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| issue date = 09/09/2011 | | issue date = 09/09/2011 | ||
| title = Examination Report No. 50-284/OL-11-01, Idaho State University | | title = Examination Report No. 50-284/OL-11-01, Idaho State University | ||
| author name = Eads J | | author name = Eads J | ||
| author affiliation = NRC/NRR/DPR/PRTB | | author affiliation = NRC/NRR/DPR/PRTB | ||
| addressee name = Kunze J | | addressee name = Kunze J | ||
| addressee affiliation = Idaho State Univ | | addressee affiliation = Idaho State Univ | ||
| docket = 05000284 | | docket = 05000284 | ||
| license number = | | license number = | ||
| contact person = Isaac P | | contact person = Isaac P, NRC/NRR/DPR/PROB | ||
| document report number = 50-284/OL-11-001 | | document report number = 50-284/OL-11-001 | ||
| document type = Letter, License-Operator Examination Report | | document type = Letter, License-Operator Examination Report | ||
Line 16: | Line 16: | ||
=Text= | =Text= | ||
{{#Wiki_filter:September 9, 2011 Dr. Jay F. Kunze Idaho State University 833 South Eighth Street | {{#Wiki_filter:September 9, 2011 Dr. Jay F. Kunze Idaho State University 833 South Eighth Street Pocatello, ID 83209 | ||
==SUBJECT:== | ==SUBJECT:== | ||
EXAMINATION REPORT NO. 50-284/OL-11-01, IDAHO STATE UNIVERSITY | EXAMINATION REPORT NO. 50-284/OL-11-01, IDAHO STATE UNIVERSITY | ||
==Dear Dr. Kunze:== | ==Dear Dr. Kunze:== | ||
During the week of July 25, 2011, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examination at your Idaho State University AGN reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2, published in June 2007. Examination questions and preliminary findings were discussed at the conclusion of the examination with those members of your staff identified in the enclosed report. | During the week of July 25, 2011, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examination at your Idaho State University AGN reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2, published in June 2007. Examination questions and preliminary findings were discussed at the conclusion of the examination with those members of your staff identified in the enclosed report. | ||
In accordance with Title 10, Section 2.390 of the Code of Federal Regulations, a copy of this letter and the enclosures will be available electronically for public inspection in the NRC Public Document Room or from the Publicly Available Records (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS). ADAMS is accessible from the NRC Web site at http://www.nrc.gov/reading-rm/adams.html (the Public Electronic Reading Room). The NRC is forwarding the individual grades to you in a separate letter which will not be released publicly. If you have any questions concerning this examination, please contact Patrick Isaac at 301-415-1019 or via email at patrick.isaac@nrc.gov. | |||
In accordance with Title 10, Section 2.390 of the Code of Federal Regulations, a copy of this letter and the enclosures will be available electronically for public inspection in the NRC Public Document Room or from the Publicly Available Records (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS). ADAMS is accessible from the NRC Web site at http://www.nrc.gov/reading-rm/adams.html (the Public Electronic Reading Room). The NRC is forwarding the individual grades to you in a separate letter which will not be released publicly. If you have any questions concerning this examination, please contact Patrick Isaac at 301-415-1019 or via email at patrick.isaac@nrc.gov. | Sincerely, | ||
/RA/ | |||
Sincerely, | Johnny H. Eads, Jr., Chief Research and Test Reactors Oversight Branch Division of Policy and Rulemaking Office of Nuclear Reactor Regulation Docket No. 50-284 | ||
==Enclosures:== | ==Enclosures:== | ||
: 1. Examination Report No. 50-284/OL-11-01 | : 1. Examination Report No. 50-284/OL-11-01 | ||
: 2. Corrected Written Examination cc: | : 2. Corrected Written Examination cc: Adam Mallicoat, Reactor Supervisor, Idaho State University cc: w/o enclosures: See next page | ||
September 9, 2011 Dr. Jay F. Kunze Idaho State University 833 South Eighth Street | September 9, 2011 Dr. Jay F. Kunze Idaho State University 833 South Eighth Street Pocatello, ID 83209 | ||
==SUBJECT:== | ==SUBJECT:== | ||
EXAMINATION REPORT NO. 50-284/OL-11-01, IDAHO STATE UNIVERSITY | EXAMINATION REPORT NO. 50-284/OL-11-01, IDAHO STATE UNIVERSITY | ||
==Dear Dr. Kunze:== | ==Dear Dr. Kunze:== | ||
During the week of July 25, 2011, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examination at your Idaho State University AGN reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2, published in June 2007. Examination questions and preliminary findings were discussed at the conclusion of the examination with those members of your staff identified in the enclosed report. | During the week of July 25, 2011, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examination at your Idaho State University AGN reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2, published in June 2007. Examination questions and preliminary findings were discussed at the conclusion of the examination with those members of your staff identified in the enclosed report. | ||
In accordance with Title 10, Section 2.390 of the Code of Federal Regulations, a copy of this letter and the enclosures will be available electronically for public inspection in the NRC Public Document Room or from the Publicly Available Records (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS). ADAMS is accessible from the NRC Web site at http://www.nrc.gov/reading-rm/adams.html (the Public Electronic Reading Room). The NRC is forwarding the individual grades to you in a separate letter which will not be released publicly. If you have any questions concerning this examination, please contact Patrick Isaac at 301-415-1019 or via email at patrick.isaac@nrc.gov. | In accordance with Title 10, Section 2.390 of the Code of Federal Regulations, a copy of this letter and the enclosures will be available electronically for public inspection in the NRC Public Document Room or from the Publicly Available Records (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS). ADAMS is accessible from the NRC Web site at http://www.nrc.gov/reading-rm/adams.html (the Public Electronic Reading Room). The NRC is forwarding the individual grades to you in a separate letter which will not be released publicly. If you have any questions concerning this examination, please contact Patrick Isaac at 301-415-1019 or via email at patrick.isaac@nrc.gov. | ||
Sincerely, | Sincerely, | ||
/RA/ | |||
Johnny H. Eads, Jr., Chief Research and Test Reactors Oversight Branch Division of Policy and Rulemaking Office of Nuclear Reactor Regulation Docket No. 50-284 | |||
Johnny H. Eads, Jr., Chief | |||
==Enclosures:== | ==Enclosures:== | ||
: 1. Examination Report No. 50-284/OL-11-01 | : 1. Examination Report No. 50-284/OL-11-01 | ||
: 2. Corrected Written Examination cc: Adam Mallicoat, Reactor Supervisor, Idaho State University cc: w/o enclosures: See next page DISTRIBUTION w/ encls.: | |||
DISTRIBUTION w/ encls.: PUBLIC | PUBLIC PROB r/f JEads Facility File (CRevelle) | ||
ADAMS ACCESSION #: ML112420716 OFFICE PROB:CE IOLB:LA PROB:BC NAME PIsaac CRevelle JEads DATE 08/30/11 09/09/11 9/9/11 OFFICIAL RECORD COPY | |||
Idaho State University Docket No. 50-284 cc: | |||
Idaho State University ATTN: Dr. Richard T. Jacobsen College of Engineering Dean Campus Box 8060 Pocatello, ID 83209-8060 Idaho State University ATTN: Dr. Richard R. Brey Radiation Safety Officer Physics Department Box 8106 Pocatello, ID 83209-8106 Toni Hardesty, Director Idaho Dept. of Environmental Quality 1410 North Hilton Boise, ID 83606 Test, Research and Training Reactor Newsletter 202 Nuclear Sciences Center University of Florida Gainesville, FL 32611 | |||
FACILITY LICENSE NO.: | EXAMINATION REPORT NO: 50-284/OL-11-01 FACILITY: Idaho State University FACILITY DOCKET NO.: 50-284 FACILITY LICENSE NO.: R-110 SUBMITTED BY: _______/JNguyen for RA/_______ __9/9/11___ | ||
Patrick J. Isaac, Chief Examiner Date | |||
==SUMMARY== | ==SUMMARY== | ||
During the week of July 25, 2011, the NRC administered operator licensing examinations to one Senior Reactor Operator Instant (SROI), one Senior Reactor Operator Upgrade, and two Reactor Operator candidates. The SROI candidate failed the examinations. All other candidates passed the examinations and have been issued a license to operate the Idaho State University reactor. | |||
REPORT DETAILS | REPORT DETAILS | ||
: 1. Examiner: | : 1. Examiner: Patrick J. Isaac, Chief Examiner | ||
: 2. Results: | : 2. Results: | ||
RO PASS/FAIL SRO PASS/FAIL TOTAL PASS/FAIL Written 2/0 0/1 2/1 Operating Tests 2/0 1/1 3/1 Overall 2/0 1/1 3/1 | RO PASS/FAIL SRO PASS/FAIL TOTAL PASS/FAIL Written 2/0 0/1 2/1 Operating Tests 2/0 1/1 3/1 Overall 2/0 1/1 3/1 | ||
: 3. Exit Meeting: | : 3. Exit Meeting: | ||
Adam Mallicoat, Idaho State University Patrick Isaac, NRC, Examiner The NRC Examiner thanked the facility for their support in the administration of the examinations and agreed to make the following changes to the written examination: | Adam Mallicoat, Idaho State University Patrick Isaac, NRC, Examiner The NRC Examiner thanked the facility for their support in the administration of the examinations and agreed to make the following changes to the written examination: | ||
Question A.7 - Accept both answers | Question A.7 - Accept both answers b and d as correct. | ||
Question C.14 - Accept | Question C.14 - Accept b as the correct answer | ||
CANDIDATE: | U. S. NUCLEAR REGULATORY COMMISSION NON-POWER INITIAL REACTOR LICENSE EXAMINATION FACILITY: Idaho State University REACTOR TYPE: AGN-201 DATE ADMINISTERED: July 25, 2011 CANDIDATE: _____________________________ | ||
INSTRUCTIONS TO CANDIDATE: | INSTRUCTIONS TO CANDIDATE: | ||
Answers are to be written on the Answer sheet provided. Attach all Answer sheets to the examination. Point values are indicated in parentheses for each question. A 70% in each category is required to pass the examination. Examinations will be picked up three (3) hours after the examination starts. | Answers are to be written on the Answer sheet provided. Attach all Answer sheets to the examination. Point values are indicated in parentheses for each question. A 70% in each category is required to pass the examination. Examinations will be picked up three (3) hours after the examination starts. | ||
% OF CATEGORY % OF CANDIDATE'S CATEGORY VALUE TOTAL SCORE VALUE CATEGORY 18.00 35.3 A. REACTOR THEORY, THERMODYNAMICS AND FACILITY OPERATING CHARACTERISTICS 18.00 35.3 B. NORMAL AND EMERGENCY OPERATING PROCEDURES AND RADIOLOGICAL CONTROLS 15.00 29.4 C. FACILITY AND RADIATION MONITORING SYSTEMS 51.00 % TOTALS FINAL GRADE All work done on this examination is my own. I have neither given nor received aid. | |||
Candidate's Signature | |||
18.00 | |||
Candidate's Signature | |||
A | A. RX THEORY, THERMO & FAC OP CHARS ANSWER SHEET Multiple Choice (Circle or X your choice) | ||
001 | If you change your Answer, write your selection in the blank. | ||
001 a b c d ___ | |||
002 a b c d ___ | |||
003 a b c d ___ | |||
004 a b c d ___ | |||
005 a b c d ___ | |||
006 a b c d ___ | |||
007 a b c d ___ | |||
008 a b c d ___ | |||
009 a b c d ___ | |||
010 a b c d ___ | |||
011 a b c d ___ | |||
012 a b c d ___ | |||
013 a b c d ___ | |||
014 a b c d ___ | |||
015 a b c d ___ | |||
016 a b c d ___ | |||
017 a b c d ___ | |||
018 a b c d ___ | |||
(***** END OF CATEGORY A *****) | |||
002 | B. NORMAL/EMERG PROCEDURES & RAD CON ANSWER SHEET Multiple Choice (Circle or X your choice) | ||
003 | If you change your Answer, write your selection in the blank. | ||
004 | 001 a b c d ___ | ||
005 | 002 a b c d ___ | ||
003 a ___ b ___ c ___ d ___ | |||
004 a ___ b ___ c ___ d ___ | |||
005 a ___ b ___ c ___ d ___ | |||
006 a b c d ___ | |||
007 a b c d ___ | |||
008 a b c d ___ | |||
009 a b c d ___ | |||
010 a b c d ___ | |||
011 a b c d ___ | |||
012 a b c d ___ | |||
013 a b c d ___ | |||
014 a b c d ___ | |||
015 a b c d ___ | |||
(***** END OF CATEGORY B *****) | |||
006 | C. PLANT AND RAD MONITORING SYSTEMS ANSWER SHEET Multiple Choice (Circle or X your choice) | ||
007 | If you change your Answer, write your selection in the blank. | ||
001 a b c d ___ | |||
002 a b c d ___ | |||
003 a b c d ___ | |||
004 a b c d ___ | |||
005 a b c d ___ | |||
006 a b c d ___ | |||
007 a b c d ___ | |||
008 a b c d ___ | |||
009 a b c d ___ | |||
010 a b c d ___ | |||
011 a b c d ___ | |||
012 a b c d ___ | |||
013 a b c d ___ | |||
014 a b c d ___ | |||
015 a b c d ___ | |||
(***** END OF CATEGORY C *****) | |||
(********** END OF EXAMINATION **********) | |||
NRC RULES AND GUIDELINES FOR LICENSE EXAMINATIONS During the administration of this examination the following rules apply: | NRC RULES AND GUIDELINES FOR LICENSE EXAMINATIONS During the administration of this examination the following rules apply: | ||
: 1. Cheating on the examination means an automatic denial of your application and could result in more severe penalties. | : 1. Cheating on the examination means an automatic denial of your application and could result in more severe penalties. | ||
Line 179: | Line 149: | ||
: 11. To pass the examination you must achieve a grade of 70 percent or greater in each category. | : 11. To pass the examination you must achieve a grade of 70 percent or greater in each category. | ||
: 12. There is a time limit of three (3) hours for completion of the examination. | : 12. There is a time limit of three (3) hours for completion of the examination. | ||
EQUATION SHEET | |||
1 Curie = 3.7 x | Pmax = | ||
( )2 eff = 0.1sec 1 Q& = m& c P T = m& H =UAT (2 l ) | |||
t P = P0 e S S SCR = l* =1x10 4 sec 1 K eff eff + & | |||
SUR = 26 .06 | |||
( ) ( | |||
CR1 1 K eff1 = CR2 1 K eff 2 ) CR1 ( 1 ) = CR2 ( 2 ) | |||
(1 ) M= | |||
1 CR | |||
= 2 P = P0 10SUR(t ) | |||
P= P0 1 K eff CR1 1 K eff1 1 K eff l* | |||
M= SDM = = | |||
1 K eff 2 K eff l* 0.693 K eff 2 K eff1 | |||
= + T1 = = | |||
eff + & 2 K eff1 K eff 2 K eff 1 | |||
= DR = DR0 e t 2 DR1 d1 = DR2 d 2 2 | |||
K eff | |||
) | |||
6 Ci E (n ) | |||
DR = | |||
R2 DR - Rem/hr, Ci - curies, E - Mev, R - feet 1 Curie = 3.7 x 1010 dis/sec 1 kg = 2.21 lbm 1 Horsepower = 2.54 x 103 BTU/hr 1 Mw = 3.41 x 106 BTU/hr 1 BTU = 778 ft-lbf °F = 9/5 °C + 32 1 gal (H2O) 8 lbm °C = 5/9 (°F - 32) cP = 1.0 BTU/hr/lbm/°F cp = 1 cal/sec/gm/°C | |||
QUESTION A.01 [1.0] | QUESTION A.01 [1.0] | ||
: b. Epi-Thermal neutron (1 eV) | Which ONE of the following neutrons would result in the highest probability of fission for 235U? | ||
: c. Prompt neutron (0.7 MeV) | : a. Thermal neutron (0.025 eV) | ||
: d. Fast neutron (2 MeV) | : b. Epi-Thermal neutron (1 eV) | ||
QUESTION A.02 [1.0] | : c. Prompt neutron (0.7 MeV) | ||
: d. Fast neutron (2 MeV) | |||
QUESTION A.02 [1.0] | |||
Which of the following power manipulations would take the longest to complete assuming the same period is maintained? | Which of the following power manipulations would take the longest to complete assuming the same period is maintained? | ||
: a. 100 mW to 400 mW | : a. 100 mW to 400 mW | ||
: b. 400 mW to 500 mW | : b. 400 mW to 500 mW | ||
: c. 1 W to 3.5 W | : c. 1 W to 3.5 W | ||
: d. 3.5 W to 4.5 W QUESTION A.03 [1.0] | : d. 3.5 W to 4.5 W QUESTION A.03 [1.0] | ||
A critical reactor is operating at a steady-state power level of 1.00 W. Reactor power is increased to a new steady-state power level of 1.05 W. Neglecting any temperature effects, what reactivity insertion is required to accomplish this? | A critical reactor is operating at a steady-state power level of 1.00 W. Reactor power is increased to a new steady-state power level of 1.05 W. Neglecting any temperature effects, what reactivity insertion is required to accomplish this? | ||
: a. 0.05 delta k/k. | : a. 0.05 delta k/k. | ||
: b. 5.0% delta k/k. | : b. 5.0% delta k/k. | ||
: c. 1.05% delta k/k. | : c. 1.05% delta k/k. | ||
: d. Indeterminate, since any amount of positive reactivity could be used. | : d. Indeterminate, since any amount of positive reactivity could be used. | ||
QUESTION A.04 [1.0] | |||
QUESTION A.04 [1.0] Which ONE of the following factors in the six-factor formula can be varied by the reactor operator? | Which ONE of the following factors in the six-factor formula can be varied by the reactor operator? | ||
: a. Fast fission factor. | : a. Fast fission factor. | ||
: b. Reproduction factor. | : b. Reproduction factor. | ||
: c. Fast non-leakage factor. | : c. Fast non-leakage factor. | ||
: d. Thermal utilization factor | : d. Thermal utilization factor. | ||
QUESTION A.07 [1.0] Which one of the following is the purpose of having an installed neutron source? | QUESTION A.05 [1.0] | ||
: a. To compensate for neutrons absorbed by experiments installed into the reactor. | If reactor period () is at 25 seconds, approximately how long will it take for reactor power to increase by a factor of 10? | ||
: b. To generate a sufficient neutron population to start a fission chain for reactor startup. | : a. 10 seconds | ||
: c. To provide for a means to allow reactivity changes to occur in a subcritical reactor. | : b. 25 seconds | ||
: d. To generate a detectable neutron level for monitoring reactivity changes in a shutdown reactor. | : c. 1 minute | ||
: d. 3 minutes QUESTION A.06 [1.0] | |||
The AGN-201 is designed to produce a fission rate within the thermal fuse that is approximately twice the average of the core. Which ONE of the following describes how this higher reaction rate is accomplished? | |||
: a. The polystyrene media used in the thermal fuse is a better moderator, raising the thermal flux in the fuse area. | |||
: b. The non-uniform fuel loading in the upper fuel disc increases the thermal flux in fuse area. | |||
: c. The fuel enrichment used in the thermal fuse is twice that of the balance of the core resulting in a higher fission rate in the fuse area. | |||
: d. The fuel density used in the thermal fuse is twice that of the balance of the core resulting in a higher fission rate in the fuse area. | |||
QUESTION A.07 [1.0] | |||
Which one of the following is the purpose of having an installed neutron source? | |||
: a. To compensate for neutrons absorbed by experiments installed into the reactor. | |||
: b. To generate a sufficient neutron population to start a fission chain for reactor startup. | |||
: c. To provide for a means to allow reactivity changes to occur in a subcritical reactor. | |||
: d. To generate a detectable neutron level for monitoring reactivity changes in a shutdown reactor. | |||
QUESTION A.10 [1.0] Which one of the following is the reason for the steady-state period after a reactor scram? | QUESTION A.08 [1.0] | ||
: a. | At the beginning of a reactor startup, Keff is 0.90 with a count rate of 30 CPS. Power is increased to a new, steady value of 60 CPS. The new Keff is: | ||
: b. | : a. 0.91 | ||
: c. 5 seconds, due to the rapid insertion of reactivity greater than eff. | : b. 0.925 | ||
: d. | : c. 0.95 | ||
: d. 0.975 QUESTION A.09 [1.0] | |||
Which ONE of the following statements describes the difference between Differential (DRW) and Integral (IRW) rod worth curves? | |||
: a. DRW relates the worth of the rod per increment of movement to rod position. IRW relates the total reactivity added by the rod to the rod position. | |||
: b. DRW relates the time rate of reactivity change to rod position. IRW relates the total reactivity in the core to the time rate of reactivity change. | |||
: c. IRW relates the worth of the rod per increment of movement to rod position. DRW relates the total reactivity added by the rod to the rod position. | |||
: d. IRW is the slope of the DRW at a given rod position QUESTION A.10 [1.0] | |||
Which one of the following is the reason for the steady-state period after a reactor scram? | |||
: a. -80 seconds, due to the decay of the longest lived delayed neutron precursor. | |||
: b. -56 seconds, due to the decay of the longest lived delayed neutron precursor. | |||
: c. 5 seconds, due to the rapid insertion of reactivity greater than eff. | |||
: d. -, due to the rapid insertion of reactivity greater than eff. | |||
QUESTION A.11 [1.0] | |||
Of the approximately 200 Mev of energy released per fission event, the largest amount appears in the form of: | Of the approximately 200 Mev of energy released per fission event, the largest amount appears in the form of: | ||
: a. Beta and gamma radiation | : a. Beta and gamma radiation | ||
: b. Prompt and delayed neutrons | : b. Prompt and delayed neutrons | ||
: c. Kinetic energy of the fission fragments | : c. Kinetic energy of the fission fragments | ||
: d. Alpha radiation | : d. Alpha radiation | ||
QUESTION | QUESTION A.12 [1.0] | ||
: a. 15 | The reactor is at 5 watts, when someone inserts an experiment which causes a 10 second positive period. If the scram delay time is 1 second and the lowest scram setpoint is 9.7 watts, which ONE of the following is the MAXIMUM power the reactor will reach prior to scramming? | ||
: d. | : a. 9.1 watts | ||
: b. 10.7 watts | |||
: c. 15.5 watts | |||
: d. 25 watts QUESTION A.13 [1.0] | |||
During a reactor startup, you insert Coarse Rod #1 in 5 equal steps of 8 cm. The reactor is still subcritical after the fifth step. Which one of the following statements best describes reactor behavior during these 5 rod insertions. | |||
: a. Each withdrawal added the same amount of reactivity. | |||
: b. For equal reactivity insertions, reactor power will increase the same amount. | |||
: c. The time for reactor power to stabilize after the fifth insertion is longer than the time after the first. | |||
: d. If you were to decrease the time between rod insertions, final critical rod height would decrease. | |||
QUESTION A.14 [1.0] | |||
Which ONE of the following is the DOMINANT factor in determining the differential reactivity worth of a control rod? | |||
: a. Radial and axial flux. | |||
: b. Total reactor power. | |||
: c. Control rod speed. | |||
: d. Delayed neutron fraction. | |||
QUESTION | QUESTION A.15 [1.0] | ||
The reactor is shutdown by 1.0% k/k and an experiment is placed into the glory hole. Count rate on the startup channel increased from 15 cps to 30 cps. What is the worth of the experiment? | |||
: a. positive 1.01% k/k | |||
: b. negative 1.01% k/k | |||
: c. positive 0.508% k/k | |||
: d. negative 0.508% k/k QUESTION A.16 [1.0] | |||
If Keff equals 1.0, how much reactivity must be added to the core to make the reactor prompt critical? | |||
: a. 10% K/K | |||
: b. 75% K/K | |||
: c. 10 K/K | |||
: d. 75 K/K QUESTION A.17 [1.0] | |||
What effect does Doppler Broadening for U-238 have on neutrons in a critical core? | |||
: a. More fission | |||
: b. More absorption | |||
: c. More scattering | |||
: d. More leakage QUESTION A.18 [1.0] | |||
While the reactor is shutdown you place an experiment into the glory hole to determine its worth. The reactor is shutdown by 2% K/K. Before insertion of the experiment, Channel #1 reads 70 cps. After insertion of the experiment, Channel #1 reads 35 cps. What is the worth of the experiment? | |||
: a. -2.1% K/K | |||
: b. -1.05% K/K | |||
: c. -0.21% K/K | |||
: d. -0.105% K/K | |||
(***** END OF CATEGORY A *****) | |||
closed? | QUESTION B.01 [1.0] | ||
Which one of the following is the correct value and reason for the minimum shield water temperature in the technical specifications? | |||
: a. 15°C. To limit the final power reached during a reactor excursion prior to the fuse melting. | |||
: b. 10°C. To limit the final power reached during a reactor excursion prior to the fuse melting. | |||
: c. 15°C. To limit the potential positive reactivity addition associated with a decrease in temperature. | |||
: d. 10°C. To limit the potential positive reactivity addition associated with a decrease in temperature. | |||
QUESTION B.02 [1.0] | |||
Which ONE of the following is the power level above which the thermal column door must be closed? | |||
: a. 0.01 watts | : a. 0.01 watts | ||
: b. 0.05 watts | : b. 0.05 watts | ||
: c. 0.1 watts | : c. 0.1 watts | ||
: d. 0.5 watts QUESTION B.03 [2.0, 0.5 each] Match the Area radiation levels in column A with the corresponding area type (as defined by 10 CFR 20) from column B. | : d. 0.5 watts QUESTION B.03 [2.0, 0.5 each] | ||
: a. 2 mr/hr | Match the Area radiation levels in column A with the corresponding area type (as defined by 10 CFR 20) from column B. (Some of the items in Col. B may be used more than once or not at all) | ||
: b. 5 mr/hr | Column A Column B | ||
: c. 10 mr/hr | : a. 2 mr/hr 1. Unrestricted | ||
: d. 100 mr/hr | : b. 5 mr/hr 2. Radiation Area | ||
: c. 10 mr/hr 3. High Radiation Area | |||
: d. 100 mr/hr 4. Very High Radiation Area | |||
QUESTION B. | QUESTION B.04 [2.0, 0.5 each] | ||
: a. | Match the operator license requirements in Column A with the proper time period from column B. | ||
: b. | Column A Column B | ||
: c. | : a. License Renewal 1 year | ||
: d. | : b. Medical Examination 2 years | ||
: c. Requalification Written Exam 4 years | |||
: d. Requalification Operating Test 6 years QUESTION B.05 [2.0, 0.5 each] | |||
Identify each of the following values as either a Safety Limit (SL), a Limited Safety Setting (LSSS) or a Limiting Condition for Operation (LCO). | |||
: a. Power 100 watts | |||
: b. Temperature 120 °C | |||
: c. Excess Reactivity 0.65% k/k (corrected to 20 °C) | |||
: d. Safety Rod with a reactivity addition rate of 0.065% k/k. | |||
QUESTION B.06 [1.0] | |||
Given the following information, calculate the half-life of the sample. | |||
Time (in minutes) Counts per minute 0 900 30 740 60 615 90 512 120 427 180 294 | |||
: a. 551 minutes | |||
: b. 122 minutes | |||
: c. 111 minutes | |||
: d. 100 minutes | |||
QUESTION B. | QUESTION B.07 [1.0] | ||
: a. | During a survey you read 100 mrem/hr with the window open and 40 mRem/hr with the window closed. Which ONE of the following is the dose rate due to GAMMA radiation? | ||
: c. | : a. 140 mRem/Hr | ||
QUESTION B. | : b. 100 mRem/Hr | ||
: a. | : c. 60 mRem/Hr | ||
: b. | : d. 40 mRem/Hr QUESTION B.08 [1.0] | ||
: | A channel test of Nuclear Safety Channels #1, #2 and #3 shall be performed prior to the first reactor startup of the day or prior to each reactor operation extending more than one day. This is an example of a(n): | ||
: d. | : a. safety limit. | ||
: b. limiting condition for operation. | |||
: c. limiting safety system setting. | |||
: d. surveillance requirement. | |||
QUESTION B.09 [1.0] | |||
Which ONE of the following is the basis for the maximum core temperature safety limit? | |||
: a. Prevent separation of the core. | |||
: b. Prevent melting of the polyethylene core material. | |||
: c. Prevent operating personnel from being exposed to high temperature. | |||
: d. Prevent spontaneous ignition of the graphite reflector. | |||
QUESTION B.10 [1.0] | |||
Prior to opening the core tank the reactor must be secured for | |||
: a. 12 hours | |||
: b. 24 hours | |||
: c. 2 days | |||
: d. 7 days | |||
QUESTION B.13 [1.0] | QUESTION B.11 [1.0] | ||
In the event of any emergency, if the radiation level outside of the operations area exceeds | |||
_______ mR/hr, the operator shall order an evacuation. | |||
: a. 10. | |||
: b. 50. | |||
: c. 75. | |||
: d. 100. | |||
QUESTION B.12 [1.0] | |||
In accordance with Emergency procedures, in the event of a fire, which ONE of the following actions should the reactor operator perform immediately after securing the reactor? | |||
: a. Notify the Pocatello Police Department. | |||
: b. Notify the U.S. NRC Operations Center. | |||
: c. Initiate a building evacuation. | |||
: d. Notify the Reactor Supervisor. | |||
QUESTION B.13 [1.0] | |||
The total scram withdrawal time of the coarse control rod and the safety rods must be less than: | The total scram withdrawal time of the coarse control rod and the safety rods must be less than: | ||
: a. 200 milliseconds. | : a. 200 milliseconds. | ||
: b. 500 milliseconds. | : b. 500 milliseconds. | ||
: c. 800 milliseconds. | : c. 800 milliseconds. | ||
: d. 1000 milliseconds. | : d. 1000 milliseconds. | ||
QUESTION B.14 [1.0] | |||
QUESTION B.14 [1.0] | You performed a startup this morning with the pneumatic tube terminus and no experiment in the reactor. After shutting down, one hour later, you removed the tube. No other changes were made to the reactor. During a new startup the new core excess will be | ||
You performed a startup this morning with the pneumatic tube terminus and no experiment in the reactor. After shutting down, one hour later, you removed the tube. No other changes were made to the reactor. During a new startup the new core excess will be | : a. larger than the previous startup. | ||
: a. larger than the previous startup. | : b. smaller than the previous startup. | ||
: b. smaller than the previous startup. | : c. the same as the previous startup. | ||
: c. the same as the previous startup. | : d. dependent on the time of shutdown. | ||
: d. dependent on the time of shutdown. | |||
QUESTION B.15 [1.0] | QUESTION B.15 [1.0] | ||
You have evacuated the EPZ. Which ONE of the following ISU staff positions is responsible (by title) for authorizing reentry? | You have evacuated the EPZ. Which ONE of the following ISU staff positions is responsible (by title) for authorizing reentry? | ||
: a. The Senior Reactor Operator | : a. The Senior Reactor Operator | ||
: b. The Reactor Supervisor | : b. The Reactor Supervisor | ||
: c. The Director of Emergency Operations | : c. The Director of Emergency Operations | ||
: d. The ISU Radiation Safety Officer | : d. The ISU Radiation Safety Officer | ||
(***** END OF CATEGORY B *****) | |||
QUESTION C.01 [1.0] | |||
QUESTION C.01 [1.0] | |||
Where would you go to deenergize the ventilation system during an emergency? | Where would you go to deenergize the ventilation system during an emergency? | ||
: a. On the reactor room wall opposite room 15 (Reactor Supervisor Office) | : a. On the reactor room wall opposite room 15 (Reactor Supervisor Office) | ||
: b. On the corridor wall just outside the door to room 23 (Subcritical Assembly Laboratory). | : b. On the corridor wall just outside the door to room 23 (Subcritical Assembly Laboratory). | ||
: c. On the corridor wall just outside the door to room 19 (Reactor Observation Room). | : c. On the corridor wall just outside the door to room 19 (Reactor Observation Room). | ||
: d. Just inside the door to room 22 (Counting Laboratory). | : d. Just inside the door to room 22 (Counting Laboratory). | ||
QUESTION C.02 [1.0] | |||
QUESTION C.02 [1.0] | |||
Which one of the following is the reason you rotate the Nuclear Instrumentation Channel #1 range switch counterclockwise after depressing the "RAISE" button? | Which one of the following is the reason you rotate the Nuclear Instrumentation Channel #1 range switch counterclockwise after depressing the "RAISE" button? | ||
: a. To prevent a reactor trip due to excessive period. | : a. To prevent a reactor trip due to excessive period. | ||
: b. To prevent a low level trip of the Safety Channel #1 sensitrol. | : b. To prevent a low level trip of the Safety Channel #1 sensitrol. | ||
: c. To compensate for control rod shadowing effects on Safety Channel #1, at higher power levels. d. To bring Safety Channel #1 readings into agreement with Safety Channels #2 and #3. | : c. To compensate for control rod shadowing effects on Safety Channel #1, at higher power levels. | ||
QUESTION C.03 [1.0] | : d. To bring Safety Channel #1 readings into agreement with Safety Channels #2 and #3. | ||
QUESTION C.03 [1.0] | |||
Which ONE of the following is NOT an interlock preventing rod insertion? | Which ONE of the following is NOT an interlock preventing rod insertion? | ||
: a. Both safety rods must be fully inserted prior to inserting the coarse control rod. | : a. Both safety rods must be fully inserted prior to inserting the coarse control rod. | ||
Line 372: | Line 394: | ||
: c. The coarse control rod must be fully withdrawn prior to inserting the safety rods. | : c. The coarse control rod must be fully withdrawn prior to inserting the safety rods. | ||
: d. The fine control rod must be greater than or equal to half inserted prior to inserting the safety rods. | : d. The fine control rod must be greater than or equal to half inserted prior to inserting the safety rods. | ||
QUESTION C.04 [1.0] | QUESTION C.04 [1.0] | ||
Which ONE of the following is the gas used in the rabbit tube assembly? | Which ONE of the following is the gas used in the rabbit tube assembly? | ||
: a. Air | : a. Air | ||
: b. Carbon Dioxide | : b. Carbon Dioxide | ||
: c. Helium | : c. Helium | ||
: d. Nitrogen | : d. Nitrogen | ||
QUESTION C.05 [1.0] | QUESTION C.05 [1.0] | ||
Which ONE of the following signals will result in opening the interlock bus? | Which ONE of the following signals will result in opening the interlock bus? | ||
: a. Manual scram switch | : a. Manual scram switch | ||
: b. Period trip | : b. Period trip | ||
: c. Earthquake sensor | : c. Earthquake sensor | ||
: d. Channel #1 high (95% full scale) | : d. Channel #1 high (95% full scale) | ||
QUESTION C.06 [1.0] | |||
QUESTION C.06 [1.0] | |||
Which one of the following detectors is used for Nuclear Instrumentation Channel #2? | Which one of the following detectors is used for Nuclear Instrumentation Channel #2? | ||
: a. | : a. BF3 filled Proportional Counter | ||
: b. | : b. BF3 filled Ionization Chamber | ||
: c. | : c. BF3 filled Geiger-Muller tuber | ||
: d. U235 lined Fission Chamber QUESTION C.07 [1.0] | : d. U235 lined Fission Chamber QUESTION C.07 [1.0] | ||
Which ONE of the following statements correctly completes the sentence concerning the access ports? | Which ONE of the following statements correctly completes the sentence concerning the access ports? The access ports | ||
: a. penetrate through the shield tank, passing by the reflector and the lead shield. | : a. penetrate through the shield tank, passing by the reflector and the lead shield. | ||
: b. pass through the shield tank up to the lead shield | : b. pass through the shield tank up to the lead shield | ||
: c. pass through the shield tank, lead shield and the reflector up to the core container. | : c. pass through the shield tank, lead shield and the reflector up to the core container. | ||
: d. pass through the shield tank up to the reflector | : d. pass through the shield tank up to the reflector QUESTION C.08 [1.0] | ||
QUESTION C.08 [1.0] | |||
The reactor is critical, with the Fine Control Rod (FCR) fully inserted. If you wish to reposition the FCR to the mid-plane of its travel, how far and in what direction must you move the Coarse Control Rod (CCR), maintaining critical conditions? | The reactor is critical, with the Fine Control Rod (FCR) fully inserted. If you wish to reposition the FCR to the mid-plane of its travel, how far and in what direction must you move the Coarse Control Rod (CCR), maintaining critical conditions? | ||
: a. 6.7 cm, out of core | : a. 6.7 cm, out of core | ||
: b. 3.3 cm, into core | : b. 3.3 cm, into core | ||
: c. 3.3 cm, out of core | : c. 3.3 cm, out of core | ||
: d. 6.7 cm, into core | : d. 6.7 cm, into core | ||
QUESTION C.09 [1.0] | QUESTION C.09 [1.0] | ||
The Low Level Interlock is controlled by power level indication from: | The Low Level Interlock is controlled by power level indication from: | ||
: a. Channel 1. | : a. Channel 1. | ||
: b. Channel 2. | : b. Channel 2. | ||
: c. Channel 3. | : c. Channel 3. | ||
: d. Auxiliary Channel. | : d. Auxiliary Channel. | ||
QUESTION C.10 [1.0] | |||
QUESTION C.10 [1.0] | |||
Which ONE of the following conditions will prevent the operator from inserting the control rods into the core? | Which ONE of the following conditions will prevent the operator from inserting the control rods into the core? | ||
: a. Shielding water less than 1 inch from the manhole opening. | : a. Shielding water less than 1 inch from the manhole opening. | ||
: b. Earthquake of negligible horizontal amplitude. | : b. Earthquake of negligible horizontal amplitude. | ||
: c. Water temperature of 20 oC. | : c. Water temperature of 20 oC. | ||
: d. Channel #1 reset button depressed. | : d. Channel #1 reset button depressed. | ||
QUESTION C.11 [1.0] | |||
QUESTION C.11 [1.0] | |||
The U-235 fuel in the AGN is contained in fuel disks and control rods. Of the total fuel in the reactor, approximately how much is contained in the control and safety rods? | The U-235 fuel in the AGN is contained in fuel disks and control rods. Of the total fuel in the reactor, approximately how much is contained in the control and safety rods? | ||
: a. 9%. b. 24%. | : a. 9%. | ||
: c. 55% | : b. 24%. | ||
: c. 55% | |||
QUESTION C.12 [1.0] | : d. 78%. | ||
QUESTION C.12 [1.0] | |||
Which ONE of the following describes the design purpose of the space in the top section of the core tank above the reactor core and the reflector? | Which ONE of the following describes the design purpose of the space in the top section of the core tank above the reactor core and the reflector? | ||
: a. Ensures free fall of the bottom half of the core during the most severe transient. | : a. Ensures free fall of the bottom half of the core during the most severe transient. | ||
: b. Increases the fast neutron population in the vicinity of experiments placed in the access ports. c. Allows for accumulation of fission product gases created during reactor operation. | : b. Increases the fast neutron population in the vicinity of experiments placed in the access ports. | ||
: d. Prevents core damage during the design basis earthquake and 6 cm. displacements. | : c. Allows for accumulation of fission product gases created during reactor operation. | ||
: d. Prevents core damage during the design basis earthquake and 6 cm. displacements. | |||
QUESTION C.13 [1.0] | QUESTION C.13 [1.0] | ||
Which ONE of the following does NOT automatically cause a reactor scram? | Which ONE of the following does NOT automatically cause a reactor scram? | ||
: a. Reactor period. | : a. Reactor period. | ||
: b. Radiation level. | : b. Radiation level. | ||
: c. Water level. | : c. Water level. | ||
: d. Power failure. | : d. Power failure. | ||
QUESTION C.14 [1.0] | |||
QUESTION C.14 [1.0] | |||
Which one of the following materials will have a positive effect on reactivity when inserted into the Glory Hole? | Which one of the following materials will have a positive effect on reactivity when inserted into the Glory Hole? | ||
: a. Borated Polyethylene | : a. Borated Polyethylene | ||
: b. Polyethylene | : b. Polyethylene | ||
: c. Natural Uranium | : c. Natural Uranium | ||
: d. Gold | : d. Gold QUESTION C.15 [1.0] | ||
When using the movable tank on the top of the reactor as a Thermal Neutron column, it is filled with | When using the movable tank on the top of the reactor as a Thermal Neutron column, it is filled with | ||
: a. Water | |||
: b. Beryllium | : b. Beryllium | ||
: c. Graphite | : c. Graphite | ||
: d. Heavy Water | : d. Heavy Water | ||
(***** END OF CATEGORY C *****) | |||
(********** END OF EXAMINATION **********) | |||
SECTION A. RX THEORY, THERMO & FAC OP CHARS A.01 a REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 78. | SECTION A. RX THEORY, THERMO & FAC OP CHARS A.01 a REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 78. | ||
A.02 a REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 346. | A.02 a REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 346. | ||
A.03 d REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 329. | A.03 d REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 329. | ||
A.04 d REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 312. | A.04 d REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 312. | ||
A.05 c REF: SUR (in decades per minute) = 26.06/ OR ln ( | A.05 c REF: SUR (in decades per minute) = 26.06/ OR ln (P0/P) = t/ ln(10) = time/25 2.302585092994 = time/25 seconds. time = 2.3026 x 25 = 57.6 seconds or 1 minute A.06 d REF: Safety Analysis Report, dated November 23, 1995, pg. 104. | ||
A.07 b or d REF: Glasstone S, and Sesonske, A, Nuclear Reactor Engineering, Kreiger Publishing, Malabar, Florida, 1991, §§ 2.70 | A.07 b or d REF: Glasstone S, and Sesonske, A, Nuclear Reactor Engineering, Kreiger Publishing, Malabar, Florida, 1991, §§ 2.70 2.74, pp. 65 66. | ||
A.08 c REF: Lamarsh, Introduction To Nuclear Engineering, 3rd Edition. | |||
A.08 c REF: Lamarsh, Introduction To Nuclear Engineering, 3rd Edition. ( | (CR2/CR1) = (1-Keff0)/(1-Keff1) (60/30) = (0.90)(1-Keff1) Keff1 = 0.95 A.09 a REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 361, 362. | ||
A.10 a REF: Lamarsh, J.R., Introduction to Nuclear Engineering, Addison-Wesley Publishing, Reading, Massachusetts, 1983, § 7.1, p. 289. | |||
A.09 a REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 361, 362. | |||
A.10 a REF: Lamarsh, J.R., Introduction to Nuclear Engineering, Addison-Wesley Publishing, Reading, Massachusetts, 1983, § 7.1, p. 289. | |||
SECTION A. RX THEORY, THERMO & FAC OP CHARS A.11 c REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 88. | SECTION A. RX THEORY, THERMO & FAC OP CHARS A.11 c REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 88. | ||
A.12 b REF: Glasstone, S. & Sesonske, , § 5.18 | A.12 b REF: Glasstone, S. & Sesonske, , § 5.18 P = P0 et/ = 9.7 x e1/10 = 9.7 x 1.1052 = 10.72 A.13 c REF: Lamarsh does not cover reactor characteristics for approach to critical. | ||
A.14 a REF: Glasstone, S. And Sesonske, A, § 5.225. | A.14 a REF: Glasstone, S. And Sesonske, A, § 5.225. | ||
A.15 c REF: SDM = 1 - Keff/Keff or Keff = 1/(1 + SDM) = 1/(1 + .01) = 0.990 CR1/CR2 = (1 - Keff2)/(1 - Keff1) or 1 - Keff2 = (1 - Keff1) CR1/CR2 = 0.0099 (15/30) = .00495 1 - Keff2 = 0.00495 Keff = 1 - 0.00495 = 0.995 Reactivity Added = (Keff1 - Keff2)/Keff1Keff2 = (0.990 - 0.995)/(0.995 x 0.990) = | |||
A.15 c REF: SDM = 1 - | 0.005076 (positive) or 0.508% | ||
A.16 b REF: Lamarsh, J.R., Introduction to Nuclear Engineering, Addison-Wesley Publishing, Reading, Massachusetts, 1983, § 7.1, pp. 286 | A.16 b REF: Lamarsh, J.R., Introduction to Nuclear Engineering, Addison-Wesley Publishing, Reading, Massachusetts, 1983, § 7.1, pp. 286 287. | ||
A.17 b REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 369. | A.17 b REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 369. | ||
A.18 a REF: SDM = (1 - Keff)/Keff Keff = 1/(1 + SDM) Given SDM = 0.2 Keff = 1/(1 + 0.2) = 1/1.02 Initial Keff = .9804 CR1/ CR2 = (1 - Keff1)/(1 - Keff2) Rearranging: Keff2 = 1 - (1 - Keff1) x CR2/CR1 Keff2 = 1 - [(1 - 0.9804) x 35/70] = 1 - 0.0196 x 2 = 1 - 0.0392 = 0.9608 | |||
A.18 a REF: SDM = (1 - | = (Keff2 -Keff1)/Keff2 Keff2 = (0.9804 - 0.9608)/(0.9804 x 0.9608) = 0.0196/ 0.94197 | ||
= 0.02081 | |||
SECTION B. NORMAL/EMERG PROCEDURES & RAD CON B.01 c REF: ISU Technical Specifications § 3.2, p. 10 B.02 d REF: ISU TS § 3.4 B.03 a, 1; b, 2; c, 2; d, 3 REF: 10 CFR 20 § 20.1003 Definitions B.04 a, 6; b, 2; c, 2 or 1; d, 1 ISU Requal plan has yearly written. | |||
REF: 10 CFR 55.21, 10 CFR 55.55, 10 CFR 55.59, ISU Requalification Plan B.05 a, SL; b, LSSS; c, LCO; d, LCO REF: ISU TS §§ 2.1, 2.2 and 3.0 B.06 c REF: | |||
A ~=~ A_0 e^{lambda(t)}~~~~ 294 ~=~ 900`e^{lambda `180} ~~~ {ln left( 294 over 900 right)} over 180 ~=~ lambda ~ = ~0.00621 # | |||
{ln(0.5)} over {0.00621} ~=~ 111 B.07 d REF: Dose () = Dose with window closed B.08 d REF: ISU Technical Specification 4.2.c B.09 b REF: ISU Technical Specification 2.1.b B.10 b REF: Maintenance Procedure #2 Prerequisites and Safety B.11 a REF: ISU Emerg. Plan Sect C.6 B.12 c REF: Emergency Plan, Section 4, Fire or Explosion B.13 d REF: ISU Technical Specification 3.2.a B.14 c REF: ISU Experimental Plan No. 19 Sample Transfer by Pneumatic Tube, Safety Analysis p. 3 B.15 c REF: Emergency Plan, Nuclear Emergency p. 13. | |||
C.13 b REF: Safety Analysis Report, dated November 23, 1995, pg. 57. | SECTION C. PLANT AND RAD MONITORING SYSTEMS C.01 a REF: Emergency Plan, Section 7.3.2 C.02 b REF: ISU OP-1 Chap. V Startup Step A.3 C.03 d REF: ISU SAR § 4.3.1 Control Rods C.04 d REF: NRC examination bank C.05 c REF: NRC Examination Question Bank C.06 b REF: ISU SAR § 4,3,2, p. 61 C.07 c REF: NRC Examination Question Bank C.08 b REF: NRC Examination Question Bank C.09 a REF: Safety Analysis Report, dated November 23, 1995, pg. 58 C.10 d REF: Safety Analysis Report, dated November 23, 1995, pg. 69 C.11 a REF: Safety Analysis Report, dated November 23, 1995, pg. 46-47 C.12 c REF: Safety Analysis Report, dated November 23, 1995, pg. 41 C.13 b REF: Safety Analysis Report, dated November 23, 1995, pg. 57. | ||
C.14 b REF: NRC Examination Question Bank C.15 c REF: ISU SAR, § 4.1}} | C.14 b REF: NRC Examination Question Bank C.15 c REF: ISU SAR, § 4.1}} |
Latest revision as of 16:23, 10 March 2020
ML112420716 | |
Person / Time | |
---|---|
Site: | Idaho State University |
Issue date: | 09/09/2011 |
From: | Johnny Eads Research and Test Reactors Branch B |
To: | Kunze J Idaho State University |
Isaac P, NRC/NRR/DPR/PROB | |
References | |
50-284/OL-11-001 | |
Download: ML112420716 (28) | |
Text
September 9, 2011 Dr. Jay F. Kunze Idaho State University 833 South Eighth Street Pocatello, ID 83209
SUBJECT:
EXAMINATION REPORT NO. 50-284/OL-11-01, IDAHO STATE UNIVERSITY
Dear Dr. Kunze:
During the week of July 25, 2011, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examination at your Idaho State University AGN reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2, published in June 2007. Examination questions and preliminary findings were discussed at the conclusion of the examination with those members of your staff identified in the enclosed report.
In accordance with Title 10, Section 2.390 of the Code of Federal Regulations, a copy of this letter and the enclosures will be available electronically for public inspection in the NRC Public Document Room or from the Publicly Available Records (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS). ADAMS is accessible from the NRC Web site at http://www.nrc.gov/reading-rm/adams.html (the Public Electronic Reading Room). The NRC is forwarding the individual grades to you in a separate letter which will not be released publicly. If you have any questions concerning this examination, please contact Patrick Isaac at 301-415-1019 or via email at patrick.isaac@nrc.gov.
Sincerely,
/RA/
Johnny H. Eads, Jr., Chief Research and Test Reactors Oversight Branch Division of Policy and Rulemaking Office of Nuclear Reactor Regulation Docket No. 50-284
Enclosures:
- 1. Examination Report No. 50-284/OL-11-01
- 2. Corrected Written Examination cc: Adam Mallicoat, Reactor Supervisor, Idaho State University cc: w/o enclosures: See next page
September 9, 2011 Dr. Jay F. Kunze Idaho State University 833 South Eighth Street Pocatello, ID 83209
SUBJECT:
EXAMINATION REPORT NO. 50-284/OL-11-01, IDAHO STATE UNIVERSITY
Dear Dr. Kunze:
During the week of July 25, 2011, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examination at your Idaho State University AGN reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2, published in June 2007. Examination questions and preliminary findings were discussed at the conclusion of the examination with those members of your staff identified in the enclosed report.
In accordance with Title 10, Section 2.390 of the Code of Federal Regulations, a copy of this letter and the enclosures will be available electronically for public inspection in the NRC Public Document Room or from the Publicly Available Records (PARS) component of NRC's Agencywide Documents Access and Management System (ADAMS). ADAMS is accessible from the NRC Web site at http://www.nrc.gov/reading-rm/adams.html (the Public Electronic Reading Room). The NRC is forwarding the individual grades to you in a separate letter which will not be released publicly. If you have any questions concerning this examination, please contact Patrick Isaac at 301-415-1019 or via email at patrick.isaac@nrc.gov.
Sincerely,
/RA/
Johnny H. Eads, Jr., Chief Research and Test Reactors Oversight Branch Division of Policy and Rulemaking Office of Nuclear Reactor Regulation Docket No. 50-284
Enclosures:
- 1. Examination Report No. 50-284/OL-11-01
- 2. Corrected Written Examination cc: Adam Mallicoat, Reactor Supervisor, Idaho State University cc: w/o enclosures: See next page DISTRIBUTION w/ encls.:
PUBLIC PROB r/f JEads Facility File (CRevelle)
ADAMS ACCESSION #: ML112420716 OFFICE PROB:CE IOLB:LA PROB:BC NAME PIsaac CRevelle JEads DATE 08/30/11 09/09/11 9/9/11 OFFICIAL RECORD COPY
Idaho State University Docket No. 50-284 cc:
Idaho State University ATTN: Dr. Richard T. Jacobsen College of Engineering Dean Campus Box 8060 Pocatello, ID 83209-8060 Idaho State University ATTN: Dr. Richard R. Brey Radiation Safety Officer Physics Department Box 8106 Pocatello, ID 83209-8106 Toni Hardesty, Director Idaho Dept. of Environmental Quality 1410 North Hilton Boise, ID 83606 Test, Research and Training Reactor Newsletter 202 Nuclear Sciences Center University of Florida Gainesville, FL 32611
EXAMINATION REPORT NO: 50-284/OL-11-01 FACILITY: Idaho State University FACILITY DOCKET NO.: 50-284 FACILITY LICENSE NO.: R-110 SUBMITTED BY: _______/JNguyen for RA/_______ __9/9/11___
Patrick J. Isaac, Chief Examiner Date
SUMMARY
During the week of July 25, 2011, the NRC administered operator licensing examinations to one Senior Reactor Operator Instant (SROI), one Senior Reactor Operator Upgrade, and two Reactor Operator candidates. The SROI candidate failed the examinations. All other candidates passed the examinations and have been issued a license to operate the Idaho State University reactor.
REPORT DETAILS
- 1. Examiner: Patrick J. Isaac, Chief Examiner
- 2. Results:
RO PASS/FAIL SRO PASS/FAIL TOTAL PASS/FAIL Written 2/0 0/1 2/1 Operating Tests 2/0 1/1 3/1 Overall 2/0 1/1 3/1
- 3. Exit Meeting:
Adam Mallicoat, Idaho State University Patrick Isaac, NRC, Examiner The NRC Examiner thanked the facility for their support in the administration of the examinations and agreed to make the following changes to the written examination:
Question A.7 - Accept both answers b and d as correct.
Question C.14 - Accept b as the correct answer
U. S. NUCLEAR REGULATORY COMMISSION NON-POWER INITIAL REACTOR LICENSE EXAMINATION FACILITY: Idaho State University REACTOR TYPE: AGN-201 DATE ADMINISTERED: July 25, 2011 CANDIDATE: _____________________________
INSTRUCTIONS TO CANDIDATE:
Answers are to be written on the Answer sheet provided. Attach all Answer sheets to the examination. Point values are indicated in parentheses for each question. A 70% in each category is required to pass the examination. Examinations will be picked up three (3) hours after the examination starts.
% OF CATEGORY % OF CANDIDATE'S CATEGORY VALUE TOTAL SCORE VALUE CATEGORY 18.00 35.3 A. REACTOR THEORY, THERMODYNAMICS AND FACILITY OPERATING CHARACTERISTICS 18.00 35.3 B. NORMAL AND EMERGENCY OPERATING PROCEDURES AND RADIOLOGICAL CONTROLS 15.00 29.4 C. FACILITY AND RADIATION MONITORING SYSTEMS 51.00 % TOTALS FINAL GRADE All work done on this examination is my own. I have neither given nor received aid.
Candidate's Signature
A. RX THEORY, THERMO & FAC OP CHARS ANSWER SHEET Multiple Choice (Circle or X your choice)
If you change your Answer, write your selection in the blank.
001 a b c d ___
002 a b c d ___
003 a b c d ___
004 a b c d ___
005 a b c d ___
006 a b c d ___
007 a b c d ___
008 a b c d ___
009 a b c d ___
010 a b c d ___
011 a b c d ___
012 a b c d ___
013 a b c d ___
014 a b c d ___
015 a b c d ___
016 a b c d ___
017 a b c d ___
018 a b c d ___
(***** END OF CATEGORY A *****)
B. NORMAL/EMERG PROCEDURES & RAD CON ANSWER SHEET Multiple Choice (Circle or X your choice)
If you change your Answer, write your selection in the blank.
001 a b c d ___
002 a b c d ___
003 a ___ b ___ c ___ d ___
004 a ___ b ___ c ___ d ___
005 a ___ b ___ c ___ d ___
006 a b c d ___
007 a b c d ___
008 a b c d ___
009 a b c d ___
010 a b c d ___
011 a b c d ___
012 a b c d ___
013 a b c d ___
014 a b c d ___
015 a b c d ___
(***** END OF CATEGORY B *****)
C. PLANT AND RAD MONITORING SYSTEMS ANSWER SHEET Multiple Choice (Circle or X your choice)
If you change your Answer, write your selection in the blank.
001 a b c d ___
002 a b c d ___
003 a b c d ___
004 a b c d ___
005 a b c d ___
006 a b c d ___
007 a b c d ___
008 a b c d ___
009 a b c d ___
010 a b c d ___
011 a b c d ___
012 a b c d ___
013 a b c d ___
014 a b c d ___
015 a b c d ___
(***** END OF CATEGORY C *****)
(********** END OF EXAMINATION **********)
NRC RULES AND GUIDELINES FOR LICENSE EXAMINATIONS During the administration of this examination the following rules apply:
- 1. Cheating on the examination means an automatic denial of your application and could result in more severe penalties.
- 2. After the examination has been completed, you must sign the statement on the cover sheet indicating that the work is your own and you have neither received nor given assistance in completing the examination. This must be done after you complete the examination.
- 3. Restroom trips are to be limited and only one candidate at a time may leave. You must avoid all contacts with anyone outside the examination room to avoid even the appearance or possibility of cheating.
- 4. Use black ink or dark pencil only to facilitate legible reproductions.
- 5. Print your name in the blank provided in the upper right-hand corner of the examination cover sheet and each Answer sheet.
- 6. Mark your Answers on the Answer sheet provided. USE ONLY THE PAPER PROVIDED AND DO NOT WRITE ON THE BACK SIDE OF THE PAGE.
- 7. The point value for each question is indicated in [brackets] after the question.
- 8. If the intent of a question is unclear, ask questions of the examiner only.
- 9. When turning in your examination, assemble the completed examination with examination questions, examination aids and Answer sheets. In addition turn in all scrap paper.
- 10. Ensure all information you wish to have evaluated as part of your Answer is on your Answer sheet. Scrap paper will be disposed of immediately following the examination.
- 11. To pass the examination you must achieve a grade of 70 percent or greater in each category.
- 12. There is a time limit of three (3) hours for completion of the examination.
EQUATION SHEET
Pmax =
( )2 eff = 0.1sec 1 Q& = m& c P T = m& H =UAT (2 l )
t P = P0 e S S SCR = l* =1x10 4 sec 1 K eff eff + &
SUR = 26 .06
( ) (
CR1 1 K eff1 = CR2 1 K eff 2 ) CR1 ( 1 ) = CR2 ( 2 )
(1 ) M=
1 CR
= 2 P = P0 10SUR(t )
P= P0 1 K eff CR1 1 K eff1 1 K eff l*
M= SDM = =
1 K eff 2 K eff l* 0.693 K eff 2 K eff1
+ T1 =
eff + & 2 K eff1 K eff 2 K eff 1
= DR = DR0 e t 2 DR1 d1 = DR2 d 2 2
K eff
)
6 Ci E (n )
DR =
R2 DR - Rem/hr, Ci - curies, E - Mev, R - feet 1 Curie = 3.7 x 1010 dis/sec 1 kg = 2.21 lbm 1 Horsepower = 2.54 x 103 BTU/hr 1 Mw = 3.41 x 106 BTU/hr 1 BTU = 778 ft-lbf °F = 9/5 °C + 32 1 gal (H2O) 8 lbm °C = 5/9 (°F - 32) cP = 1.0 BTU/hr/lbm/°F cp = 1 cal/sec/gm/°C
QUESTION A.01 [1.0]
Which ONE of the following neutrons would result in the highest probability of fission for 235U?
- a. Thermal neutron (0.025 eV)
- b. Epi-Thermal neutron (1 eV)
- c. Prompt neutron (0.7 MeV)
- d. Fast neutron (2 MeV)
QUESTION A.02 [1.0]
Which of the following power manipulations would take the longest to complete assuming the same period is maintained?
- a. 100 mW to 400 mW
- b. 400 mW to 500 mW
- c. 1 W to 3.5 W
- d. 3.5 W to 4.5 W QUESTION A.03 [1.0]
A critical reactor is operating at a steady-state power level of 1.00 W. Reactor power is increased to a new steady-state power level of 1.05 W. Neglecting any temperature effects, what reactivity insertion is required to accomplish this?
- a. 0.05 delta k/k.
- b. 5.0% delta k/k.
- c. 1.05% delta k/k.
- d. Indeterminate, since any amount of positive reactivity could be used.
QUESTION A.04 [1.0]
Which ONE of the following factors in the six-factor formula can be varied by the reactor operator?
- a. Fast fission factor.
- b. Reproduction factor.
- c. Fast non-leakage factor.
- d. Thermal utilization factor.
QUESTION A.05 [1.0]
If reactor period () is at 25 seconds, approximately how long will it take for reactor power to increase by a factor of 10?
- a. 10 seconds
- b. 25 seconds
- c. 1 minute
- d. 3 minutes QUESTION A.06 [1.0]
The AGN-201 is designed to produce a fission rate within the thermal fuse that is approximately twice the average of the core. Which ONE of the following describes how this higher reaction rate is accomplished?
- a. The polystyrene media used in the thermal fuse is a better moderator, raising the thermal flux in the fuse area.
- b. The non-uniform fuel loading in the upper fuel disc increases the thermal flux in fuse area.
- c. The fuel enrichment used in the thermal fuse is twice that of the balance of the core resulting in a higher fission rate in the fuse area.
- d. The fuel density used in the thermal fuse is twice that of the balance of the core resulting in a higher fission rate in the fuse area.
QUESTION A.07 [1.0]
Which one of the following is the purpose of having an installed neutron source?
- a. To compensate for neutrons absorbed by experiments installed into the reactor.
- b. To generate a sufficient neutron population to start a fission chain for reactor startup.
- c. To provide for a means to allow reactivity changes to occur in a subcritical reactor.
- d. To generate a detectable neutron level for monitoring reactivity changes in a shutdown reactor.
QUESTION A.08 [1.0]
At the beginning of a reactor startup, Keff is 0.90 with a count rate of 30 CPS. Power is increased to a new, steady value of 60 CPS. The new Keff is:
- a. 0.91
- b. 0.925
- c. 0.95
- d. 0.975 QUESTION A.09 [1.0]
Which ONE of the following statements describes the difference between Differential (DRW) and Integral (IRW) rod worth curves?
- a. DRW relates the worth of the rod per increment of movement to rod position. IRW relates the total reactivity added by the rod to the rod position.
- b. DRW relates the time rate of reactivity change to rod position. IRW relates the total reactivity in the core to the time rate of reactivity change.
- c. IRW relates the worth of the rod per increment of movement to rod position. DRW relates the total reactivity added by the rod to the rod position.
- d. IRW is the slope of the DRW at a given rod position QUESTION A.10 [1.0]
Which one of the following is the reason for the steady-state period after a reactor scram?
- a. -80 seconds, due to the decay of the longest lived delayed neutron precursor.
- b. -56 seconds, due to the decay of the longest lived delayed neutron precursor.
- c. 5 seconds, due to the rapid insertion of reactivity greater than eff.
- d. -, due to the rapid insertion of reactivity greater than eff.
QUESTION A.11 [1.0]
Of the approximately 200 Mev of energy released per fission event, the largest amount appears in the form of:
- a. Beta and gamma radiation
- b. Prompt and delayed neutrons
- c. Kinetic energy of the fission fragments
- d. Alpha radiation
QUESTION A.12 [1.0]
The reactor is at 5 watts, when someone inserts an experiment which causes a 10 second positive period. If the scram delay time is 1 second and the lowest scram setpoint is 9.7 watts, which ONE of the following is the MAXIMUM power the reactor will reach prior to scramming?
- a. 9.1 watts
- b. 10.7 watts
- c. 15.5 watts
- d. 25 watts QUESTION A.13 [1.0]
During a reactor startup, you insert Coarse Rod #1 in 5 equal steps of 8 cm. The reactor is still subcritical after the fifth step. Which one of the following statements best describes reactor behavior during these 5 rod insertions.
- a. Each withdrawal added the same amount of reactivity.
- b. For equal reactivity insertions, reactor power will increase the same amount.
- c. The time for reactor power to stabilize after the fifth insertion is longer than the time after the first.
- d. If you were to decrease the time between rod insertions, final critical rod height would decrease.
QUESTION A.14 [1.0]
Which ONE of the following is the DOMINANT factor in determining the differential reactivity worth of a control rod?
- a. Radial and axial flux.
- b. Total reactor power.
- c. Control rod speed.
- d. Delayed neutron fraction.
QUESTION A.15 [1.0]
The reactor is shutdown by 1.0% k/k and an experiment is placed into the glory hole. Count rate on the startup channel increased from 15 cps to 30 cps. What is the worth of the experiment?
- a. positive 1.01% k/k
- b. negative 1.01% k/k
- c. positive 0.508% k/k
- d. negative 0.508% k/k QUESTION A.16 [1.0]
If Keff equals 1.0, how much reactivity must be added to the core to make the reactor prompt critical?
- a. 10% K/K
- b. 75% K/K
- c. 10 K/K
- d. 75 K/K QUESTION A.17 [1.0]
What effect does Doppler Broadening for U-238 have on neutrons in a critical core?
- a. More fission
- b. More absorption
- c. More scattering
- d. More leakage QUESTION A.18 [1.0]
While the reactor is shutdown you place an experiment into the glory hole to determine its worth. The reactor is shutdown by 2% K/K. Before insertion of the experiment, Channel #1 reads 70 cps. After insertion of the experiment, Channel #1 reads 35 cps. What is the worth of the experiment?
- a. -2.1% K/K
- b. -1.05% K/K
- c. -0.21% K/K
- d. -0.105% K/K
(***** END OF CATEGORY A *****)
QUESTION B.01 [1.0]
Which one of the following is the correct value and reason for the minimum shield water temperature in the technical specifications?
- a. 15°C. To limit the final power reached during a reactor excursion prior to the fuse melting.
- b. 10°C. To limit the final power reached during a reactor excursion prior to the fuse melting.
- c. 15°C. To limit the potential positive reactivity addition associated with a decrease in temperature.
- d. 10°C. To limit the potential positive reactivity addition associated with a decrease in temperature.
QUESTION B.02 [1.0]
Which ONE of the following is the power level above which the thermal column door must be closed?
- a. 0.01 watts
- b. 0.05 watts
- c. 0.1 watts
- d. 0.5 watts QUESTION B.03 [2.0, 0.5 each]
Match the Area radiation levels in column A with the corresponding area type (as defined by 10 CFR 20) from column B. (Some of the items in Col. B may be used more than once or not at all)
Column A Column B
- a. 2 mr/hr 1. Unrestricted
- b. 5 mr/hr 2. Radiation Area
- c. 10 mr/hr 3. High Radiation Area
- d. 100 mr/hr 4. Very High Radiation Area
QUESTION B.04 [2.0, 0.5 each]
Match the operator license requirements in Column A with the proper time period from column B.
Column A Column B
- a. License Renewal 1 year
- b. Medical Examination 2 years
- c. Requalification Written Exam 4 years
- d. Requalification Operating Test 6 years QUESTION B.05 [2.0, 0.5 each]
Identify each of the following values as either a Safety Limit (SL), a Limited Safety Setting (LSSS) or a Limiting Condition for Operation (LCO).
- a. Power 100 watts
- b. Temperature 120 °C
- c. Excess Reactivity 0.65% k/k (corrected to 20 °C)
- d. Safety Rod with a reactivity addition rate of 0.065% k/k.
QUESTION B.06 [1.0]
Given the following information, calculate the half-life of the sample.
Time (in minutes) Counts per minute 0 900 30 740 60 615 90 512 120 427 180 294
- a. 551 minutes
- b. 122 minutes
- c. 111 minutes
- d. 100 minutes
QUESTION B.07 [1.0]
During a survey you read 100 mrem/hr with the window open and 40 mRem/hr with the window closed. Which ONE of the following is the dose rate due to GAMMA radiation?
- a. 140 mRem/Hr
- b. 100 mRem/Hr
- c. 60 mRem/Hr
- d. 40 mRem/Hr QUESTION B.08 [1.0]
A channel test of Nuclear Safety Channels #1, #2 and #3 shall be performed prior to the first reactor startup of the day or prior to each reactor operation extending more than one day. This is an example of a(n):
- a. safety limit.
- b. limiting condition for operation.
- c. limiting safety system setting.
- d. surveillance requirement.
QUESTION B.09 [1.0]
Which ONE of the following is the basis for the maximum core temperature safety limit?
- a. Prevent separation of the core.
- b. Prevent melting of the polyethylene core material.
- c. Prevent operating personnel from being exposed to high temperature.
- d. Prevent spontaneous ignition of the graphite reflector.
QUESTION B.10 [1.0]
Prior to opening the core tank the reactor must be secured for
- a. 12 hours1.388889e-4 days <br />0.00333 hours <br />1.984127e-5 weeks <br />4.566e-6 months <br />
- b. 24 hours2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br />
- c. 2 days
- d. 7 days
QUESTION B.11 [1.0]
In the event of any emergency, if the radiation level outside of the operations area exceeds
_______ mR/hr, the operator shall order an evacuation.
- a. 10.
- b. 50.
- c. 75.
- d. 100.
QUESTION B.12 [1.0]
In accordance with Emergency procedures, in the event of a fire, which ONE of the following actions should the reactor operator perform immediately after securing the reactor?
- a. Notify the Pocatello Police Department.
- b. Notify the U.S. NRC Operations Center.
- c. Initiate a building evacuation.
- d. Notify the Reactor Supervisor.
QUESTION B.13 [1.0]
The total scram withdrawal time of the coarse control rod and the safety rods must be less than:
- a. 200 milliseconds.
- b. 500 milliseconds.
- c. 800 milliseconds.
- d. 1000 milliseconds.
QUESTION B.14 [1.0]
You performed a startup this morning with the pneumatic tube terminus and no experiment in the reactor. After shutting down, one hour later, you removed the tube. No other changes were made to the reactor. During a new startup the new core excess will be
- a. larger than the previous startup.
- b. smaller than the previous startup.
- c. the same as the previous startup.
- d. dependent on the time of shutdown.
QUESTION B.15 [1.0]
You have evacuated the EPZ. Which ONE of the following ISU staff positions is responsible (by title) for authorizing reentry?
- a. The Senior Reactor Operator
- b. The Reactor Supervisor
- c. The Director of Emergency Operations
- d. The ISU Radiation Safety Officer
(***** END OF CATEGORY B *****)
QUESTION C.01 [1.0]
Where would you go to deenergize the ventilation system during an emergency?
- a. On the reactor room wall opposite room 15 (Reactor Supervisor Office)
- b. On the corridor wall just outside the door to room 23 (Subcritical Assembly Laboratory).
- c. On the corridor wall just outside the door to room 19 (Reactor Observation Room).
- d. Just inside the door to room 22 (Counting Laboratory).
QUESTION C.02 [1.0]
Which one of the following is the reason you rotate the Nuclear Instrumentation Channel #1 range switch counterclockwise after depressing the "RAISE" button?
- a. To prevent a reactor trip due to excessive period.
- b. To prevent a low level trip of the Safety Channel #1 sensitrol.
- c. To compensate for control rod shadowing effects on Safety Channel #1, at higher power levels.
- d. To bring Safety Channel #1 readings into agreement with Safety Channels #2 and #3.
QUESTION C.03 [1.0]
Which ONE of the following is NOT an interlock preventing rod insertion?
- a. Both safety rods must be fully inserted prior to inserting the coarse control rod.
- b. Both safety rods must be fully inserted prior to inserting the fine control rod.
- c. The coarse control rod must be fully withdrawn prior to inserting the safety rods.
- d. The fine control rod must be greater than or equal to half inserted prior to inserting the safety rods.
QUESTION C.04 [1.0]
Which ONE of the following is the gas used in the rabbit tube assembly?
- a. Air
- b. Carbon Dioxide
- c. Helium
- d. Nitrogen
QUESTION C.05 [1.0]
Which ONE of the following signals will result in opening the interlock bus?
- a. Manual scram switch
- b. Period trip
- c. Earthquake sensor
- d. Channel #1 high (95% full scale)
QUESTION C.06 [1.0]
Which one of the following detectors is used for Nuclear Instrumentation Channel #2?
- a. BF3 filled Proportional Counter
- b. BF3 filled Ionization Chamber
- c. BF3 filled Geiger-Muller tuber
- d. U235 lined Fission Chamber QUESTION C.07 [1.0]
Which ONE of the following statements correctly completes the sentence concerning the access ports? The access ports
- a. penetrate through the shield tank, passing by the reflector and the lead shield.
- b. pass through the shield tank up to the lead shield
- c. pass through the shield tank, lead shield and the reflector up to the core container.
- d. pass through the shield tank up to the reflector QUESTION C.08 [1.0]
The reactor is critical, with the Fine Control Rod (FCR) fully inserted. If you wish to reposition the FCR to the mid-plane of its travel, how far and in what direction must you move the Coarse Control Rod (CCR), maintaining critical conditions?
- a. 6.7 cm, out of core
- b. 3.3 cm, into core
- c. 3.3 cm, out of core
- d. 6.7 cm, into core
QUESTION C.09 [1.0]
The Low Level Interlock is controlled by power level indication from:
- a. Channel 1.
- b. Channel 2.
- c. Channel 3.
- d. Auxiliary Channel.
QUESTION C.10 [1.0]
Which ONE of the following conditions will prevent the operator from inserting the control rods into the core?
- a. Shielding water less than 1 inch from the manhole opening.
- b. Earthquake of negligible horizontal amplitude.
- c. Water temperature of 20 oC.
- d. Channel #1 reset button depressed.
QUESTION C.11 [1.0]
The U-235 fuel in the AGN is contained in fuel disks and control rods. Of the total fuel in the reactor, approximately how much is contained in the control and safety rods?
- a. 9%.
- b. 24%.
- c. 55%
- d. 78%.
QUESTION C.12 [1.0]
Which ONE of the following describes the design purpose of the space in the top section of the core tank above the reactor core and the reflector?
- a. Ensures free fall of the bottom half of the core during the most severe transient.
- b. Increases the fast neutron population in the vicinity of experiments placed in the access ports.
- c. Allows for accumulation of fission product gases created during reactor operation.
- d. Prevents core damage during the design basis earthquake and 6 cm. displacements.
QUESTION C.13 [1.0]
Which ONE of the following does NOT automatically cause a reactor scram?
- a. Reactor period.
- b. Radiation level.
- c. Water level.
- d. Power failure.
QUESTION C.14 [1.0]
Which one of the following materials will have a positive effect on reactivity when inserted into the Glory Hole?
- a. Borated Polyethylene
- b. Polyethylene
- c. Natural Uranium
- d. Gold QUESTION C.15 [1.0]
When using the movable tank on the top of the reactor as a Thermal Neutron column, it is filled with
- a. Water
- b. Beryllium
- c. Graphite
- d. Heavy Water
(***** END OF CATEGORY C *****)
(********** END OF EXAMINATION **********)
SECTION A. RX THEORY, THERMO & FAC OP CHARS A.01 a REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 78.
A.02 a REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 346.
A.03 d REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 329.
A.04 d REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 312.
A.05 c REF: SUR (in decades per minute) = 26.06/ OR ln (P0/P) = t/ ln(10) = time/25 2.302585092994 = time/25 seconds. time = 2.3026 x 25 = 57.6 seconds or 1 minute A.06 d REF: Safety Analysis Report, dated November 23, 1995, pg. 104.
A.07 b or d REF: Glasstone S, and Sesonske, A, Nuclear Reactor Engineering, Kreiger Publishing, Malabar, Florida, 1991, §§ 2.70 2.74, pp. 65 66.
A.08 c REF: Lamarsh, Introduction To Nuclear Engineering, 3rd Edition.
(CR2/CR1) = (1-Keff0)/(1-Keff1) (60/30) = (0.90)(1-Keff1) Keff1 = 0.95 A.09 a REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 361, 362.
A.10 a REF: Lamarsh, J.R., Introduction to Nuclear Engineering, Addison-Wesley Publishing, Reading, Massachusetts, 1983, § 7.1, p. 289.
SECTION A. RX THEORY, THERMO & FAC OP CHARS A.11 c REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 88.
A.12 b REF: Glasstone, S. & Sesonske, , § 5.18 P = P0 et/ = 9.7 x e1/10 = 9.7 x 1.1052 = 10.72 A.13 c REF: Lamarsh does not cover reactor characteristics for approach to critical.
A.14 a REF: Glasstone, S. And Sesonske, A, § 5.225.
A.15 c REF: SDM = 1 - Keff/Keff or Keff = 1/(1 + SDM) = 1/(1 + .01) = 0.990 CR1/CR2 = (1 - Keff2)/(1 - Keff1) or 1 - Keff2 = (1 - Keff1) CR1/CR2 = 0.0099 (15/30) = .00495 1 - Keff2 = 0.00495 Keff = 1 - 0.00495 = 0.995 Reactivity Added = (Keff1 - Keff2)/Keff1Keff2 = (0.990 - 0.995)/(0.995 x 0.990) =
0.005076 (positive) or 0.508%
A.16 b REF: Lamarsh, J.R., Introduction to Nuclear Engineering, Addison-Wesley Publishing, Reading, Massachusetts, 1983, § 7.1, pp. 286 287.
A.17 b REF: Lamarsh, Introduction to Nuclear Engineering, 3rd Edition, page 369.
A.18 a REF: SDM = (1 - Keff)/Keff Keff = 1/(1 + SDM) Given SDM = 0.2 Keff = 1/(1 + 0.2) = 1/1.02 Initial Keff = .9804 CR1/ CR2 = (1 - Keff1)/(1 - Keff2) Rearranging: Keff2 = 1 - (1 - Keff1) x CR2/CR1 Keff2 = 1 - [(1 - 0.9804) x 35/70] = 1 - 0.0196 x 2 = 1 - 0.0392 = 0.9608
= (Keff2 -Keff1)/Keff2 Keff2 = (0.9804 - 0.9608)/(0.9804 x 0.9608) = 0.0196/ 0.94197
= 0.02081
SECTION B. NORMAL/EMERG PROCEDURES & RAD CON B.01 c REF: ISU Technical Specifications § 3.2, p. 10 B.02 d REF: ISU TS § 3.4 B.03 a, 1; b, 2; c, 2; d, 3 REF: 10 CFR 20 § 20.1003 Definitions B.04 a, 6; b, 2; c, 2 or 1; d, 1 ISU Requal plan has yearly written.
REF: 10 CFR 55.21, 10 CFR 55.55, 10 CFR 55.59, ISU Requalification Plan B.05 a, SL; b, LSSS; c, LCO; d, LCO REF: ISU TS §§ 2.1, 2.2 and 3.0 B.06 c REF:
A ~=~ A_0 e^{lambda(t)}~~~~ 294 ~=~ 900`e^{lambda `180} ~~~ {ln left( 294 over 900 right)} over 180 ~=~ lambda ~ = ~0.00621 #
{ln(0.5)} over {0.00621} ~=~ 111 B.07 d REF: Dose () = Dose with window closed B.08 d REF: ISU Technical Specification 4.2.c B.09 b REF: ISU Technical Specification 2.1.b B.10 b REF: Maintenance Procedure #2 Prerequisites and Safety B.11 a REF: ISU Emerg. Plan Sect C.6 B.12 c REF: Emergency Plan, Section 4, Fire or Explosion B.13 d REF: ISU Technical Specification 3.2.a B.14 c REF: ISU Experimental Plan No. 19 Sample Transfer by Pneumatic Tube, Safety Analysis p. 3 B.15 c REF: Emergency Plan, Nuclear Emergency p. 13.
SECTION C. PLANT AND RAD MONITORING SYSTEMS C.01 a REF: Emergency Plan, Section 7.3.2 C.02 b REF: ISU OP-1 Chap. V Startup Step A.3 C.03 d REF: ISU SAR § 4.3.1 Control Rods C.04 d REF: NRC examination bank C.05 c REF: NRC Examination Question Bank C.06 b REF: ISU SAR § 4,3,2, p. 61 C.07 c REF: NRC Examination Question Bank C.08 b REF: NRC Examination Question Bank C.09 a REF: Safety Analysis Report, dated November 23, 1995, pg. 58 C.10 d REF: Safety Analysis Report, dated November 23, 1995, pg. 69 C.11 a REF: Safety Analysis Report, dated November 23, 1995, pg. 46-47 C.12 c REF: Safety Analysis Report, dated November 23, 1995, pg. 41 C.13 b REF: Safety Analysis Report, dated November 23, 1995, pg. 57.
C.14 b REF: NRC Examination Question Bank C.15 c REF: ISU SAR, § 4.1