| title = NRR E-mail Capture - (External_Sender) Supplemental Material for Today 2.206 Public Mtg

{{#Wiki_filter:NRR-PMDAPEm Resource From:                     Paul Gunter [paul@beyondnuclear.org]

Sent:                     Monday, June 29, 2015 10:44 AM To:                       Chereskin, Alexander Cc:                       Azulay/Jessica; Tim Judson

[External_Sender] Supplemental material for today 2.206 public mtg Attachments:               fitz_2206_2nd-prb-mtg_FINAL_06292015_pg-statement.doc; hydrogen-generation-safety-report.pdf Follow Up Flag:           Follow up Flag Status:               Flagged Hi Alex, Please find attached my statement for today meeting with the PRB and the referenced supplemental document.

I can shorten my oral statement to fit the time each of us is allotted See you soon.

[External_Sender] Supplemental material for today 2.206 public mtg Sent Date:              6/29/2015 10:43:51 AM Received Date:          6/29/2015 10:43:50 AM From:                  Paul Gunter Created By:            paul@beyondnuclear.org Recipients:

1 Statement of Paul Gunter, Beyond Nuclear Before the U.S. Nuclear Regulatory Commission Emergency Enforcement Petition Review Board Public Meeting As per 10 CFR 2.206 Re: James Fitzpatrick Nuclear Generating Station Docket 050-00333 Monday, June 29, 2015 Good afternoon. My name is Paul Gunter and I represent the Petitioner Beyond Nuclear based in Takoma Park, MD.

Fukushima Daiichi Units 1, 3 and 4 experienced hydrogen explosions.

4 licensing agreements for the containment performance criteria. It further deferred its commitment to maintain defense in depth at Fitzpatrick when the operator opted out of installing hardened containment vent, instead relying upon a pre-installed only partially hardened containment vent system. Given that Generic Letter 89-16 was implemented under 10 CFR 50.59, Fitzpatricks as-installed partial containment vent hardware was not inspected by NRC walk down, only a review of its design.

5 ISSUANCE OF ORDER TO MODIFY LICENSES WITH REGARD TO RELIABLE HARDENED CONTAINMENT VENTS CAPABLE OF OPERATION UNDER SEVERE ACCIDENT CONDITIONS super ceding EA 2012-050. EA 2013-109 provides for compliance dates for Phase I for the installation of a now enhanced reliable hardened containment vent on the wetwell component of the containment no later than June 30, 2018 and for Phase II compliance no later than June 30, 2019 for the installation of an optional unfiltered containment vent on the drywell component of the containment or an alternative mitigation strategy for Severe Accident Water Addition and Severe Accident Water Management that does not install a hardened vent but instead relies upon partial flood up of the drywell component while managing water addition to maintain freeboard in the wetwell so that the Phase I hardened vent remains operable to relieve an accidents high pressure, extreme temperature and non-condensable and combustible gases to the atmosphere. The wetwell vent does not have an external filter and relies upon the original designs scrubbing effect in the wetwell water to prevent radiological releases to the environment. The Petitioners now note the addition of a one and half year delay before full implementation of the Phase 1 wetwell hardened containment vent totaling up as an additional three years that Fitzpatrick will operate with the vulnerable Mark I pressure suppression containment system and the pre-existing partially hardened containment vent. The Petitioners reassert that extending the continued operation of Fitzpatrick with an unreliable containment under accident conditions represents undue risk to public health and safety in the interim and prompts the call for the suspension of the

The Petition Review Board accepts three of the Petitioners challenges to Fitzpatricks continued operation for review then holds the request for suspension of the operating license in abeyance. Those challenges are:

In each case, the Petition Review Board references the NRC Near Term Task Forces Recommendation 5.1 to order licensees to include reliable hardened containments vents on all Mark I and Mark II boiling water reactors namely Enforcement Action 2013-109 and Task Force Recommendation 6 for a long term review by NRC to identify insights about hydrogen control and mitigation inside containment or in other buildings as additional information is revealed through further study of the Fukushima Daiichi accident.

8 consequences that would affect large sectors of society, economy and the environment.

The matter of arriving at timely resolution to these unaddressed issues ranks high among the Petitioners concerns.

According to NRC presentations, the current challenges to the hydrogen gas problem include very little reliable empirical data on hydrogen is being reported since the Fukushima accident and any verifiable information on the chain of events at Fukushima may not be available for 10+ years.

In support of their petition, the Petitioners submit for the record Natural Resource Defense Councils technical report Preventing Hydrogen Explosions in Severe Nuclear Accidents: Unresolved Safety Issues Involving Hydrogen Generation and Mitigation. (March 2014) with findings that NRC and the nuclear industry are far from resolution by Recommendation 6.

Even after Fukushima Daiichis three devastating hydrogen explosions, the NRC has relegated its investigation of severe accident hydrogen safety issues to the lowest-priority of its post-Fukushima Daiichi accident response. The NRDC report finds that beyond adding reliable hardened containment vents to Fukushima-style reactors, it could take decades before the U.S. nuclear industry implements further hydrogen control measures.

9 A boiling water reactor like Fitzpatrick has several times more mass of zirconium in their reactor cores than larger pressurized water reactors like Indian Point Unit 3. A typical BWR core with 800 fuel assemblies would actually have more than the 76,000 kg of zirconium cited by the IAEA as typically present in a BWR core. It is the interaction of the zirconium fuel cladding with steam at high temperatures during a severe accident that generates the explosive hydrogen gas.

The NRDC technical report further finds that the NRC computer models under-predict hydrogen gas generation rates during severe accidents. Citing technical reports from Oak Ridge National Laboratory and the International Atomic Energy Agency which account for hydrogen gas generation during the evolution of a severe accident and how computer safety models under predict rates of hydrogen generation that would occur during the re-flooding of an overheated reactor core can cause hydrogen gas rates to vary by a large degree. NRDC points out that despite these reports, the NRC Near Term Task Force failed to discuss NRC computer safety models, like MELCOR, under predict such hydrogen gas generation rates thus undermining defense-in-depth with less conservative computer models. When hydrogen generation rates are underpredicted, hydrogen mitigation systems are not likely to be designed so that they could handle the generation rates that would occur in actual severe accidents.

As such, contrary to NRC and industry claims, the reliable hardened containment vent issue is not yet resolved and very likely prove as

10 troublesome to NRC and industry on holding to current implementation schedules and no more reliable than the wide variance of design of its predecessor. The NRDC report calls particular attention to severe accident scenarios where there is a rapid containment pressure increases and uncertainty for the diameter and thickness of a reliable containment vent line and more certainty for the lack of reliability of the as-built containment vent currently relied at Fitzpatrick for the next several years.

The NRDC report further illuminates that the current NRC enforcement action does not require that hydrogen be mitigated in the BWR secondary containment, also known as the reactor building, in severe accidents despite the multiple demonstrations and devastating consequence at Fukushima Daiichi. In line with the NRC defense-in-depth philosophy, hydrogen gas leakage from more than 150 penetrations in the Fitzpatrick Mark I primary containment and/or a hardened containment vent line needs to be considered and mitigated.

Severe nuclear accident hydrogen explosions remain an unresolved safety issue.

The NRDC report points out that during a severe accident, large volumes of water will be pumped into Fitzpatricks reactor core creating thousands of kilograms of steam. This large quantity of steam will initially create an inerting effect that can suppress and prevent hydrogen gas explosions. When the steam eventually condenses at some point in an accident, either naturally or by the use

11 of containment spray systems hydrogen combustion can occur with only a very small amount of energy from an electrical spark or a static electric charge, for example that caused the Hindenburg disaster.

NRDC REPORT                        MARCH 2014 R:14-02-B Preventing Hydrogen Explosions In Severe Nuclear Accidents:

Unresolved Safety Issues Involving Hydrogen Generation And Mitigation AUTHOR Mark Leyse NRDC Nuclear Program Consultant CONTRIBUTING EDITOR Christopher Paine Senior Nuclear Policy Adviser, NRDC

ACKNOWLEDGMENTS NRDC gratefully acknowledges the support of its work on nuclear safety from the Carnegie Corporation of New York, the Beatrice R. and Joseph A. Coleman Foundation, and the Independent Council for Safe Energy, a project of the Tides Center. The author thanks Christopher Paine, Matthew McKinzie, Jordan Weaver, Thomas Cochran, George Peridas, David Lochbaum, Gordon Thompson, and Robert Leyse for their suggestions and for reviewing this report; the author is particularly grateful to Mr. Paine for requesting that he write this report.

ABOUT NRDC The Natural Resources Defense Council (NRDC) is an international nonpro"t environmental organization with more than 1.4 million members and online activists. Since 1970, our lawyers, scientists, and other environmental specialists have worked to protect the worlds natural resources, public health, and the environment. NRDC has of"ces in New York City, Washington, D.C., Los Angeles, San Francisco, Chicago, Bozeman, MT, and Beijing and works with partners in Canada, India, Europe, and Latin America. Visit us at www.nrdc.org and follow us on Twitter @NRDC.

NRDCs policy publications aim to inform and in"uence solutions to the worlds most pressing environmental and public health issues. For additional policy content, visit our online policy portal at www.nrdc.org/policy.

NRDC Director of Communications: Lisa Benenson NRDC Deputy Director of Communications: Lisa Goffredi NRDC Policy Publications Director: Alex Kennaugh Design and Production: www.suerossi.com

TABLE OF CONTENTS I. EXECUTIVE  

...................................................................................................................................................................... 4 II. Hydrogen Generation in Nuclear Power Plant Accidents ............................................................................................................. 13 A. Technical  

Design Basis Accidents and the Zirconium-Steam Reaction .................................................................... 13 B. Severe Accidents and the Heat Produced by the Zirconium-Steam Reaction .............................................................................. 17 C. Hydrogen Generation in Accidents: Rates and Quantities ............................................................................................................ 17 D. NRC Models Underpredict Severe Accident Hydrogen Generation Rates ................................................................................... 18 E. An Attempt to Eliminate Hydrogen Risk: Developing Non-Zirconium Fuel Cladding .................................................................... 19 III. Severe Accident Hydrogen Explosions: An Unresolved Safety Issue .......................................................................................... 20 A. The Potential Damage of Missiles Propelled by Hydrogen Explosions ......................................................................................... 20 B. Hydrogen Explosions: De"agrations and Detonations .................................................................................................................. 21 C. Limitations of Computer Safety Models to Predict Hydrogen Distribution in the Containment and Hydrogen De"agration-to-Detonation Transition ..................................................................................... 22 IV. Severe Accident Hydrogen Mitigation ............................................................................................................................................ 23 A. Hydrogen-Mitigation Strategies for Different Containment Designs ............................................................................................ 23 Case Study: Hydrogen Risks in Westinghouses Probabilistic Risk Assessment for the AP1000 and Plans for Managing an AP1000 Severe Accident .......................................................................................... 29 B. Problems with Current Hydrogen-Mitigation Strategies for Respective Reactor Designs............................................................ 30 C. Monitoring Core Degradation and Hydrogen Generation in Severe Accidents ............................................................................. 36 V. NRDCs Recommendations for Reducing the Risk of Hydrogen Explosions in Severe Nuclear Accidents .............................. 40 A. Develop and Experimentally Validate Computer Safety Models that Would be Capable of Conservatively Predicting Rates of Hydrogen Generation in Severe Accidents ....................................................................... 40 B. Assess the Safety of Existing Hydrogen Recombiners, and Potentially Discontinue the Use of PARs until Technical Improvements are Developed and Certi"ed .............................................................................. 40 C. Signi"cantly Improve Existing Oxygen and Hydrogen Monitoring Instrumentation...................................................................... 40 D. Upgrade Current Core Diagnostic Capabilities in Order to Better Signal to Plant Operators the Correct Time to Transition from Emergency Operating Procedures to Severe Accident Management Guidelines................................................................................................................................ 40 E. Require All Nuclear Power Plants to Control the Total Quantity of Hydrogen that Could be Generated in a Severe Accident .................................................................................................................................... 41 F. Require that Data from Leak Rate Tests be used to Help Predict the Hydrogen Leak Rates of the Primary Containment of each BWR Mark I And Mark II Licensed by the NRC in Different Severe Accident Scenarios ................................................................................................................................ 41 3 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

I. EXECUTIVE  

A s demonstrated during the March 2011 severe nuclear accident in Fukushima, Japan, accumulation and subsequent detonation of hydrogen gas produced by an overheated nuclear core reacting with steam can breach a reactors containment structures and result in widespread radioactive contamination.1 The gas is initially generated by the rapid oxidation of the zirconium alloy tubes (fuel cladding) that surround the low-enriched uranium fuel pellets in commercial power reactors (Figure 1).

When the fuel cladding enters a certain temperature range       water reactor (BWR) designs, this discharge is initially into well above its typical operating temperature, the zirconium-       the pressure suppression pool or wetwell portion of the steam reaction becomes autocatalytic, meaning that it             primary containment.3 propagates via self-heating from the chemical reaction itself.         In the March 2011 Fukushima Daiichi accidentin This produces large quantities of hydrogen in a brief period.       which the cores of three GE-designed boiling water reactors This intense reaction also causes the fuel cladding to erode       lost all cooling and melted downhydrogen leaked from and breach, which releases harmful levels of radionuclides         the primary containments into the reactor buildings.

into the reactor vessel. The fuel cladding is the "rst line of     The hydrogen accumulated in the reactor buildings and defense among multiple barriersthe reactor vessel, a steel         detonated, causing large releases of harmful radionuclides and/or reinforced concrete containment, and a further,           that contaminated a wide area and prompted the evacuation secondary containment in some designs2that are intended            of some 90,000 people. A smaller hydrogen explosion also to prevent release to the environment of the biologically          occurred in the March 1979 Three Mile Island Unit 2 (TMI-2) hazardous radionuclides produced by nuclear "ssion (see            accidenta partial core meltdown of a pressurized water Figure 2). In some accident scenarios, over-pressurization          reactor (PWR)that did not breach the containment.

of the reactor vessel can be exacerbated by the buildup                The U.S. Nuclear Regulatory Commission (NRC) has a of hydrogen from the zirconium-steam reaction, causing              checkered history when it comes to requiring measures that seals at the multiple penetrations of the vessel required for      would effectively reduce the risk of hydrogen explosions reactor monitoring and control to leak hydrogen into the            in the event of a severe accident at a U.S. nuclear power containment.                                                        plant. This regulatory lapse is rooted in the history of the development of commercial nuclear power in the United Figure 1: Structure of a Uranium Fuel Assembly States, when the NRCs predecessor agency, the Atomic Energy Commission (AEC), had a dual mandate: both to promote and to regulate commercial nuclear power.

As a consequence of this internal con"ict of interest, rather than consult independent scienti"c and technical institutions, the AEC entrusted two companies that designed nuclear reactorsWestinghouse and General Electric (GE) with the mission of demonstrating that in a large-pipe-break loss-of-coolant accident (LOCA), the emergency core-cooling systems for their respective reactor designs would in fact prevent overheating of the core, and hence prevent the generation of large quantities of explosive hydrogen gas.

In response to the TMI-2 partial meltdown in 1979, the NRC revised its regulations regarding the control of hydrogen in an effort to help prevent hydrogen explosions in severe nuclear accidents. In 1981, the NRC issued a requirement that Source: NRC                                                        GE-BWRs with the small-volume Mark I and somewhat larger Mark II containments operate with their atmospheres inerted To protect the integrity of the reactors cooling system,        with nitrogen, to minimize the risk of hydrogen combustion.

pressure relief valves are designed to open automatically,          In 1985, the NRC required installation of hydrogen igniters resulting in discharge of radioactively contaminated steam          systems to burn off leaked hydrogen before it accumulates and hydrogen gas into the containment. In older boiling 4 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

fourth line of defense Primary containment (drywell): third line of defense Reactor pressure vessel (RPV), enclosing nuclear core: second line of defense Primary containment torus (wetwell): part of third line of defense, relieving gas pressure buildup in undersize drywell Source: NRC Reactor Concepts Manual, Rev. 0200 to explosive concentrationsin pressurized water reactor            years, or even decades, before the U.S. nuclear industry (PWR) ice condenser containments and GE-BWR Mark III              implements further hydrogen control measures.

Figure 3: Cutaway View of a GE Mark II BWR with Uni"ed Concrete Drywell/Wetwell Primary Containment Design This design is deployed at Limerick Units 1 and 2, Susquehanna 1 and 2, and Nine Mile Point 2.

Reactor vessel Drywell Vent pipes to wetwell Water level Wetwell Source: Containment Integrity Research at Sandia National Laboratories - An Overview, NUREG/CR-6906 6 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

evidence that current reactor computer In 1972, the chief nuclear safety analyst for the AEC safety models do not accurately predict the onset of rapid recommended discouraging further use of the type hydrogen generation in severe nuclear accidents, and that of primary containments used in the GE-BWR Mark I they under-predict the rates of hydrogen generation that and Mark II designs, claiming they were susceptible to occur in such accidents; overpressurization. One reason these containments are Q a n aging "eet of U.S. reactors that will increasingly operate    vulnerable is that their volumes are relatively small: typically beyond the 40-year term of their initial licenses while            about one-ninth and one-sixth the volume, respectively, facing severe competitive pressures from other electricity        of PWR large dry containments. In September 1989, the generation technologies, creating a perilous tradeoff              NRC publicly acknowledged that BWR Mark I primary between economic viability and public safety;                      containments might not be able to withstand the internal gas Q t he compromised ability of 40-year old containments to          pressures that would build up in severe accidents. However, prevent hydrogen leakage (for example, at the seals of            at the time, the NRC merely issued guidance that was not pipe and cable penetrations) under the elevated-pressure          legally binding, recommending that owners of BWR Mark I conditions that are expected to occur in severe accidents;        designs on their own initiative install a hardened vent to the external environment for each reactor units doughnut-Q t he apparent willingness of the NRC to accede to licensee shaped wetwellto reduce the internal gas pressure and requests to relax and defer requirements for periodic remove decay heat in the event of a severe accident.

containment pressurization and leak rate testing; and In the United States, the vents currently installed in each Q t he lack of technical readiness of U.S. power reactor            BWR Mark I wetwell (see Figure 1) do not have a standardized owners to detect and control dangerous concentrations              design, are not out"tted with high-capacity "lters to prevent of hydrogen in all the places where it could migrate and          the release of harmful radionuclides in accidents, are not explode in a nuclear power plant.                                  subject to NRC inspection for proper maintenance and We conclude that the NRC is failing to meet the statutory          continuing operability, and do not have an independent train standard of adequate protection of the public against the          of backup power sources to help ensure remote operation hazard of hydrogen explosions in a severe reactor accident.          during a station blackout (i.e., a total loss of both grid-Our reasons are summarized below and set forth in more                connected and backup alternating current power at a nuclear detail in the body of this report.                                    power plant).

As overall leak-rate tests demonstrate, GE-BWR Mark

: 1. NRC computer safety models underpredict the rates of              I and Mark II primary containments are not designed to hydrogen generation that have occurred in experiments                prevent hydrogen leakage in accidents. These tests are legally simulating severe nuclear accidents.                                  required at U.S. nuclear power plants for determining how Reports from the Oak Ridge National Laboratory (1997), the            much radiation would be released from the containment OECD Nuclear Energy Agency (2001), and the International              in a design-basis accident (i.e., an anticipated accident in Atomic Energy Agency (IAEA) (2011) support the conclusion            which, by design, a core melt would be prevented). In overall that current computer safety models underpredict the rates            leak rate testsconducted below their nominal design of hydrogen generation that may occur in severe accidents            pressuresBWR Mark I and Mark II primary containments when zirconium fuel cladding and other core components                have been shown to leak hundreds of pounds of air per react with steam, especially during a re-"ooding of an                day. For example, in 1999, tests conducted at Nine Mile overheated reactor core. Unfortunately, the NRCs 2011                Point Unit 1 (a BWR Mark I) and at Limerick Unit 2 (a BWR Recommendations for Enhancing Reactor Safety in the 21st              Mark II) found that overall leakage rates at both units Century: Near-Term Task Force Review of Insights from the            exceeded 350 pounds of air per day, an amount that is less Fukushima Daiichi Accident and subsequent Fukushima                  than the maximum allowed leak rates. This means that in a safety review documents do not discuss the fact that the              severe accident, even if there were no damage to a primary NRCs computer safety modelssuch as the widely used                  containment, hydrogen would leak into the secondary MELCOR code developed by Sandia National Laboratories                containment (reactor building). Leak rates would increase underpredict the hydrogen generation rates that occur in              as the internal pressure increased, and they would become severe accidents. By overlooking the de"ciencies of computer          even greater if the seals at the various piping and cable safety models, the NRC undermines its own philosophy                  penetrations were damaged. (Typical BWR containments of defense-in-depth, which requires the application of                have 175 penetrations, almost twice as many as typical PWR conservative models. When hydrogen generation rates are              containments.)

underpredicted, hydrogen mitigation systems are not likely to be designed so that they can handle the hydrogen gas generation rates that would occur in actual severe accidents.

Figure 4: Internet Images of the Fukushima Daiichi Nuclear Power Station from the Ocean Side Before and After the March 2011 Tsunami and Hydrogen Explosions Destroyed (from Right) Units 1, 3, and 4 A plume is visible coming from a blown-out shield building panel in the side of the Unit 2 reactor, which, while still intact, also experienced a core melt.

Photo credits: top, unknown; bottom, Digital Globe 8 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

: 3. GE-BWR Mark I and II containments perform poorly in                  In a nuclear power plant accident, a mixture of leak rate tests, yet the NRC is planning to further relax            hydrogen, nitrogen, and steam could leak from the primary requirements for leak rate testing.                                  containment; as internal pressures increase and the accident BWR Mark I primary containments have failed a number of              progresses, the concentration of hydrogen in the leaking overall leak rate tests; for example, Oyster Creekthe oldest        mixture would increase. If there were no damage to the operating commercial reactor in the United States, which is          primary containment, the quantity of hydrogen that leaked considered to be quite similar to Fukushima Daiichi Unit 1          (by weight) would be relatively small, because hydrogen is has failed at least "ve tests. In one test, Oyster Creeks primary  about one-fourteenth as dense as air. However, a secondary containment leaked at a rate 18 times greater than its design        containment could be breached if, for example, only 20 to 40 leak rate; if this test was conducted at the same pressure          pounds of hydrogen were to leak into it, accumulate locally, as subsequent Oyster Creek tests, which seems likely, the            and explode.

primary containment leaked more than 6800 pounds of air per day. Such results raise the questions: What were            4. Large-volume PWR dry containments, made of the observed pre-accident leak ratesbelow design                    reinforced concrete with a steel liner, are a prominent pressureof the three primary containments that leaked              safety feature of many U.S. nuclear power plants; hydrogen at Fukushima Daiichi? Could there have been                however, they are not necessarily invulnerable to the excessive hydrogen leakage at one or more of the primary            effects of hydrogen explosions.

containments, without it becoming overpressurized?                  The NRC mistakenly claims that the large containment Since the Fukushima Daiichi accident, the problem of              volumes of most PWRsa reactor design found in about hydrogen leakage from primary containments has still not            two-thirds of the U.S. nuclear "eetwould keep the been adequately addressed. Mark II primary containments              pressure spikes from potential hydrogen explosions within must also be assessed as likely to incur hydrogen leaks              their design pressures. But this claim is predicated on an in severe accidents. Nevertheless, the NRC is currently              uncertain and therefore misplaced assumption that hydrogen preparing to extend the intervals at which overall and local        combustion would occur in the form of a de"agration, a leak rate tests must be conducted to once every 15 years            combustion wave traveling at a subsonic speed relative to the (from the current 10 years) and once every 75 months (from          unburned gas.

the current "ve years), respectively. This will only further            However, when local hydrogen concentrations are decrease the safety margin of BWR Mark I and Mark II                greater than about 10 percent by volume, it is possible for a designs. In its safety analyses to assess extending the test        de"agration to transition into a detonation, a combustion intervals, the NRC overlooked the fact that BWR Mark I and          wave traveling at a supersonic speed relative to the unburned Mark II primary containments are particularly vulnerable to          gas. Unfortunately, in a severe accident, a hydrogen hydrogen leakage.                                                    detonation could occur within a PWR large dry containment In a severe accident, BWR Mark I primary containments            if there were elevated local hydrogen concentrations, that leak excessively in tests conducted below their design          especially in the presence of carbon monoxide and high pressure would leak dangerous quantities of explosive                temperatures; this could cause internal pressure spikes to hydrogen gas into secondary containments; however,                  exceed twice the containments design pressure.

the NRC does not seem concerned about these excessive                    Furthermore, a local hydrogen explosion occurring inside leakage rates. A 1995 NRC report, NUREG-1493, concluded              the containment could propel debris, such as concrete blocks that increasing allowable leakage rates by 10 to 100 times          from internal walls, into the containment structure at high results in a marginal risk increase, while reducing costs            velocities. The impact of such internally generated missiles by about 10 percent [emphasis added]. And a 1990 NRC                could damage essential safety systems and severely crack a report, NUREG-1150, concluded that even if there is leakage          PWRs containment.

equivalent to 100 percent of the contained gas volume per                According to a 2011 IAEA report on the mitigation of day, the calculated individual latent cancer fatality risk          hydrogen hazards in severe nuclear accidents, no analysis is below the NRCs safety goal. But this safety goal clearly        ever has been made on the damage potential of "ying objects would not be achieved if leaking hydrogen were to detonate          generated in an explosion of hydrogen. Yet we know from in the reactor buildings, as it did at Fukushima Daiichi.           the Fukushima Daiichi accident that debris propelled from In March 2013, the NRC asserted that [s]ensitivity              hydrogen detonations caused extensive damage to backup analyses in NUREG-1493 and other studies show that light            emergency power supplies and hoses that were intended water reactor accident risk is relatively insensitive to the        to inject seawater into overheated reactors. Some of the containment leakage rate because the risk is dominated              debris dispersed around the site by explosions was highly by accident sequences that result in failure or bypass of            radioactive, exposing personnel to higher dose rates and containment [emphasis added]. In reality, the progression          setting back their efforts to control the accident.

of the Fukushima Daiichi accident was indeed affected by                As nuclear safety expert David Lochbaum has noted, the leakage of hydrogen gas. The evidence suggests that Unit        During design basis accidents, the response of operators 3s primary containment did not fail before hydrogen leaked          and workers is primarily passiveverifying that automatic into the Unit 3 reactor building and detonated. The internal        equipment actions have occurred. In essence, workers are pressure of Unit 3s primary containment actually increased          observers during design basis accidents. During severe after the hydrogen explosion occurred.                              accidents, workers get off the bench and into the game.

The keystone of [the U.S. nuclear] industrys response to          hydrogen as it is generated in an accident, before it can reach Fukushima is FLEX, an array of portable components                concentrations at which combustion would threaten the moved into place by workers. Inadequate hydrogen control            integrity of the less sturdy containment. In a severe accident, during a severe accident would seem to render FLEX                  to safely actuate hydrogen igniters, operators would need virtually useless.4                                                to know the local concentration of hydrogen in the vicinity of each igniter; if igniters were actuated too lateafter local

accidents is not risk-signi"cant. Indian Point on the Hudson          Furthermore, GE-BWR Mark I and Mark II designs operate River near New York City is the only nuclear power plant in        with hydrogen monitors installed only in their inerted the United States that currently operates with PARs. The new        primary containments, not in their reactor buildings. In the Westinghouse AP1000 design, under construction in Georgia,          Fukushima Daiichi accident, hydrogen from three nuclear South Carolina, and China, is intended to operate with only        units leaked into these buildings and exploded.

temperatures exceeded 3300°F.                                        In line with the conclusions of the NRCs own Advisory In a severe accident, plant operators are supposed to            Committee on Reactor Safeguards (ACRS), the NRC should implement SAMGs before the onset of the rapid zirconium-            reclassify oxygen and hydrogen monitors as safety-related steam reaction, which leads to thermal runaway in                    equipment that must undergo full quali"cation (including the reactor core. Clearly, using core-exit thermocouple              seismic quali"cation), have redundancy, and have has its own measurements in order to detect inadequate core cooling              independent train of emergency electrical power.

or uncovering of the core is neither reliable nor safe. For            The current NRC requirement that hydrogen monitors be example, PWR operators could end up re-"ooding an                    functional within 90 minutes of emergency cooling water overheated core simply because they do not know the                  injection into the reactor vessel is clearly inadequate for actual condition of the core. Unintentionally re-"ooding an          protecting public and plant worker safety. Following onset of overheated core could generate hydrogen, at a rate as high          an accident, NRC regulations should require that hydrogen as 5,000 grams per second, and the containment could be              monitors be functional within a timeframe that enables compromised if large quantities of that hydrogen were to            immediate detection of quantities of hydrogen indicative of detonate, as occurred at Fukushima.                                  core damage and a potential threat to containment integrity.

The NRC should also require hydrogen monitoring instrumentation to be installed in:

: 3. any plant structure where it would be possible for A. The NRC should develop and experimentally validate                      hydrogen to enter.5 computer safety models that can conservatively predict rates of hydrogen generation in severe accidents.

D. Current core diagnostic capabilities require upgrading The NRC needs to acknowledge that its existing computer to provide plant operators a better signal for when to safety models underpredict the rates of hydrogen generation transition from emergency operating procedures to that occur in severe accidents. The NRC should conduct a severe accident management guidelines.

series of experiments with multi-rod bundles of zirconium The NRC should require plants to use thermocouples placed alloy fuel rod simulators and/or actual fuel rods as well as at different elevations and radial positions throughout study the full set of existing experimental data. The NRCs the reactor core to enable plant operators to accurately objective in this effort should be to develop models capable measure a wide range of temperatures inside the core of predicting with greater accuracy the rates of hydrogen under both typical and accident conditions. In the event generation that occur in severe accidents.

of a severe accident, in-core thermocouples would provide plant operators with crucial information to help them track B. The safety of existing hydrogen recombiners should be the progression of core damage and manage the accident, assessed, with the use of PARs potentially discontinued indicating, in particular, the correct time to transition from until technical improvements are developed and certi"ed.

Experimentation and research should be conducted in order to improve the performance of PARs so that they E. The NRC should require all nuclear power plants to will not malfunction and incur ignitions in the elevated control the total quantity of hydrogen that could be hydrogen concentrations that occur in severe accidents.              generated in a severe accident.

The NRC and European regulators should perform safety                The NRC should require all nuclear power plants to analyses to determine if existing PARs should be removed            operate with systems for combustible gas control that from plant containmentsand, if so, whether they should              would effectively and safely control the total quantity of be replaced with electrically powered thermal hydrogen              hydrogen that could potentially be generated in different recombiners that have their own independent train                    severe accident scenarios; and to have strategies for venting of emergency power. The latter course would require                  gas from the inerted primary BWR Mark I and Mark II operators to have instrumentation capable of providing              containments without causing signi"cant radiological timely information on the local hydrogen concentrations              releases. The NRC should also require nuclear power plants throughout the containment, so they could deactivate the            to operate with systems for combustible gas control that thermal recombiners when hydrogen concentrations reached            are capable of preventing local concentrations of hydrogen the levels at which the recombiners malfunction and incur            in the containment from reaching concentrations that ignitions.                                                          could support explosions powerful enough to breach the containment, or damage other essential accident-mitigating 11 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

features. Hydrogen explosions are not expected to occur              The rationale for this requirement is obvious: Hydrogen inside the primary BWR Mark I and Mark II containments,          explosions, or hydrogen concentrations in the reactor which operate with inerted atmospheres, unless somehow            building that pose a detonation risk, can severely inhibit oxygen is present.                                                emergency response actions essential to containing the The NRC should require licensees who operate nuclear          accident. Or even worse, emergency response actions power plants with hydrogen igniter systems to perform            themselves, such as hooking up portable power equipment, analyses demonstrating that these systems would effectively      could actually provide the spark for hydrogen explosions in and safely mitigate hydrogen in different severe accident        critical areas of the plant.

scenarios. Licensees unable to do so would be ordered to            The NRC should also end its practice of allowing repairs upgrade their systems to adequate levels of performance.          to be made immediately before leak rate tests are conducted to evaluate potential leakage paths, such as containment F. The NRC should require that data from leak rate tests          welds, valves, "ttings, and other components that penetrate be used to help predict the hydrogen leak rates of the            containment. This repair before test practice obviously primary containment of each BWR Mark I and Mark II                defeats the nuclear safety objective of providing an accurate licensed by the NRC in different severe accident scenarios.      statistical sample of actual pre-existing containment leak The NRC should require that data from overall leak rate tests    rates.

and local leak rate testsalready required by Appendix J            Finally, the NRC should reconsider its plan to extend the to Part 50 for determining how much radiation would be            intervals of overall and local leak rate tests to once every released from the containment in a design basis accident        15 years and 75 months, respectively. The NRC needs to also be used to help predict hydrogen leak rates for a            conduct safety analyses that consider BWR Mark I and Mark range of severe accident scenarios involving the primary          II primary containments are vulnerable to hydrogen leakage.

containments of each GE-BWR Mark I and Mark II licensed          It also seems probable that as old reactors are kept in service by the NRC. If data from an individual leak rate test were to    beyond their original licensed lifetimes, the intervals between indicate that dangerous quantities of explosive hydrogen          leak rate tests should be shortened rather than extended.

12 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

II. HYDROGEN GENERATION IN NUCLEAR POWER PLANT ACCIDENTS A. TECHNICAL BACKGROUND: DESIGN                                            located in the reactor core as long as a suf"cient "ow of coolant is maintained.8 BASIS ACCIDENTS AND THE ZIRCONIUM-U.S. nuclear power plants are referred to as light water STEAM REACTION                                                            reactors because they use ordinary water (H2O), as opposed In typical operating conditions at a nuclear power plant,                  to heavy water (2H2O or D2O), as a coolant. In a boiling highly pressurized coolant6 water is pumped through the                    water reactor like those that suffered hydrogen explosions reactor coolant system7 piping into the reactor pressure                  at Fukushima, the coolant exits the reactor core as a steam-vessel where it "ows between the fuel rods, carrying away                  water mixture. Water droplets are removed in a steam heat produced by the "ssion (splitting) of uranium (235U)                  dryer located above the core, and then the steam passes atoms in the fuel. The coolant waters temperature exceeds                through the steam line to the main turbine, which powers an 500°F; nonetheless, it still provides cooling for the fuel rods            electric generator, and is condensed back into water before reentering the core (see Figure 5).

Figure 5: Schematic Diagram of Heat Removal from a Boiling Water Reactor (BWR)

Heat is removed during normal operation by generating steam, which rises to the top of the reactor vessel (1), and is then used directly (red line) to drive a turbine (2) that spins an electrical generator. When a reactor shuts down, however, the core continues to produce heat from radioactive decay. This decay heat is removed initially by bypassing the turbine and delivering the steam directly to the condenser (3), which is cooled by water pumped from lakes, rivers, or ocean (green), with the condensed steam (blue) returning to the reactor as coolant (4). When steam pressure drops to approximately 50 pounds per square inch, the residual heat removal (RHR) system (5) is used to complete the cool-down process. Water in the normal coolant recirculation loop (6) is diverted from the recirculation pump to the RHR pump which sends it through a supplementary heat exchanger and back to the reactor.

In a pressurized water reactor the coolant typically                       Reactor cores have tens of thousands of uranium fuel rods, circulates to and from the reactor in two to four closed                   bundled together into fuel assemblies. For example, each primary loops, where it is maintained at a pressure high                 reactor at Indian Point Energy Center near New York City has enough to prevent the water from boiling. Each primary loop                 87 metric tons of fuel contained in 193 fuel assemblies (each has a steam generator (heat exchanger) where the coolant                    with 204 fuel rods), or almost 40,000 fuel rods. The cladding heats and boils water circulating through a secondary loop                of the fuel rods is made of zirconium alloy.9 The fuel cladding maintained at a lower pressure than the primary loop                      is a thin tube, typically with a diameter of less than half an producing pressurized steam to spin the main turbine and                    inch, sheathing small cylindrical uranium-dioxide fuel pellets generate electricity (see Figures 6 and 7).                                stacked one on top of the other. The active fuel region of Both reactor types have main condensers to condense the                the fuel rods (the length of the cladding containing the fuel steam back into water after it exits the turbines; this water              pellets) is approximately 12 feet long.

is pumped back to the reactor pressure vessel (in a BWR) or                    In sum, a reactor core contains large amounts of zirconium steam generator (in a PWR). The main condensers of both                    metal that can react with steam at high temperatures to BWRs and PWRs rely on vast amounts of water, drawn from                    produce vast quantities of hydrogen gas. In the event of a local water body such as a lake, river, or ocean. This water              a design basis accident,10 BWR and PWR emergency core may be returned directly to the local water body at elevated                cooling systems are designed to inject and circulate water temperatures, sometimes damaging the local ecology;                        through the reactor core to prevent the fuel rods from alternately, cooling towers may be deployed to remove heat                  overheating when the normal reactor cooling system ceases from this water. Roughly two-thirds of the thermal energy                  to function. The respective emergency core cooling systems produced by a nuclear reactor is not converted into electricity            are required to mitigate a number of postulated design-basis but rather is discharged to the environment as waste heat.                  accidents, including the worst-case scenario envisioned Figure 6: Simpli"ed Schematic Diagram of a Westinghouse Pressurized Water Reactor (PWR) with Three Intersecting Heat Transfer Heat Loops PWR designs typically have two to four primary loops and a corresponding number of steam generators and main coolant pumps.

Water in the primary loop is maintained by the pressurizer at around 2250 pounds per square inch, about twice the pressure of a BWR. Weak points in this system from a radiation containment perspective are the numerous valves and penetrations of the reactor vessel required to control and cool the reactor; the seals of the main coolant pumps, which must be actively cooled and are prone to leakage; and the thousands of small-diameter, thin-walled primary loop steam tubes in the steam generators, which are prone to erosion and leakage into the secondary loop. The tertiary loop can be open, returning heated water from the turbine condenser directly to a local river, lake, or bay; or closed, utilizing one or more wet (evaporative) or dry (fan-driven air) cooling towers (not shown) to recycle the tertiary coolant in a semiclosed loop (makeup water must be added to the system due to evaporative losses).

Source: The Westinghouse Pressurized Water Reactor Nuclear Power Plant, page 4 14 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

To set the scale, the interior of the reactor vessel is about 15 feet wide by 40 feet high. U.S. examples include Indian Point Units 2 and 3 (New York), Vogtle Units 1 and 2 (Georgia), Comanche Peak Units 1 and 2 (Texas) and Diablo Canyon Units 1 and 2 (California).

Reactor pressure vessel (2) and primary coolant loop piping are shown in red; main steam lines (in blue) are shown coming from the top of the steam generators (3),

shown in light green. These are supplied by the feedwater system (dark green piping), which also cools the spent fuel pool (4) and main coolant pump seals (dark green). The turbine building (5) encloses a steam-driven turbine generator unit (in purple) with a rated output of 1500 MWe. The tertiary cooling loop for the turbine steam condenser is not shown.

PRODUCED BY THE ZIRCONIUM-STEAM                                            The NRC needs to consider that not all severe accidents REACTION                                                              would be relatively slow-moving station-blackout accidents caused by natural disasters, like the Fukushima Daiichi Practically speaking [zirconium] oxidation runaway comes              accident. Fast-moving accidents could also occur; for indue to the heat of the oxidation reaction increasing                example, a large-pipe-break LOCA could rapidly transition generally faster than heat losses from other mechanisms.             into a severe accident, because of thermal runaway. A

[zirconium] cladding oxidation [emphasis added].21                    containment to reach 4 percent of the containments volume Once thermal runaway (runaway zirconium oxidation)                (the lower "ammability limit).27 17 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

However, in a severe PWR accident, the picture changes          molten core with concrete (out of which containment "oors dramatically: hydrogen generation could occur at rates from        are made).41 A safety study for the PWRs at Indian Point 100 to 5,000 grams per second28 (two orders of magnitude            discusses a case in which interaction of a molten core with a greater than in a design basis accident), and similar rates        concrete containment "oor would generate more than 2721.5 would occur in a severe BWR accident. An OECD Nuclear              kg of hydrogen.42 Energy Agency report states, a rapid initial [hydrogen]-              If a molten core interacted with concrete, carbon source occurs in practically all severe accident scenarios          monoxide (which, like hydrogen, is a combustible gas) would because the large chemical heat release of the [zirconium]-        also be generated. Depending on different accident scenarios, steam reaction causes a fast self-accelerating temperature          concrete types, and geometrical factors affecting the molten excursion during which initially large surfaces and masses          core-concrete interaction, the quantities of carbon monoxide of reaction partners are available.29                              generated could vary greatly; concentrations could differ by If an overheated reactor core were re-"ooded with water,        up to several volume percent in the containment.43, 44 up to 300,000 grams of hydrogen could be generated in 60 seconds.30 In this scenario, according to one report, between 5,000 and 10,000 grams of hydrogen could be generated per          D. NRC MODELS UNDERPREDICT SEVERE second.31 (In the TMI-2 accident, re-"ooding of the uncovered      ACCIDENT HYDROGEN GENERATION RATES reactor core by the emergency core cooling system caused a A 2001 OECD Nuclear Energy Agency report advises that spike in the hydrogen generation rates; it has been estimated high hydrogen generation rates must be taken into account that approximately 33 percent of all the hydrogen produced in risk analysis and in the design of hydrogen mitigation occurred during re-"ooding.32) systems. However, the same report notes that computer The total quantity of hydrogen that could be generated in a safety models used by regulators underpredicted the actual severe accident is different for PWRs and BWRs. Considering rates of hydrogen generation that occurred in two sets of hydrogen generated only from the oxidation of zirconium:

experiments simulating severe accidents: the CORA tests and if the total amount of the zirconium in a typical PWR core, LOFT LP-FP-2.45 (The CORA and LOFT LP-FP-2 experiments approximately 26,000 kilograms (kg), were to chemically react were conducted to investigate accidents that lead to a with steam, this would generate approximately 1150 kg of meltdown of the reactor core. LOFT LP-FP-2 was conducted hydrogen; if the total amount of zirconium in a typical BWRs with an actual nuclear reactor, 1/50th the volume of a full-core, approximately 76,000 kg, were to chemically react with size PWR, designed to represent the major component and steam, this would produce about 3360 kg of hydrogen.33 system response of a commercial PWR. LOFT LP-FP-2 was Large BWR cores typically have about a 58-percent greater an actual core meltdownthe most realistic severe accident initial uranium mass than large PWR cores,34 and this larger experiment conducted to date; it combined decay heating, mass is divided into approximately 45 percent more fuel severe fuel damage, and the quenching of zirconium fuel rods than in a PWR. However, these differences alone do not cladding with water.46) Computer safety models also failed to account for the fact that BWR cores have almost three times predict hydrogen generation in the initial QUENCH facility the mass of zirconium in their cores than PWRs.35,36 BWR experiments.47 This indicates that computer safety models cores have signi"cantly more zirconium mainly because, also underpredict the hydrogen generation rates that would unlike PWRs, BWR fuel assemblies have channel boxes occur in severe accidents.48 surrounding the fuel rods. The mass of each BWR assembly A 1997 Oak Ridge National Laboratory (ORNL) report states channel box is greater than 100 kg.37 Thus a BWR core with that hydrogen generation in severe accidents can be divided 800 fuel assemblies would actually have more than the into two separate phases: 1) a phase that runs from when 76,000 kg of zirconium cited by the IAEA as typically present the fuel cladding is still intact through the initial melting of in a BWR core.)

the fuel cladding, which accounts for about 25 percent of The total quantity of hydrogen generated in a severe the total hydrogen produced; and 2) a phase after the initial accident can vary widely: The Fukushima Daiichi accident, melting of the fuel cladding, in which there is additional which resulted in three meltdowns, most likely generated melting, relocation, and the formation of uranium-more than 3,000 kg of hydrogen per affected unit; the zirconium-oxygen blockages, which accounts for about 75 amount produced in the TMI-2 accident is estimated at percent of the total hydrogen generated (as indicated in about 500 kg.38 In a severe accident, hydrogen would also analyses of the BWR CORA-28 and -33 tests).49 be generated within the reactor vessel from the oxidation According to the 1997 ORNL report, computer safety of non-zirconium materials: metallic structures and boron models predict hydrogen generation rates reasonably well carbide (in BWR cores).39 In the TMI-2 accident, the oxidation for the "rst phase, in which the fuel cladding remains intact, of steel accounted for approximately 10 percent to 15 but predict hydrogen generation rates for the second phase percent of the total hydrogen generation.40 In a case in which much less robustly. The 1997 ORNL report stresses that it the molten core penetrated the reactor vessel, hydrogen is obvious that computer safety models need to accurately would be generated from the oxidation of metallic material predict hydrogen generation rates when the fuel cladding is (chromium, iron, and any remaining zirconium) during no longer intact, especially because most of the hydrogen direct containment heating and also from interaction of the 18 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

generation occurs in that phase.50                                      In 2010, according to an article in Nuclear Engineering A 2011 International Atomic Energy Agency (IAEA) report          International, a type of silicon carbide fuel cladding with a states that computer safety models underpredict the rates of        triplex design57 was still in the early stages of development hydrogen generation that would occur during a re-"ooding            and testing the article opines that developing such cladding of an overheated reactor core.51 The report cautions that,          is a high-risk, but potentially high-payoff58 venture. It in different scenarios, re-"ooding could cause hydrogen            remains to be seen if triplex silicon carbide would be a generation rates to vary to a large degree and that predictions    suitable replacement for zirconium alloy as a fuel-cladding need to consider the possible range of outcomes in order            material; there are a number of problems with silicon carbide to help prepare for severe accident hydrogen risk. In the           cladding that still need to be resolved.

BWR CORA-17 test, which simulated the re-"ooding and                    One problem is that during typical reactor operation the quenching of an overheated core, approximately 90 percent          fuel pellets in silicon carbide cladding would have higher of the hydrogen generation occurred during re-"ooding.52            temperatures than they do when sheathed in zirconium. This Unfortunately, recent reports do not explicitly state            would occur for two reasons: First, after extended irradiation, the extent that computer safety models under-predict                silicon carbide has a lower thermal conductivity than hydrogen generation rates during the re-"ooding and                zirconium alloy,59 meaning less of the fuels heat would pass quenching of an overheated corei.e., a percentage value            through the cladding and into the coolant. Second, the thin of the under-prediction has not been provided. However,             gap between the fuel pellets and the cladding would not be presentation slides from a 2008 European meeting state that        closed early in the "rst fuel cycle as occurs when zirconium the total amount of hydrogen under re"ooding remains              cladding is used.60 Both of these phenomena would prevent highly underestimated in [the] CORA-13 and LOFT LP-                the pressurized water from cooling the fuel pellets in silicon FP-2 experiments [emphasis added]. In fact, regarding              carbide cladding as effectively as it does when the fuel pellets recent computer simulations of LOFT LP-FP-2, the same              are sheathed in zirconium cladding.

presentation slides state: High temperature excursions with            A second problem is that an effective means of extended core degradation and enhanced hydrogen release            hermetically sealing the ends of silicon carbide fuel-cladding observed in the test during re"ood was not reproduced due          rods has not yet been developed.61 If the fuel-cladding rods to the lack of adequate modeling53 [emphasis added].               were not hermetically sealed during reactor operation, "ssion Despite these reports dating back to 1997, the NRCs 2011        products would escape from the fuel rods and enter the Near-Term Task Force report on insights from the Fukushima          coolant water.

Daiichi accident failed to mention, much less discuss, the             A June 2012 Nuclear Energy Advisory Committee report fact that the NRCs computer safety modelssuch as the              lists additional problems with silicon carbide fuel cladding, widely used MELCOR code developed by Sandia National                such as a lack of ductility (the ability to bend, expand or Laboratoriesunderpredict the hydrogen generation                  contract without breaking) compared with currently used rates that occur in severe accidents. By overlooking the           cladding types. The report also speculates that within four de"ciencies of computer safety models, the NRC undermines          years further research and experimentation should con"rm its own philosophy of defense-in-depth, which requires              whether or not such problems can be resolved. If the the application of conservative models.54 When hydrogen            problems are resolved, in-reactor testing of silicon carbide generation rates are underpredicted, hydrogen mitigation            fuel cladding could take an additional 10 to 20 years.62 systems are not likely to be designed so that they could            Hence, even if all were to go well, it could take more than handle the generation rates that would occur in actual              two decades before silicon carbide fuel cladding is ready for severe accidents.                                                   commercial use. There is certainly no reason to expect that zirconium alloy fuel cladding will ever be widely replaced in the aging U.S. "eet of nuclear power plants, which are facing E. AN ATTEMPT TO ELIMINATE HYDROGEN                                obsolescence in the 2025-2050 timeframe.

RISK: DEVELOPING NON-ZIRCONIUM FUEL CLADDING Perhaps the most effective way to help prevent hydrogen explosions in severe accidents would be to develop fuel cladding that does not generate large quantities of hydrogen when the core overheats in such accidents. Zirconium alloy cladding could possibly be replaced with silicon carbide, molybdenum alloys, molybdenum-zirconium alloys, or iron-chromium-aluminum alloys.55 Silicon carbide is perhaps the most promising alternate; in the design basis accident temperature rangebelow 2200°Fsilicon carbide is far less reactive than zirconium with steam,56 generating much less hydrogen.

AN UNRESOLVED SAFETY ISSUE In the Fukushima Daiichi accident, hydrogen detonated in                Such extreme pressure spikes could cause a PWR large and seriously damagedthe reactor buildings housing Units            dry containment to fail. There are also other safety analyses 1, 3, and 4, causing large radiological releases. The hydrogen        with worrisome results. For example, analyses conducted explosion that occurred in the Unit 1 reactor building also          for Indian Point Units 2 and 3 about three decades ago caused a blowout panel in the Unit 2 reactor building to            found that peak pressures caused by hydrogen explosions open, which resulted in a loss of secondary containment              could exceed the estimated failure pressure of Indian Points integrity.63 Actually, from a strict technical perspective,          containmentsapproximately 126 pounds per square inch secondary containment integrity was lost the moment the            gauge72 (psig) or 141 pounds per square inch absolute73 "ooded emergency diesel generators failed to supply backup            (psia).74 For certain severe accident scenarios, peak pressure power. Maintaining secondary containment integrity requires          spikes were predicted to be 160 psia, 169 psia, about 157 psia, (a) an intact reactor building structure, and (b) a standby gas      and 180 psia or greater.75 (Some nuclear safety experts believe treatment system to "lter releases from the intact structure          the accuracy of containment failure pressure estimates is to the atmosphere and maintain the structure at a lower              questionable; according to one, Experimental data on the pressure than ambient pressure (thus ensuring, in the case            ultimate potential strength of containment buildings and of small leaks, that outside air leaks in rather than inside air      their failure modes are lacking.76) leaking out). Flooding of the emergency diesel generators by the tsunami took away (b) hours before the explosion took away (a).64                                                          A. THE POTENTIAL DAMAGE OF MISSILES As discussed in the preceding sections, the zirconium-            PROPELLED BY HYDROGEN EXPLOSIONS steam reaction will generate large quantities of hydrogen In a severe accident, a local hydrogen explosion within the in severe accidents. When it reaches a suf"cient local containment could propel debris, such as concrete blocks concentration inside the containment, this hydrogen will from disintegrated compartment walls, at extremely high explode if exposed to an ignition source, of which there are speeds. The impact of such debris (internally-generated many, given the amount of electrical equipment and wiring missiles) could compromise essential safety systems and located inside the containment. In the TMI-2 accident, even breach the containment, especially if it were made of a hydrogen explosionprobably initiated by an electric steel.77 If a PWR large dry containment made of reinforced spark65occurred in the containment (a PWR large dry concrete with a steel liner78 were struck by a missile propelled containment). The TMI-2 accident explosion did not breach by a hydrogen explosion, the containment would be more the containment; however, the integrity of either a PWR ice likely to incur cracks than to experience gross failure. Yet condenser containment or a BWR Mark III containment this is mere speculation: According to a 2011 IAEA report, could be compromised by an explosion of the quantity of no analysis ever has been made on the damage potential of hydrogen generated in the TMI-2 accident, because such "ying objects, generated in [a hydrogen]-explosion.79 containments have substantially smaller volumes and lower An Institute of Nuclear Power Operations (INPO) report, design pressures than PWR large dry containments.66,67 published in November 2011 thoroughly documents how in The fact that a hydrogen explosion did not breach the Fukushima Daiichi accident, internally generated missiles TMI-2s containment does not preclude the possibility that and missiles from secondary containments, propelled by if a meltdown were to occur at another PWR with a large hydrogen explosions, caused a considerable amount of dry containment, a hydrogen explosion could breach the damage and set back efforts to control the accident.80 The containment, exposing the public to a large radiological report states:

B. HYDROGEN EXPLOSIONS:                                                      hydrogen concentration was 8.1 volume percent87 causing a rapid pressure increase of approximately 28 psi in the DEFLAGRATIONS AND DETONATIONS containment.88) A famous instance of a hydrogen de"agration In a severe accident, water pumped into the reactor core to                  occurred on May 6, 1937, when the hydrogen-"lled dirigible cool the fuel rods would heat up and produce thousands                      Hindenburg ignited while landing at Lakehurst, NJ and of kilograms of steam, which would enter the containment                    collapsed into a smoldering mass of twisted wreckage on the through pressure relief valves or a break in the cooling system              ground within a matter of seconds.

circuit. At different points in an accident the presence of                    In a severe reactor accident, hydrogen could randomly large quantities of steam in the containment would have                      de"agrate when its concentrations were at 8.0 volume an inerting effect, either helping to prevent or completely                  percent or lower, because only a small quantity of energy is preventing hydrogen combustion if the steam concentration                    required for igniting hydrogen; sources of random ignition were 55 volume percent82 or greater. (If hydrogen combustion                include electric sparks from equipment and static electric were to occur, the presence of steam would help reduce its                  charges.89 It has been postulated that in the TMI-2 accident, intensity.83) However, after enough steam condensed and                      the hydrogen de"agration was initiated by a ringing this would be inevitable at some point in an accident, either                telephone90 and in the case of the Hindenburg, by the buildup naturally or by the use of containment spray systems84                      of a static electric charge on its specially-coated outer skin.

to about 8.0 volume percent, hydrogen combustion would                      Unfortunately, in a severe accident, the average hydrogen be in the form of a de"agration with a relatively slow "ame                  concentration in the containment could reach 7.0 to 16.0 speed.86 A de"agration is a combustion wave traveling at a                  volume percent, or higher; local concentrations could be subsonic speed relative to the unburned gas. (In the TMI-                    much higher. In a dry atmosphere of hydrogen and air, with 2 accident, a hydrogen de"agration occurred when the                        hydrogen concentrations above about 10.0 volume percent, Table 1: Calculated Hydrogen (H2) production Due to 75% Zirconium-Water Reaction Note that all the predicted containment hydrogen concentrations (far right-hand column) are above the combustion threshold of 4.1 volume percent, and most are above temperature-dependent detonation thresholds of 11.6 and 9.4 volume percent hydrogen, at 68°F and 212°F, respectively.

"ames can accelerate up to and beyond the speed of sound:               C. LIMITATIONS OF COMPUTER SAFETY this phenomenon is termed de"agration-to-detonation MODELS TO PREDICT HYDROGEN transition.91 A detonation is a combustion wave traveling at a supersonic speed (greater than the speed of sound) relative           DISTRIBUTION IN THE CONTAINMENT to the unburned gas. Hydrogen combustion in the form of                 AND HYDROGEN DEFLAGRATION-TO-detonations occurred in the Fukushima Daiichi accident.                 DETONATION TRANSITION Higher temperatures and/or the presence of carbon                   In a September 2011 meeting of the Advisory Committee on monoxide could increase the likelihood of a de"agration-               Reactor Safeguards (ACRS), Dana Powers, senior scientist at to-detonation transition. In a dry hydrogen-air mixture,               Sandia National Laboratories, expressed concern over the the lower concentration limits at which de"agration-to-                 fact that hydrogen detonations occurred in the Fukushima detonation transition can occur is 11.6 volume percent                 Daiichi accident and stated that in experiments, detonations at temperature of 68°F; at 212°F, the lower concentration               areextraordinarily hard to get.96,97,98 Consequently, limit falls to 9.4 volume percent.92 And in the presence               computer safety models (codes) derived from these of 5.0 volume percent of carbon monoxide (generated                     experiments have limitations in predicting the hydrogen if a molten core interacts with a containments concrete               distribution and steam condensation that would occur in the "oor), 10.0 volume percent of hydrogen can detonate at                 containment in different severe accident scenarios.

approximately 68°F.93                                                     A 2007 OECD Nuclear Energy Agency report states, One safety expert has concluded that within the large               Further work in code developmentand code user geometries of PWR-containments a slow laminar de"agration               training, supported by suitable complex experiments, is would be very unlikely. In most cases, highly ef"cient                 necessary to achieve more accurate predictive capabilities combustion modes must be expected.94 In a small-break                 for containment thermal hydraulics and atmospheric gas/

LOCA, large quantities of steam could enter the containment             steam distribution. As a result of the code assessment, the well before hundreds of kilograms of hydrogen were                     modeling of the following three phenomena appeared to be released into the containment. In such a scenario, thermal             the major issues: condensation, gas density strati"cation, and strati"cation could prevent the hydrogen from mixing                   jet injection [emphasis added].99 with the steam.95 In scenarios in which large quantities of               Computer safety models also have limitations in predicting steam were present in the containment, the hydrogen could               the phenomenon of hydrogen de"agrations transitioning reach high concentrations because the inerting effect of the           into detonations; as well as the maximum pressure loads steam could prevent the hydrogen from igniting at lower                 the containment would incur from detonations, in different concentrations. After the steam condensed, a de"agration               scenarios. Westinghouses probabilistic risk assessment could transition into a etonation.                                     for its new and supposedly passively safe AP1000 reactor design, under construction in Georgia and South Carolina, observes that the phenomenon of hydrogen de"agration-Table 2: Release Paths in LWR Containments                          to-detonation transition is complex and not completely understood and that the maximum pressure loads from detonations are dif"cult to calculate.100 The Fukushima Daiichi accident demonstrated that the NRC needs to conduct more realistic hydrogen combustion experimentsperhaps in facilities on the same scale as actual reactor containments, at elevated temperatures and with the large quantities of hydrogen that are produced in severe accidents.

An Overview, Sandia National Laboratories, NUREG/CR-6906/ SAND2006-2274P, July 2006 22 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

IV. SEVERE ACCIDENT HYDROGEN MITIGATION A. HYDROGEN-MITIGATION STRATEGIES                                    Table 3: U.S. Power Reactor Containment Structures, FOR DIFFERENT CONTAINMENT DESIGNS                                    by Type Over the course of six decades, the NRC and its predecessor agency, the Atomic Energy Commission, have licensed six basic types of reactor containments (see Table 3), but within each type there are numerous design and construction differences (see Table 4) that translate into a wide and highly uncertain range of capacities to contain a severe reactor accident.

PWRs with Large Dry Containments and PWRs with Subatmospheric Containents The NRC does not require the owners of PWRs with large dry containments (52 out of 53 such units are currently operational in the U.S.), or the owners of PWRs with sub-atmospheric containments, maintained at an internal pressure below atmospheric pressure ("ve out of seven such units are currently operational in the U.S.) to mitigate the        Source: NUREG/CR-6906/SAND2006-2274P, July 2006 hydrogen that would be generated in severe accidents. The agency assumes that the large containment volumes of such PWRs are suf"cient to keep the pressure spikes of potential            In September 2003, the NRC likewise rescinded its hydrogen de"agrations within the design pressures of the            requirement that PWRs with large dry containments and structures.101                                                      PWRs with sub-atmospheric containments operate with One hydrogen mitigation strategy for these types of              hydrogen recombiners installed in their containments. It containments would be to mix the hydrogen entering                  decided that the quantity of hydrogen produced in design-the containment using its fan coolers; this would reduce            basis accidents would not be risk-signi"cant and that local hydrogen concentrations and mix the hydrogen with            hydrogen recombiners would be ineffective at mitigating the steam, which has an inerting effect.102 A second hydrogen          quantity of hydrogen produced in severe accidents104 when mitigation strategy for such PWRs would be to use hydrogen          hydrogen generation could occur at rates as high as 5.0 kg per recombiners, safety devices that eliminate hydrogen in an          second.105 accident by recombining hydrogen with oxygena reaction                In the United States, if such PWRs still have hydrogen that produces steam and heat. There are two types of                recombiners, there are typically two of them in each recombiners: passive autocatalytic recombiners (PAR), which        containment, to mitigate the quantity of hydrogen produced operate without electric power, and electrically powered            in a design basis accident. For example, Indian Points thermal recombiners. The hydrogen removal capacity for              containments each have two hydrogen recombiner units.106 one hydrogen recombiner unit is only several grams per              To help mitigate hydrogen in a wide range of severe accident second.103                                                          scenarios, a group of European nuclear safety experts have recommended that such PWRs have from 30 to 60 hydrogen recombiner units distributed in their containments.107 However, even 60 hydrogen recombiner units would not be capable of eliminating all of the hydrogen generated in some severe accident scenarios within the timeframe required to prevent a hydrogen explosion.

Table 4: U.S. PWRs Classi"ed by Containment Construction Type Source: NUREG/CR-6906/SAND2006-2274P, July 2006 24 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

Figure 9: Typical PWR Large Dry Containment Designs Left: Large dry steel primary containment with reinforced-concrete shield. Right: Containment constructed with post-tensioned concrete with steel liner (e.g., Palisades).

Steel primary containment Reinforced-concrete shield building 2.5 feet thick 25 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

the U.S.) and BWR Mark IIIs (four are currently operational          Such containments could be compromised by an in the United States) operate with hydrogen igniters installed    explosion of the quantity of hydrogen that was generated in their containments in order to mitigate the hydrogen            in the TMI-2 accident.110 Hydrogen igniters are intended to that would be generated in the event of a severe accident.108      manage the quantity of hydrogen that would be generated Hydrogen igniters are intended to burn off hydrogen as it is       by a zirconium-steam reaction of 75 percent of the fuel-generated in an accident, before it reaches concentrations        claddings active length,111 which is considerably less than the at which combustion would threaten the integrity of the            quantity of hydrogen generated at each melted-down unit at containment. Hydrogen mitigation is essential for PWRs with        Fukushima-Daiichi.

Shield Hydrogen igniters building dome                                                            Containment spray system Steel primary Concrete shield                                                                                      containment building wall Top of ice bed Ice condenser                                                                                    Steam generator Ice condenser Vapor barrier Accumulator Ventilation fan and equipment Reactor vessel Steel liner Reactor cavity Sump Source: NUREG/CR-6906/SAND2006-2274P, July 2006 27 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

BWR Mark I and BWR Mark II                                              Such containments, if not inerted, could easily be The NRC requires that BWR Mark Is (23 such units are                  compromised by an explosion of the quantity of hydrogen currently operational in the U.S.) and BWR Mark IIs (eight            generated in the TMI 2 accident. A year after the Fukushima such units are currently operational in the U.S.) operate with        accident, in March 2012, the NRC ordered the installation primary containments that have an inerted atmosphere112              of reliable hardened vents in BWR Mark I and Mark II to help prevent hydrogen combustion. An inerted                      containments by December 31, 2016.116 A hardened vent containment atmosphere is de"ned as having less than                  could help control hydrogen in a severe accident but its 4.0 percent oxygen by volume.113                                      primary purposes are to remove heat from and depressurize Nitrogen is used to inert BWR Mark I and Mark II primary          BWR Mark I and Mark II containments, which due to their containments because nitrogen is inexpensive and nontoxic.            small volumes are more susceptible than other containment Such containments are relatively small, so deinerting and            designs to failure from overpressurization in an acident.

inerting for outages between fuel cycles can be achieved                  In September 1989, the NRC issued non-legally within hours; these processes are also inexpensive.114                binding guidance to all owners of BWR Mark I facilities, If BWR Mark I and Mark II primary containments were                recommending117 that hardened vents be installed.118 The not inerted, they would be extremely vulnerable to hydrogen          NRC does not require that hydrogen be mitigated in the explosions in severe accidents, because of their relatively          secondary containments of BWR Mark I and Mark II units.

to the use of hydrogen igniters and containment sprays to meet containment requirements.

CASE STUDY: Hydrogen Risks in Westinghouses Probabilistic Risk Assessment for the AP1000 and Plans for Managing an AP1000 Severe Accident Currently four Toshiba-Westinghouse AP1000 units are under construction in South Carolina and Georgia. The NRC purports to have more stringent safety requirements for the AP1000, that re"ect the Commissions expectation that future designs will achieve a higher standard of severe accident performance than currently operating light water reactors.119 And Westinghouse has touted the AP1000 as having, in the event of a severe accident, a far lower probability of breaching its containment than currently operating nuclear power plants. However, Westinghouses probabilistic risk assessment (PRA) for the AP1000 erroneously claims that it would not be possible for a hydrogen detonation to occur in the AP1000s containment if the hydrogen concentration were less than 10.0 volume percent. A hydrogen detonation could compromise the containment and thus cause a large radioactive release. In fact, Westinghouses PRA assumes that the containment would fail in all cases, in which hydrogen de"agrations transitioned into detonations.120 Westinghouses PRA for the AP1000 states that [s]ince the lowest hydrogen concentration for which de"agration-to-detonation transition has been observed in the intermediate-scale FLAME facility at Sandia [National Laboratories] is 15 percent,121 and [NRC regulation] 10 CFR 50.44 limits hydrogen concentration to less than 10 percent, the likelihood of de"agration-to-detonation transition is assumed to be zero if the hydrogen concentration is less than 10 percent.122 Westinghouse does not consider that the lower concentration limits at which de"agration-to-detonation transition can occur, at temperatures of 68°F and 212°F, are 11.6 and 9.4 volume percent of hydrogen, respectively.123 According to a 1998 Brookhaven National Laboratory report: Most postulated severe accident scenarios are characterized by containment atmospheres of about 373K [212°F] However, calculations have shown that under certain accident scenarios local compartment temperatures in excess of 373K [212°F] are predicted.124 It is perplexing that Westinghouses PRA for the AP1000 as well as the NRCs regulations for future water-cooled reactors rely on outdated assumptions that the phenomenon of hydrogen de"agration-to-detonation transition cannot occur below hydrogen concentrations of 10.0 volume percent: in 1991, Sandia National Laboratories reported that, in an experiment, de"agration-to-detonation transition occurred at 9.4 volume percent of hydrogen.125 The previous year, the same information was reported at the NRCs Eighteenth Water Reactor Safety Information Meeting.126 In a September 2011 Advisory Committee on Reactor Safeguards meeting, Dana Powers, a senior scientist at Sandia National Laboratories, expressed concern over the fact that hydrogen detonations occurred in the Fukushima Daiichi accident and stated that in experiments, detonations areextraordinarily hard to get.127 However, neglecting to reassess hydrogen-combustion safety issues for the AP1000 after Fukushima, the NRC went ahead and issued licenses for two AP1000s in February 2012.

Paradoxically, two of the AP1000 containments safety deviceshydrogen igniters, and passive autocatalytic hydrogen recombiner (PAR) units when they malfunction and behave like ignitersprovide ignition sources that are capable of causing hydrogen detonations. In a severe accident, hydrogen igniters must be actuated at the correct time, because, as Peter Hoffman wrote in the Journal on Nuclear Materials: [t]he concentration of hydrogen in the containment may be combustible for only a short time before detonation limits are reached.128 If AP1000 operators were to actuate the hydrogen igniters in an untimely fashionafter a local detonable concentration of hydrogen developed in the containmentit could cause a detonation. This especially could occur because Westinghouses emergency response guidelines for the AP1000 are "awed: Operators are instructed to actuate hydrogen igniters when the core-exit gas temperature exceeds 1200°F. Westinghouse maintains that the core-exit temperature would reach 1200°F before the onset of the rapid zirconium-steam reaction of the fuel cladding,129 which leads to thermal runaway in the reactor core; however, experimental data demonstrates that this would not necessarily be the case.

Westinghouse and the NRC, which approved the AP1000 design, both overlooked dataavailable for more than a quarter centuryfrom the most realistic severe accident experiment conducted to date (LOFT LP-FP-2), in which core-exit temperatures were measured at approximately 800°F when maximum in-core fuel-cladding temperatures exceeded 3300°F.

In LOFT LP-FP-2, when core-exit temperatures were 800°F, the rapid zirconium-steam reaction of the fuel cladding had already occurred and the reactor core had started melting down. Hence, relying on core-exit temperature measurements in an AP1000 severe accident could be unsafe: In a scenario in which operators re-"ooded an overheated core simply because they did not know the actual condition of the core, hydrogen could be generated at rates as high as 5.0 kg per second. If operators were to actuate hydrogen igniters in such a scenario, it could cause a hydrogen detonation.

Westinghouses general description of the AP1000 states that [PARs] control hydrogen concentration following design basis events.130 However, in the elevated hydrogen concentrations that occur in severe accidents, PARs are prone to malfunctioning and behaving like hydrogen igniters. This is a problem: AP1000 operators would not be able to switch off PARs, because they operate without electrical power. If the AP1000 containments PAR units malfunctioned and incurred ignitions after a detonable concentration of hydrogen developed in the containment, it could cause a detonation.131 This could occur in a number of severe accident scenarios, especially those in which the AP1000 containments hydrogen igniter system was not operational,132 enabling local detonable concentrations of hydrogen to develop in the containment.

Is Likely to Vary Widely Figure 14 compares the calculated design pressure (in pounds per square inch above sea level atmospheric pressure, or psig) of the six main types of U.S. commercial reactor containments with their net free volume in millions of cubic feet. BWR Mark I and II have a nominally strong pressure rating, due to their use of pressure-suppression pools, but very low free volume. The BWR Mark III and PWR ice condenser designs have the lowest design pressures of the group as well as moderate volumes, while the two other PWR containment designs have the largest volumes along with comparatively high design pressures.

Source: NUREG/CR-6906/SAND2006-2274P, July 2006                      Source: NUREG/CR-6906/SAND2006-2274P, July 2006, p. xvii B. PROBLEMS WITH CURRENT HYDROGEN-                                states that in a severe accident, steam typically would be present in the containment, yet the quantity of steam would MITIGATION STRATEGIES FOR RESPECTIVE be unpredictable because of condensation, which would be REACTOR DESIGNS                                                    facilitated by containment spray systems. Detonations would PWRs with Large Dry Containments and PWRs with                    most likely be initiated through de"agration-to-detonation Subatmospheric Containments                                        transition, yet direct detonations could perhaps be possible As noted above, the NRC does not require owners of                at higher temperatures.134 PWRs with large dry containments and PWRs with sub-                  Hydrogen recombiners would be prone to malfunctioning atmospheric containments to mitigate the hydrogen                  by incurring ignitions in the elevated concentrations that would be generated in severe accidents; however,             that occur in severe accidents. This would be a serious in severe accidents, it would be possible for the pressure        problem: A recombiners unintended ignition could cause a spikes of hydrogen explosions to exceed the design                detonation.135 pressures of such containments. The NRC has reported                  PARs could be advantageous in station-blackout that hydrogen detonations could occur in PWRs with                accidentsa complete loss of grid-supplied and backup large dry containments and PWRs with sub-atmospheric              on-site alternating current powerbecause they operate containments. For example, a 1990 NRC letter to plant              without either external power or plant operator actuation; owners states that in severe accidents, local and global          however, there is no way to prevent such recombiners from hydrogen detonations could occur in PWRs with large dry or        self-actuating or to shut them off in elevated hydrogen sub-atmospheric containments.133                                  concentrations. Plant operators would be able to control Furthermore, a 1991 report by Sandia National                  the operation of electrically powered thermal hydrogen Laboratories cautions that in severe accidents, in which          recombiners; yet operators should be cautious about 75 percent of the fuel-cladding active length oxidized,            actuating thermal recombiners in an accident. Plant detonable concentrations of hydrogen could develop in dry          operators should actuate thermal recombiners only if hydrogen-air mixtures in such containments. The report            hydrogen concentrations are low and should deactivate them 30 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

Source: NUREG/CR-6906/SAND2006-2274P, July 2006 if hydrogen concentrations increase to dangerous levels. Of            PWRs with Ice Condenser Containments and course, to soundly make such decisions, operators would                BWR Mark III Containments need to ascertain local hydrogen concentrations throughout            The NRC requires that PWRs with ice condenser the containment, which would be especially dif"cult in the            containments and BWR Mark IIIs operate with hydrogen course of a fast-moving and/or chaotic accident scenario.              igniters installed in their containments in order to mitigate Among the PWRs in the United States that still have                the hydrogen that would be generated in the event of a severe hydrogen recombiners installed, only one has PARs (Indian              accident.140 However, hydrogen igniters should be used only Point Unit 2); the others have thermal recombiners                    in cases where the effects of their use are entirely predictable, typically two units in each containment. In Europe, some              and predictions must indicate that the containment would PWRs have from 30 to 60 PARs installed and distributed in              not be threatened by any potential de"agrations arising from their containments to help mitigate hydrogen in the event              the deliberate ignition of hydrogen.141 of a severe accident.136 This is puzzling, given that such                Safety experts have questioned the safety of using igniters recombiners would be prone to behaving like igniters                  to mitigate hydrogen at certain times in some severe accident malfunctioning by incurring ignitionsin elevated hydrogen            scenarios. For example, an OECD Nuclear Energy Agency concentrations.137                                                    report published in August 2000 states, The main question in After intensive deliberation, European regulators decided          the application of the igniter concept is its safety orientation.

not to require igniters in PWRs (those without ice condenser          The use of igniters should reduce the overall risk to the containments) because [u]ncertainties were identi"ed with            containment and should not create new additional hazards respect to, among other aspects, hydrogen distribution and            such as a local detonation.142 combustion behavior.138 In line with the reasoning behind                Another paper, published in 2006, states that [w]ith early this decision, it seems that European regulators should                ignition, the hydrogen will be eliminated by slow combustion also be hesitant about allowing PWRs to operate with PARs              without high thermal and temperature loads, but with installed in their containments, because unintended ignitions          late ignition, hydrogen detonation transition will quickly from such recombiners would be neither predictable nor                occur with high local thermal and pressure loads which will preventable in a severe accident.                                      threaten the integrity of the containment.143 Another problem with hydrogen recombiners is that in a                A 1990 NRC letter to plant owners cautions that hydrogen severe accident, cesium iodide particles transported through          igniters would be prevented from operating in station them could be converted into volatile iodine, producing an            blackouts at PWRs with ice condenser containments and additional source term of radiation exposure.139 31 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

Figure 15: Prestressed concrete containment vessel                    In a severe accident, water already present or pumped (PCCV) at the Ohi Unit 3 reactor in Japan                          into the reactor core to cool the fuel rods would heat up and produce thousands of kilograms of steam, which would A 1:4 scale model of a prestressed concrete containment            enter the drywell of the primary containment. The water in vessel (PCCV) at the Ohi Unit 3 reactor in Japan, undergoes a      the wetwells suppression pool is intended to condense the massive rupture in a 2001 Sandia Laboratory test at 3.63 times    steam and help absorb the heat released by the accident to its design pressure (Pd), or 206.4 psig. The pressurized model    reduce the pressure in the primary containment; as the steam had experienced leak rates in earlier tests, indicating functional pressure builds up in the drywell, steam vents downward failure at 2.4 times Pd.                                           into the wetwell through pipes, which terminate underwater in the suppression pool. (Without the condensation of the steam in the suppression pool, the relatively small primary containments of BWR Mark Is and Mark II units (often termed pressure suppression containments) would quickly fail from overpressurization.

However, the generation of suf"ciently large quantities of non-condensable hydrogen gas in a severe accident could overwhelm the capacity of the primary containment. For example, there could be a severe accident scenario at a BWR Mark I in which there is a rapid accumulation of steam in the drywell and non-condensable gas (nitrogen149 and hydrogen) in the wetwell; in such a scenario, the primary containments pressure could rapidly increase up to the venting and failure levels.150 Early BWRs Perform Poorly in Containment Leak-Rate Tests, Even When Liberal Test Protocols Allow Pretest Repairs to Supposedly As Found Condition of Seals and Valves Source: NNUREG/CR-6906/SAND2006-2274P, July 2006                      BWR Mark I and Mark II primary containments are designed to limitnot preventhydrogen leakage in accidents. In overall leak rate tests151conducted below design pressure BWR Mark IIIs. If hydrogen were not burned off, it could such containments leak hundreds of pounds of air per day.

reach detonable concentrations; if power were then restored, For example, in 1999, tests conducted at Nine Mile Point the igniters could cause a hydrogen detonation.144 Unit 1, a BWR Mark I, and Limerick Unit 2, a BWR Mark II, BWR Mark I and BWR Mark II Containments                              found that overall leakage rates at both units were in excess of Hydrogen generation is a serious problem for the small-               350 pounds of air per day,152, 153 which is actually less than the volume, inerted BWR Mark I primary containment, because              maximum allowed leak rates.

would be generated (potentially exceeding 3,000 kg146) at            leak rates would increase as the internal pressure increased rates as high as 5,000 to 10,000 grams per second if there were      and would become even greater if the seals at the various a re-"ooding of an overheated reactor core.147 This would            piping and cable penetrations were damaged. (Typical BWR increase the internal pressure of the primary containment.            containments have 175 penetrations, almost twice as many If enough hydrogen were generated, the containment would              as typical PWR containments.)154 likely "rst leak excessively before failing catastrophically from        Regarding reactor containments and hydrogen leakage, a overpressurization.                                                  2011 IAEA report states:

A BWR Mark I primary containment is made up of a                    [N]o containment is fully leak tight, [hydrogen] will leak drywell shaped like an inverted lightbulb, which contains the            to the surrounding areas, which often have the function reactor vessel, and a steel wetwell (also called a torus) shaped        of secondary containment. Hence, there is a certain like a doughnut, which surrounds the base of the drywell.                risk that combustion may occur outside the primary The drywell and wetwell are connected by large pipes. The                containment. This may lead to combustion loads exerted wetwell is half "lled with water (typically about 790,000                on the containment from outside. Usually, containments gallons148)and is sometimes referred to as a suppression                have considerable margin against loads from inside, as pool. A BWR Mark II primary containment also has a drywell              they are in principle designed to carry the pressure loads and wetwell (concrete), but these are shaped and oriented                from a large break LOCA. The pressure bearing capability from their BWR Mark I counterparts.                                      for loads from outside can be substantially less155 32 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

Mark I and Mark II primary containments would prevent                    [R]eported leakage rates often do not represent true overpressurization, and that [f]ailure of non-metallic seals            leakage rates. Utilities are generally allowed to perform for containment penetrations (primarily equipment hatches,                some minor repair on a valve prior to recording its as-drywell heads, and purge valves) are the most signi"cant                  found condition for a leakage test. Similarly, major repair sources of containment leakage.158 BWR drywell heads,                    (such as completely rebuilding a valve) is permitted prior which have diameters between 30 to 40 feet, would most                    to recording a valves as-left condition at the end of its likely incur the highest leak rates in the containment as                leakage test.167 internal pressures increased.159 Containments have had leaks, exceeding allowable leakage              Hence, around 1985 when NUREG/CR-4220 was rates, that lasted for many monthsprimarily from large              published, it was a common practice for utilities to make penetrations, such as the purge and vent valves, [main steam          minor repairs on valves immediately before recording isolation valves, for BWRs only], and valves inadvertently left        their as-found leak rates. The local leak rate tests that are open.160 In fact, BWR Mark I primary containments have                intended to measure leakage rates at containment isolation failed a number of overall leak rate tests; for example, Oyster        valves are termed Type C tests. In September 1995, the Creekthe oldest operating commercial reactor in the U.S.,            NRC extended Type C test intervals from two years to "ve which is considered to be quite similar to Fukushima Daiichi          years. Interestingly, the failure rates of Type C as-found tests Unit 1has failed at least "ve tests.161                              have decreased by about one order of magnitude since the In one test, Oyster Creeks primary containment leaked at          test intervals for such tests were increased in 1995.168 Such a rate that was 18 times greater than its design leak rate;162        signi"cant improvements beg the question: since 1995, to if this test was conducted at 35 psig, the same pressure as            what degree have valves been repaired immediately before subsequent Oyster Creek tests,163 which seems likely, the              recording their as-found leak rates?

the three primary containments that leaked hydrogen at                enabling repairs to be made sothat the Type A test can be Fukushima Daiichi?                                                    passed easily.169 Since the Fukushima Daiichi accident, the problem of                  In a March 2013 ACRS meeting, an ACRS member similarly hydrogen leakage from primary containments has not been                observed that [i]f they did all their preparations perfectly, adequately addressed. (Mark II primary containments would              they would never fail.170 It is clear that overall leak rate tests also incur hydrogen leaks in severe accidents.) In fact, the          and local leak rate tests would provide a far more accurate NRC is currently preparing to reduce the frequency of both            assessment of pre-existing containment leak rates if repairs local and overall leak rate testing from once every "ve and            were not allowed to be made immediately before testing.

once every 10 years, respectively, to once every 75 months                A report from the Electric Power Research Institutes and 15 years, respectively.                                            (EPRI), Risk Impact Assessment of Extended Integrated 33 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

Source: P.J. Pelto et al., Reliability Analysis of Containment Isolation Systems, Paci"c Northwest Laboratory, NUREG/CR 4220, June 1985, available at: NRCs ADAMS Documents, Accession Number:

ML103050471 Leak Rate Testing Intervals,171 has been used by the NRC to                       In a severe accident, any primary containment in a help justify the extension of testing intervals.172 However, this              condition that would cause it to fail a leak-rate test would report overlooked the fact that in severe accidents, BWR Mark                  leak dangerous quantities of explosive hydrogen gas into a I and Mark II primary containments leak explosive hydrogen                      reactor building, even at below design pressure; however, the gas into secondary containments. A second major problem                        NRC does not seem concerned about excessive leakage rates.

with EPRIs report is that its list of overall leak rate test failures          A 1995 NRC report177 concluded thatincreasing allowable does not include the majority of test failures reported in                      leakage rates by 10 to 100 times results in a marginal risk NUREG/CR-4220. NUREG/CR-4220 lists a total of 60 overall                        increase, while reducing costs by about 10 percent178 (integrated) leak rate tests that failed before March 1985;173                  [emphasis added]. And a 1989/1990 NRC report179 concluded in fact, NUREG/CR-4220 also reports that when considering                      that even if there is a containment leakage of 100 percent per the results of local leak rate tests that failed with excessive                day, the calculated individual latent cancer fatality risk is leakage rates, the number of overall leak rate tests that failed                below the NRCs safety goal.180 Clearly, this safety goal would is a total of 109.174                                                          not be achieved if leaking hydrogen were to detonate in By contrast, EPRIs report lists a total of nine containment                secondary containments, as it did at Fukushima Daiichi.

leakage or degradation events that occurred before March                          In March 2013, the NRC stated that [s]ensitivity 1985.175 Regarding its methodology for assessing the risk                      analyses in NUREG-1493 and other studies show that light impact of extended test intervals, EPRIs report states                        water reactor accident risk is relatively insensitive to the The "rst step is to obtain current containment leak rate                      containment leakage rate because the risk is dominated testing performance information. This information                            by accident sequences that result in failure or bypass of is used to develop the probability of a pre-existing leak in                    containment181 [emphasis added]. The progression of the the containment using the Jeffreys Non-Informative Prior                        Fukushima Daiichi accident was certainly affected by the statistical method [emphasis added].176 Clearly, the NRC                      leakage of hydrogen gas. In fact, it is possible that Unit 3s needs to review a large portion of the existing data that EPRI                  primary containment did not fail before hydrogen leaked overlooked and reassess the risk impact of extended test                        into the Unit 3 secondary containment and detonated.

The internal pressure of Unit 3s primary containment                    It is important to consider that in the Fukushima Daiichi actually increased after the hydrogen explosion occurred.              accident, the particular design of the installed vents may The explosion occurred on March 14 at 11:01 am, then                  have caused the accident to be worse than it would have been at 12:00 pm the primary containments pressure started                without their use: The INPO report of November 2011 states increasing from 52.2 psia to 53.7 psia, at 4:40 pm the pressure        that it is postulated that the hydrogen explosion in the Unit started decreasing from 69.6 psia, and at 8:30 pm the pressure        4 reactor building was caused by hydrogen from Unit 3.194 started increasing from 52.2 psia.182 In the Fukushima Daiichi        Unit 3 and Unit 4s containment vent exhaust piping was accident, the BWR Mark I primary containments of Units 1,              interconnected, so hydrogen may have been vented from 2, and 3 incurred internal pressures that exceeded the loads          Unit 3 to Unit 4s secondary containment,195 where it they were designed to sustain. According to an INPO report            detonated.

published in November 2011, the highest recorded internal                In severe accidents, spent fuel pools are vulnerable to the pressures in the primary containments of Units 1, 2, and 3            hydrogen explosions that can occur in BWR Mark I and Mark were approximately 1.7, 1.7, and 1.4 times greater than their          II secondary containments. Spent fuel pools, which store fuel design pressures, respectively.183 (In the accident, hydrogen          assemblies after they are discharged from the reactor core, leaked from the primary containmentsaccording to INPO:                are located in the secondary containment of these designs, most probably at the penetrations184of Units 1, 2, and 3            elevated about 70 to 80 feet above ground level. If a spent fuel and detonated in the secondary containments of Units 1, 3,            pool were compromised by a hydrogen explosion, it could and 4.) The NRC has stated that in the circumstances of the            cause large radiological releases.

Fukushima Daiichi accident, it is reasonable to conclude that            Some thought initially that the explosion that occurred in BWR Mark IIs would also incur devastating consequences,                Fukushima Daiichi Unit 4 at 6:00 am on March 15, 20113.63 because Mark II containment designs are only slightly larger          days after the March 11, 2011 earthquakecould have been in volume than Mark I containment designs185 and also use              caused by the detonation of hydrogen gas generated by the wetwell pressure suppression.186                                      reaction of steam with the zirconium cladding of fuel rods stored in the spent fuel pool. Subsequent investigations Reliable Hardened Vents                                                indicated that this was not the case.

In an attempt to resolve the problems of BWR Mark I and                  However, according to a 2012 ORNL paper, the hydrogen Mark II primary containment overpressurization and decay              that detonated could have come from the Unit 4 pools fuel heat removal, in March 2012, the NRC ordered that reliable            assemblies reacting with steam: If there were a loss of spent hardened vents be installed in BWR Mark Is and Mark IIs by            fuel pool cooling, the water in the pool would be heated by December 31, 2016.187 (As stated above, in September 1989,            the fuel rods decay heat until it reached the boiling point; the NRC had tried to solve the same problems by issuing                then the water would boil away, uncovering the fuel rods.

non-legally binding guidance to all the owners of BWR Mark            ORNL computer analyses found that in this scenario, a Is, recommending188 that hardened vents be installed in Mark          total of 1,800 kg to 2,050 kg of hydrogen could have been Is.189) The NRCs order stipulates a number of performance            generated. The analyses also found that 150 kg of hydrogen objectives and features that a new design of a hardened vent          an amount that could have caused the Unit 4 explosion must have; for example, shall include a means to prevent              would have been generated 3.63 days after the accident inadvertent actuation.190                                            commenced if the initial water level in the pool were 4.02 It could be dif"cult to design a hardened vent that                meters (at the top of the active length of the fuel rods).196 would perform well in scenarios in which there were rapid                The NRC does not require that hydrogen be mitigated in containment-pressure increases. A 1988 report by the                  the secondary containments of BWR Mark I and Mark II sites Committee on the Safety of Nuclear Installations report states        in severe accidents. This is a problem, because hydrogen that [f ]iltered venting is less feasible for those sequences        could leak into secondary containments and explode, as resulting in early over-temperature or overpressure                    occurred in the Fukushima Daiichi accident. The Fukushima conditions. This is because the relatively early rapid increase        Daiichi accident demonstrated that BWR Mark I secondary in containment pressure requires large containment                    containmentsessentially ordinary industrial buildings penetrations for successful venting.191 This indicates that a        with design pressures of approximately 3.0 psig197cannot reliable hardened vents piping will likely need a diameter            withstand hydrogen explosions. (BWR Mark II secondary and thickness greater than what has been voluntarily                  containments also have low design pressures.) In line with installed at BWR Mark I containments in the United States.192          the NRCs approach to safety through defense-in-depth,198 If a hardened vent were designed for passive operation by          the Fukushima Daiichi accident scenario of hydrogen means of a rupture disk, in place of a remotely or manually            leaking from overpressurized primary containments and/

In many cases, a predetermined core-exit thermocouple              MONITORING FOR THE PRESENCE OF measurement would be used to signal the time for PWR OXYGEN AND HYDROGEN operators to transition from emergency operating procedures The NRC requires that BWR Mark I and Mark II units (EOP) to severe accident management guidelines (SAMG).

operate with oxygen monitors installed in their primary The NRCs Near-Term Task Force report states that EOPs containments in order to con"rm that the containment typically cover accidents to the point of loss of core cooling remains inerted during operation. In a severe accident, if a and initiation of inadequate core cooling (e.g., core exit primary containment were to become de-inerted, severe temperatures in PWRs greater than 649 degrees Celsius [1,200 accident management strategies, such as purging and degrees Fahrenheit]).199 venting, would need to be considered.207 Experimental data indicates that core-exit thermocouple The NRC also requires that all licensed plants operate measurements would not be an adequate indicator for with the ability to monitor hydrogen concentrations in when to safely transition from EOPs to SAMGs.200 Two of the their containments. However, in 2003, the NRC reclassi"ed main conclusions from experiments are: 1) that core-exit hydrogen monitors (and oxygen monitors) as non-safety-temperature measurements display in all cases a signi"cant related equipment,208, 209 meaning that this equipment does delay (up to several hundred seconds) and: 2) that core-exit not have to undergo full quali"cation (including seismic temperature measurements are always signi"cantly lower (up quali"cation), does not have redundancy, and does not to several hundred degrees Celsius) than the actual maximum require onsite (standby) power.

cladding temperature.201 In an experiment simulating a severe In severe accidents, hydrogen monitors would be used accidentLOFT LP-FP-2core-exit temperatures were to help assess the degree of core damage that had occurred measured at approximately 800°F when in-core fuel-cladding and to help with accident management. For example, BWR temeratures exceeded 3300°F.202 Mark IIIs use hydrogen monitors to help guide emergency In a severe accident, plant operators are supposed to operating procedures: Hydrogen igniters would not be used implement SAMGs before the onset of the rapid zirconium-In scenarios in which hydrogen reached concentrations that steam reaction, which leads to thermal runaway in would threaten containment integrity if the hydrogen were to the reactor core. Clearly, using core-exit thermocouple combust.

measurements in order to detect inadequate core cooling BWR Mark I and Mark IIs operate with hydrogen monitors or uncovering of the core would be neither reliable nor installed in their inerted primary containments yet do safe. For example, PWR operators could end up re-"ooding not have such monitors in their secondary containments.

an overheated core simply because they did not know the David Lochbaum of the Union of Concerned Scientists actual condition of the core. Unintentionally re-"ooding an has cautioned that [t]he inability to monitor hydrogen overheated core could generate hydrogen, at rates as high as concentrations could cause [plant] operators to not vent effectiveness.203

[BWR Mark I and Mark II] reactor buildings, thus leading Core-exit thermocouples are not installed in BWRs. In a to ignitions resulting in loss of secondary containment severe accident involving this type of reactor, plant operators integrity. He states further that without the ability to monitor are supposed to detect inadequate core cooling or uncovering hydrogen, operators could preemptively vent the reactor of the core by measuring the water level in the reactor core.

In 1983, the NRC issued an order requiring that in a severe      Despite Fukushima Daiichis three devastating hydrogen accident, hydrogen monitors function within 30 minutes              explosions, the NRC has relegated severe-accident hydrogen after coolant water is injected into the reactor vessel; in 1998,   safety issues to the least proactive stage of its post-Fukushima the NRC determined that the 30-minute requirement can be            regulatory responses to the accident (termed Tier 3). NRDC overly burdensome and imposed a 90-minute requirement,             believes that the NRC should reconsider its approach and instead.211 The NRC seems to believe that all severe accidents      promptly address severe accident safety issues involving would be slow-moving station-blackout accidentsa                    hydrogen. In this section we outline a number of safety complete loss of grid-supplied and backup onsite alternating        initiatives that the NRC should pursue to reduce the risk of current powerlike the Fukushima Daiichi accident; it does          hydrogen explosions in severe accidents.

not consider that fast-moving accidents are also possible.

Deployed at Shin-Kori 1 and 2; Shin-Wolsong 1 and 2, South Korea.

To control the reactor, dozens of control rod extensions (2) must penetrate the vessel closure head (3) via nozzles (1) so that control rods can be withdrawn or inserted to control the "ssion reaction in nuclear fuel assemblies (8).

Highly pressurized water in the primary cooling loop enters the reactor vessel at (7) and exits at (5), the site of coolant temperature measurements that are supposed to guide operator actions in an accident.

Source: econtent.unm.edu/cdm/search/collection/nuceng 37 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents

Figure 17: GE Boiling Water Reactor (BWR) Model 6 Reactor Vessel Note that control rod blades on the bottom must be hydraulically driven upward into the core, rather than dropping from above as they do in a PWR.

Figure 18 Source: Reactor Concepts Manual, Boiling Water Reactor Systems, USNRC, Technical Training Center, www.

V. NRDCS RECOMMENDATIONS FOR REDUCING THE RISK OF HYDROGEN EXPLOSIONS IN SEVERE NUCLEAR ACCIDENTS A. DEVELOP AND EXPERIMENTALLY                                        C. SIGNIFICANTLY IMPROVE EXISTING VALIDATE COMPUTER SAFETY                                            OXYGEN AND HYDROGEN MONITORING MODELS THAT WOULD BE CAPABLE OF                                      INSTRUMENTATION CONSERVATIVELY PREDICTING RATES                                      The NRC should reclassify oxygen and hydrogen monitors OF HYDROGEN GENERATION IN SEVERE                                    as safety-related equipment that has undergone full ACCIDENTS                                                            quali"cation (including seismic quali"cation), has redundancy, and has its own independent train of emergency The NRC needs to acknowledge that its existing computer electrical power. These recommendations are in accordance safety models underpredict the rates of hydrogen generation with the conclusions of the NRCs Advisory Committee that occur in severe accidents. The NRC should conduct a on Reactor Safeguards (ACRS), which stated that [t]he series of experiments with multi-rod bundles of zirconium experience at Fukushima showed that essential reactor and alloy fuel rod simulators and/or (actual) fuel rods as well as containment instrumentation should be enhanced to better study the full set of existing experimental data. The NRCs withstand beyond-design basis accident conditions and objective in this effort should be to develop models capable that [r]obust and diverse instrumentation that can better of predicting with greater accuracy the rates of hydrogen withstand severe accident conditions is needed to diagnose, generation that occur in severe accidents.

safety analyses to determine if existing PARs should be removed from plant containments. It is possible such analyses would "nd that removing PARs would help improve            D. UPGRADE CURRENT CORE DIAGNOSTIC safety in the event of a severe accident. Until PARs are CAPABILITIES IN ORDER TO BETTER SIGNAL developed that do not pose a risk of ignitions in elevated hydrogen concentrations, the NRC and European regulators            TO PLANT OPERATORS THE CORRECT should also review whether to replace PARs with electrically        TIME TO TRANSITION FROM EMERGENCY powered thermal hydrogen recombiners. However, this could            OPERATING PROCEDURES TO SEVERE prove costly, and thermal hydrogen recombiners would not            ACCIDENT MANAGEMENT GUIDELINES function in a station-blackout accident unless provided with The NRC should require plants to operate with their own independent train of emergency power.

However, to safely operate thermal recombiners, operators In the event of a severe accident, in-core thermocouples would be required to have instrumentation providing would provide plant operators with crucial information to timely information on the local hydrogen concentrations help them track the progression of core damage and manage throughout the containment.

the accidentfor example, indicating the correct time to transition from EOPs to SAMGs.

E. REQUIRE ALL NUCLEAR POWER PLANTS                                  F. REQUIRE THAT DATA FROM LEAK RATE TO CONTROL THE TOTAL QUANTITY OF                                    TESTS BE USED TO HELP PREDICT THE HYDROGEN THAT COULD BE GENERATED IN                                  HYDROGEN LEAK RATES OF THE PRIMARY A SEVERE ACCIDENT                                                    CONTAINMENT OF EACH BWR MARK I The NRC should require all PWRs (with large dry                      AND MARK II LICENSED BY THE NRC IN containments, subatmospheric containments, and ice                  DIFFERENT SEVERE ACCIDENT SCENARIOS condenser containments) and BWR Mark IIIs to operate with The NRC should require that data from overall leak rate tests systems for combustible gas control that would effectively and local leak rate testsalready required by Appendix J and safely control the total quantity of hydrogen that to Part 50 for determining how much radiation would be could potentially be generated in different severe accident released from the containment in a design basis accident scenarios (this value is different for PWRs and BWRs). The be used to help predict hydrogen leak rates from the primary NRC should also require the same for BWR Mark I and Mark containment of each BWR Mark I and Mark II licensed by II unless it is demonstrated that venting (without causing the NRC under different severe accident scenarios. If data signi"cant radiological releases) their inerted containments from an individual leak rate test indicates that dangerous would effectively and safely control the hydrogen generated quantities of explosive hydrogen gas would leak from a in severe accidents. Systems for combustible gas control primary containment in a severe accident, the plant owner also need to effectively and safely control the total quantity would be required to repair the containment.

allowing repairs to be made immediately before the testing of Additionally, the NRC should require all PWRs and BWR potential leakage paths, such as containment welds, valves, IIIs to operate with systems for combustible gas control "ttings, and components which penetrate containment.213 that would be capable of preventing local concentrations Additionally, NRDC recommends that the NRC reevaluate of hydrogen in the containment or other structures its plan to extend the intervals of overall and local leak rate from reaching levels that would support combustions, tests to once every 15 years and 75 months, respectively.214 de"agrations, or detonations that could cause a loss of (There are two types of local leak rate tests; Type B is containment integrity and/or necessary accident mitigating required at least once every 10 years.) The NRC needs to features.

conduct safety analyses that take into account the relatively Furthermore, the NRC should require licensees of PWRs greater vulnerability of BWR Mark I and Mark II primary with ice condenser containments and BWR Mark IIIs (and containments to hydrogen leakage. It is probable that the any other nuclear power plants that would operate with intervals between leak rate tests would need to be shortened hydrogen igniter systems) to perform analyses demonstrating rather than extended.

such tests do not provide accurate assessments of preexisting containment leak rates. The NRC needs to investigate whether repairs have been recently made immediately before conducting as found tests. More important, the NRC needs to fully integrate into its regulatory role the fact that in the Fukushima Daiichi accident, hydrogen leaked from the primary containments of Units 1, 2, and 3 and detonated in the secondary containments of Units 1, 3, and 4, causing large radiological releases.

that a nuclear facility must be designed and built to withstand without loss to the systems, structures, and components necessary to ensure public          27 Atomic Energy Commission, Safety Evaluation Report for Indian health and safety. See www.nrc.gov/reading-rm/basic-ref/glossary/design        Point Nuclear Generating Unit No. 3, Docket No. 50-286, September basis-accident.html.                                                           21, 1973, available at: www.nrc.gov, Electronic Reading Room, ADAMS Documents, Accession Number: ML072260465, p. 6-10.

11 The NRC states that beyond design basis accident is a term used as a technical way to discuss accident sequences that are possible but         28 E. Bachellerie et al., Designing and Implementing a PAR-System in were not fully considered in the design process because they were              NPP Containments, p. 158.

(located at: http://www.nrc.gov/reactors/bwrs.html) and NRC, Pressurized Water Reactors (located at: http://www.nrc.gov/reactors/    56 A.P. Ramsey, T. McKrell, and M.S. Kazimi, Silicon Carbide Oxidation pwrs.html).                                                              in High Temperature Steam, Advanced Nuclear Power Program, MIT-ANP-TR-139, 2011, abstract.

36 Recent designs of BWR and PWR fuel assemblies have on the order of 96 and 264 fuel rods per assembly, respectively. Hence BWR and        57 A triplex cladding design consists of three layers of material PWR cores can have up to approximately 76,800 and 52,800 fuel rods per    surrounding the nuclear fuel: an inner layer of dense silicon carbide for core, respectively; so BWRs cores can have approximately 45 percent      "ssion gas retention, a central composite layer of wound silicon carbide more fuel rods. NRC, Certi"cate of Compliance No. 1014, Appendix        "bers to enhance mechanical performance, and an outer environmental B, Approved Contents and Design Features for the Hi-Storm 100 Cask      barrier coating to enhance corrosion resistance. See Ken Yueh, David System, (available at ADAMS No: ML13351A189), pp. 2.39, 2.44.            Carpenter, and Herbert Feinroth, Clad in Clay, Nuclear Engineering International (January 2010), p. 14-15.

38 Jae Sik Yoo and Kune Yull Suh, Analysis of TMI-2 Benchmark            59 A 2011 Idaho National Laboratory report states that the thermal Problem Using MAAP4.03 Code, Nuclear Engineering and Technology          conductivity of silicon carbide can exceed the value of zirconium before 41, No. 7 (September 2009), p. 949.                                      irradiation. Extended irradiation tends to lower the [thermal] conductivity to a value half to one-third that of zirconium. See George Grif"th, Idaho 39 IAEA, Mitigation of Hydrogen Hazards in SA, p. 6.

60 David M. Carpenter, Gordon E. Kohse, and Mujid S. Kazimi, An CSNI/R(2001)15, October 1, 2001, Part I: B. Clément (IPSN), K. Trambauer Assessment of Silicon Carbide as a Cladding Material for Light Water (GRS), and W. Scholtyssek (FZK), Working Group on the Analysis and Reactors, Advanced Nuclear Power Program, MIT-ANP-TR-132, Management of Accidents, GAMA Perspective Statement on In-November 2010, abstract.

Vessel Hydrogen Sources, p. 15 (hereinafter: In-Vessel and Ex-Vessel Hydrogen Sources, Part I).                                              61 Electric Power Research Institute, Silicon Carbide Provides Opportunity to Enhance Nuclear Fuel Safety, EPRI Progress Report, 41 IAEA, Mitigation of Hydrogen Hazards in SA, p. 6.

2.2 x 106 cubic feet. PWRs with ice condenser containments and 48 LOFT LP-FP-2 was conducted in the Loss-of-Fluid Test Facility at Idaho BWR Mark IIIs have containment design pressures of approximately National Engineering Laboratory in July 1985. The CORA and QUENCH        20 psig and 15 psig, respectively; PWR large dry containments have a tests were conducted at Karlsruhe Institute of Technology in Germany in  design pressure of approximately 53 psig. See M.F. Hessheimer et al.,

the 1980s and 1990s.                                                      Containment Integrity Research at SNL, NUREG/CR-6906, p. 24.

68 Charles Miller et al., Recommendations for Enhancing Reactor Safety    87 Kahtan N. Jabbour, NRC, letter regarding Turkey Point Units 3 and 4, in the 21st Century: The Near-Term Task Force Review of Insights from      exemption from hydrogen control requirements, December 12, 2001, the Fukushima Daiichi Accident, p. 42.                                    Attachment 2, Safety Evaluation by the Of"ce of Nuclear Reactor Regulation, Turkey Point Units 3 and 4, available at: www.nrc.gov, NRC 69 These analyses were conducted for different PWRs, which have Library, ADAMS Documents, Accession Number: ML013390647, p. 4.

containments with different free volumes and different quantities of fuel cladding (active length) in their cores; the containments of these PWRs    88 W. E. Lowry et al., Lawrence Livermore National Laboratory, Final also have different design pressures and estimated failure pressures.      Results of the Hydrogen Igniter Experimental Program, NUREG/CR-Therefore, the results of these analyses do not directly apply to all      2486, February 1982, p. 4.

pressure spikes that a PWR containment might be expected to incur if an explosionof the quantity of hydrogen generated from a zirconium-steam      90 OECD Nuclear Energy Agency, Report on FA and DDT, p. 1.2.

71 Kahtan N. Jabbour, NRC, letter regarding Turkey Point Units 3 and 4, exemption from hydrogen control requirements, December 12, 2001,            94 Helmut Karwat, Igniters to Mitigate the Risk of Hydrogen , Safety Evaluation by the Of"ce of Nuclear Reactor            ExplosionsA Critical Review, Nuclear Engineering and Design 118, Regulation, Turkey Point Units 3 and 4, available at: www.nrc.gov, NRC    1990, p. 267.

73 Pounds per square inch absolute is the value of a given pressure      97 A number of hydrogen combustion experiments have been conducted relative to a vacuum (0.0 pounds per square inch).                          at Sandia National Laboratories; for example, such experiments were 74 Power Authority of the State of New York, Consolidated Edison            conducted in the 1980s at the FLAME facilitya rectangular channel Company of New York, Indian Point Probabilistic Safety Study, Vol.        100 feet long, 8 feet high, and 6 feet wide. M.P. Sherman et al., Sandia 8, 1982, available at: www.nrc.gov, NRC Library, ADAMS Documents,          National Laboratories, FLAME Facility: The Effect of Obstacles and Accession Number: ML102520201, p. 4.2-1 and Appendix 4.4.1, p. 14.          Transverse Venting on Flame Acceleration and Transition to Detonation for Hydrogen-Air Mixtures at Large Scale, NUREG/CR-5275, available at:

8, 1982, available at: www.nrc.gov, NRC Library, ADAMS Documents,          98 Most experiments investigating the lower hydrogen concentration Accession Number: ML102520201, p. 4.3-22, 4.3-23.                          limits at which de"agration-to-detonation transition occurs have been conducted in detonation tubes; such tubes have been 39 to 70 feet long 76 M.F. Hessheimer et al., Containment Integrity Research at SNL,        and about 11 to 17 inches in diameter. OECD Nuclear Energy Agency, NUREG/CR-6906, p. 28; the source of this quote is NRC, Severe              Report on FA and DDT, p. 3.5.

Accident Risks: An Assessment or Five U.S. Nuclear Power Plants, NUREG-1150, Vol. 3, January 1991, Appendix D, Responses to                99 OECD Nuclear Energy Agency, International Standard Problem ISP-47 Comments on First Draft of NUREG-1150, p. D-22.                            on Containment Thermal Hydraulics: Final Report, NEA/CSNI/R(2007)10, September 2007, p. 7.

100 Westinghouse, AP1000 Design Control Document, Rev. 19, Tier 78 M. F. Hessheimer et al., Containment Integrity Research at SNL,        2 Material, Chapter 19, Probabilistic Risk Assessment, Sections 19.41 NUREG/CR-6906, p. 8.                                                        to 19.54, June 13, 2011, available at: www.nrc.gov, NRC Library, ADAMS 79 IAEA, Mitigation of Hydrogen Hazards in SA, p. 62.                    Documents, Accession Number: ML11171A409, p. 19.41-2.

108 In January 1985, the NRC began requiring plant owners to install        126 NRC, Proceedings of the U.S. Nuclear Regulatory Commission hydrogen control systems in the containments of such designs. See NRC      Eighteenth Water Reactor Safety Information Meeting, NUREG/CP-Policy Statement, Combustible Gas Control in Containment, Federal        0114, Vol. 2, April 1991. S.B. Dorofeev et al., Evaluation of the Hydrogen Register, Vol. 68, No. 179, September 16, 2003, p. 54124.                  Explosion Hazard, available at: www.nrc.gov, NRC Library, ADAMS Documents, Accession Number: ML042250131, p. 328.

109 PWRs with ice condenser containments and BWR Mark IIIs have containment design pressures of approximately 20 psig and 15          127 Advisory Committee on Reactor Safeguards, 586th Meeting, psig, respectively. See M.F. Hessheimer et al., Containment Integrity      September 8, 2011, available at: ADAMS Documents, Accession Number:

Research at SNL, NUREG/CR-6906, p. 24.                                     ML11256A117, p. 95.

110 Allen L. Camp et al., Sandia National Laboratories, Light Water        128 Peter Hofmann, Current Knowledge on Core Degradation Reactor Hydrogen Manual, NUREG/CR-2726, August 1983, p. 4-107.             Phenomena, a Review, Journal of Nuclear Materials 270, Nos. 1-2 (April 1, 1999), p. 208.

111 NRC Policy Statement, Combustible Gas Control in Containment, Federal Register 68, No. 179 (September 16, 2003), p. 54124.               129 Westinghouse, AP1000 Design Control Document, Rev. 19, Tier 2 Material, Chapter 19, Probabilistic Risk Assessment, Appendix 112 In December 1981, the NRC began requiring plant owners to operate 19D, Equipment Survivability Assessment, June 13, 2011, available BWR Mark Is and Mark IIs with inerted primary containments. See NRC at: www.nrc.gov, NRC Library, ADAMS Documents, Accession Number:

Policy Statement, Combustible Gas Control in Containment, Federal ML11171A416, p. 19D-3.

Register, Vol. 68, No. 179, September 16, 2003, p. 54123.

130 Westinghouse, AP1000 Design Control Document, Rev. 19, Tier 113 Federal Register 68, No. 179 (September 16, 2003), p. 54141.

2 Material, Chapter 1, Introduction and General Description of Plant, 114 IAEA, Mitigation of Hydrogen Hazards in SA, p. 74.                   Section 1.9, June 13, 2011, available at: www.nrc.gov, NRC Library, 115 BWR Mark I and Mark II primary containments have volumes of            ADAMS Documents, Accession Number: ML11171A337, p. 1.9-80.

approximately 0.28 x 106 cubic feet and 0.4 x 106 cubic feet, respectively; 131 K. Fischer, et al., Hydrogen Removal from LWR Containments these are about one-eighth and one-sixth the volumes, respectively,        by Catalytic-Coated Thermal Insulation Elements (THINCAT), Nuclear of typical PWR large dry containments. See M.F. Hessheimer et al.,         Engineering and Design 221 (January 2003), p. 146.

132 Westinghouse quali"es that the AP1000 containments hydrogen 116 NRC, Order Modifying Licenses with Regard to Reliable Hardened        igniter system, if operational during a severe accident, will burn hydrogen Containment Vents, EA-12-050, March 12, 2012, available at: www.          as soon as the lean upward "ammability limits are met [emphasis nrc.gov, NRC Library, ADAMS Documents, Accession Number:                    added]. See Westinghouse, AP1000 Design Control Document, Rev.

ML12054A694.                                                                19, Tier 2 Material, Chapter 19, Probabilistic Risk Assessment, Sections 117 See NRC, Installation of a Hardened Wetwell Vent, Generic Letter      19.41 to 19.54, p. 19.41-4.

89-16, September 1, 1989, p. 1. Generic Letter 89-16 states that the      133 NRC, letter to all licensees holding operating licenses and Commission has directed the [NRC] staff to approve installation of a        construction permits for nuclear power plants, except licensees of BWR hardened vent under the provisions of 10 CFR 50.59 [Changes, Tests,       Mark I plants, Completion of Containment Performance Improvement and Experiments] for licensees, who on their own initiative, elect to      Program, Etc., July 6, 1990, available at: www.nrc.gov, NRC Library, incorporate this plant improvement.                                       ADAMS Documents, Accession Number: ML031210418, p. 1.

118 NRC, Installation of a Hardened Wetwell Vent, Generic Letter 89-     134 D.W. Stamps et al., Sandia National Laboratories, Hydrogen-Air-16, September 1, 1989, p. 1.                                               Diluent Detonation Study for Nuclear Reactor Safety Analyses, NUREG/

119 NRC Policy Statement, Combustible Gas Control in Containment,         CR-5525, January 1991, available at: www.nrc.gov, NRC Library, ADAMS Federal Register 68, No. 179 (September 16, 2003), p. 54128; and see        Documents, Accession Number: ML071700388, p. 53-p. 54.

NRC Policy Statement Severe Reactor Accidents Regarding Future            135 K. Fischer et al., Hydrogen Removal from LWR Containments Designs and Existing Plants, Federal Register 50, No. 153 (August 8,      by Catalytic-Coated Thermal Insulation Elements (THINCAT), Nuclear 1985), p. 32138-32150.                                                     Engineering and Design 221 (January 2003), p. 146.

120 Westinghouse, AP1000 Design Control Document, Rev. 19, Tier          136 E. Bachellerie et al., Designing and Implementing a PAR-System in 2 Material, Chapter 19, Probabilistic Risk Assessment, Sections 19.34    NPP Containments, p. 159.

to 19.35, June 13, 2011, available at: www.nrc.gov, NRC Library, ADAMS 137 OECD Nuclear Energy Agency, Report on FA and DDT, p. 1.6.

Documents, Accession Number: ML11171A405, p. 19.34-4.

IAEA, Mitigation of Hydrogen Hazards in SA, p. 66.

121 M.P. Sherman et al., Sandia National Laboratories, FLAME Facility:

138 Eckardt, Bernd A., Michael Blase, and Norbert Losch, Containment The Effect of Obstacles and Transverse Venting on Flame Acceleration        hydrogen control and "ltered venting design and implementation, and Transition to Detonation for Hydrogen-Air Mixtures at Large Scale,     Framatome ANP, Offenbach, Germany (2002), p. 3-4.

NUREG/CR-5275, April 1989, available at: ADAMS Documents, Accession Number: ML071700076, p. 2.                                                 139 Sonnenkalb, Martin, and Gerhard Poss, The international test programme in the THAI Facility and its use for code validation, 122 Westinghouse, AP1000 Design Control Document, Rev. 19, Tier          EUROSAFE Forum, Brussels, Belgium (2009), pp. 16-17.

2 Material, Chapter 19, Probabilistic Risk Assessment, Sections 19.41 140 In January 1985, the NRC began requiring plant owners to install to 19.54, June 13, 2011, available at: www.nrc.gov, NRC Library, ADAMS hydrogen control systems in the containments of such designs. See NRC Documents, Accession Number: ML11171A409, p. 19.41-4.

Policy Statement, Combustible Gas Control in Containment, Federal 123 D.W. Stamps et al., Sandia National Laboratories, Hydrogen-Air-        Register, Vol. 68, No. 179, September 16, 2003, p. 54124.

Diluent Detonation Study for Nuclear Reactor Safety Analyses, NUREG/

141 Helmut Karwat, Igniters to Mitigate the Risk of Hydrogen CR-5525, January 1991, available at: www.nrc.gov, NRC Library, ADAMS ExplosionsA Critical Review, Nuclear Engineering and Design 118, Documents, Accession Number: ML071700388, p. 43.

1990, p. 268.

124 G. Ciccarelli et al., Brookhaven National Laboratory, The Effect of 142 OECD Nuclear Energy Agency, Report on FA and DDT, p. 1.10.

Initial Temperature on Flame Acceleration and De"agration-to-Detonation Transition Phenomenon, NUREG/CR-6509, May 1998, available at:             143 Xiao Jianjun, Zhou Zhiwei, and Jing Xingqing, Safety www.nrc.gov, NRC Library, ADAMS Documents, Accession Number:                Implementation of Hydrogen Igniters and Recombiners for Nuclear Power ML071650380, p. 1.                                                         Plant Severe Accident Management, Tsinghua Science and Technology 11, No. 5 (October 2006), p. 557.

125 D.W. Stamps et al., Sandia National Laboratories, Hydrogen-Air-Diluent Detonation Study for Nuclear Reactor Safety Analyses, NUREG/

CR-5525, January 1991, available at: www.nrc.gov, NRC Library, ADAMS Documents, Accession Number: ML071700388, p. 43.

45 NRDC Preventing Hydrogen Explosions In Severe Nuclear Accidents