| title = Watts Bar Nuclear Plant (WBN) - Unit 2 - Final Safety Analysis Report (Fsar), Amendment 105, 3.6 Protection Against Dynamic Effects Associated with the Postulated Rupture of Piping

{{#Wiki_filter:PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-1WATTS BARWBNP-1053.6 PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPINGGeneral Design Criterion 4 of Appendix A to 10 CFR 50 requires that structures, systems, and components important to plant safety be protected from the dynamic effects of a pipe rupture. This section of the FSAR describes the design measures necessary to ensure compliance with this requirement. This section is subdivided into Part A and Part B. To be consistent with the standard format, all sections and subsection numbers are suffixed with either A or B.Part A (3.6A) includes all piping systems inside and outside containment except the reactor coolant loop piping. The reactor coolant branch lines, however, are within the scope of this part. Also, jet impingement considerations of the reactor coolant loop on components other than those associated with the primary loop are within the scope of this report.Part B (3.6B) includes the reactor coolant loop system except as stated in 3.6A.3.6A   PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPING (EXCLUDING REACTOR COOLANT SYSTEM PIPING)Criteria presented herein regarding break size, shape, orientation, and location are in accordance with the guidelines transmitted to TVA by the NRC in letter, dated December 1972, and subsequent amendments for outside containment, and NRC Regulatory Guide 1.46 for inside containment. These criteria also include considerations which are further clarified in the NRC Branch Technical Positions ASB3-1 and MEB 3-1 where appropriate. Arbitrary intermediate breaks (AIBs) postulated in accordance with the documents noted above are eliminated by NRC Generic Letter 87-11

[4]. The final routing of field routed systems will not be completed until late in the plant construction schedule. Field-routed piping generally possesses very little potential, insofar as their functions are concerned, toward affecting plant shutdown. Their failure can, however, cause damage to other components and equipment, especially electrical, which may be required for shutdown of the plant. Field-routed and field-located items such as electrical conduit, cable trays, instrument and control lines, and junction and terminal boxes, etc., are protected as required for plant shutdown. Where field routing was required, guidance was provided to minimize the number of unacceptable interactions. A followup field review and evaluat ion for identifying unacceptable interactions and ensuring implementation of corrections is performed.The following definitions and assumptions are applicable to this section:DEFINITIONS 1Acceptable Interaction

3.6-2PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105A pipe rupture interaction for which, from a systems standpoint, the net required safety functions for a particular rupture are not impaired when assuming a single active component failure.

2Active ComponentAny component which must perform a mechanical motion or change of state during the course of accomplishing a primary safety function.

3Double-Ended RuptureA circumferential pipe rupture where flow is sustained from both ends of the break.4Environmental EffectsThe wetting, pressure, temperature, flammable, radiation, etc., conditions within the ''zone of influence'' (Definition 28) of a pipe rupture.

5Essential Systems and ComponentsSystems and components required to shutdown the reactor and/or mitigate the consequences of a postulated pipe failure without offsite power. The seismic classification of essential components and systems is in accordance with Regulatory Guide 1.29.

6High Energy Fluid SystemsFluid systems that, during normal plant conditions, satisfy the following: (a)Maximum operating temperature exceeds 200°F, and (b)Maximum operating pressure exceeds 275 psig.Systems may be classified as moderate energy (see Definition 13) if the total time that the above conditions are exceeded is less than either of the following: (a)One percent of the normal operating life span of the plant.(b)Two percent of the time period required for the system to accomplish its design function.

7Inside ContainmentInside containment is defined for pipe rupture evaluation purposes to include all piping inside the Shield Building and the main steam valve rooms. The  

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-3WATTS BARWBNP-105actual containment boundary for integrity purposes is normally taken at the second isolation valve.

8Jet Impingement ForceThe jet force on an object resulting from a ruptured pipe. The magnitude of this force depends on such parameters as the thermodynamic conditions of the fluid in the pipe, distance of the pipe rupture from the target and the shape of the target.

9 Jet ThrustThat reactive dynamic force on a ruptured pipe due to a fluid being accelerated out of a break.

10Line-Mounted ValvesValves located in a line and supported by the line.

11Loss-of-Coolant Accident (LOCA)LOCA is defined as a net loss of reactor coolant inventory when makeup is provided only by the normal makeup system and an orderly shutdown of the plant is prevented. Normal makeup is sized to maintain a constant reactor coolant system (RCS) inventory with a rupture equivalent to a 3/8-inch diameter hole. Therefore, a rupture is considered a LOCA when the flow rate is greater than the equivalent flow from a 3/8-inch diameter hole.

12LOCA BoundaryFor piping extended from the RCS, the boundary of postulated pipe rupture which cannot be isolated when assuming a single active failure shall be defined as follows: (a)First locked closed or administratively closed isolation valve (pressurizer safety valves are examples). The valves forming the Class1 boundary in all drain lines are considered as administratively closed.(b)Second of two normally open, remotely operable, independent isolation valves capable of automatic closure and verification that they will close.(c)First normally closed check valve capable of verification that it is closed and capable of providing isolation from a reactor coolant source.(d)Second of two normally open check valves capable of verification that they will close and capable of providing isolation from a reactor coolant source. (Verification that a check valve will close should be interpreted 3.6-4PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105as meaning ''capable of periodic test that will verify its capability of closure, such as during a refueling outage.'')(e)First normally open and remotely operable automatic isolation valve following a normally open check valve (capable of providing isolation from a reactor coolant source) if both are capable of verification that they will close.If a pipe failure beyond the above defined boundary of possible isolation could result in a normally open boundary valve failing to close, then a LOCA may exist beyond that boundary.

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-9WATTS BARWBNP-105Active components (electrical, mechanical, and instrumentation and control) shall be assumed incapable of performing their function when subjected to a jet unless the active component is enclosed in a qualified spray-proof enclosure (such as one qualified to the NEMA IV, Hosedown Test Standard), the component is known to be insensitive to such an environment, or unless justified that the active function will not be impaired.When the jet consists of steam or subcooled liquid that flashes at the break, unprotected components located at a distance greater than 10 diameters (ID) from the break or equivalent diameter of the crack shall be assumed undamaged by the jet without further analysis. The basis for this criterion is contained in Reference [5].Concrete erosion that may result from jet impingement shall be assumed to be of insufficient magnitude to jeopardize structural integrity.

3.6-10PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105For piping systems that are enclosed in suitably designed structures or compartments to protect other structures, systems, and components important to safety, pipe breaks shall be postulated according to section 3.6A.2 and the resulting jet thrust loading effects determined. "Worst case" breaks may be postulated in a piping component within the protective structure or compartment at locations which result in the maximum loading from the impact of the postulated ruptured pipe and jet discharge force on each wall, floor, and roof of the structure or compartment, including internal pressurization.3.6A.1.1.4  Protective MeasuresWhere physical separation of source and target and relocation or rerouting are not feasible, the following protective devices will be provided to mitigate the unacceptable consequences of the postulated ruptures.

follows: 1High Energy PipingCircumferential ruptures and longitudinal splits (a)Pipe whip.(b)Jet impingement.(c)Environmental effects.

3.6-16PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105Through-wall leakage cracks (a)Jet impingement (b)Environmental effects 2Moderate Energy PipingThrough-wall leakage cracks (a)Environmental effects.In particularly susceptible areas, the jet impingement load associated with a through-wall leakage crack in moderate energy piping with the pressure exceeding 275 psig shall also be considered.

3.6A.2.1.4  FloodingFlooding consequences are also considered in addition to the local effects listed above in Section 3.6A.2.1.3 from piping failures. Additional environmental concerns are addressed in Section 3.11.2.

1High Energy Line Breaks (HELBs)For the purposes of flooding evaluations, fluid systems that, during normal plant conditions are either in operation or maintained pressurized under conditions where maximum operating temperature exceeds 200

°F are conservatively classified as high energy. This is bounding since for a given line, the flow from a high energy break emanates from a larger break area than flow from a moderate energy crack. The circumferential rupture is the bounding break for HELB flooding analyses.Systems classified as high energy are re-classified as moderate energy if the total time that the above conditions are exceeded is less than either of the following: (a)1% of the normal operating life span of the plant, or (b)2% of the time required for the system to accomplish its system design function.The systems evaluated for high energy break flooding include the reactor coolant, main steam, feedwater, auxiliary boiler, auxiliary feedwater steam supply, and chemical and volume control system.

2Moderate Energy Line Breaks (MELBs)For the purposes of flooding evaluations, fluid systems are classified as moderate energy that, during normal plant conditions, are either in operation or maintained pressurized (above atmospheric pressure) under conditions PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-17WATTS BARWBNP-105where: (1) The maximum operating temperature is 200

°F or less or (2) the 1or 2% exclusion rules described above are applicable. The through-wall leakage crack is the postulated break for the MELB flooding analysis. Flood levels are calculated for the plant on an area basis. Both submergence and structural loading are addressed in the flooding studies.HELB and MELB flooding effects are evaluated on all essential equipment on a case by case basis. If it is determined that an essential component is not qualified or cannot be demonstrated to operate under the adverse flood conditions, then the essential component is protected. Protection is accomplished by relocating the component or by installing a barrier or curb. Safe shutdown is ensured for design basis HELB/MELB flooding events through these actions.

3.6A.2.1.5  Leak-Before-Break ApplicationThe application of leak-before-break as applied to the primary loop piping is discussed in Section 3.6B.1.In addition, leak-before-break technology has been applied to the pressurizer surge line to eliminate the dynamic effects of a pressurizer surge line rupture as a design basis for Watts Bar Nuclear Plant. This is in accordance with the final rule change to General Design Criteria 4 [Ref. 12]. Authorization for their elimination is discussed in Reference [9] and is based on fracture mechanics results presented in References [10] and [11].3.6A.2.2  Analytical Met hods to Define For cing Functions a nd Response Models 3.6A.2.2.1  Assumptions 1The thrust load acting on the pipe due to a blowdown jet is equal and opposite to the jet.

4For the purpose of estimating jet forces, the blowdown is to an infinite volume at standard conditions.

3.6-18PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105 3.6A.2.2.2  Blow down Thrust LoadsThe thrust force at any time, T (t) is given bywhere:E = fluid density at break at time t V E = fluid velocity at break at time t AjE = pipe break exit area P E = control volume pressure at break at time t P A = ambient pressure g c = gravitation constantA simplified analysis may be conducted by assuming that the fluid is blowing down in a steady state condition with frictionless flow from a reservoir at fixed absolute pressure Po.  (Po is the initial line pressure.)  When the fluid is subcooled, nonflashing liquid, the flow will not be critical at the break area so that:

and If P A <<P o the thrust force may be conservatively approximated by:When the fluid is saturated, flashing or superheated vapor, the fluid can be assumed to be a perfect gas. The velocity for critical flow at the break area is given by:

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-19WATTS BARWBNP-105andwhere K=  C p/C v is a ratio of specific heats C p  =  specific heat at constant pressure C v  =  specific heat at constant volumeA value of K = 1.3 is justified for steam as being conservative. If P E >> P A, the thrust force may be conservatively approximated by:

where Y j= Normal load applied to a target by the jet A i = Cross-sectional area of jet intercepted by target structure A j = Total cross-sectional area of jet at the target structure S F = Shape factor D LF= Dynamic load factorT= Total blowdown thrust at break as calculated in Section 3.6A.2.2.2 = Angle between jet axis and a line perpendicular to the target.The ratio A i/A j represents the proportion of the total mass flow from the jet which is intercepted by target structure. A dynamic load factor of 2.0 shall be used in the absence of an analysis justifying a lower value. The following shape factors are recommended.

3.6-20PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105Jet impinging on a slab [Figure 3.6-1 sector (a)]Rectangular jet impinging on a pipe larger than jet [Figure 3.6-1 sector (b)]Rectangular jet impinging on a pipe with h greater than D o [Figure 3.6-1 sector (b)] Circular jet impinging on pipe with jet diameter (D j = 2r j) less than pipe diameter [Figure3.6-1 sector (c)]Circular jet impinging on pipe with jet diameter greater than pipe diameter [Figure 3.6-1 sector (d)]These are the most common cases that will occur in the pipe rupture evaluation. Other shape factors may be obtained by idealizing the surface as infinitesimal planes and performing an integration over the area impinged upon by the jet.

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-21WATTS BARWBNP-1053.6A.2.3  Dynamic Analysis Methods to Verify Integrity and Operability3.6A.2.3.1  General Criteria for Pipe Whip Evaluation 1The dynamic nature of the piping thrust load shall be considered. In the absence of analytical justification to the contrary, a dynamic load factor of 2.0 may be applied in determining piping system response.

2Nonlinear (elastic-plastic strain hardening) pipe and restraint material properties may be considered as applicable.

3Pipe whip shall be considered to result in unrestrained motion of the pipe along a path governed by the hinge mechanism and the direction of the vector thrust of the break force. A maximum of 180&deg; rotation may take place about any hinge.

3.6A.2.3.2  Main Reactor Coolant Loop Piping SystemThe dynamic analyses applicable to the reactor coolant loop piping are discussed in Section 3.6B.3.6A.2.3.3  Othe r Piping SystemsThe pressure time history, jet impingement load on targets, and the thrust resulting from the blowdown of postulated ruptures in piping systems shall be determined by thermal and hydraulic analyses or a conservative simplified analyses.In general, the loading that may result from a break in piping will be determined using either a dynamic blowdown or a conservative static blowdown analysis. The method for analyzing the interaction effects of a whipping pipe with a restraint will be one of the following:

1Equivalent static method 2Lumped parameter method 3Energy balance method.In the cases where time history or energy balance method is not used, a conservative static analyses model will be assumed. The loading factors to be used for the static model are discussed in Section 3.6A.2.3.5.The lumped parameter method is carried out by utilizing a lumped mass model. Lumped mass points are interconnected by springs to take into account inertia and stiffness properties of the system. A dynamic forcing function or equivalent static loads may be applied at each hypothesized break point with unacceptable pipe whip interactions. Clearances and inelastic effects will be considered in the analyses.

3.6-22PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105The energy balance method is based on the principle of conservation of energy. The kinetic energy of the pipe generated during the first quarter cycle of movement will be assumed to be converted into equivalent strain energy, which will be distributed to the pipe or the support. The strain in the restraint shall be limited to 50% of the ultimate uniform strain.3.6A.2.3.4  Simplified Pipe Whip AnalysisA conservative method may be used to determine for a given rupture whether pipe whip takes place. This method is based on calculation of the minimum internal forces necessary to form a plastic hinge in the pipe, and the number of hinges required for a pipe whip mechanism.Occurrence of a pipe whip is dependent on formation of a sufficient number of hinges to develop a mechanism. Two commonly encountered examples are:A. Cantilever pipe with end loadB. Continuous pipe supported at both ends with lateral loadWhereL, L 1 , L 2 = Distance from support to load Mult  = The ultimate moment Twhip  = The thrust load at which pipe whip will occur.The applied thrust load shall consider a dynamic amplification factor of 2.0 unless an analysis is performed to justify a lesser value.

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-23WATTS BARWBNP-105 3.6A.2.3.5  Pipe Whip Restraint DesignThe design limits which shall be used in the design of pipe whip restraints are shown in the following table:  Type of Design        Plastic            ElasticLoading CombinationD+L+T a+P a+Y r+Y j+Y m D+L+T a+P a+Y r+Y j+Y mStress/strain limits50% uniform1.5 S m or 1.2 S y,Ultimate strainbut not to exceed 0.7 S uNote: Earthquake and pipe rupture are not assumed to exist concurrently when evaluating the pipe whip restraints.Where:D=Dead load L=Live T a=Thermal load resulting from postulated break P a=Pressure load resulting from postulated break Y r=Pipe restraint reactions resulting from postulated break Y j=Jet impingement load generated by postulated break Y m=Pipe whip impact load resulting from postulated break S m=Design stress - intensity S y=Yield stress S u=Ultimate tensile stressDynamic response amplification was accounted for by multiplication of loads by appropriate dynamic factors or through use of dynamic analysis. The following dynamic load factors were used for the local structure components design.

1For piping system with no gaps at the restraint, a dynamic load factor of 2.0 was applied regardless of pipe size.

2For piping system with gaps not exceeding 1 inch at the restraint, a dynamic load factor of 3.0 may be applied.

3.6-24PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105 3A linear interpolation for gaps between zero and 1 inch may be made. The above dynamic factors in items 1 and 2 are applicable to small line (6-inch nominal diameter or less) without subsequent analyses. Items 2 and 3 may also be applied to large lines (larger than 6-inch nominal diameter) providing sufficient analyses are performed to show that the dynamic factor has not been exceeded.

4For gaps in excess of 1 inch, dynamic load factors shall be justified by analyses.3.6A.2.3.6  Energy Absorbing Materials An energy absorbing material (crushable honeycomb) is sometimes used to absorb the kinetic energy of the ruptured pipe and to limit the loads on the restraint structure. For systems where the energy balance method of analysis is used, the kinetic energy of the pipe generated during the first quarter cycle of movement will be assumed to be converted into equivalent strain energy, which will be distributed on the pipe or the support. The actual crush shall not exceed 90% of the available crush depth.

3.6A.2.4  Guard Pipe Assembly Design CriteriaGuard pipes for penetrations are classified as TVA Class K. The chemical and mechanical tests and nondestructive examinations shall be in accordance with the ASME Material Specification. Markings and certified mill tests shall be in accordance with the requirements for process pipe. All welding shall be made in accordance with ASME Code, Section III, NC-4000. All girth butt welds shall be magnetic particle or liquid penetrant inspected in accordance with Appendix IX of ASME Code, Section III. Acceptance standards shall be in accordance with NE-5000.The guard pipe shall be designed for the same temperature and pressure as the process pipe. However, the allowable stresses shall be 90% of yield strength (0.2%

offset) at design temperature.The guard pipe shall be designed to have its lowest natural frequency greater than 33 Hz where possible to allow the zero period acceleration to be used. Where 33 Hz is not practical, the actual frequencies expanded by 10%, shall be used in conjunction with the appropriate floor response spectra, to determine the design acceleration. The seismic loading shall be that which results from input accelerations of 1.5 g horizontal and 1 g vertical for the operating basis earthquake and twice these values for the safe shutdown earthquake.Inservice inspections and accessibility requirements are discussed in Section 5.2.8 for ASME Class 1 systems. Section 6.6 for ASME Class 2 and 3 systems and Section 3.8.2.7.9 for ASME Class MC and metallic liners of Class CC components.

Penetration assemblies to be used for piping penetrations of containment areas are discussed in Section 3.8.2.If circumferential ruptures or longitudinal splits are postulated in the process pipe (in accordance with Section 3.6A.2.1.2) at locations enclosed by the guard pile, the guard PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-25WATTS BARWBNP-105pipe shall be capable of mitigating the consequences of the break. If no circumferential ruptures or longitudinal splits are postulated in the process pipe, arbitrary through-wall leakage cracks shall be assumed and the guard pipe shall be capable of mitigating the consequences of the cracks.

3.6A.2.5  Summary of Dynamic Analysis ResultsA letter from J. E. Gilleland to Mr. Giambusso dated May 16, 1974, submitted CEB Report No. 72-22, "Evaluation of the Effects of Postulated Pipe Failures Outside of Containment for the Sequoyah Nuclear Plant Units 1 and 2."  In this letter it was stated that this report is also applicable to the Watts Bar Nuclear Plant and upon completion of the Watts Bar piping outside the containment, any differences between the Sequoyah and Watts Bar designs would be addressed in the Watts Bar FSAR. The major differences between the Watts Bar and Sequoyah designs outside containment are the main steam and feedwater routing in the open bay area of the Control Building.

3.6A.2.5.1  Stress Summary and Isometrics - Inside ContainmentThe stress summary for each of the postulated break locations for the following systems larger than 4 inches in nominal size are presented in Tables 3.6-1 through 3.6-6.Table No.System Description3.6-1Main Steam Lines 3.6-2Main Feedwater Lines3.6-3Auxiliary Feedwater Steam Supply Lines - Unit 1 3.6-3AAuxiliary Feedwater Steam Supply Lines - Unit 2 3.6-4SI Cold Leg Injection 3.6-5RHR/SI Hot Leg Recirculation, Loop 4 3.6-6SI Hot Leg Recirculation, Loops 1, 2, and 3

Isometrics showing break type locations, protective device locations and constrained directions of the above systems are presented in Figures 3.6-2 through 3.6-17.Inside containment the isometrics for Unit 2 are generally opposite hand to Unit 1. The stress summaries and isometrics are based on the analysis current at the time of the amendment submittal indicated on the figures and tables. This information is considered to be representative and presents typical historical results for Units 1 and 2.

3.6-26PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-1053.6A.2.5.2  Summary of Protection Requirements and Is ometrics-Outside ContainmentA summary of protection requirements including break types and locations for main steam and main feedwater lines are presented in Tables 3.6-9 and 3.6-10, respectively. Isometrics showing break types, locations. protective device locations and constrained directions for these lines are shown in Figures 3.6-21 through 3.6-24.Outside containment, the break types, break locations, isometrics, protective device locations and constrained directions for Unit 2 are generally opposite hand to Unit 1. The isometrics and protection requirements reflect the analysis current at the time of amendment submittal indicated on the figures and tables. This information is considered to be representative and presents typical historical results for Units 1 and2. 3.6B PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPING 3.6B.1 Break Locations And Dynamic Effects Associated With Postulated Primary Loop Pipe Rupture The dynamic effects of postulated double-ended pipe ruptures in the reactor coolant loop piping have been eliminated from the design basis of the Watts Bar Nuclear Plant by the application of leak before break technology in accordance with the final rule change to General Design Criterion 4 (Reference 12). Authorization for their elimination is provided in Reference [6] and is based on fracture mechanics analysis results presented in References [7] and [8].The plant design bases was revised in several areas to take advantage of the elimination of reactor coolant loop (RCL) pipe breaks. The protective measures taken to mitigate the dynamic effects of these breaks remain in place. However, these protective devices no longer perform a pipe whip restraint function. See FSAR Section 5.5 and Figures 5.5-11, 5.5-12, and 5.5-13.In other areas, design basis analyses have been conducted based on the original postulated double-ended breaks. Even with the elimination of these dynamic effects, these analyses continue to demonstrate the adequacy and acceptability of the plant design. These analyses shall remain the analyses of record unless indicated otherwise in this safety analysis report.Leak-before-break has also been applied to the pressurizer surge line as discussed in Section 3.6A.2.1.5.As stipulated in the final rule change to GDC-4, a non-mechanistic double-ended rupture of the largest pipe in the reactor coolant system is still postulated for the PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-27WATTS BARWBNP-105purposes of containment design, ECCS design, and environmental qualification of electrical and mechanical equipment.Previously postulated breaks in branch lines (except the pressurizer surge line) attached to the reactor coolant loops remain unaffected.

3.6B.2 Analytical Met hods to Define Forcing F unction and Response ModelsThe reactor coolant loop breaks used in determining the forcing functions (discussed below) and in calculating the resulting hydraulic transients and loadings have been eliminated as noted in Section 3.6B.1. However, these analyses envelope the effects of any remaining breaks, e.g., in branch lines at the loop attachment points, and as such continue to demonstrate the adequacy of the design for these loadings. Following is a summary of the methods used to determine the dynamic response of the reactor coolant loop associated with postulated pipe breaks in the loop piping. Detailed descriptions of the methods are given in Reference [1].In order to determine the thrust and reactive force loads to be applied to the reactor coolant loop during the postulated loss of coolant accident (LOCA), it is necessary to have a detailed description of the hydraulic transient. Hydraulic forcing functions are calculated for the ruptured and intact reactor coolant loops as a result of a postulated LOCA. These forces result from the transient flow and pressure histories in the reactor coolant system. The calculation is performed in two steps. The first step is to calculate the transient pressure, mass flow rates, and thermodynamic properties as a function of time. The second step uses the results obtained from the hydraulic analysis, along with input of areas and direction coordinates and calculates the time history of forces at appropriate locations in the reactor coolant loops.The hydraulic model represents the behavior of the coolant fluid within the entire reactor coolant system. Key parameters calculated by the hydraulic model are pressure, mass flow rate, and density. These are supplied to the thrust calculation, together with appropriate plant layout information to determine the time dependent loads exerted by the fluid on the loops. In evaluating the hydraulic forcing functions during a postulated LOCA, the pressure and momentum flux terms are dominant. The inertia and gravitational terms are taken into account in evaluation of the local fluid conditions in the hydraulic model.The blowdown hydraulic analysis is required to provide the basic information concerning the dynamic behavior of the reactor core environment for the loop forces, reactor kinetics and core cooling analysis. This requires the ability to predict the flow, quality, and pressure of the fluid throughout the reactor system. The MULTIFLEX 3.0  

The MULTIFLEX 3.0 features which differ from MULTIFLEX 1.0 are primarily related to vessel forces. The loop forcing functions do not differ significantly from those 3.6-28PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105generated using the NRC approved MULTIFLEX 1.0 model. MULTIFLEX 3.0 has been accepted by NRC for several applications [Ref.13], [Ref. 14], [Ref. 15], [Ref. 16] and has been extensively used for the LOCA analysis of various 2, 3 and 4 loop nuclear plants.MULTIFLEX is a digital computer program for calculation of pressure, velocity, and force transients in reactor primary coolant systems during the subcooled, transition, and the early saturation portion of blowdown caused by LOCA. During this phase of accident, large amplitude rarefaction waves are propagated through the system with the velocity of sound causing large differences in local pressures. As local pressures drop below saturation, causing formation of steam, the amplitudes and velocities of these  waves drastically decrease. Therefore,the largest forces across the loop piping due to wave propagation occur during the subcooled portions of the blowdown transient. MULTIFLEX includes mechanical structure models and their interaction with the thermal-hydraulic system, although these features are only involved in the vessel and steam generator modeling. The THRUST computer program was developed to compute the transient (blowdown) hydraulic loads resulting from a LOCA.The blowdown hydraulic loads on primary loop components are computed from the equation.Which includes both the static and dynamic effects. The symbols and units are:F=Force, lb fA=Actual calculated break flow area, ft 2P=System pressure, psia=Mass flow rate, lb m/sec=Density, lb m/ft 3g=Gravitational constant = 32.174 ft/sec 2 A m=Mass flow area, ft 2In the model to compute forcing functions, the reactor coolant loop system is represented by a similar model as employed in the blowdown analysis. The entire loop layout is described in a coordinate system. Each node is fully described by: 1)blowdown hydraulic information, and 2) the orientation of the streamlines of the force nodes in the system, which includes flow areas, and projection coefficients along the three axes of the global coordinate system. Each node is modeled as a separate control volume with one or two flow apertures associated with it. Two apertures are used to simulate a change in flow direction and area. Each force is divided into its x, F144 AP14.7-m*2 gA m 2144------------------------

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-29WATTS BARWBNP-105y, and z components using the projection coefficients. The force components are then summed over the total number of apertures in any one node to give a total x force, totaly force, and total z force. These thrust forces serve as input to the piping/restraint dynamic analysis.The THRUST Code is described in Reference [3].3.6B.3  Dynamic Analysis of the Reactor Coolant Loop Piping Equipment Supports and Pipe Whip RestraintsThe dynamic analysis of the reactor coolant loop piping for the LOCA loadings is described in Section 5.2.1.10.Section 5.2 defines the loading combinations, associated with the reactor piping systems, considered to assure the integrity of vital components and engineered safety features.REFERENCES 1'Pipe Breaks for the LOCA Analysis of the Westinghouse Primary Coolant Loop,' WCAP-8082-P-A (Proprietary) and WCAP-8172-A (Non-Proprietary), January 1975.

3.6-30PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105 10TVA Letter to the NRC dated June 22, 1992 transmitting enclosures, "Technical Justification for Eliminating Pressurizer Surge Line Rupture as the Structural Design Basis for WBN Units 1 and 2", WCAP-12773 (proprietary) and WCAP-12774 (nonproprietary), both dated December 1990.

12Federal Register, Volume 52, Number 207, October 27, 1987, 41288.

RHR5-B0-36282458135 598323325133855 329481637215368 154890.0060.0 0.0 C C C A C C

3.6-40PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105Table 3.6-7  Deleted by Amendment 79 PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-41WATTS BARWBNP-105Table 3.6-8  Deleted Per Amendment 64 3.6-42PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105Table 3.6-9  Summary of Protection Requirements - Outside Containment 4 - MAIN STEAM (Page 1 of 6) PIPING SYSTEM  Main SteamPIPING NOMINAL DIA. 36 inch PIPING SCHEDULE  1.307-inch wall BREAKLOCATIONBREAK 1 TYPE THRUST 1DIRECTION WHIP 2FORMEDEFFECT ON REQUIRED 3COMPONENTSAcceptable/UnacceptableRequired Fix201,301, 203,303CDownstreamYesPipe whip into refueling water storage tankUnacceptable, results in loss of emergency core cooling water supplyProvide a bunker to prevent unacceptable damage to tankJet impingement on refueling water storage tankUnacceptable, results in loss of emergency core cooling water supplyProvide a bunker to prevent unacceptable damage to tank205,305, 207,307CDownstreamYesPipe whip into refueling water storage tankUnacceptable, results in loss of emergency core cooling water supplyProvide a bunker to prevent unacceptable damage to tankJet impingement on refueling water storage tankUnacceptable, results in loss of emergency core cooling water supplyProvide a bunker to prevent unacceptable damage to tankUpstreamYesJet impingement on refueling water storage tankUnacceptable, results in loss of emergency core cooling water supplyProvide a bunker to prevent unacceptable damage to tank209,309CDownstreamYesPipe whip into refueling water storage tankUnacceptable, results in loss of emergency core cooling water supplyProvide a bunker to prevent unacceptable damage to tankSee page 6 of 6 for Notes.

3.6-43PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105Jet impingement on refueling water storage tankUnacceptable, results in loss of emergency core cooling water supplyProvide a bunker to prevent unacceptable damage to tankUpstreamYesJet impingement on refueling water storage tankUnacceptable, results in loss of emergency core cooling water supplyProvide a bunker to prevent unacceptable damage to tank211,311CDownstreamYesPipe whip damage to A1 wall of Auxiliary BuildingUnacceptable, wall fails, environmental damage to essential components will result from steam entering Auxiliary

BuildingRestraints H31W, H21WUpstreamYesJet impingement on refueling water storage tankUnacceptable, results in loss of emergency core cooling water supplyProvide a bunker to prevent unacceptable damage to tank217,317CDownstreamYesPipe whip damage to A1 wall of Auxiliary BuildingUnacceptable, wall fails, environmental damage to essential components will result from steam entering Auxiliary

BuildingRestraints H31W, H21WUpstreamYesPipe impact on refueling water storage tankUnacceptable, results in loss of emergency core cooling water supplyProvide a bunker to prevent unacceptable damage to tankSee page 6 of 6 for Notes.Table 3.6-9  Summary of Protection Requirements - Outside Containment 4 - MAIN STEAM (Page 2 of 6) PIPING SYSTEM  Main SteamPIPING NOMINAL DIA. 36 inch PIPING SCHEDULE  1.307-inch wall BREAKLOCATIONBREAK 1 TYPE THRUST 1DIRECTION WHIP 2FORMEDEFFECT ON REQUIRED 3COMPONENTSAcceptable/UnacceptableRequired Fix PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-44WATTS BARWBNP-105217,317LUpYesJet impingement on ceiling of counting room and radio-chemical laboratory (unit 1 only)Unacceptable, ceiling fails, environmental damage to essential components due to steam entering elevation 713 of the Auxiliary Building Sleeves S217 S317LDownYesPipe impact on ceiling of counting room and radio-chemical laboratory (unit 1 only)Unacceptable, ceiling fails, environmental damage to essential components due to steam entering elevation 713 of the Auxiliary Building Sleeves S217 S317LeftYesPipe whip into Auxiliary Building HVAC intakeUnacceptable, environmental damage to essential components due to steam entering elevation 737 of the Auxiliary

BuildingSleeves S217, S317RightYesJet impingement on Auxiliary Building HVAC intakeUnacceptable, environmental damage to essential components due to steam entering elevation 737 of the Auxiliary

BuildingSleeves S217, S317218,318CUpstreamYesPipe whip damage to south wall of south steam valve roomUnacceptable, damage to main steam and feedwater isolation valves located in valve roomRestraints G22W, G32W418,118,218,318LRightYesJet impingement on spreading room exhaust duct in C11-wall (unit 2 only)Unacceptable, loss of Control Building habitability due to steam environmentHVAC to have 3 psi backdraft damper installed to prevent steam from entering

control buildingSee page 6 of 6 for Notes.Table 3.6-9  Summary of Protection Requirements - Outside Containment 4 - MAIN STEAM (Page 3 of 6) PIPING SYSTEM  Main SteamPIPING NOMINAL DIA. 36 inch PIPING SCHEDULE  1.307-inch wall BREAKLOCATIONBREAK 1 TYPE THRUST 1DIRECTION WHIP 2FORMEDEFFECT ON REQUIRED 3COMPONENTSAcceptable/UnacceptableRequired Fix 3.6-45PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105419,119,219, 319CUpstreamYesPipe impact on elevation 755, which supports control room HVAC equipmentUnacceptable, floor fails and results in environmental damage to control roomRestraints L42D, L12D, L22D, L32D420,120,220, 320CUpstreamYesPipe impact on elevation 755, which supports control room HVAC equipmentUnacceptable, floor fails and results in environmental damage to control roomRestraints L42D, L12D, L22D, L32D423124LUpYesPipe impact on elevation 729 floor of Turbine Building adjacent to doors to Control BuildingUnacceptable, floor fails, possible damage to essential components

within Control Building due to jet/missile impingement on Control

Building doorsSleeves S424, S125423,124LDownYesJet Impingement on elevation 729 floor of Turbine Building adjacent to doors to Control BuildingUnacceptable, floor fails, possible damage to essential components

Building doorsSleeves S424, S125424,125,225,325CUpstreamYesPipe impact on the north-wall of Control BuildingUnacceptable, wall fails, environmental damage to essential components

within Control BuildingRestraints M42S, M32S, M22S, M12SSee page 6 of 6 for Notes.Table 3.6-9  Summary of Protection Requirements - Outside Containment 4 - MAIN STEAM (Page 4 of 6) PIPING SYSTEM  Main SteamPIPING NOMINAL DIA. 36 inch PIPING SCHEDULE  1.307-inch wall BREAKLOCATIONBREAK 1 TYPE THRUST 1DIRECTION WHIP 2FORMEDEFFECT ON REQUIRED 3COMPONENTSAcceptable/UnacceptableRequired Fix PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE3.6-46WATTS BARWBNP-105424,125LUpYesPipe impact on elevation 729 floor of Turbine Building adjacent to door to Control BuildingUnacceptable, floor fails, possible damage to essential components

within Control Building due to jet/missile impingement on Control

within Control Building due to jet/missile impingement on Control

Building doorsSleeves S424, S125425,126,226, 326CUpstreamYesPipe impact on n-wall of Control BuildingUnacceptable, wall fails, environmental damage to essential components in  

Control BuildingRestraints M42S, M12S, M22S, M32SThrough-Wall Leakage CracksThrough-wall leakage crack break below Control Building HVAC exhaust ducting at elevation 755 on q-wall (unit 2 only)Through-wall leakage crack break would fill control room HVAC with steamUnacceptable, loss of habitability of control roomHVAC to have 3 psi backdraft damper installed to prevent steam from entering control roomSee page 6 of 6 for Notes.Table 3.6-9   Summary of Protection Requirements - Outside Containment 4 - MAIN STEAM (Page 5 of 6) PIPING SYSTEM   Main SteamPIPING NOMINAL DIA. 36 inch PIPING SCHEDULE 1.307-inch wall BREAKLOCATIONBREAK 1 TYPE THRUST 1DIRECTION WHIP 2FORMEDEFFECT ON REQUIRED 3COMPONENTSAcceptable/UnacceptableRequired Fix 3.6-47PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105 Notes:1)Direction of thrust on pipe. Jet load is opposite. For circumferential (C) breaks consider upstream thrust on the upstream pipe and downstream thrust on the downstream pipe. For longitudinal (L) breaks consider up, down, lateral left, and lateral right thrust (facing downstream).2)Whip trajectory is governed by hinge mechanism and direction of vector thrust of break force. Maximum 180&deg; rotation about any plastic hinge. Sweep of jet is governed by pipe motion.3)Type of effect (jet, whip, environment, etc.) and components affected. 4)This applies to unit 1. Unit 2 is opposite hand unless otherwise noted. Reflects Analysis Which Was Current at Time of Amendment 51 SubmittalThrough-wall leakage crack break below Auxiliary Building HVAC intake canopy at elevation 743 on A1-wallThrough-wall leakage crack break would fill Auxiliary Building

with steamUnacceptable, environmental damage to essential components in Auxiliary BuildingHVAC to have temperature sensors installed which control intake fans, preventing steam from entering Auxiliary BuildingIn all other cases effects of through-wall leakage crack breaks are acceptable.Table 3.6-9   Summary of Protection Requirements - Outside Containment 4 - MAIN STEAM (Page 6 of 6) PIPING SYSTEM   Main SteamPIPING NOMINAL DIA. 36 inch PIPING SCHEDULE 1.307-inch wall BREAKLOCATIONBREAK 1 TYPE THRUST 1DIRECTION WHIP 2FORMEDEFFECT ON REQUIRED 3COMPONENTSAcceptable/UnacceptableRequired Fix 3.6-48PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREWATTS BARWBNP-105THIS PAGE INTENTIONALLY BLANK PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREOF PIPING3.6-49WATTS BAR WBNP-105Table 3.6-10  (Page 1 of 3)Summary of Protection Requirements - Outside Containment 4 - FeedwaterPIPING SYSTEM FeedwaterPIPING NOMINAL Dia. 18 inch  PIPING SCHEDULE    80 BREAK LOCATION BREAK 1  TYPE THRUST 1    DIRECTION WHIP 2 FORMED     EFFECT ON REQUIRED 3        COMPONENTS                     Acceptable/Unacceptable                     Required Fix 418,   118, 218,  318  LLeft  NoJet impingement on spreading room exhaust duct in C11-wall (unit 2 only)Unacceptable loss of Control Building ventilationProvide 3 psibackdraft damper   420,  120, 220,  320  LDown  YesPipe impact on elevation 708 floor of Control BuildingUnacceptable, failure of floor allows pipe whip into electrical board room air handling units below.

Environmental damage to essential components and loss of control room habitability may result.Restraints J42U, J12U, J22U, J32U  421,   121, 221,  321  CDownstream  YesPipe impact on elevation 708 floor of Control BuildingUnacceptable, failure of floor allows pipe whip into electrical board room air handling units below.

Environmental damage to essential components and loss of control room habitability may result.Restraints J42U, J12U, J22U, J32U  422,  122, 222, 322  CDownstream  YesPipe impact on elevation 708 floor of Control BuildingUnacceptable, failure of floor allows pipe whip into electrical board room air handling units below.

Environmental damage to essential components & loss of control room habitability may result.Restraints J42U, J12U, J22U, J32U  423,   123,   223, 323  CUpstream  YesPipe impact on C-3 wall of Control BuildingUnacceptable, failure of wall allows pipe whip into spreading room of Control Building. Environmental damage to essential components and loss of control room habitability may result.Restraints K42W, K12W, K22W, K32WSee page 3 of 3 for notes.

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREOF PIPING3.6-50WATTS BAR WBNP-105424,124,224, 324  CUpstream  YesPipe impact on C-3 wall of Control BuildingUnacceptable, failure of wall allows pipe whip into spreading room of Control Building. Environmental damage to essential components and loss of control room habitability may result.Restraints K42W, K12W, K22W, K32W425,125,225, 325  CDownstream  YesPipe impact on elevation 755 floorUnacceptable, floor fails and results in environmental damage to control room.Restraints K42W, K12W, K22W, K32W  LDown  YesPipe impact on C-3 wall of Control BuildingUnacceptable, failure of wall allows pipe whip into spreading room of Control Building. Environmental damage to essential components and loss of control room habitability may result.Restraints K42W, K12W, K22W, K32W426,126,226, 326   CDownstream  YesPipe impact on elevation 755 floorUnacceptable, floor fails and results in environmental damage to control room.Restraints K42W, K12W, K22W, K32W  LDown  YesPipe impact on C-3 wall of Control BuildingUnacceptable, failure of wall allows pipe whip into spreading room of Control Building. Environmental damage to essential components and loss of control room habitability may result.Restraints K42W. K12W, K22W, K32W428,128,228,328  CDownstream  YesPipe impact on elevation 755 floorUnacceptable, floor fails and results in environmental damage to Control Building.Restraints K42W, K12W, K22W, K32WSee page 3 of 3 for notes.Table 3.6-10  (Page 2 of 3)Summary of Protection Requirements - Outside Containment 4 - FeedwaterPIPING SYSTEM FeedwaterPIPING NOMINAL Dia. 18 inch  PIPING SCHEDULE    80 BREAK LOCATION BREAK 1  TYPE THRUST 1    DIRECTION  WHIP 2 FORMED    EFFECT ON REQUIRED 3        COMPONENTS                    Acceptable/Unacceptable                    Required Fix 

3.6-51PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREOF PIPINGWATTS BARWBNP-105 Notes:1)  Direction of thrust on pipe. Jet load is opposite.For circumferential (C) breaks consider upstream thrust on the upstream pipe and downstream thrust on the downstream pipe.

For longitudinal (L) breaks consider up, down, lateral left, and lateral right thrust (facing downstream).2)  Whip trajectory is governed by hinge mechanism and direction of vector thrust of break force. Maximum 180

&deg; rotation about any plastic hinge. Sweep of jet is governed by pipe motion.3)  Type of effect (jet, whip, environment, etc.) and components affected.

Reflects Analysis Which Was Current at Time of Amendment 51 Submittal      Through-Wall Leakage cracksThrough-wall leakage crack break below Control Building HVAC exhaust ducting at elevation 755 on q-wall (unit2 only)Through-wall leakage crack break would fill control room HVAC with  

steamUnacceptable, loss of habitability of control roomHVAC to have 3 psi backdraft damper installed to prevent steam entering control roomThrough-wall leakage crack break below Auxiliary Building HVAC intake canopy at elevation 743 on A1-wallThrough-wall leakage crack break would fill Auxiliary Building HVAC with

steamUnacceptable, environmental damage to essential components in Auxiliary BuildingHVAC to have temperature sensors installed, which control intake fans, preventing steam from entering Auxiliary Bldg.In all other cases, effects of through-wall leakage crack breaks are acceptable.Table 3.6-10  (Page 3 of 3)Summary of Protection Requirements - Outside Containment 4 - FeedwaterPIPING SYSTEM FeedwaterPIPING NOMINAL Dia. 18 inch  PIPING SCHEDULE    80 BREAK LOCATION BREAK 1  TYPE THRUST 1    DIRECTION  WHIP 2 FORMED    EFFECT ON REQUIRED 3         COMPONENTS                    Acceptable/Unacceptable                    Required Fix 

3.6-52PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTUREOF PIPINGWATTS BARWBNP-105THIS PAGE INTENTIONALLY BLANK PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPING3.6-53WATTS BAR WBNP-105Figure 3.6-1  Shape Factors

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPING3.6-54WATTS BAR WBNP-105Figure 3.6-2  Isometric of Postulated Break Locations (Main Steam Line from Steam Generator #1)

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPING3.6-61WATTS BAR WBNP-105Figure 3.6-9 Isometric of Postulated Break Location (Feedwater Line to Steam Generator # 4)

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPING3.6-62WATTS BAR WBNP-105Figure 3.6-10  Isometric of Postulated Break Locations (Auxiliary Feedwater Steam Supply Lines)

PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPING3.6-63WATTS BAR WBNP-105Figure 3.6-11  S.I. Cold Leg Injection Loop 1 Isometric PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPING3.6-64WATTS BAR WBNP-105Figure 3.6-12  S.I. Cold Leg Injection Loop 4 Isometric PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPING3.6-65WATTS BARWBNP-105Figure 3.6-13  S.I. Cold Leg Injection Loop 2 Isometric PROTECTION AGAINST DYNAMIC EFFECTS ASSOCIATED WITH THE POSTULATED RUPTURE OF PIPING3.6-66WATTS BAR WBNP-105Figure 3.6-14  Isometric of Postulated Break Locations (SI Cold Leg Injection Loop 3)

3.7-2SEISMIC DESIGN WATTS BARWBNP-105thus, the generation of ARS are not necessary, and there are no outstanding issues which necessitate a reevaluation. If a reevaluation of such features to resolve CAQ's etc., is required, Set B ground motion will be used in the reevaluation.3.7.1  Seismic Input 3.7.1.1  Ground Response SpectraVibratory ground motions are defined by two sets of site seismic design response spectra:  the Modified Newmark Ground Re sponse Spectra or Original Site Design Response Spectra for Set A and Set C analyses and the Site Specific Ground Response Spectra for Set B (Evaluation) analyses.

3.7.1.1.2  Site Specific Ground Response Spectra (Set B)Seismic input motions for the evaluation of existing structures, systems, and components are defined by the top-of-rock SSRS shown in Figures 3.7-4a through 3.7-4r. Peak SSE and OBE top-of-rock accelerations are 0.215g (horizontal SSE), 0.15g (vertical SSE), 0.09g (horizontal OBE), and 0.06g (vertical OBE).3.7.1.2  Design Time Histories 3.7.1.2.1  Time Hi stories for Original Site Gr ound Response Spectra (Set A and SetC)For time history analyses, four artificial acceleration time histories were developed so that the response spectra produced by the arithmetic average of the response spectra of each individual record envelope the site seismic design response spectra. Figures3.7-1 through 3.7-4 show the comparison, for the various damping ratios, of these averaged response spectra and the site seismic design response spectra for the SSE. Table 3.7-1 lists the system period intervals at which the response spectra are calculated.

3.7.1.2.2  Time Hi stories for Site Specific Gr ound Response Spectra (Set B)Set B analyses utilize three statistically independent acceleration time histories. The response spectra for these three statistically independent time histories are shown in Figures 3.7-4a through 3.7-4r. These time histories satisfy the SRP design spectra enveloping requirements.

SEISMIC DESIGN 3.7-3WATTS BARWBNP-105The power spectral density function (PSDF) enveloping criteria of  NUREG/CR-5347 were used to ensure adequate energy content of the artificial time histories. The PSDF enveloping criteria are that the PSDFs of artificial time histories whose response spectra envelope the 84th-percentile target response spectra should generally envelope the "minimum required" target PSDF for the corresponding non-exceedance probability level to ensure adequate motion energy contents of artificial time histories. The minimum required target PSDF is defined as the 80% of the target PSDF. The minimum required horizontal and vertical 84th-percentile target PSDFs for the Watts Bar site-specific ground motions were calculated and compared with the corresponding PSDFs of the artificial time histories as shown in Figures 3.7-4s, 3.7-4t, and 3.7-4u.As can be seen from Figures 3.7-4s and 3.7-4t, the PSDFs of the horizontal artificial time histories envelope the corresponding minimum required 84th-percentile target PSDFs in the frequency range of 0.7 cps to 25 cps. The PSDF of the artificial time history H2 dip slightly below the horizontal minimum required 84th-percentile target PSDF in the small frequency range of 0.5 cps to 0.7 cps. This slight dip is considered inconsequential because the response spectral values of H2 time history envelope the site-specific response spectra in this frequency range and no structural frequencies of Category I structures exist in this low frequency range. Thus, the horizontal SSRS-compatible artificial time histories have adequate motion energy contents and their PSDFs satisfy the PSDF enveloping criter ia proposed in NUREG/CR-5347 in the frequency range of 0.7 cps to 25 cps.Similarly, as can be seen from Figure 3.7-4u, the PSDF of the vertical artificial time history envelope the corresponding minimum required, 84th-percentile target PSDF in the frequency range from 1.6 to 25 cps. The PSDF of the artificial time history has very slight dips below the vertical minimum required 84th-percentile target PSDF in the small frequency ranges of 0.40 to 0.42 cps, and 1.2 to 1.6 cps. These slight dips are considered inconsequential because the response spectral values of the vertical time history envelope the site-specific response spectra in these frequency ranges and no structural frequencies of Category I structure exist in this low frequency range. Thus, the vertical SSRS-compatible artificial time history has adequate motion energy contents and its PSDF satisfy the PSDF enveloping criteria proposed in NUREG/CR-5347 in the frequency range of 1.6 to 25 cps.3.7.1.3  Critical Damping ValuesThe specific percentages of critical damping values used for Category I structures, systems, and components are provided in Table 3.7-2 for Sets A, B, and C.

3.7.1.4  Supporting Me dia for Seismic Cate gory I StructuresA complete description of the supporting media for each Seismic Category I structure is provided in Section 2.5.4. Pertinent data concerning the supporting media for Set A, B, and C analyses of each Seismic Category I structure is also given in Table 3.7-3.

====3.7.2 Seismic====

System AnalysisThis section describes the seismic analysis performed for Category I structures.

3.7-4SEISMIC DESIGN WATTS BARWBNP-1053.7.2.1 Seismic Analysis MethodsThe seismic methods of analysis used for the Category I structures listed in Section3.2.1 are described in the following sections.

3.7.2.1.1 Category I Rock-Supported Stru ctures - Original Analyses (Set A)The seismic analyses of Category I structures were based upon dynamic analyses using the lumped mass normal mode method with idealized mathematical models. The inertial properties of the models were characterized by the mass, eccentricity, and mass moment of inertia of each mass point. Mass points were located at floor slabs, changes in geometry, and at intermediate points to adequately model the structure. The stiffness properties were characterized by the moment of inertia, area, shear shape factor, torsion constant, Young's modulus, and shear modulus. Significant modes of vibration were considered in determining the total response. For structures with built-in asymmetry and open structures which have low torsional resistance, coupled translation and torsion were included in the dynamic analyses. Torsional effects for the closed structures with small eccentricities have insignificant effect on the responses. To demonstrate this, a dynamic analysis study of the steel containment vessel, including an accidental eccentricity of 5% of the diameter, showed that the induced torsion had a negligible effect on the acceleration response spectra. Structural response was calculated in both the east-west and north-south directions except where symmetry justifies analyses in one direction. The effect of the vertical component of earthquake motions on the structural response was included.For structures surrounded by soil, the effect of the soil stiffness on the structural response was determined by replacing the soil with springs of equivalent stiffness. Due to seismic motion, the soil pressure against structures was increased above the static soil pressure. The magnitude of this increase was determined by using the shaking table experiments performed for the design of TVA's Kentucky Hydro Project[1]. For a ground acceleration of 0.18g the static soil pressure was increased by 46% for a dry fill and 22% for a saturated fill. This incremental increase was combined with the static pressure as a triangle of pressure whose apex is at the rock surface and maximum ordinate is at the ground surface. In addition to the soil pressure increase as described above for a saturated fill, the hydrostatic pressure of water within the fill was increased 22%. This incremental increase was combined with the static water pressure as a triangle of pressure whose apex is at the water surface and maximum ordinate is at the rock surface or bottom of structure. Calculations using the shaking table experiment results have been confirmed using information in Reference[2]. A more detailed description of the seismic analyses of Category I rock-supported structures is discussed below.The in situ measured shear wave velocity of the bedrock upon which the structures are founded has an average value of 5,900 feet per second (Section 2.5.4.8). Therefore, the effect of structure-foundation interaction was investigated for the major structures.

SEISMIC DESIGN 3.7-5WATTS BARWBNP-105The structural response was computed using the response spectrum modal analysis method. The techniques used to account for the three components of motion and the method of combining modal responses when computing the structural response of a structure are explained in Sections 3.7.2.6 and 3.7.2.7, respectively.Response spectra were produced by the time history-modal analysis method using the four artificial accelerograms discussed in Section 3.7.1.2 and the techniques of Sections 3.7.2.5 and 3.7.2.9.When torsion is considered, accelerations and deflections were calculated at the farthest points on the structure from the shear center, on the axis perpendicular to the direction of motion. The moment and shear due to earthquake motion were used in combination with other appropriate loads to determine overturning moments.

The response was calculated for both th e OBE and the SSE, except when the same percentages of critical structural damping were specified for both earthquake levels, in which case the response was calculated for the OBE only (the SSE results are twice the OBE results). For applicable stress criteria, see Section 3.8.The damping ratios used in the dynamic analyses of the structures are given in Table3.7-2.To ensure that the results of the seismic analysis of the structures were used in the design, the analyses became part of the nuclear plant design criteria and were submitted to the design sections responsible for design and to the principal engineer. For more detailed procedures and criteria of design control measures, see Section 3.8.Shield Building Two separate, distinct analyses were performed on the reinforced concrete structure to determine the response of the structure to horizontal motion when modeled as a cantilever beam and the response of the dome to vertical motion when modeled as a shell.The Watts Bar Shield Building is identical to the Shield Building at TVA's Sequoyah Nuclear Plant. The building has been assumed to have identical structural properties in both the east-west and north-south directions. A sketch of the lumped mass model is shown in Figure 3.7-5 and the structural properties are listed in Table 3.7-4. The dome was considered a rigid body and its weight added at mass point 25. The dynamic analyses in both the horizontal and vertical directions was done by the normal mode response spectrum method. Although no structural eccentricities exist in the building, an accidental eccentricity of 5% of the diameter was assumed in the design. Periods for the normal modes of vibration are listed in Table 3.7-5.Since torsion is considered, the maximum structural accelerations and deflections will not occur at the center of mass but rather at the point on the structure farthest from the shear center. For the Shield Building the shear center is located at the geometric center. Accordingly, all structural accelerations and deflections as well as the floor response spectra have been computed at a point located on the shell wall. Structural 3.7-6SEISMIC DESIGN WATTS BARWBNP-105responses were calculated for both the OBE and SSE using structural damping of 2 and 5 percent, respectively.Foundation-structure interaction studies were performed to determine the response characteristics of the Shield Building steel containment-interior concrete system to rocking-type motion. These analyses were performed considering lumped-mass models of the structure coupled with foundation springs. These springs were calculated as detailed by Whitman

[3]. The results of these investigations indicated that the Shield Building accelerations would increase by less than 15% compared to the accelerations of a rigid base, single structure system. As a result, all spectra used to compute structural response and all accelerograms used to compute floor response spectra were multiplied by a factor of 1.15. The site response spectra for structures without rocking have previously been shown in Figures 2.5-236a and 2.5-236b. The effects of the soil which partially surround the building were investigated for the Sequoyah Nuclear Plant

[4] and the effects are negligible.Floor response spectra were computed for four individual artificial earthquakes (increased in amplitude by 15%) and the result found by taking the arithmetic mean of the four analyses. Spectra were computed for damping ratios of 0.005, 0.01, and 0.02 for the OBE and 0.005, 0.01, 0.02, 0.030, 0.040, and 0.050 for the SSE. Vertical modes of vibration were calculated for comparison with the results for the dome as a shell.

The rigid-body simulation of the dome as performed in the analysis of the cantilever beam model does not provide an accurate representation of the response of the dome to vertical earthquake excitation. Thus, an analogy was developed using shell theory to determine the earthquake moments and forces in the dome.Figure 3.7-6 illustrates the logic performed in the analysis. The shell model is shown in Figure 3.7-7.A flexibility matrix was developed using the shell model and the analysis performed using the response spectrum modal analysis techniques. The modes involving primarily deformation of the cylinder as computed in this analysis (modes 1 and 5) compare favorably with modes 1 and 2 of the vertical lumped mass cantilever beam analysis as shown in Table 3.7-5 (periods agree within 3%). Modes 2, 3, and 4 are primarily modes of vibration involving the dome. Also, the total meridional force at the base of the building as calculated by this method compares closely with the total force at the base in the cantilever beam analysis. This indicated the appropriateness of the analogy.The structural response for the shell model was calculated for both the OBE and the SSE using structural damping of 2% and 5%, respectively.Interior Concrete Structure The idealized lumped mass model of the reinforced concrete structure used in the dynamic earthquake analysis is shown in Figure 3.7-8. Element properties are given in Table 3.7-6 and mass point properties in Table 3.7-7. The foundation structure interaction analysis of the Shield Building interior concrete-steel containment system discussed above for the Shield Building analysis revealed no significant change in the SEISMIC DESIGN 3.7-7WATTS BARWBNP-105response of the interior concrete structure as compared to the response assuming a fixed base. Therefore, the dynamic analysis was performed using a fixed base model.The dynamic earthquake analysis was performed by the response spectrum modal analysis technique. The results were computed for both the OBE and SSE conditions with structural damping of 2% and 5% respectively. The effects of torsion and longitudinal motion were considered. Periods for the normal modes of vibrations are listed in Table 3.7-8.Response spectra were produced for damping values of 0.005, 0.01, and 0.02 for the OBE at mass points 1, 2, 3, 4, 6, 8, 10, 12, 13, and 14 for motion in both the east-west and north-south directions. Response spectra for vertical motion were obtained at ground and at mass point 14, and linear interpolation (Section 3.7.2.5) was used to produce vertical spectra at intermediate mass points. Response spectra were produced for damping values of 0.005, 0.010, 0.020, 0.050, 0.100, and 0.150 for the SSE at mass points 3, 5, 6, 8, 9, 10, 11, and 14 for motion in both the east-west and north-south directions. Response spectra for vertical motion were produced at mass point 14 and ground. Linear interpolation (see Section 3.7.2.5) was used to obtain vertical response spectra at intermediate points.Auxiliary/Control BuildingThe idealized lumped mass model of the reinforced concrete structure is shown in Figure 3.7-9. Foundation-structure interaction was investigated by using a lumped mass-rock spring model, as discussed in Section 3.7.2.4. The results verified that a fixed base analysis may be used with no loss in accuracy. The dynamic analysis was performed by the response spectrum modal analysis technique. The results were computed for the OBE condition, and resu lts for the SSE were obtained by doubling the values from the OBE. Element properties for the fixed base model are given in Table 3.7-9 and mass point properties in Table 3.7-10. Contributory weights to account for the soil contained within the wing walls at the north end of the structure were included in the total weights of the appropriate mass points. The effects of torsion and longitudinal motion were considered. Periods for the normal modes of vibrations are listed in Table 3.7-11.Steel Containment Vessel The containment vessel dynamic seismic analyses were performed using a lumped mass beam model. Structural and equipment masses were included, and structural properties were computed by hand calculations. The beam model and its properties are shown in Figure 3.7-7B.Maximum overturning moments, shears, deflections, and shell stresses were computed by the response spectrum method. The site seismic design response spectra for 1% damping described in Sections 2.5.2.6 and 2.5.2.7 were utilized. The analyses were performed by CBI proprietary computer program 1017 described in Appendix 3.8C. Total response was computed by taking the absolute sum of modal responses.

3.7-8SEISMIC DESIGN WATTS BARWBNP-105A time-history analysis using the model in Figure 3.7-7B was performed in order to develop response spectra for equipment attached to the containment vessel. Four artificial earthquakes having an averaged response spectrum greater than the design response spectrum provided the seismic input. Using each of the artificial earthquakes individually, the beam model was analyzed and histories of acceleration were generated. For each of the acceleration histories, response spectra for various mass points and values of assumed damping were generated. The design spectra were the envelopes of the spectra generated from the four earthquakes and were used to design the vessel and the vessel's appurtenances in the scope of CBI, the vessel designer, fabricator, and erector. These calculations were performed by CBI computer programs 1017, 1044, and 1668, all of which are described in Appendix 3.8C.As part of the review process and to provide response spectra for the design of equipment, piping and subsystems attached to and or supported by the containment vessel not supplied by the CBI, TVA performed an independent dynamic seismic analysis of the containment vessel. The ground motion input used to generate the floor response spectra consisted of the same four accelerograms of artificial earthquakes used by CBI.The containment was idealized as a beam-type model consisting of lumped masses connected by massless elastic members. This lumped mass model is shown in Figure3.7-7C. The element properties and inertial properties which were used in the analysis are shown in Table 3.7-5A and Table 3.7-5B, respectively.North Steam Valve RoomThe idealized lumped mass model of the reinforced concrete structure is shown in Figure 3.7-10. The structure is founded on bedrock and partially imbedded in soil. The effect of the soil restraint on the seismic response of the structure was included in the lumped mass model as soil spring restraints. The soil springs were calculated in accordance with the methodology given in Section 3.7.2.1.3. Element properties are shown in Table 3.7-12 and mass point properties in Table 3.7-13.The dynamic analysis was performed using the response spectrum modal analysis technique. Response spectra were produced for selected elevations within the structure by the time history modal analysis method. Results were computed for the OBE with results for the SSE obtained by doubling those for the OBE. The frequencies for those modes considered important to the response of the structure are listed in Table 3.7-14.Essential Raw Cooling Water Intake Pumping StationThe idealized lumped mass model of the reinforced concrete structure used in the analysis is shown in Figure 3.7-11. The dynamic analysis was performed by the response spectrum modal analysis technique. The results were computed for both the OBE and SSE with an assumed structural damping of 5% for each earthquake. Element properties are given in Table 3.7-15 and mass point properties in Table3.7-16. The effects of torsion and soil restraint were considered. Periods for normal modes of vibration are listed in Table 3.7-17.

SEISMIC DESIGN 3.7-9WATTS BARWBNP-105In addition, the effect on the building response of various water levels inside the pump wells was studied. The results of this study showed that the natural period of vibration was affected by variations in water level. Therefore, the structural responses used for design were those for the "worst-case" conditions. The amplitude of the response spectra peaks was not significantly affected by the water level variations. Only the location of the peak changed as the natural periods changed in response to water level variations. Accordingly, the response spectra peaks were broadened to account for the range of variations in natural period.The response spectra for horizontal motion were produced for damping ratios of 0.005, 0.01, and 0.02 for both the OBE and SSE at mass points 6, 7, 8, and 10. Response spectra for vertical motion were produced for the base and mass points 8 and 10.

Vertical spectra for intermediate mass points were developed using linear interpolation, as outlined in Section 3.7.2.5. Essential Raw Cooling Water Intake Pumping Station-Retaining WallsThe reinforced concrete retaining walls were designed as a rigid structure subjected to the top of rock acceleration. Dynamic soil pressures on the retaining wall was determined in accordance with Reference [1].

3.7.2.1.2 Category I Rock - Supported Structures - Ev aluation and New Design or Modification Analyses (S et B and Set B+C) Analysis methodologies used in the original analyses (Set A) of Category I rock-supported structures were used in Evaluation (Set B) and New Design/Modification (Set B plus Set C) analyses except as noted in the remainder of this subsection. These exceptions provide for a seismic modeling approach which is consistent with current SRP Subsection 3.7.2 (NUREG 0800, Rev. 1) requirements.Structures were represented as three-dimensional lumped mass stick models in the analyses except when coupling effects from omitted degrees of freedom were not significant. Actual centers of rigidity and actual mass eccentricities were modeled. Sufficient numbers of modes were included in the response to assure participation of at least 90% of the total mass. The simultaneous effects of three components of seismic input were considered by combining the co-directional responses resulting from the three components of input either by algebraic summation (for simultaneous inputs) or by the square-root-of-the-sum-of-squares (SRSS) method. For design of structural elements, calculated seismic torsional moments were increased to account for accidental torsion. This increase is determined by multiplying the story shear force by the accidental eccentricity (defined as + 5% of the structure dimension perpendicular to the direction of excitation.) Rock-supported structures (ACB, IPS) were modeled as fixed base structures except where rock-structure interaction (Reactor Building) or structure-surrounding soil interaction (NSVR) effects were important. In these cases, three-dimensional finite element analysis was used to account for the interaction effects. The analyses were based on a foundation rock shear wave velocity of 5900 fps (Section 2.5.4.8). For rock-supported structures deeply embedded in soil, the effect of soil-structure 3.7-10SEISMIC DESIGN WATTS BARWBNP-105interaction was considered and, where significant, included in the analysis model. The soil stiffness was determined as discussed in Subsection 3.7.2.1.4.Structural damping values used in Set B and Set C analyses are given in Table 3.7-2. Where necessary, element associated damping was converted to modal damping using the strain energy composite modal damping approach.Reactor Building Rock-Structure Interaction AnalysisThe Reactor Building consists of the Shield Building (SB), Steel Containment Vessel (SCV), and interior concrete structure (ICS) including the NSSS piping, equipment, and components. The Set B and Set C Reactor Building model is a three branch, three dimensional (3-D) lumped mass model with branches representing the ICS, SB, and SCV. The ICS model was developed from a finite element analyses whereas the SB and SCV models were Set A models updated to include, in the vertical model, the fundamental vertical drumming mode of the dome for each of these structures. The ICS model used for the analyses also includes the NSSS model.The Reactor Building is partially embedded in soils below the finished grade at Elevation 728.0 and in foundation rock below Elevation 702.78. In order to take into account the embedment effect on seismic responses, rock-structure interaction analyses were performed for the Reactor Building using the 3-D SSI analysis-computer program SASSI.For the seismic response analysis, the input ground motion input was prescribed at the surface of the rock foundation (Elevation 702.78). This is the elevation of the top of the Reactor Building basemat where base fixity was provided for the structural models used in the original design basis seismic analysis (Set A). For rock-structure interaction analyses, the structural models for SB, SCV, and ICS were coupled together through the common Reactor Building basemat. The embedment of the Reactor Building basemat in the rock foundation was considered.Using the SASSI computer program, time history response analyses for the Reactor Building were performed in the frequency domain using the Fast Fourier Transform (FFT) method.Shield Building (SB)The Set B and Set C dynamic model for the axisymmetric Shield Building structure is represented by a 3-D lumped mass single stick (Figure 3.7-5A) having the center of mass coincident with the center of rigidity for each lumped mass elevation. The model consists of 25 lumped masses interconnected with 25 elastic beam elements and a single-degree-of-freedom (SDOF) system located at the dome spring line elevation (Elevation 852.0) for simulating the fundamental vertical drumming mode of the dome.

Except for the vertical SDOF system for the dome and the concrete modulus, the model configuration, lumped masses, and elastic beam element properties are the same as those used in the original design basis seismic analyses (Set A analysis). The vertical SDOF system for representing the fundamental vertical drumming mode of the dome was developed by matching the frequency and effective modal mass of the SEISMIC DESIGN 3.7-11WATTS BARWBNP-105SDOF system with those of the fundamental vertical drumming mode of the dome obtained from a separate finite element modal analysis for the dome. The model geometry, lumped masses, and elastic beam element properties for SB used for Set B and Set C analyses are summarized in Table 3.7-4A.Interior Concrete Structure (ICS)The ICS consists of a complex assemblage of curved walls, columns and slabs which have some cross sections with significant asymmetry. In order to develop a seismic model, static, 3-D, finite element analyses were performed to determine the equivalent beam properties that simulate the seismic responses of the ICS. Consistency of equivalent stick model properties and response transfer functions with those of the finite element model demonstrated the adequacy of the 3-D equivalent stick model.Since the equivalent beam model results in center-of-rigidity locations for axial and bending deformations different from those for shear and torsional deformations, the 3-D stick model for the ICS was represented by a combination of two sticks. One stick consists of elements with only axial areas of the structure located at the centers of rigidity for axial and bending deformations and another stick consists of elements with all other beam element properties, except the axial area, located at the centers of rigidity for shear and torsional deformations. The final configuration of the 3-D stick model for the ICS is shown in Figures 3.7-8A and 3.7-8B.Mass and member element properties are summarized in Tables 3.7-6A and 3.7-6B. Mass properties are unchanged from those of the original analysis (See Table 3.7-7).Steel Containment Vessel (SCV)The dynamic model for the SCV Set B and Set C analyses is represented by a 3-D lumped mass, concentric single stick model as shown in Figure 3.7-7A. The model consists of 23 lumped masses interconnected with 23 elastic beam elements and a vertical SDOF system located at the dome spring line elevation (Elevation 814.5) to represent the fundamental vertical mode of the dome. Mass and member element properties are defined in Table 3.7-5C. Except for the mass eccentricities and the SDOF vertical model, the model configuration, lumped masses, and elastic beam element properties are the same as those used in the original (Set A) design basis seismic analyses described in Section 3.7.2.1.1. During the analysis of Set B and SetC, it was determined that the 5% accidental eccentricity will yield much higher eccentric responses than from the actual eccentricities which were used in Set A analysis. Therefore, the actual eccentricities were neglected in Set B and Set C analyses. However, 5% accidental eccentricity was used to calculate torsional moments. The SDOF vertical dome model for SCV was developed by matching the frequency and effective modal mass of the SDOF system with those of the fundamental vertical mode of the dome obtained from a separate finite element modal analysis.Nuclear Steam Supply System (NSSS) ComponentsFor Set B and Set C analyses, the dynamic model for the NSSS components is coupled with the Interior Concrete Structure (ICS) model, and the coupled model is 3.7-12SEISMIC DESIGN WATTS BARWBNP-105 used for seismic response analyses. The dynamic model for the NSSS components included in the coupled model for the ICS consists of the models for the Reactor Pressure Vessel (RPV), four primary reactor coolant loop piping (hot legs, cold legs, and cross-over legs), the steam generator (SG), and the reactor coolant pump (RCP) associated with each loop, as shown in Figures 3.7-8C through 3.7-8G. In coupling the NSSS model to the ICS stick model, the RCL attachment points are connected to the ICS model at the appropriate elevations of the attachment points through rigid links.

The dynamic model data fo r the NSSS components are obtained from Westinghouse Electric Corporation.Due to the presence of gaps and tension-only tie rods at the NSSS supports, these supports exhibit nonlinear behavior under dynamic loading conditions. For the purpose of linear response analysis, four linearized NSSS analysis cases, each with a unique set of linearized NSSS support stiffn ess, are used to represent the nonlinear behavior under various dynamic loading conditions. For each NSSS analysis case, a specific set of NSSS supports with their specified orientations are activated for a particular loading condition and linear support stiffnesses are developed and provided by Westinghouse Electric Corporation to represent the active supports for application to the particular analysis case.The final acceleration response spectra and movements values are the envelope values resulting from the different NSSS cases. Furthermore, the ARS and movement values at the corresponding locations of the four loops are enveloped to obtain the enveloped ARS and movements applicable to all four loops.The seismic analysis of the NSSS components which was performed by Westinghouse is discussed in Section 5.2.1.10.Auxiliary Control Building (ACB)The Set B and Set C three-dimensional lumped parameter fixed-base model of the Auxiliary Control Building is shown in Figure 3.7-9A. The centers of mass and centers of rigidity were modeled at their actual geometric locations as defined in Table 3.7-9A. The element properties and masses are unchanged from the original analysis, except for the concrete shear modulus, and are listed in Tables 3.7-9 and 3.7-10.The dynamic analysis was performed by the time-history modal analysis technique. Structural responses were computed and floor ARS were generated for the same elevations as Set A. For Set C, since the structure damping ratios for OBE and SSE are the same (5%), the OBE responses were computed and the SSE responses were obtained by doubling the OBE responses. Separate OBE and site-specific SSE analyses were performed for Set B using structure damping ratios of 4% for OBE and  

7% for site-specific SSE.Essential Raw Cooling Water Intake Pumping Station (IPS)The ERCW IPS original analysis model is updated to consider torsional effects. It incorporates rotatory inertia and the eccentricities between the centers of mass and centers of rigidity. No lateral soil springs were included as these had been determined SEISMIC DESIGN 3.7-13WATTS BARWBNP-105from previous analyses to produce a negligible soil-structure interaction effect. The highest water level was used for both the Set C SSE and OBE earthquakes and Set B site-specific SSE and OBE earthquakes, since this condition yields the lowest frequency and hence would produce the highest response levels. The Set B and SetC IPS model is shown in Figure 3.7-11A. Table 3.7-15A presents the element properties. Tables 3.7-16A and 3.7-16B define the weight properties and coordinates of centers of mass and centers of rotation, respectively.North Steam Valve Room (NSVR)To account for the soil-structure interaction effects due to the presence of backfill surrounding the foundation walls, soil-structure interaction (SSI) analyses were performed for the NSVR. The methodology used for SSI analysis is the same as that used for Category I soil-supported structures described in Section 3.7.2.1.4.The three-dimensional lumped mass model used in the seismic analysis of the NSVR superstructure is shown in Figures 3.7-10A and 3.7-10B, and the model properties are given in Tables 3.7-13A and 3.7-13B.

3.7.2.1.3  Category I So il-Supported Structures - Or iginal Analysis (Set A)For structures founded on soil, the acceleration at top of rock was amplified or attenuated through the soil deposit using the techniques outlined in Section 3.7.2.4. The soil-supported structures were analyzed using lumped-mass and soil spring modeling techniques. A typical model is shown in Figure 3.7-12.Table 3.7-3 contains a tabulation of Seismic Category I soil-supported structures for the plant (small miscellaneous structures are not included in the table). Details of the supporting media and foundation characteristics are presented in Table 3.7-3 and Section 3.7.1.4. The horizontal and vertical translational soil springs and the rocking soil spring included in the lumped-mass model to simulate soil structure interaction are calculated using the procedures outlined by Whitman[3]. The damping ratio used for soil-supported structures depends on the predominant type of motion, as explained by Richard[5], but is not permitted to exceed 10% in any case. Embedment effects are accounted for by constructing a translational soil spring using Whitman's vertical spring expressions and attaching it to appropriate point or points on the structure.Specific features associated with the seismic analysis of the Category I soil-supported structures are discussed below.Diesel Generator BuildingThe idealized lumped mass model of the reinforced concrete structure used in the analysis is shown in Figure 3.7-13. Element properties are given in Table 3.7-18 and mass point properties in Table 3.7-19. The effects of horizontal translation and rocking of the base were considered.The soils investigation of Section 2.5.4 revealed a soils profile from bedrock consisting of a firm silty gravel overlain by lean clays, silt of low plasticity, and sandy silt. In order to assure a firm foundation for the structure, the material between the top of firm gravel 3.7-14SEISMIC DESIGN WATTS BARWBNP-105and the grade slab (a depth of approximately 17 feet) was excavated and replaced with compacted granular fill.The Diesel Generator Building is founded on granular fill overlying firm gravel (see Figure 2.5-226). The shear wave velocity for the foundation material was determined to be 1650 ft/s and was used to calculate the value of the soil springs for the lumped-mass soil-structure interaction model. A parametric study was conducted to investigate the effects on building response of varying the shear wave velocity of the foundation material from 1150 ft/s to 2150 ft/s. The parametric study resulted in the structure being designed for earthquake loads from the peak of the amplified response spectrum for surface motion. The predominant motion of the structure was a translatory rigid body motion. Motion of this type results in large damping; therefore, a damping ratio of 0.10 was used for the analysis. Longitudinal motion was also considered. Periods for the normal modes of vibrations are listed in Table 3.7-20. Response spectra were produced for damping ratios of 0.005, 0.010, 0.020, 0.050, and 0.070 for mass points 1, 3, and 6 for motion in both east-west and north-south directions.Waste Packaging Area (WPA)The following two paragraphs describe the original design basis analysis for using SetA criteria performed for the WPA.The idealized lumped mass model of the reinforced concrete structure is shown in Figure 3.7-14. Element properties are given in Table 3.7-21 and mass point properties in Table 3.7-22. The analysis indicated that the primary motion of the structure was in rocking and translation of the base. Motion of this type results in large damping; therefore, a damping ratio of .10 was used in the analysis. Longitudinal motion was also considered. Periods for the normal modes of vibration are listed in Table 3.7-23.Due to the extent of excavation for the Auxiliary Building and the results of the investigation for the Diesel Generator Building, all in situ material down to the top of rock was excavated and replaced with compacted granular fill for the WPA (see Figure2.5-225). The shear wave velocity for the material was determined to be 1650 ft/s, and was used to calculate the value of the soil springs for the lump-mass soil-structure interaction model. A parametric study was conducted to investigate the effects on building response of varying the shear wave velocity from 1150 ft/s to 2150 ft/s. The parametric study resulted in the structure being designed for earthquake loads from the peak of the amplified response spectrum for surface motion. Additional studies beyond those described above have been performed to determine relative displacements between the WPA and the Auxiliary and Control Buildings.Refueling Water Tanks and ERCW Pipe TunnelsThe refueling water tank and foundations were designed for seismic loads determined from the basic procedure outlined above. Soil property variations were considered in SEISMIC DESIGN 3.7-15WATTS BARWBNP-105order to define conservative design loads, and ten-percent damping was used because of predominant translational soil spring motion. The adequacy of the design was later verified by more exact analytical techniques for soil-structure and fluid-structure interaction.Pipe tunnels are analyzed as discussed under "Underground Electrical Concrete Conduit Banks" except axial loads are not considered due to the segmented configuration of the tunnel. Dynamic soil pressures on the walls are determined in accordance with Reference [1].Underground Electrical Concrete Conduit BanksThe underground electrical concrete conduit banks which lead from the Auxiliary Building to the Diesel Generator Building and the Intake Pumping Station were seismically analyzed.Utilizing the average values for the soil shear wave velocity and density, the ground deformation pattern in terms of wave length and amplitude is determined. The buried conduit banks are assumed to deform along with the surrounding soil layers.The average shear wave velocity of a single layer representation of a multi-layered soil system may be determined by:Where, V ST=  Average shear velocity in the soil, ft/sec V S =  Shear velocity in each layer of soil, ft/sech' =  Depth of each layer of soil, fth =  Total depth of soil, ftThe fundamental period of the single layer is calculated from the following equation:

M j =  lowest modal number associated with group j of closely spaced modes N j =  highest modal number associated with group j of closely spaced modes K z =  coupling factor with R T 2 R i 2 i 1=N2 R K R KK 1+=N jKM j=N j 1-j 1=S+= K1'K'-'k k'+--------------------------------

3.7-28SEISMIC DESIGN WATTS BARWBNP-105Where,j = frequency of closely spaced mode j (rad/sec)j = fraction of critical damping in closely spaced mode j t d = duration of the earthquake (sec.)An example of this equation applied to a system can be supplied with the following considerations. Assume that the predominant contributing modes have frequencies as given below:There are two groups of closely spaced modes, namely with modes 2, 3, 4 and 6, 7.

Therefore,S =  2 number of groups of closely spaced modes M 1 =  2 lowest modal number associated with group 1 N 1 =  4 highest modal number associated with group 1 M 2 =  6 highest modal number associated with group 2 N 2 =  7 highest modal number associated with group 2N =  8 total number of modes consideredThe total response for this system is, as derived from the expansion of  the first equation under Section 3.7.2.7.2:3.7.2.8  Interaction of Non-Category I Structures With Seismic Category I StructuresAll interfaces between Category I and non-Category I structures were designed to withstand the displacement and/or dynamic loads produced by both the Category I and non-Category I structures and equipment. The Turbine Building and Service Buildings are the only non-Category I structures for which this section applies. The Turbine and Mode12345678Frequency5.08.08.38.611.015.516.020 R T 2 R 1 2 R 2 2 R 3 2R 8 2 2 R 2 R 3 23+++++= 2+R 2 R 4 24 2 R 3 R 4 34 2 R 6 R 7 67++

SEISMIC DESIGN 3.7-29WATTS BARWBNP-105Service Buildings were analyzed for a total lateral base shear computed as the product of the mass of the structure and the ground acceleration for the SSE. The total lateral shear was distributed in the height of the structure according to the provisions of the Uniform Building Code.

3.7.2.9  Effects of Parameter Va riations on Floor Response SpectraTo account for variations in structural frequencies owing to variations in material properties of the structure and soil and to approximations in modeling techniques used in seismic analyses, the computed floor response spectra are smoothed and peaks associated with the structural frequencies are broadened + 10% for Set A and Set C and + 15% for Set B.For the soil-supported structures in which floor response spectra were produced, the soil properties were varied to account for variations in soil properties. Soil-structure interaction was considered as discussed in Sections 3.7.2.1 and 3.7.2.4.

3.7.2.10  Use of Constant Vertical Load Factors 3.7.2.10.1  Other Than NSSS 3.7.2.10.1.1  Origin al Analysis (Set A)A vertical lumped mass dynamic analysis using the techniques outlined in Section3.7.2.1.1 was performed for all of the Category I structures to determine the vertical loads. The results for each horizontal earthquake analysis were separately added on an absolute basis to the loads from the vertical earthquake analysis. Static vertical load factors were not used unless the dynamic analysis indicated the structure behaved as a rigid body in the vertical direction.3.7.2.10.1.2  Evaluation and Ne w Design or Modification AnalysesThe Category I structures, when analyzed for vertical motion, used lumped-mass dynamic techniques as discussed in Section 3.7.2.1.2. For Evaluation Analyses (SetB), the co-directional time history responses are either computed by simultaneous application of the seismic input in three directions or by the SRSS method. For Set C, co-directional responses are combined by SRSS only. For systems and components the appropriate floor response spectra was used in the analysis. Static load factors were not used for either Set B or Set C analysis.

3.7.2.10.2  For NSSSStatic vertical load factors are not used as the vertical floor response load for the seismic design of safety-related systems and components within Westinghouse scope of responsibility.

3.7.2.11  Methods Used to A ccount for Torsional EffectsThe dynamic analysis of structures is discussed in Section 3.7.2.1. In original or SetA analyses, torsional effects were considered by using a lumped-mass cantilever beam 3.7-30SEISMIC DESIGN WATTS BARWBNP-105model to represent stiffness and inertial characteristics. The torsional moment of inertia, eccentricity, and mass moment of inertia were included in the analyses.In the process of preparing lumped-mass mathematical models for the Set A analyses, the location of both the center of rotation and center of mass for each floor were computed. Accelerations and deflections were calculated where their maximum values occurred (at the farthest points on the structure from the shear center, on the axis perpendicular to the direction of motion).For Set B and Set C analyses, modeling of torsional effects was refined by three-dimensional modeling.The models described above were subjected to seismic excitations and the resultant responses in the form of frequencies, mode shapes, moments, and forces were obtained.3.7.2.12  Comparison of R esponses - Set A versus Set BThe comparison of Set A and Set B responses showed that, in general, Set A responses were higher. In making the ARS comparisons, the applicable damping ratios of Set A and Set B were used. In certain frequency ranges, Set B responses were higher than Set A responses. An evaluation was performed on a building by building basis to assess the impact of Set B response. Adequacy of structures, systems, and components for Set B effects has been documented in calculations.As a sample comparison of Set A and Set B responses, the ARS comparisons for Auxiliary Control Building, which is a rock-supported structure, and for the Diesel Generator Building, which is a soil-supported structure, are presented. The ARS for north-south, east-west and vertical directions are compared. The comparison at Elevation 692.0 and Elevation 814.25 of the Auxiliary Control Building are presented in Figures 3.7-15D through 3.7-15I.

3.7.2.14  Determination of Category I Structure Overturning Moments3.7.2.14.1  Original AnalysisFrom the dynamic analyses of the structures, the seismic moments, shears, and vertical loads were determined at the base of the structure. These loads were used in combination with other appropriate loads in determining total overturning effects as discussed in Section 3.8.

3.7.2.14.2  Eval uation and New De sign or Modification AnalysisFrom the dynamic earthquake, analyses total moments, shears, and vertical loads were computed.

SEISMIC DESIGN 3.7-31WATTS BARWBNP-105The earthquake moment, shear, and vertical load were used in combination with other appropriate loads in determining total overturning effects as discussed in Section 3.8.

3.7.2.15  Analysis Procedure for DampingThe damping values used in the dynamic earthquake analyses of Category I structures are given in Table 3.7-2.For Set A analysis, the Category I structural models were not coupled together, therefore, the structural damping values used in the seismic analyses are as shown in Tables 3.7-2 and 3.7-24.For Set B and Set C analyses, either composite modal damping or structural damping were used in the seismic analyses of Category I structures. The damping values used for the various structures and components are given in Tables 3.7-2 and 3.7-24. The damping used in the seismic analysis of systems and components are also given in Tables 3.7-2 and 3.7-24.Under the Westinghouse standard scope of supply and analysis, the lowest damping value associated with each element of the system is used for all modes.

====3.7.3 Seismic====

Subsystem Analysis 3.7.3.1 Seismic Analysis Me thods for Other Than NSSSThe seismic analysis of Category I piping systems is described in detail in Section3.7.3.8. In the analysis of piping subsystems there are two distinct approaches to seismic analysis. A detailed analysis is discussed in Section 3.7.3.8.2 and a simplified analysis is discussed in Section 3.7.3.8.3.The general seismic analysis of Category I equipment and components is discussed in Section 3.7.3.16. Additional details applicable for simplified analysis are discussed in Sections 3.7.3.5 and 3.7.3.10.The seismic analyses of HVAC and conduit/cable tray subsystems are discussed in Sections 3.7.3.17 and 3.10.3, respectively.The detailed seismic analyses of Category I subsystems is based upon dynamic analyses using the lumped mass normal mode method with idealized mathematical models. The inertial properties of the models are characterized by mass, eccentricity, and mass moment of inertia of each mass point. Mass points are located at carefully selected points in order to accurately model the subsystem as described in Section 3.7.3.3.1. The stiffness properties are characterized by the moment of inertia, area, torsion constant, Young's modulus, and shear modulus.The response of Category I subsystems are computed by the response spectrum modal analysis method for designs. All significant modes of vibration are considered 3.7-32SEISMIC DESIGN WATTS BARWBNP-105in determining the total response. Subsystem response is calculated in three orthogonal directions. Seismic responses of the Category I subsystems, equipment, and components are determined and combined in accordance with Sections 3.7.3.6 and 3.7.3.7. The damping ratios used in the dynamic analyses of the structures, subsystems, and equipment/components are shown in Table 3.7-2.

3.7.3.2  Determination of Nu mber of Earthquake Cycles 3.7.3.2.1  Category I Systems and Components Other Than NSSSDuring the design life of the plant (40 years), two earthquakes of OBE magnitude and one SSE are postulated to occur. This was based upon a study of seismic history in the Southern Appalachian Province over a 100-year period. Based on this study, each occurrence is conservatively assumed to have a time duration of 15 seconds of strong excitation.For Class A Category I components, an evaluation of predominant frequencies revealed that the most significant response of components is conservatively considered using an average frequency of 20 Hz. Therefore, the total number of cycles considered for the OBE and SSE are 600 and 300, respectively. The seismic qualification testing of Category I equipment considers the number of events and durations described above in accordance with IEEE 344-1975.ASME Section III Class 1 Piping Analysis - Since the piping in this scope has been reanalyzed in accordance with SRP requirements, the piping analysis has assumed the occurrence of 5 OBEs and 1 SSE. The number of peak stress cycles may be obtained from the synthetic time history used for the analysis (with a minimum duration of 10 seconds), or a minimum of 10 peak stress cycles per event assumed.

3.7.3.2.2  NSSS SystemWhere fatigue analysis of mechanical systems and components is required, Westinghouse specifies in the equipment specification that 20 occurrences of OBE having 20 cycles of maximum response for each occurrence, be analyzed. The fatigue analyses are performed as part of the stress report.

3.7.3.3  Procedure Used for Modeling 3.7.3.3.1  Other Than NSSS 3.7.3.3.1.1  Modeling of Piping Systems for De tailed Rigorous AnalysisThe continuous piping system is modeled as an assemblage of beams. The mass of each beam is lumped at the nodes connected by weightless elastic members, representing the physical properties of each segment. The pipe lengths between mass points are such that the adequate simulation of the dynamic characteristics of the piping system is ensured. All concentrated weights on the piping system such as main SEISMIC DESIGN 3.7-33WATTS BARWBNP-105valves, relief valves, pumps, motors, and effects of support mass on piping system when found to be significant are modeled as lumped masses unless isolated from the system by positive anchorage. The torsional effects of the valve operators and other line-mounted equipment with offset center of gravity with respect to center line of the pipe is included in the analytical model.

3.7.3.3.1.2 Mode ling of EquipmentFor seismic analysis, Seismic Category I equipment is represented by lumped mass systems which consist of discrete masses connected by weightless springs. The criteria used to lump masses are:

(1)The number of modes of a dynamic system is controlled by the number of masses used. The number of masses is chosen so that all significant modes are included. The modes are considered as potentially significant if the corresponding natural frequencies are less than 33 Hz. For modes greater than 33 Hz the rigid response contribution is considered.

(2)Mass is lumped at points where significant concentrated weight and continuous mass are located.

3.7.3.3.1.3 Modeling of HVAC, Conduit, and Cable Tray SubsystemsRuns of HVAC, conduit, and cable tray subsystems (including supports) are modeled by continuous or discrete mass models with the interconnecting elements represented by their effective stiffness properties. Additional lumped masses are applied at or near significant concentrated weights such as from fittings or other in-line or attached commodities. Significant concentrated weights are those which cannot be adequately represented by smearing their effect as part of the overall uniform mass. Mass eccentricities and torsional stiffnesses are considered. Where models are truncated, at least one span and the next support on either side of the contiguous span(s) and support(s) of interest for evaluation are modeled. Alternately, the contiguous span(s) and support(s) of interest are evaluated with one half of the adjacent spans on either side modeled with symmetry boundary conditions such that no artificial stiffening is introduced.A sufficient number of masses (or degrees of freedom) are modeled such that additional masses would not increase the predicted responses by more than 10%. Alternately, the number of masses are modeled to be at least twice as many as the number of modes with frequencies less than 33 Hz. The dynamic analysis considers all modes with significant mass participation such that inclusion of additional modes would not increase the predicted responses by more than 10%. Alternately, the dynamic analysis considers all modes up to 33 Hz and includes an additional check for any missing mass.3.7.3.3.2  Modeling of NSSS SubsystemsThe criteria and procedures used for model ing of NSSS subsystems is given in Section3.7.2.3.

3.7-34SEISMIC DESIGN WATTS BARWBNP-105 3.7.3.4  Basis for Sele ction of Frequencies 3.7.3.4.1 Other Than NSSSThe method used to analyze systems for dynamic loading is the modal response spectrum method.Frequencies of the subsystems are selected such that all significant modes of vibration are included in the analysis. Frequencies of simplified analysis models are determined by solutions of closed form expressions. Frequencies of detailed analysis models are determined by computerized solutions.The subsystem or component model is subjected to loadings in the form of accelerations that represent the seismic environment of its supports. Since the response spectrum employed is representative of the building elevation at the equipment/system location considered, structural amplifications are reflected in the spectra. Therefore, the input acceleration values taken from the building response spectra and utilized as input to the dynamic analysis of the subsystem or component assures the model is loaded in a representative manner and the proper amplifications determined. The subsystem or component was analyzed and designed for the amplified loading.

3.7.3.4.2 NSSS Basis for Sel ection of Forcing FrequenciesThe analysis of equipment subjected to seismic loading involves several basic steps, the first of which is the establishment of the intensity of the seismic loading. Considering that the seismic input originates at the point of support, the response of the equipment and its associated supports based upon the mass and stiffness characteristics of the system, will determine the seismic accelerations which the equipment must withstand.Three ranges of equipment/support behavior which affect the magnitude of the seismic acceleration are possible:

(1)If the equipment is rigid relative to the structure, the maximum acceleration of the equipment mass approaches that of the structure at the point of equipment support. The equipment acceleration value in this case corresponds to the low-period region of the floor response spectra.

(2)If the equipment is very flexible relative to the structure, the internal distortion of the structure is unimportant and the equipment behaves as though supported on the ground.

(3)If the periods of the equipment and supporting structure are nearly equal, resonance occurs and must be taken into account.In addition, an equipment/support system is considered to be rigid if the fundamental natural frequency is greater than 33 Hz.

SEISMIC DESIGN 3.7-35WATTS BARWBNP-1053.7.3.5  Use of Equivalent Static Load Method of Analysis 3.7.3.5.1 Other Than NSSSFor discussion of the equivalent static load method as applied to equipment/components, see Sections 3.7.3.10.1, 3.7.3.16.1, 3.7.3.16.2, and 3.7.3.16.3.For other Category I subsystems, the following discussion applies:

Simplified seismic analysis by the equivalent static load method may be used as an alternative to detailed computer analysis when the subsystem being analyzed is adequately represented by an effective one degree-of-freedom system with multi-mode effects accommodated by the use of a multi-mode factor. A modal participation factor of 1.0 is used for the equivalent static load method. If the subsystem is determined to be rigid (fundamental frequency  > 33 Hz), then the acceleration of the building at the elevation of the subsystem attachment (floor zero period acceleration) is used with a multi-mode factor of 1.0; i.e., the subsystem is evaluated for rigid-body response. When no frequency evaluation of the subsystem is made, the peak acceleration of the applicable floor response spectrum is used multiplied by a multi-mode factor of 1.5 except where a lower factor is justified. When a frequency evaluation is made and the subsystem is determined to be flexible, the highest acceleration at or above the determined frequency is used for evaluation multiplied by a multi-mode factor of 1.5 except where a lower factor is justified. For HVAC, conduit, and cable tray subsystems a multi-mode factor of 1.2 has been justified.

3.7.3.5.2 Use of Equi valent Static Load Method of Analysis for NSSSThe static load equivalent or static analysis method involves the multiplication of the total weight of the equipment or component member by the specified seismic acceleration coefficient, which is established on the basis of the expected dynamic response characteristics of the component. Components which can be adequately characterized as a single-degree-of-freedom system are considered to have a modal participation factor of one. Seismic acceleration coefficients for multi-degree of freedom systems, which may be in the resonance region of the amplified response spectra curves, are increased by 50 percent to account conservatively for the increased modal participation.3.7.3.6  Three Components of Earthquake MotionSeismic responses of Category I subsystems, equipment, and components are analytically computed or simulated by qualification tests for the applicable Set A, B, and C seismic inputs in three orthogonal directions. The Set A, B, and C inputs for original analysis/qualification, evaluation, and new design/modification are described in Section 3.7.2.

3.7-36SEISMIC DESIGN WATTS BARWBNP-105 3.7.3.6.1  Pi ping SubsystemsThe seismic responses of Category I piping subsystems are determined assuming that the three components of the earthquake motion occur simultaneously. The maximum response due to each of the three components of earthquake motion is combined by SRSS of the maximum directional responses caused by each of the three components of earthquake motion.

3.7.3.6.2 HVAC Duct ing, Conduit, and Cable Tray Subsystems The seismic responses of HVAC ducting, cable tray, and conduit subsystems are determined by two dimensional seismic analysis and associated testing of representative duct, cable tray, and conduit spans. Seismic input in each major horizontal direction is applied separately but simultaneously with vertical input.