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| {{#Wiki_filter:3. NUREG-1 537, Part 1, Sectioti 4.6 recommends that an application should justify the assumptions andmethods, and validate results. bi/scuss the BLOOST code transient analysis in additional detail includingthe quantitative values of the rfajor parameters that enter the analysis. This should include the fluxpeaking factors used to represehf the hottest fuel rod.Please see the attached "BLOOST Code Validation Report" which provides more detail regarding theassumptions and methods of th'e BLOOST code. The "BLOOST Code Validation Report" also discusses abenchmarking study performed at the Sandia TRIGA Annular Core Pulse Reactor (ACPR).3-t 5. NUREG-1537, Part 1, Section 13.1.2 provides guidance to the licensee to identfi,5 all potential methodswhereby excess reactivity could be accidentally inserted into the reactor to cause an excursion. Pleasediscuss these potential methods and evaluate those found to be credible. At a minimum, analyze a rampinsertion of reactivity of the most reactive control rod (not the transient rod) at its maximum insertionrate, starting from the most Jim iting power level. Evaluations should include discussion of the model,assumptions, and calculation results.A ramp insertion of reactivity resulting from the withdrawal of a control rod may be caused by operatorerror or instrument malfunction. In order to determine power as a function of time during a linearreactivity increase, a single delayed neutron group model with a prompt jump approximation is used:*where P(t) is the power at time t, P0 is the initial power level, f3 is the total delayed neutron fraction(0.007), X, is the one group decay constant (0.405 sec-'), t is time, and y is the linear insertion rate ofreactivity.Control rod data for the AFRRI TRIGA reactor is shown in Table 1.Table 1. Control rod data for the AFRRI TRIGA reactor in core position 500.Rod Total Worth Total Withdrawal Average Insertion($). Time (sec) Rate ($/sec)Transient 2.89 29.0 0.0997Safety. 2.65 39.4 0.0673Shim 2.74 36.1 0.0760Regulating 3.01 34.8 0.0865For the reactivity insertion accident, starring power levels of 100 W and 1.0 MW were considered. TheSCRAM set point was assumed to b~e 1.09 MW, and a 0.5 second delay time was assumed betweenreaching the SCRAM set point and of the control rods. In addition to the single controlrod withdrawal scenario, the simultaneous withdrawal of all four control rods was also analyzed as aworst case. | | {{#Wiki_filter:3. NUREG-1 537, Part 1, Sectioti 4.6 recommends that an applicationshouldjustify the assumptions and methods, and validate results. bi/scuss the BLOOST code transientanalysis in additionaldetail including the quantitativevalues of the rfajor parametersthat enter the analysis. This should include the flux peakingfactors used to represehf the hottestfuel rod. |
| Table 2. Summary of ramp insertion of reactivity for AFRRI TRIGA control rods.'Rod Withdrawn Starting Power Time until Release of Total ReactivityControl Rods (sec) Inserted at SCRAM ($)Transient 100 W 9.77 0.93___________1.0 MW 1.23 0.13Safety 100 W 13.5 0.92___________1.0 MW 1.53 0.11Shim 100 W 12.23 0.931.0 MW .1.43 0.11Regulating "100 W 10.99 0.951.0 MW 1.32 0.12All Rods 100 W 3.51 1.161.0 MW 0.74 0.25In all cases, including the simultaneous withdrawal of all control rods, the total reactivity insertion is wellbelow the pulse reactivity insertion limit of $3.50 (2.45% Ak/k), thus safety of the reactor would not beadversely impacted. | | Please see the attached "BLOOST Code Validation Report" which provides more detail regarding the assumptions and methods of th'e BLOOST code. The "BLOOST Code Validation Report" also discusses a benchmarking study performed at the Sandia TRIGA Annular Core Pulse Reactor (ACPR). |
| 6. NUREG-1537 Part 1, Section 13 provides guidance to the licensee to discuss potential accidentscenarios. Section 13.1.5 of the SAR presents the results oalan analysis al a reactivity insertion of $0.51.Justify the magnitude of this assumed reactivity insertion in comparison with the maximum reactivityinsertion associated with any sin~gle experiment.The following analysis will replace the reference to a reactivity insertion of $0.51 of the SAR:The failure of an experiment or experiments could result in instantaneous insertion of reactivity. Theworst possible case would be the prompt addition of $3.00 (2.1% Ak/k) within the reactor core. TheTechnical Specifications establish that the sum of the absolute reactivity worths of all experiments in thereactor and in the associated experimental facilities shall not exceed $3.00 (2.1% Ak/k). Theinstantaneous insertion of $3.00 (2.1% Ak/k) to the reactor core as a result of a worst case reactivityinsertion is bounded by the an~lysis of the $3.50 (2.45% Ak/k) pulse limit and would not result in anyadverse safety conditions withili the AFRRI TRIGA core. | | por~-A_*ieddw 3-t |
| }} | | : 5. NUREG-1537, Part 1, Section 13.1.2 provides guidance to the licensee to identfi,5 all potential methods whereby excess reactivity could be accidentally inserted into the reactorto cause an excursion. Please discuss these potential methods and evaluate those found to be credible. At a minimum, analyze a ramp insertion of reactivity of the most reactive control rod (not the transient rod) at its maximum insertion rate, startingfrom the most Jim iting power level. Evaluationsshould include discussion of the model, assumptions, and calculationresults. |
| | A ramp insertion of reactivity resulting from the withdrawal of a control rod may be caused by operator error or instrument malfunction. In order to determine power as a function of time during a linear reactivity increase, a single delayed neutron group model with a prompt jump approximation is used: |
| | *where P(t) is the power at time t, P0 is the initial power level, f3 is the total delayed neutron fraction (0.007), X,is the one group decay constant (0.405 sec-'), t is time, and y is the linear insertion rate of reactivity. |
| | Control rod data for the AFRRI TRIGA reactor is shown in Table 1. |
| | Table 1. Control rod data for the AFRRI TRIGA reactor in core position 500. |
| | Rod Total Worth Total Withdrawal Average Insertion |
| | ($). Time (sec) Rate ($/sec) |
| | Transient 2.89 29.0 0.0997 Safety. 2.65 39.4 0.0673 Shim 2.74 36.1 0.0760 Regulating 3.01 34.8 0.0865 For the reactivity insertion accident, starring power levels of 100 W and 1.0 MW were considered. The SCRAM set point was assumed to b~e 1.09 MW, and a 0.5 second delay time was assumed between reaching the SCRAM set point and a*tual-elease of the control rods. In addition to the single control rod withdrawal scenario, the simultaneous withdrawal of all four control rods was also analyzed as a worst case. |
| | |
| | Table 2. Summary of ramp insertion of reactivity for AFRRI TRIGA control rods. |
| | 'Rod Withdrawn Starting Power Time until Release of Total Reactivity Control Rods (sec) Inserted at SCRAM ($) |
| | Transient 100 W 9.77 0.93 |
| | ___________1.0 MW 1.23 0.13 Safety 100 W 13.5 0.92 |
| | ___________1.0 MW 1.53 0.11 Shim 100 W 12.23 0.93 1.0 MW .1.43 0.11 Regulating "100 W 10.99 0.95 1.0 MW 1.32 0.12 All Rods 100 W 3.51 1.16 1.0 MW 0.74 0.25 In all cases, including the simultaneous withdrawal of all control rods, the total reactivity insertion is well below the pulse reactivity insertion limit of $3.50 (2.45% Ak/k), thus safety of the reactor would not be adversely impacted. |
| | : 6. NUREG-1537 Part1, Section 13 provides guidance to the licensee to discuss potential accident scenarios. Section 13.1.5 of the SAR presents the results oalan analysis al a reactivity insertion of $0.51. |
| | Justify the magnitude of this assumed reactivity insertion in comparison with the maximum reactivity insertion associatedwith any sin~gle experiment. |
| | The following analysis will replace the reference to a reactivity insertion of $0.51 of the SAR: |
| | The failure of an experiment or experiments could result in instantaneous insertion of reactivity. The worst possible case would be the prompt addition of $3.00 (2.1% Ak/k) within the reactor core. The Technical Specifications establish that the sum of the absolute reactivity worths of all experiments in the reactor and in the associated experimental facilities shall not exceed $3.00 (2.1% Ak/k). The instantaneous insertion of $3.00 (2.1% Ak/k) to the reactor core as a result of a worst case reactivity insertion is bounded by the an~lysis of the $3.50 (2.45% Ak/k) pulse limit and would not result in any adverse safety conditions withili the AFRRI TRIGA core.}} |
Letter Sequence Other |
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Initiation
- Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request, Request
- Acceptance...
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MONTHYEARML1023100752010-08-13013 August 2010
Request for Additional Information Regarding Financial Qualifications for the License Renewal Review
Project stage: Request
ML1024400342010-08-25025 August 2010
Request for Additional Information Regarding the Application for License Renewal
Project stage: Request
ML1030701252010-10-19019 October 2010
Letter Armed Forces Radiobiology Research Institute - Approval of Request for an Extension Response to Request for Additional Information Dated July 19, 2010
Project stage: Response to RAI
ML1030701212010-10-21021 October 2010
Letter Armed Forces Radiobiology Research Institute-Request for Additional Information Regarding the Application for License Renewal
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ML1104606872011-02-0707 February 2011
Request for Additional Information Regarding the Application for License Renewal
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ML11165A0162011-06-0303 June 2011
Armed Forces Radiobiology Research Institute, Response to Request for Additional Information Dtd 07/19/2010 Regarding the Application for License Renewal
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ML11269A0302011-09-0606 September 2011
Response to Request for Additional Information Regarding the Application for Renewal of License R-84
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Esponse to Request for Additional Information Regarding the Application for License Renewal
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ML12032A0542012-01-17017 January 2012
Response to Request for Additional Information Regarding the Application for License Renewal
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ML15296A4512012-04-20020 April 2012
21C025, Rev. 0, Bloost Code Validation Report.
Project stage: Other
ML12122A1462012-04-20020 April 2012
Request for Additional Information Regarding the Application for License Renewal
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ML12272A3032012-09-21021 September 2012
Request for Additional Information Regarding the Application for License Renewal
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ML1018000132012-10-26026 October 2012
Armed Forces Radiobiology Research Institute - Determination of Acceptability and Sufficiency for Docketing and Opportunity for a Hearing Regarding the Application for Renewal of Facility License No. R-84 for the Afrri Reactor
Project stage: Other
ML13182A0842013-06-28028 June 2013
Armed Forces Radiobiology Research Institute - Response to Request for Additional Information Regarding the Application for License Renewal
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ML13254A0642013-08-27027 August 2013
Us Dept of Defense, Uniformed Services University of the Health Sciences - Submittal of Revised Technical Specifications, Docket 50-170
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ML14115A1692014-05-16016 May 2014
Armed Forces Radiobiology Research Institute (Afrri) - Request for Additional Information for the for the License Renewal Review of the Afrri Reactor Facility
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ML14349A3192014-12-0404 December 2014
Request for Additional Information Regarding the Renewal of Facility Operating License No. R-84 for the Afrri Triga Reactor Facility
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ML15026A4192015-02-23023 February 2015
Request for Additional Information Physical Security Plan Review for License Renewal
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ML15093A0992015-03-30030 March 2015
Letter from Stephen L. Miller Enclosing Revision of the Technical Specifications for the Armed Forces Radiobiology Research Institute Reactor (License R-84, Docket 50-170)
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ML15182A2392015-06-25025 June 2015
Us Dept of Defense, Armed Forces Radiobiology Research Institute - Response to Request for Additional Information Regarding the Physical Security Plan Review for License Renewal
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ML15273A4772015-11-0202 November 2015
Armed Forces Radiobiology Research Institute (Afrri) - Request for Additional Information Regarding the Renewal of Facility Operating License No. R-84 for the Afrri Triga Reactor Facility
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ML15317A0142015-11-0404 November 2015
Response to Armed Forces Radiobiology Research Institute - Request for Additional Information Regarding Physical Security Plan Review for License Renewal
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ML16040A3102016-02-0909 February 2016
Request for Additional Information Regarding the Application for License Renewal
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ML16060A2102016-02-26026 February 2016
Submittal of Technical Specifications for the Armed Forces Radiobiology Research Institute Facility
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ML16089A3732016-03-23023 March 2016
Armed Forces Radiobiology Research Institute - Transmittal of 2015 Annual Operating Report
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ML16232A1642016-08-0505 August 2016
Response to NRR Request for Additional Information Regarding the Application for License Renewal for Affri Facility
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ML16232A1672016-08-0505 August 2016
Technical Specifications for the Affri Reactor Facility
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ML16232A1662016-08-0505 August 2016
Response to NRR Request for Additional Information Regarding the Renewal of the Armed Forces Radiobiology Research Institute, Triga Reactor Facility
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ML16218A2242016-08-0505 August 2016
Armed Forces Radiobiology Research Institute TRIGA Research Reactor proposed license renewal IPaC Trust Resources Report
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ML16258A4642016-09-12012 September 2016
Reactor Operator Requalification Program for the Affri Triga Reactor Facility
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ML16258A4632016-09-12012 September 2016
Us Dept of Defense, Armed Forces Radiobiology Research Institute (Afrri), Submittal of Request for Additional Information Regarding the Application for License Renewal
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Afrri Request for Additional Information for License Renewal
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Request for Additional Information Regarding the Application for License Renewal
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Us Dept. of Defense, Armed Forces Radiobiology Research Institute (Afrri), Response to Request for Additional Information Regarding Application for License Renewal
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AFRRI Technical Specifications
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ML16321A4612016-11-16016 November 2016
Us Armed Forces Radiobiology Research Institute Letter Regarding Review of Draft License R-84
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ML13211A1912016-11-18018 November 2016
Armed Forces Radiobiology Research Institute - Environmental Assessment and Finding of No Significant Impact Regarding Renewal of Facility Operating License No. R-84.)
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ML13211A1902016-11-18018 November 2016
Environmental Assessment and Finding of No Significant Impact Regarding License Renewal for the Armed Forces Radiobiology Research Institute (Afrri) Triga Mark-F Research Reactor (FRN)
Project stage: Other
ML16077A2842016-11-30030 November 2016, 1 December 2016
Afrri Renewal of Facility Operating License
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ML16278A3472016-11-30030 November 2016
SER: Renewal of the Facility Operating License for the Armed Forces Radiobiology Research Institute TRIGA Reactor
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ML16077A3032016-11-30030 November 2016
Armed Forces Radiobiology Research Institute - Issuance of Renewed Facility Operating License No. R-84 for the Armed Forces Radiobiology Research Institute Research Reactor
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ML16077A3012016-12-0101 December 2016
Federal Register Notice - Afrri License Issuance
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NRC-2012-0272, Federal Register Notice - Afrri License Issuance2016-12-0101 December 2016
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2015-11-02
[Table View] |
21C025, Rev. 0, Bloost Code Validation Report.| ML15296A451 |
| Person / Time |
|---|
| Site: |
05000704, Armed Forces Radiobiology Research Institute |
|---|
| Issue date: |
04/20/2012 |
|---|
| From: |
Sherman R
General Atomics, Hitachi America, Ltd, Marubeni Canada, Ltd, TRIGA Technologies |
|---|
| To: |
Govt of Thailand, Office of Atomic Energy for Peace, Office of Nuclear Reactor Regulation |
|---|
| References |
|---|
| TAC ME1587 21C025, Rev. 0 |
| Download: ML15296A451 (4) |
|
|
|---|
Category:Report
MONTHYEARML21316A0382021-11-0808 November 2021
Enclosure 5 - Errata for Usuhs/Afrri Triga Reactor Control System Functional Requirements Specification (Conceptual) - T3S990001-FRS Rev a
ML21316A0362021-11-0808 November 2021
Enclosure 3 - Usuhs/Afrri Triga Reactor Control System Functional Requirements Specification (Conceptual) - T3S990001-FRS Rev a, Redacted
ML20318A3432020-11-10010 November 2020
Enclosure 1c - License Amendment Request for the Upgrade of the Instrumentation and Control System for the Armed Forces Radiobiology Research Institute Triga Reactor - Redacted
ML20318A3402020-11-10010 November 2020
Explanation of Enclosures
ML16218A2242016-08-0505 August 2016
Armed Forces Radiobiology Research Institute TRIGA Research Reactor proposed license renewal IPaC Trust Resources Report
ML15296A4512012-04-20020 April 2012
21C025, Rev. 0, Bloost Code Validation Report.
2021-11-08
[Table view]
Category:Technical
MONTHYEARML21316A0382021-11-0808 November 2021
Enclosure 5 - Errata for Usuhs/Afrri Triga Reactor Control System Functional Requirements Specification (Conceptual) - T3S990001-FRS Rev a
ML21316A0362021-11-0808 November 2021
Enclosure 3 - Usuhs/Afrri Triga Reactor Control System Functional Requirements Specification (Conceptual) - T3S990001-FRS Rev a, Redacted
ML20318A3432020-11-10010 November 2020
Enclosure 1c - License Amendment Request for the Upgrade of the Instrumentation and Control System for the Armed Forces Radiobiology Research Institute Triga Reactor - Redacted
ML20318A3402020-11-10010 November 2020
Explanation of Enclosures
ML16218A2242016-08-0505 August 2016
Armed Forces Radiobiology Research Institute TRIGA Research Reactor proposed license renewal IPaC Trust Resources Report
ML15296A4512012-04-20020 April 2012
21C025, Rev. 0, Bloost Code Validation Report.
2021-11-08
[Table view] |
Text
3. NUREG-1 537, Part 1, Sectioti 4.6 recommends that an applicationshouldjustify the assumptions and methods, and validate results. bi/scuss the BLOOST code transientanalysis in additionaldetail including the quantitativevalues of the rfajor parametersthat enter the analysis. This should include the flux peakingfactors used to represehf the hottestfuel rod.
Please see the attached "BLOOST Code Validation Report" which provides more detail regarding the assumptions and methods of th'e BLOOST code. The "BLOOST Code Validation Report" also discusses a benchmarking study performed at the Sandia TRIGA Annular Core Pulse Reactor (ACPR).
por~-A_*ieddw 3-t
- 5. NUREG-1537, Part 1, Section 13.1.2 provides guidance to the licensee to identfi,5 all potential methods whereby excess reactivity could be accidentally inserted into the reactorto cause an excursion. Please discuss these potential methods and evaluate those found to be credible. At a minimum, analyze a ramp insertion of reactivity of the most reactive control rod (not the transient rod) at its maximum insertion rate, startingfrom the most Jim iting power level. Evaluationsshould include discussion of the model, assumptions, and calculationresults.
A ramp insertion of reactivity resulting from the withdrawal of a control rod may be caused by operator error or instrument malfunction. In order to determine power as a function of time during a linear reactivity increase, a single delayed neutron group model with a prompt jump approximation is used:
- where P(t) is the power at time t, P0 is the initial power level, f3 is the total delayed neutron fraction (0.007), X,is the one group decay constant (0.405 sec-'), t is time, and y is the linear insertion rate of reactivity.
Control rod data for the AFRRI TRIGA reactor is shown in Table 1.
Table 1. Control rod data for the AFRRI TRIGA reactor in core position 500.
Rod Total Worth Total Withdrawal Average Insertion
($). Time (sec) Rate ($/sec)
Transient 2.89 29.0 0.0997 Safety. 2.65 39.4 0.0673 Shim 2.74 36.1 0.0760 Regulating 3.01 34.8 0.0865 For the reactivity insertion accident, starring power levels of 100 W and 1.0 MW were considered. The SCRAM set point was assumed to b~e 1.09 MW, and a 0.5 second delay time was assumed between reaching the SCRAM set point and a*tual-elease of the control rods. In addition to the single control rod withdrawal scenario, the simultaneous withdrawal of all four control rods was also analyzed as a worst case.
Table 2. Summary of ramp insertion of reactivity for AFRRI TRIGA control rods.
'Rod Withdrawn Starting Power Time until Release of Total Reactivity Control Rods (sec) Inserted at SCRAM ($)
Transient 100 W 9.77 0.93
___________1.0 MW 1.23 0.13 Safety 100 W 13.5 0.92
___________1.0 MW 1.53 0.11 Shim 100 W 12.23 0.93 1.0 MW .1.43 0.11 Regulating "100 W 10.99 0.95 1.0 MW 1.32 0.12 All Rods 100 W 3.51 1.16 1.0 MW 0.74 0.25 In all cases, including the simultaneous withdrawal of all control rods, the total reactivity insertion is well below the pulse reactivity insertion limit of $3.50 (2.45% Ak/k), thus safety of the reactor would not be adversely impacted.
- 6. NUREG-1537 Part1, Section 13 provides guidance to the licensee to discuss potential accident scenarios. Section 13.1.5 of the SAR presents the results oalan analysis al a reactivity insertion of $0.51.
Justify the magnitude of this assumed reactivity insertion in comparison with the maximum reactivity insertion associatedwith any sin~gle experiment.
The following analysis will replace the reference to a reactivity insertion of $0.51 of the SAR:
The failure of an experiment or experiments could result in instantaneous insertion of reactivity. The worst possible case would be the prompt addition of $3.00 (2.1% Ak/k) within the reactor core. The Technical Specifications establish that the sum of the absolute reactivity worths of all experiments in the reactor and in the associated experimental facilities shall not exceed $3.00 (2.1% Ak/k). The instantaneous insertion of $3.00 (2.1% Ak/k) to the reactor core as a result of a worst case reactivity insertion is bounded by the an~lysis of the $3.50 (2.45% Ak/k) pulse limit and would not result in any adverse safety conditions withili the AFRRI TRIGA core.