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Fukushima Nuclear Power Plant Accident and Nuclear Perspectives Tetsuo YUHARA
The University of Tokyo, the Canon Institute for Global Studies
Hiroshi UJITA
Tokyo Institute of Technology
Fengjun DUAN
The Canon Institute for Global Studies
1. Introduction
Here, the Fukushima Daiichi Severe Accident is described and the direction for nuclear power after the
accident is discussed. Energy mixture formation against global warming is further examined. Taking the effort
for energy-saving as major premise, carbon-sequestration for fossil fuel, renewable energy and nuclear energy
should be altogether developed, which means energy best mix is achieved, under the CO2 constraint around
450ppm atmosphere.
2. Severe Accident of Fukushima Daiichi Nuclear Power Plant
2.1 What happened in the Fukushima Daiichi Nuclear Power Plant
East- Japan Great Earthquake is described, as follows;
Magnitude of the Earthquake (Mw) is 9.0, which is ranked 4th largest in the world. All 15 plants located
east coast of north Japan suffered Earthquake, while every plant was successfully shutdown as same as
Kashiwazaki plants suffered large Earthquake in 2007.
The first and highest tsunami wave was observed at 15:51 (65 min. after the earthquake) of March 11th at a
point 50km north of the Fukushima Daiichi Nuclear Power Station. All plants were attacked by Tsunami,
while observed Tsunami height only in Fukushima Daiichi Nuclear Power Plant is over actual ground level (or
design height), and therefore Loss of Power phenomena have occurred in 3 plants in Daiichi site as
summarized in Table 1.
Status of the Nuclear Power Stations hit by the Earthquake and the Tsunami, and accident process are
summarized as below;
(1) On March 11th, there was a huge magnitude 9.0 earthquake that occurred off the Pacific Coast of Japan.
All Nuclear Power Plants (NPPs) on the east coast were shut down safely (See Fig.1 (a)). Every emergency
cooling function succesfully operated and was cooling the reactor core.
(2) About one hour later, a huge tsunami hit Japan. However, all NPPs continued cooling down operations,
except for Fukushima Daiichi NPP (1F), where Residual Core Cooling system still operated (See Fig.1
(b)).
(3) Because 1F NPP was attacked by a tsunami that was much higher than the plant was designed for, the Sea
Water Pumps and Power Supply Systems were flooded and the plant then lost the cooling systems due to a
Station Blackout, etc. (See Fig.1 (c)).
- Operating units (1F1, 2& 3) lost the Core and Spent Fuel Pool cooling systems
- Outage unit (1F4) lost the Spent Fuel Pool cooling systems
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Table 1 Status of the Nuclear Power Plants (NPPs) hit by the quake and the tsunami
NPS Unit Type MWe Before Quake After Quake After Tsunami Acceleration (gal) Tsunami Height
HigashiDori 1 BWR-5 1,100 Outage Cold Shutdown Cold Shutdown --- ---
Onagawa
1 BWR-4 524 Operating Automatic Scram Cold Shutdown 587 [529] Design: 9.1m
Ground level: 13.8m
(Observed: 13m) 2 BWR-5 825 Reactor Start Automatic Scram Cold Shutdown 607 [594]
3 BWR-5 825 Operating Automatic Scram Cold Shutdown 573 [512]
Fukushima
Daiichi
(1F)
1 BWR-3 460 Operating Automatic Scram Loss of cooling 447 [489] Design: 5.7m
Ground level:
10m (1F1-4)
13m (1F5&6)
(Observed: 14-15m)
2 BWR-4 784 Operating Automatic Scram Loss of cooling 550 [438]
3 BWR-4 784 Operating Automatic Scram Loss of cooling 507 [441]
4 BWR-4 784 Outage Cold Shutdown Cold Shutdown 319 [445]
5 BWR-4 784 Outage Cold Shutdown Cold Shutdown 548 [452]
6 BWR-5 1,100 Outage Cold Shutdown Cold Shutdown 444 [448]
Fukushima
Daini (2F)
1 BWR-5 1,100 Operating Automatic Scram Cold Shutdown 254 [434] Design: 5.2m
Ground level: 12m
(Observed: 6.5-7m,
Locally >14m)
2 BWR-5 1,100 Operating Automatic Scram Cold Shutdown 243 [428]
3 BWR-5 1,100 Operating Automatic Scram Cold Shutdown 277 [428]
4 BWR-5 1,100 Operating Automatic Scram Cold Shutdown 210 [415]
Tokai Daini - BWR-5 1,100 Operating Automatic Scram Cold Shutdown 225 [400] Ground level: 8m
(Observed: 5.4m)
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Figure 1(a). Accident Progression - just after the earthquake
Figure 1(b). Accident Progression - just after the tsumami hit
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Figure 1(c). Accident Progression - Loss of core cooling
Figure 1(d). Accident Progression - S/C vent and Water injection
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- Outage units (1F5& 6) successfully achieved cold shutdown through recovery measures.
(4) Hydrogen explosions occurred at the units in which cooling function was lost, which may have been
caused by a Zirconium-water reaction. In addition, the Reactor Building was damaged (1F1, 3&4) (See
Fig.1 (d)).
(5) For the units that lost the cooling system, water is continuously being injected from outside (1F1-4) (See
Fig.1 (d).
(6) Quite a large amount of radioactive material has been released into the atmosphere and sea, and
continuous efforts are being made to bring the situation under control. Radiation level decreases gradually
for three month to steady level (See Fig.2).
Figure2. Radiation dose around the NPP
(7) Extensive recovery efforts are being continued. Stable cooling is scheduled to take three months and cold
shutdown is scheduled to take another 3 to 6 months (See Fig.3).
As the total safety function status is summarized in Fig. 4, shutdown was successfully done, while cooling and
containment functions were damaged.
International Nuclear and Radiation Scale rating of three accidents are compared in Fig.5, Fukushima is
assessed as Level 7 but release amount is one order less than Chernobyl even three units damaged. The reason
why Fukushima and TMI is less release than Chernobyl is due to reactivity control capability and fission
product containment potential in the water.
Figure 6 shows Frequency-Consequence Curves (only for early fatalities) for Severe Accidents in various
energy chains, OECD 1969-2001. Even the Chernobyl accident, the risk is very small than other energy
industries, and we cannot plot Fukushima or TMI accidents because no fatalities (people death). The issue to
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be care in near future would be psychological problem such as Posttraumatic stress disorder for evacuating
people, as appeared in Chernobyl case.
Figure3. Future Schedule - Roadmap towards Restoration
(Red colored: newly added to the previous version, ☆: reported to the government)
2.2 Countermeasures
Countermeasures, which are lessons learned from accident, are summarized here.
1. against Station Black-Out
1) Ensuring the water tightness of essential equipment facilities, such as Metal-clad switchgears and
Emergency Diesel Generators.
2) Secure power supply system through diversification of Power Supply sources, Fukushima Daiichi Nos. 5
and 6 were safe due to diversification.
3) Secure robust cooling functions of reactor and containment vessel.
2. against Severe Accident
Severe Accident means core melting and damage of Containment Vessel. So far Severe Accident is
considered as Beyond Design Basis Accident (B-DBA), those measures should be extensively evaluated,
thorough Accident Management (AM) measures.
1) Enhancement of prevention measures of hydrogen explosion
2) Enhancement of Containment Venting system
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Figure 4. Station Black Out with Loss of Heat Sink
Figure 5. INES Rating of three accidents
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Figure 6. Frequency-Consequence Curves for Severe Accidents in Various Energy Chains OECD 1969-2001
The causes of accident and countermeasures of safety on the NPP are considered on the aspects of
regulations, designs and operations. To protect the Severe Accident under the station black out accident, safety
design of NPP is further examined once more.
3. Rethinking nuclear power plant safety issues
3.1 Accident root cause analysis
First of all, Fukushima Daiichi accident issues will be presented. "Assuming while not considering such
event!" That is the phrase to represent the Fukushima Daiichi Accident problem. First priority for safety
related personnel is that Human Factor and Common Mode Failure are always worth keeping in mind.
Station Blackout: Loss of offsite Power & Emergency DG failure
Site with multiple units, Earthquake and Tsunami multiple events
Everything would be done completely, while by formalism
Imagination lack on risk or severe condition by responsible personnel
There are two items to be discussed, which are considered to be root cause of the Accident. One is “Rare
Event” treatment; the other is “Crisis Management” problem, while both are due to lack of imagination by
responsible personnel. Rare Event is high consequence with low frequency. Low consequence with high
frequency event is easy to treat by commercial reason, while it is very difficult to handle the rare event even
the risk is just the same. Unexpected event has been used frequently, but it is the risk-benefit issues to assume
or not. Tsunami Probabilistic Risk Analysis has been carried out, and safety related personnel knew the
severity of the effect well. Regardless of the initiating event, lack of measures to “Complete Loss of Power” is
to be asked.
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There are many Crisis Management problems as follows;
Delay in initial response
Delay in decision making
Delay in external support request
Poor collaboration among government (Prime Minister Kan), bureaucrats (NISA, JNES), and
interested party (TEPCO)
Poor information disclosure in emergency situation
After all, it is a matter of organizational culture. Anyway, rare event occurred on one occasion, measures
had to be taken. Fukushima Daiichi Nuclear power plants as “National Privatization” destroyed by large-scale
disasters should be treated same as infrastructure systems as a national policy.
3.2 What should be done to improve the safety
Safety design principle is “Defense in Depth” concept as shown below, which should be therefore
reconsidered reflecting the accident causes.
• Preventing damage
• Failure expansion mitigation: autonomous characteristic, inherent safety (intrinsic safety)
• Incident prevention: a fail-safe, fool-proof, redundancy, diversity
• Incident expansion mitigation: confinement, control release
• Environmental effects mitigation: evacuation
Usual systems focus on the forefront function, such as preventing damage, expansion mitigation, or
incident prevention, while safety critical systems increases attention to back-up function, if it has a large
enough impact on the environment. Common Mode Failure, such as External Initiating Event, which is
usually Rare Event, or auxiliary systems failure is difficult to install to Defense in Depth design.
• Earthquake & Tsunami, Off-site Power & EDG & Buttery
• Sea Water Cooling
Swiss Cheese Model proposed by Reason, J indicates operational problem. Fallacy of the defense in depth
has frequently occurred recently because plant system is safe enough as operators not consider system safety.
And then safety culture degradation would be happened, whose incident will easily become organizational
accident. Such situation requires final barrier that is Crisis Management.
Concept of “Soft Barrier” has been proposed. There are two type of safety barriers, one is Hard Barrier that
is simply Defense in Depth. The other is Soft Barrier, which maintains the hard barrier as expected condition,
makes it perform as expected function. Even when it does not perform its function, human activity to prevent
hazardous effect and its support functions, such as manuals, rules, lows, organization, social system, etc. Soft
Barrier can be further divided to two measures, one is “Software for design”: Common mode failure treatment,
Safety logic, Usability, etc. The other is “Humanware for operation”, such as operator, maintenance personnel,
Emergency Procedure, organization, management, Safety Culture, etc.
4. Mitigation of global warming by optimum energy mixture
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Setting and meeting the common target of CO2 emission and energy mix are proposed on the basis of
climate science and engineering model simulations. The feasible target for emission scenario named
“over-shoot and zero emission” is proposed. International cooperation would enable the practical mitigation
against global warming, based on cost minimum optimization over the world. Innovative and useful
technologies should be introduced with well balances among renewable energy, nuclear energy and fossil
energy.
Target of emission scenario and long term energy vision against global warming is discussed here. Feasible
CO2-emission scenario of the world, based on scientific concept is set as the target. To meet the target, world
energy mix fitting to this CO2 emission scenario was optimized well-balanced between investment and merit
of fuel savings. International system on simple and transparent corporations, excluding speculation for carbon
offset has been proposed. Alternative and feasible global emission pathway by scientific analysis based on
target of global mean temperature rise, to limit the global surface temperature rise to approximate 2 degree C
compared to pre-industrial levels, to decrease the CO2 concentration by zero emission after a peak over the
target concentration by Global Emission Pathway: Z650 as shown in Fig. 7(a), which means that total
accumulation CO2 in this century is 650GtC. Compared with the IPCC 450ppm equilibrium stabilization
scenario, the proposed global emission pathway, so called Z650 scenario, allows a relatively large emissions
during the near short term as shown in Fig. 7(b). Therefore, the Z650 scenario will generate a higher CO2
concentration in the near future. The concentration will exceed 450ppm in a short period, but it will decrease
and stabilize at a lower level. As the result, the Z650 scenario will cause a similar temperature rise with the
IPCC 450ppm scenario as shown in Fig. 7(c). Multi gas GHG concentrations: max 2.3 degree C in 2100 and
saturating 2 degree C towards 2200.
Result of simulation is shown below, in which system cost minimum optimization under Z650 restriction
all over the world;
Total Primary Energy for Z650 shown in Fig. 8(a) continuously increases up to 2100, where both nuclear
and renewable energy increase. Peak of fossil fuel consumption is around 2030. As the results, portion of
Fossil: Nuclear: Renewable is 5: 2: 3 in 2050, while 3: 2: 5, in 2100. Region Total Primary Energy for Z650 is
also examined as shown in Fig. 8(b). In industrialized countries, total primary energy is almost constant up to
2100, where share of fossil fuel gradually decreases and share of renewable energy mainly increases
alternatively. In developing countries, total primary energy continuously increases up to 2100, where peak of
fossil fuel consumption is around 2040, and both nuclear and renewable energy increase remarkably. As CO2
emission is summarized in Fig. 8(c), developing countries would be able to release CO2 much until 2030. As
investment and fuel saving costs are summarized in Fig. 8(d), in industrialized countries (2005 level = 1)
investment cost is $5Tri, while earn fuel saving $4Tri, and in developing countries (2005 level = 1) investment
cost $8Tri, while earn fuel saving $9Tri.
5. Innovative technology and deployment
Innovative technology and deployment to achieve world under CO2 constraint are proposed as follows;
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Figure7. Global Emission Pathway - Z650
(a) CO2 emission; (b) Concentration; (c) Global mean temperature rise
Figure 8(a). Total Primary Energy for Z650
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Figure 8(b). Region Total Primary Energy for Z650
(left: industrialized countries; right: developing countries)
Figure 8(c). CO2 emissions of Z650 scenario
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Figure 8(d). Result of simulation Investment &fuel saving cost
(1) Innovative technology
1) Replacements of clean and highly efficient fossil-power plants (Combined cycles with natural gases and
gasified coals) efficiency: η=30% to 50%〜60%
2) Introductions of advanced nuclear power plants (3rd + and 4th generation reactor systems) and advanced
spent fuel recycle systems
3) Stabilization of unstable renewable energy with large-scaled battery and stable supply with grid networks
4) Fuel alternative in transport sector (Fuel cell vehicle and Electric vehicle)
5) Energy saving in industrial sector , especially steel , cement, paper &pulp and chemical industries
(2) Deployment
1) New systems instead of the current CDM’s short coming (i.e., additionality)
2) Speedy and fair deployment systems of advanced technology
3) Excluding speculations in carbon offset trading mechanism
The feasible target for new emission scenario (Overshoot & Zero-Emission) instead of traditional concept and
energy mix against global warming has been proposed. It demonstrated that international cooperation would
enable the practical mitigation against global warming, based on cost minimum optimization over the world. It
identified that innovative and useful technologies should be introduced over the world. International
cooperation should be advanced with new system instead of additionality of CDM in Kyoto Protocol and
without speculation of carbon trading.
6. Energy issue and role of nuclear energy after the Fukushima Daiichi Accident
Premise here is that "Global warming is an invariant problem!", "Energy security is also the invariant
problem!". The long-term energy demand and supply simulation to minimize the total energy system cost was
conducted for energy prediction during the 21st Century in the world. Taking the effort for energy-saving as
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major premise, carbon-sequestration for fossil fuel, renewable energy and nuclear energy should be altogether
developed, which means energy best mix is achieved, under the CO2 constraint around 450ppm atmosphere.
Nuclear phase-out scenario, in which new nuclear plant construction is prohibited, is possible even
considering the issue of global warming, from simulation as shown in Fig. 9. Until around 2050, mostly
replaced by natural gas. Since 2080, the contribution of the fossil power declined, large-scale introduction of
the Fuel Cell. Nuclear phase-out scenario has two problems; increasing energy costs, little room for
countermeasure and large uncertainties of technology. Therefore, rational use of nuclear power is requested,
that is each country should make decision, Japan and several European countries will be also phase out, while
China, India and ASEAN countries will continue to be introduced. If the accident happens again anywhere in,
it will become the global phase-out. Therefore, rational unified safety standards (organizational structure,
design and operation, regulations) should be reviewed based on the Fukushima Daiichi Problem world-wide
analysis and established in the world.
Figure 9. Z650 and Nuclear power phase out (no newly established since 2020)
Table 2 summarizes the results. In Z650 case, idealized energy mix is obtained, well-balanced between
investment and fuel saving. In Nuclear Phase Out (NuPO) case, unbalance between investment and fuels
saving, and the burden on developing countries increases largely
7. Conclusion
Cause of Fukushima Daiichi Nuclear Accident is simple and primitive, and can be overcome. Main cause
was lack of Water tightness of switchgear, and/ or lack of water proof of emergency diesel generator.
Evolutions of safety technologies of nuclear power plants, such as emergency residual heat removal system
have been in progress for this half a century. The future energy outlook should not be designed by
technologies in 1960’s. Now we are in the age of “Generation 3+” Reactor system, which have passive
safety characteristics.
Nuclear power and renewable energy should be two wheels towards low carbon societies against global
warming with economical growth. Under the new concept on emission scenario and with feasible advanced
technologies, industrialized and developing countries can reach to low carbon societies with the optimized
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energy mix by all-over-the-world-cost minimum simulation. International cooperation system against global
warming should be reestablished on the basis of Science, Feasibility, and Fairness.
Table 2. Summary of results/CO2Emission, Additional investment & Fuel savings in REF, Z650, and NuPO
References
(1) H. Ito, JANTI Report to American Society for Mechanical Engineers, May 12, 2011.
(2) Burgherr & Hirschberg, 2005, Stefan Hirschberg, 22.06.2006, NEA/Paris 13.
(3) T. Matsuno et al., “Stabilization of the CO2 concentration via zero-emission in the next century”,
presented at the 1st CIGS Symposium on Oct. 27, 2009.
(4) RCP Database (version1.0), IIASA Homepage (http://www.iiasa.ac.at/web-apps/tnt/RcpDb) .
(5) T. Yuhara et al., “Towards the harmony - Principles for the new climate regime- ”, presented at the 2nd
CIGS Symposium on Sep. 16, 2011.