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ASME B

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Title: ASME B


1
ASME BPV Code for In-Service Inspection of
Nuclear Containment Buildings
  • Steven G. Brown, PE

2
Introduction
  • Why is this of interest outside the nuclear
    industry?
  • Professional Development Hour
  • More than that sharing information across
    various industries for improvement of the
    profession
  • Acknowledgements
  • K. R. Rao Campion Guide to ASME Boiler and
    Pressure Vessel Code
  • Working Group Containment
  • Entergy
  • Disclaimer The views presented are my own
  • If its right, its because my mentors got it
    right,
  • If its messed up, its probably my original
    idea.

3
Terminal Objective
  • At the conclusion of the class the engineer will
    have a basic understanding of the current rules
    requiring inservice inspection of nuclear
    containment vessels.

4
Enabling Objectives
  • State the purpose of containment vessel as used
    at commercial nuclear power plants in the US
  • Describe the general types of containment vessels
    currently used in the US commercial nuclear power
    industry.
  • State the difference between Class MC and Class
    CC components.
  • State the regulations requiring inservice
    inspection of nuclear containment buildings.

5
Enabling Objectives (cont)
  • Be able to state the section of ASME Code
    providing requirements for inservice inspection
    of Class CC components of nuclear containment
    vessels.
  • Discuss the type and frequency of inservice
    examinations for nuclear power plant containment
    vessels.

6
Purpose of Containment
  • 10 CFR 50 - GDC 16 Containment Designs - Key
    design requirement for all U.S. commercial
    nuclear plants.
  • Establish an essentially leak tight barrier
    against the uncontrolled release of radioactivity
    into the environment
  • Ensure that the containment design conditions
    important to safety are cont exceeded for as long
    as required for post-accident conditions.

7
Typical Steel Containment Vessels
  • Steel Pressure Vessel Class MC
  • Typically Carbon Steel
  • Approx. 40 to 60 psi
  • gt 100 Feet Diameter
  • gt 200 Feet Tall
  • Shell thickness 1.5 or more
  • Concrete Shield Building

Containment Design Diagrams on this and
subsequent slides are from EPRI TM-102C
8
Typical Steel Containment Vessels
  • BWR Mark I Class MC (typical)
  • Nominal 62 psi
  • Removable Head
  • Torus suppression pool

9
Typical Steel Containment Vessels
  • BWR Mark II (Shown) Clas MC Typical
  • Nominal 45 psi
  • Removable Head
  • Suppression pool below
  • BWR Mark III (Not Shown) May be MC or CC
  • Large vessel with internal drywell
  • Suppression pool internal around drywell

10
Typical Concrete Containment
  • Concrete Structure with steel liner
  • Concrete provides structural element Class CC
  • Steel liner provides leak tightness Class MC

11
Typical Concrete Containment
  • Post-Tensioned Concrete Containment
  • Concrete is kept under compression by a system of
    steel tendons
  • Tendon system and rebar are Class CC.

12
Provisions for Containment Inspections and Testing
  • 10 CFR 50 - GDC 53 Containments shall be
    designed to permit
  • Appropriate periodic inspection of all important
    areas, such as penetrations
  • An appropriate surveillance program
  • Periodic testing at containment design pressure
    of the leak tightness of penetrations

13
Philosophy of Containment Examination
  • ASME IWE and IWL define requirements for
    containment examination
  • Preservice
  • Inservice
  • Requirements based on Industry Experience and
    Environmental Conditions
  • Visual Examination of Containment
  • Testing for Tendons
  • Pressure / Leakage Testing per 10 CFR App J

14
History of Code Requirements
  • IWE 1st published 1981 (Class MC Components)
  • Weld Based Examinations
  • Very similar to rules for Class 1 and 2 nuclear
    components.
  • Subsequently addressed general degradation of
    surface areas
  • Incorporated by rulemaking (10 CFR 50.55a) in
    1996
  • Required all containments to be treated as MC or
    CC
  • Included conditions for use

15
History of Code Requirements
  • IWL 1st published 1988 (Class CC Components)
  • Provided rules for examination of concrete
    surfaces
  • Similar to regulatory requirements already in
    Regulatory Guides 1.35 and 1.35.1
  • Regulatory Guides only required for post
    tensioned containments
  • Incorporated by rulemaking (10 CFR 50.55a) in
    1996
  • IWL replaced use of the Regulatory Guides
  • Transition period was allowed for plants using
    regulatory guides
  • Applicable to ALL concrete containments

16
Current Regulatory Requirements
  • 10 CFR 50.55a
  • Incorporates ASME BPV Code Section XI by
    reference with conditions
  • References ASME Section XI Sub-Section IWE for
    Class MC containments and Liners of Class CC
    containments
  • References ASME Section XI Sub-Section IWL for
    Class CC containments

17
Containment Leak Testing
  • 10 CFR 50 Appendix J
  • Periodic testing of containment vessel and
    penetrations
  • Type A tests Integrated Leak Rate Test
  • Type B and C tests Local Leak Rate Tests

18
IWE Examinations
  • IWE-1100 SCOPE
  • This Subsection provides requirements for
    inservice inspection of Class MC pressure
    retaining components and their integral
    attachments, and of metallic shell and
    penetration liners of Class CC pressure retaining
    components and their integral attachments in
    light-water cooled plants.

19
IWE Examinations
  • Exempted Components
  • Components outside the boundaries of the
    containment system
  • Embedded or inaccessible portions of containment
    (with limitations on what modifications to plant
    can embed)
  • Piping, pumps, and valves (examined per either
    IWB or IWC)

20
IWE Examinations
  • General Schedule for Inservice
  • 10 year inspection interval
  • Divided into 3 inspection periods (3 or 4 years)
  • Provisions for shifting interval (and one of the
    periods) by one year
  • Preservice (in general)
  • Exam conducted prior to placing component
    inservice
  • Includes repair or replacement
  • Same exam as required for periodic inservice exam

21
IWE Examination Tables
22
IWE Examination Tables
23
IWE Details
  • Category E-A Containment Surfaces
  • E1.11 Accessible Surfaces
  • General Visual Each Period.
  • Includes Bolted Connections VT-3 per 10 CFR
    50.55a
  • E1.12 Wetted Surfaces of Submerged Areas
  • General Visual Each Interval
  • VT-3 per 10 CFR 50.55a
  • E1.20 BWR Vent System (Mark I)
  • General Visual Each Interval
  • VT-3 per 10 CFR 50.55a
  • E1.30 Moisture Barriers
  • General Visual Each Period

24
IWE Details Moisture Barriers
25
IWE Details
  • Category E-C Augmented Examination
  • Applicable to areas subject to accelerated
    degradation or with previously noted degradation
  • E4.11 Visible Surfaces
  • Detailed Visual Each Period.
  • VT-1 per 10 CFR 50.55a
  • E4.12 Surface Area Grid
  • Ultrasonic Thickness Measurement (UT) Each Period

26
IWL Examinations
  • IWL-1100 SCOPE
  • This Subsection provides requirements for
    preservice examination, inservice inspection, and
    repair/replacement activities of reinforced
    concrete and the post-tensioning systems of Class
    CC components, herein referred to as concrete
    containments as defined in CC-1000 Section III
    Design Code.

27
IWL Examinations
  • Exempted Components
  • Steel portions not backed by concrete
  • Shell metallic liners
  • Penetration liners
  • Inaccessible tendon end anchorages (with
    limitations)
  • Concrete surfaces covered by the liner,
    foundation material, or backfill or otherwise
    obstructed. (Aging concerns for buried concrete
    addressed in later editions of code.)

28
IWL Examinations
  • General Schedule for Inservice Examination
  • 1, 3, and 5 years following Structural Integrity
    Test (SIT)
  • Within 6 months on either side of anniversary
  • Total inspection window of 1 year
  • 10 years after SIT and every 5 years thereafter
  • Within 1 year on either side of anniversary
  • Total inspection window of 2 years
  • 1 year plus or minus 3 months for concrete
    repairs
  • Preservice
  • Similar to IWE
  • Unique role of RPE

29
IWL Examinations
  • Two Major Divisions
  • Category L-A Concrete Surfaces
  • All concrete containments
  • Category L-B Unbonded Post-Tensioning System
  • Post tension design only
  • Tendons divided by type
  • Separate population for tendons impacted by
    repairs
  • Provisions for sites with multiple plants / units

30
IWL Examination Tables
31
IWL Details
  • Category L-A Concrete Surfaces
  • L1.11 All Accessible Areas
  • General Visual Each Inspection to identify
    suspect areas
  • Resolution per RPE
  • L1.12 Suspect Areas
  • Detailed Visual
  • Up close exam to determine if the area is a
    problem
  • Performed by or under the direction of a
    Registered Professional Engineer

32
IWL Details
  • Category L-B Unbonded Post-Tensioning Systems
  • Sample Size
  • Sample of Tendons
  • 4 of Each Type
  • Minimum of 4 and Maximum of 10
  • Reduced sample for good inspection history
  • 2 of Each Type
  • Minimum of 3 and Maximum of 5
  • Separate population with reduced sample size for
    tendons affected by repair

33
Overview of Post-Tension Containment
34
Parts of a Tendon Anchorage
35
Exposed Tendon Anchorage
36
Uninstalled Tendon
37
Parts of a Tendon Anchorage
38
IWL Details
  • L2.10 Tendon
  • Tendon Force / Elongation Test
  • Hydraulic Ram connected to end of tendon
  • Load cell measures force needed to lift tendon
    off of the shims
  • Common Tendon
  • One tendon is measured in each inspection
  • Results trended to ensure tendon stress remains
    above the minimum needed by design for life of
    the plant

39
IWL Details
  • L2.20 Wire or Strand
  • Destructive sample of one wire (typical tendon up
    to 186 wires) from one tendon of each type NOT
    the common tendon
  • Visual exam for entire length
  • Sample from each end, the middle and area of most
    severe degradation tested for
  • Yield Strength,
  • Ultimate Strength, and
  • Elongation

40
IWL Details
  • L2.30 Anchorage Hardware and Surrounding
    Concrete
  • Detailed Visual Entire Sample Population
  • Includes
  • bearing plates,
  • anchor heads,
  • wedges,
  • buttonheads,
  • shims, and
  • concrete extending 2 feet from edge of the
    bearing plate.

41
IWL Details
  • L2.40 Corrosion Protection Medium
  • Sample from each end of each examined tendon
  • Chemical analysis for
  • Water content,
  • Water soluble chlorides, nitrates, and sulfides
  • Reserve Alkalinity (expressed as milligrams of
    Potassium Hydroxide)
  • L2.50 Free Water
  • The amount of any free water (if any) contained
    in the tendon cap is documented and analyzed to
    determine pH.

42
IWL Examinations
  • Additional 10 CFR 50.55a exam
  • Grease caps that are accessible must be visually
    examined to detect grease leakage or grease cap
    deformations.
  • Grease caps must be removed for this examination
    when there is evidence of grease cap deformation
    that indicates deterioration of anchorage
    hardware

43
Additional 10 CFR 50.55a Requirements
  • The licensee shall evaluate the acceptability of
    inaccessible areas when conditions exist in
    accessible areas that could indicate the presence
    of or result in degradation to such inaccessible
    areas.
  • Reporting Requirements
  • Other provisions

44
Objectives
  • State the purpose of containment vessel as used
    at commercial nuclear power plants in the US
  • Describe the general types of containment vessels
    currently used in the US commercial nuclear power
    industry.
  • State the difference between Class MC and Class
    CC components.
  • State the regulations requiring inservice
    inspection of nuclear containment buildings.

45
Enabling Objectives (cont)
  • Be able to state the section of ASME Code
    providing requirements for inservice inspection
    of Class CC components of nuclear containment
    vessels.
  • Discuss the type and frequency of inservice
    examinations for nuclear power plant containment
    vessels.

46
References
  • 10 CFR 50.55a
  • ASME BPV Code Section XI, Subsections IWE and
    IWL, 2004 Edition
  • Rao, K. R. (editor), Companion Guide to the ASME
    Boiler and Pressure Vessel Code, 3rd Edition
  • EPRI TM-102C

47
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