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Behavior of nuclear fuel during a reactor accident

April 11, 2024

This page describes how uranium dioxide nuclear fuel behaves during both normal nuclear reactor operation and under reactor accident conditions, such as overheating. Work in this area is often very expensive to conduct, and so has often been performed on a collaborative basis between groups of countries, usually under the aegis of the Organisation for Economic Co-operation and Development's Committee on the Safety of Nuclear Installations (CSNI).

This is a false colour tomography picture of a bundle (FPT1) of 18 irradiated fuel rods (23 GWd/tU mean burn-up) degraded under steam as part of the PHEBUS set of experiments. The black and blue is for areas of low density while red is an area of high density. It can be seen that the fuel has failed mechanically and has formed a pool near the bottom of the bundle. The bottom of the bundle did not melt.

Swelling edit

Cladding edit

Both the fuel and cladding can swell. Cladding covers the fuel to form a fuel pin and can be deformed. It is normal to fill the gap between the fuel and the cladding with helium gas to permit better thermal contact between the fuel and the cladding. During use the amount of gas inside the fuel pin can increase because of the formation of noble gases (krypton and xenon) by the fission process. If a Loss-of-coolant accident (LOCA) (e.g. Three Mile Island) or a Reactivity Initiated Accident (RIA) (e.g. Chernobyl or SL-1) occurs then the temperature of this gas can increase. As the fuel pin is sealed the pressure of the gas will increase (PV = nRT) and it is possible to deform and burst the cladding. It has been noticed that both corrosion and irradiation can alter the properties of the zirconium alloy commonly used as cladding, making it brittle. As a result, the experiments using unirradiated zirconium alloy tubes can be misleading.

According to one paper[1] the following difference between the cladding failure mode of unused and used fuel was seen.

Unirradiated fuel rods were pressurized before being placed in a special reactor at the Japanese Nuclear Safety Research Reactor (NSRR) where they were subjected to a simulated RIA transient. These rods failed after ballooning late in the transient when the cladding temperature was high. The failure of the cladding in these tests was ductile, and it was a burst opening.

The used fuel (61 GW days/tonne of uranium) failed early in the transient with a brittle fracture which was a longitudinal crack.

It was found that hydrided zirconium tube is weaker and the bursting pressure is lower.[2]

The common failure process of fuel in the water-cooled reactors is a transition to film boiling and subsequent ignition of zirconium cladding in the steam. The effects of the intense hot hydrogen reaction product flow on the fuel pellets and on the bundle's wall well represented on the sidebar picture.

Fuel edit

The nuclear fuel can swell during use, this is because of effects such as fission gas formation in the fuel and the damage which occurs to the lattice of the solid. The fission gases accumulate in the void that forms in the center of a fuel pellet as burnup increases. As the void forms, the once-cylindrical pellet degrades into pieces. The swelling of the fuel pellet can cause pellet-cladding interaction when it thermally expands to the inside of the cladding tubing. The swollen fuel pellet imposes mechanical stresses upon the cladding. A document on the subject of the swelling of the fuel can be downloaded from the NASA web site.[3]

Fission gas release edit

As the fuel is degraded or heated the more volatile fission products which are trapped within the uranium dioxide may become free. For example, see.[4]

A report on the release of 85Kr, 106Ru and 137Cs from uranium when air is present has been written. It was found that uranium dioxide was converted to U3O8 between about 300 and 500 °C in air. They report that this process requires some time to start, after the induction time the sample gains mass. The authors report that a layer of U3O7 was present on the uranium dioxide surface during this induction time. They report that 3 to 8% of the krypton-85 was released, and that much less of the ruthenium (0.5%) and caesium (2.6 x 10−3%) occurred during the oxidation of the uranium dioxide.[5]

Heat transfer between the cladding and the water edit

In a water-cooled power reactor (or in a water-filled spent fuel pool, SFP), if a power surge occurs as a result of a reactivity initiated accident, an understanding of the transfer of heat from the surface of the cladding to the water is very useful. In a French study, metal pipe immersed in water (both under typical PWR and SFP conditions), was electrically heated to simulate the generation of heat within a fuel pin by nuclear processes. The temperature of the pipe was monitored by thermocouples and for the tests conducted under PWR conditions the water entering the larger pipe (14.2 mm diameter) holding the test metal pipe (9.5 mm outside diameter and 600 mm long) was at 280 °C and 15 MPa. The water was flowing past the inner pipe at circa 4 ms−1 and the cladding was subjected to heating at 2200 to 4900 °C s−1 to simulate an RIA. It was found that as the temperature of the cladding increased the rate of heat transfer from the surface of the cladding increased at first as the water boiled at nucleation sites. When the heat flux is greater than the critical heat flux a boiling crisis occurs. This occurs as the temperature of the fuel cladding surface increases so that the surface of the metal was too hot (surface dries out) for nucleation boiling. When the surface dries out the rate of heat transfer decreases, after a further increase in the temperature of the metal surface the boiling resumes but it is now film boiling.[6]

Hydriding and waterside corrosion edit

As a nuclear fuel bundle increases in burnup (time in reactor), the radiation begins changing not only the fuel pellets inside the cladding, but the cladding material itself. The zirconium chemically reacts to the water flowing around it as coolant, forming a protective oxide on the surface of the cladding. Typically a fifth of the cladding wall will be consumed by oxide in PWRs. There is a smaller corrosion layer thickness in BWRs. The chemical reaction that takes place is:

Zr + 2 H2O → ZrO2 + 2 H2 (g)

Hydriding occurs when the product gas (hydrogen) precipitates out as hydrides within the zirconium. This causes the cladding to become embrittled, instead of ductile. The hydride bands form in rings within the cladding. As the cladding experiences hoop stress from the growing amount of fission products, the hoop stress increases. The material limitations of the cladding is one aspect that limits the amount of burnup nuclear fuel can accumulate in a reactor.

CRUD (Chalk River Unidentified Deposits) was discovered by Chalk River Laboratories. It occurs on the exterior of the clad as burnup is accumulated.

When a nuclear fuel assembly is prepared for onsite storage, it is dried and moved to a spent nuclear fuel shipping cask with scores of other assemblies. Then it sits on a concrete pad for a number of years waiting for an intermediate storage facility or reprocessing. The transportation of radiation-damaged cladding is tricky, because it is so fragile. After being removed from the reactor and cooling down in the spent fuel pool, the hydrides within the cladding of an assembly reorient themselves so that they radially point out from the fuel, rather than circularly in the direction of the hoop stress. This puts the fuel in a situation so that when it is moved to its final resting place, if the cask were to fall, the cladding would be so weak it could break and release the spent fuel pellets inside the cask.

Corrosion on the inside of the cladding edit

Zirconium alloys can undergo stress corrosion cracking when exposed to iodine;[7] the iodine is formed as a fission product which depending on the nature of the fuel can escape from the pellet.[8] It has been shown that iodine causes the rate of cracking in pressurised zircaloy-4 tubing to increase.[9]

Graphite moderated reactors edit

In the cases of carbon dioxide cooled graphite moderated reactors such as magnox and AGR power reactors an important corrosion reaction is the reaction of a molecule of carbon dioxide with graphite (carbon) to form two molecules of carbon monoxide. This is one of the processes which limits the working life of this type of reactor.

Water-cooled reactors edit

Corrosion edit

In a water-cooled reactor the action of radiation on the water (radiolysis) forms hydrogen peroxide and oxygen. These can cause stress corrosion cracking of metal parts which include fuel cladding and other pipework. To mitigate this hydrazine and hydrogen are injected into a BWR or PWR primary cooling circuit as corrosion inhibitors to adjust the redox properties of the system. A review of recent developments on this topic has been published.[10]

Thermal stresses upon quenching edit

In a loss-of-coolant accident (LOCA) it is thought that the surface of the cladding could reach a temperature between 800 and 1400 K, and the cladding will be exposed to steam for some time before water is reintroduced into the reactor to cool the fuel. During this time when the hot cladding is exposed to steam some oxidation of the zirconium will occur to form a zirconium oxide which is more zirconium rich than zirconia. This Zr(O) phase is the α-phase, further oxidation forms zirconia. The longer the cladding is exposed to steam the less ductile it will be. One measure of the ductility is to compress a ring along a diameter (at a constant rate of displacement, in this case 2 mm min−1) until the first crack occurs, then the ring will start to fail. The elongation which occurs between when the maximum force is applied and when the mechanical load is declined to 80% of the load required to induce the first crack is the L0.8 value in mm. The more ductile a sample is the greater this L0.8 value will be.

In one experiment the zirconium is heated in steam to 1473 K, the sample is slowly cooled in steam to 1173 K before being quenched in water. As the heating time at 1473 K is increased the zirconium becomes more brittle and the L0.8 value declines.[11]

Aging of steels edit

Irradiation causes the properties of steels to become poorer, for instance SS316 becomes less ductile and less tough. Also creep and stress corrosion cracking become worse. Papers on this effect continue to be published.[12]

Cracking and overheating of the fuel edit

This is due to the fact that as the fuel expands on heating, the core of the pellet expands more than the rim. Because of the thermal stress thus formed the fuel cracks, the cracks tend to go from the center to the edge in a star shaped pattern. A PhD thesis on the subject has been published[13] by a student at the Royal Institute of Technology in Stockholm (Sweden).

The cracking of the fuel has an effect on the release of radioactivity from fuel both under accident conditions and also when the spent fuel is used as the final disposal form. The cracking increases the surface area of the fuel which increases the rate at which fission products can leave the fuel.

The temperature of the fuel varies as a function of the distance from the center to the rim. At distance x from the center the temperature (Tx) is described by the equation where ρ is the power density (W m−3) and Kf is the thermal conductivity.

Tx = TRim + ρ (rpellet² – x²) (4 Kf)−1

To explain this for a series of fuel pellets being used with a rim temperature of 200 °C (typical for a BWR) with different diameters and power densities of 250 Wm−3 have been modeled using the above equation. These fuel pellets are rather large; it is normal to use oxide pellets which are about 10 mm in diameter.

  •  
    Temperature profile for a 20 mm diameter fuel pellet with a power density of 250 W per cubic meter. The central temperature is very different for the different fuel solids.
  •  
    Temperature profile for a 26 mm diameter fuel pellet with a power density of 250 W per cubic meter.
  •  
    Temperature profile for a 32 mm diameter fuel pellet with a power density of 250 W per cubic meter.

To show the effects of different power densities on the centerline temperatures two graphs for 20 mm pellets at different power levels are shown below. It is clear that for all pellets (and most true of uranium dioxide) that for a given sized pellet that a limit must be set on the power density. It is likely that the maths used for these calculations would be used to explain how electrical fuses function and also it could be used to predict the centerline temperature in any system where heat is released throughout a cylinder shaped object.[14]

  •  
    Temperature profile for a 20 mm diameter fuel pellet with a power density of 500 W per cubic meter. Because the melting point of uranium dioxide is about 3300 K, it is clear that uranium oxide fuel is overheating at the center.
  •  
    Temperature profile for a 20 mm diameter fuel pellet with a power density of 1000 W per cubic meter. The fuels other than uranium dioxide are not compromised.

Loss of volatile fission products from pellets edit

The heating of pellets can result in some of the fission products being lost from the core of the pellet. If the xenon can rapidly leave the pellet then the amount of 134Cs and 137Cs which is present in the gap between the cladding and the fuel will increase. As a result, if the zircaloy tubes holding the pellet are broken then a greater release of radioactive caesium from the fuel will occur. It is important to understand that the 134Cs and 137Cs are formed in different ways, and hence as a result the two caesium isotopes can be found at different parts of a fuel pin.

It is clear that the volatile iodine and xenon isotopes have minutes in which they can diffuse out of the pellet and into the gap between the fuel and the cladding. Here the xenon can decay to the long lived caesium isotope.

Genesis of 137Cs edit

Formation of 137Cs from its precursors
Element Isotope decay mode half life direct fission yield
Sn 137 β very short (<1 s) 0.00%
Sb 137 β very short (<1 s) 0.03%
Te 137 β 2.5 seconds 0.19%
I 137 β 24.5 seconds 1.40%
Xe 137 β 3.8 minutes 1.44%
Cs 137 β 30 years 0.08%

These fission yields were calculated for 235U assuming thermal neutrons (0.0253 eV) using data from the chart of the nuclides.[15]

Genesis of 134Cs edit

In the case of 134Cs the precursor to this isotope is stable 133Cs which is formed by the decay of much longer lived xenon and iodine isotopes. No 134Cs is formed without neutron activation as 134Xe is a stable isotope. As a result of this different mode of formation the physical location of 134Cs can differ from that of 137Cs.

Formation of 134Cs and its decay products (daughters)
Element Isotope decay mode half life direct fission yield
In 133 β 0.18 seconds 0.00%
Sn 133 β 1.45 seconds 0.07%
Sb 133 β 2.5 minutes 1.11%
Te 133m β (82.5%) 55.4 minutes 0.49%
Te 133 β 12.5 minutes 0.15%
I 133 β 20.8 hours 1.22%
Xe 133 β 5.2 days 0.00%
Cs 133 stable (undergoes neutron activation in the core) 0.00%
Cs 134 β 2.1 years 6.4 x 10−6%

These fission yields were calculated for 235U assuming thermal neutrons (0.0253 eV) using data from the chart of the nuclides.[15]

An example of a recent PIE study edit

In a recent study, used 20% enriched uranium dispersed in a range of different matrices was examined to determine the physical locations of different isotopes and chemical elements.

The fuels varied in their ability to retain the fission xenon; the first of the three fuels retained 97% of the 133Xe, the second retained 94% while the last fuel only retained 76% of this xenon isotope. The 133Xe is a long-lived radioactive isotope which can diffuse slowly out of the pellet before being neutron activated to form 134Cs. The more short-lived 137Xe was less able to leach out of the pellets; 99%, 98% and 95% of the 137Xe was retained within the pellets. It was also found that the 137Cs concentration in the core of the pellet was much lower than the concentration in the rim of the pellet, while the less volatile 106Ru was spread more evenly throughout the pellets.[16]

The following fuel is particles of solid solution of urania in yttria-stabilized zirconia dispersed in alumina which had burnt up to 105 GW-days per cubic meter.[17] The scanning electron microscope (SEM) is of the interface between the alumina and a fuel particle. It can be seen that the fission products are well confined to within the fuel, little of the fission products have entered the alumina matrix. The neodymium is spread throughout the fuel in a uniform manner, while the caesium is almost homogenously spread out throughout the fuel. The caesium concentration is slightly higher at two points where xenon bubbles are present. Much of the xenon is present in bubbles, while almost all of the ruthenium is present in the form of nanoparticles. The ruthenium nanoparticles are not always colocated with the xenon bubbles.

Release of fission products into coolant water in a Three Mile Island type accident edit

At Three Mile Island a recently SCRAMed core was starved of cooling water, as a result of the decay heat the core dried out and the fuel was damaged. Attempts were made to recool the core using water. According to the International Atomic Energy Agency for a 3,000 MW (t) PWR the normal coolant radioactivity levels are shown below in the table, and the coolant activities for reactors which have been allowed to dry out (and over heat) before being recovered with water. In a gap release the activity in the fuel/cladding gap has been released while in the core melt release the core was melted before being recovered by water.[18]

The levels of radioactivity in the coolant of a typical PWR under different conditions (MBq L−1)
Isotope Normal >20% Gap release >10% Core melt
131I 2 200000 700000
134Cs 0.3 10000 60000
137Cs 0.3 6000 30000
140Ba 0.5 100000

Chernobyl release edit

The release of radioactivity from the used fuel is greatly controlled by the volatility of the elements. At Chernobyl much of the xenon and iodine was released while much less of the zirconium was released. The fact that only the more volatile fission products are released with ease will greatly retard the release of radioactivity in the event of an accident which causes serious damage to the core. Using two sources of data it is possible to see that the elements which were in the form of gases, volatile compounds or semi-volatile compounds (such as CsI) were released at Chernobyl while the less volatile elements which form solid solutions with the fuel remained inside the reactor fuel.

According to the OECD NEA report on Chernobyl (ten years on),[19] the following proportions of the core inventory were released. The physical and chemical forms of the release included gases, aerosols and finely fragmented solid fuel. According to some research the ruthenium is very mobile when the nuclear fuel is heated with air.[20] This mobility has been more evident in reprocessing, with related releases of ruthenium, the most recent being the airborne radioactivity increase in Europe in autumn 2017, as with the ionizing radiation environment of spent fuel and the presence of oxygen, radiolysis-reactions can generate the volatile compound ruthenium(VIII) oxide, which has a boiling point of approximately 40 °C (104 °F) and is a strong oxidizer, reacting with virtually any fuel/hydrocarbon, that are used in PUREX.

Some work on TRISO fuel heated in air, with the respective encapsulation of nuclides, has been published.[21]

Table of chemical data edit

Chemical forms of fission products in uranium dioxide,[22] the percentage release at Chernobyl and the temperatures according to Colle et al. required to release 10% of an element from either unoxidized or oxidized fuel. When data from one element is assumed to apply to another element the energy is in Italics.
Element Gas Metal Oxide Solid solution Radioisotopes Release at Chernobyl[19] T required for 10% release from UO2 T required for 10% release from U3O8
Br Yes
Kr Yes 85Kr 100%
Rb Yes Yes
Sr Yes Yes 89Sr and 90Sr 4–6% 1950 K
Y Yes 3.5%
Zr Yes Yes 93Zr and 95Zr 3.5% 2600 K
Nb Yes
Mo Yes Yes 99Mo >3.5% 1200 K
Tc Yes 99Tc 1300 K
Ru Yes 103Ru and 106Ru >3.5%
Rh Yes
Pd Yes
Ag Yes
Cd Yes
In Yes
Sn Yes
Sb Yes
Te Yes Yes Yes Yes 132Te 25–60% 1400 K 1200 K
I Yes 131I 50–60% 1300 K 1100 K
Xe Yes 133Xe 100% 1450 K
Cs Yes Yes 134Cs and 137Cs 20–40% 1300 K 1200 to 1300 K
Ba Yes Yes 140Ba 4–6% 1850 K 1300 K
La Yes 3.5% 2300 K
Ce Yes 141Ce and 144Ce 3.5% 2300 K
Pr Yes 3.5% 2300 K
Nd Yes 3.5% 2300 K
Pm Yes 3.5% 2300 K
Sm Yes 3.5% 2300 K
Eu Yes 3.5% 2300 K

The releases of fission products and uranium from uranium dioxide (from spent BWR fuel, burnup was 65 GWd t−1) which was heated in a Knudsen cell has been repeated.[23] Fuel was heated in the Knudsen cell both with and without preoxidation in oxygen at c 650 K. It was found even for the noble gases that a high temperature was required to liberate them from the uranium oxide solid. For unoxidized fuel 2300 K was required to release 10% of the uranium while oxidized fuel only requires 1700 K to release 10% of the uranium.

According to the report on Chernobyl used in the above table 3.5% of the following isotopes in the core were released 239Np, 238Pu, 239Pu, 240Pu, 241Pu and 242Cm.

Degradation of the whole fuel element edit

Water and zirconium can react violently at 1200 °C, at the same temperature the zircaloy cladding can react with uranium dioxide to form zirconium oxide and a uranium/zirconium alloy melt.[24]

PHEBUS edit

In France a facility exists in which a fuel melting incident can be made to happen under strictly controlled conditions.[25][26] In the PHEBUS research program fuels have been allowed to heat up to temperatures in excess of the normal operating temperatures, the fuel in question is in a special channel which is in a toroidal nuclear reactor. The nuclear reactor is used as a driver core to irradiate the test fuel. While the reactor is cooled as normal by its own cooling system the test fuel has its own cooling system, which is fitted with filters and equipment to study the release of radioactivity from the damaged fuel. Already the release of radioisotopes from fuel under different conditions has been studied. After the fuel has been used in the experiment it is subject to a detailed examination (PIE), In the 2004 annual report from the ITU some results of the PIE on PHEBUS (FPT2) fuel are reported in section 3.6.[27][28]

LOFT edit

The Loss of Fluid Tests (LOFT) were an early attempt to scope the response of real nuclear fuel to conditions under a loss-of-coolant accident, funded by USNRC. The facility was built at Idaho National Laboratory, and was essentially a scale-model of a commercial PWR. ('Power/volume scaling' was used between the LOFT model, with a 50MWth core, and a commercial plant of 3000MWth).

The original intention (1963–1975) was to study only one or two major (large break) LOCA, since these had been the main concern of US 'rule-making' hearings in the late 1960s and early 1970s. These rules had focussed around a rather stylised large-break accident, and a set of criteria (e.g. for extent of fuel-clad oxidation) set out in 'Appendix K' of 10CFR50 (Code of Federal Regulations). Following the accident at Three Mile Island, detailed modelling of much smaller LOCA became of equal concern.

38 LOFT tests were eventually performed and their scope was broadened to study a wide spectrum of breach sizes. These tests were used to help validate a series of computer codes (such as RELAP-4, RELAP-5 and TRAC) then being developed to calculate the thermal-hydraulics of LOCA.

See also edit

Contact of molten fuel with water and concrete edit

Water edit

Extensive work was done from 1970 to 1990 on the possibility of a steam explosion or FCI when molten 'corium' contacted water. Many experiments suggested quite low conversion of thermal to mechanical energy, whereas the theoretical models available appeared to suggest that much higher efficiencies were possible. A NEA/OECD report was written on the subject in 2000 which states that a steam explosion caused by contact of corium with water has four stages.[29]

  • Premixing
    • As the jet of corium enters the water, it breaks up into droplets. During this stage the thermal contact between the corium and the water is not good because a vapor film surrounds the droplets of corium and this insulates the two from each other. It is possible for this meta-stable state to quench without an explosion or it can trigger in the next step
  • Triggering
    • A externally or internally generated trigger (such as a pressure wave) causes a collapse of the vapor film between the corium and the water.
  • Propagation
    • The local increase in pressure due to the increased heating of the water can generate enhanced heat transfer (usually due to rapid fragmentation of the hot fluid within the colder more volatile one) and a greater pressure wave, this process can be self-sustained. (The mechanics of this stage would then be similar to those in a classical ZND detonation wave).
  • Expansion
    • This process leads to the whole of the water being suddenly heated to boiling. This causes an increase in pressure (in layman's terms, an explosion), which can result in damage to the plant.

Recent work edit

Work in Japan in 2003 melted uranium dioxide and zirconium dioxide in a crucible before being added to water. The fragmentation of the fuel which results is reported in the Journal of Nuclear Science and Technology.[30]

Concrete edit

A review of the subject can be read at [31] and work on the subject continues to this day; in Germany at the FZK some work has been done on the effect of thermite on concrete, this is a simulation of the effect of the molten core of a reactor breaking through the bottom of the pressure vessel into the containment building.[32][33][34]

Lava flows from corium edit

The corium (molten core) will cool and change to a solid with time. It is thought that the solid is weathering with time. The solid can be described as Fuel Containing Mass, it is a mixture of sand, zirconium and uranium dioxide which had been heated at a very high temperature[35] until it has melted. The chemical nature of this FCM has been the subject of some research.[36] The amount of fuel left in this form within the plant has been considered.[37] A silicone polymer has been used to fix the contamination.

The Chernobyl melt was a silicate melt which did contain inclusions of Zr/U phases, molten steel and high uranium zirconium silicate. The lava flow consists of more than one type of material—a brown lava and a porous ceramic material have been found. The uranium to zirconium for different parts of the solid differs a lot, in the brown lava a uranium rich phase with a U:Zr ratio of 19:3 to about 38:10 is found. The uranium poor phase in the brown lava has a U:Zr ratio of about 1:10.[24] It is possible from the examination of the Zr/U phases to know the thermal history of the mixture. It can be shown that before the explosion that in part of the core the temperature was higher than 2000 °C, while in some areas the temperature was over 2400–2600 °C.

 
The radioactivity levels of different isotopes in the FCM, this has been back calculated by Russian workers to April 1986, note that the levels of radioactivity have decayed a great deal by now

Spent fuel corrosion edit

Uranium dioxide films edit

Uranium dioxide films can be deposited by reactive sputtering using an argon and oxygen mixture at a low pressure. This has been used to make a layer of the uranium oxide on a gold surface which was then studied with AC impedance spectroscopy.[38]

Noble metal nanoparticles and hydrogen edit

According to the work of the corrosion electrochemist Shoesmith[39] the nanoparticles of Mo-Tc-Ru-Pd have a strong effect on the corrosion of uranium dioxide fuel. For instance his work suggests that when the hydrogen (H2) concentration is high (due to the anaerobic corrosion of the steel waste can) the oxidation of hydrogen at the nanoparticles will exert a protective effect on the uranium dioxide. This effect can be thought of as an example of protection by a sacrificial anode where instead of a metal anode reacting and dissolving it is the hydrogen gas which is consumed.

References edit

  1. ^ T. Nakamura; T. Fuketa; T. Sugiyama; H. Sasajima (2004). "Failure Thresholds of High Burnup BWR Fuel Rods under RIA Conditions". Journal of Nuclear Science and Technology. 41 (1): 37. doi:10.3327/jnst.41.37.
  2. ^ F. Nagase & T. Fuketa (2005). "Investigation of Hydride Rim Effect on Failure of Zircaloy-4 Cladding with Tube Burst Test". Journal of Nuclear Science and Technology. 42: 58–65. doi:10.3327/jnst.42.58.
  3. ^ Simplified analysis of nuclear fuel pin swelling. (PDF) . Retrieved on 2011-03-17.
  4. ^ J.Y. Colle; J.P. Hiernaut; D. Papaioannou; C. Ronchi; A. Sasahara (2006). "Fission product release in high-burn-up UO2 oxidized to U3O8". Journal of Nuclear Materials. 348 (3): 229. Bibcode:2006JNuM..348..229C. doi:10.1016/j.jnucmat.2005.09.024.
  5. ^ P. Wood and G.H. Bannister, CEGB report 2006-06-13 at the Wayback Machine
  6. ^ V. Bessiron (2007). "Modelling of Clad-to-Coolant Heat Transfer for RIA Applications". Journal of Nuclear Science and Technology. 44 (2): 211–221. doi:10.3327/jnst.44.211.
  7. ^ Gladkov, V.P.; Petrov, V.I.; Svetlov, A.V.; Smirnov, E.A.; Tenishev, V.I.; Bibilashvili, Yu. K.; Novikov, V.V (1993). "Iodine diffusion in the alpha phase of Zr-1% Nb alloy". Atomic Energy. 75 (2): 606–612. doi:10.1007/BF00738998. S2CID 93818169.
  8. ^ Energy Citations Database (ECD) – Document #4681711. Osti.gov (1971-07-01). Retrieved on 2011-03-17.
  9. ^ S.Y. Park; J.H. Kim; M.H. Lee; Y.H. Jeong (2007). "Stress-corrosion crack initiation and propagation behavior of Zircaloy-4 cladding under an iodine environment". Journal of Nuclear Materials. 372 (2–3): 293. Bibcode:2008JNuM..372..293P. doi:10.1016/j.jnucmat.2007.03.258.
  10. ^ K. Ishida; Y. Wada; M. Tachibana; M. Aizawa; M. Fuse; E. Kadoi (2006). "Hydrazine and Hydrogen Co-injection to Mitigate Stress Corrosion Cracking of Structural Materials in Boiling Water Reactors, (I) Temperature Dependence of Hydrazine Reactions". Journal of Nuclear Science and Technology. 43 (1): 65–76. doi:10.3327/jnst.43.65.
  11. ^ Y. Udagawa; F. Nagase & T. Fuketa (2006). "Effect of Cooling History on Cladding Ductility under LOCA Conditions". Journal of Nuclear Science and Technology. 43 (8): 844. doi:10.3327/jnst.43.844.
  12. ^ K. Fukuya; K. Fujii; H. Nishioka; Y. Kitsunai (2006). "Evolution of Microstructure and Microchemistry in Cold-worked 316 Stainless Steels under PWR Irradiation". Journal of Nuclear Science and Technology. 43 (2): 159–173. doi:10.3327/jnst.43.159.
  13. ^ Microsoft Word – fuelReport.doc. (PDF) . Retrieved on 2011-03-17.
  14. ^ Radiochemistry and Nuclear Chemistry, G. Choppin, J-O Liljenzin and J. Rydberg, 3rd Ed, 2002, Butterworth-Heinemann, ISBN 0-7506-7463-6
  15. ^ a b Table of Nuclides. Atom.kaeri.re.kr. Retrieved on 2011-03-17.
  16. ^ N. Nitani; K. Kuramoto; T. Yamashita; K. Ichise; K. Ono; Y. Nihei (2006). "Post-irradiation examination on particle dispersed rock-like oxide fuel". Journal of Nuclear Materials. 352 (1–3): 365–371. Bibcode:2006JNuM..352..365N. doi:10.1016/j.jnucmat.2006.03.002.
  17. ^ N. Nitani; K. Kuramoto; T. Yamashita; Y. Nihel; Y. Kimura (2003). "In-pile irradiation of rock-like oxide fuels". Journal of Nuclear Materials. 319: 102–107. Bibcode:2003JNuM..319..102N. doi:10.1016/S0022-3115(03)00140-5.
  18. ^ Generic assessment procedures for determining protective actions during a reactor accident, International Atomic Energy Agency technical document 955, published in Austria August 1997 ISSN 1011-4289, p. 60
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External links edit

LOFT tests
  • Idaho National Engineering Laboratory, 4 December 1979
  • , Idaho National Engineering Laboratory, June 1979
  • , Idaho National Engineering Laboratory, February 1980

April 11, 2024
behavior, nuclear, fuel, during, reactor, accident, this, page, describes, uranium, dioxide, nuclear, fuel, behaves, during, both, normal, nuclear, reactor, operation, under, reactor, accident, conditions, such, overheating, work, this, area, often, very, expe. This page describes how uranium dioxide nuclear fuel behaves during both normal nuclear reactor operation and under reactor accident conditions such as overheating Work in this area is often very expensive to conduct and so has often been performed on a collaborative basis between groups of countries usually under the aegis of the Organisation for Economic Co operation and Development s Committee on the Safety of Nuclear Installations CSNI This is a false colour tomography picture of a bundle FPT1 of 18 irradiated fuel rods 23 GWd tU mean burn up degraded under steam as part of the PHEBUS set of experiments The black and blue is for areas of low density while red is an area of high density It can be seen that the fuel has failed mechanically and has formed a pool near the bottom of the bundle The bottom of the bundle did not melt Contents 1 Swelling 1 1 Cladding 1 2 Fuel 2 Fission gas release 3 Heat transfer between the cladding and the water 4 Hydriding and waterside corrosion 4 1 Corrosion on the inside of the cladding 4 2 Graphite moderated reactors 4 3 Water cooled reactors 4 3 1 Corrosion 4 3 2 Thermal stresses upon quenching 4 4 Aging of steels 5 Cracking and overheating of the fuel 5 1 Loss of volatile fission products from pellets 5 1 1 Genesis of 137Cs 5 1 2 Genesis of 134Cs 5 2 An example of a recent PIE study 6 Release of fission products into coolant water in a Three Mile Island type accident 7 Chernobyl release 7 1 Table of chemical data 8 Degradation of the whole fuel element 8 1 PHEBUS 8 2 LOFT 8 3 See also 9 Contact of molten fuel with water and concrete 9 1 Water 9 1 1 Recent work 9 2 Concrete 10 Lava flows from corium 11 Spent fuel corrosion 11 1 Uranium dioxide films 11 2 Noble metal nanoparticles and hydrogen 12 References 13 External linksSwelling editCladding edit Both the fuel and cladding can swell Cladding covers the fuel to form a fuel pin and can be deformed It is normal to fill the gap between the fuel and the cladding with helium gas to permit better thermal contact between the fuel and the cladding During use the amount of gas inside the fuel pin can increase because of the formation of noble gases krypton and xenon by the fission process If a Loss of coolant accident LOCA e g Three Mile Island or a Reactivity Initiated Accident RIA e g Chernobyl or SL 1 occurs then the temperature of this gas can increase As the fuel pin is sealed the pressure of the gas will increase PV nRT and it is possible to deform and burst the cladding It has been noticed that both corrosion and irradiation can alter the properties of the zirconium alloy commonly used as cladding making it brittle As a result the experiments using unirradiated zirconium alloy tubes can be misleading According to one paper 1 the following difference between the cladding failure mode of unused and used fuel was seen Unirradiated fuel rods were pressurized before being placed in a special reactor at the Japanese Nuclear Safety Research Reactor NSRR where they were subjected to a simulated RIA transient These rods failed after ballooning late in the transient when the cladding temperature was high The failure of the cladding in these tests was ductile and it was a burst opening The used fuel 61 GW days tonne of uranium failed early in the transient with a brittle fracture which was a longitudinal crack It was found that hydrided zirconium tube is weaker and the bursting pressure is lower 2 The common failure process of fuel in the water cooled reactors is a transition to film boiling and subsequent ignition of zirconium cladding in the steam The effects of the intense hot hydrogen reaction product flow on the fuel pellets and on the bundle s wall well represented on the sidebar picture Fuel edit The nuclear fuel can swell during use this is because of effects such as fission gas formation in the fuel and the damage which occurs to the lattice of the solid The fission gases accumulate in the void that forms in the center of a fuel pellet as burnup increases As the void forms the once cylindrical pellet degrades into pieces The swelling of the fuel pellet can cause pellet cladding interaction when it thermally expands to the inside of the cladding tubing The swollen fuel pellet imposes mechanical stresses upon the cladding A document on the subject of the swelling of the fuel can be downloaded from the NASA web site 3 Fission gas release editAs the fuel is degraded or heated the more volatile fission products which are trapped within the uranium dioxide may become free For example see 4 A report on the release of 85Kr 106Ru and 137Cs from uranium when air is present has been written It was found that uranium dioxide was converted to U3O8 between about 300 and 500 C in air They report that this process requires some time to start after the induction time the sample gains mass The authors report that a layer of U3O7 was present on the uranium dioxide surface during this induction time They report that 3 to 8 of the krypton 85 was released and that much less of the ruthenium 0 5 and caesium 2 6 x 10 3 occurred during the oxidation of the uranium dioxide 5 Heat transfer between the cladding and the water editIn a water cooled power reactor or in a water filled spent fuel pool SFP if a power surge occurs as a result of a reactivity initiated accident an understanding of the transfer of heat from the surface of the cladding to the water is very useful In a French study metal pipe immersed in water both under typical PWR and SFP conditions was electrically heated to simulate the generation of heat within a fuel pin by nuclear processes The temperature of the pipe was monitored by thermocouples and for the tests conducted under PWR conditions the water entering the larger pipe 14 2 mm diameter holding the test metal pipe 9 5 mm outside diameter and 600 mm long was at 280 C and 15 MPa The water was flowing past the inner pipe at circa 4 ms 1 and the cladding was subjected to heating at 2200 to 4900 C s 1 to simulate an RIA It was found that as the temperature of the cladding increased the rate of heat transfer from the surface of the cladding increased at first as the water boiled at nucleation sites When the heat flux is greater than the critical heat flux a boiling crisis occurs This occurs as the temperature of the fuel cladding surface increases so that the surface of the metal was too hot surface dries out for nucleation boiling When the surface dries out the rate of heat transfer decreases after a further increase in the temperature of the metal surface the boiling resumes but it is now film boiling 6 Hydriding and waterside corrosion editAs a nuclear fuel bundle increases in burnup time in reactor the radiation begins changing not only the fuel pellets inside the cladding but the cladding material itself The zirconium chemically reacts to the water flowing around it as coolant forming a protective oxide on the surface of the cladding Typically a fifth of the cladding wall will be consumed by oxide in PWRs There is a smaller corrosion layer thickness in BWRs The chemical reaction that takes place is Zr 2 H2O ZrO2 2 H2 g Hydriding occurs when the product gas hydrogen precipitates out as hydrides within the zirconium This causes the cladding to become embrittled instead of ductile The hydride bands form in rings within the cladding As the cladding experiences hoop stress from the growing amount of fission products the hoop stress increases The material limitations of the cladding is one aspect that limits the amount of burnup nuclear fuel can accumulate in a reactor CRUD Chalk River Unidentified Deposits was discovered by Chalk River Laboratories It occurs on the exterior of the clad as burnup is accumulated When a nuclear fuel assembly is prepared for onsite storage it is dried and moved to a spent nuclear fuel shipping cask with scores of other assemblies Then it sits on a concrete pad for a number of years waiting for an intermediate storage facility or reprocessing The transportation of radiation damaged cladding is tricky because it is so fragile After being removed from the reactor and cooling down in the spent fuel pool the hydrides within the cladding of an assembly reorient themselves so that they radially point out from the fuel rather than circularly in the direction of the hoop stress This puts the fuel in a situation so that when it is moved to its final resting place if the cask were to fall the cladding would be so weak it could break and release the spent fuel pellets inside the cask Corrosion on the inside of the cladding edit Zirconium alloys can undergo stress corrosion cracking when exposed to iodine 7 the iodine is formed as a fission product which depending on the nature of the fuel can escape from the pellet 8 It has been shown that iodine causes the rate of cracking in pressurised zircaloy 4 tubing to increase 9 Graphite moderated reactors edit In the cases of carbon dioxide cooled graphite moderated reactors such as magnox and AGR power reactors an important corrosion reaction is the reaction of a molecule of carbon dioxide with graphite carbon to form two molecules of carbon monoxide This is one of the processes which limits the working life of this type of reactor Water cooled reactors edit Corrosion edit In a water cooled reactor the action of radiation on the water radiolysis forms hydrogen peroxide and oxygen These can cause stress corrosion cracking of metal parts which include fuel cladding and other pipework To mitigate this hydrazine and hydrogen are injected into a BWR or PWR primary cooling circuit as corrosion inhibitors to adjust the redox properties of the system A review of recent developments on this topic has been published 10 Thermal stresses upon quenching edit In a loss of coolant accident LOCA it is thought that the surface of the cladding could reach a temperature between 800 and 1400 K and the cladding will be exposed to steam for some time before water is reintroduced into the reactor to cool the fuel During this time when the hot cladding is exposed to steam some oxidation of the zirconium will occur to form a zirconium oxide which is more zirconium rich than zirconia This Zr O phase is the a phase further oxidation forms zirconia The longer the cladding is exposed to steam the less ductile it will be One measure of the ductility is to compress a ring along a diameter at a constant rate of displacement in this case 2 mm min 1 until the first crack occurs then the ring will start to fail The elongation which occurs between when the maximum force is applied and when the mechanical load is declined to 80 of the load required to induce the first crack is the L0 8 value in mm The more ductile a sample is the greater this L0 8 value will be In one experiment the zirconium is heated in steam to 1473 K the sample is slowly cooled in steam to 1173 K before being quenched in water As the heating time at 1473 K is increased the zirconium becomes more brittle and the L0 8 value declines 11 Aging of steels edit Irradiation causes the properties of steels to become poorer for instance SS316 becomes less ductile and less tough Also creep and stress corrosion cracking become worse Papers on this effect continue to be published 12 Cracking and overheating of the fuel editThis is due to the fact that as the fuel expands on heating the core of the pellet expands more than the rim Because of the thermal stress thus formed the fuel cracks the cracks tend to go from the center to the edge in a star shaped pattern A PhD thesis on the subject has been published 13 by a student at the Royal Institute of Technology in Stockholm Sweden The cracking of the fuel has an effect on the release of radioactivity from fuel both under accident conditions and also when the spent fuel is used as the final disposal form The cracking increases the surface area of the fuel which increases the rate at which fission products can leave the fuel The temperature of the fuel varies as a function of the distance from the center to the rim At distance x from the center the temperature Tx is described by the equation where r is the power density W m 3 and Kf is the thermal conductivity Tx TRim r rpellet x 4 Kf 1To explain this for a series of fuel pellets being used with a rim temperature of 200 C typical for a BWR with different diameters and power densities of 250 Wm 3 have been modeled using the above equation These fuel pellets are rather large it is normal to use oxide pellets which are about 10 mm in diameter nbsp Temperature profile for a 20 mm diameter fuel pellet with a power density of 250 W per cubic meter The central temperature is very different for the different fuel solids nbsp Temperature profile for a 26 mm diameter fuel pellet with a power density of 250 W per cubic meter nbsp Temperature profile for a 32 mm diameter fuel pellet with a power density of 250 W per cubic meter To show the effects of different power densities on the centerline temperatures two graphs for 20 mm pellets at different power levels are shown below It is clear that for all pellets and most true of uranium dioxide that for a given sized pellet that a limit must be set on the power density It is likely that the maths used for these calculations would be used to explain how electrical fuses function and also it could be used to predict the centerline temperature in any system where heat is released throughout a cylinder shaped object 14 nbsp Temperature profile for a 20 mm diameter fuel pellet with a power density of 500 W per cubic meter Because the melting point of uranium dioxide is about 3300 K it is clear that uranium oxide fuel is overheating at the center nbsp Temperature profile for a 20 mm diameter fuel pellet with a power density of 1000 W per cubic meter The fuels other than uranium dioxide are not compromised Loss of volatile fission products from pellets edit The heating of pellets can result in some of the fission products being lost from the core of the pellet If the xenon can rapidly leave the pellet then the amount of 134Cs and 137Cs which is present in the gap between the cladding and the fuel will increase As a result if the zircaloy tubes holding the pellet are broken then a greater release of radioactive caesium from the fuel will occur It is important to understand that the 134Cs and 137Cs are formed in different ways and hence as a result the two caesium isotopes can be found at different parts of a fuel pin It is clear that the volatile iodine and xenon isotopes have minutes in which they can diffuse out of the pellet and into the gap between the fuel and the cladding Here the xenon can decay to the long lived caesium isotope Genesis of 137Cs edit Formation of 137Cs from its precursors Element Isotope decay mode half life direct fission yieldSn 137 b very short lt 1 s 0 00 Sb 137 b very short lt 1 s 0 03 Te 137 b 2 5 seconds 0 19 I 137 b 24 5 seconds 1 40 Xe 137 b 3 8 minutes 1 44 Cs 137 b 30 years 0 08 These fission yields were calculated for 235U assuming thermal neutrons 0 0253 eV using data from the chart of the nuclides 15 Genesis of 134Cs edit In the case of 134Cs the precursor to this isotope is stable 133Cs which is formed by the decay of much longer lived xenon and iodine isotopes No 134Cs is formed without neutron activation as 134Xe is a stable isotope As a result of this different mode of formation the physical location of 134Cs can differ from that of 137Cs Formation of 134Cs and its decay products daughters Element Isotope decay mode half life direct fission yieldIn 133 b 0 18 seconds 0 00 Sn 133 b 1 45 seconds 0 07 Sb 133 b 2 5 minutes 1 11 Te 133m b 82 5 55 4 minutes 0 49 Te 133 b 12 5 minutes 0 15 I 133 b 20 8 hours 1 22 Xe 133 b 5 2 days 0 00 Cs 133 stable undergoes neutron activation in the core 0 00 Cs 134 b 2 1 years 6 4 x 10 6 These fission yields were calculated for 235U assuming thermal neutrons 0 0253 eV using data from the chart of the nuclides 15 An example of a recent PIE study edit In a recent study used 20 enriched uranium dispersed in a range of different matrices was examined to determine the physical locations of different isotopes and chemical elements A solid solution of urania in yttria stabilized zirconia YSZ Y Zr atom ratio of 1 4 Urania particles in an inert matrix formed by a mixture of YSZ and spinel MgAl2O4 Urania particles dispersed in the inert matrix formed by a mixture of YSZ and alumina The fuels varied in their ability to retain the fission xenon the first of the three fuels retained 97 of the 133Xe the second retained 94 while the last fuel only retained 76 of this xenon isotope The 133Xe is a long lived radioactive isotope which can diffuse slowly out of the pellet before being neutron activated to form 134Cs The more short lived 137Xe was less able to leach out of the pellets 99 98 and 95 of the 137Xe was retained within the pellets It was also found that the 137Cs concentration in the core of the pellet was much lower than the concentration in the rim of the pellet while the less volatile 106Ru was spread more evenly throughout the pellets 16 The following fuel is particles of solid solution of urania in yttria stabilized zirconia dispersed in alumina which had burnt up to 105 GW days per cubic meter 17 The scanning electron microscope SEM is of the interface between the alumina and a fuel particle It can be seen that the fission products are well confined to within the fuel little of the fission products have entered the alumina matrix The neodymium is spread throughout the fuel in a uniform manner while the caesium is almost homogenously spread out throughout the fuel The caesium concentration is slightly higher at two points where xenon bubbles are present Much of the xenon is present in bubbles while almost all of the ruthenium is present in the form of nanoparticles The ruthenium nanoparticles are not always colocated with the xenon bubbles Release of fission products into coolant water in a Three Mile Island type accident editAt Three Mile Island a recently SCRAMed core was starved of cooling water as a result of the decay heat the core dried out and the fuel was damaged Attempts were made to recool the core using water According to the International Atomic Energy Agency for a 3 000 MW t PWR the normal coolant radioactivity levels are shown below in the table and the coolant activities for reactors which have been allowed to dry out and over heat before being recovered with water In a gap release the activity in the fuel cladding gap has been released while in the core melt release the core was melted before being recovered by water 18 The levels of radioactivity in the coolant of a typical PWR under different conditions MBq L 1 Isotope Normal gt 20 Gap release gt 10 Core melt131I 2 200000 700000134Cs 0 3 10000 60000137Cs 0 3 6000 30000140Ba 0 5 100000Chernobyl release editThe release of radioactivity from the used fuel is greatly controlled by the volatility of the elements At Chernobyl much of the xenon and iodine was released while much less of the zirconium was released The fact that only the more volatile fission products are released with ease will greatly retard the release of radioactivity in the event of an accident which causes serious damage to the core Using two sources of data it is possible to see that the elements which were in the form of gases volatile compounds or semi volatile compounds such as CsI were released at Chernobyl while the less volatile elements which form solid solutions with the fuel remained inside the reactor fuel According to the OECD NEA report on Chernobyl ten years on 19 the following proportions of the core inventory were released The physical and chemical forms of the release included gases aerosols and finely fragmented solid fuel According to some research the ruthenium is very mobile when the nuclear fuel is heated with air 20 This mobility has been more evident in reprocessing with related releases of ruthenium the most recent being the airborne radioactivity increase in Europe in autumn 2017 as with the ionizing radiation environment of spent fuel and the presence of oxygen radiolysis reactions can generate the volatile compound ruthenium VIII oxide which has a boiling point of approximately 40 C 104 F and is a strong oxidizer reacting with virtually any fuel hydrocarbon that are used in PUREX Some work on TRISO fuel heated in air with the respective encapsulation of nuclides has been published 21 Table of chemical data edit Chemical forms of fission products in uranium dioxide 22 the percentage release at Chernobyl and the temperatures according to Colle et al required to release 10 of an element from either unoxidized or oxidized fuel When data from one element is assumed to apply to another element the energy is in Italics Element Gas Metal Oxide Solid solution Radioisotopes Release at Chernobyl 19 T required for 10 release from UO2 T required for 10 release from U3O8Br Yes Kr Yes 85Kr 100 Rb Yes Yes Sr Yes Yes 89Sr and 90Sr 4 6 1950 K Y Yes 3 5 Zr Yes Yes 93Zr and 95Zr 3 5 2600 K Nb Yes Mo Yes Yes 99Mo gt 3 5 1200 KTc Yes 99Tc 1300 KRu Yes 103Ru and 106Ru gt 3 5 Rh Yes Pd Yes Ag Yes Cd Yes In Yes Sn Yes Sb Yes Te Yes Yes Yes Yes 132Te 25 60 1400 K 1200 KI Yes 131I 50 60 1300 K 1100 KXe Yes 133Xe 100 1450 K Cs Yes Yes 134Cs and 137Cs 20 40 1300 K 1200 to 1300 KBa Yes Yes 140Ba 4 6 1850 K 1300 KLa Yes 3 5 2300 K Ce Yes 141Ce and 144Ce 3 5 2300 K Pr Yes 3 5 2300 K Nd Yes 3 5 2300 K Pm Yes 3 5 2300 K Sm Yes 3 5 2300 K Eu Yes 3 5 2300 K The releases of fission products and uranium from uranium dioxide from spent BWR fuel burnup was 65 GWd t 1 which was heated in a Knudsen cell has been repeated 23 Fuel was heated in the Knudsen cell both with and without preoxidation in oxygen at c 650 K It was found even for the noble gases that a high temperature was required to liberate them from the uranium oxide solid For unoxidized fuel 2300 K was required to release 10 of the uranium while oxidized fuel only requires 1700 K to release 10 of the uranium According to the report on Chernobyl used in the above table 3 5 of the following isotopes in the core were released 239Np 238Pu 239Pu 240Pu 241Pu and 242Cm Degradation of the whole fuel element editWater and zirconium can react violently at 1200 C at the same temperature the zircaloy cladding can react with uranium dioxide to form zirconium oxide and a uranium zirconium alloy melt 24 PHEBUS edit In France a facility exists in which a fuel melting incident can be made to happen under strictly controlled conditions 25 26 In the PHEBUS research program fuels have been allowed to heat up to temperatures in excess of the normal operating temperatures the fuel in question is in a special channel which is in a toroidal nuclear reactor The nuclear reactor is used as a driver core to irradiate the test fuel While the reactor is cooled as normal by its own cooling system the test fuel has its own cooling system which is fitted with filters and equipment to study the release of radioactivity from the damaged fuel Already the release of radioisotopes from fuel under different conditions has been studied After the fuel has been used in the experiment it is subject to a detailed examination PIE In the 2004 annual report from the ITU some results of the PIE on PHEBUS FPT2 fuel are reported in section 3 6 27 28 LOFT edit The Loss of Fluid Tests LOFT were an early attempt to scope the response of real nuclear fuel to conditions under a loss of coolant accident funded by USNRC The facility was built at Idaho National Laboratory and was essentially a scale model of a commercial PWR Power volume scaling was used between the LOFT model with a 50MWth core and a commercial plant of 3000MWth The original intention 1963 1975 was to study only one or two major large break LOCA since these had been the main concern of US rule making hearings in the late 1960s and early 1970s These rules had focussed around a rather stylised large break accident and a set of criteria e g for extent of fuel clad oxidation set out in Appendix K of 10CFR50 Code of Federal Regulations Following the accident at Three Mile Island detailed modelling of much smaller LOCA became of equal concern 38 LOFT tests were eventually performed and their scope was broadened to study a wide spectrum of breach sizes These tests were used to help validate a series of computer codes such as RELAP 4 RELAP 5 and TRAC then being developed to calculate the thermal hydraulics of LOCA See also edit NUREG 1150 Nuclear powerContact of molten fuel with water and concrete editWater edit Extensive work was done from 1970 to 1990 on the possibility of a steam explosion or FCI when molten corium contacted water Many experiments suggested quite low conversion of thermal to mechanical energy whereas the theoretical models available appeared to suggest that much higher efficiencies were possible A NEA OECD report was written on the subject in 2000 which states that a steam explosion caused by contact of corium with water has four stages 29 Premixing As the jet of corium enters the water it breaks up into droplets During this stage the thermal contact between the corium and the water is not good because a vapor film surrounds the droplets of corium and this insulates the two from each other It is possible for this meta stable state to quench without an explosion or it can trigger in the next step Triggering A externally or internally generated trigger such as a pressure wave causes a collapse of the vapor film between the corium and the water Propagation The local increase in pressure due to the increased heating of the water can generate enhanced heat transfer usually due to rapid fragmentation of the hot fluid within the colder more volatile one and a greater pressure wave this process can be self sustained The mechanics of this stage would then be similar to those in a classical ZND detonation wave Expansion This process leads to the whole of the water being suddenly heated to boiling This causes an increase in pressure in layman s terms an explosion which can result in damage to the plant Recent work edit Work in Japan in 2003 melted uranium dioxide and zirconium dioxide in a crucible before being added to water The fragmentation of the fuel which results is reported in the Journal of Nuclear Science and Technology 30 Concrete edit A review of the subject can be read at 31 and work on the subject continues to this day in Germany at the FZK some work has been done on the effect of thermite on concrete this is a simulation of the effect of the molten core of a reactor breaking through the bottom of the pressure vessel into the containment building 32 33 34 Lava flows from corium editThe corium molten core will cool and change to a solid with time It is thought that the solid is weathering with time The solid can be described as Fuel Containing Mass it is a mixture of sand zirconium and uranium dioxide which had been heated at a very high temperature 35 until it has melted The chemical nature of this FCM has been the subject of some research 36 The amount of fuel left in this form within the plant has been considered 37 A silicone polymer has been used to fix the contamination The Chernobyl melt was a silicate melt which did contain inclusions of Zr U phases molten steel and high uranium zirconium silicate The lava flow consists of more than one type of material a brown lava and a porous ceramic material have been found The uranium to zirconium for different parts of the solid differs a lot in the brown lava a uranium rich phase with a U Zr ratio of 19 3 to about 38 10 is found The uranium poor phase in the brown lava has a U Zr ratio of about 1 10 24 It is possible from the examination of the Zr U phases to know the thermal history of the mixture It can be shown that before the explosion that in part of the core the temperature was higher than 2000 C while in some areas the temperature was over 2400 2600 C nbsp The radioactivity levels of different isotopes in the FCM this has been back calculated by Russian workers to April 1986 note that the levels of radioactivity have decayed a great deal by nowSpent fuel corrosion editUranium dioxide films edit Uranium dioxide films can be deposited by reactive sputtering using an argon and oxygen mixture at a low pressure This has been used to make a layer of the uranium oxide on a gold surface which was then studied with AC impedance spectroscopy 38 Noble metal nanoparticles and hydrogen edit According to the work of the corrosion electrochemist Shoesmith 39 the nanoparticles of Mo Tc Ru Pd have a strong effect on the corrosion of uranium dioxide fuel For instance his work suggests that when the hydrogen H2 concentration is high due to the anaerobic corrosion of the steel waste can the oxidation of hydrogen at the nanoparticles will exert a protective effect on the uranium dioxide This effect can be thought of as an example of protection by a sacrificial anode where instead of a metal anode reacting and dissolving it is the hydrogen gas which is consumed References edit T Nakamura T Fuketa T Sugiyama H Sasajima 2004 Failure Thresholds of High Burnup BWR Fuel Rods under RIA Conditions Journal of Nuclear Science and Technology 41 1 37 doi 10 3327 jnst 41 37 F Nagase amp T Fuketa 2005 Investigation of Hydride Rim Effect on Failure of Zircaloy 4 Cladding with Tube Burst Test Journal of Nuclear Science and Technology 42 58 65 doi 10 3327 jnst 42 58 Simplified analysis of nuclear fuel pin swelling PDF Retrieved on 2011 03 17 J Y Colle J P Hiernaut D Papaioannou C Ronchi A Sasahara 2006 Fission product release in high burn up UO2 oxidized to U3O8 Journal of Nuclear Materials 348 3 229 Bibcode 2006JNuM 348 229C doi 10 1016 j jnucmat 2005 09 024 P Wood and G H Bannister CEGB report Archived 2006 06 13 at the Wayback Machine V Bessiron 2007 Modelling of Clad to Coolant Heat Transfer for RIA Applications Journal of Nuclear Science and Technology 44 2 211 221 doi 10 3327 jnst 44 211 Gladkov V P Petrov V I Svetlov A V Smirnov E A Tenishev V I Bibilashvili Yu K Novikov V V 1993 Iodine diffusion in the alpha phase of Zr 1 Nb alloy Atomic Energy 75 2 606 612 doi 10 1007 BF00738998 S2CID 93818169 Energy Citations Database ECD Document 4681711 Osti gov 1971 07 01 Retrieved on 2011 03 17 S Y Park J H Kim M H Lee Y H Jeong 2007 Stress corrosion crack initiation and propagation behavior of Zircaloy 4 cladding under an iodine environment Journal of Nuclear Materials 372 2 3 293 Bibcode 2008JNuM 372 293P doi 10 1016 j jnucmat 2007 03 258 K Ishida Y Wada M Tachibana M Aizawa M Fuse E Kadoi 2006 Hydrazine and Hydrogen Co injection to Mitigate Stress Corrosion Cracking of Structural Materials in Boiling Water Reactors I Temperature Dependence of Hydrazine Reactions Journal of Nuclear Science and Technology 43 1 65 76 doi 10 3327 jnst 43 65 Y Udagawa F Nagase amp T Fuketa 2006 Effect of Cooling 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Behavior of nuclear fuel during a reactor accident amp oldid 1190788893, wikipedia, wiki, book, books, library,

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