Rev 4 to, 180-Day Rept in Response to IE Bulletin 80-11 for Dresden Nuclear Power Station Units 2 & 3.

ML18041A125
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Site:	Dresden
Issue date:	09/14/1984
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H~t 180-DAY REPORT IN RESPONSE TO IE BULIETIN 80-11 I FOR DRESDEN NUCIEAR POWER STATION UNITS 2 AND 3 COMMONWEALTH EDISON COMPANY DOCKET NUMBERS 50-237 AND 50-249 PREPARED BY: Bechtel Power Corporation Report Date: September 14, 1984 Revision 4

~"I 1.0

2.0 INTRODUCTION

SCOPE TABLE OF CONTENTS Pacae 3.0 3.1 3.2 3.3 3.4 3.5

3.6 DESCRIPTION

OF MASONRY WALLS LOCATION FUNCTION WALL CONFIGURATION CONSTRUCTION MATERIALS CONSTRUCTION PRACTICES RECONCILIATION WITH 180-DAY REPORT, REVISION 3 4.0 REEVALUATION OF MASONRY WALLS 4.1 4.2 4.3 4.4 4.5 4.6 4.7S.o 5.1 6.0 POSTULATED LOADS ALLOWABLE STRESSES JUSTIFICATION OF THE REEVAIUATION CRITERIA SEQUENCE OF ANALYSIS METHOD OF ANALYSIS AND ACCEPTANCE CRITERIA ASSUMPTIONS AND ANALYSIS CONSTRAINTS MASONRY WALL TESTING PROGRAM RESULTS OF MASONRY WALL EVALUATION

SUMMARY

REFERENCES 6 6 7 7 8 10 10 APPENDIXES Masonry Wall Plans Additional Justification of the Reevaluation Criteria TABLES Masonry Walls-Function and Physical Properties Allowable Stresses in Concrete Masonry Walls Applied Loads and Evaluation Results 0050c

1.0 INTRODUCTION

This 180-day report is being issued in response to NRC IE Bulletin 80-11, dated May 8, 1980 (Reference 6.2).This report has been prepared by Bechtel Power Corporation, Ann Arbor, Michigan.for Commonwealth Edison Company's Dresden Nuclear Power Station, Units 2 and 3.Revision 4 of this report incorporates the status change of two masonry walls which Sere previously identified in Revision 3 as meeting the acceptance criteria.2.0 SCOPE The 180-day report furnishes information requested in Item 2b of NRC IE Bulletin 80-11.It deals solely with masonry walls identified in this report as safety-related.

Any masonry wall is considered safety-related when it is in proximity to or has attachments from safety-related piping or equipment such that wall failure could damage a safety-related system.The analyses are based on as-built conditions identified during site surveys of June and July 1980 and July 1981.

3.0 DESCRIPTION

OF MASONRY WALLS 3.1 LOCATION The figures in Appendix A show the location of all safety-related masonry walls.3.2 FUNCTION The function of each masonry wall is identified in Table 1 according to one of the following categories.

3.2.1 Fire Wall These walls were constructed to prevent the spread of fire from one side of the wall to the other according to the appropriate fire rating associated with the wall's thickness.

3.2.2 Partition Wall The partition walls are interior dividing walls whose sole purpose is to separate a portion of a room from the remainder.

3.2.3 Shieldin Wall The masonry shielding walls.typically made of solid units which are required to restrict radiation exposures.

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3.2.4 Blockout A blockout, made of masonry, seals an opening in a larger concrete wall.These openings are left in the concrete walls to provide for equipment installation or pipe penetrations before the opening is sealed with the masonry.3.2.5 Exterior Wall Exterior walls have at least a part of one face exposed to the outside, or are a part of the boundary of the Units 2 and 3 reactor turbine building complex.Only exterior walls are subject to wind or tornado loads.3.3 WALL CONFIGURATION Wall dimensions and boundary conditions for each wall are indicated in Table l.Each boundary is categorized as either a fixed support capable of providing both moment and shear resistance, a simple support resisting only shear forces, or a free edge through which no forces can be transferred.

3.4 CONSTRUCTION MATERIAI S 3.4.1 Hollow Masonr The hollow masonry units, which are identified on the design drawings, were specified as three-core blocks conforming to ASTM C 90.Grade N-I, Lightweight Aggregate.

Masonry walls.which are not shown on the design drawings, were assumed to consist of hollow units of the same type specified above.This assumption and the material properties of the hollow block were verified by plant-specific tests (see Section 4.7).Site surveys have found that the hollow masonry walls consist of both two-core and three-core units.3.4.2 Solid Masonr Two types of solid blocks (normal weight and magnetite) were used in the solid masonry construction.

Plant-specific tests determined the material properties of both types of block (see Section 4.7).3.4.3 Mortar The mortar used in the const, ruction of the hollow masonry walls was specified as ASTM C 270, Type N, with a 28-day compressive strength of 750 psi.Tests on the mortar used in the solid masonry found that it was, as a minimum.comparable to that specified for hollow masonry (see Section 4.7).0050c 0

Reinforcin Steel 3.4.4 According to the design drawings and specifications, the masonry walls are reinforced in the bed joint of every other course.This joint reinforcement consists of heavy-duty, continuous, rectangular, ladder type steel reinforcement, whose minimum yield strength is 65 ksi.Deformed bar steel, where shown on the drawings, has a minimum yield strength of 40 ksi.3.4.5 Anchors Masonry anchors have been used in certain locations to tie the masonry wall to an adjacent structural element.These anchors consist of two types: corrugated metal ties (dovetail anchors)which are used for connections to concrete walls or columns and 3/16-inch diameter adjustable bar ties welded to the supporting structural steel.3.5 CONSTRUCTION PRACTICES The masonry walls at the station were constructed in accordance with the applicable job and standard specifications for masonry work and have a high quality of masonry workmanship.

Conformance to applicable ASTM specifications was required for concrete blocks, mortar, reinforcing ties, and anchors.Storage and protection of blocks and walls, as well as cold weather protection, were specified.

The mortar joints of solid masonry walls were required to be constructed with full mortar coverage on all vertical and horizontal faces.The vertical joints were to be shoved tight.A full mortar bedding was specified for webs and face shells of the hollow masonry walls.Face shells were required to be fully buttered and pressed into place to ensure full, well-compacted horizontal and vertical mortar joints.3.6 RECONCILIATION WITH 180-DAY REPORT, REVISION 3 This latest revision of the 180-day report incorporates the following information:

3.6.1 The inclusion of walls 37 and 103 to the list of walls which do not meet the acceptance criteria.These walls were previously identified as meeting the acceptance criteria.With the incorporation of the above, a total of 64 masonry walls now meet the acceptance criteria.This represents a decrease of two walls over the total shown in Revision 3 of this report.0050c

4.0 REEVALUATION OF MASONRY WALLS 4.1 POSTULATED LOADS The loads which were considered in the evaluation of each wall are identified in Table 3.4.1.1 Dead Load D This load includes the dead weight of the wall and all permanently attached equipment, piping, conduit, and cable trays.The construction sequences have allowed the permanent dead load deflection to occur prior to the erection of the masonry walls.Therefore, the dead loads from the floor above are not transferred to the masonry walls.This load includes applicable live loads which can be transferred to the masonry wall through the floor framing.The live loads are not considered in those load combinations when they would relieve wall stresses.4.1.3 Attachment Loads Ro and Ra The attachment loads are localized loads which are a result of the reactions from the supports of piping, cable trays, conduits, HVAC ducts.and other systems.The reactions are determined for the normal operating or shutdown condition (Ro)and for the accident condition (Ra)which results from the thermal conditions generated by the postulated pipe break and includes Ro.Exterior walls are subject to a uniform pressure load corresponding to the design wind speed.The design wind speed for Dresden Units 2 and 3 is 110 miles per hour.4.1.5 Tornado Load Wt Exterior walls are subject to velocity pressures, differential pressures, and tornado missiles of the design tornado identified in the plant FSAR.The maximum tornado wind speed is 300 miles per hour.The maximum differential pressure is 170 psf.0050c

The following missiles are generated by the design tornado:~1 a.A telephone pole 35'-0" long.with a butt diameter of 13 inches, a unit weight of 50 pcf, and total weight of 1,200 pounds, and having a velocity of 150 miles per hour b.A 1-ton mass with a velocity of 100 miles per hour and a contact area of 25 square feet A probabilistic risk assessment for tornado missiles impacting walls D2-529-43C-74 and D2-517-316-105 was performed by others.The results of this analysis show the probability of a tornado missile striking either of these two walls to be approximately 10-7 per year.Therefore, the evaluation includes only the effects of wind pres'sure and depressurization.

The original design considered the buildings housing safety-related piping, conduit, cable trays, and equipment as sealed;therefore, tornado loadings do not affect interior walls.4.1.6 0 eratin Basis Earth uake Eo This load represents the seismic load generated by the operating basis earthquake (OBE).The design ground accelerations are as follows: a.Horizontal 0.1 g b.Vertical=0.067 g 4.1.7 Safe Shutdown Earth uake Es This load represents the seismic load generated by the safe shutdown earthquake (SSE).The design ground accelerations are twice those shown for the OBE.4.1.8 Thermal Loads To and Ta Thermal loads account for the effects of thermal gradients under normal operating (To)and accident (T)conditions.

The operating loads represent the most critical steady-state condition.

while the accident condition is a short-term thermal transient resulting from the postulated pipe leak, including To 0050c

4.1.9 Hi h-Ener Pi e Break The high-energy piping systems outside of the primary containment were investigated and their proximity to the safety-related masonry walls was established.

It was found that only a break in the RWCS would impact the masonry walls.However, a break in this system is precluded by means of leak detection and administrative action.Room temperature monitors are capable of responding to small RWCS leaks by providing indication and alarm to the control room.At this time, the operators shall take the appropriate action to isolate the RWCS, thereby preventing a full pipe rupture.The analysis of the masonry walls in proximity to the RWCS addresses the effects of the postulated pipe leak by considering the thermal transient discussed in Subsection 4.1.8 and differential pressure (Pa).This load is represented by an equivalent static pressure across a wall.4.2 ALLOWABLE STRESSES The allowable masonry stresses, excluding collar joint stresses, under normal load combinations are in accordance with those given by the Building Code Requirements for Concrete Masonry Structures (ACI 531-79)(Reference 6.1).Allowable stresses for extreme environmental and abnormal load combinations are increased by a factor of 1.67 over the above ACI code allowable stresses.For the mortar collar joints, the allowable shear and tension stresses are 10 psi for normal load combinations and 14 psi for extreme environmental and abnormal load combinations.

Allowable stresses applicable to the different types of masonry are given in Table 2.4.3 JUSTIFICATION OF THE REEVALUATION CRITERIA.Except as noted, allowable stresses of masonry units and mortar are based on the code values as published in ACI 531-79.These values are considered reasonable and conservative.

References to tests and other codes are provided in the commentary to ACI 531-79.It is noted that the allowable stresses are used for the evaluation of existing masonry walls and not for the design of new walls.Because building codes do not address abnormal and extreme environmental conditions, a factor of 1.67 was used to provide allowable stresses under these loading combinations.

Based on available margins of safety, this factor is considered to be reasonable.

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Published data on tension and shear strength of collar joints are almost nonexistent.

The ultimate collar joint stresses were therefore determined by plant-specific in situ tests.The allowable stress, as given in Section 4.2, was obtained by applying a safety margin of three to the minimum test result (see Section 4.7).Additional justification of the reevaluation criteria is provided in Appendix B.4.4 SEQUENCE OF ANALYSIS Each wall is initially analyzed considering only dead and seismic loads or dead and tornado loads, whichever appears most critical.For all walls which are found to be acceptable, the following applicable loadings are considered:

live load, attachment loads, pipe leak loa'ds, and interstory drift.4.5 METHOD OF ANALYSIS AND ACCEPTANCE CRITERIA 4.5.1 Stress Anal sis Based on the walls'oundary conditions, each wall is idealized as either a cantilever;,one-way strip, or two-way plate which is supported along at least two adjacent edges.The wall is then considered acceptable if all wall stresses under'll load combinations are less than or equal to the established allowable stresses.4.5.2 Stabilit and Slidin Anal sis Cantilever walls which do not meet the acceptance criteria for allowable stresses are analyzed with regard to overturning stability and sliding movement.A factor of safety against overturning is determined for both OBE and SSE loads.The minimum acceptable factors of safety are 2.0 for OBE and 1.5 for SSE conditions.

Before the wall is considered acceptable, the total wall movement, including rocking and sliding, must not adversely affect any safety-related items.4.5.3 Anal sis of Archin Effects Masonry walls with mortared joints at, both the top and bottom boundaries that do not meet, the acceptance criteria for allowable stresses are investigated for arching effects.The wall s capability of resisting horizontal loads, after ultimate tension stresses are exceeded, is developed when the wall jams at the top and bottom against the supporting structural members.The center of the wall cracks due to tension stresses, and a three-hinged arch is formed to resist the loads through compression stresses only.0050c

Design seismic loads generated by the safe shutdown earthquake are based on the peak acceleration of the applicable response criteria and a damping factor of 10%of critical.The stiffnesses of the supporting structural elements are accounted for in the analysis.Also, the deflection at the center hinge must be less than or equal to one third of the wall thickness.

If an arching wall meets the above requirementj it is considered acceptable when the compression stress develo'ped in the arch is less than or equal to the allowable flexural compression stress shown in Table 2.4.5.4 Interstor Drift Under Seismic Loads The effects of interstory drift are considered by determining the in-plane shear strain in the wall due to the relative displacement between the top and bottom of the wall.The allowable in-plane strains are 0.0001 for unconfined walls and 0.001 for confined walls.An unconfined wall is defined as a wall supported only on two adjacent sides.A confined wall is supported on any three sides or at the top and bottom of the wall (References 6.5, 6.6.and 6.7).These acceptance criteria are considered to be justified because none of the masonry walls carry a significant part of the buildings'tory shear or moment.Also, test data indicate that the gross shear strain of walls is a more reliable indicator for predicting the onset of cracking than loads or stresses.The out-of-plane relative displacement creates a bending moment in the wall only in the case where the top and bottom boundaries are supported.

and at least one represents a fixed condition.

None of the masonry walls at the Dresden station are effectively fixed at either the top or the bottom boundary;therefore, the out-of-plane interstory drift is not considered.

4.6 ASSUMPTIONS AND ANALYSIS CONSTRAINTS The following assumptions and constraints were employed in the reevaluation of the masonry walls.4.6.1 Nonsafety-related walls, anchor bolts.and embedments were not within the scope of the reevaluation.

4.6.2 All loads and load combinations outlined in the plant PSAR are considered in the reevaluation.

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4.6.3 The seismic loads on masonry walls are dependent on the damping characteristics of the material, which are expressed in percentage of critical damping as follows (References 6.3 and 6.4): a.Uncracked Masonry Wall, Out-of-Plane Acceleration 1)OBE: 2%2)SSE: 2'4 b.Vital Piping Systems.Horizontal and Vertical Accelerations 1)OBE: 0.5%2)SSE: 2't The plant FSAR specifies damping of 0.5'4 under OBE conditions for vital piping systems.For the purpose of this evaluation, vital piping are defined as all safety-related piping.c.Other Attached Systems, Horizontal and Vertical Accelerations

4.6.4 1)OBE

1'4 2)SSE'W This category includes nonsafety-related piping and safety-related and nonsafety-related conduit, cable trays, and HVAC ductwork.A masonry wall is considered an isotropic, elastic material.Its natural frequency is calculated using standard plate formulas.For a wall with an opening, the calculated frequency is reduced by 9%if the size of the opening equals or is greater than 15%of the wall area.The reduction is proportionally less for a smaller opening.For multiple openings, the largest'one is considered.

To account for variation in stiffness and mass of the wall, the above frequency is varied by+10%and the maximum response is used in the analysis.4~6.5 4.6.6 In accordance with the plant FSAR, the effects of the seismic loads of one horizontal and the vertical direction are added arithmetically.

Dead loads from the floor above are not considered being transferred to the masonry walls.A part of the live load from these floors is transferred to the walls;however, it is not considered if it will relieve wall stresses.0050c

4.6.7 4.6.8 Shear and tensile stresses are not transferred across the continuous vertical mortar joints of walls laid in stack bond or the vertical mortar joints of a wall boundary adjacent to a concrete structural member.Standard, prefabricated sections of the horizontal joint reinforcing steel are provided at all corners of masonry walls.However, their contribution to th4 strength capacity of this intersection is not considered.

4.7 MASONRY WAIL TESTING PROGRAM A sampling and testing program was performed at the station.This program provided the material properties necessary to determine the allowable stresses applicable for the masonry wall evaluations.

The testing was also considered to fulfill the special inspection requirements of Reference 6.1;thus allowing the use of inspected allowable stresses.The findings of the program are as follows.4.7.1 The hollow masonry block has an average compressive strength of 2,100 psi on the net area.4~7.2 4.7.3 The solid masonry block has an average compressive strength of 3,400 psi.r The mortar used in both the hollow and solid masonry construction is.as a minimum, comparable to ASTM C 270, Type N.4.7.4 The average unit weight of the hollow masonry is 110 pcf and the average unit weight for the solid masonry is 132 pcf.4.7,5 In situ tests were performed on two walls to determine the strength of the mortared collar joint.The resulting failure stresses were 37.6 and 32.7 psi.4.7.6 One wall (D2-534-33G-21) was found to consist of magnetite aggregate.

Tests indicate the block of this wall to have a compressive strength of 6,000 psi and a unit weight of 235 pcf.The mortar was found to be comparable to ASTM C 270, Type M.5.0 RESUITS OF MASONRY WALL EVALUATION Table 3 lists the results of the masonry wall reevaluation.

The criteria used to justify the wall's acceptance or mode in which it does not meet the criteria are identified.

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5.1

SUMMARY

~~'he following summarizes the results of the reevaluation of 96 safety-related masonry walls: 5.1.1 Total number of walls meeting the acceptance criteria: 64 5.1.2 Total number of walls which do not meet the acceptance criteria: 32

6.0 REFERENCES

6.1 Building Code Requirements for Concrete Masonry Structures, ACI 531-79, American Concrete Institute, Detroit, Michigan, 1979 6.2 USNRC IE Bulletin 80-11, dated May 8.1980'.3 Final Safety Analysis Report (FSAR)for the Dresden Nuclear Power Station Units 2 and 3 6.4 Damping Values for Seismic Design of Nuclear Powez Plants, U.S.Nuclear Regulatory Commission Regulatory Guide 1.61, October 1973 6.5 Becica, I.J.and H.G.Harris, Evaluation of Techniques in the Direct Modeling of Concrete Masonry Structures, Dzexel University Structural Models Laboratory Report M77-1.June 1977 6.6 6.7 Fishburn.C.C., Effect of Mortar Properties on Strength of Masonry, National Bureau of Standards Monograph 36 U.S.Government Printing Office, November 1961 Mayes, R.L.;Clough, R.W.;et al.Cyclic Loading Tests of Masonry Piers, 3 Volumes, EERC 76/8, 78/28.79/12 Earthquake Engineering Research Center, College of Engineering University of California, Berkeley, California 6'60-Day Report in response to IE Bulletin 80-11 for Dresden Nuclear Power Station Units 2 and 3, Commonwealth Edison Company.Docket Numbers 50-237 and 50-249 dated July 3, 1980 0050c

TABLE 1 MASONRY WALLS-FUNCTION AND PHYSICAL PROPERTIES Wall Function Thick-ness W thea Bond Sine (hei ht x width)Shown on Boundary Design Su rt Drawin s Remarks D2"570-40M-1 D2-570-39M-2 D2-570-43K-3 D2-570-42J-4 D3-570-45K-7 D-5 0-5K-8 D2-570-38M-11 D2-561-4D-12 D-1-D-1 D3-545-44D-14 Partition 12" Shielding 12" Partition Partition 6" Partition 12" Shielding 12" Shielding 18" Shielding 12" Shielding 18" Shielding 12" Hollow Hollow Solid Solid Solid Solid Hollow Hollow Hollow Hollow Running'-0"x9'-6" Running'-1"x17'-1" Running 6'-3"x21'-7" Running'-5"x22'-ll" Running-5"x23'-ll" Running'-9"x9'-7" Running 14'-9"x22'-0" Running 16'-3"x21'-7" Running 7e-1"x8'-8"*

Running'-1"xl8'-0 Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes D2-570-43K-15 D3-570-5K-16 Blockout Blockout 24" 24" Hollow*Hollow Running'-6"x2'-0" Running'-4"xl'-ll" No No*-Assumed*-Assumed BOUNDARY SUPPORTS Free edge Simple support Fixed support L%hoot 1 nf 7

TABLE 1 MhSONRY MhLLS-FUNCTION hND PHYSIChL PROPERTIES Mall 2-534-33E-20 2-534-33G-21 2-534-33H-22 2-545-38H-23 Function Partition Blockout Blockout Firewall Thick-ness 12" 18" 8 ll 12" ollow Solid ollow ollow W thea Bond unning tack unning unning Sice (hei ht x width)26'-10"x9"-1" 9'-9"xl6-4" 14'-6"x6'-8" 24'-0"x8'-6" Boundary Su rt Shown on Design Drawi s Yes Yes Yes Yes Reaarks 2-545-39J-24 2-545-39J-25 2-S45-41H-26 Shielding Shielding Shielding 24" 24" 16" olid olid olid unning unning tack 12'-3"x14'-2 8~-1"x6'-7" 8'-0"x170-2")(x x)c Yes Yes Yes 2-545-44J-31 2-545-43L-32 2-545-43M-33 3-545-44J-34 3-545-45L-38 3-545-48N-40 Shielding Shielding Shielding Shielding Shielding Firewall 1 80t 4 8 tt 56" 18" 48tl 12" olid olid olid olid olid ollow 8 unning unning unning unning unning unning 8'-0"x6'-0" 10'-10"xll'-4" 10'-0"x4'-8" 8'-1"x6'-0" 10'-8"xll'-6" 12'-8"xl4'-10" Q Yes Yes Yes Yes Yes Yes 2-545-40N-41 Firewall 12" lollow unning 12'-8"xl4'-10" Yes E:

ThBLE 1 MhSONRY MhLLS-FUNCTION hND PHYSIChL PROPERTIES Mall Function Thick-ness M thes Bond Site (hei ht x width)Shown on Boundary Design Su rt Drawin s Remarks D--F-F rewa Firewall D2-549-32F-48 Firewall D2-549-32G-49 Firewall D3-545-49H-42 Shielding D3-545-50H-44 Partition D2-549-32F-45 Firewall 24" 12" 8 It 8'tt 8 tt Solid Hollow Hollow Ho ow Hollow Hollow Hollow Running Running unning Running Running Running unning 13'-5"x12"-0" 24'-6"x8'-8" 9'-0"xlO'-4" 1-x 10-6 x21-8 10'-6"x9'-8" 10'-6"x20'-9" Yes Yes Yes Yes Yes Yes Yes D2-549-32G-50 Firewall D2-549-31G-51 Firewall D2-549-32G-52 Firewall D2-549-33G-53 Blockout D2-549-33H-54 Blockout D2"534-33G-55 Blockout D2-534-33G-56 Blockout D--M-B oc out D3-5 5-47M-68 Blockout D2-545-39J-66 Shielding 8I~8I~8 II 8I~8 tt 20" 8tt 24" 24" Hollow Hollow Hollow Hollow Hollow Hollow Hollow Solid Hollow Hollow unning unning unning unning unning unning unning Running unning unning 10'-6"xl7'-2" 10'-6"x21'-5" 8'-ll"x17'-3" 12'-0"x6'-0" 12'-0"x14'-8" 14'-6"x4'-8" 14'-6"x6'-9" 8'-1"x4'-3" 3'-6"x7'-5" 3'"x7'-5" xxxK xx xx Yes Yes Yes Yes Yes Yes Yes Yes No No Type of block and number of w thea assumed Type of block and number of wythes assumed

ThBLE 1 MhSONRY MhLLS-FUNCTION hND PHYSIChL PROPERTIES Mall Function D2-534-43H-70 Partition D3-53-5D-71 Partition D3-534-44D-72 Partition Thick-ness 12" 12" 12" Hollow Hollow Hollow M thea Bond Running Running Running Sise (hei ht x width 3'-5"x26'~0" 13-5'x9-6" 13'-5"xl4'-7" Boundary Su rt XK)EC Shown on Design Drawi s Yes Yes"Yes Reasrks D3-534-44D-73 Partition]2I~Hollow Running 13'-5"x9'-7" Yes D2-529-43C-74 Partition 12" Hollow Running 11'-4"x39'-4" Yes D2-545-41J-76 Shielding D3-545-46H-77 Shielding D2-517-33E-80 Partition D2-503-35E-81 Shielding 24M 24" 12 Solid Solid Hollow 36" Solid Running Running Running Running 8'-1"x4'-0" 8'-2"x4'-1" 15'-ll"x9'-3" 29'-ll"x31'-10" Yes Yes Yes Yes D2-517-31F-82 Firewall D2-517-32F-83 Firewall D2-517-32G-84 Firewall D2-517-33H-85 Shielding D2-517-33H-86 Firewall D2-517-38H-87 Firewall D2-517-39H-88 Blockout 02-517-39K-89 Shielding 12" 12"]2I~12" 12" 24" 24" Hollow Hollow Hollow Hollow Hollow Hollow Solid Solid Running Running Running Running Running Running Running Running 16'-0"x23'-0" 16'-0"x39'-0" 16'-0"x23'-0" 13'-0"x20'-8" 14'-3"x18'-0" 27'-7"x8'-8" 7'-0"x14'-5" 8'-2"x9'-10" JC)l K)C Yes Yes Yes Yes Yes Yes Yes Yes

TABLE 1 MhSONRY ILLS-FUNCTION hND PHYSIChL PROPERTIES Mall Function Thick-ness W thea Bond Sise (hei ht x width)Boundary Su rt Shown on Design Drawi s D2-517-426-90 Blockout 12" Hollow Running 8'-6"x17'"6" Yes D3-517-49H-92 Partition 12" D-517"'i9J-93 Shielding 2 D2-517-34E-94 Partition 12" D2-Sll-33G-95 Partition 12" D2-517-43H-96 Shielding 18" D3-517-45H-97 Shielding 18" Hollow Solid Hollow Hollow Solid Solid Running 27'-5"x8'-8" Running 8-2 x-10 Running 31'-0"x29'-0" Running 15'-ll"xS'-9" Running 9'-8"x8'-0" Running 9'-8"x8'-0" k X X XIX W Yes Yes Yes Yes Yes Yes D3-517-46N-98 Firewall D3-517-46N-99 Firewall D3-517-46N-100 Firewall 12" 12" 12" Hollow Hollow Hollow Running 7'-'"xll'-5 Running 7'-0"xll'-5" Running 7'-0"xl6'-8" Yes Yes Yes D2-517-38H-101 Partition 12" Hollow Running 27'-0"x10'-6" C.:P Yes D3-S17-46G-104 Partition 8 tl D3-517-50H-102 Partition 12" D3-507-44C-103 Shielding 12" Hollow Solid Hollow Running 30'-0"x10'-5" Running 10'-1"'-3" Running 12'-6"xl7'-6" Yes Yes No D-G-1 Blockout Hollow Running 7-ll"x6'-4" XXX No D--E-Partition Hollow Running 15-11 x3-1" Yes

TABLE 1 MhSONRY WALLS-FUNCTION AND PHYSICAL PROPERTIES Mall Function Thick-neea e W thea Bond Sise (hei ht x width)Shown on Boundary Design Su rt Drawi s Remarks D3-517-45D-107 Blockout D2-517-44D-108 Shielding D2-517-44E-109 Partition 1 2'2" 12" Hollow Hollow Hollow 1 Running Running Running 14'-10"x14'-7" 7'-5"x6'-0" 9'-10"xl3'-2." Cy Yes Yes Yes elis filled with sand D2-517-43E-110 Partition D2-517-39H-ill Blockout D2"528-35H-112 Firewall D2-528-34H-113 Firewall 12" 24"]2'2" Hollow Hollow*Hollow Hollow Running 4*Running Running 1 Running 9'-10"x9'-6".6'-5"x2'-5" 5'-1"xl3'-3" 7'-8"x6'-10" Yes No Yes Yes*-Assumed D3-528-54H-114 Firewall D3-528-54H-11S Firewall D2-517-43H-116 Blockout D3-517-49H-117 Shielding D2-S07-45C-118 Shielding D2-517-5A-120 Exterior 12" 12" 12" 24" 8 to 1 2 lt Hollow Hollow Hollow Hollow*Solid Hollow 1 Running Running 1 Running 2*Running 1 Stack 1 Running 8'-1"x14'-0" 8'-1"x8'-6" 9'-4"x2S'-ll"'-4"x2'-4" 6'-3"x2'-3" 20 I-2"x14'-ll" Yes Yes Yes No Yes Yes*Assumed D2-517-3A-121 Exterior 12" Hollow 1 Running 20'-2"x14'-ll" y.K)C pC Yes

TABLE 1 HhSONRY MALLS-FUNCTION AND PHYSICAL PROPERTIES Mall Function Thick-ness M thee Bond Siee (hei ht x width Shown on Boundary Design Su rt Dravi e Remarks D--H-B oc out D3-476-45H-122 Blockout 3 6 It Hollow Hollow Running Running 4'-5"x9'-4" 4-8'9-No No Type of block and number of wythes assumed Type of block and number of wythes assumed D2-558-43K-35 Shielding D2-558-43K>>36 Shielding b2-558-42K-37 Shielding D3-558-45K-39 Shielding 30" Solid 36It Solid 36" Solid 12" Solid Runnin 6 Running 2 Running 6 Running 5t 2tt x 13t 3II 8'-5" x 12t-0" 5I 4tf x 3f 41I 8~5 Il x 12 I Otl Yes Yes Yes No ase not mortared 0

TABLE 2ALLOWABLE STRESSES IN CONCRETE MASONRY WALLS T e 1 Wall Loadin Condition e 2 Wall Loadin Condition T e of Stress si Flexural compression, Fm Transverse and punching shear, Vm Shear in mortar collar joint.Vmc~Direct or Normal to bed jo flexural Hollow-Parallel to bed tension Normal to bed jo Solid-Parallel to bed Mortar collar joints, Ftc ints.Fth joints, Fthp ints.Ftsn joints, Ftsp Normal 340 35 10 14 27 10 Abnormal and Extreme Environmental 560 59 14 23 46 14 Normal 390 38 10 27 40 10 Abnormal and Extreme Environmental 650 63 14 46 68 14 Axial compression allowable (Fa)is dependent upon the height and thickness of the wall Fa=0.225 fm[1-(h)3]40t T e 1 Wall e 2 Wall Hollow-unit wall fm-1..020 psi mo-750 psi Solid-unit wall fm=1,190 psi mo=750 psi 1.For walls laid in stack bond, shear and tensile stresses shall not be transferred across the continuous vertical joints.2.Material properties and the shear capacity of mortared collar joints have been veriTied by field tests.0191C

APPLIED LOADS AND EVALUATION RESULTS A plied Loads Evaluation Results Wall D2-570-40M-1 Normal E 0 D L W R DrW 0 E s R T P a a a Abnormal Y P Meets Acceptance Criteria Does Not Meet Acce tance Criteria Exceeds overturning criteria Remarks D2-570-39M-2 Exceeds overturning criteria D2-570-43K-3 Meets over-turning criteria D2-570-42J-4 eets over-turning criteria D3-570-45K-7 eets over-turning criteria D3-570-45K-8 eets over-urning criteria D2-570-38M-11 Exceeds overturning criteria D2-561-44D-12 Exceeds overturning riteria

A plied Loads TMI APPLIED LOADS AND EVALUATION RESULTS Evaluation Results Wall D3-561-45D-13 Normal D L E R Dr 0 0 Abnormal T a W E R s a P Y a p Meets Acceptance Criteria Does Not Meet Acce tance Criteria Exceeds overturning criteria Remarks D3-545-44D-14 Meets allowable stresses D2-570-43K-15 Meets allowable stresses D3-570-45K-16 Meets allowable stresses D2-534-33E-20 il Exceeds allowable tension D2-534-33G-21 J~I Jl Meets allowable stresses D2-534-33H-22 Jl Exceeds overturning criteria D2-545-388-23 J4 J Jl Meets allowable stresses

~TABL APPLIED LOADS AND EVALUATION RESULTS.Applied Loads Evaluation Results Wall D2-545-39J-24 Normal D L W E R Dr 0 0 W Abnormal E R T s a a P a Y P Meets Acceptance Criteria Meets allowable stresses Does Not Meet Acce tance Criteria Remarks D2-545-39J-25 iJ Meets allowable stresses 02-545-41H-26 eets over-turning criteria D2-545-44J-31 J~/Exceeds allowable strain.for interstory drift D2-545-43L-32 J J<VJJ Meets allowable stresses D2-545-43M-33 JV dJ4 Meets allowable stresses D3-545-44J-34 dJ ill Exceeds allowable strain for interstory drift D3-545-45L-38

./4 Mls eets allowable stresses

,~

~TABL APPLIED LOADS AND EVALUATION RESULTS Applied Loads Evaluation Results Wall D3-545-48N-40 Normal E 0 D L W R DrW 0 Abnormal E R T s a a JJ P a Meets Acceptance Y p Criteria Does Not Meet Acce tance Criteria Exceeds allowable stresses Remarks D2-545-40N-41 Exceeds allowable stresses D3-545-49H-42 Meets allowable stresses D3-545-50H-44 Jd Meets allowable stresses D2-549-32F-45 JJ Meets allowable stresses D2-549-31F-46 4 v'i Meets allowable stresses D2-549-32F-47 Meets allowable stresses D2-549-32F-48 JJ Meets allowable stresses

APPLIED LOADS AND EVALUATION RESULTS A plied Loads Evaluation Results Wall D2-549-32G-49 Normal E 0 D L W R DrW 0 E 8 R T P a a a Abnormal Y P Meets Acceptance Criteria Meets allowable stresses Does Not Meet Acceptance Criteria Remarks D2-549-32G-50 Meets allowable stresses D2-549-31G-51 Meets allowable stresses D2-549-32G-52 il Meets allowable stresses D2-549-33G-53 Exceeds allowable tension D2-549-33H-54 Exceeds allowable tension D2-534-33G-55 Meets allowable stresses D2-534-33G-56 eets allowable stresses

~TAB APPLIED LOADS AND EVALUATION RESULTS A plied Loads Evaluation Results Wall D2-545-39J-66 L W E R 0 0 Normal Dr Wt E S R T P a a a Abnormal Y P Meets Acceptance Criteria Meets allowable stresses Does Not Meet Acce tance Criteria Remarks D3-,545-47M-67 4 v'eets allowable stresses D3-545-47M-68 Meets allowable stresses D2-534-43H-70 Meets allowable stresses D3-534-45D-71 J 4 Meets allowable stresses D3-534-.44D-72 Meets allowable stresses D3-534-44D-73 eets allowable stresses D2-529-43C-74 Jl Exceeds allowable tension

TABL APPLIED LOADS AND EV UATION RESULTS A plied Loads Evaluation Results Wall D2-545-41J-76 D L E R 0 0 Normal Dr Wt E R a T P Y a a p Abnormal Meets Acceptance Criteria Does Not Meet Acceptance Criteria Exceeds allowable strain for interstory drift Remarks D3-545-46H-77 Exceeds allowable strain for interstory drift D2-517-33E-80 4 J Exceeds allowable tension D2-503-3SE-81 Exceeds arching criteria D2-517-31F-82 Exceeds allowable tension D2-517-32F-83 Exceeds overturning criteria 92-517-32G"84 J J Exceeds allowable tension D2-517-33H-85 Exceeds allowable tension

Applied Loads~TABL APPLIED LOADS AND EVALUATION RESULTS Evaluation Results Wall D2-517-33H-86 Normal D L 4 J E R Dr 0 0 W Abnormal E R T s a a p a Meets Acceptance Y p Criteria Does Not Meet Acceptance Criteria Exceeds allowable stresses Remarks D2-517-38H-87 4 Jd Jl Meets allowable stresses D2-517-39H-88 4d J Meets allowable stresses D2-517-39K-89 Meets allowable stresses D2-517-42G-90 il eets over-turning criteria D3-517-49H-92 llew JJ eets allowable stresses D3-517-49J-93

~ii eets allowable tresses D2-517-34E-94 Jv Exceeds overturning criteria

APPLIED LOADS AND EVALUATION RESULTS A plied Loads Evaluation Results Wall D2-517-33G-95 Normal E 0 D L W R Dr 0 W Abnormal E R s a iJ T P Y a a p Meets Acceptance Criteria Does Not Meet Acceptance Criteria Exceeds allowable tension Remarks D2-517-43H-96 Exceeds overturning criteria D3-517-45H-97 Meets over-turning criteria n3-517-46N-98 Meets allowable stresses D3-517-46N-99 JJ Meets allowable stresses D3-517-46N-100 li Exceeds allowable tension D2-517-38H-101 Meets allowable stresses D3-517-50H-102 lJ Meets allowable stresses

APPLIED LOADS AND EVALUATION RESULTS A plied Loads Evaluation Results Wall D3-507-44C-103 D L Normal W E R 0 0 Dr W R a T P Y a a p Abnormal Meets Acceptance Criteria Does Not Meet Acce tance Criteria Exceeds overturning criteria Remarks D3-517-46G-104 iv Meets arching criteria D2-517-31G-105 Meets arching criteria D2-517-33E-106 Meets allowable stresses D3-517-45D-107 Meets allowable stresses D2-517-44D-108 Meets over-turning criteria D2-517-44E-109 Jd Meets allowable stresses D2-517-43E-110 eets allowable stresses

TABLE APPLIED LOADS AND EVALUATION RESULTS Applied Loads Evaluation Results Mall D2-517-39H-ill Normal E 0 D L W R Dr M 0 Abnormal E R T s a a p Meets Acceptance Y p Criteria eets allowable stresses Does Not Meet Acceptance Criteria Remarks D2-528-35H-112 Meets allowable J stresses D2-528-33H-113 JJ JJJ Meets allowable stresses D3-528-54H-114 JJ eets allowable tresses D3-528-54H-115 eets allowable tresses D2-517-43H-116 eets allowable tresses D3-517-49H-117 Meets allowable stresses D2-507-45C-118 Exceeds overturning criteria

~TAB APPLIED LOADS AND EVALUATION RESULTS A plied Loads Evaluation Results Wall D2-517-5A-120 Normal D L W J J R 0 DrW E s R a T P a a JJ Abnormal Y P Meets Acceptance Criteria Does Not Meet Acceptance Criteria Exceeds allowable stresses Remarks D2-517-3A-121 lJ Exceeds allowable stresses D3-476-45H-122 i J Meets allowable stresses D3-476-43H-123 Meets allowable stresses eets allowable stresses D2-558-43K-36 eets allowable stresses.D2-558-42K-37 Exceeds allowable stresses in support bracke t.D2-558-45K-3 9 eets allowable tresses LEGEND Dr Interstory drift

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APPENDIX B ADDITIONAL JUSTIFICATION OF THE REEVALUATION CRITERIA0052C

Appendix B, Page ii of ii TABLE OF CONTENTS 1.0 2.0