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| issue date = 09/02/2014 | | issue date = 09/02/2014 | ||
| title = Examination Report, No. 50-005/OL-14-01, Pennsylvania State University | | title = Examination Report, No. 50-005/OL-14-01, Pennsylvania State University | ||
| author name = Hsueh K | | author name = Hsueh K | ||
| author affiliation = NRC/NRR/DPR/PRTA | | author affiliation = NRC/NRR/DPR/PRTA | ||
| addressee name = Unlu K | | addressee name = Unlu K | ||
Line 9: | Line 9: | ||
| docket = 05000005 | | docket = 05000005 | ||
| license number = R-002 | | license number = R-002 | ||
| contact person = Young P | | contact person = Young P, DPR/PROB, 415-4094 | ||
| case reference number = 50-005/OL-14-01 | | case reference number = 50-005/OL-14-01 | ||
| document report number = 50-005/OL-14-01 | | document report number = 50-005/OL-14-01 | ||
Line 18: | Line 18: | ||
=Text= | =Text= | ||
{{#Wiki_filter:September 2, 2014 Dr. Kenan Unlu, Director Breazeale Nuclear Reactor Radiation Science and Engineering Center The Pennsylvania State University University Park, PA | {{#Wiki_filter:September 2, 2014 Dr. Kenan Unlu, Director Breazeale Nuclear Reactor Radiation Science and Engineering Center The Pennsylvania State University University Park, PA 16802-2301 | ||
==SUBJECT:== | ==SUBJECT:== | ||
EXAMINATION REPORT NO. 50-005/OL-14-01, PENNSYLVANIA STATE UNIVERSITY BREAZEALE RESEARCH REACTOR | EXAMINATION REPORT NO. 50-005/OL-14-01, PENNSYLVANIA STATE UNIVERSITY BREAZEALE RESEARCH REACTOR | ||
==Dear Dr. Unlu:== | ==Dear Dr. Unlu:== | ||
During the week of August 11, 2014, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examinations at your Pennsylvania State University Breazeale Research Reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2. 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 August 11, 2014, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examinations at your Pennsylvania State University Breazeale Research Reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2. 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 Phillip T. Young at (301) 415-4094 or via internet e-mail Phillip.Young@nrc.gov. | |||
Sincerely, | |||
/RA/ | |||
Kevin Hsueh, Chief Research and Test Reactors Oversight Branch Division of Policy and Rulemaking Office of Nuclear Reactor Regulation Docket No. 50-005 | |||
==Enclosures:== | |||
. | : 1. Examination Report No. 50-005/OL-14-01 cc without enclosures: see next page | ||
Dr. Kenan Unlu, Director September 2, 2014 Breazeale Nuclear Reactor Radiation Science and Engineering Center The Pennsylvania State University University Park, PA 16802-2301 | |||
==SUBJECT:== | ==SUBJECT:== | ||
EXAMINATION REPORT NO. 50-005/OL-14-01, PENNSYLVANIA STATE UNIVERSITY BREAZEALE RESEARCH REACTOR | EXAMINATION REPORT NO. 50-005/OL-14-01, PENNSYLVANIA STATE UNIVERSITY BREAZEALE RESEARCH REACTOR | ||
==Dear Dr. Unlu:== | ==Dear Dr. Unlu:== | ||
During the week of August 11, 2014, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examinations at your Pennsylvania State University Breazeale Research Reactor. The examination was | During the week of August 11, 2014, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examinations at your Pennsylvania State University Breazeale Research Reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2. 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 Phillip T. Young at (301) 415-4094 or via internet e-mail Phillip.Young@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 Phillip T. Young at (301) 415-4094 or via internet e-mail Phillip.Young@nrc.gov | Sincerely, | ||
/RA/ | |||
Kevin Hsueh, Chief Research and Test Reactors Oversight Branch Division of Policy and Rulemaking Office of Nuclear Reactor Regulation Docket No. 50-005 | |||
Kevin Hsueh, Chief Research and Test Reactors Oversight Branch Division of Policy and Rulemaking Office of Nuclear Reactor Regulation | |||
Docket No. 50-005 | |||
==Enclosures:== | ==Enclosures:== | ||
: 1. Examination Report No. 50-005/OL-14-01 cc w/o enclosures: See next page | : 1. Examination Report No. 50-005/OL-14-01 cc w/o enclosures: See next page DISTRIBUTION w/encls.: | ||
PUBLIC ADAMS ACCESSION #: ML14230A904 OFFICE DPR/PROB DIRS/IOLB DPR/PROB NAME PYoung CRevelle KHsueh DATE 8/19/2014 8/28/2014 9/02/2014 OFFICIAL RECORD COPY | |||
Pennsylvania State University Docket No. 50-005 cc: | |||
Mr. Jeffrey A. Leavey, Manager of Radiation Protection Pennsylvania State University 0201 Academic Project BL University Park, PA 16802 Dr. Neil A. Sharkey Interim Vice President for Research of the Graduate School Pennsylvania State University 304 Old Main University Park, PA 16802-1504 Director, Bureau of Radiation Protection Department of Environmental Protection P.O. Box 8469 Harrisburg, PA 17105-8469 Test, Research and Training Reactor Newsletter P.O. Box 118300 University of Florida Gainesville, FL 32611-8300 Mark A. Trump Associate Director for Operations Breazeale Nuclear Reactor Radiation Science and Engineering Center Pennsylvania State University University Park, PA 16802-1504 | |||
U. S. NUCLEAR REGULATORY COMMISSION OPERATOR LICENSING INITIAL EXAMINATION REPORT REPORT NO.: 50-005/OL-14-01 FACILITY DOCKET NO.: 50-005 FACILITY LICENSE NO.: R-2 FACILITY: Pennsylvania State University Breazeale Reactor SUBMITTED BY: ____________/RA/_________ 8/28/2014 Phillip T. Young, Chief Examiner Date | |||
REPORT NO.: | |||
FACILITY DOCKET NO.: 50-005 | |||
FACILITY LICENSE NO.: R-2 | |||
FACILITY: | |||
SUBMITTED BY: | |||
/RA/_________ | |||
==SUMMARY== | |||
During the week of August 11, 2014, the NRC administered license examinations to three Senior Reactor Operator license candidates. The applicant passed all portions of the examination. | |||
REPORT DETAILS | REPORT DETAILS | ||
: 1. Examiner: | : 1. Examiner: Phillip T. Young, Chief Examiner | ||
: 2. Results: | : 2. Results: | ||
: 3. Exit Meeting | RO PASS/FAIL SRO PASS/FAIL TOTAL PASS/FAIL Written 0/0 1/0 1/0 Operating Tests 0/0 3/0 3/0 Overall 0/0 3/0 3/0 | ||
: 3. Exit Meeting | |||
. Phillip T. Young, NRC Examiner Dr. Kenan Unlu, Director Mark A. Trump, Associate Director for Operations The examiner thanked the facility for their cooperation during the administration of the examinations and acknowledged that they had no comments on the written examination. | |||
The examiner thanked the facility for their cooperation during the administration of the examinations and acknowledged that they had no comments on the written examination. | ENCLOSURE 1 | ||
U. S. NUCLEAR REGULATORY COMMISSION NON-POWER INITIAL REACTOR LICENSE EXAMINATION FACILITY: Pennsylvania State University Breazeale Reactor REACTOR TYPE: POOL TYPE, MODIFIED TRIGA DATE ADMINISTERED: 8/12/2014 CANDIDATE: _____________________________ | |||
INSTRUCTIONS TO CANDIDATE: | INSTRUCTIONS TO CANDIDATE: | ||
Answers are to be written on the answer sheet provided. Attach the answer sheets to the examination. Points for each question are indicated in brackets for each question. A 70% in each section 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 the answer sheets to the examination. Points for each question are indicated in brackets for each question. A 70% in each section is required to pass the examination. Examinations will be picked up three (3) hours after the examination starts. | ||
% of Category % of Candidates Category Value Total Score Value Category 20.00 33.3 A. Reactor Theory, Thermodynamics and Facility Operating Characteristics 20.00 33.3 B. Normal and Emergency Operating Procedures and Radiological Controls 20.00 33.3 C. Facility and Radiation Monitoring Systems 60.00 % TOTALS FINAL GRADE All work done on this examination is my own. I have neither given nor received aid. | |||
Candidate's Signature | |||
Value | |||
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. | |||
: 13. When you have completed and turned in you examination, leave the examination area. If you are observed in this area while the examination is still in progress, your license may be denied or revoked. | |||
Q = m c p T = m H = UA T eff = 0.1 seconds -1 S S CR1 (1 - K eff 1 ) = CR 2 (1 - K eff 2 ) | |||
SCR = | |||
SUR = 26.06 eff - 1 - K eff CR1 (- 1 ) = CR 2 (- 2 ) | |||
1 - K eff 0 M= 1 CR1 1 - K eff 1 M= = | |||
t 1 - K eff CR2 P = P0 10SUR(t) | |||
P = P0 e (1 - ) | |||
P= P0 (1 - K eff ) - | |||
SDM = = = + | |||
K eff eff | |||
( K eff - 1) | |||
K eff 2 - K eff 1 0.693 = | |||
= K eff k eff 1 x K eff 2 T= | |||
6CiE(n) | |||
DR = DR0 e- t DR = 2 2 | |||
DR 1 d 1 = DR 2 d 2 2 | |||
R DR - Rem, Ci - curies, E - Mev, R - feet 2 | |||
( 2 - )2 ( 1 - ) | |||
= | |||
Peak 2 Peak 1 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 EF = 9/5 EC + 32 1 gal (H2O) . 8 lbm EC = 5/9 (EF - 32) cP = 1.0 BTU/hr/lbm/EF cp = 1 cal/sec/gm/EC | |||
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.001 (1.0 point) {1.0} | |||
Which ONE of the following is true concerning the differences between prompt and delayed neutrons? | |||
: a. Prompt neutrons account for less than one percent of the neutron population while delayed neutrons account for approximately ninety-nine percent of the neutron population | |||
: b. Prompt neutrons are released during fast fissions while delayed neutrons are released during thermal fissions | |||
: c. Prompt neutrons are released during the fission process while delayed neutrons are released during the decay of fission products | |||
: d. Prompt neutrons are the dominating factor in determining the reactor period while delayed neutrons have little effect on the reactor period Answer: A.01 c. | |||
REF: Reactor Training Manual, Page 2-16. | |||
Question A.002 (1.0 point) {1.0} | |||
In accordance with the PSBR Technical Specifications, the term "Shutdown Margin" describes: | |||
: a. the time required for the rods to fully insert | |||
: b. the departure from K-effective = 1.00 | |||
: c. the amount of subcriticality, considering the worth of all rods | |||
: d. the amount of subcriticality with the most reactive rod fully withdrawn Answer: A.02 d. | |||
REF: PSBR Technical Specifications, Section 1.1.42. | |||
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.003 (1.0 point) {3.0} | |||
Experimenters are attempting to determine the critical mass of a new fuel material. As more fuel was added the following fuel to count rate data was taken: | |||
Fuel Counts/Sec 1.00 kg 500 1.50 kg 800 2.00 kg 1142 2.25 kg 1330 2.50 kg 4000 2.75 kg 15875 Which one of the following is the amount of fuel needed for a critical mass? | |||
: a. 2.60 kg | |||
: b. 2.75 kg c 2.80 kg | |||
: d. 2.95 kg Answer: A.03 c. | |||
REF: Glasstone, S. and Sesonske, A, Nuclear Reactor Engineering, Kreiger Publishing, Malabar, Florida, 1991, §§ 3.161 3.163, pp. 190 & 191. | |||
Question A.004 (1.0 point) {4.0} | |||
The reactor has scrammed following an extended period of operation at full power. Which one of the following accounts for a majority of the heat generated one (1) hour after the scram? | |||
: a. Spontaneous fissions | |||
: b. Delayed neutron fissions | |||
: c. Alpha fission product decay | |||
Experimenters are attempting to determine the critical mass of a new fuel material. As more fuel was added the following fuel to count rate data was taken: | |||
Fuel Counts/Sec 1.00 kg 500 1.50 kg 800 2.00 kg 1142 2.25 kg 1330 2.50 kg 4000 2.75 kg 15875 | |||
Which one of the following is the amount of fuel needed for a critical mass? | |||
: a. 2.60 kg | |||
Answer: A.03 c. | |||
REF: | |||
Question | |||
The reactor has scrammed following an extended period of operation at full power. Which one of the following accounts for a majority of the heat generated one (1) hour after the scram? | |||
: a. Spontaneous fissions b. Delayed neutron fissions | |||
: c. Alpha fission product decay | |||
: d. Beta fission product decay Answer: A.04 d. | : d. Beta fission product decay Answer: A.04 d. | ||
REF: Burn, R., Introduction to Nuclear Reactor Operations, © 1988 pg. 3-4. | REF: Burn, R., Introduction to Nuclear Reactor Operations, © 1988 pg. 3-4. | ||
Section A | Section A Reactor Theory, Thermo, and Facility Characteristics Question A.005 (1.0 point) {5.0} | ||
A factor in the six-factor formula which is most affected by control rod position is: | A factor in the six-factor formula which is most affected by control rod position is: | ||
: a. Resonance escape probability | : a. Resonance escape probability | ||
: c. Neutron reproduction factor | : b. Fast fission factor | ||
: c. Neutron reproduction factor | |||
Answer: A.05 d. | : d. Thermal utilization factor Answer: A.05 d. | ||
REF: Reactor Training Manual - | REF: Reactor Training Manual - Fission Process Question A.006 (1.0 point) {6.0} | ||
Fission Process | Coolant flows through a reactor core at a rate of 50 GPM, resulting in a coolant temperature increase of 6 degrees F. The power of the reactor is: | ||
: a. 5.3 kW. | |||
Question | : b. 14.7 kW. | ||
Coolant flows through a reactor core at a rate of 50 GPM, resulting in a coolant temperature increase of 6 degrees F. The power of the reactor is: | : c. 44.0 kW. | ||
: a. 5.3 kW. b. 14.7 kW. c. 44.0 kW. d. 329.1 kW. | : d. 329.1 kW. | ||
Answer: A.06 c. | |||
Answer: A.06 c. REF: Power = (Mass flow rate)(Specific heat)(temperature increase) Power = (50 GPM)(8.34 lbs/gallon)(1 Btu/lb-deg F)(6 deg F)(60 min/hour) Power = (150,120 Btu/hour)(1 kW/3413 Btu/hour) = 44.0 kW | REF: Power = (Mass flow rate)(Specific heat)(temperature increase) | ||
Power = (50 GPM)(8.34 lbs/gallon)(1 Btu/lb-deg F)(6 deg F)(60 min/hour) Power = (150,120 Btu/hour)(1 kW/3413 Btu/hour) = 44.0 kW Question A.007 (1.0 point) {7.0} | |||
Question | A reactor scram has resulted in the instantaneous insertion of .006 K/K of negative reactivity. | ||
A reactor scram has resulted in the instantaneous insertion of .006 K/K of negative reactivity. Which one of the following is the stable negative reactor period resulting from the scram? | Which one of the following is the stable negative reactor period resulting from the scram? | ||
: a. 45 seconds | : a. 45 seconds | ||
: b. 56 seconds | |||
Answer: A.07 c. | : c. 80 seconds | ||
REF: Burn, R., Introduction to Nuclear Reactor Operations, © 1982, § 4.6, p. 4-16. | : d. 112 seconds Answer: A.07 c. | ||
REF: Burn, R., Introduction to Nuclear Reactor Operations, © 1982, § 4.6, p. 4-16. | |||
Section A | Section A Reactor Theory, Thermo, and Facility Characteristics Question A.008 (1.0 point) {8.0} | ||
The count rate is 50 cps. An experimenter inserts an experiment into the core, and the count rate decreases to 25 cps. Given the initial | The count rate is 50 cps. An experimenter inserts an experiment into the core, and the count rate decreases to 25 cps. Given the initial Keff of the reactor was 0.8, what is the worth of the experiment? | ||
: a. = - 0.42 | : a. = - 0.42 | ||
: b. = + 0.42 | |||
Answer: A.08 a. REF: CR1 / CR2 = (1 - | : c. = - 0.21 | ||
: d. = + 0.21 Answer: A.08 a. | |||
REF: CR1 / CR2 = (1 - Keff2) / (1 - Keff1) 50 / 25 = (1 - Keff2) / (1 - 0.8) | |||
Therefore Keff2 = 0.6 = Keff2 - Keff1 / Keff2 | |||
* Keff1 = (0.6 - 0.8)/(0.6 | * Keff1 = (0.6 - 0.8)/(0.6 | ||
* 0.8) = - 0.41667 | * 0.8) = - 0.41667 Question A.009 (1.0 point) {9.0} | ||
A reactor startup is in progress. Each control rod withdrawal is inserting exactly EQUAL amounts of reactivity. Select the EXPECTED neutron population and count rate response as "Keff" approaches 1.0. | |||
Question | The change in neutron population per reactivity insertion is: | ||
A reactor startup is in progress. Each control rod withdrawal is inserting exactly EQUAL amounts of reactivity. Select the EXPECTED neutron population and count rate response as "Keff" approaches 1.0. | : a. SMALLER, and it takes LESS time to reach a new equilibrium count rate | ||
: b. LARGER, and it takes LESS time to reach a new equilibrium count rate. | |||
The change in neutron population per reactivity insertion is: | : c. SMALLER, and it takes MORE time to reach a new equilibrium count rate. | ||
: a. SMALLER, and it takes LESS time to reach a new equilibrium count rate | : d. LARGER, and it takes MORE time to reach a new equilibrium count rate. | ||
Answer: A.09 d. | |||
Answer: | REF: Reactor Training Manual - Introduction To Nuclear Physics Question A.010 (1.0 point) {10.0} | ||
REF: Reactor Training Manual - Introduction To Nuclear Physics | As primary coolant temperature increases, control rod worth: | ||
: a. decreases due to lower reflector efficiency. | |||
Question | : b. decreases due to higher neutron absorption in the moderator. | ||
As primary coolant temperature increases, control rod worth: | : c. increases due to the increase in thermal diffusion length. | ||
: b. decreases due to higher neutron absorption in the moderator. c. increases due to the increase in thermal diffusion length. | |||
: d. remains the same due to constant poison cross-section of the control rods.. | : d. remains the same due to constant poison cross-section of the control rods.. | ||
Answer: | Answer: A.10 c. | ||
REF: Reactor Training Manual - Reactivity Feedback | REF: Reactor Training Manual - Reactivity Feedback | ||
Section A | Section A Reactor Theory, Thermo, and Facility Characteristics Question A.011 (1.0 point) {11.0} | ||
A reactor has been operating at full power for one week when a scram occurs. Twelve hours later, the reactor is brought critical and quickly raised to full power. Considering xenon effects only, to maintain a constant power level for the next few hours, control rods must be: | A reactor has been operating at full power for one week when a scram occurs. Twelve hours later, the reactor is brought critical and quickly raised to full power. Considering xenon effects only, to maintain a constant power level for the next few hours, control rods must be: | ||
: a. inserted | : a. inserted | ||
: b. maintained at the present position | |||
: c. withdrawn | |||
: d. withdrawn, then inserted to the original position Answer: A.11 a. | |||
REF: PSBR Training Manual, Pages 2-28 through 2-32 Question A.012 (1.0 point) {12.0} | |||
Which ONE of the following describes the difference between reflectors and moderators? | |||
: a. Reflectors decrease core leakage while moderators thermalize neutrons | |||
: b. Reflectors shield against neutrons while moderators decrease core leakage | |||
: c. Reflectors decrease thermal leakage while moderators decrease fast leakage | |||
: d. Reflectors thermalize neutrons while moderators decrease core leakage Answer: A.12 a REF: Introduction to Nuclear Reactor Operations, Reed Robert Brown, Section 5.4 Question A.013 (1.0 point) {13.0} | |||
Which ONE of the following statements describes the difference between Differential 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 Answer: A.13 a. | |||
REF: Standard NRC Question | |||
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.014 (1.0 point) {14.0} | |||
During a startup you increase reactor power from 100 watts to 195 watts in a minute. Which ONE of the following is reactor period? | |||
: a. 30 seconds. | |||
: b. 60 seconds. | |||
: c. 90 seconds. | |||
: d. 120 seconds. | |||
Answer: A.14 c. | |||
REF: P = P0 e = t/ln(P/P0) = 60/ln (195/100) = 60/ln(1.95) = 89.84 . 90 sec. | |||
Question A.015 (1.0 point) {15.0} | |||
The Fast Fission Factor () is defined as The ratio of the number of neutrons produced by | |||
: a. fast fission to the number produced by thermal fission. | |||
: b. thermal fission to the number produced by fast fission. | |||
: c. fast and thermal fission to the number produced by thermal fission. | |||
During a startup you increase reactor power from 100 watts to 195 watts in a minute. Which ONE of the following is reactor period? | |||
: a. 30 seconds. b. 60 seconds. c. 90 seconds. d. 120 seconds. | |||
Answer: | |||
REF: P = | |||
. 90 sec. | |||
Question | |||
The Fast Fission Factor () is defined as | |||
: a. fast fission | |||
: c. fast and thermal fission to the number produced by thermal fission. | |||
: d. fast fission to the number produced by fast and thermal fission. | : d. fast fission to the number produced by fast and thermal fission. | ||
Answer: | Answer: A.15 c. | ||
REF: Reactor Training Manual - Neutron Life Cycle Question | REF: Reactor Training Manual - Neutron Life Cycle Question A.016 (1.0 point) {16.0} | ||
The amount of radioactivity in any material can be determined by: | The amount of radioactivity in any material can be determined by: | ||
: c. Measuring the total number of radioactive emissions given off over time. d. First figure out c. above, then multiply the results by the correct quality factor. | : a. Measuring the dose coming from it using an accurate radiation detector. | ||
: b. Taking the results of a. above and multiplying by (4 x pi) to account for geometry. | |||
: c. Measuring the total number of radioactive emissions given off over time. | |||
: d. First figure out c. above, then multiply the results by the correct quality factor. | |||
Answer: A.16 c. | |||
REF: Glasstone, 1958, CHAP 5, LAMARSH, 1983, CHAP 2.8 | |||
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.017 (1.0 point) {17.0} | |||
A reactor operator understands that: | |||
: a. The more neutrons multiply during startup the lower the shim blades are at critical. | |||
Section A | : b. There is no fixed relationship between neutron level and criticality. | ||
A reactor operator understands that: | : c. Neutron multiplication during startup is just neutrons getting lost at a slower rate. | ||
: b. There is no fixed relationship between neutron level and criticality. c. Neutron multiplication during startup is just neutrons getting lost at a slower rate. d. Without the Sb-Be source the reactor would not go critical. | : d. Without the Sb-Be source the reactor would not go critical. | ||
Answer: | Answer: A.17 b. | ||
REF: Glasstone, 1958, CHAP 14 Question A.018 (1.0 point) {18.0} | |||
Question | Given the lowest of the high power scrams is 110%, and the scram delay time is 0.5 sec. If the reactor is operating at 100% power prior to the scram, approximately how high will reactor power get with a positive 20 second period? | ||
Given the lowest of the high power scrams is 110%, and the scram delay time is 0.5 sec. If the reactor is operating at 100% power prior to the scram, approximately how high will reactor power get with a positive 20 second period? | : a. 113% | ||
: a. 113% | : b. 116% | ||
: c. 124% | : c. 124% | ||
: d. 225% | |||
Answer: A.18 a. | Answer: A.18 a. | ||
REF: P = | REF: P = P0 e t/ Po = 110% = 20 sec. t = 0.5 P = 110 e 0.5/20 = 112.78% | ||
Question A.019 (1.0 point) {19.0} | |||
Question | Which ONE of the following is NOT a major contributor to the prompt negative temperature coefficient at the Penn State TRIGA reactor? | ||
Which ONE of the following is NOT a major contributor to the prompt negative temperature coefficient at the Penn State TRIGA reactor? | : a. the U-235 doppler effect | ||
: a. the U-235 doppler effect | : b. the U-238 doppler effect | ||
: c. the ZrH cell effect | : c. the ZrH cell effect | ||
: d. the core leakage effect Answer: A.19 a. | : d. the core leakage effect Answer: A.19 a. | ||
REF: PSBR Training Manual | REF: PSBR Training Manual | ||
Question | Section A Reactor Theory, Thermo, and Facility Characteristics Question A.020 (1.0 point) {20.0} | ||
Given: Primary coolant flow rate is 500 gallons/minute and secondary flow rate is 700 gallons/minute. The T across the primary side of the heat exchanger is 13 F and secondary inlet temperature to the heat exchanger is 73 F. Assuming both the primary and secondary coolants have the same Cp value, which ONE of the following is the secondary outlet temperature? | |||
: a. | : a. 82 F | ||
: c. | : b. 85 F | ||
: d. | : c. 89 F | ||
: d. 91 F Answer: A.20 a. | |||
REF: Tsec= (Flowpri/Flowsec) x Tpri Tsec= (500/700) x 13 F = 9.28 F Secondary outlet = 73 F + 9.28 F = 82.3 F | |||
Question | Section B Normal/Emergency Procedures & Radiological Controls Question B.001 (1.0 point) {1.0} | ||
: a. Gamma 1. Stopped by thin sheet of paper | An accessible area within the facility has general radiation levels of 325 mrem/hour. What would be the EXPECTED posting for this area? | ||
: c. Alpha | : a. "Caution, Very High Radiation Area" | ||
: d. Neutron | : b. "Danger, Airborne Radioactivity Area" | ||
: c. "Danger, High Radiation Area" | |||
: d. "Caution, Radiation Area" Answer: B.01 c. | |||
REF: 10CFR20 Question B.002 (1.0 point) {2.0} | |||
While working on an experiment, you receive the following radiation doses: 100 mrem (), | |||
25 mrem (), and 5 mrem (thermal neutrons). Which ONE of the following is your total dose? | |||
: a. 175 mrem | |||
: b. 155 mrem | |||
: c. 145 mrem | |||
: d. 135 mrem Answer: B.02 d. | |||
REF: Reactor Training Manual - Ionizing Radiation Question B.003 (1.0 point, 1/4 each) {3.0} | |||
Match type of radiation (1 thru 4) with the proper penetrating power (a thru d) | |||
: a. Gamma 1. Stopped by thin sheet of paper | |||
: b. Beta 2. Stopped by thin sheet of metal | |||
: c. Alpha 3. Best shielded by light material | |||
: d. Neutron 4. Best shielded by dense material Answer: B.03 a. = 4; b. = 2; c. = 1; d. = 3 REF: Reactor Training Manual - Health Physics | |||
Section B | Section B Normal/Emergency Procedures & Radiological Controls Question B.004 (1.0 point, 1/4 each) {4.0} | ||
: a. Reactor Operator licensed at the facility. b. Senior Reactor Operator licensed at the facility. | 10CFR50.54(x) states: A licensee may take reasonable action that departs from a license condition or a technical specification (contained in a license issued under this part) in an emergency when this action is immediately needed to protect the public health and safety and no action consistent with license conditions and technical specifications that can provide adequate or equivalent protection is immediately apparent. Per 10CFR50.54(y), which one of the following is the minimum level of authorization for this action? | ||
: c. Facility Manager (or equivalent at facility). d. The U.S. Nuclear Regulatory Commission Project Manager | : a. Reactor Operator licensed at the facility. | ||
: b. Senior Reactor Operator licensed at the facility. | |||
: c. Facility Manager (or equivalent at facility). | |||
: d. The U.S. Nuclear Regulatory Commission Project Manager Answer: B.04 b. | |||
REF: 10CFR50.54(y). | |||
Question B.005 (1.0 point) {5.0} | |||
In accordance with the Technical Specifications, which ONE situation below is NOT permissible when the reactor is operating? | |||
: a. scram time of a control rod = >1 second | |||
: b. depth of water above the top of the bottom grid plate = 18 feet | |||
: c. conductivity of bulk pool water = 5 micromhos/cm | |||
: d. reactivity insertion by a control rod = 0.12% delta k/k Answer: B.05 a. | |||
REF: Technical Specifications, Section 3.2.6 Question B.006 (1.0 point) {6.0} | |||
The maximum power level shall be no greater than 1.1 MW. This is an example of a: | |||
: a. safety limit. | |||
: b. limiting safety system setting. | |||
: c. limiting condition for operation. | |||
: d. surveillance requirement. | |||
Answer: B.06 c. | |||
REF: TS 3.1.1 | |||
Section B Normal/Emergency Procedures & Radiological Controls Question B.007 (1.0 point) {7.0} | |||
Which one of the following statements defines the Technical Specifications term "Channel Test?" | |||
: a. The adjustment of a channel such that its output corresponds with acceptable accuracy to known values of the parameter which the channel measures. | |||
: b. The qualitative verification of acceptable performance by observation of channel behavior . | |||
: c. The introduction of a signal into a channel for verification of the operability of the channel. | |||
: d. The combination of sensors, electronic circuits and output devices connected to measure and display the value of a parameter Answer: B.07 c. | |||
REF: TS 1.1.6 Question B.008 (1.0 point) {7.0} | |||
As permitted by 10 CFR 50.59, the PSBR may: | |||
: a. Modify systems and change the Technical Specifications (TS) if the NRC is notified afterwards. | |||
: b. Perform new and little understood experiments when they are for research. | |||
: c. Determine the effects of modifications and their impact on TS. | |||
: a. The adjustment of a channel such that its output corresponds with acceptable accuracy to known values of the parameter which the channel measures. | |||
: b. The qualitative verification of acceptable performance by observation of channel behavior . | |||
: c. The introduction of a signal into a channel for verification of the operability of the channel. | |||
: d. The combination of sensors, electronic circuits and output devices connected to measure and display the value of a parameter | |||
Answer: B.07 c. | |||
REF: | |||
Question | |||
: a. Modify systems and change the Technical | |||
: b. Perform new and little understood experiments when they are for research. | |||
: c. Determine the effects of modifications and their impact on TS. | |||
: d. Redefine the boundaries of accidents previously analyzed in the Safety Analysis Report (SAR). | : d. Redefine the boundaries of accidents previously analyzed in the Safety Analysis Report (SAR). | ||
Answer: B.08 c. | Answer: B.08 c. | ||
REF: | REF: 10 CFR 50.59 Question B.009 (1.0 point) {9.0} | ||
A small radioactive source is to be stored in an accessible area of the reactor building. The source reads 2 R/hr at 1 foot. Assuming no shielding is to be used, a Radiation Area barrier would have to be erected from the source at least a distance of approximately: | |||
Question | : a. 400 feet | ||
: a. 400 feet | : b. 40 feet | ||
: c. 20 feet | |||
: d. 10 feet Answer: B.09 c. | |||
REF: DR1D12 = DR2D22 | |||
Question | Section B Normal/Emergency Procedures & Radiological Controls Question B.010 (1.0 point) {10.0} | ||
Which ONE of the following would be classified as an OPERATIONAL EVENT? | |||
: b. Each time X-Scram Bypass (F1) is to be used, the Reactor Operator must have the express Facility | : a. Operation in violation of a safety limit. | ||
: c. If you are performing a CCP with the reactor at power which requires X-Scram Bypass (F1), the Reactor Operator must have the express Facility | : b. Release of fission products from a fuel element. | ||
: c. Unanticipated reactivity change greater than $1.00 . | |||
: d. Reactor scram. | |||
Answer: B.10 d. | |||
REF: AP-4 C.1.a Question B.011 (1.0 point) {11.0} | |||
Which of the following is the most correct statement regarding the use of the X-SCRAM Bypass (F1)? | |||
: a. Performing Wide Range Monitor Checks in accordance with SOP-2 does not require express Facility Directors approval. | |||
: b. Each time X-Scram Bypass (F1) is to be used, the Reactor Operator must have the express Facility Directors approval. | |||
: c. If you are performing a CCP with the reactor at power which requires X-Scram Bypass (F1), the Reactor Operator must have the express Facility Directors approval before proceeding. | |||
: d. If you are handling highly radioactive samples by the pool deck during reactor power operations, X-Scram Bypass (F1) may be authorized by the Facility Director for up to 1 minute in order to preclude an inadvertent scram from an evacuation signal. | : d. If you are handling highly radioactive samples by the pool deck during reactor power operations, X-Scram Bypass (F1) may be authorized by the Facility Director for up to 1 minute in order to preclude an inadvertent scram from an evacuation signal. | ||
Answer: B.11 | Answer: B.11 a REF: PSBR SOP-1, Rev. 18 | ||
Question | Section B Normal/Emergency Procedures & Radiological Controls Question B.012 (1.0 point) {12.0} | ||
You have not performed the functions of an RO or SRO in the past 6 months. Per the Regulations, prior to resuming activities authorized by your license, how many hours must you complete in that function under the direction of an RO or SRO as appropriate? | A radioactive source generates a dose of 100 mr/hr at a distance of 10 feet. Using a two inch thick sheet of lead for shielding the reading drops to 50 mr/hr at a distance of 10 feet. What is the minimum number of sheets of the same lead shielding needed to drop the reading to less than 5 mr/hr at a distance of 10 feet? | ||
: a. 4 | : a. 1 | ||
: b. 3 | |||
: c. 5 | |||
: d. 7 Answer: B.12 c. | |||
REF: Two inches = one-half thickness (T1/2). Using 5 half-thickness will drop the dose by a factor of (1/2)5 = 1/32 100/32 = 3.13 Question B.013 (1.0 point) {13.0} | |||
Which one of the following is the 10 CFR 20 definition of TOTAL EFFECTIVE DOSE EQUIVALENT (TEDE)? | |||
: a. The sum of the deep dose equivalent and the committed effective dose equivalent. | |||
: b. The dose that your whole body receives from sources outside the body. | |||
: c. The sum of the external deep dose and the organ dose. | |||
: d. The dose to a specific organ or tissue resulting from an intake of radioactive material Answer: B.13 a. | |||
REF: 10 CFR 20.1003 Definitions Question B.014 (1.0 point) {14.0} | |||
You have not performed the functions of an RO or SRO in the past 6 months. Per the Regulations, prior to resuming activities authorized by your license, how many hours must you complete in that function under the direction of an RO or SRO as appropriate? | |||
: a. 4 | |||
: b. 6 | |||
: c. 12 | |||
: d. 40 Answer: B.14 b. | |||
REF: 10CFR55.53(f)(2)) | |||
Section B | Section B Normal/Emergency Procedures & Radiological Controls Question B.015 (1.0 point) {15.0} | ||
Which ONE of the following is NOT true for reactor power calibration? | Which ONE of the following is NOT true for reactor power calibration? | ||
: a. The objective is to verify the performance and operability of the power measuring channel. | : a. The objective is to verify the performance and operability of the power measuring channel. | ||
: b. The thermal power level channel calibration will assure that the reactor is to be operated at or below the licensed power levels. | : b. The thermal power level channel calibration will assure that the reactor is to be operated at or below the licensed power levels. | ||
: c. The thermal power channel calibration shall be made on the linear power level monitoring channel biennially, not to exceed 30 months. | : c. The thermal power channel calibration shall be made on the linear power level monitoring channel biennially, not to exceed 30 months. | ||
: d. The percent power level monitor of the Power Range channel shall be used as the official indication to verify that the reactor is operated at or below the authorized power level. | : d. The percent power level monitor of the Power Range channel shall be used as the official indication to verify that the reactor is operated at or below the authorized power level. | ||
Answer: B.15 d. | |||
Answer: B.15 d. REF: | REF: T.S. 4.1.1 and SOP-1, II.j Question B.016 (1.0 point) {16.0} | ||
Which ONE of the following are the potential sources of airborne radioactive material release at the PSBR. | |||
Question | : a. A loss of coolant accident, and the reactivity insertion accident. | ||
Which ONE of the following are the potential sources of airborne radioactive material release at the PSBR. | : b. A loss of coolant accident, and a rupture of one or more fuel elements. | ||
: a. A loss of coolant accident, and the reactivity insertion accident. b. A loss of coolant accident, and a rupture of one or more fuel elements. c. The reactivity insertion accident, and leakage or rupture of an irradiated sample or experimental apparatus. | : c. The reactivity insertion accident, and leakage or rupture of an irradiated sample or experimental apparatus. | ||
: d. A rupture of one or more fuel elements, and leakage or rupture of an irradiated sample or experimental apparatus. | : d. A rupture of one or more fuel elements, and leakage or rupture of an irradiated sample or experimental apparatus. | ||
Answer: B.16 d. | Answer: B.16 d. | ||
REF: | REF: EP-5 V.c.1 Question B.017 (1.0 point) {17.0} | ||
Which one of the following terms matches the definition of The reactor building and all connected structures ? | |||
: a. Emergency Planning Zone (EPZ). | |||
: b. Reactor Site Boundary. | |||
: c. Restricted Area. | |||
: d. Site Geographical Area. | |||
Answer: B.17 a. | |||
REF: EP-1, Definitions | |||
Section B Normal/Emergency Procedures & Radiological Controls Question B.018 (1.0 point) {18.0} | |||
In the event of a bomb threat, the person receiving the threat should... | |||
: a. ask the person making the threat for his name and address. | |||
: b. call 911 after the call has ended. | |||
: c. immediately activate the Emergency Plan. | |||
: d. immediately evacuate the reactor building and proceed to the facility gate. | |||
Answer: B.18 a. | |||
In the event of a bomb threat, the person receiving the threat should... a. ask the person making the threat for his name and address. | REF: PSBR EP-8 Question B.019 (1.0 point) {19.0} | ||
: b. call 911 after the call has ended. c. immediately activate the Emergency Plan. d. immediately evacuate the reactor building and proceed to the facility gate. | A release of airborne radioactive material where a person at the reactor site boundary is expected to receive a deep dose equivalent of 15 mrem over a 24 hour period is classified as: | ||
Answer: B.18 a. REF: | : a. Unusual Event | ||
: b. Alert | |||
Question | : c. Site Area Emergency | ||
A release of airborne radioactive material where a person at the reactor site boundary is expected to receive a deep dose equivalent of 15 mrem over a 24 hour period is classified as: | : d. General Emergency Answer: B.19 a. | ||
: a. Unusual Event | REF: EP-5 Section D.3 Question B.020 (1.0 point) {20.0} | ||
: c. Site Area Emergency | In the event of an emergency involving an emergency evacuation, the Duty RO is responsible to: | ||
: a. be a member of the re-entry team and reporting to the Emergency Director. | |||
Question | : b. be the acting Emergency Director until relieved by higher levels of facility management. | ||
In the event of an emergency involving an emergency evacuation, the Duty RO is responsible to: a. be a member of the re-entry team and reporting to the Emergency Director. | : c. admit appropriate emergency support personnel to the facility to mitigate the consequences of the emergency. | ||
: b. be the acting Emergency Director until relieved by higher levels of facility management. | |||
: c. admit appropriate emergency support personnel to the facility to mitigate the consequences of the emergency. | |||
: d. open and take charge of the Emergency Support Center, distributing emergency equipment to appropriate support personnel. | : d. open and take charge of the Emergency Support Center, distributing emergency equipment to appropriate support personnel. | ||
Answer: B.20 a. REF: | Answer: B.20 a. | ||
REF: EP-1.B.4 | |||
Question | Section C Facility and Radiation Monitoring Systems Question C.001 (1.0 point) {1.0} | ||
: a. A stroke of about 15 inches. b. A length of about 43 inches. | Which ONE of the following is a condition under which air can be applied to the cylinder of the transient rod on the DCC-X? | ||
: c. A fuel follower of about 15 inches. d. They contain graphite reflector sections. | : a. Pulse mode and initial power up to 100 kw. | ||
Answer: C.03 | : b. Transient rod drive is at the bottom end of travel position. | ||
: c. Square wave mode and initial power greater than 1 kw. | |||
: d. The counter clockwise limit switch is closed. | |||
Answer: C.01 b. | |||
REF: PSBR Training Manual, page 4-45. | |||
Question C.002 (1.0 point) {2.0} | |||
The Emergency Exhaust System is activated when: | |||
: a. the facility exhaust system is secured | |||
: b. the reactor bay has a positive pressure with respect to the atmosphere | |||
: c. a building evacuation is initiated | |||
: d. the pressure drop across the facility exhaust system filters doubles Answer: C.02 c. | |||
REF: PSBR Training Manual, Section 5-3-4 Question C.003 (1.0 point) {3.0} | |||
Which one of the following is true for ALL control rods (i.e., the safety, the shim, the regulating and the transient rods) | |||
: a. A stroke of about 15 inches. | |||
: b. A length of about 43 inches. | |||
: c. A fuel follower of about 15 inches. | |||
: d. They contain graphite reflector sections. | |||
Answer: C.03 a. | |||
==Reference:== | ==Reference:== | ||
PSBR Training Manual, Section 3.5 | PSBR Training Manual, Section 3.5 | ||
Section C Facility and Radiation Monitoring Systems Question | Section C Facility and Radiation Monitoring Systems Question C.004 (1.0 point) {4.0} | ||
: b. | SCRAM logic is designed to meet the single failure criterion. Which one pair of parameters below are in the correct circuits? | ||
: c. | Scram Circuit #1 Scram Circuit #2 | ||
: d. | : a. Fuel temperature High Fission Chamber Power High | ||
: b. Manual Scram Pulse Timer Scram | |||
: c. Pulse Timer Scram GIC Power High | |||
: d. Keyswitch Off Fuel Temperature High Answer: C.04 c. | |||
REF: PSBR Training Manual, Section 4.2.10.2 Question C.005 (1.0 point) {5.0} | |||
Which one of the following is true for the rod drive interlocks? | |||
: a. The rod drive interlock logic is fail safe on loss of power since power is not required for the motor controller digital inputs to perform the inhibit function. | |||
: b. The rod drive pushbuttons provide normally closed contacts for interlock functions and normally open contacts for inputs to DCC-X. | |||
: c. The interlock validation in RSS and the use of redundant software interlocks for the demand velocity signal provide a diverse control rod withdrawal interlock. | |||
: d. If more than one rod pushbutton is pressed at one time, the logic blocks manual withdrawal of the last selected rod or rods and all rods in the automatic mode of control. | |||
Answer: C.05 b. | |||
REF: PSBR Training Manual, Section 4.20.7.2c | |||
Answer: C.06 d. | Section C Facility and Radiation Monitoring Systems Question C.006 (1.0 point) {6.0} | ||
When the ventilation system is in the emergency exhaust mode . | |||
: a. air outside of the PSBR facility is pulled into the emergency exhaust system through a screened opening in the east wall of the reactor bay to dilute the filtered air that is ultimately released through the 18 PVC Emergency Exhaust Stack which terminates above the main Reactor Bay roof. | |||
: b. air outside of the PSBR facility is pulled into the emergency exhaust system and a DCC-X message Emerg Ventilation Flow On can be observed by the Reactor Operator which is the most positive indication that the system has flow. | |||
: c. filtered air is recirculated in the reactor bay to prevent the potential release of fission products to the environment. | |||
: d. filtered air is ultimately released through the 18 PVC Emergency Exhaust Stack which terminates above the main Reactor Bay roof. | |||
Answer: C.06 d. | |||
==Reference:== | ==Reference:== | ||
PSBR Training Manual, Chapter 5.3.4.3 | PSBR Training Manual, Chapter 5.3.4.3 Question C.007 (1.0 point) {7.0} | ||
Which one of the following initiates a reactor operation inhibit by DCC-X? | |||
Question | : a. Emergency exhaust system operating. | ||
: b. Reactor pool level below normal. | : b. Reactor pool level below normal. | ||
: c. Radiation hazard from the neutron beam ports. d. Fuel temperature is high. | : c. Radiation hazard from the neutron beam ports. | ||
: d. Fuel temperature is high. | |||
Answer: C.07 | Answer: C.07 c. | ||
==Reference:== | ==Reference:== | ||
PSBR Training Manual, page 4-29 | PSBR Training Manual, page 4-29 Question C.008 (1.0 point) {8.0} | ||
In the Automatic Control mode, the controlling signal is: | |||
Question | : a. reactor power as measured by the Power Range Monitor | ||
: a. reactor power as measured by the Power Range Monitor | : b. reactor period as measured by the GIC | ||
: c. reactor power as measured by the Wide Range Monitor | : c. reactor power as measured by the Wide Range Monitor | ||
: d. reactor period as measured by the Power Range Monitor Answer: C.08 c. | |||
Answer: C.08 c. | REF: PSBR Training Manual, Section 4.1.7 | ||
REF: | |||
Section C Facility and Radiation Monitoring Systems Question | Section C Facility and Radiation Monitoring Systems Question C.009 (1.0 point) {9.0} | ||
: b. | When the Automatic Mode Menu is displayed, rod mode "2" is selected. This means that the rods selected for regulation are the: | ||
: c. | : a. regulating rod and safety rod | ||
: d. | : b. regulating rod and shim rod | ||
: c. safety rod and shim rod | |||
: d. regulating rod and transient rod Answer: C.09 b. | |||
REF: PSBR Training Manual, Section 4.2.9.1 Question C.010 (1.0 point) {10.0} | |||
In the PSBR Water Handling System, pool water conductivity is measured: | |||
: a. at the suction of the purification pump | |||
: b. downstream of the skimmer | |||
: c. between the filter and purification pump | |||
: d. at the inlet of the demineralizer Answer: C.10 d. | |||
REF: PSBR Training Manual, Section 5-2-3. | |||
Question C.011 (1.0 point) {11.0} | |||
Streaming of radiation from the central thimble is prevented by: | |||
: a. a graphite shield box over the top of the tube | |||
: b. the tube being filled with water | |||
: c. a boral plug inserted into the top of the tube | |||
: d. large radius bend in the tube Answer: C.11 b. | |||
REF: PSBR Training Manual, Section 5-4-6 | |||
Question | Section C Facility and Radiation Monitoring Systems Question C.012 (1.0 point) {12.0} | ||
A reactor stepback is initiated by: | |||
: a. east or west bay monitor high radiation | |||
: b. east and west facility exhaust fans off | |||
: c. high fuel temperature | |||
: d. pulse timer timed out Answer: C.12 c REF: PSBR Training Manual, Section 4.2.9.1bi Question C.013 (1.0 point) {13.0} | |||
The purge gas for the Power Range Monitor is . | |||
: a. CO2 | |||
: b. Argon | |||
: c. Nitrogen | |||
: d. Oxygen Answer: C.13 a | |||
==Reference:== | ==Reference:== | ||
PSBR Training Manual, Chapter 4, Section 4.1.14 Question | PSBR Training Manual, Chapter 4, Section 4.1.14 Question C.014 (1.0 point) {14.0} | ||
: b. Shim rod | The is coupled to its drive by air pressure applied to its cylinder via a solenoid valve. | ||
: c. Regulating rod | : a. Safety rod | ||
: d. Transient rod Answer: C.14 d. | : b. Shim rod | ||
: c. Regulating rod | |||
: d. Transient rod Answer: C.14 d. | |||
==Reference:== | ==Reference:== | ||
PSBR Training Manual, Chapter 4, Section 4.2.4 | PSBR Training Manual, Chapter 4, Section 4.2.4 | ||
Section C Facility and Radiation Monitoring Systems Question | Section C Facility and Radiation Monitoring Systems Question C.015 (1.0 point) {15.0} | ||
Per PSBR TS under no conditions should any experiment or action be initiated which would allow | Per PSBR TS under no conditions should any experiment or action be initiated which would allow to be introduced into the pool water. If came in contact with the stainless steel fuel element cladding, it could possibly cause a failure of the cladding leading to a fission product release. | ||
: a. Nitrogen | : a. Nitrogen | ||
: c. Mercury | : b. Argon | ||
: d. Chlorine Answer: C.15 c. | : c. Mercury | ||
: d. Chlorine Answer: C.15 c. | |||
==Reference:== | ==Reference:== | ||
PSBR Training Manual, Chapter 5, Section 5.1.4 | PSBR Training Manual, Chapter 5, Section 5.1.4 Question C.016 (1.0 point) {16.0} | ||
Which ONE of the following types of detector is used in the Reactor Bay East and West Monitors? | |||
Question | : a. Geiger-Mueller tube | ||
: a. Geiger-Mueller tube | : b. Scintillation detector | ||
: c. Ionization chamber | : c. Ionization chamber | ||
: d. Proportional counter Answer: C.16 a REF: PSBR Training Manual, Section 4.1.12 Question C.017 (1.0 point) {17.0} | |||
Answer: C.16 a REF: PSBR Training Manual, Section 4.1.12 | The thermocouples in the instrumented fuel elements measure temperature at the: | ||
: a. interior surface of the cladding | |||
Question | : b. center of the zirconium rod | ||
: b. center of the zirconium rod | : c. outer surface of the fuel | ||
: c. outer surface of the fuel | : d. interior of the fuel Answer: C.17 d. | ||
: d. interior of the fuel Answer: C.17 d. | REF: PSBR Training Manual, Section 5.1.4 | ||
REF: | |||
Section C Facility and Radiation Monitoring Systems Question | Section C Facility and Radiation Monitoring Systems Question C.018 (1.0 point) {18.0} | ||
: b. Decreased delta T across the Pool Heat Exchanger. | Which one of the following would be an indication of a leak in the Pool Heat Exchanger? | ||
: c. Excessive makeup to the pool. | : a. Increased radioactivity in the pond water. | ||
: b. Decreased delta T across the Pool Heat Exchanger. | |||
: c. Excessive makeup to the pool. | |||
: d. Increased pool level. | : d. Increased pool level. | ||
Answer: C.18 | Answer: C.18 d. | ||
REF: PSBR Training Manual, Section 3.11 Question C.019 (1.0 point) {19.0} | |||
Question | Which one of the following describes an RSS operational interlock function while in the PULSE mode of operation? | ||
: a. Prevents manual withdrawal of more than one rod. b. Prevents application of air to the transient rod if the drive is not fully down. c. Prevents manual withdrawal of any rod. d. Prevents outward movement of all rods except the transient rod. | : a. Prevents manual withdrawal of more than one rod. | ||
: b. Prevents application of air to the transient rod if the drive is not fully down. | |||
Answer: C.19 | : c. Prevents manual withdrawal of any rod. | ||
REF: | : d. Prevents outward movement of all rods except the transient rod. | ||
Answer: C.19 d. | |||
Question | REF: PSBR Training Manual, Section 4.20.4.2 Question C.020 (1.0 point) {20.0} | ||
: b. the resin in the demineralizer is not damaged. c. nucleate boiling does not occur on fuel element surfaces. d. the expansion of pool water at higher temperatures does not reduce the moderating | The DCC-X bulk pool temperature alarms at ~100°F to ensure that: | ||
Answer: C.20 b REF: | : a. there is an adequate heat sink for the full thermal power of the reactor. | ||
: b. the resin in the demineralizer is not damaged. | |||
: c. nucleate boiling does not occur on fuel element surfaces. | |||
: d. the expansion of pool water at higher temperatures does not reduce the moderating capability of the coolant. | |||
Answer: C.20 b REF: PSBR Training Manual, Section 3.9}} |
Latest revision as of 18:15, 5 February 2020
ML14230A904 | |
Person / Time | |
---|---|
Site: | Pennsylvania State University |
Issue date: | 09/02/2014 |
From: | Kevin Hsueh Research and Test Reactors Licensing Branch |
To: | Unlu K Pennsylvania State Univ |
Young P, DPR/PROB, 415-4094 | |
Shared Package | |
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September 2, 2014 Dr. Kenan Unlu, Director Breazeale Nuclear Reactor Radiation Science and Engineering Center The Pennsylvania State University University Park, PA 16802-2301
SUBJECT:
EXAMINATION REPORT NO. 50-005/OL-14-01, PENNSYLVANIA STATE UNIVERSITY BREAZEALE RESEARCH REACTOR
Dear Dr. Unlu:
During the week of August 11, 2014, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examinations at your Pennsylvania State University Breazeale Research Reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2. 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 Phillip T. Young at (301) 415-4094 or via internet e-mail Phillip.Young@nrc.gov.
Sincerely,
/RA/
Kevin Hsueh, Chief Research and Test Reactors Oversight Branch Division of Policy and Rulemaking Office of Nuclear Reactor Regulation Docket No.50-005
Enclosures:
- 1. Examination Report No. 50-005/OL-14-01 cc without enclosures: see next page
Dr. Kenan Unlu, Director September 2, 2014 Breazeale Nuclear Reactor Radiation Science and Engineering Center The Pennsylvania State University University Park, PA 16802-2301
SUBJECT:
EXAMINATION REPORT NO. 50-005/OL-14-01, PENNSYLVANIA STATE UNIVERSITY BREAZEALE RESEARCH REACTOR
Dear Dr. Unlu:
During the week of August 11, 2014, the U.S. Nuclear Regulatory Commission (NRC) administered operator licensing examinations at your Pennsylvania State University Breazeale Research Reactor. The examination was conducted according to NUREG-1478, "Operator Licensing Examiner Standards for Research and Test Reactors," Revision 2. 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 Phillip T. Young at (301) 415-4094 or via internet e-mail Phillip.Young@nrc.gov.
Sincerely,
/RA/
Kevin Hsueh, Chief Research and Test Reactors Oversight Branch Division of Policy and Rulemaking Office of Nuclear Reactor Regulation Docket No.50-005
Enclosures:
- 1. Examination Report No. 50-005/OL-14-01 cc w/o enclosures: See next page DISTRIBUTION w/encls.:
PUBLIC ADAMS ACCESSION #: ML14230A904 OFFICE DPR/PROB DIRS/IOLB DPR/PROB NAME PYoung CRevelle KHsueh DATE 8/19/2014 8/28/2014 9/02/2014 OFFICIAL RECORD COPY
Pennsylvania State University Docket No.50-005 cc:
Mr. Jeffrey A. Leavey, Manager of Radiation Protection Pennsylvania State University 0201 Academic Project BL University Park, PA 16802 Dr. Neil A. Sharkey Interim Vice President for Research of the Graduate School Pennsylvania State University 304 Old Main University Park, PA 16802-1504 Director, Bureau of Radiation Protection Department of Environmental Protection P.O. Box 8469 Harrisburg, PA 17105-8469 Test, Research and Training Reactor Newsletter P.O. Box 118300 University of Florida Gainesville, FL 32611-8300 Mark A. Trump Associate Director for Operations Breazeale Nuclear Reactor Radiation Science and Engineering Center Pennsylvania State University University Park, PA 16802-1504
U. S. NUCLEAR REGULATORY COMMISSION OPERATOR LICENSING INITIAL EXAMINATION REPORT REPORT NO.: 50-005/OL-14-01 FACILITY DOCKET NO.: 50-005 FACILITY LICENSE NO.: R-2 FACILITY: Pennsylvania State University Breazeale Reactor SUBMITTED BY: ____________/RA/_________ 8/28/2014 Phillip T. Young, Chief Examiner Date
SUMMARY
During the week of August 11, 2014, the NRC administered license examinations to three Senior Reactor Operator license candidates. The applicant passed all portions of the examination.
REPORT DETAILS
- 1. Examiner: Phillip T. Young, Chief Examiner
- 2. Results:
RO PASS/FAIL SRO PASS/FAIL TOTAL PASS/FAIL Written 0/0 1/0 1/0 Operating Tests 0/0 3/0 3/0 Overall 0/0 3/0 3/0
- 3. Exit Meeting
. Phillip T. Young, NRC Examiner Dr. Kenan Unlu, Director Mark A. Trump, Associate Director for Operations The examiner thanked the facility for their cooperation during the administration of the examinations and acknowledged that they had no comments on the written examination.
ENCLOSURE 1
U. S. NUCLEAR REGULATORY COMMISSION NON-POWER INITIAL REACTOR LICENSE EXAMINATION FACILITY: Pennsylvania State University Breazeale Reactor REACTOR TYPE: POOL TYPE, MODIFIED TRIGA DATE ADMINISTERED: 8/12/2014 CANDIDATE: _____________________________
INSTRUCTIONS TO CANDIDATE:
Answers are to be written on the answer sheet provided. Attach the answer sheets to the examination. Points for each question are indicated in brackets for each question. A 70% in each section is required to pass the examination. Examinations will be picked up three (3) hours after the examination starts.
% of Category % of Candidates Category Value Total Score Value Category 20.00 33.3 A. Reactor Theory, Thermodynamics and Facility Operating Characteristics 20.00 33.3 B. Normal and Emergency Operating Procedures and Radiological Controls 20.00 33.3 C. Facility and Radiation Monitoring Systems 60.00 % TOTALS FINAL GRADE All work done on this examination is my own. I have neither given nor received aid.
Candidate's Signature
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.
- 13. When you have completed and turned in you examination, leave the examination area. If you are observed in this area while the examination is still in progress, your license may be denied or revoked.
Q = m c p T = m H = UA T eff = 0.1 seconds -1 S S CR1 (1 - K eff 1 ) = CR 2 (1 - K eff 2 )
SCR =
SUR = 26.06 eff - 1 - K eff CR1 (- 1 ) = CR 2 (- 2 )
1 - K eff 0 M= 1 CR1 1 - K eff 1 M= =
t 1 - K eff CR2 P = P0 10SUR(t)
P = P0 e (1 - )
P= P0 (1 - K eff ) -
SDM = = = +
K eff eff
( K eff - 1)
K eff 2 - K eff 1 0.693 =
K eff k eff 1 x K eff 2 T
6CiE(n)
DR = DR0 e- t DR = 2 2
DR 1 d 1 = DR 2 d 2 2
R DR - Rem, Ci - curies, E - Mev, R - feet 2
( 2 - )2 ( 1 - )
=
Peak 2 Peak 1 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 EF = 9/5 EC + 32 1 gal (H2O) . 8 lbm EC = 5/9 (EF - 32) cP = 1.0 BTU/hr/lbm/EF cp = 1 cal/sec/gm/EC
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.001 (1.0 point) {1.0}
Which ONE of the following is true concerning the differences between prompt and delayed neutrons?
- a. Prompt neutrons account for less than one percent of the neutron population while delayed neutrons account for approximately ninety-nine percent of the neutron population
- b. Prompt neutrons are released during fast fissions while delayed neutrons are released during thermal fissions
- c. Prompt neutrons are released during the fission process while delayed neutrons are released during the decay of fission products
- d. Prompt neutrons are the dominating factor in determining the reactor period while delayed neutrons have little effect on the reactor period Answer: A.01 c.
REF: Reactor Training Manual, Page 2-16.
Question A.002 (1.0 point) {1.0}
In accordance with the PSBR Technical Specifications, the term "Shutdown Margin" describes:
- a. the time required for the rods to fully insert
- b. the departure from K-effective = 1.00
- c. the amount of subcriticality, considering the worth of all rods
- d. the amount of subcriticality with the most reactive rod fully withdrawn Answer: A.02 d.
REF: PSBR Technical Specifications, Section 1.1.42.
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.003 (1.0 point) {3.0}
Experimenters are attempting to determine the critical mass of a new fuel material. As more fuel was added the following fuel to count rate data was taken:
Fuel Counts/Sec 1.00 kg 500 1.50 kg 800 2.00 kg 1142 2.25 kg 1330 2.50 kg 4000 2.75 kg 15875 Which one of the following is the amount of fuel needed for a critical mass?
- a. 2.60 kg
- b. 2.75 kg c 2.80 kg
- d. 2.95 kg Answer: A.03 c.
REF: Glasstone, S. and Sesonske, A, Nuclear Reactor Engineering, Kreiger Publishing, Malabar, Florida, 1991, §§ 3.161 3.163, pp. 190 & 191.
Question A.004 (1.0 point) {4.0}
The reactor has scrammed following an extended period of operation at full power. Which one of the following accounts for a majority of the heat generated one (1) hour after the scram?
- a. Spontaneous fissions
- b. Delayed neutron fissions
- c. Alpha fission product decay
- d. Beta fission product decay Answer: A.04 d.
REF: Burn, R., Introduction to Nuclear Reactor Operations, © 1988 pg. 3-4.
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.005 (1.0 point) {5.0}
A factor in the six-factor formula which is most affected by control rod position is:
- a. Resonance escape probability
- b. Fast fission factor
- c. Neutron reproduction factor
- d. Thermal utilization factor Answer: A.05 d.
REF: Reactor Training Manual - Fission Process Question A.006 (1.0 point) {6.0}
Coolant flows through a reactor core at a rate of 50 GPM, resulting in a coolant temperature increase of 6 degrees F. The power of the reactor is:
- a. 5.3 kW.
- b. 14.7 kW.
- c. 44.0 kW.
- d. 329.1 kW.
Answer: A.06 c.
REF: Power = (Mass flow rate)(Specific heat)(temperature increase)
Power = (50 GPM)(8.34 lbs/gallon)(1 Btu/lb-deg F)(6 deg F)(60 min/hour) Power = (150,120 Btu/hour)(1 kW/3413 Btu/hour) = 44.0 kW Question A.007 (1.0 point) {7.0}
A reactor scram has resulted in the instantaneous insertion of .006 K/K of negative reactivity.
Which one of the following is the stable negative reactor period resulting from the scram?
- a. 45 seconds
- b. 56 seconds
- c. 80 seconds
- d. 112 seconds Answer: A.07 c.
REF: Burn, R., Introduction to Nuclear Reactor Operations, © 1982, § 4.6, p. 4-16.
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.008 (1.0 point) {8.0}
The count rate is 50 cps. An experimenter inserts an experiment into the core, and the count rate decreases to 25 cps. Given the initial Keff of the reactor was 0.8, what is the worth of the experiment?
- a. = - 0.42
- b. = + 0.42
- c. = - 0.21
- d. = + 0.21 Answer: A.08 a.
REF: CR1 / CR2 = (1 - Keff2) / (1 - Keff1) 50 / 25 = (1 - Keff2) / (1 - 0.8)
Therefore Keff2 = 0.6 = Keff2 - Keff1 / Keff2
- Keff1 = (0.6 - 0.8)/(0.6
- 0.8) = - 0.41667 Question A.009 (1.0 point) {9.0}
A reactor startup is in progress. Each control rod withdrawal is inserting exactly EQUAL amounts of reactivity. Select the EXPECTED neutron population and count rate response as "Keff" approaches 1.0.
The change in neutron population per reactivity insertion is:
- a. SMALLER, and it takes LESS time to reach a new equilibrium count rate
- b. LARGER, and it takes LESS time to reach a new equilibrium count rate.
- c. SMALLER, and it takes MORE time to reach a new equilibrium count rate.
- d. LARGER, and it takes MORE time to reach a new equilibrium count rate.
Answer: A.09 d.
REF: Reactor Training Manual - Introduction To Nuclear Physics Question A.010 (1.0 point) {10.0}
As primary coolant temperature increases, control rod worth:
- a. decreases due to lower reflector efficiency.
- b. decreases due to higher neutron absorption in the moderator.
- c. increases due to the increase in thermal diffusion length.
- d. remains the same due to constant poison cross-section of the control rods..
Answer: A.10 c.
REF: Reactor Training Manual - Reactivity Feedback
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.011 (1.0 point) {11.0}
A reactor has been operating at full power for one week when a scram occurs. Twelve hours later, the reactor is brought critical and quickly raised to full power. Considering xenon effects only, to maintain a constant power level for the next few hours, control rods must be:
- a. inserted
- b. maintained at the present position
- c. withdrawn
- d. withdrawn, then inserted to the original position Answer: A.11 a.
REF: PSBR Training Manual, Pages 2-28 through 2-32 Question A.012 (1.0 point) {12.0}
Which ONE of the following describes the difference between reflectors and moderators?
- a. Reflectors decrease core leakage while moderators thermalize neutrons
- b. Reflectors shield against neutrons while moderators decrease core leakage
- c. Reflectors decrease thermal leakage while moderators decrease fast leakage
- d. Reflectors thermalize neutrons while moderators decrease core leakage Answer: A.12 a REF: Introduction to Nuclear Reactor Operations, Reed Robert Brown, Section 5.4 Question A.013 (1.0 point) {13.0}
Which ONE of the following statements describes the difference between Differential 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 Answer: A.13 a.
REF: Standard NRC Question
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.014 (1.0 point) {14.0}
During a startup you increase reactor power from 100 watts to 195 watts in a minute. Which ONE of the following is reactor period?
- a. 30 seconds.
- b. 60 seconds.
- c. 90 seconds.
- d. 120 seconds.
Answer: A.14 c.
REF: P = P0 e = t/ln(P/P0) = 60/ln (195/100) = 60/ln(1.95) = 89.84 . 90 sec.
Question A.015 (1.0 point) {15.0}
The Fast Fission Factor () is defined as The ratio of the number of neutrons produced by
- a. fast fission to the number produced by thermal fission.
- b. thermal fission to the number produced by fast fission.
- c. fast and thermal fission to the number produced by thermal fission.
- d. fast fission to the number produced by fast and thermal fission.
Answer: A.15 c.
REF: Reactor Training Manual - Neutron Life Cycle Question A.016 (1.0 point) {16.0}
The amount of radioactivity in any material can be determined by:
- a. Measuring the dose coming from it using an accurate radiation detector.
- b. Taking the results of a. above and multiplying by (4 x pi) to account for geometry.
- c. Measuring the total number of radioactive emissions given off over time.
- d. First figure out c. above, then multiply the results by the correct quality factor.
Answer: A.16 c.
REF: Glasstone, 1958, CHAP 5, LAMARSH, 1983, CHAP 2.8
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.017 (1.0 point) {17.0}
A reactor operator understands that:
- a. The more neutrons multiply during startup the lower the shim blades are at critical.
- b. There is no fixed relationship between neutron level and criticality.
- c. Neutron multiplication during startup is just neutrons getting lost at a slower rate.
- d. Without the Sb-Be source the reactor would not go critical.
Answer: A.17 b.
REF: Glasstone, 1958, CHAP 14 Question A.018 (1.0 point) {18.0}
Given the lowest of the high power scrams is 110%, and the scram delay time is 0.5 sec. If the reactor is operating at 100% power prior to the scram, approximately how high will reactor power get with a positive 20 second period?
- a. 113%
- b. 116%
- c. 124%
- d. 225%
Answer: A.18 a.
REF: P = P0 e t/ Po = 110% = 20 sec. t = 0.5 P = 110 e 0.5/20 = 112.78%
Question A.019 (1.0 point) {19.0}
Which ONE of the following is NOT a major contributor to the prompt negative temperature coefficient at the Penn State TRIGA reactor?
- a. the U-235 doppler effect
- b. the U-238 doppler effect
- c. the ZrH cell effect
- d. the core leakage effect Answer: A.19 a.
REF: PSBR Training Manual
Section A Reactor Theory, Thermo, and Facility Characteristics Question A.020 (1.0 point) {20.0}
Given: Primary coolant flow rate is 500 gallons/minute and secondary flow rate is 700 gallons/minute. The T across the primary side of the heat exchanger is 13 F and secondary inlet temperature to the heat exchanger is 73 F. Assuming both the primary and secondary coolants have the same Cp value, which ONE of the following is the secondary outlet temperature?
- a. 82 F
- b. 85 F
- c. 89 F
- d. 91 F Answer: A.20 a.
REF: Tsec= (Flowpri/Flowsec) x Tpri Tsec= (500/700) x 13 F = 9.28 F Secondary outlet = 73 F + 9.28 F = 82.3 F
Section B Normal/Emergency Procedures & Radiological Controls Question B.001 (1.0 point) {1.0}
An accessible area within the facility has general radiation levels of 325 mrem/hour. What would be the EXPECTED posting for this area?
- a. "Caution, Very High Radiation Area"
- b. "Danger, Airborne Radioactivity Area"
- c. "Danger, High Radiation Area"
- d. "Caution, Radiation Area" Answer: B.01 c.
REF: 10CFR20 Question B.002 (1.0 point) {2.0}
While working on an experiment, you receive the following radiation doses: 100 mrem (),
25 mrem (), and 5 mrem (thermal neutrons). Which ONE of the following is your total dose?
- a. 175 mrem
- b. 155 mrem
- c. 145 mrem
- d. 135 mrem Answer: B.02 d.
REF: Reactor Training Manual - Ionizing Radiation Question B.003 (1.0 point, 1/4 each) {3.0}
Match type of radiation (1 thru 4) with the proper penetrating power (a thru d)
- a. Gamma 1. Stopped by thin sheet of paper
- b. Beta 2. Stopped by thin sheet of metal
- c. Alpha 3. Best shielded by light material
- d. Neutron 4. Best shielded by dense material Answer: B.03 a. = 4; b. = 2; c. = 1; d. = 3 REF: Reactor Training Manual - Health Physics
Section B Normal/Emergency Procedures & Radiological Controls Question B.004 (1.0 point, 1/4 each) {4.0}
10CFR50.54(x) states: A licensee may take reasonable action that departs from a license condition or a technical specification (contained in a license issued under this part) in an emergency when this action is immediately needed to protect the public health and safety and no action consistent with license conditions and technical specifications that can provide adequate or equivalent protection is immediately apparent. Per 10CFR50.54(y), which one of the following is the minimum level of authorization for this action?
- a. Reactor Operator licensed at the facility.
- b. Senior Reactor Operator licensed at the facility.
- c. Facility Manager (or equivalent at facility).
- d. The U.S. Nuclear Regulatory Commission Project Manager Answer: B.04 b.
REF: 10CFR50.54(y).
Question B.005 (1.0 point) {5.0}
In accordance with the Technical Specifications, which ONE situation below is NOT permissible when the reactor is operating?
- a. scram time of a control rod = >1 second
- b. depth of water above the top of the bottom grid plate = 18 feet
- c. conductivity of bulk pool water = 5 micromhos/cm
- d. reactivity insertion by a control rod = 0.12% delta k/k Answer: B.05 a.
REF: Technical Specifications, Section 3.2.6 Question B.006 (1.0 point) {6.0}
The maximum power level shall be no greater than 1.1 MW. This is an example of a:
- a. safety limit.
- b. limiting safety system setting.
- c. limiting condition for operation.
- d. surveillance requirement.
Answer: B.06 c.
REF: TS 3.1.1
Section B Normal/Emergency Procedures & Radiological Controls Question B.007 (1.0 point) {7.0}
Which one of the following statements defines the Technical Specifications term "Channel Test?"
- a. The adjustment of a channel such that its output corresponds with acceptable accuracy to known values of the parameter which the channel measures.
- b. The qualitative verification of acceptable performance by observation of channel behavior .
- c. The introduction of a signal into a channel for verification of the operability of the channel.
- d. The combination of sensors, electronic circuits and output devices connected to measure and display the value of a parameter Answer: B.07 c.
REF: TS 1.1.6 Question B.008 (1.0 point) {7.0}
As permitted by 10 CFR 50.59, the PSBR may:
- a. Modify systems and change the Technical Specifications (TS) if the NRC is notified afterwards.
- b. Perform new and little understood experiments when they are for research.
- c. Determine the effects of modifications and their impact on TS.
- d. Redefine the boundaries of accidents previously analyzed in the Safety Analysis Report (SAR).
Answer: B.08 c.
REF: 10 CFR 50.59 Question B.009 (1.0 point) {9.0}
A small radioactive source is to be stored in an accessible area of the reactor building. The source reads 2 R/hr at 1 foot. Assuming no shielding is to be used, a Radiation Area barrier would have to be erected from the source at least a distance of approximately:
- a. 400 feet
- b. 40 feet
- c. 20 feet
- d. 10 feet Answer: B.09 c.
REF: DR1D12 = DR2D22
Section B Normal/Emergency Procedures & Radiological Controls Question B.010 (1.0 point) {10.0}
Which ONE of the following would be classified as an OPERATIONAL EVENT?
- a. Operation in violation of a safety limit.
- b. Release of fission products from a fuel element.
- c. Unanticipated reactivity change greater than $1.00 .
- d. Reactor scram.
Answer: B.10 d.
REF: AP-4 C.1.a Question B.011 (1.0 point) {11.0}
Which of the following is the most correct statement regarding the use of the X-SCRAM Bypass (F1)?
- a. Performing Wide Range Monitor Checks in accordance with SOP-2 does not require express Facility Directors approval.
- b. Each time X-Scram Bypass (F1) is to be used, the Reactor Operator must have the express Facility Directors approval.
- c. If you are performing a CCP with the reactor at power which requires X-Scram Bypass (F1), the Reactor Operator must have the express Facility Directors approval before proceeding.
- d. If you are handling highly radioactive samples by the pool deck during reactor power operations, X-Scram Bypass (F1) may be authorized by the Facility Director for up to 1 minute in order to preclude an inadvertent scram from an evacuation signal.
Answer: B.11 a REF: PSBR SOP-1, Rev. 18
Section B Normal/Emergency Procedures & Radiological Controls Question B.012 (1.0 point) {12.0}
A radioactive source generates a dose of 100 mr/hr at a distance of 10 feet. Using a two inch thick sheet of lead for shielding the reading drops to 50 mr/hr at a distance of 10 feet. What is the minimum number of sheets of the same lead shielding needed to drop the reading to less than 5 mr/hr at a distance of 10 feet?
- a. 1
- b. 3
- c. 5
- d. 7 Answer: B.12 c.
REF: Two inches = one-half thickness (T1/2). Using 5 half-thickness will drop the dose by a factor of (1/2)5 = 1/32 100/32 = 3.13 Question B.013 (1.0 point) {13.0}
Which one of the following is the 10 CFR 20 definition of TOTAL EFFECTIVE DOSE EQUIVALENT (TEDE)?
- a. The sum of the deep dose equivalent and the committed effective dose equivalent.
- b. The dose that your whole body receives from sources outside the body.
- c. The sum of the external deep dose and the organ dose.
- d. The dose to a specific organ or tissue resulting from an intake of radioactive material Answer: B.13 a.
REF: 10 CFR 20.1003 Definitions Question B.014 (1.0 point) {14.0}
You have not performed the functions of an RO or SRO in the past 6 months. Per the Regulations, prior to resuming activities authorized by your license, how many hours must you complete in that function under the direction of an RO or SRO as appropriate?
- a. 4
- b. 6
- c. 12
- d. 40 Answer: B.14 b.
REF: 10CFR55.53(f)(2))
Section B Normal/Emergency Procedures & Radiological Controls Question B.015 (1.0 point) {15.0}
Which ONE of the following is NOT true for reactor power calibration?
- a. The objective is to verify the performance and operability of the power measuring channel.
- b. The thermal power level channel calibration will assure that the reactor is to be operated at or below the licensed power levels.
- c. The thermal power channel calibration shall be made on the linear power level monitoring channel biennially, not to exceed 30 months.
- d. The percent power level monitor of the Power Range channel shall be used as the official indication to verify that the reactor is operated at or below the authorized power level.
Answer: B.15 d.
REF: T.S. 4.1.1 and SOP-1, II.j Question B.016 (1.0 point) {16.0}
Which ONE of the following are the potential sources of airborne radioactive material release at the PSBR.
- a. A loss of coolant accident, and the reactivity insertion accident.
- b. A loss of coolant accident, and a rupture of one or more fuel elements.
- c. The reactivity insertion accident, and leakage or rupture of an irradiated sample or experimental apparatus.
- d. A rupture of one or more fuel elements, and leakage or rupture of an irradiated sample or experimental apparatus.
Answer: B.16 d.
REF: EP-5 V.c.1 Question B.017 (1.0 point) {17.0}
Which one of the following terms matches the definition of The reactor building and all connected structures ?
- a. Emergency Planning Zone (EPZ).
- b. Reactor Site Boundary.
- c. Restricted Area.
- d. Site Geographical Area.
Answer: B.17 a.
REF: EP-1, Definitions
Section B Normal/Emergency Procedures & Radiological Controls Question B.018 (1.0 point) {18.0}
In the event of a bomb threat, the person receiving the threat should...
- a. ask the person making the threat for his name and address.
- b. call 911 after the call has ended.
- c. immediately activate the Emergency Plan.
- d. immediately evacuate the reactor building and proceed to the facility gate.
Answer: B.18 a.
REF: PSBR EP-8 Question B.019 (1.0 point) {19.0}
A release of airborne radioactive material where a person at the reactor site boundary is expected to receive a deep dose equivalent of 15 mrem over a 24 hour2.777778e-4 days <br />0.00667 hours <br />3.968254e-5 weeks <br />9.132e-6 months <br /> period is classified as:
- a. Unusual Event
- b. Alert
- c. Site Area Emergency
- d. General Emergency Answer: B.19 a.
REF: EP-5 Section D.3 Question B.020 (1.0 point) {20.0}
In the event of an emergency involving an emergency evacuation, the Duty RO is responsible to:
- a. be a member of the re-entry team and reporting to the Emergency Director.
- b. be the acting Emergency Director until relieved by higher levels of facility management.
- c. admit appropriate emergency support personnel to the facility to mitigate the consequences of the emergency.
- d. open and take charge of the Emergency Support Center, distributing emergency equipment to appropriate support personnel.
Answer: B.20 a.
REF: EP-1.B.4
Section C Facility and Radiation Monitoring Systems Question C.001 (1.0 point) {1.0}
Which ONE of the following is a condition under which air can be applied to the cylinder of the transient rod on the DCC-X?
- a. Pulse mode and initial power up to 100 kw.
- b. Transient rod drive is at the bottom end of travel position.
- c. Square wave mode and initial power greater than 1 kw.
- d. The counter clockwise limit switch is closed.
Answer: C.01 b.
REF: PSBR Training Manual, page 4-45.
Question C.002 (1.0 point) {2.0}
The Emergency Exhaust System is activated when:
- a. the facility exhaust system is secured
- b. the reactor bay has a positive pressure with respect to the atmosphere
- c. a building evacuation is initiated
- d. the pressure drop across the facility exhaust system filters doubles Answer: C.02 c.
REF: PSBR Training Manual, Section 5-3-4 Question C.003 (1.0 point) {3.0}
Which one of the following is true for ALL control rods (i.e., the safety, the shim, the regulating and the transient rods)
- a. A stroke of about 15 inches.
- b. A length of about 43 inches.
- c. A fuel follower of about 15 inches.
- d. They contain graphite reflector sections.
Answer: C.03 a.
Reference:
PSBR Training Manual, Section 3.5
Section C Facility and Radiation Monitoring Systems Question C.004 (1.0 point) {4.0}
SCRAM logic is designed to meet the single failure criterion. Which one pair of parameters below are in the correct circuits?
Scram Circuit #1 Scram Circuit #2
- a. Fuel temperature High Fission Chamber Power High
- b. Manual Scram Pulse Timer Scram
- c. Pulse Timer Scram GIC Power High
- d. Keyswitch Off Fuel Temperature High Answer: C.04 c.
REF: PSBR Training Manual, Section 4.2.10.2 Question C.005 (1.0 point) {5.0}
Which one of the following is true for the rod drive interlocks?
- a. The rod drive interlock logic is fail safe on loss of power since power is not required for the motor controller digital inputs to perform the inhibit function.
- b. The rod drive pushbuttons provide normally closed contacts for interlock functions and normally open contacts for inputs to DCC-X.
- c. The interlock validation in RSS and the use of redundant software interlocks for the demand velocity signal provide a diverse control rod withdrawal interlock.
- d. If more than one rod pushbutton is pressed at one time, the logic blocks manual withdrawal of the last selected rod or rods and all rods in the automatic mode of control.
Answer: C.05 b.
REF: PSBR Training Manual, Section 4.20.7.2c
Section C Facility and Radiation Monitoring Systems Question C.006 (1.0 point) {6.0}
When the ventilation system is in the emergency exhaust mode .
- a. air outside of the PSBR facility is pulled into the emergency exhaust system through a screened opening in the east wall of the reactor bay to dilute the filtered air that is ultimately released through the 18 PVC Emergency Exhaust Stack which terminates above the main Reactor Bay roof.
- b. air outside of the PSBR facility is pulled into the emergency exhaust system and a DCC-X message Emerg Ventilation Flow On can be observed by the Reactor Operator which is the most positive indication that the system has flow.
- c. filtered air is recirculated in the reactor bay to prevent the potential release of fission products to the environment.
- d. filtered air is ultimately released through the 18 PVC Emergency Exhaust Stack which terminates above the main Reactor Bay roof.
Answer: C.06 d.
Reference:
PSBR Training Manual, Chapter 5.3.4.3 Question C.007 (1.0 point) {7.0}
Which one of the following initiates a reactor operation inhibit by DCC-X?
- a. Emergency exhaust system operating.
- b. Reactor pool level below normal.
- c. Radiation hazard from the neutron beam ports.
- d. Fuel temperature is high.
Answer: C.07 c.
Reference:
PSBR Training Manual, page 4-29 Question C.008 (1.0 point) {8.0}
In the Automatic Control mode, the controlling signal is:
- a. reactor power as measured by the Power Range Monitor
- b. reactor period as measured by the GIC
- c. reactor power as measured by the Wide Range Monitor
- d. reactor period as measured by the Power Range Monitor Answer: C.08 c.
REF: PSBR Training Manual, Section 4.1.7
Section C Facility and Radiation Monitoring Systems Question C.009 (1.0 point) {9.0}
When the Automatic Mode Menu is displayed, rod mode "2" is selected. This means that the rods selected for regulation are the:
- a. regulating rod and safety rod
- b. regulating rod and shim rod
- c. safety rod and shim rod
- d. regulating rod and transient rod Answer: C.09 b.
REF: PSBR Training Manual, Section 4.2.9.1 Question C.010 (1.0 point) {10.0}
In the PSBR Water Handling System, pool water conductivity is measured:
- a. at the suction of the purification pump
- b. downstream of the skimmer
- c. between the filter and purification pump
- d. at the inlet of the demineralizer Answer: C.10 d.
REF: PSBR Training Manual, Section 5-2-3.
Question C.011 (1.0 point) {11.0}
Streaming of radiation from the central thimble is prevented by:
- a. a graphite shield box over the top of the tube
- b. the tube being filled with water
- c. a boral plug inserted into the top of the tube
- d. large radius bend in the tube Answer: C.11 b.
REF: PSBR Training Manual, Section 5-4-6
Section C Facility and Radiation Monitoring Systems Question C.012 (1.0 point) {12.0}
A reactor stepback is initiated by:
- a. east or west bay monitor high radiation
- b. east and west facility exhaust fans off
- c. high fuel temperature
- d. pulse timer timed out Answer: C.12 c REF: PSBR Training Manual, Section 4.2.9.1bi Question C.013 (1.0 point) {13.0}
The purge gas for the Power Range Monitor is .
- a. CO2
- b. Argon
- c. Nitrogen
- d. Oxygen Answer: C.13 a
Reference:
PSBR Training Manual, Chapter 4, Section 4.1.14 Question C.014 (1.0 point) {14.0}
The is coupled to its drive by air pressure applied to its cylinder via a solenoid valve.
- a. Safety rod
- b. Shim rod
- c. Regulating rod
- d. Transient rod Answer: C.14 d.
Reference:
PSBR Training Manual, Chapter 4, Section 4.2.4
Section C Facility and Radiation Monitoring Systems Question C.015 (1.0 point) {15.0}
Per PSBR TS under no conditions should any experiment or action be initiated which would allow to be introduced into the pool water. If came in contact with the stainless steel fuel element cladding, it could possibly cause a failure of the cladding leading to a fission product release.
- a. Nitrogen
- b. Argon
- c. Mercury
- d. Chlorine Answer: C.15 c.
Reference:
PSBR Training Manual, Chapter 5, Section 5.1.4 Question C.016 (1.0 point) {16.0}
Which ONE of the following types of detector is used in the Reactor Bay East and West Monitors?
- a. Geiger-Mueller tube
- b. Scintillation detector
- c. Ionization chamber
- d. Proportional counter Answer: C.16 a REF: PSBR Training Manual, Section 4.1.12 Question C.017 (1.0 point) {17.0}
The thermocouples in the instrumented fuel elements measure temperature at the:
- a. interior surface of the cladding
- b. center of the zirconium rod
- c. outer surface of the fuel
- d. interior of the fuel Answer: C.17 d.
REF: PSBR Training Manual, Section 5.1.4
Section C Facility and Radiation Monitoring Systems Question C.018 (1.0 point) {18.0}
Which one of the following would be an indication of a leak in the Pool Heat Exchanger?
- a. Increased radioactivity in the pond water.
- b. Decreased delta T across the Pool Heat Exchanger.
- c. Excessive makeup to the pool.
- d. Increased pool level.
Answer: C.18 d.
REF: PSBR Training Manual, Section 3.11 Question C.019 (1.0 point) {19.0}
Which one of the following describes an RSS operational interlock function while in the PULSE mode of operation?
- a. Prevents manual withdrawal of more than one rod.
- b. Prevents application of air to the transient rod if the drive is not fully down.
- c. Prevents manual withdrawal of any rod.
- d. Prevents outward movement of all rods except the transient rod.
Answer: C.19 d.
REF: PSBR Training Manual, Section 4.20.4.2 Question C.020 (1.0 point) {20.0}
The DCC-X bulk pool temperature alarms at ~100°F to ensure that:
- a. there is an adequate heat sink for the full thermal power of the reactor.
- b. the resin in the demineralizer is not damaged.
- c. nucleate boiling does not occur on fuel element surfaces.
- d. the expansion of pool water at higher temperatures does not reduce the moderating capability of the coolant.
Answer: C.20 b REF: PSBR Training Manual, Section 3.9