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t i, ; I CD RAFT) TECHNICAL EVALUATJON REPORT DESIGN CODES,.DESIG*N*CRITE-RIA, . AND LOADING COMBINATIONS CONSUMERS POWER COMPANY PALISADES NUCLEAR POWER STATION NRC DOCKET NO.

50-255 NRCTACNO.

41502 NRC CONTRACT NO. NRC-03-79-118 Prepared by Franklin Research Canter The Parkway at Twentieth Street Philadelphia, PA 19103 Prepared fa; i f.Juclear Regulatory Commission Washington, D. C. 20555 FRC PROJECT C5257 FRC ASSIGNMENT 11 FRCTASK 324, SEP Topic III-7 .B T. Stilwell, M. Darwish, Author: E *. M. Wallo, R. Koliner, P. Noell, R. H. Hollinger FRC Group Leader: T. c. St:i.lwell Lead NRC Engineer:

D. Persinko January 20, 1982 (Rev. 3) This report was prepared as an account of wor'.c: sponsored by an agency of the Unitad States Government.

Neither the United States q.,:>varnmant nor any agel"r.y thereof, or a!"y of their employees, makes any warranty, i;irESSed or implied, or assumes any legal liability or responsibility for anv third party's use, or the results of such use, of any information.

apparatus, product or process disclosed in this report,. or represents that its use by such third party would not infringe privately owned rights.

DO.CKET fllE COPY R.esearch Center A Division of The FrankJin Institute 0202190306 820212 . PDR ADOCK 05000255 *p ,. .. PDR The Beniamin Fninldin Paricway, Phila .. ?a. I S103 (2151448-1000

-t *. 'l ::* *,1 . *:*, j ' ' *-** '**{ .. ,; ; ' .:,.. .-.. ' .. ' **.i . ':] j ;--*j *-:-* *.j ' :..* 1 -. ._: i . -CD RAFT) TECHNICAL EVALUATION REPORT DESIGN CODES, DESIGN CRITERIA, .AND *LOADING COMBINATIONS CONSUMERS POWER COMPANY PALISADES NUCLEAR POWER STATION NRC DOCKET NO. 50-255 NRC TAC NO. 41502 NRC CONTRACT NO. NRC--03-79-118 . Prepared by Franklin Research Center The Parkway at Twentieth Street Philadelphia, PA 19103 Prepared for Nuclear Regulatory Commission Washington, D. C. 20555 FRC PROJECT C5257 FRC ASSIGNMENT 11 FRCTASK 324, SEP Topic III-7.B T. Stilwell, M. Darwish, Author: E. M. Wallo, R. Koliner, P. Noell, R. H. Hollinger FRC Group Leader: T. C. Stilwell Lead NRC Engineer:

D. Persinko Jantlary 20, 1982 (Rev. 3) This report was prepared as an account of work sponsored by an agency of the United States Government.

Neither the United States Government nor any agency thereof, or any of their employees, makes any warranty, pressed or implied, or assumes any legal liability or responsibility for any third party's use, or the results of such use, of any information, apparatus, product or process disclosed in this report,. or represents that its use by such third party would not infringe privately owned rights. -ftnklin R.esearch Center A Division of The FrankJin Institute The Benjamin Franklin Parilway, Phila., Pii. I 9103 (215) 448-I 000

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-'<J . :--.. .l '.":l :5 .. e Section l 2 3 4 5 6 7 8 9 10 CONTENTS Title INTRODUCTION

* BACKGROUND REVIEW OBJECTIVES.

METHOD 7.1 Information Retrieval

* 7.2.

of Information Content. 7.3 Code Comparison Reviews

* 7.4 Assessment of the Potential Impact of Code Changes * ._ *.. -: m-cs2s7-324 Page l 2 3 4 7 9 11 11 12 12 15 7. 4.1 Classification of Code Changes * * * * *

* 16 7.4.l.l General and Conditional Classifications of Code Change Impacts * * * * *

* 17 7.4.l.2 Cade Impacts on Structural Margins *

* 18 7.5 Plant-Specific Code Changes * . * * * * *

* 20 PALISADES SEISMIC CATEGORY I STRUCTURES  

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* 21 STRUCTURAL DESIGN CRITERIA LOADS AND LOAD COMBINATION CRITERIA 10.l Description of Tables of Loads and Load Combinations iii . -...,_ ..... .. 22 24 24 Research Center I\ OMsion ol The Franldfn lnslilule  

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*' . -.. --.*.; . **': TER-C5257-324 CONTENTS (Cont.) Section 11 10.2 Load Definitions 10.3 Design Load Tables, "Comparison of Design Basis Loads" 10.4 Load Combination Tables, "Comparison of Load Combination Criteria" REVIEW FINDINGS 11.l Major Findings of AISC-1963 vs. AISC-1980 Code Comparison.

11.2 Major Findings of ACI 318-63 vs. ACI 349-76 Code Comparison

* 11.3 Major Findings of ACI 301-63 vs. ACI 301-72 (Revised 197_5) Comparison . . 11.4 Major Findings of ACI. 318-63 vs. ASME B&:PV Code, Section III, Division 2, 1980 Code Comparison . 12  

13 RECOMMENDATIONS 14 REFERENCES APPENDIX A -SCALE A AND Ax CHANGES DEEMED INAPPROPRIATE TO PALISADES PLANT APPENDIX B -APPENDIX C -APPENDIX D -APPENDIX I -SUMMARIES OF CODE FINDINGS -COMPARATIVE EVALUATIONS AND MODEL STUDIES ACI CODE,PHILOSOPHIES CODE COMPARISON REVIEW OF TECHNICAL DESIGN .BASIS DOCUMENTS DEFINING CURRENT LICENSING FOR SEP TOPIC III-7 .B (SEPARATELY BOUND) '

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___ ----. *-. _, TER-C5257-324 CONTENTS (Cont.) Section Title APPENDIX II -CODE COMPARISON REVIEW OF AISC SPECIFICATION FOR THE DESIGN, FABRICATION, AND ERECTION OF STRUCTURAL STEEL FOR BUILDINGS FOR THE* YEARS 1980 VS. 1963 (SEPARATELY BOUND) APPENDIX III -NOT APPLICABLE TO PALISADES PLANT APPENDIX IV -CODE COMPARISON REVIEW OF CODE REQUIREMENTS FOR NUCLEAR SAFETY RELATED CONCRETE STRUCTURES ACI 349-76 VS. BUILDING CODE REQUIREMENTS FOR FORCED CONCRETE ACI 318-63 (SEPARATELY BPUND) APPENDIX V -COMPARISON REVIEW OF THE SPECIFICATIONS APPENDIX VI FOR STRUCTURAL CONCRETE FOR BUILDINGS, ACI 301-72 (1975 REVISION)

VS. ACI 301-63 (SEPARATELY BOUND) CODE COMPARISON REVIEW OF CODE REQUIREMENTS.FOR ASME B&PV CODE SECTION III, DIVISION 2, 1980 (ACI 359-80) VS. BUILDING CODE REQUIREMENTS FOR REINFORCED CONCRETE ACI 318-63 (SEPARATELY BOUND) enklin Research Center A Olvlslon ol The Franklin lftllilllle v

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.. FOREWORD This Technical Evaluation Report was prepared by Franklin Research Center under a contract with the U.S. Nuclear Regulatory Commission (Office of Nuclear Reactor Regulation, Division of Operating Reactors) for technical assistance in support of NRC operating reactor licensing actions. The technical evaluation was conducted in accordance with criteria established by the NRC.

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.l *,,I **': . -: ** . *. .****.: ' ' . . ; '*, ' . l .. * .. *. 1* PALISADES SER ADDENDA -SEP TOPIC III-7.B To be inserted before Section 10.2 in FRC report: Current criteria require consideration during plant design of thirteen load combinations for most structures, as shown in the load combination tables. These specific requirements were not in effect at the time when SEP plants were designed.

Consequently, other sets of load-combinations were used. In comparing actual and current criteria, an attempt was made to match each of the load combination?

actually considered to its nearest counterpart under present requirements.

For example, consider a plant where the SSE was addressed in combination with other loads, but not in combination with the effects of a LGCA (load combination 13). The load combination tables would reflect this by showing that load case 9 was addressed, but that load case 13 was not. If six load cases were considered, only six (nearest counterpart) load cases are indicated in the table---not partial fulfillment of all 13. The scale rankings assigned to loads and load combinations in tables are intended as an aporaisal of plant status, with respect to demonstration of compliance 1 t1ith current design criteria, based on infonnation available to the NRC prior to the inception of the SEP review. A number of structurally related SEP topics review some loads and load combinations in detail based upon current calculational methods. In order that a consistant basis for the tables be maintained,.

they are based upon load combination considered in. the original design of-the facility, or in the case of they are upon the combinations used in the design of the modification.

Loads which were not inciuded in the original design or have increased in magnitude and have not been specifically addressed in another SEP topic should be addressed by the licensee.

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: l. INTRODUCTION For the Seismic Category I buildings and structures at the Palisades Nuclear Power Station, this report provides a comparison of (a) the structural design codes and loading criteria used in the design with (b) the corresponding codes and criteria used for current licensing of new plants. The objective of the code comparison review is to identify deviations in design criteria from current criteria, and to assess the effect of these deviations on margins of safety, as they were originally perceived and as they would be perceived today. The work was conducted as part of the Nuclear Regulatory Commission's (NRC) Systematic Evaluation Program (SEP) and provides technical assistance for Topic III-7.B, "Design Codes, Design Criteria, and Load Combinations." The report was prepared at the Franklin Research Center unaer NRC Contract No. NRC-03-79-118

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: 2. BACKGROUND With the development of nuclear power, provisions addressing facilities for nuclear applications were progressively introduced into the codes and standards to which plant building and structures are designed.

_ Because of this evolutionary development, older nuclear power plants conform to a number of different versions of these codes, some of which have since undergone considerable revision.

There has likewise been a corresponding development of other licensing criteria, resulting in similar non-uniformity in many of the requirements to '-which plants have been licensed.

With this in mind, the NRC undertook an extensive program to evaluate the safety of 11 older plants (and eventually all plants) to a conunon set of criteria.

The program, entitled the Systematic Evaluation Program (SEP), employs current licensing criteria (as defined by NRC's Standard Review Plan) as the conunon basis for these evaluations.

* To* make the necessary determinations,.

the NRC is investigating, under the SEP, 137 topics spanning a broad spectrum of safety-related issues. The work reported herein constitutes the results of part* of the investigation of one of these topics, Topic III-7.B, "Design Codes, Design Criteria, and Load Combinations." This topic is charged with the compar-ison of structural design criteria_

in effect in the late 1950's to the late 1960's (when the SEP plants were constructed) with those in effect today. Other SEP topics also address other aspects of the integrity of plant structures.

All these-structurally oriented tasks, taken together, will be used to assess the structural-adequacy of the SEP plants with_ regard to current requirements.

The determinations with respect to structural safety will then be integrated into an overall SEP evaluation encompassing the entire spectrum of safety-related topics * *The report addresses only the_Palisades plant.

Research Center, A Division of The Franklin lnldtute  

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: 3. REVIEW OBJECTIVES The broad objective of the NRC's Systematic Evaluation Program (SEP) is to reassess the safety of 11 older nuclear power plants in accordance with the intent of the requirements governing the licensing of current plants, and to provide assurance, possibly requiring backfitting, that operation of these plants conforms to the general level of safety required of modern plants. Task III-7.B of the SEP effort seeks to compare actual and current structural design criteria for the major civil engineering structures at each SEP plant site, i.e., those important to shutdown, containment, or both, and therefore designated Seismic Category I The broad safety objective of SEP Task III-7.B is (when integrated with several other interfacing SEP topics) to assess the capability of all Seismic Category I structures to withstand all design conditions stipulated by the NRC, at least to a degree sufficient to assure that the nuclear power plant can be safely shut down under.all circumstances.

The objective of FRC's present effort under Task III-7.B is to provide, through code comparisons, a rational basis for making the required technical assessments, and a tool which will assist in the. structural review. Finally, the objective of the present report is to present the results of FRC's Task III-7.B work as they relate to the Palisades Nuclear Power Station.

Research Center A OMsion cl The FranJcUn Institute

. ** ... i .. .... _,. . :___*--***--'----'* TER-C5257-324 .e 4. SCOPE FRC was asked to review the provisions of the structural codes and dards used for design of SEP plant Seismic Category I civil engineering tures* and compare them with the corresponding provisions governing current licensing practice.

The review includes the containment and all Category I structures within and exterior to it. Explicit among the criteria to be reviewed are loads and loading combinations postulated for these structures.

To carry out the review, FRC was assigned the following tasks: l. Identify current design requirements, based on a review of NRC Regulations; lOCFRSO.SSa, "Codes and Standard";

and the NRC Standard Review Plan (SRP). -2. Review the structural design codes-, design criteria, design and analysis procedures, and load combinations (including combinations involving seismic loads) used in the design of all Category I structures as defined in the Final Safety Analysis Report (FSAR) for each SEP plant. 3. Based upon the plant-specific design codes and standards identified in Task 2 and current licensing codes and standards from Task 1, identify plant-specific deviations from current licensing criteria for design codes and.criteria.

: 4. Assess the significance of the identified deviations, performing (where necessary) comparative analyses to quantify significant deviations.

Such analyses may be made on elements (beams, columns, frames, and the like) and should be explored over a range of parameters representative of plant structures.

: 5. Prepare a Technical Eval)lation Report for each SEP plant including:  

----a. comparisons of plant design codes and criteria to those currently accepted for licensing

: b. assessment of _the significance of the deviations

: c. results of any comparative stress analyses performed in order to . make an assessment of the significance of the**code changes upon safety_margi 0 s *in general, these are the structures normally examined.in licensing reviews under Section 3.8 of the SRP. (but note the list at the end* of this section of structures specifically excluded from FRC's scope).

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: d. overall evaluation of the acceptability of structural codes used at each SEP plant. A number of SEP topics examine aspects of the integrity of the structures composing SEP facilities.

Several of these interface with the Task III-7.B effort as shown below: III-1 III-2 III-3 III-4 III-5 III-6 III-7 .A. III-7.C III-7 .D Designation Classification of Structures, Components, Equipment, and Systems (Seismic and Quality) Wind and Tornado Loading Hydrodynamic Loads Missile Generation and Protection Evaluation of Pipe Breaks Supports Inservice.Inspection of Structures Delamination of Prestressed Concrete Structures . Structural Integrity Tests Because they are covered either elsewhere within the SEP review or within other NRC programs, the following matters are explicitly excluded from the FRC scope: Mark I torus shell, supports, vents, local region of drywell at vent penetrations Reactor pressure vessel supports, steam generator supports, pump supports Equipment supports*in SRP 3.8.3 Research Center A Olvtslon ot The FranklJn lnstilute  Reviewed in Generic Task A-7. Reviewed in Generic Task A-2, A-12. Reviewed generally in Topic III-6, Generic Task A-12.

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* Other component supports (steel and concrete)

Testing of containment Inservice quality control/assurance Determination of structures that* should be classified Seismic Category I Shield walls and subcompartments inside containment Masonry walls Seismic analysis Research Center A Division ol The Frenldln lnllltute

* Specific supports have been analyzed in detail in Topic III-6. (Component supports may be included later if items of concern applicable to component supports are found as a result of reviewing the structural codes.) Reviewed in Topic III-7.D. Shoqld be considered in FRC review only to the extent that it affects design criteria, design allowables.

Aspects of inservice inspection are being reviewed in Topics III-7.A and III-3.C Not in FRC scope. Reviewed in Generic Task A-2. Reviewed generically in .IE Bulletin.*

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.':.. .*; , .. *: .*.: . . . , ... * .. .; . i TER-C5257-324 S. MARGINS OF SAFETY, There are several bases upon which margins of safety* may be defined and discussed

* The most often used is the margin of safety based on yield strength.

This is a particularly useful concept when discussing the behavior of steels, and became ingrained into the engineering vocabulary at the time when steel was the principal metal of engineering structures.

In this usage, the margin of safety reflects the reserve capacity of a structure to withstand extra loading without experiencing an incipient permanent change of shape anywhere throughout the structure.

Simultaneously, it reflects the reserve load carrying capacity existing before the structure is brought to the limit for which an engineer could be certain the computations (based on elastic behavior of the metal) applied. This is the cQnventional use of the term and the meaning which engineers take as intended,.

unless the tem is.further qualified to show something else is meant. Thus, if a structure is stated to have a margin of safety of 1.0 under a given set of loads, then it will be generally understood that every load on the structure may be sim1,1ltaneously doubled without encountering (anywhere) inelastic stresses or deflections.

On the other hand, if (under load) a structure has no margin of safety, any increment to any load will cause the structure to experience, in a least one (and possibly.more than one) location, some permanent distortion (however small) of its original shape. However, because the yield strengths of common structural steels are . generally well below their ultimate strengths, the engineer knows that in most (but not in all) the structure possesses substantial reserve beyond his computed margin--to carry additional load. There are other useful ways, however, to speak of safety margins and these (not the conventional one) are particularly relevant to the aims of the SEP program. *Factors of safety (FS) are related to margins of safety (MS) through the relation MS = FS -l.

Research Center A Division of The Fninklln lnsdtute ;-

*.* .. ,, " 'i, ______ , __ .. ___ <<**.__ ___ _ TER-CS257-324 One may speak of margins of safety with respect to code allowable limits. This margin reflects the reserve capacity of a structure to withstand extra loading while still conforming to all criteria governing its design. One may also speak (if it is made clear in advance that this is the intended meaning) of margins of safety against actual failure. Both steel and concrete structures exhibit much higher nmargins of safety* on this second basis than is shown by computation of margins of safety based on code allowables.

These latter concepts of "margin of safetyn are very significant to the SEP review. Indeed the basic review concept, at least as it relates to structural integrity, cannot be easily defined in any quantitative manner without considering both. The SEP review concept is predicated on the assumption that it is unrealistic to expect that plants which were built to, and were in compliance with, older codes will still conform to current criteria in all respects.

The SEP review seeks to assess whether or not meet the "intent" of lic1msing cr,iteria as defined by the Standard Review Plan (SRP). The objective is not to require that older plants be brought into conformance with all SRP requirements,to the letter, but rather to assess whether or not their design is sufficient to provide the general level of safety that current licensing requirements With respect to aspects of the SEP' program that involve the integrity of structures, the SEP review concept can be rephrased in a somewhat more fashion in terms of these two "margins of safety." Thus, it is not expected or demanded that all structures show positive margins of safety based upon code allowables in meeting all current SRP requirements; but it is demanded that margins of safety based upon ultimate strength are not only positive, but ample. In fact, the critical judgments to be made (for SEP plants) are: ,,.__**"==>.

* to what extent may current code margins be infringed upon. 2. what minimum margin of safety based on ultimate strength must be assured. The choice of method for Topic III-7.B review can be discussed in terms of these two key considerations.*

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: 6. CHOICE OF REVIEW APPROACH The approach taken in the review process depends, to a large degree, upon which of the two previously stated key questions one chooses to emphasize and address first. One could give primary consideration to the second. If this approach is chosen, one first sets up a minimum margin of safety (based on failure) that will be acceptable.for SEP plants. This margin is to be computed in accordance with current criteria.

Then, one investigates structures designed in accordance with earlier code provisions, and to different loading combinations, to see if they meet the chosen SEP margin when challenged by current loading combinations and evaluated to current criteria.

This gives the appearance of being efficient.

The review proceeds from the general ' (the chosen minimum margin of safety) to the particular (the ability of&deg;a previously designed structure to meet the chosen margin). Moreover, issues are immediately resolved on a "g_or n0"".'9C?" basis. Hc;:>wever, the initial step is* not easy; neither are the necessary evaluations.

One is dealing with highly loaded structures in regions where materials behave inelastically. making in such areas is sure to be difficult, and likely to be highly controversial.

The alternative approach is taken in this review. It proceeds from the particular to the general, and places initial emphasis upon seeking .to answer (for SEP plants) questions as to what, how many, and of what magnitude are the infringements on current criteria.

No new rulemaking is involved (at least .at the outset). All initial assessments are based on existing criteria.

Current and older codes are compared paragraph-by-paragraph to see the effects that code changes may have on the load carrying ability of individual elements (beams, columns, frames, and the like). It should be noted that this process, although involving judgments, is basically fact-finding  

--not decisionmaking

* This kind of review is painstaking, and there is no assurance in advance that it in itself will be decisive.

Research Center A Division of The FnmkUn lrwltute It may turn out, after examination of the

,; **".i . : * *. ,1 .. " *. :.-.. -' -TER-CS257-324 facts, that designs predicated upon the older criteria infringe upon current design allowables in many cases and to extensive depths. If so, such information will certainly be of value to the final safety assessment, but many open questions will remain. On the other hand, it may turn out that infringements upon current criteria are infrequent and not of great magnitude.

If this is the case, many issues will have been resolved, and questions of structural integrity sharply focused upon a few remaining key Center A Division ol The Franlclln lnllflule  * ---  

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: 7. METHOD A brief description of the approach used to carry out SEP Topic follows. For discussion of the work, it is convenient to divide it into six areas: 1. information retrieval assembly .2. appraisal of information content 3. code comparison reviews 4. code change impact assessment

: s. plant-specific review of the relevancy of code change impacts 6. summarizing plant status vis-a-vis design criteria changes. 7.1 INFORMATION RETRIEVAL The initial step (and to a lesser extent an ongoing task of the review) was to collect and organize necessary informationo At the beginning of FRC's _work assignment, NRC forwarded files relevant to the work. These submittals.

included pertinent sections of plant FSARs, Standard Review Plan (SRP) 3.8, response to questions on Topic III-7.B previously requested of licensees by the NRC, and other relevant data and reports

* FRC organized these submittals into Topic files on a plant basis. The files also house additional information, subsequently received, and other documents developed for the plant review. A number of channels were used to gather additional information.

These included information requests to NRC; letter requests for additional mation sent to licensees; plant site visits; and retrieval of representat.ive structural drawings, design calculations, and design specifications.

In addition, a separate file was set up to maintain past and present structural codes, NRC Regulatory Guides, Staff Position Papers, and other relevant documents (including, where available, reports from SEP tasks interfacing with the III-7.B effort).

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* 7.2 APPRAISAL OF INFORMATION CONTENT Most of the information sources were originally written for purposes other than those of the Task III-7.B review. Consequently, much of the information sought was embedded piecemeal in the documents furnished.

These sources were searched for the relevant information that they did contain. Generally it was found that information gaps remained (i.e., some needed items were not referenced at all*or, when they were found, often not specific enough for Task III-7.B purposes).

The information found was assembled and the gaps were filled through the information retrieval efforts mentioned earlier. 7.3 CODE COMPARISON REVIEWS The codes and standards used to represent current licensing practice were selected as described in Appendix I of this report. Briefly summarized, the criteria selection corresponds to NUREG-800, of NRC's SRP, the operative document providing guidanc:e to NRC reviewers on licensing mat;ters (see

* Reference l). Next, the Seismic Category I structures at the Palisades Nuclear Power. Station were identified (see Section 8). For these, on a structure basis, the codes and standards which were used for actual design were likewise identified (see Section 9). Each code was then paired with its counterpart that would govern design were the structure to be licensed today. Workbooks were prepared for each code pair. The workbook format consisted of paragraph-by-corresponding paragraph photocopies of the older and the current versions laid out side-by-side on 11 by 17-inch pages. A central column between the codes was left' open to provide space for reviewer comments.

The code versions were initially screened to discover areas where the text either remained identical in both versions or had been reei:Hted without changing technical content. Code paragraphs which were found to be essentially the same in both versions were so marked in the comments column.

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* ... *l . -. . . .. :*/: i -** . . . , . -**-* .. =-*-** ........ : . TER-CS257-324 The review then focused on the remaining portions of the codes where textual disparities existed. Pertinent conunents regarding such changes were entered. Typical comments address either the reason the change had been introduced, or the intent of the change, or its impact upon safety margins, or a combination of such considerations.

As can be readily appreciated, many different circumstances arise in such evaluations--some simple, some complex. A few examples are cited and briefly discussed below. Provisions were found where code changes liberalized requirements, i.e., less stringent criteria are in force today than were formerly required.

Such changes are introduced from time to time as new information becomes available regarding the provision in question.

Not infrequently code committees are called upon to protect against failure modes where the effects are well known; but too little is yet clear concerning the actual failure mechanism and the relative importance of the contr.ibuting factors. The committee often cannot defer action until* a full investigation has been completed.,.

but 'must *act on behalf of safety. Issues such as these are usually resolved with prudence and caution--sometimes by the adoption of a rule (based upon experience and judgment) known to be conservative enough to assure safety. Subsequent tigation may produce evidence showing the adopted rule to be over-cautious, and provide grounds for its relaxation.

On the other hand, some changes which on first view may appear to reflect a relaxation of code requirements do not in fact actually do so. Structural codes tend to be documents with interactive provisions.

Sometimes apparent liberalization of a code paragraph may really reflect a general tightening of criteria, because the change is associated with stiffening of requirements elsewhere.

To cite a simple example, a newly introduced code provision may be found making it unnecessary to check thin flanged, box section beams of relatively small depth-to-width ratio for buckling.

This might appear to be a relaxation of requirements.

However, elsewhere the code has also introduced a require-Research Center A Division of The Franklln lnslilule  . 

-.,, --*' TER-C5257-324 ment that the designer must space end supports closely enough to preclude buckling.

Thus, code requirements have been tightened, not relaxed. In the code comparison review, wherever it was found that code ments had truly been relaxed, this was noted in the reviewer's comments.

Because liberalization of code criteria clearly cannot give rise to safety issues concerning structures built to more stringent requirements, such matters were not considered further. On the other hand, whenever it was clear that a code change introduced more stringent criteria, the potential impact of the change on margins of safety shown for the structure was assessed.

When it was felt that the change (although more restrictive) would not significantly affect safety margins, this judgment was entered in the commentary.

When it was clear that the code change had the potential to significantly affect the perc.eived margin of safety, this was noted in the comments and the paragraph was. flagged for further consideration.

the* effects of a code change are not e-asily seen.* Indeed, depending upon a number of factors,*

the change may reflect a tightening of requirements for some structures and a liberalization for others. When doubtful or ambiguous situations were encountered, the effect of the code change was explored analytically using simple models. A variety of analytical techniques were used, depending on the situation at hand. One general approach was to select a basic structural element (a beam, a column, a frame, a slab, or the like) and analytically test it, under both the older and the current criteria.

Although one must be cautious about*claiming that results from simplified models may be totally applicable to the more complex situations occurring in real structures, it was felt that such examples provided reasonable guidance for making rational judgments concerning the impact of changed code provisions on perceived margins of safety. 7.4 ASSESSMENT OF THE POTENTIAL IMPACT OF CODE CHANGES As the scope of the Task III-7.B assignment makes clear, a limited objective is sought (for the present) :with respect to assessment of the effects of code changes on Seismic Category I structures.

The scope of review is not set at the level of appraisal of individual, as-built structures on plant sites. Correspondingly, the review does not attempt. to make quantitative assessments as to. the structural adequacy under current NRC criteria of specific structures at particular SEP plants

* To the contrary, the scope of the review is confined.to the comparison of former structural codes and criteria with counterpart current requirements.

Although the review is therefore car.ried out with minimal reference to actual structures in the field, th.e assessments of code change. impacts that can be made at the code comparison level hold considerable significance for actual structures

* Research Center A Division of The Franldln lnslltute

*_-._ .. -: TER-C5257-324 In this respect, two important points should be noted: 1. The review brings sharply into focus the changes in code provisions that may give rise to concern with respect to structural margins of safety as perceived from the standpoint of the requirements that NRC now imposes upon plants currently being licensed.

The review simultaneously culls away a number of code changes that do not give rise to such concerns, but which (because they are there) would otherwise have to be addressed, on a structure-by-structure basis. 2. The effects of code'changes that can be determined from the of code review are confined to potential or possible impacts on actual structures.

Review, conducted at the code comparison level, cannot determine whether or not potentially adverse impacts are actually realized in a given structure.

The review may only that this may be the case. For example, current criteria may require demonstration of integrity of a structure under a loading combination that includes an additional load not specified in the corresponding loading combination.

to which the structure was designed.

If the non""consider.ed load is large .A (i.e., in the of or larger than* other major loads that were \W" . included) , . then i.t. is quite possible that some members in* the structure would appear overloaded as viewed by current criteria.

Thus a potential concern exists. However, no determination as to actual overstress in any member can be made by code review alone. Actual margins of safety in the controlling member (and several others*) must certainly be examined before even a tentative judgment of this kind may be attempted.

In order to carry out the code review objec.tive of identifying criteria chariges that had the potentia*l to give rise to concern about* possible impairment of perceived margins of safety, the following scheme classifying code change impacts was adopted. 7.4.1 Classification of Code Chanqes Where code changes involve technical content (as opposed to those which are editorial, organizational, administrative, and the like), the changes are classified according to the following scheme. *The addition-of a new load can change the location of the_point of highest stress.

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Center . A Division of The Franklin lnslitute  

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* TER-CS257-324 Each such code change is classified according to its potential to alter perceived margins of safety* in structural elements to which it applies. categories are established:

.. Four Scale A Change -The new criteria have the potential to substantially impair margins of safety as perceived under the former criteria.

Scale Ax Change -The impact of the code change on margins of safety is not immediately apparent.

Scale Ax code changes require analytical studies of model structures to. assess the potential magnitude of their effect upon marg_ins of safety. Scale B Change -The new criteria operate to impair margins of safety but not enough 'to cause engineering concern about the adequacy of any structural element. Scale C Change -The new cr.iteria will give rise to larger margins of safety than were exhibited under the former criteria.

7.4.l.l* General and Conditional Classifications of Code Change Impacts Scale ratings of code changes are found in* two different forms in .this .. report. For example, some may be designated as "Scale A," and others as "Scale C." Others may have dual designation, such as "Scale A if ---[a condition statement]

or Scale C if --[a second condition statement]." In assigning scale classifications, an efficient design to original criteria is assumed. That is, it is postulated that (a) the provision in question controls design and (b) the structural member to which the code provision applies was proportioned to be at (or close to) the allowable limit. The impact scale rating is assigned accordingly.

If the code change is Scale A, and it applies (in a particular structure) to a member which is not highly stressed, then this may afford excellent grounds for asserting that this particular member is but it does not *That is, if (all other considerations remaining the same) safety margins as computed by the older code rules were to be recomputed for an as-built structure in accordance with current code provisions, would there be a difference due only to the code change under consideration?

Research Center A Division ot The Franklin lnslllllte

:** : .. J * .. ; . 4,--* .... TER-C5257-324 thereby downgrade the ranking to, say, a Scale B change for that member. The scale ranking is not a function of member stress* nor a ranking of member adequacy.

The scale system ranks code change impact, not individual members. However, a number of code provisions are framed so that the allowable limit is made a function of member proportion.

When this kind of a code provision is changed, the change may affect members of certain proportions one way and members of other proportions differently.

For example, assume a change in column design.requirements is introduced .in the code and this is framed in terms of radius of gyration.  

*The new rule acts to tighten design requirements for slender columns, but liberalizes former requirements for columns that are not slender. This change may be rated Scale A for slender columns, and simultaneously, Scale C for non-slender ones. Although some columns now appear to be Scale A columns while others appear to be Scale C columns, the distinction between them resides in the code, and.is not a reflection of.member adequacy *. Clearly, it is still code changes that are ranked; but, in this case, the code change does not happen to affect all columns in a unilateral way. 7.4.1.2 Code Impacts on Structural Margins This classification of code changes identifies both (a) changes that have the potential to significantly impair perceived margins of safety (Scale A changes) and (b) changes that have the potential to enhance perceived margins of safety (Scale C changes).

Emphasis is subsequently placed on Scale A changes, not on Scale c* changes. The purpose of the code comparison review is to narrow down and bring into sharper focus the areas where structures shown adequate under former criteria may not fully comply with current criteria.

Once such criteria changes have been identified, actual structures may be checked to see if the potential concern. is applicable to the structure.

Depending upon a number of structure-specific circumstances, this may or may not. be.so. * * *.There. are* exceptions, but* these. are code-related, not adequacy-related  

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Center A Division of The Franlclln lnalltute .

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d .l l TER-C5257-324 The same thing is true of Scale C changes, i.e., those that may enhance perceived structural margins. Specific structures must be examined to see if the potential benefit is actually applicable to the structure.

If it is applicable, credit may be taken for it. However, this step cari only be taken at the structural level, not at the code level. A simple example may help clarify this point. Assume a steel beam exists in a structure designed by AISC 1963 rules for the then-specified loading combination.

Current criteria require inclusion of an additional load in the loading combination (Scale A change), but the current structural code permits a higher allowable load if the beam design conforms to certain stipulated proportions (Scale C change). Several circumstances are possible for beams in actual structures, as shown below. New Load Maximum stress in beam under original loading conditions*was low with ample margin for tiOnal load Maximum stress in beam under original loading condition was near former allowable limit Maximum stress in beam under original loading condition was near former allowabie limit Higher Stress Limit Applicability immaterial Beam qualifies for higher stress limit Beam does not qualify for increased stress limit Results Beam adequate under current criteria Beam may be adequate under current criteria Beam unlikely to be adequate under current criteria It. is clear from this example that the function of the code review is to point out code changes that might impair perceived margins of safety, and that assessment of the applicability of the results of the review is best accomplished at the level.

Research Center A Dlvi!ion of The Franklln Institute

... * *'" * .. _ .. : .*.* . !-",. ., TER-C5257-324 7.5 PLANT-SPECIFIC CODE CHANGF.S There is substantial ov.erlap among the SEP plants in the codes and standards used for structural design. For example, several plants followed the provisions of ACI-318, 1963 edition, in designing major concrete structures.

Thus, the initial work (comparing older and current criteria) is not plant-specific.

However, when reviewed codes are packaged in sets containing only those code comparisons relevant to design of Seismic Category I structures in a particular SE!> plant, the results begin to take on specific character.

* particular SEP plant have then been identified.

However, this list is almost surely overly long because the list has been prepared without reference to actual plant structures.

For example, the code change list might include an item relating to recently introduced provisions for the design of slender columns, and none -actually exii;t in any in that particular plant. In-depth examination of design drawings, audit of structural analyses, and review of plant specifications were beyond the scope of _the III-7.B task. Accordingly, FRC did not attempt such activities.

However, occasional reference to such documents was necessary to the review work. Consequently, FRC was able to cull from the list some items that were obviously inappropriate to the plant structures.

Wherever this was the reason for removal was documented, but no attempt was made to remove every such item. ----Code changes that, for structures in general,.may be significant but did not appear applicable to any of the Category I structures at Palisades were relegated to Appendix A *. The Scale A or Scale A changes that remained are x . listed on a code-by-code basis in Sectfon 11 * .

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: 8. PALISADES SEISMIC CATEGORY I STRUCTURF.s SEP Topic III-1 has for its objectives the classification of components, structures, and systems with respect to both quality group and seismic designation.

The task force charged with this responsibility has presented its findings in Reference S, and the following structures have been determined to be Seismic Category I: A. Containment Includes:

Cylindrical wall, dome, and slab Liner (no credit for structural strength under mechanical loads) Equipment hatch Personnel locks B. Internal Structures Reactor cavity Steam generator compartments (reviewed in Generic Task A-2) Biological shield (reviewed in Generic Task A-2) C. EXternal Structures

: l. Auxiliary building (entire building except for administrative and access control areas) Includes:

Control room Diesel generator compartments Switchgear room (The above three items are in a common enclosure with three floor levels) Spent fuel pool New fuel storage area Radwaste area Pump rooms (for ECCS and

: 2. Turbine building (only the basement area which houses auxiliary feedwater pumps is Seismic Category I) 3. Intake/discharge structures including pump house for service water pumps

* Research Center A Division of The Franldln lnsli!Ute   

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: 9. STRUCTURAL DESIGN CRITERIA The structural codes governing design of the major Seismic Category I ., structures for the Palisades Nuclear Power Generating Station are in the following table. Structure A. Containment

* 2*. Liner 3. Personnel locks and equipment hatches B. . Internal Structures Design Criteria ACI 318-63 ACI 301-63 (specifications for concrete)

ASME B&PV Section III, 1965 . (Provisions of Article* 4*) ASME B&PV Section VIII (undated), (Fabrication tices for Welded Vessels Only) ASME B&PV Section IX (undated), (welding procedure and welders qualifications only) ACI 318-63 for Concrete ASME B&PV Section III, 1965, for steel ACI 318-63 AISC 1963 *The two si3nificant applications of this article

: 1. determination of thermal stresses in the liner 2. analysis of pipe penetration attached .to the liner.

Research Center A DMsJon of The Franklin Institute  Current Criteria ASME B&PV Code, Section III, Division 2, 1980 (subtitled ACI 359-80) ACI 301-72 (Rev. 1975) ASME B&PV Code, Section III, Division 2, 1980 (Subtitled ACI 359-80) ASME B&PV Code, Section III, Division 2, 1980 (subtitled ACI 359-80) ACI 349-80 

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: l. Auxiliary building Control room Fuel pool Diesel generator room Radwaste facility

* 2. Service water, intake, pump house, and discharge structures

: 3. Turbine building auxiliary feedwater pump enclosure Design Criteria AISC 1963 ACI 318-63 AISC 1963* ACI 318-63 AISC 1963 ACI 318-63 TER-C5257-324 Current Criteria AISC 1980 ACI 349-76 AISC 1980 ACI 349-76 AISC 1980 ACI 349-76  

: 1. Palisades FSAR Section 5 and Appendix B (Identifies codes for Items A and B) 2. Seismic Review of Palisades Nuclear Power Plant Unit I, Phase I Report -

Research Center A qlvisicn ol The Franklin Institute

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: 10. LOADS AND LOAD COMBINATION CRITERIA ------------10 .1 DESCRIPTION OF TABLES OF I.DADS AND I.DAD COMBINATIONS The requirements governing loads and load combinations to be considered in the design of civil engineering structures for nuclear service have been revised since the older nuclear power plants were constructed and licensed.

Such changes constitute a major aspect of the general pattern of evolving design requirements; consequently, they are singled out for special tion in the present section of this report. The NRC Regulatory Guides and Standard Review Plans provide guidance regarding what loads and load combinations must be considered.

In some cases, the required loads and load combinations are also specified within the ing structural design code; other structural codes have no such provisions and take loads and load combinations as given a priori. In this report, loads and load combinations are treated within the present section whether or not the structural design codes .also include them. Later sections of this report address, paragraph by paragraph, changes in text between design codes current at the time the plant was constructed and those governing design today; however, to avoid repetition, code changes related to loads and load combinations will not be again although they may appear as provisions of the structural design codes.* To provide a compact and systematic comparison of previous and present requirements, the facts are marshalled in tabular form. Two sets of tables are used: 1. load tables 2. load combination tables. Both sets of tables'are constructed in a9cordance with current requirements for Seismic Category I structures, i.e., the load tables list all loads that must be considered in today's design of these structures, and the load combination tables list all combinations of these loadings for which current licensing procedures require demonstration of structural integrity.

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.. ! =: *.:1 TER-C5257-324 In general, the loads and load combinations to be considered are determined by the structure under discussion.

The design loads for the structure housing the emergency power _diesel generator, for example, are quite different than those for the design of the containment vessel. Consequently, structures must be considered individually.

Each structure usually requires a load table and load combination table appropriate to its specific design requirements.

The design requirements for the various civil engineering structures within a nuclear power plant are echoed in applicable sections of NRC's Standard Review Plan (SRP)

The tables in the present report correspond to, and sununarize, these requirements for each structure.

A note at the bottom of each table provides the reference to the applicable section of the Standard Review Plan1 Section 10.2 of this report lists, for reference, the load symbols used in the charts together with their definitions.

and the load tables are filled in according to the following scheme: 1. The list of potentially loads (according to current requirements) is examined to eliminate loads which either do not occur on, or are not significant for, the structure under consideration.

: 2. The loads included in the actual design basis are then checked against the reduced list to see if all applicable loads (according to current requirements) were actually considered during design. 3. Each load that was considered during design is next screened to see if it appears to correspond to current requirements.

Questions such as the following are addressed:

Were all the individual loads encompassed by the load category definition represented in the applied loading? Do all loads appear to match present requirements (1) in magnitude?

(2) in method of application?

: 4. An annotation is made as to whether deviations from present requirements exist, either because of load omissions or because the loads do not correspond in magnitude or in other particulars.

: 5. If a deviation is found, a judgment (in the form of a scale ranking) is made as to the potential impact of the deviation on perceived margins of safety. 6. Relevant notes or comments are recorded.

Research Center A OMslon ol The Franklln Institute TER-C5257-324 Of particular importance to the Topic III-7.B review are comments ing that the effec_ts of certain loadings (tornado and seismic loads, in particular) are being-examined under-other SEP -topics. -rn all such cases, the findings of these special SEP topics (where review in depth of the indicated loading conditions will be undertaken) will be definitive for the overall SEP effort.

* Consequently, no licensee investigation of such issues is required under Topic III-7.B nor is such effort within the scope of Topic III-7.B (see Section 4). Licensee participation in the resolution of such issues may, however, be requested under the scope of other SEP topics devoted to such issues. . After the load tables have been filled out, the load combination tables are compiled.

Like the load tables, the load combination are up to current requirements and the load combinations actually used in the design basis are matched against these requirements.

For ease of comparison, the load combinations actually used are imposed on-the load combinations currently required.

This -.is accomplished in two steps: 1. Currently specified combinations include loads sufficient for the most general cases. In particular applications, some of these are either inappropriate or insignificant.

Therefore, the first step is to strike all loads that are not applicable to the structure under consideration from all load combinations in which they appear. 2. Next, loads actually combined are indicated by encircling (in the appropriate load combinations) each load contributing to the summation considered for design. Thus, the comparison between what was actually done and what is required today is readily apparent.

If the load combinations used are in complete accord with current requirements, each load symbol on the sheet appears as either struck or encircled.

Load combinations not considered and loads omitted from the load combinations stand out as unencircled items. A scale ranking is next assigned to the load combinations;

_however (unlike the corresponding ranking of loads), a .scale ranking is not necessarily assigned *to each one. When the load_combinations used for design correspond  

---*closely to current requirements, scale ratings may be assigned to all combina-e Center A Oivtsion of The Franldln lnslilUle  

. : * .. =-. .,,. . ------* ---** ****---*** .. ... , . "** ______ ,_ _____ _ TER-CS257-324 tions. However, when the number of load combinations considered in design was substantially fewer than current criteria prescribe, it did not appear to serve any engineering purpose to rank the structure for each currently required load combination.

Instead, a limited number of loading cases (usually two) were ranked. The following considerations guided the selection of these cases: 1. For purposes of the SEP review, it was not believed necessary to require an extensive reanalysis of structures under all load combinations currenfly specified.

: 2. SEP plants have been in full power operation for a number of years. During this time, they have experienced a wide spectrum of operating and upset conditions.

There is no evidence that major Seismic Category I structures lack integrity under these operating conditions.

: 3. The most severe load occur under emergency and accident conditions.

These are also the conditions associated with the ** greatest consequences to public health and safety. 4. If demonstration of structural adequacy under the most .severe load combinations c'urrently spec.ified for emergency and accident conditions is provided, a reasonable can be drawn that the structure is also adequate to sustain the less severe loadings associated with less severe consequences.

10.2 LOAD DEFINITIONS D Dead loads or their related internal moments and forces (such as permanent equipinent loads). E or E 0 Loads generated by the operating basis earthquake.

F Loads resulting from the of pre-stress.

H Hydrostatic loads under operating conditions.

Ha Hydrostatic loads generated under accident conditions, such as post-accident internal flooding. (FL is sometimes used by others* to designate post-!.OCA internal flooding.)  

*See, for example, SRP 3.8.2.

Research Center A Division cf The Fnmlclln IMlltutc  

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... . . ----*-i* -* TER-C5257-324 L Live loads or their related internal moments and forces (such as movable equipment P 0 or Pv Loads resulting from pressure due to normal operating conditions

* Pa Pressure load generated by accident conditions (such as those generated by the postulated pipe break accident).

Ps All pressure loads which are caused by the actuation of safety relief valve discharge including pool swell and subsequent hydrodynamic loads. Ro Pipe reactions during startup, normal operating, or shutdown conditions, based on the critical transient or steady-state condition.

Ry or Ra Pipe reactions under accident conditions (such as those generated by thermal transients associated with an accident).

Rs All pipe reaction loads which are generated by the discharge of safety relief valves. Ta Thermal loads under accident conditions (such as those generated by a postulated pipe break accident).

T 0 Thermal effects and *1oads during startup, normal operating, or shutdown conditions, based on the most critical transient or steady-state condition.

Ts All thermal loads which are generated by the discharge of safety relief valves. W Loads generated by the design wind specified for the plant. W' or Wt

* Loads generated by the design tornado specified for the plant. Y* ] Tornado loads include loads due to tornado wind pressure, created differential pressure, and tornado-generated missiles.

Equivalent static load on the structure generated by the reaction on the broken pipe during the design bas1s Equivalent static load on the structure .generated by the ment of the fluid jet from the broken pipe during the design basis accident.

Ym . Missile impact equivalent static. load on the structure generated by or during the design basis accident, such as pipe whipping.

Research Center A OMsion of The Franklin Institute

; : * .:*l ***; TER-C5257-324 The load combination charts correspond to loading cases and load tions as specified in the appropriate SRP. Each chart is associated with a specific SRP as identified in the notes accompanying the chart. Guidance with respect to the specific loads which must be considered in forming each load combination is provided by the referenced SRP. All SRPs are prepared to a standard format; consequently, subsection 3 of each plan always contains the appropriate load definitions and load combination guidance.

Center A Oivlolcn cf The Franklin lnsdtute TER-C5257-324

: 10. 3 DESIGN LOAD TABLES "COMPARISON OF DESIGN BASIS LOADS" e.** Research Center A OMsion of The F111nklln IMllllllE  

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