January 1, 2018

https://www.nrc.gov/docs/ML1728/ML17286A284.pdf

text

Issue Date: 12/21/17 1 71124.01

NRC INSPECTION MANUAL ARCB

INSPECTION PROCEDURE 71124 ATTACHMENT 01

RADIOLOGICAL HAZARD ASSESSMENT AND EXPOSURE CONTROLS

Effective Date: January 1, 2018

PROGRAM

APPLICABILITY: IMC 2515 App A

CORNERSTONE: Occupational Radiation Safety

INSPECTION BASIS: See IMC 0308, Attachment 2

SAMPLE

REQUIREMENTS:

Sample Requirements Minimum Baseline Sample

Completion Requirements

Budgeted Range

Sample Type Section(s) Frequency Sample Size Samples Hours

Radiological Hazard

Assessment

02.01 Annual 1 per site 1 per site 36 +/- 4 per site

Instructions to

Workers

02.02 Annual 1 per site 1 per site

Contamination and

Radioactive Material

Control

02.03 Annual 1 per site 1 per site

Radiological

Hazards Control

and Work Coverage

02.04 Annual 1 per site 1 per site

High Radiation Area

and Very High

Radiation Area

Controls

02.05 Annual 1 per site 1 per site

Radiation Worker

Performance and

Radiation Protection

Technician

Proficiency

02.06 Annual 1 per site 1 per site

Issue Date: 12/21/17 2 71124.01

71124.01-01 INSPECTION OBJECTIVES

01.01 Review and assess licensee performance in assessing the radiological hazards in the

workplace associated with licensed activities and the implementation of appropriate

radiation monitoring and exposure controls.

01.02 Verify that the licensee is properly identifying and reporting PIs for the Occupational

Radiation Safety Cornerstone.

01.03 To conduct a Routine Review of problem identification and resolution activities per

Inspection Procedure (IP) 71152, “Problem Identification and Resolution.”

71124.01-02 INSPECTION REQUIREMENTS

02.01 Radiological Hazard Assessment

a. Evaluate whether current station survey protocols are reasonable to identify the

magnitude and extent of radiation levels, concentrations or quantities of radioactive

materials, and the potential radiological hazard.

b. Determine if, since the last inspection, there have been changes to plant operations that

may result in a significant new radiological hazard for onsite workers or members of the

public. If a new hazard is identified, verify that, consistent with 10 CFR 20.1501, the

licensee has assessed the potential impact of these changes and has implemented

periodic monitoring to detect and quantify the radiological hazard.

c. Review two radiological surveys from each of 3-6 selected plant areas. Verify that the

thoroughness and frequency of the surveys is appropriate for the provided radiological

hazard.

d. Conduct walk-downs of the radiological control area (RCA)—including radioactive

waste processing, storage, and handling areas—and other areas of the facility to

evaluate material conditions and potential radiological conditions.

e. Select 3-5 radiologically risk significant work activities. Verify that appropriate pre-work

surveys were performed.

f. Evaluate the radiological survey program to determine if radiological hazards are

properly identified.

g. Select 3-5 air sample survey records and verify that samples are collected and counted

in accordance with licensee procedures. When possible, observe work in potential

airborne areas, and verify that air samples are representative of the breathing air zone

when used to assess dose.

h. Verify the licensee has a program for monitoring levels of loose surface contamination

in areas of the plant with the potential for contamination to become airborne.

Issue Date: 12/21/17 3 71124.01

02.02 Instructions to Workers

a. Review 3-5 radiation work permits (RWPs) used to access high radiation areas (HRAs)

and identify the work control instructions or control barriers and verify that workers have

been made aware of the RWP work restrictions, requirements and work area dose

rates.

b. Verify that electronic alarming dosimeter (EAD) dose and dose rate alarm set points are

based on current radiological survey data and plant procedures.

c. As available, review 3-4 occurrences where worker’s received valid EAD alarms. Verify

the licensee responded to EAD alarms as directed by plant procedures.

d. Verify that the licensee informs workers of changes in plant operations or radiological

conditions that could significantly impact their occupational dose.

e. Select 3-5 containers holding nonexempt, licensed radioactive materials that may cause

unplanned or inadvertent exposure of workers, and verify that they are labeled and

controlled in accordance with 10 CFR 20.1904, “Labeling Containers,” or meet the

requirements of 10 CFR 20.1905(g).

02.03 Contamination and Radioactive Material Control

a. Observe locations where the licensee monitors potentially contaminated material

leaving the RCA, and verify the methods used for control, survey, and release from

these areas are sufficient to control the spread of contamination and prevent the

unintended release of radioactive materials from the site.

b. Observe workers exiting the RCA and performing contamination monitoring. Verify that

there is guidance and that workers are knowledgeable on how to respond to an alarm

that indicates the presence of radioactive material.

c. Verify that radiation monitoring instrumentation has appropriate sensitivity for the

type(s) of radiation present and that instrumentation is used at its typical sensitivity

levels based on appropriate counting times and background radiation levels.

d. Select 2-3 sealed sources from the licensee’s inventory records that present the

greatest radiological risk. Verify that sources are accounted for and have been verified

to be intact (i.e., they are not leaking their radioactive content).

e. Verify that any transactions since the last inspection involving nationally tracked

sources were reported in accordance with 10 CFR 20.2207.

02.04 Radiological Hazards Control and Work Coverage

a. Verify that existing radiological conditions are consistent with posted surveys, RWPs,

and workers are complying with RWPs and pre-job briefings.

b. Verify the adequacy of surveys, radiation protection job coverage and contamination

controls during job performance observations.

c. During job performance observations, verify that personnel radiation monitoring devices

are placed on the individual’s body consistent with the method the licensee is

employing to monitor dose from external radiation sources.

d. For high-radiation work areas with dose rate gradients of a factor of 5 or more, review

the application of dosimetry to effectively monitor exposure to personnel. If available,

evaluate the work controls and dosimetry used for underwater diving activities with

severe dose gradients.

e. If available, evaluate 3-5 RWPs for work within airborne radioactivity areas to verify

adequate containment barrier integrity and temporary ventilation system operation.

Observe actual work in airborne or potentially airborne areas, as available.

f. Evaluate the licensee’s physical and programmatic controls for highly activated or

contaminated materials (non-fuel) stored within spent fuel pool and other storage pools.

Verify that appropriate controls (i.e., administrative and physical controls) are in place to

preclude inadvertent removal of these materials from the pool.

02.05 High Radiation Area and Very High Radiation Area Controls

a. Observe posting and physical controls for HRAs, HRAs with dose rates greater than 1

rem/hour, and very high radiation areas (VHRAs).

b. Inspect a representative selection of posting and physical controls for HRAs and

VHRAs to verify conformance with the Occupational PI and review the circumstances of

any occurrences that are potentially reportable under the licensee’s Occupational PI.

c. Review any procedural changes since the last inspection to determine the adequacy of

access controls for HRAs / VHRAs. Verify that any changes to licensee procedures did

not substantially reduce the effectiveness and level of worker protection.

d. Verify the adequacy of the controls in place for HRAs with dose rates greater than 1

rem/hour for compliance with technical specifications (T.S.) and licensee procedures.

This includes areas of the plant that have the potential to become risk-significant HRAs

during certain plant operations.

e. Verify the adequacy of the controls for high risk areas, such as for VHRAs, including

areas that have the potential to become VHRAs during certain plant operations. Verify

that an individual is unable to gain unauthorized access to any VHRA.

02.06 Radiation Worker Performance and Radiation Protection Technician Proficiency

a. During job performance observations, evaluate radiation worker performance and

awareness with respect to stated radiation protection work requirements.

b. Verify that workers are aware of their EAD dose and dose rate set points, and allowable

stay times or permissible dose for radiologically significant work under each RWP.

c. Verify that workers are aware of the guidance on how to respond to EAD alarms in

accordance with plant procedures.

d. During job performance observations, evaluate the performance and awareness of the

radiation protection technician with respect to all radiation protection work requirements.

e. Observe radiation protection technician performance of radiation surveys. Verify the

appropriateness of the instrument(s) being used, and verify instrument(s) used have

been calibrated and source checked.

02.07 Problem Identification and Resolution

For each sample, conduct a routine review of problem identification and resolution

activities using Inspection Procedure (IP) 71152, “Problem Identification and Resolution.”

71124.01-03 INSPECTION GUIDANCE

To the extent practicable, inspections should be scheduled to coincide with refueling outages or

other radiologically significant plant activities so as to maximize the opportunities for the

inspector to verify licensee performance through direct observation.

Note: Walk-downs and work activity observations required by Section 02.01, 02.02, 02.03,

02.04, 02.05, 02.06 and 02.07 should be performed together, to the extent practical.

Review all licensee PIs for the Occupational Exposure Cornerstone. For more information on

Performance Indicators, see NEI 99-02, “Regulatory Assessment Performance Indicator

Guideline” (ML13261A116) and information on changes in Frequently Asked Questions at

http://www.nrc.gov/reactors/operating/oversight/program-documents.html#pi.

Review the results of radiation protection program audits and review any condition reports

related to occupational radiation safety since the last inspection. The results of the radiation

protection program audit (e.g., licensee’s quality assurance audits or other independent audits)

and condition report reviews should be used to gain insights into overall licensee performance

and focus the inspector’s inspection activities on areas that are most likely to yield safetysignificant results, consistent with the principle of “smart sampling.” Annual radiation protection

program audits are required by 10 CFR 20.1101(c). NUREG/CR-6204, “Questions and Answers

Based on Revised 10 CFR Part 20,” (ML12166A179) provides further guidance on annual

program audits in Q&A # 118, #134, and # 380.

If any of the sample inspection requirements cannot be completed, the procedure should be

closed in accordance with IMC 0306, “Planning, Tracking and Reporting of the Reactor

oversight Process (ROP).” For example, if certain steps could not be completed due to sample

unavailability, the procedure attachment should be declared “Complete – full sample not

available” with a comment addressing the specific steps or activities that could not be

completed.

03.01 Radiological Hazard Assessment Sample

a. Survey protocol should consider the current and historical isotopic mix and isotopic

percent abundance, including current and historical presence of hard-to-detect

radionuclides and potential alpha hazards. See IP 71124.04 for further guidance on

source term determination.

Independent surveys (or having the licensee perform a supervised confirmatory survey)

may be performed on a limited basis when there is some doubt about the efficacy of the

licensee’s survey.

The inspector can assess the knowledge and skill of the Health Physics technicians

through discussions and observation of performance.

b. Changes in plant operations that may result in changes to the scope of radiological

hazards include but are not limited to the following:

o Degraded reactor fuel integrity that can result in hot particle contamination, or the

presence of transuranic nuclides (or other hard-to-detect radionuclides), for work

activities previously unaffected,

o Changes in reactor water chemistry (e.g., hydrogen injection in a BWR) that can

result in significant changes to the in-plant radiation source term,

o Significant onsite spills, or contamination of uncontaminated systems, that can

result in a new pathway for the release, or potential release, of radioactive

materials off site,

o Storage of radioactive materials in the owner-controlled area (e.g., remote or

satellite RCAs within the plant site), and

o Degraded material conditions of radwaste systems or other plant components

containing radioactivity.

c. No guidance provided.

d. Other areas to evaluate during walkdowns can include the protected area, controlled

area, contaminated tool storage, contaminated machine shops, satellite RCAs, and

infrequently accessed HRAs of the plant.

e. The results of the audit and condition report reviews should be used to gain insights into

overall licensee performance and focus the inspector’s inspection activities on areas

that are most likely to yield safety-significant results, consistent with the principle of risk

significance and “smart sampling.” An appropriate survey should be of the right type,

sensitivity and technique and the survey should enable adequate quantification of the

radiological hazard and establishment of protective measures.

f. Consider discussing with radiation protection staff (supervisors and technicians) the

procedures, equipment, and performance of radiation surveys for both routine and nonroutine activities. Technicians should be knowledgeable about when and how to survey

areas for:

1. Hot particles,

2. Alpha emitters,

3. Neutron radiation,

Issue Date: 12/21/17 7 71124.01

4. Airborne radioactivity, including the potential presence of transuranic

radionuclides and/or other hard-to-detect radionuclides,

5. Work activities that could suddenly and significantly increase radiological

conditions such as in-core detector movement, fuel moved in affected areas of

drywell or auxiliary building, movement of irradiated materials in the spent fuel

pool, and

6. Severe radiation field dose gradients that can result in non-uniform exposures.

g. If the licensee uses continuous air monitors (CAMs) to monitor real-time airborne

conditions, the CAM units should be properly located to serve their intended function,

and in low background areas to minimize false alarms. If the licensee uses skidmounted particulate, iodine, and noble gas (SPING)-type instruments to monitor

airborne conditions, the instrument should be serving its intended purpose, and the air

being monitored should be representative of the actual work areas.

Continuous air monitors positioned throughout the power plant are often used as initial

trending indicators of increasing airborne radioactive material levels. While identified

increases in airborne levels may not be dose significant (as indicated by the directly

measurable beta- and gamma-emitting radionuclides), power plants with known

transuranic contamination problems should consider and assess this transuranic

component when appropriate. This focus is especially vital during certain maintenance

activities in known transuranic-contaminated areas.

General area air samples are typically used by licensees to verify the effectiveness of

engineering controls to mitigate airborne radiological hazards at the work site.

Breathing zone air samples are necessary when the licensee assigns individual internal

doses from airborne concentrations of radioactive material.

See Information Notice (IN) 97-36, “Unplanned Intakes by Worker of Transuranic

Airborne Radioactive Materials and External Exposure Due to Inadequate Control of

Work,” June 20, 1997, for a discussion of previous problems and guidance in this area.

h. Licensees should have a program for monitoring levels of loose surface contamination

in areas of the plant with the potential for the contamination to become airborne.

Potential airborne radioactivity area activities may include entry into areas that are not

routinely entered and subject to previous contamination from failed fuel. The

information gained from completion of inspection requirement 02.01 will also provide

insights on radiological hazards and potential hazards that the licensee’s survey

program should assess.

03.02 Instructions to Workers Sample

a. The radiological controls (e.g., RWPs) for entry into high radiation areas may be plant

specific. Review plant T.S.s to determine the requirements for entry and work in HRAs;

e.g., authorization to enter into HRAs, EAD set points, pre-job briefings, continuous job

coverage, and stay time limitations.

Consider reviewing survey maps and attending pre-job briefings to observe instructions

to workers. Workers should be able to remember their work restrictions established on

the RWPs and as instructed in pre-job briefs (i.e., where they are allowed to work, what

they are allowed to do and what they are not allowed to do, and stop work conditions

(e.g., contact HP prior to system breach or worker actions that may cause a change in

radiological conditions).

b. The initial EAD set points (e.g., pre-outage) for EAD dose and dose rate alarms are

commonly set based on historical data. The EAD alarm set points should be adjusted

as needed based on actual dose rates and for changes in radiological conditions (e.g.,

during an outage).

c. Focus the review on valid EAD alarms. Malfunctions and invalid alarms are inspected

in IP 71124.04. The causes of EAD alarms should be evaluated; including validity of

the EAD alarms and worker compliance with access into HRA work locations and

permitted work activities. Follow-up investigations should be conducted as needed to

determine the actual radiological conditions for unexpected radiological hazards.

d. Changes in plant operations or plant conditions that may result in changes to

radiological hazards include:

1. Reactor head lifts, lifting or disassembly of reactor internals, fuel movement,

system breaches, in core detector movement or removal, control rod drive

replacement, temporary storage of highly radioactive material, resin sluicing and

filter changes, and loss of airborne radioactivity control (e.g., due to system

breach, lack or improper use of high-efficiency particulate air [HEPA] units, etc.),

2. Degraded reactor fuel integrity that can result in hot particle contamination, or the

presence of transuranic nuclides (or other hard to detect radionuclides), for work

activities previously unaffected,

3. Changes in reactor water chemistry (e.g., hydrogen injection in a BWR) that can

result in significant changes to the in-plant radiation source term,

4. Significant onsite spills, or contamination of uncontaminated systems, that can

result in a new pathway for the release, or potential release, of radioactive

materials off site,

5. Storage of radioactive materials in the owner-controlled area (e.g., remote or

satellite RCAs within the plant site, radioactive material or radioactive waste

stored in drums, taped plastic bags or other containers onsite awaiting release

offsite), and

6. Degraded material conditions of radwaste systems or other plant components

containing radioactivity.

e. Emphasis should be on the review of containers that have the potential for containing

the most significant radiological hazard (i.e., containers that provide shielding of the

source, or that contain significant amounts of loose contamination that could become an

airborne hazard). Containers that have the potential for containing the most significant radiological hazards (i.e., newly generated and temporarily stored containers in out-ofthe way locations such as in corners or under stairwells), or that contain significant

amounts of loose contamination that could become an airborne hazard should be

labeled and controlled. New containers with high dose rates generated during an

outage that create radiological hazards for workers must be labeled and area postings

updated.

03.03 Contamination and Radioactive Material Control Sample

a. 10 CFR Part 20 does not contain release limits for the release of contaminated material

to unrestricted areas; thus, the licensee’s criteria should be that no detectable licensed

radioactive material (radioactive gaseous and liquid effluents excepted) is released for

unrestricted use or as waste into an unrestricted area.

During plant tours, be aware of any openings in plant process buildings or structures

(e.g., containment equipment hatches) that may provide a means for the inadvertent

release of airborne radioactive material. The licensee’s program should ensure that

these openings maintain an inward airflow and are controlled to prevent inadvertent

releases. If the airflow is outward verify that monitoring is being performed in

accordance with RG 1.21, as appropriate. Also see procedure 71124.06 for additional

guidance. When possible, observe Health Physics personnel surveying and releasing

material for unrestricted use to ensure that the work is performed in accordance with

plant procedures and the procedures are sufficient to control the spread of

contamination and prevent the unintended release of radioactive materials from the site.

b. Review the licensee’s criteria for the survey and release of personal items using smallarticle monitors (SAMs). Workers should be provided guidance on how to use the

SAMs and they should be knowledgeable on how to respond to an alarm that indicates

the presence of licensed radioactive material. If workers are permitted to self-frisk

personal items, selectively consider observing one or two controls points to ensure that

workers are complying with applicable guidance and training.

c. During plant walk-downs, consider background dose rates; they should not excessively

interfere with the sensitivity of contamination monitoring equipment (e.g., friskers,

personnel contamination monitors). Contamination monitoring equipment for free

release of equipment and materials should be in a low background area. The licensee

should not have established a de facto “release limit” by raising the instrument’s

detection sensitivity through such methods as raising the energy discriminator level or

locating the instrument in a high-radiation background area.

Review the licensee’s equipment to verify that the radiation detection sensitivities are

consistent with the NRC guidance as follows:

1. IE Circular 81-07, “Control of Radioactively Contaminated Material,”

2. IN 85-92, “Surveys of Wastes Before Disposal from Nuclear Reactor Facilities,”

December 2, 1985, including surface contamination and final measurements of

aggregated waste,

3. Health Physics Position (HPPOS) 221 from NUREG/CR-5569, Rev. 1, “Health

Physics Positions Data Base,” May 1, 1992, for volumetrically contaminated

material, and

4. HPPOS-250 for radionuclides that decay via electron capture.

d. Licensees are require under 20.1501(a)(2) to conduct surveys that are reasonable

under the circumstances to evaluate the magnitude and extent of radiation levels;

evaluate quantities of radioactivity; and evaluate potential radiological hazards.

Some plants have T.S. requirements to inventory and leak test sources greater than a

certain activity (e.g., > 100 microcurie beta/gamma, and 5 microcurie alpha

activity). Other plants may have moved this requirement to a licensee controlled

document. In cases where the specific requirements, as stated in a plant’s license, are

different than the applicable regulations, licensees are obligated to meet the specific

requirements as stated in their license. Therefore, it is possible that a particular

licensee would be obligated to leak test sources that are otherwise exempt from leak

testing per NRC regulations because that licensee contains a provision in their T.S. that

generically states that sources above a certain level require leak testing.

The focus of this specific inspection requirement is on sealed sources that present the

greatest radiological risk in the event their leakage is not adequately

monitored. Devices that only contain exempt concentrations (10 CFR 30.14) or exempt

quantities (10 CFR 30.18); or certain devices that are exempt from NRC materials

licensing requirements under 10 CFR 30.15, 10 CFR 30.19, 10 CFR 30.20 or 10 CFR 30.22; or devices that contain generally licensed by-product materials that are exempt

from leak testing as described in 10 CFR 31.5(c)(2)(i) or (ii) do not require leak testing

per NRC regulations and do not fall within the scope of this inspection

requirement. Performance deficiencies that result from licensees failing to leak test

sources that require leak testing by a T.S. or a procedure, but are exempt per NRC

regulations specifically listed in this paragraph should be dispositioned as minor

violations.

Sealed sources in calibrators may contain levels of radioactivity that require additional

security measures in accordance with 10 CFR Part 37. Most calibrators are located

inside the protected area where adequate security is maintained per the station’s

security plans. However, some licensees have irradiators/calibrators that are located

outside the protected area. Control of these radioactive sources may need particular

review.

High activity irradiators/calibrators are required to be registered in the NRC Sealed

Source and Device Registry (SSDR). The SSDR lists which sources can be used in a

particular device, the frequency for leak tests, the ANSI Category (ANSI CAT I is a selfshielded irradiator whereas a CAT II would fall under 10 CFR Part 36, “Licenses And

Radiation Safety Requirements For Irradiators”), conditions of normal use, and other

information related to the use of the device.

Routine maintenance can be performed by licensee personnel, but non-routine

maintenance must be performed by the device manufacturer (or distributor) or a person

specifically authorized by NRC or an Agreement State. Source installations and source

reloads/exchanges (e.g., non-routine maintenance) can result in overexposures if not

Issue Date: 12/21/17 11 71124.01

done safely.

e. No guidance provided.

03.04 Radiological Hazards Control and Work Coverage Sample

a. During tours of the facility and review of ongoing work selected in 02.01 (above),

evaluate ambient radiological conditions, radiological postings (e.g., radiation areas,

radioactive material areas and associated radiation levels or potential radiation levels.

b. Adequate radiological controls include performing required surveys (e.g., radiation,

contamination and airborne), radiation protection job coverage (e.g., audio and visual

surveillance for remote job coverage) and contamination controls. Also, consider the

licensee’s use of EADs as HRA monitoring devices in high noise areas.

c. Dosimeters (e.g., thermoluminescent (TLD) dosimeters, optically stimulated

luminescence (OSL) dosimeters, etc.) should be placed in the location of highest

expected dose or the licensee should use an NRC-approved method of determining

effective dose equivalent (for external exposures) (EDEX). Inspectors should consider

the adequacy of the licensee’s criteria for utilization and placement of whole body and

extremity dosimeters, including their use in non-uniform radiation fields. In

10 CFR 20.1201(c), no work areas are exempt from the requirement to measure deep

dose equivalent (DDE) at the part of the body receiving the highest exposure.

d. While not a focus of this inspection, the licensee’s procedure should have reasonable

criteria for complying with 10 CFR 20.1201(c) for workers where dose rates are greater

than 10 millirem (mrem) per hour. Additionally, assuming a dose gradient of 1.5 or

more, it would not be reasonable to move the personal dosimeter (or provide for

additional dosimeters), unless an individual’s dose missed by not moving the dosimeter

was “significant” (e.g., 30 mrem for an individual for the work shift).

From a collective dose perspective (assuming a dose gradient of 1.5 or more), a

“missed” collective dose of 250 mrem or more for a job is a reasonable threshold action

criterion for the licensee to provide additional personal monitoring (or move the

dosimeter) to measure the highest DDE, consistent with 10 CFR 20.1201(c). The

licensee may be using an NRC-approved method of measuring effective dose

equivalent for external exposure (EDEX). The dosimeter placement should be

consistent with an approved method (see Regulatory Guide 8.40, “Methods for

Measuring Effective Dose Equivalent from External Exposure.

Consider underwater diving activities, where the dose rate gradients are severe,

thereby increasing the necessity of providing multiple dosimeters and/or enhanced job

controls.

e. Consider airborne radioactivity controls and monitoring, including potentials for

significant airborne levels (e.g., grinding, grit blasting, system breaches, entry into

tanks, cubicles, reactor cavities).

f. Potential focus areas include any work areas with a history of, or the potential for,

airborne transuranic radionuclides, or other hard-to-detect radionuclides. For these

selected airborne radioactive material areas, verify containment barrier integrity (e.g.,

tent or glove box) and temporary HEPA ventilation system operation.

Licensees may store highly activated materials (e.g., fuel channels and irradiated low

power range monitors) underwater on short-hangers, which could be inadvertently

raised to the pool surface. If unshielded, these materials could create an HRA or

VHRA.

Consider if the licensee is abiding by time limits that apply to items stored in the spent

fuel pool.

For applicable guidance and a history of previous events, see the following documents:

1. Regulatory Guide 8.38, Section C.4.2,

2. IN 90-33, “Sources of Unexpected Occupational Radiation Exposure at Spent

Fuel Storage Pools,” dated May 9, 1990, HPPOS-016 and HPPOS-245 in

NUREG/CR-5569, “Health Physics Positions Data Base” (ML093220108) and

HPPOS-333 at ADAMS Accession No. ML040760364); and

3. Questions and Answers number 447 and 448 in NUREG/CR-6204, “Questions

and Answers Based on Revised 10 CFR Part 20,” (ML12166A179).

03.05 High Radiation Area and Very High Radiation Area Controls Sample

a. These areas provide the potential for significant worker overexposures, and in some

cases, potentially lethal acute exposures. Posting and physical control requirements

and guidance are provided in the T.S.s, 10 CFR Part 20, specifically 20.1602, and

Regulatory Guide 8.38, as regards administrative controls, barrier enhancements, and

key controls.

b. Focus on verifying aspects of the licensee PIs associated with high-risk HRAs (greater

than 25 rem in 1 hour1.157407e-5 days <br />2.777778e-4 hours <br />1.653439e-6 weeks <br />3.805e-7 months <br /> at 30 centimeters from the source) and for all VHRAs. The intent

of this limited inspection oversight/requirement is to maintain continued NRC vigilance

of the licensee’s program and procedural controls and plant staff awareness of these

special, accessible areas where the potential for lethal overexposure exists. Do not

repeat this HP inspection requirement during the site wide annual PI verification team

inspection.

c. Focus on any procedural changes since the last inspection to determine the adequacy

of access controls for HRAs / LHRAs. Verify that any changes to licensee procedures

do not substantially reduce the effectiveness and level of worker protection.

d. Check on the adequacy of controls for HRAs greater than 1 rem/hour. Doors should be

locked, and or flashing lights installed in accordance with T.S. requirements.

e. High risk areas include:

1. Operationally transient areas of the plant such as radioactive waste processing,

handling and storage areas, tanks, etc.

2. Pressurized Water Reactors (PWRs) primary containments and Boiling Water

Reactors (BWRs) drywells may have separate controls in place for full power

operation, reduced power operations, and plant shut down or outage conditions.

3. Other vulnerable areas include, but are not limited to control of BWR traversing

in-core probe (TIP) areas, PWR thimble withdrawal areas, reactor cavity sumps,

fuel transfer areas, spent fuel pools, reactor cavities, and/or reactor storage pits.

Include the radiological controls implemented for workers entering containment

during power operations in your review.

4. The radiation fields in several of the above areas may also meet the dose rate

criteria necessary for VHRA controls, depending on plant operations and design.

Control of diving in these areas is also radiologically challenging and will require

communication beforehand with the HP group; so as to allow corresponding

timely actions to properly post, control, and monitor the radiation hazards

including re-access authorization. For more information, see:

a. NUREG-1736 “Consolidated Guidance: 10 CFR Part 20 – Standards for

Protection Against Radiation” sections 10 CFR 20.1601 and 10 CFR 20.1602 and Regulatory Guide 8.38, "Control of Access to High and Very

High Radiation Areas of Nuclear Plants,"

b. Regulatory Guide 8.38, Section C.4, Appendices A and B, for guidance for

specific work areas and activities that have documented histories of

worker overexposures, and

c. NUREG/CR-6204 (ML12166A179) and NUREG/CR-5569 (ML093220108).

03.06 Radiation Worker Performance and Radiation Protection Technician Proficiency Sample

a. Workers should be made aware of the significant radiological conditions in their

workplace and the RWP controls/limits in place and that their performance should

reflect the level of radiological hazards present.

b. Workers should be able to remember their EAD set points, stay time limitations, and

what they are required to do if they receive an EAD alarm.

c. Note: Some EAD alarms are anticipated for workers traversing a high dose rate work

area.

d. Consider if technicians are aware of the radiological conditions in their workplace and

the RWP controls/limits and if their performance is consistent with their training and

qualifications with respect to the radiological hazards and work activities.

e. No guidance provided.

03.07 Problem Identification and Resolution

Per IP 71152, it is expected that routine reviews of PI&R activities should equate to

approximately 10 to 15 percent of the resources estimated for the associated baseline

Issue Date: 12/21/17 14 71124.01

cornerstone procedures, this is a general estimate only based on the overall effort

expected to be expended in each strategic performance area. It is anticipated that the

actual hours required to be expended may vary significantly from attachment to

attachment, depending on the nature and complexity of the issues that arise at the

particular facility. Overall, an effort should be made to remain within the 10 to 15

percent estimate on a strategic performance area basis. Inspection time spent

assessing PI&R as part of the baseline procedure attachments should be charged to

the corresponding baseline procedure.

71124.01-04 REFERENCES

None

END

Issue Date: 12/21/17 Att 1-1 71124.01

Attachment 1 - Revision History for IP71124 Attachment 01

Commitment

Tracking

Number

Accession

Number

Issue Date

Change Notice

Description of Change Description of

Training Required

and Completion

Date

Comment Resolution and

Closed Feedback Form

Accession Number (PreDecisional, Non-Public

Information)

N/A 12/02/09

CN 09-030

Conducted four year search for commitments and

found none.

This new procedure is being issued as a result of

the 2009 ROP IP Realignment. It supersedes

inspection requirements in IP 71121 and 71122.

Yes

09/09/2009

ML092810383

N/A ML15344A189

02/19/16

CN 16-007

Major revisions to the IP 71124.01 procedure

attachment were made in response to the 2013

ROP Enhancement Project.

The revisions clarified the existing inspection

requirements and enhanced the inspection

guidance section. The revision also changes

how inspection samples are counted.

In addition, two feedback forms were

incorporated.

N/A ML15344A245

Closed FBF 71124.01-

1636

ML15352A047

Closed FBF 71124.01-

2132

ML15352A060

N/A ML17286A284

12/21/17

CN 17-031

Major editorial revision of IP 71124.01.

Added guidance applicable to leak testing

radioactive sources.

Section 02 was audited and modified to move

guidance to Section 03 and concisely state

actions necessary to complete each requirement.

Verbal discussion

of changes during

2017 HP

Counterpart

meeting,

09/06/2017

ML17300A479

Issue Date: 12/21/17 Att 1-2 71124.01

Commitment

Tracking

Number

Accession

Number

Issue Date

Change Notice

Description of Change Description of

Training Required

and Completion

Date

Comment Resolution and

Closed Feedback Form

Accession Number (PreDecisional, Non-Public

Information)

Added 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> to the total hours available to

complete this attachment annually. 4 hours4.62963e-5 days <br />0.00111 hours <br />6.613757e-6 weeks <br />1.522e-6 months <br /> were

moved from 71124.02.

Added table with inspection resources and

sample completion summary to the first page to

pilot new IP format in support of future updates to

IMC 0040.

PI&R was transitioned from an independent

sample to a requirement that would be completed

as part of each sample. Guidance section

updated to reflect resource estimates for routine

review of PI&R activities per IP 71152 Section

04.01.