{{#Wiki_filter:HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 RAI 17: Clarify the distance between the ISFSI and the controlled area boundary and revise the calculation for the dose at the controlled area boundary and the dose rate versus distance, as necessary.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 and viceversa, given the characteristics of the site described by the response spectrum, which has not been provided.

This information is necessary to determine compliance with 10 CFR 72.92, and 72.103(a)(2).

Holtec Response:

The stackup at the UMAX ISFSI pad is the limiting configuration for seismic response analysis, as compared to the stackup at the CTF, because (a) both locations are subject to the same design basis seismic motion and (b) the rocking frequency of the stackup at the UMAX ISFSI pad is less than the rocking frequency of the stackup at the CTF (owing to the longer bolt length associated with the former configuration), which means that the stackup at the UMAX ISFSI pad is subject to higher spectral accelerations and therefore higher demand loads. This is further explained below.

The design basis seismic events for the HISTORE CIS Facility, which includes the HISTORM UMAX ISFSI and the CTF inside the Cask Transfer Building, are defined in Table 4.3.3 of the HISTORE SAR. As discussed in SAR Section 4.3.6, the stackup configuration is a ShortTerm Operation, and therefore it is only required to be analyzed for OBE loading. However, for conservatism the stackup analysis performed in Supplement 5 to HI2177585, and also discussed in SAR Section 5.4.1.4, considers the Design Extended Condition Earthquake (DECE) as input. Per SAR Table 4.3.3, the DECE is defined as a RG 1.60 earthquake having a ZPA value of 0.25g in all three orthogonal directions (2 horizontal and 1 vertical). In summary, there is no difference between the two stackup locations with respect to the design basis seismic motion, and a bounding earthquake (DECE) is used as input to the seismic analysis for stackup.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 The density of the shield gate top plate is intentionally increased to account for the weight of miscellaneous shield gate components (e.g., the hydraulic actuating system) not explicitly modeled in the stackup analysis LSDYNA model in Supplement 5 of HI2177585. Since those miscellaneous components are all located below the shield gate top plate, including their weight at the top plate conservatively increases the overall center of gravity of the stackup for the seismic analysis. Therefore, it is not required to update the analyses as the current ones remain conservatively bounding.

RAI 53: Justify the claim that the weight used to model the HITRAC CS in LSDYNA is conservative with respect to seismic demands. Include a discussion of when the HITRAC CS is fully loaded versus partially loaded. Update, as needed, any seismic calculations related to the simulation of the HITRAC CS using LSDYNA.

Page 117 of Holtec Report No. HI2177585, Structural Calculation Package for HISTORE CIS Facility claims that a weight of 380,000 lbs for the HITRAC CS is conservative with respect to seismic analysis.

However, this claim is not justified given that a higher weight may not necessarily indicate a more severe seismic response depending on the response spectrum that typifies the site, which has not been provided. That is, a partially loaded MPC may produce higher demands on certain components of the HI TRAC CS depending on the response spectrum of the site and dynamic behavior of the HITRAC CS.

This information is necessary to determine compliance with 10 CFR 72.92 and 72.122(b)(2)(i).

Holtec Response:

Designed to have a very stiff structure, the HITRAC CS cask itself will behave like a rigid body (i.e., with a natural frequency above 33 Hz.) in a seismic event. However, the smallest natural frequency of the anchored HITRAC CS stackup system is controlled by the relatively flexible anchoring bolts. Using the bounding cask weight in the seismic analysis can capture the lowerbound natural frequency of the system. Because the seismic response of the RG. 1.60 earthquake reduces with the increase of frequency after 2.5 Hz, it is conservative to use the upper bound cask weight in the seismic analysis of the HITRAC CS stackup system whose minimum natural frequency is shown in the following calculation to be 19.0 Hz.

A partially loaded MPC would increase the natural frequency of the stackup system and therefore reduce the seismic response of the stackup. In summary, using the bounding weight is conservative. Unless noted, all the input data used in the following natural frequency calculation is taken from Holtec Report No. HI2177585R0 and Holtec Drawing No. 10868R0.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 PROPRIETARY INFORMATION WITHHELD PER 10CFR2.390

RAI 54: Define the duration of a work shift as it pertains to seismic qualification.

Section 4.3.6 of the HISTORE SAR states, in part:

This information is necessary to determine compliance with 10 CFR 72.122(b)(2)(i).

Holtec Response:

Section 5.5.2 of the SAR describes the scenario where the vertical cask transporter and related equipment is carrying the HITRAC CS under seismic loading. However, it is unclear how the same system responds to a lightning strike or tornado while traveling to the ventilated vertical module and performing downloading operations. Provide justification and/or supplemental calculations and update the SAR, as necessary, showing that the transported canister will not be breached by a missile strike or a tip over of the vertical cask transporter. If the tip over scenario is credible, the structural, shielding, thermal, and confinement analyses should be updated to consider the damage from that event.

This information is necessary to determine compliance with 10 CFR 72.92 and 72.106.

The calculations performed in Supplement No. 2 to HI2177585 demonstrate that a freestanding HI TRAC CS, completely independent from the vertical cask transporter (VCT), will not tipover as a result of the design basis tornado wind and missile impact. The calculations also show that the HITRAC CS adequately protects the MPC against penetrant missiles due to a tornado event.

When the HITRAC CS is being carried by the VCT, the aspect ratio (i.e., ratio of c.g. height to minimum base dimension) decreases significantly, which enhances stability. The physical presence of the VCT also serves as an additional barrier against missile impact on the HITRAC CS. In summary, the tornado wind and missile evaluations for the freestanding HITRAC CS, which are documented in Supplement No. 2 to HI2177585, are bounding for the VCT carrying a loaded HITRAC CS.

Regarding a lightning strike, the HITRAC CS contains over 75,000 lb of highly conductive carbon steel with over 600 square feet of external surface area. Such a large surface area and metal mass is adequate

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 impact limiters, loaded MPC, and miscellaneous rigging, and determines that the lifting device has a minimum safety factor of 1.283 (or 28.3% margin) over and above NURE0612 and ANSI N14.6 requirements. This means that, although it is not permissible from a design and licensing standpoint, the horizontal lift beam is capable of carrying significantly more weight (i.e., an additional 100 kips) without exceeding its design stress limits.

RAI 58: Provide a basis for the assumption that the vertical cask transporter (VCT) is essentially a rigid body when transporting a loaded HITRAC CS and how the use of the peak ground acceleration (PGA) alone, for calculations involving tipping and sliding, is conservative. Confirm the rigid body nature of the system, incorporate the response spectrum of the site based on the actual dynamic behavior of the system, and update the calculations used to determine tipping and sliding. 1 to Report No. HI2177585, Rev. 0, details the calculations used to determine the amount of sliding and tipping that the loaded VCT may experience. The methodology used from ASCE Standard 4305 assumes that while carrying the HITRAC CS, the VCT is a rigid body. Two concerns related to the assumption that the system is a rigid body are:

: 1. The fundamental period of the VCT has not been provided. When empty, the VCT weighs approximately 210,000 lbs and weighs an additional 375,000 lbs when carrying a fully loaded HI TRAC CS. The loaded VCT is expected to have a fundamental period that is 67% larger relative to the unloaded VCT, which could allow the fully loaded VCT to experience larger seismic demands.

The demand is unclear as the response spectrum of the site has not been provided.

: 2. The VCT, while carrying the HITRAC CS, appears to have at least 2 dominant periods given that the MPC can sway independently from VCT during an earthquake. This would violate the rigid body assumption of ASCE Standard 4305.

This information is necessary to determine compliance with 10 CFR 72.122(b)(2)(i).

The design basis ground response spectra for the site are specified in SAR Table 4.3.3. The OBE, DBE, and DECE spectra are all RG 1.60 spectra with ZPA values of 0.10g, 0.15g, and 0.25g, respectively. Per Subsection 4.3.6 of the SAR, OBE applies to the ShortTerm Operations required to load the arriving canisters at HISTORE, including transit of the HITRAC CS using the VCT. Supplement 6 to HI2177585,

The cask transfer building (CTB) has been classified as not important to safety. Its collapse onto the HI TRAC CS transfer cask and HISTAR 190 transportation package has been postulated as an accident scenario and detailed in Report No. HI2177585 R0. In the structural calculation package, it is assumed that a W40 x 324 beam from the building strikes either the HISTAR 190 package or the HITRAC CS transfer cask, which was simulated using LSDYNA. However, the application does not provide detailed drawings or details of the CTB, so it is not possible to confirm if the loading that the HITRAC CS transfer cask or HISTAR 190 transportation package would experience as a result of building collapse is bounding. Its possible that a smaller object, such as a pipe driven by heavy load behind it or some other object, may be a more damaging scenario than the collapse of a beam onto the system.

Holtec Report No. HI2177585 R0, Structural Calculation Package, provides calculated estimates of fatigue life for the HITRAC CS and associated lifting ancillaries, referred to as components for the purposes of this RAI. The report estimates the number of fatigue cycles a component of the HITRAC CS and associated lifting ancillaries may observe based on the maximum bounding allowable stress the component may experience during its lifetime. While fatigue cycles based on maximum stress of this nature are useful, they dont capture the complete fatigue life of the component since low stress, high cycles observed during handling and movement by the VCT have been ignored. In addition, calculated fatigue cycles have not been linked to a periodic inspection, maintenance, repair, or replacement of the VCT, HITRAC CS, lifting ancillaries etc. Fatigue life should relate to the number of canister deployments or some other measure, where a canister deployment is defined for purposes of

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 discussion as the movement of a canister upon initial receipt from rail car to its ventilated vertical module (VVM) location, or from the VVM back to the rail car.

For a given canister deployment, the HITRAC CS, VCT, and associated lifting ancillaries will observe a combination of high stress and low stress cycles, which should be combined to calculate the fatigue life of the component via a cumulative damage model such as Miners rule. High stress cycles are expected during lifting operations while low stress cycles are expected when being handled by the VCT as it travels from the rail car to the VVM. The number of low stress cycles and stress itself will depend on the vibrational characteristics of the VCT while carrying the HITRAC CS, the weight of the canister being moved, the distance the HITRAC CS is carried (which depends on the VVM location), etc.

This information is necessary to determine compliance with 10 CFR 72.122(b).

Holtec Response:

Supplement 10 to HI2177585 will be revised to address low stress cycles for the various lifting equipment and correlate the resulting fatigue life to a number of canister deployments.

515: Provide an explanation and justification for the excessive amounts of hour glassing energy observed during seismic simulations during stackup analysis. Update the model and any results in the HISTORE SAR, as necessary.

Comparison of hour glassing energy to internal energy for the Design Extend Condition Earthquake (DECE) seismic simulation of the CS Stackup analysis at the CTF and UMAX (via LSDYNA) reaches 16%

during the simulation, indicating that the model is potentially exhibiting unrealistic behavior and likely leading to erroneous stress and strain output of the analyzed components. Similar behavior was also noted for the Safe Shutdown Earthquake (SSE) scenario.

This information is necessary to determine compliance with 10 CFR 72.24(c)(2) and 72.122(b)

Holtec Response:

The time histories of the total internal energy and the total hourglass energy of the DECE simulation are shown in the following plot (Figure 5151) which is reproduced from the LSDYNA analysis supporting Supplement 5 of HI2177585. Although the ratio of the hourglass energy to the internal energy is relatively large over a small duration (i.e., between 8.0 and 9.0 seconds), the magnitudes of the two types of energies are very small relative to the internal energies at other times during the simulation. As demonstrated in Figure 5152, where the total kinetic energy (i.e., seismic energy) of the stackup is plotted along with the total internal energy and the total hourglass energy, the hourglass energy is shown to be extremely small and can be considered as noise when compared with the kinetic energy of the stack up. The same behavior is observed in the SSE simulation. In conclusion, there is no need to update the analyses.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 PROPRIETARY INFORMATION WITHHELD PER 10CFR2.390

Holtec Response:

: 1) The stress analysis of the HITRAC CS lifting trunnions is based on the strength properties of SA 564 630 H100, which is the weaker of the two material options (i.e., SB637 N07718 and SA564 630 H1100) specified on Licensing Drawing 10868. From Supplement 1 to HI2177585, SA564 630 H100 has yield and ultimate strength values of 100 ksi and 138 ksi, respectively, at 350°F.

SB637 N07718 has yield and ultimate strength values of 139.5 ksi and 172 ksi, respectively, at 350°F per Table 3.3.4 of the HISTORM FW FSAR [1.3.7].

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 onsite translocation (e.g., lifting and handling of the HITRAC CS). In addition, the maximum calculated temperature of the HITRAC Concrete, during normal onsite transfer, is 271°F per Table A.7.1 of HI2177553. This validates the use of 350°F as a bounding metal temperature for the HITRAC CS lifting trunnions. The higher temperatures referenced in RAI 519, namely 572°F and 642°F, are associated with accident conditions, not shortterm operations (i.e., lifting and handling).

: 3) The HITRAC CS lift links are analyzed in Supplement 12 to HI2177585 based a bounding metal temperature of 300°F. This is conservative since it exceeds the calculated temperature (200°F) of the HITRAC outer shell per Table A.7.1 of HI2177553, and it matches the permissible temperature limit for the HITRAC CS concrete for shortterm operations.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 RAI 521: Provide stressstrain curves based on material testing for SA516 Gr. 70 at 400 degrees F.

Supplement 5 to Report No. HI2177585 provides stressstrain curves with guessed material properties (n and k coefficients) for SA516 Gr. 70 at 400 deg. F, which is used in seismic simulations of the HITRAC CS. Material properties used in ITS equipment should be well defined and based on physical testing as seismic evaluations of ITS equipment cannot be verified otherwise. Seismic evaluations are only as good as the material properties that go into them, and the seismic response may be very different than observed when material properties are assumed arbitrarily.

This information is necessary to determine compliance with 10 CFR 72.24(c)(3) and 72.122(b)(2)(i)

Holtec Response:

The truestresstruestrain curve of material SA516 Gr. 70 is derived using Mathcad in Report HI2177585.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 Calculations have been provided for the tilt frame and saddle, however, margins of safety that describe the buckling of web plates and beams (BOM 2, 7, 12) of the tilt frame and saddle have not been provided. Update the calculations as necessary.

This information is needed to ensure compliance with 10 CFR 72.122(b).

Holtec Response:

The structural calculation of the tilt frame and saddle, which is performed in Supplement 13 to Report HI 2177585, appropriately considers the buckling of the Wbeam (item 2 of Holtec Drawing 10899) and the beam side plate (item 7 of Holtec Drawing 10899). The Wbeam and the beam side plate of the tilt frame, hereafter referred to as boxed beam are evaluated for buckling (a.k.a compressive) loads in combination with the bending loads during the upending/downending operations. The combined compression and bending evaluation of the boxed beam is performed per the guidance in ASME NF Subsection NF3322.1(c) and (e). The limiting margin of safety against compression and bending for the boxed beam is 1.073 as listed on page 1325 of Supplement 13 to Report HI2177585.

The saddle web plates (item 12 of Holtec Drawing 10899) are 1 inch thick plates, which are well supported by the gusset plates (item 16, 17, and 21 of Holtec Drawing 10899) on either side. These gusset plates are placed at equal intervals over the full width of the web plates and are welded to the web plates over the entire height of the gusset plates. As a result, the buckling of the saddle web plate is not a credible failure mode and therefore has not been explicitly evaluated. Additionally, the vonMises stress plot for the saddle (shown in Figure 13.33 of Supplement 13 to Report HI2177585) also confirms that the stresses on the saddle web plates are negligible, and the saddle assembly is primarily subjected to bearing loads.

Notwithstanding the above, a critical buckling load for the saddle web plate is conservatively calculated below. The margin of safety against the conservatively estimated critical buckling load for the saddle web plates is greater than 2.0 as shown below.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 The orientation of the slings (cable pitch) can greatly influence the buckling load on these members and should be placed on the licensing drawings or technical specifications to avoid overloading these members and should correspond to what has been provided in the calculations.

Supplement 13 to Holtec Report No. HI2177585R0 states that seismic analysis of these components is not performed because they are seismic exempt as per the document Licensing report on the HISTORE CIS Facility, HI2167374, Revision 0 (i.e., the HISTORE SAR). The SAR states, in part, that: [f]ollowing the universally practiced lift and set rule at nuclear power plants, transient activities such as upending of a cask, attaching of slings or installation of fasteners, are treated as transient activities that are not subject to a seismic qualification. For clarity of application, any activity that spans less than a work shift is deemed to be seismicexempt.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 basis, and therefore Holtec agrees that the possibility of an earthquake occurring during a repeated lifting operation cannot be ruled out.

That being said, the HISTORE CIS Facility is a low intensity earthquake site, which means that the load increase associated with an earthquake event is offset by the increased design factors for the lifting equipment and/or the increase in allowable stress that is associated with an accident level event. The seismic qualification of the Transport Cask Horizontal Lift Beam and its sling attachments is discussed specifically in the response to RAI 523. The same general rationale applies to the HISTAR 190 Lift Yoke, the HITRAC CS Lift Yoke, the MPC Lift Attachment, and the HITRAC CS Lift Links, as they are all designed and analyzed as ANSI N14.6 special lifting devices with minimum safety factors of 6 and 10 against the material yield strength and the ultimate tensile strength, respectively. The HISTAR 190 Tilt Frame and Saddle are further discussed below.

Per Subsection 4.3.6 of the SAR, the applicable earthquake event for ShortTerm Operations, which includes all lifting and handling operations from the time the transport package is received at site until the canister is placed in a HISTORM VVM for interim storage, is the Operating Basis Earthquake (OBE).

Per SAR Table 4.3.4, the OBE event is defined as a 2% damped RG 1.60 earthquake with a ZPA value of 0.10g in three orthogonal directions. Accordingly, the peak acceleration associated with the OBE vertical response spectrum is 0.405g, which means that the demand load on the Tilt Frame and Saddle would increase by no more than 40.5% under OBE conditions. On the other hand, the percentage increase in allowable stresses between ASME NF Level A (normal) and ASME NF Level B (offnormal) is 33% per Table NF3251.21. These two percentage factors can be used to make a conservative estimate of the minimum safety factor for the Tilt Frame and Saddle under OBE conditions.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 Licensing Drawing 10900 depicts two strong back plates (BOM 1) which act in unison when performing lifting operations. During lifting operations, these two plates will be subjected to bending moments with unbraced compression flanges, which could undergo lateral torsional buckling. It is noted that thin rods (spacers) that link these two plates are depicted on the licensing drawings, but their ability to brace these two components is unknown, and their dimensions and material properties have not been provided. An evaluation of lateral torsional buckling for the lift yoke was not provided. The calculations and licensing drawings should be updated, as necessary.

Component                      Temperature, °F        LongTerm Limit from          ShortTerm HISTORM UMAX          Operations Limit from FSAR, °F            HISTORE SAR, °F Fuel Cladding                        669                        752                      -

These results and comparisons to limits show that there is no limit to time the MPC may remain in the HI TRAC CS while the UMAX heat removal system is restored to operable status.

RAI 67: Update the draft Design Feature Technical Specification to indicate the minimum HISTORM UMAX module pitch justified by the thermal analysis.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 There is no clear basis provided in the SAR for the 91 deg F temperature difference between the average VVM air outlet duct temperature and the ISFSI ambient temperature mentioned in the proposed Technical Specification SR 3.1.2. In addition, a LCO criteria was not specified in the proposed Technical Specification Basis SR 3.1.2 in Chapter 16 of the HISTORE SAR.

This information is needed to determine compliance with 10 CFR 72.26 and 72.122(b).

Currently, proposed Technical Specification LCO 3.1.1 states that the SFSC Heat Removal System is operable when 50% or more of the inlet vent duct areas are unblocked and available for flow. However, Section 4.6.1.2 of the HISTORM UMAX FSAR, which is incorporated by reference, only indicated the results for thermal performance when the HISTORM UMAX air inlet vents were 50% blocked (no mention of outlet vents).

This information is needed to determine compliance with 10 CFR 72.26 and 72.122(b).

Holtec Response:

The storage module deployed at HISTORE is the UMAX, which has already been reviewed and certified by the NRC on Docket 721040. As such, the accident 100% vent blockage scenario for the HISTORE is intended to be the same as that for the UMAX, namely a 100% blockage of the inlet vents. Any HISTORE SAR text referring to blockage of the outlet vents is, therefore, inadvertent. All HISTORE SAR text concerning the vent blockage accident condition, including the description of proposed Technical Specification LCO 3.1.1, has been clarified to state that the outlet vent area is at least 50% unblocked and available for flow.

There are two primary reasons why blockage of the storage module outlet vents is not considered a credible event for the HISTORE. First, ventilation air exiting the outlet vents is incapable of drawing items into the vents. Airflow toward an inlet vent could entrain lightweight materials like plastic sheeting or fallen leaves, drawing it up against and holding it against the vent screen. But airflow away from an outlet vent would tend to push such items away. Second, as described in Section 2.3.1 of the HISTORE SAR, snowfall significant enough to block the outlet vents is not credible. The bottom edge of the outlet vents is over 12 above the top of the lid horizontal surface that could accumulate snowfall (shown on Sheet 3 of Holtec Drawing 10875 in HISTORE SAR Section 1.5). This exceeds the largest ever recorded snowfall for the site, 10 inches in February 1956, described in the SAR Subsection 2.3.1. Moreover, heated air exiting the outlet vents would melt snow as it falls, further reducing accumulation.

The amount of heat removed from the MPC external surfaces by natural circulation of air is reduced to less than 7% of that under normal conditions (i.e. when inlet and outlet vents completely unblocked). Therefore, in an unlikely event of complete blockage of both inlet and outlet vents, that small additional heat removal capability by air through outlet vents is also lost.

This will result in a small temperature rise compared to the large available temperature margins (greater than 80°C) established from the transient study of complete inlet vents blockage.

Due to the fact that the cooling air enters the cask below the MPC and exits above the MPC in both the HISTORM FW and the UMAX, and due to the UMAX also having significant margin (for example, greater than 50°C for the fuel cladding), it is reasonable to conclude that the margin is sufficient to accommodate the temperature rise due to a coincident 50% outlet duct blockage.

RAI 612: Provide the maximum ambient temperature limit for conducting short term operations in the Technical Specifications.

Proposed Technical Specification 4.2.4 indicates that operations should not be performed if ambient temperatures are below 0 deg F. There was no corresponding maximum temperature limit for conducting short term operations and no transfer analyses, for example, at accidentlevel ambient temperatures. The maximum ambient temperature analyzed for short term operations was reported as 91 deg F in Table 6.4.1 of the HISTORE SAR and Table 1.1 of Holtec Report No. HI2177553, Thermal Analysis of HITRAC CS Transfer Cask. However, the HISTORE SAR, including in Table 2.7.1, indicates that ambient temperatures could be above that value (e.g., 108+ deg F).

RAI 613: Update the proposed Technical Specification Design Feature 4.2.1 to indicate that the design of the HISTORM UMAX modules are limited to Type SL and Type XL of the UMAX Version C module.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 Holtec Report No. HI2177591, Thermal Evaluation of HISTORM UMAX at HISTORE CIS Facility, states that MPCs of certain heights are to be installed in Type SL or Type XL UMAX Version C modules with storage cavity depths made at two discrete dimensions. The thermal analyses and performance of the system are based on these design aspects, but they were not included in the Technical Specifications.

This information is needed to determine compliance with 10 CFR 72.26 and 72.122(b).

Holtec Response:

Proposed Technical Specifications Section 4.2.1 has been updated to indicate that the design of the HI STORM UMAX modules are limited to Type SL and Type XL of the UMAX module.

RAI 614: Provide the Holtec Engineering Change Order (ECO) 502124, Revision 0, and its corresponding 10 CFR 72.48 evaluation.

Section 2 of Holtec Report No. HI2177591, Thermal Evaluation of HISTORM UMAX at HISTORE CIS Facility, states that the thermal model is based on ECO 502124, but this was not provided in the application.

This information is needed to determine compliance with 10 CFR 72.24(d) and 72.128(a).

The ECO referenced was fully incorporated into the HISTORM UMAX FSAR Revision 4, and all subsequent revisions, which have been submitted on the HISTORM UMAX docket.

Section 2 of Holtec Report No. HI2177553, Thermal Analysis of HITRAC CS Transfer Cask, broadly states that the analysis principles and methodology for the calculations are adopted from the HISTORM FW FSAR and HISTORM UMAX FSAR. The principles and methodology relevant to the HITRAC CS should be described or specific sections/paragraphs of the HISTORM FW FSAR and HISTORM UMAX FSAR should be referenced for staff to evaluate the thermal analyses of the HITRAC CS.

The thermal analyses principles and detailed methodology adopted for HITRAC CS are described in Section A.2 and Section B.2 of Holtec Report HI2177553 for normal and accident conditions respectively.

RAI 616: Provide the mass and energy residuals, mass and energy balances, DO balances, and justification of grid convergence for the thermal analyses mentioned in Section 6 of the HISTORE SAR and those provided in Holtec Report No. HI2177553, Thermal Analysis of HITRAC CS Transfer Cask;

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 Holtec Report No. HI2177591, Thermal Evaluations of HISTORM UMAX at HISTORE CIS Facility; and Holtec Report No. HI2177597, HISTORE CTF Thermal Evaluation.

The abovementioned numerical criteria, which are part of computational best practices (e.g. NUREG 2152) are needed to confirm that the results provided in the referenced thermal analyses are relevant to the review.

This information is needed to determine compliance with 10 CFR 72.24(d) and 72.128(a).

Holtec Response:

To address the regulators comment, numerical residuals, energy balance and mass balances are now included in the respective calculations packages to demonstrate numerical convergence of the results. It is verified that the energy and mass balances are essentially 100% and that the peak cladding temperature and numerical residuals have stabilized. This is consistent with the approach adopted in other dry storage license applications such as HISTORM UMAX FSAR (USNRC Docket No. 721040) and the HISTAR 190 SAR (USNRC Docket No. 719373).

As an example, the numerical residuals from the normal storage condition evaluations of HISTORM UMAX documented in HI2177591 are shown below. The numerical residuals for HITRAC CS and HISTAR in CTF evaluations are added to HI2177553 and HI2177597 respectively.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 Holtec Response:

The airflow pathway within the shield gate is shown in the following regions of the HITRAC CS Licensing Drawing (Holtec Drawing 10868, Revision 0):

PROPRIETARY INFORMATION WITHHELD PER 10CFR2.390

                                                                                                ]

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061

                                                                                                ]

The above details in the licensing drawing 10868 provide the necessary geometric information and dimensions for the thermal model. To provide further clarity to the reviewer, additional figures showing the as modelled airflow paths through the HITRAC CS shield gate and respective computed path lines are added in the revised thermal report (HI2177553). The design dimensions and modelled dimensions are also tabulated in Appendix A of the revised report.

While, the HITRAC CS is placed above the HISTAR 190 cask in the CTF, the shield gates are in the open position, allowing direct flow path through the HITRAC cavity as shown in Figure 6.4.3 of the HISTORE FSAR and is reproduced below. Since the shield gates are in fully open position, they do not have any impact on the thermal evaluations of HISTAR 190 in CTF presented in HI2177597.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 a) the basis for only a 25% penalty on the heat transfer coefficient, recognizing that a typical buoyant flow pattern around a vertical cylinder would be disturbed by a collapsed structure; b) the basis of certain radiation heat transfer parameters, such as the reported 30% penalty of surface emissivity, the external ambient temperature from a locally close structure (used for radiation heat transfer calculations), view factor, solar flux on the building; c) confirmation that the shield gate inlets are the only air inlet to the HITRAC CS ventilated flow and that those are 100% blocked; d) the basis for 10% of the exit air area remains unblocked and clarify the exit areas (HITRAC CS, CTF pipe vents, CTF cavity top) of HITRAC CS and CTF (refer to HISTORE SAR Figure 6.4.3);

e) explanation of how the 10% exit area remaining unblocked, whereas page B7 of HI2177553 states that 100% of the top opening of the HITRAC CS cavity is assumed to be blocked in the thermal model; f) the justification for the assumption (Holtec Report No. HI2177597) that excluding the HI TRAC CS from being placed in the stackup position is bounding, considering that Section 6.1 of the HISTORE SAR states that the limiting thermal condition occurs when the canister is loaded in the transfer cask and its shield gate is closed.

This information is needed to determine compliance with 10 CFR 72.24(d) and 72.128(a).

Holtec Response:

Note, that the CTB design has been revised to be a hardened concrete structure, and due to its security related functions, building collapse is no longer credible. However, for completeness, the response to the reviewers question is provided below.

Thermal evaluation of HITRAC CS under CTB collapse accident is evaluated with certain reasonable assumptions as explained below:

PROPRIETARY INFORMATION WITHHELD PER 10CFR2.390

RAI 620: Clarify whether Equation B.2.1 (Section B.2.1.2 of Holtec Report No. HI2177553, Thermal Analysis of HITRAC CS Transfer Cask) is meant to provide the temperature rise due to the solid phase fire or the total temperature rise. In addition, provide the temperature rise and thermal load due to the solid phase fire and the temperature rise and thermal load due to the liquid phase fire and explain how the T was applied to the model to determine the values reported in Table B.6.1.1.

The text preceding Equation B.2.1 states that the equation is to provide the temperature rise due to the solid phase fire; however, the equation uses the subscript total, rather than solid, which is then used in the subsequent terminology section (possibly there is a typographical error in the equation). Based on the above, the staff does not understand the intent of the equation as written and, therefore, how its results factor in the values reported in Table B.6.1.1.

Holtec Response:

There is a typographical error in Section B.2.1.2 of Holtec report HI2177553. The temperature rise (T) computed here is the total temperature rise due to liquid and solid phase fires combined. The computed T is added to the initial condition to obtain the maximum temperatures during postfire cool down. This is corrected in the revised thermal report.

The thermal load due to the solid phase and liquid phase fires combined is added in Appendix B of the report. The total temperature rise ratio (Ttotal/Tliquid) is also presented in Table B.2.1. Since this ratio is close to unity (1.0048), it is concluded that the additional temperature rise due to heat flux contribution from the solid phase fire is negligible, which is also stated in Section B.6.1.1 of the report.

The NRC staff is correct that the maximum local temperature of the HITRAC CS concrete exceeds the revised accident temperature limit of 572oF under the hypothetical CTB collapse accident. However, it must be noted that portion of the cask concrete that exceeds this limit is accounted for by using reduced concrete density (See Table 7.3.1 of the HISTORE SAR) in shielding evaluations (Holtec Report HI 2177599). Consistent with the UST criteria, the amount of concrete that exceeds 554oF1 under this accident is added to Appendix B of the revised Thermal Report HI2177553.

HI2177597, HISTORE CTF Thermal Evaluation; Holtec Report No. HI2177553, Thermal Analysis of HITRAC CS Transfer Cask; and Holtec Report No. HI2177591, Thermal Evaluations of HISTORM UMAX at HISTORE CIS Facility, are based on the bounding content to be stored at the HISTORE CISF.

1 The UST criteria set forth in Chapter 6 of HISTORE SAR suggests a minimum of 10oC margintolimit.

The heat load patterns 1 through 6 and the bounding pattern (pattern 1) provided in Table 4.1.1 of the HISTORE SAR is the same as that provided in Table 7.C.7 of the HISTAR 190 SAR. Therefore, the bounding pattern established in the HISTAR 190 SAR is adopted for all the evaluations presented in Chapter 6 of the HISTORE SAR and the supporting calculation packages listed above.

This information is needed to determine compliance with 10 CFR 72.24(d) and 72.128(a).

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 To address the NRC staffs comment, the pedestal design is now presented in the drawing 10895.

The thermal evaluations in Report HI2177597 models the pedestal as a solid cylinder with an understated thermal conductivity. The pedestal design in drawing 10895, has a higher metal volume fraction and therefore higher effective thermal conductivity than that adopted in evaluations presented in report HI 2177595. The evaluations also conservatively neglect radiative heat transfer between the pedestal and the ground, as well as natural convection in the gas spaces within the pedestal shell.

RAI 624: Clarify that the maximum pressures for the short term CTF normal operation (e.g., Table 6.3 of Holtec Report No. HISTORE CTF Thermal Evaluation) and the CTB collapse accident scenario are based on having the maximum initial backfill pressure for the pressure range reported in Section 2.0 of HI 2177597, Methodology and Assumptions.

The calculation package states that the minimum backfill pressure is used in the thermal analyses to understate the thermosiphon effect within the MPC. However, the determination of maximum pressure, which should be reported, is based on the maximum backfill pressure for normal, offnormal, and accident conditions.

This information is needed to determine compliance with 10 CFR 72.24(d) and 72.128(a).

Holtec Response:

Yes, the maximum initial helium backfill pressure values are used in computing the MPC cavity pressure under all scenarios presented in the report. This has also been stated in Section 6.3 of report HI2177597.

RAI 625: Confirm that the component temperatures in the HISTORE SAR and Holtec Report No. HI 2177597, HISTORE CTF Thermal Evaluation; Holtec Report No. HI2177553, Thermal Analysis of HI TRAC CS Transfer Cask; and Holtec Report No. HI2177591, Thermal Evaluations of HISTORM UMAX at HISTORE CIS Facility, satisfy the unconditionally safe threshold (UST) after considering the effects due to modeling uncertainties (e.g., grid convergence uncertainty).

The acceptability of component temperatures should be reviewed considering that the HITRAC CS concrete after the CTB collapse accident scenario appears to indicate that the 640 deg F temperature may not satisfy the unconditionally safe threshold (UST) defined in Section 6.0 of the HISTORE SAR, which did not address the effects due to grid convergence uncertainty.

This information is needed to determine compliance with 10 CFR 72.24(d) and 72.128(a).

Holtec Response:

The computational grids adopted for the thermal evaluations presented in Holtec Reports HI2177553, HI2177591 and HI2177597 are consistent with the converged mesh established in past thermal evaluations.

HI2177553 (HITRAC CS): The computational mesh for MPC37 is exactly that adopted for the licensing basis calculations performed in HISTORM UMAX FSAR (Docket No. 721040). The computational mesh

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 density adopted for the HITRAC geometry, particularly in the annular gap is similar to that adopted in the NRC approved licensing basis evaluations performed for HISTORM UMAX under Docket No. 721040. The grid convergence index for this grid is therefore expected to be in the same order as that for the HISTORM UMAX thermal evaluations which is ~1.07%. Since there are robust margins (>10oC) for all components, it can be concluded to satisfy the unconditionally safe threshold. As outlined in RAI 621 and addressed in the revised thermal report HI2177553, the portion of HITRAC concrete that exceed the temperature limit already considers the UST criteria and adopts a 10oC penalty.

The maximum temperature limit of the HISTAR 190 Oring under normal and accident conditions is provided in Table 4.4.4 of the HISTORE CISF FSAR. This Oring is rated to a minimum temperature of 40oF since it is also used in transport condition (see Chapter 3 of USNRC Docket No. 719373).Under the hypothetical CTB collapse evaluation, the HISTAR cavity is assumed to be filled with nitrogen/air i.e. no credit is taken for the presence of helium within the HISTAR cavity. The sealing functionality of the HI STAR lid is not relied upon under this scenario and therefore the Oring temperature is not reported. To address reviewers specific request on the Oring temperatures, the temperature of Oring under this accident has been postprocessed and found to be 243oC.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 RAI 627: Clarify in Chapter 3 of the HISTORE SAR that the HISTAR 190 is the only transportation package that is used to ship content to the HISTORE CISF.

Chapter 3 (Page 33) of the HISTORE SAR states that transportation packages other than the HISTAR 190 would be used to transport content. However, the thermal analyses that are provided to demonstrate compliance with site specific parameters and design features are based only on the HI STAR 190 package.

This information is needed to determine compliance with 10 CFR 72.24(d) and 72.128(a).

The operations procedure mentions the need to perform a corrective action associated with blockage of air flow, but a transient HITRAC thermal analysis with blocked airflow and a time limit to perform the corrective action were neither listed nor provided.

This information is needed to determine compliance with 10 CFR 72.24(d) and 72.128(a).

First, it should be stated that the closure of the shield gates and removal of the HITRAC is not a malfunction but is a planned step. This condition is bounded by the burial under debris event in Paragraph 4.6.2.3 of Revision 3 of the HISTORM UMAX FSAR, which provides an equation for determining an allowable duration. That equation is used to with the maximum allowable decay heat and the minimum allowable component rise to the shortterm operations temperature limit to determine the allowable duration for the HITRAC to be removed from atop the UMAX.

The initial condition for this determination is the steadystate MPC in HITRAC condition. The maximum decay heat is 32.15 kW from Table 4.1.2 of the HISTORE SAR. The minimum temperature rise is for the fuel cladding, which is the difference between the calculated value from HISTORE SAR Table 6.4.6 and the limit of 390°C (400°C from ISG11 Rev. 3 minus 10°C per SAR Section 6.0), or 734°F - 669°F = 65°F or 36°C. The UMAX weight and specific heat capacity are from Table 4.6.8 of the HISTORM UMAX FSAR. For these inputs the allowable blockage time is:

46000        419              36 21582        6.0 32150 If the HITRAC cannot be removed from atop the UMAX within this time, this would be considered an accident condition and would be bounded by the 100% vent blockage event. Paragraph 6.5.2.5 of the HI STORE SAR incorporates Paragraph 4.6.2.3 of the HISTORM UMAX FSAR for this accident condition.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 This discussion has been added to Section 6.4 of the HISTORE SAR.

However, descriptions of those changes were not provided such that assessments by technical disciplines could not be performed.

: 2. UMAX cavity depth is fixed to two discrete values and not variable as permitted in the design licensed in USNRC Docket No. 721040. As also has been described in Section 6.4.1, thermal performance of UMAX Version C is either the same or improved.

Table 6.0.1 of HISTORE SAR indicates that Paragraph 4.6.2.3 of the HISTORM UMAX FSAR provides information that applies for the scenario of 100% blockage of air inlets and outlet. However, Paragraph 4.6.2.3 discusses the scenario of 100% blockage of air inlets only.

See response to RAI611 above.

This information is needed to determine compliance with 10 CFR 72.24(d) and 72.128(a).

Holtec Response:

Section average temperature is defined as the lineal average temperature through the thickness of a component. Maximum section average temperature, therefore, is the largest section average temperature of all sections through a component. Bulk average temperature is the spatially integrated average of temperatures of an entire component volume. These definitions have been added to the glossary of terms in the beginning of the HISTORE SAR.

There was no mention of thermal stresses in Chapter 5 of the HISTORE SAR, even though many of the SSCs are new (e.g., HITRAC CS, CTF) or have new designs (e.g., module). Thermal stresses are expected to impact safety margins already calculated (e.g., seismic and tornadic wind effects) since they exist in the analysis of the SSCs a priori. That is, they should be considered concurrently with both seismic and tornadic effects. Update any relevant calculations as necessary.

The welded steel portions of the HISTORM UMAX VVM, the HITRAC CS, and the CTF are all designed to meet the stress limits given in ASME Section III, Subsection NF for Class 3 supports. As such, thermal stresses within the support need not be evaluated, as explicitly stated in note (5) to Table NF3251.21.

The structural design criteria for the HITRAC CS and the CTF are summarized in Paragraphs 4.3.3.1 and 4.3.5.1 of the HISTORE SAR, respectively. The applicable stress limits for the metallic components of the HISTORM UMAX VVM are confirmed in Section 2.6 of the HISTORM UMAX FSAR.

The SAR does not describe the source(s) of different fuels needed for operating onsite vehicles, such as the Vertical Cask Transporters and heavy haul tractor/trailers (SAR Section 3.1.4.7, Maintenance Operations), or those used for heating and other operational purposes. Existence or presence of large fuel source(s) (e.g., a fuel storage tank or a tanker truck) near important to safety structures could be a potential hazard that needs to be assessed.

Section 7.1.2 of the HISTORE SAR states that: Assemblies with higher burnups[:] Those would also have correspondingly higher cooling times to meet transport requirements. However, Table 7.1.1 of the HI STORE SAR states that the maximum burnup is 45 GWd/MTU. It is not clear if this statement implies that spent fuel with burnups higher than 45 GWd/MTU will be stored at the CISF. Since the UMAX design allows for storage of fuel with a maximum burnup of 68.2 GWd/MTU for PWR fuel assemblies and 65 GWd/MTU for BWR assemblies( ML14202A032, UMAX FSAR), the applicant should clarify this discrepancy between the burnup limit used in the shielding analysis and these SAR statements.

This information is necessary to determine compliance with 10 CFR 72.104(a), (b), (c) and 72.106(b).

The permissible contents for the HISTORE CIS facility is described in Subsection 4.1.1 of the HISTORE SAR, where the authorized materials are incorporated by reference from Section 2.1 of the HISTORM UMAX FSAR. The authorized contents include fuel with a maximum burnup of 68.2 GWd/mtU for PWR fuel assemblies and 65 GWd/mtU for BWR assemblies. To demonstrate compliance with the regulatory requirements, the shielding analysis is revised using the bounding source terms. For additional details about the source terms, the reviewer is referred to the responses to RAIs 73 and 74.

RAI 73: Provide specific minimum cooling time for higher burnup fuel to demonstrate that fuel with higher burnup will meet the design basis source terms limit of the HISTORE CISF.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 Section 7.1.2 of the HISTORE SAR, states that: Assemblies with higher burnups[:] Those would also have correspondingly higher cooling times to meet transport requirements. However, the applicant did not provide specific minimum cooling time requirement for each fuel burnup and enrichment limit. Without specific minimum cooling times for burnup and enrichment combination, the staff cannot verify if the higher burnup fuel meets the design basis source terms used in the HISTORE CISF dose analyses.

This information is necessary to determine compliance with 10 CFR 72.104(a), (b), (c) and 72.106(b).

Since the canisters arrive at the HISTORE CIS facility in a NRCcertified transport cask such as HISTAR 190, the fuel specifications for the HISTAR 190 transport cask, presented in Tables 7.C.7 through 7.C.10 of the HISTAR 190 SAR, are used as the basis of the shielding analysis and they are explicitly provided in Chapter 7 of the HISTORE CISF SAR.

This information is necessary to determine compliance with 10 CFR 72.104(a), (b), (c) and 72.106(b).

Holtec Response:

Description Region 1          Region 2    Region 3 MPC37        0.95            1.70      0.84/1.1 MPC89        0.35            0.62          0.35

RAI 75: Justify the adequacy of the 2000 hours occupancy assumption in the calculation of the annual dose at the controlled area boundary.

Section 7.4.2.1 of the HISTORE SAR states that: [t]he maximum controlled area boundary dose rate (assuming an occupancy of 2,000 hours per year) is below the 25 mrem annual dose limit of 10 CFR 72.104. However, the SAR does not provide the basis for assuming 2000 hours occupancy of a real individual at the controlled area boundary.

RAI 77: Demonstrate that the HISTORE CIS storage system design is sufficiently similar to that of the HISTORM UMAX design so that the analyses for HISTORM UMAX are applicable to the HISTORE CIS system.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 Section 7.2.2.1 of the HISTORE SAR states that: [t]he version of the HISTORM UMAX storage system used here is slightly different from that described in [1.0.6]. However, the differences are minor, and do not affect the principal design features of the system. A discussion of the shielding design features of the storage system see Subsection 5.1.1 in [1.0.6]. This Subsection is incorporated here by reference.

The staff also notes that Section 7.4.2.2 states that a separate shielding calculation for the HITRAC CS with assumption of substantially degraded concrete was performed. However, the SAR does not discuss the amount of concrete degradation assumed. The SAR should explicitly discuss and justify the amount of concrete degradation assumed in the shielding calculations for the HITRAC CS to demonstrate compliance with the regulatory requirements of 10 CFR 72.106.

HISTORE Consolidated Interim Storage Facility Requests for Additional Information Part 6 Attachment 2 Holtec Letter 5025061 This information is necessary to determine compliance with 10 CFR 72.104(a), (b), (c) and 72.106(a) and (b).

Holtec Response:

The HITRAC VW analyzed in the HISTORM FW SAR, which has radial layers of steelleadsteelwater steel, is not used at the HISTORE CISF; therefore, accident conditions dose rates of the HITRAC VW are not applicable at the HISTORE CISF. The HITRAC CS, which has radial layers of steelconcretesteel is used at the HISTORE CISF, so accident conditions related to this transfer cask are relevant to the HI STORE CIS Facility SAR. For the bounding accident condition for the HITRAC CS, which is either burial under debris or a fire accident, any concrete that exceeds 1100oF is considered degraded, as mentioned in Chapter 4 and 6, and is not credited for shielding under accident conditions. Under the fire accident conditions, less than 1% of the total concrete volume is considered degraded, and under burial conditions less than 10% of the total concrete volume is considered degraded, which is detailed further in Reference [6.5.4] of the SAR. Although concrete degradation is not uniform down the length of the side of the HITRAC under the thermal accident, there are no localized radiation streaming paths that could increase dose rates beyond what is analyzed with the reduced concrete density in the accident conditions HITRAC CS model. Conservatively, the shielding analysis assumes a substantial loss of concrete areal density following the fire accident, with the density reduced from 3.05 g/cc (normal conditions) to 2.4 g/cc (accident conditions) or a decrease in total concrete areal density of 21.3% for accident conditions. HITRAC CS bounding accident conditions dose results demonstrating compliance with 10 CFR 72.106 are presented in Table 7.4.4.

RAI 79: Provide an assessment of the amount of Carbon14 that can be generated by neutron radiation of the air passing through the annular space between the canister and the VVM and an estimate of its contribution to the controlled area boundary dose.

Carbon14 (C14) is a radioactive material that can be produced by neutron irradiation of Nitrogen14, Oxygen16, and Oxygen17 that exists in the atmospheric air. For small ISFSIs, the generation of C14 is generally insignificant and, accordingly, the staff has not been concerned with its potential contribution to the dose to the general public and occupational workers inside or outside the controlled area boundary. However, larger spent fuel storage facilities, such as that proposed for the HISTORE CISF, could generate higher amounts of C14 during its operation. Accordingly, the SAR should provide an assessment or estimate of the amount of C14 that can be generated during its operation to determine its contribution to the total dose to workers and the general public.

This information is necessary to determine compliance with 10 CFR 72.104(a), (b), and (c).

Holtec Response:

The dose rate versus distance as a result of C14 production from a HISTORM UMAX system is documented in the new report HI2200954 R0. The results are used in HISTORE dose versus distance report (HI2177599 R2), and occupational dose report (HI2177600 R2), and discussed in the HISTORE storage SAR.

RAI 710: Provide justification for excluding the manufacturing tolerances for important to safety structures and components in the shielding analyses for the HISTORE CISF.