other vertical tendons


to be above the minimum required forces well beyond the 40-year plant life.The simple regression
was found. As a part of the licensee's corrective action, the licensee used the same tendons for lift-off testing, thus subjecting the tendons to cyclic loading. A more appropriate methodology is the random selection of


model is a mathematical
tendons to be tested.


way of stating the statistical
In 1996, the V. C. Summer licensee, South Carolina Electric & Gas Co., performed the 15-year (fifth) tendon


relationship
surveillance. For each group of tendons, the licensee used the averages of the lift-off forces from each


that exists between two variables.
surveillance and plotted the five points from the five surveillances on a graph. The five points are joined by


In this case, the tendon force (TF) is a dependent
http://www.nrc.gov/reading-rm/doc-collections/gen-conm/info-notices/1999/in990 1 0.html


variable that varies with time (T), the independent
03/13/200?


variable.
Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... line segments. On the basis of this graph, the licensee concluded that the tendon force levels in the three


The two principal
groups of tendons would be acceptable beyond the 20-year surveillance. A subsequent linear regression


elements of a statistical
analysis using individual lift-off forces, instead of the averages, indicated that the dome and hoop tendons


relationship
would not go below the minimum required forces until 32 years after the SIT. The vertical tendons that had


are (1) the tendency of the dependent
been retensioned were predicted not to go below the minimum required force until 42 years after the SIT.


variable TF to vary in a systematic
In 1993, the licensee of the Crystal River Nuclear Plant, Unit 3, Florida Power Corporation, performed the fifth


way with the independent
tendon surveillance. A detailed study that considered both the average and the individual lift-off forces was


variable T, and the scattering
performed. On the basis of the results of linear regression analysis, the licensee concluded that with the


of points about the "curve" that represents
exception of the vertical tendons' result, which gave a slightly steeper slope for the individual data points, there was no difference between the two methods for the hoop and dome tendons. The prestressing forces in


the relationship
the three groups of tendons were indicated to be above the minimum required forces well beyond the 40-year


between TF and T. For a small sample size (2% of the population), using the average of the TF for each surveillance
plant life.


test masks the true variation
The simple regression model is a mathematical way of stating the statistical relationship that exists between


between TF and T. Therefore, an analysis using the individual
two variables. In this case, the tendon force (TF) is a dependent variable that varies with time (T), the


lift-off forces for the regression
independent variable. The two principal elements of a statistical relationship are (1) the tendency of the


analysis gives results that could be statistically
dependent variable TF to vary in a systematic way with the independent variable T, and the scattering of


validated.
points about the "curve" that represents the relationship between TF and T. For a small sample size (2% of


On the basis of experience, as evidenced
the population), using the average of the TF for each surveillance test masks the true variation between TF


from the examples presented
and T. Therefore, an analysis using the individual lift-off forces for the regression analysis gives results that


and the statistical
could be statistically validated.


analysis, it is evident that the appropriate
On the basis of experience, as evidenced from the examples presented and the statistical analysis, it is


method for evaluating
evident that the appropriate method for evaluating the adequacy of the tendon force is the regression analysis


the adequacy of the tendon force is the regression
using the individual lift-off forces as the data for the trend analysis.


analysis using the individual
http://www.nrc.gov/reading-rm/doc-collections/gen-comm/info-notices/1999/in9901 0.html


lift-off forces as the data for the trend analysis.http://www.nrc.gov/reading-rm/doc-collections/gen-comm/info-notices/1999/in9901
03/13/2003}}
0.html 03/13/2003}}


{{Information notice-Nav}}
{{Information notice-Nav}}

Latest revision as of 09:37, 16 January 2025

Degradation of Prestressing Tendon Systems in Prestresssed Concrete Containments
ML031500244
Person / Time
Issue date: 04/13/1999
From: Matthews D, Newberry S
Office of Nuclear Reactor Regulation
To:
References
IN-99-010
Download: ML031500244 (6)
v  d  e


Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... :.ffi>

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Home > Electronic Reading Room > Document Collections > General Communications > Information Notices > 1999 > IN 9

UNITED STATES

NUCLEAR REGULATORY COMMISSION

OFFICE OF NUCLEAR REACTOR REGULATION

WASHINGTON, D.C. 20555-0001

April 13, 1999

NRC INFORMATION NOTICE

DEGRADATION OF PRESTRESSING TENDON SYSTEMS IN PRESTRESSED

99-10:

CONCRETE CONTAINMENTS

Addressees

Purpose

Description of Circumstances

o Prestressing Tendon Wire Breakage

o Effects of High Temperature on the Prestressing Forces in Tendons

o Companoadedf

Presressiore

o ..prison and_Trending f_Pestr

.FogErces

  • Discu$sion

Addressees

All holders of operating licenses for nuclear power reactors.

Purpose

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

degradation of prestressing systems components of prestressed concrete containments (PCCs). The specific

items addressed are (1) prestressing tendon wire breakage, (2) the effects of high temperature on the

prestressing forces in tendons, and (3) trend analysis of prestressing forces. It is expected that recipients will

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

problems. However, suggestions contained in this information notice are not NRC requirements; therefore, no

specific action or written response is required.

Description of Circumstances

Results of inspections of PCCs and PCC tendons have identified a number of concerns related to the

degradation of prestressing tendon systems in PCCs and the ability of the containment structure to perform its

function. The relevant findings associated with these concerns are discussed below.

Prestressing Tendon Wire Breakage

Recent observations related to containment prestressing systems have revealed conditions that may

precipitate tendon wire breakage. Conditions such as uneven shim stack heights on the anchor-heads, spalling

and cracking of concrete beneath the anchor-head base plates, free water in the bottom grease caps, poorly

drained top anchorage ledges, and the absence of filler grease in various areas can lead to corrosion of

tendons and eventually to wire breakage. Specific plant observations and instances of failure of tendons and

associated anchorages are detailed in Attachment 1.

Effects of High Temperature on the Prestressing Forces in Tendons

http://www.nrc.gov/reading-rm/doc-collections/gen-comrn/info-notices/1 999/in9901O.html

03/13/2003

Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... Ucensees at a number of plants have reported lower than predicted prestressing forces for vertical, hoop, and

dome tendons. Investigations and analyses have indicated that the prestressing tendon relaxation losses

range from 15.5 to 20 percent over 40 years at an average sustained temperature of 32 C (90 F) around

the tendons. However, the tendon relaxation loss values used in PCCs vary between 4 to 12 percent. These

values were determined at the presumed ambient temperature of 20 C (68 F). The relevant plant

observations and discussions are reported in Attachment 2.

Comparison and Trending of Prestressing Forces

The use of the provisions of Regulatory Guide 1.35.1 ("Determining Prestressing Forces for Inspection of

Prestressed Concrete Containments") or equivalent methods are important to maintaining the safety function

of the prestressing tendon system and the concrete containment. Moreover, proper comparison and trending

analysis is critical in determining the future trends in prestressing force in PCCs. Licensees have reported

losses using the average forces determined from the liftoff testing, thereby masking the true variation in the

loss of prestressing forces. An analysis using the individual lift-off forces for regression analysis gives results

that are statistically valid. Attachment 3 contains the staffs discussion of the variation in trend analysis of

tendon prestressing forces.

Discussion

As nuclear power plants continue to age, in particular, plants with a PCC, the management and mitigation of

effects of degradation as a result of aging become increasingly more important. The containment structure

serves as the final barrier against the release of fission products to the environment under postulated design- basis accident conditions. Therefore, it is essential that its integrity be maintained. Focus on the prestressing

tendon system for containment integrity is based on the vital role it plays. However, other components that

make up the system also need to be examined. The observations detailed in the three attachments, and the

observations made during the Oconee site visit (see Attachment 1), indicate that other contributions to the

degradation of containment could potentially compromise its effectiveness.

PCC degradations, such as concrete spalling, water infiltration into tendon galleries, and concrete cracking in

the containment and the containment dome, all affect the containment's ability to function properly. It

remains important to ensure that the cumulative effects of degradation mechanisms do not compromise the

safety of the containment. The attributes discussed in the three attachments will be useful in identifying the

potential problem areas and in evaluating the results of the inservice inspections of containments.

This information notice requires no specific action or written response. However, recipients are reminded that

they are required to consider industry-wide operating experience (including NRC information notices), where

practical, when setting goals and performing periodic evaluations under Section 50.65, "Requirements for

Monitoring the Effectiveness of Maintenance at Nuclear Power Plants," of Part 50 of Title 10 of the Code of

Federal Regulations. If you have any questions about the information in this notice, please contact one of the

technical contacts listed below or the appropriate Office of Nuclear Reactor Regulation (NRR) project manager.

/s/'d by S. F. Newberry

For

David B. Matthews, Director

Division of Regulatory Improvement Programs

Office of Nuclear Reactor Regulation

Technical contacts:

H. Ashar, NRR

G. Hatchett, NRR

301-415-2851

301-415-3315 E-mail: hga@nrc.gov

E-mail: gxh@nrc.gov

Attachments:

1. Prestressing Tendon Wire Breakage

2. Effects of High Temperature on the Prestressing Forces in Tendons

3. Comparison and Trending of Prestressing Forces

4. List of Recently Issued Information Notices

http://www.nrc.gov/reading-rmldoc-collections/gen-commlinfo-notices/1999fin99010.html

03/13/2003

Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... (NUDOCS Accession Number 9904090219)

ATTACHMENT 1

IN 99-10

April 13, 1999

Prestressing Tendon Wire Breakage

During the 20th-year surveillance of the prestressing system of Calvert Cliffs Nuclear Power Plant, Unit 1, in

June-July 1997, the licensee (Baltimore Gas & Electric Company--BG&E) found a low lift-off value compared to

the prestressing force for one of the three randomly selected vertical tendons. The low lift-off value was

attributed to the uneven shim stack heights on the two opposite sides of the anchor-head. In accordance with

the plant's Technical Specifications (TSs) requirement, the licensee tested two additional vertical tendons

adjacent to this tendon. However, during the lift-off testing of one of these tendons, noises were heard that

indicated that some of the tendon wires might have broken. A visual examination of the tendon indicated that

three wires had broken at 12.7-17.2 centimeters (5-7 inches) below the bottom of the button-heads. Further

examination of the wires at the top of other vertical tendons revealed additional wire breakage. The licensee

expanded the lift-off testing and visual examination to 100 percent of the vertical tendons. Similar

degradation of other vertical tendons was found. As a part of its corrective action, the licensee is planning to

replace 63 of the 202 vertical tendons in Unit 1 and 64 of the 204 vertical tendons in Unit 2.

NRC's Information Notice 85-10, dated February 1985, and its supplement of March 1985, "Post-Tensioned

Containment Tendon Anchor-Head Failure," described prestressing tendon anchor-head failures at both units

of the Joseph M. Farley Nuclear Plant. The root cause analysis of that event indicated that there were several

factors contributing to it, such as, free water in the grease caps at the bottom of the vertical tendons, high

hardness of the anchorage material, and high stresses in the anchor-heads. The failures had resulted from

hydrogen embrittlement of the anchor-head material. The free water in the bottom grease caps of the vertical

tendons may have accumulated (through a number of years) from the poorly drained top anchorage ledge of

the vertical tendons (similar to the condition at the Calvert Cliffs containments). However, at Farley, wire

failures did not occur.

In general, American Society for Testing and Materials (ASTM) A-421 ("Uncoated Stress-Relieved Wire for

Prestressed Concrete") wires (used at both Farley and Calvert Cliffs) are not susceptible to hydrogen-induced

cracking. However, BG&E's engineering evaluation indicated brittle hydrogen-induced cracking on a third of

the broken wires. All of the brittle fractures were preceded by severe corrosion. The engineering evaluation

also indicates that some of the brittle fractures may have occurred earlier but were not found during the

periodic inspections. To ensure that the stressing washers (anchor-heads) are not affected, BG&E visually

examined the anchor-heads at both ends of the vertical tendons and found no visible cracks or fractures. The

lessons learned from these two events indicate that the prestressing wires and anchor-heads of the button- headed prestressing systems are susceptible to cracking from tensile stress and hydrogen-induced corrosion.

The severity and the extent of corrosion depend upon the ability of the moisture to reach unprotected areas, the duration of exposure, and the material characteristics.

In April 1998, the NRC staff visited the Oconee Nuclear Station (OCN) to discuss issues related to the

licensee's license renewal technical report. As part of the visit, the staff performed a walkdown inspection of

the OCN containments and other structures. The following observations are related to the prestressing system

degradations reported by the staff:

  • At Tendon 12V6, the concrete beneath the 5.1-centimeter (2-inch) thick anchor-bearing plate had

spalled along the outer edge; a cavity existed below the plate. Cracks in the concrete beneath the outer

edge of the bearing plates were observed for a number of tendons.

  • Tendon grease had leaked from a significant number of hoop tendons in the containments of all three

units at OCN.

  • The Unit 1 tendon access gallery showed water infiltration and standing water at several locations. The

licensee indicated that the Unit 2 tendon access gallery at one time held as much as 51 centimeters (20

http://www.nrc.gov/reading-rmldoc-collections/gen-comm/info-notices/1999/in99010.html

03/13/2003

Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... inches) of water. The licensee is periodically purging the tendon galleries of all three units to remove

water.

The licensee addressed these and similar degradations under the requirements of its TSs or in accordance with

Criterion XVI of 10 CFR Part 50, Appendix B.

ATTACHMENT 2

IN 99-10

April 13, 1999

Effects of High Temperature on the Prestressing Forces in Tendons

In 1979-1980, the licensee of the Robert E. Ginna Nuclear Power Plant, Rochester Gas & Electric Corporation, reported lower than predicted forces for several of the vertical tendons in its partially prestressed containment

structure. Extensive analysis and testing performed by the licensee indicated the cause of the consistently

lower prestressing forces to be appreciably higher (than estimated) relaxation of prestressing steel as a result

of the average high temperatures around the tendons. The 1000-hour and 10,000-hour testing performed at

the Fritz Engineering Laboratory of Lehigh University of the wires taken from some of the vertical tendons

showed that the 40-year relaxation could be between 15.5 and 20 percent at 32 Celsius (C) (90 Fahrenheit

[°F]), an average temperature around the tendons during the summer. The wire relaxation assumed in the

design was 12 percent.

During the fourth surveillance of tendon forces in February 1990 at Virgil C. Summer Nuclear Station, the

licensee, South Carolina Electric & Gas Co., discovered that the forces in the 115 vertical tendons were lower

than expected. Because the wires used in the prestressing tendons were of the same size, type, and

relaxation property as those used in the Ginna tendons, the licensee concluded that the reason for low

prestressing forces was the higher (than considered) relaxation of prestressing wires. As in the case of the

Ginna containment, the average temperature around the tendons was determined to be 32 C (90 F). To

remedy the situation, the licensee retensioned the vertical tendons at an average lock-off force of 0.685 of the

guaranteed ultimate tensile strength of the wires.

During the performance of 20th-year tendon surveillance in November-December 1992 at Turkey Point

Station, Units 3 and 4, the licensee, Florida Power & Light Co., found that the measured prestressing forces of

a number of randomly selected tendons in both units were appreciably lower than the predicted forces. The

lower tendon forces were found in hoop, vertical, and dome tendons. The licensee, with the assistance of its

consultant, investigated the root cause and implemented necessary corrective actions. The root cause

investigation indicated that the most probable cause for lower prestressing forces (higher prestressing losses)

was an increased tendon wire steel relaxation resulting from the sustained high temperatures around the

tendons. Analysis of the meteorological data indicated that the average sustained temperatures around the

tendons could be estimated as 32 C (90 F). The supplier of the prestressing wire had provided 8 percent as

the wire relaxation loss at 20 C (68 F) and had indicated higher relaxation losses at higher temperatures. In

estimating prestressing forces, the utility had used 8 percent of the prestressing force in the tendons as the

loss due to relaxation.

Many of the prestressed concrete containments in the United States are typically subjected to average tendon

temperatures greater than 32 C (90 F) during hot weather or year around. Although only three plants

reported lower prestresssing forces (than the predicted) due to higher (than considered in the design)

relaxation, this condition may exist at many other plants with PCCs. However, plants may not experience

more than projected loss of prestressing force due to (1) conservative estimates of losses in the design, (2)

frequent unsystematic retensioning of tendons, (3) improper use of a method of trending measured tendon

forces, or (4) a combination of Items (1), (2), and (3).

Regulatory Guide (RG) 1.35.1, "Determining Prestressing Forces for Inspection of Prestressed Concrete

Containments" (July 1990), provides a simple method of documenting the installation forces, potential initial

losses in the prestressing force, and a method of incorporating the time-dependent losses. The basic concept

recommended in the guide is to establish predicted forces for all the tendons at various times since the

http://www.nrc.gov/reading-rmldoc-collections/gen-comm/info-notices1

999/in9901 O.html

03/13/2003

Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... complete installation of tendons. As the initial elastic shortening losses could vary from tendon to tendon, the

individual tendon predicted forces can be tabulated for comparison with the measured lift-off forces.

Sometimes the measured lift-off forces are adjusted to account for the initial elastic shortening loss or the

time-dependent losses. This adjustment defeats the purpose of making a correct comparison. Sometimes the

measured lift-off force is computed using the effective unbroken wires in the tendon, thus making the

comparison inappropriate. Calculation of the average effective wire forces in the tendon from the measured

tendon force is made only to ensure that it does not exceed 70 percent of the guaranteed ultimate tensile

strength of the wire.

In the United States, the main cause for the lower than predicted prestressing forces has been identified as

the high relaxation of the tendon steel. However, in France, where the prestressing tendons are grouted and

their prestressing forces could not be directly measured, the cause for the indirectly estimated low

prestressing forces has been identified as creep and shrinkage of the containment concrete. The basic creep of

the concrete could also be higher (than estimated) at higher temperatures, giving rise to higher loss of the

prestressing force. These two effects on prestressing forces could not be separated without substantial

research. On the basis of the results of the relaxation tests on the prestressing steel, it appears that the

dominant contributing factor is the higher relaxation of the prestressing steel. Nevertheless, the containment

integrity has to be demonstrated on the basis of the availability of the minimum required prestressing force.

ATTACHMENT 3

IN 99-10

April 13, 1999

Comparison and Trending of Prestressing Forces

In 1994, during the 20th-year tendon surveillance of Three Mile Island Nuclear Station, Unit 1 (TMI-1),

prestressed concrete containment (conforming to Regulatory Guide [RG] 1.35 [Revision 3]) and TMI-1 Technical Specifications, the licensee, General Public Utilities Nuclear Corporation, subjected a total of 11 tendons (5 hoop, 3 vertical, and 3 dome) to lift-off testing. On the basis of the data from this lift-off testing, in

conjunction with data from the previous surveillance tests for each group of tendons, the licensee originally

performed a trending analysis for each group of tendons and concluded that none of the tendon groups would

go below each group's minimum required force during the 40-year plant life. However, the licensee

subsequently performed a linear regression analysis using individual lift-off forces rather than the average of

the lift-off forces and found that the hoop tendons would go below the minimum required force beginning in

the 25th year.

The licensee of the Oconee Nuclear Station, Duke Power Company, performed the sixth tendon surveillance on

Oconee Unit 3 in the summer of 1995. The licensee, using the averages of the lift-off forces obtained to that

date, plotted them on a graph on which the predicted upper bound and lower bound are shown and concluded

that the mean lift-off force for each group fell below the required values (i.e., the lower bound). A subsequent

trending analysis on the basis of individual lift-off forces indicated that the dome tendon force began to go

below the minimum required force about 8 years after the structural integrity test (SIT). For other tendon

groups in Unit 3, the tendon forces were not predicted to go below the minimum required value until 40 years

or more after the SIT. Since Oconee Units 1 and 2 are identical to Oconee Unit 3, the licensee performed a

trend analysis for each of these units and found that the vertical tendon forces in Unit 1 and Unit 2 were

predicted to go below the minimum value at 30 years and 10 years after the SIT, respectively. These results

were caused by additional wire breakage of other vertical tendons. The licensee expanded the lift-off testing

and visual examination to 100 percent of the vertical tendons. Similar degradation of other vertical tendons

was found. As a part of the licensee's corrective action, the licensee used the same tendons for lift-off testing, thus subjecting the tendons to cyclic loading. A more appropriate methodology is the random selection of

tendons to be tested.

In 1996, the V. C. Summer licensee, South Carolina Electric & Gas Co., performed the 15-year (fifth) tendon

surveillance. For each group of tendons, the licensee used the averages of the lift-off forces from each

surveillance and plotted the five points from the five surveillances on a graph. The five points are joined by

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Information Notice No. 99-10: Degradation of Prestressing Tendon Systems in Prestresse... line segments. On the basis of this graph, the licensee concluded that the tendon force levels in the three

groups of tendons would be acceptable beyond the 20-year surveillance. A subsequent linear regression

analysis using individual lift-off forces, instead of the averages, indicated that the dome and hoop tendons

would not go below the minimum required forces until 32 years after the SIT. The vertical tendons that had

been retensioned were predicted not to go below the minimum required force until 42 years after the SIT.

In 1993, the licensee of the Crystal River Nuclear Plant, Unit 3, Florida Power Corporation, performed the fifth

tendon surveillance. A detailed study that considered both the average and the individual lift-off forces was

performed. On the basis of the results of linear regression analysis, the licensee concluded that with the

exception of the vertical tendons' result, which gave a slightly steeper slope for the individual data points, there was no difference between the two methods for the hoop and dome tendons. The prestressing forces in

the three groups of tendons were indicated to be above the minimum required forces well beyond the 40-year

plant life.

The simple regression model is a mathematical way of stating the statistical relationship that exists between

two variables. In this case, the tendon force (TF) is a dependent variable that varies with time (T), the

independent variable. The two principal elements of a statistical relationship are (1) the tendency of the

dependent variable TF to vary in a systematic way with the independent variable T, and the scattering of

points about the "curve" that represents the relationship between TF and T. For a small sample size (2% of

the population), using the average of the TF for each surveillance test masks the true variation between TF

and T. Therefore, an analysis using the individual lift-off forces for the regression analysis gives results that

could be statistically validated.

On the basis of experience, as evidenced from the examples presented and the statistical analysis, it is

evident that the appropriate method for evaluating the adequacy of the tendon force is the regression analysis

using the individual lift-off forces as the data for the trend analysis.

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