- #10,886
rmattila
- 244
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robinson said:
Remember that the ability to use the power from unit 6:s EDG was what saved unit 5 at Fukushima.
robinson said:Safety would mean isolating each reactor, so that if a catastrophic failure occurs, you don't risk losing all the reactors.
There was concern about profit in the Soviet Union. The disease was not called "shareholder value" but it was the race between capitalism and socialism.Astronuc said:Please provide the evidence to support this claim. I don't believe that there was concern about profit in the Soviet Union.
Aus heutiger Sicht waren die Hauptursachen des Unfalls
- gravierende Mängel der reaktorphysikalischen Auslegung und der Auslegung der
Abschalteinrichtungen,
- ein politisches und organisatorisches System, welches nicht in der Lage war, diese
Mängel abzustellen, obwohl sie lange vor dem Unfall bekannt waren,
- ein sicherheitstechnisch unzureichend durchdachtes und geprüftes Versuchsprogramm,
- eine Betriebsführung und Bedienungseinrichtungen, die das Personal bei der
Wahrnehmung seiner Verantwortung für die Sicherheit überforderten.
Bestimmt und verschärft wurde der Unfallablauf durch:
- Ungünstige Wahl des Zeitpunktes - hoher Abbrand mit sehr großem positiven Voideffekt
von mindestens 5 b - für die Durchführung des Versuchs
- Nichtbeachtung der Erfordernisse der Reaktorsicherheit bei Aufstellung des Versuchsprogramms
- geringe Erfahrungen und unzureichende Beteiligung des Betriebspersonals an den
Vorbereitungen des Versuchs sowie Verstöße des Betriebspersonals gegen Betriebsvorschriften
Conditions prior to the accident
Schematic diagram of reactor
The conditions to run the test were established before the day shift of 25 April 1986. The day shift workers had been instructed in advance and were familiar with the established procedures. A special team of electrical engineers was present to test the new voltage regulating system.[20] As planned, a gradual reduction in the output of the power unit was begun at 01:06 on 25 April, and the power level had reached 50% of its nominal 3200 MW thermal level by the beginning of the day shift. At this point, another regional power station unexpectedly went off line, and the Kiev electrical grid controller requested that the further reduction of Chernobyl's output be postponed, as power was needed to satisfy the peak evening demand. The Chernobyl plant director agreed and postponed the test.
At 23:04, the Kiev grid controller allowed the reactor shut-down to resume. This delay had some serious consequences: the day shift had long since departed, the evening shift was also preparing to leave, and the night shift would not take over until midnight, well into the job. According to plan, the test should have been finished during the day shift, and the night shift would only have had to maintain decay heat cooling systems in an otherwise shut down plant. The night shift had very limited time to prepare for and carry out the experiment. A further rapid reduction in the power level from 50% was executed during the shift change-over. Alexander Akimov was chief of the night shift, and Leonid Toptunov was the operator responsible for the reactor's operational regimen, including the movement of the control rods. Toptunov was a young engineer who had worked independently as a senior engineer for approximately three months.[14]:36–8
rmattila said:Remember that the ability to use the power from unit 6:s EDG was what saved unit 5 at Fukushima.
Impact of one reactor/unit on other units is a consideration in NPP design.robinson said:Safety would mean isolating each reactor, so that if a catastrophic failure occurs, you don't risk losing all the reactors.
robinson said:... Without capable trained people, a support system, water, electricity and constant attention, any reactor/fuel pond is just a disaster waiting to happen.
rmattila said:Remember that the ability to use the power from unit 6:s EDG was what saved unit 5 at Fukushima.
Still, one has to avoid common mode failure. Fukushima Daiichi - Units 1-4 were all affected by the same event - the tsunami. They all lost offsite power, a common element, and they all got their turbine buildings, EDGs and switch gear flooded. Having redundancy (which is common) is no good if the redundant systems have a common vulnerability. Redundant system must also have independence, usually through different locations and trains/routes.joewein said:Good point and one that also occurred to me when I read the comment you replied to.
If twinned reactors share 3 or 4 EDGs or redundant grid connections as in the case of the F-1 units, if you were to instead build those reactors at isolated locations, would they still be built with the same number of redundant units? Of course one would hope so from a safety point of view, but the economic realities are such that there would be more pressure to cut corners and not double costs.
You would have to give each unit the full number of diesels, transformers and power lines that each pair now has, instead of being able to share via a local bus for redundancy.
jim hardy said:htf are you fluent in the language of those gts.de links?
joewein said:Good point and one that also occurred to me when I read the comment you replied to.
If twinned reactors share 3 or 4 EDGs or redundant grid connections as in the case of the F-1 units, if you were to instead build those reactors at isolated locations, would they still be built with the same number of redundant units? Of course one would hope so from a safety point of view, but the economic realities are such that there would be more pressure to cut corners and not double costs.
You would have to give each unit the full number of diesels, transformers and power lines that each pair now has, instead of being able to share via a local bus for redundancy.
rmattila said:I've never really thought through the redundancy requirements concerning twin units. The way things are here in Finland is that a general N+2 requirement is applied for all first-line safety systems (maintenance/repair + random single failure), so each unit must have two own diesel generators in addition to the minimum number required for fulfilling the safety function. Building twin units does not relax this safety requirement, but the practise has been to enable cross-connections between the diesel busbars to provide additional defence-in-depth in case of a common-mode failure of more than the assumed number of diesels (=2 per unit).
rmattila said:That is what made the accident disastrous for the plant - what made it an environmental disaster was the lack of defence-in-depth preparations for a severe accident. This is largely due to the old containment design, which is apparently very difficult to backfit to contain the radioactivity in case of a severe accident.
joewein said:I remembered incorrectly when I talked about 3 or 4 shared EDGs per pair at F-1. Each of the units had two EDGs, except for unit 6 (a BWR5) which had three. So it was really 4 or 5 shared EDGs per pair if one counts the bus for power exchange.
There was some diversity in EDGs, as each pair had at least one-air cooled EDG (in units 2, 4 and 6), but the one in unit 6 was the lone survivor.
joewein said:Even if they could not do much about the Mark 1 containments of unit 1-5 (and did not want to retire the units), and they knew the small containments would have trouble dealing with the large amount of hydrogen produced in a zirconium reaction on a prolonged station blackout, presumably they could have built some kind of "overflow containment" away from the unit for venting into instead of directly into the stack? At the very least they could have inserted some kind of wet scrubber before the stack, to remove as much Cs and I as possible without generating too much back-pressure. They weren't exactly short of space on-site, if you consider they're now setting up tanks for several 10,000 m3 of water and two separate water decontamination systems within walking distance of the wrecked units.
I think so - but don't ask my German teachers.jim hardy said:htf are you fluent in the language of those gts.de links?
There's something I've wondered about for over twenty five years - Perhaps you'd know.
""A special team of electrical engineers was present to test the new voltage regulating system.[20] ""
rmattila said:The Swedes built a facility called FILTRA at their Barsebäck two-unit BWR site in the early 1980's. Here's a really thorough and well-written progress report of the project that resulted into a 10 000 m3 gravel bed being built next to the the units. That might be one approach to improve the capacity of old containments; however, it won't remove the problems related to preventing core-concrete interactions if a molten core falls to the bottom of the containment.
westfield said:This document appears to indicate the operators aligned the venting from both drywell AND S\C. No scrubbing from the drywell venting.
The document also indicates very high dose rates in the buildings and onsite well before the venting even took place. To my laybrain that seems odd - was there containment failure before they even got to vent?
source : http://www.tepco.co.jp/en/press/corp-com/release/betu11_e/images/110618e15.pdf"
On the SGTS\HVS contamination - why the high dose rates in the Unit 1 Turbine building early on? And why does SGTS even go into the turbine building? Why does the SGTS appear to be HEAVILY contaminated, it shouldn't have even been possible for it to be working after loss of power. So SGTS just opens itself up on loss of power? WTF. The more I read about the design of these systems the less I want to know, kind of.
Most Curious said:The 1st few feet of the control rods were graphite rather than absorber material so a SCRAM or even orderly insertion of control rods INCREASED power until the absorber portion of the rod was in the core.
I_P said:TEPCO has considerable stake in claiming that the meltdowns were entirely the result of an unforeseeable, rare event (huge tsunami) rather than being initiated by earthquake damage from shaking that was within or just barely exceeded the plant design basis.
Most Curious said:Sadly, the Chernobyl engineer in charge ordered the ECCS locked out - literally padlocked - to preserve test integrity!
The up and down changes in reactor power were against written safety requirement and resulted in nearly ALL of the control rods out of the core to attempt power increase. They got their power increase allright, but it was WAY too much and WAY too fast.
The RBMK has a positive void and positive temperature coefficient making control at low power levels VERY difficult and unstable.
The 1st few feet of the control rods were graphite rather than absorber material so a SCRAM or even orderly insertion of control rods INCREASED power until the absorber portion of the rod was in the core.
All of the above and a few more items made the RBMK a ticking time bomb, just waiting for a few operator errors to cause a disaster.
At 7:36 pm on August 13, we adjusted the rate of water injection through
reactor feed water system piping arrangement to approximately 3.8m3/h as
we confirmed decrease in the amount of water injection to the reactor.
http://www.tepco.co.jp/en/press/corp-com/release/11081401-e.html
tsutsuji said:http://mainichi.jp/select/jiken/news/20110607ddm003040107000c.html :
It was discovered that the 13 km long Yunotake fault which runs in Iwaki city 40 km south of Fukushima Daini was activated by aftershocks of the 11 March earthquake. The problem is that this fault had been overlooked in past earthquake safety designs. NISA instructs all NPP operators to review their earthquake safety assessments to ensure similar faults elsewhere are not being overlooked.
tsutsuji said:http://www.tepco.co.jp/en/nu/fukushima-np/images/handouts_110814_02-e.pdf A magnitude 6 earthquake occurred at 3:22 AM on 12 August off the Fukushima prefecture shore. This press release explains the consequences on the Fukushima Daiichi plant: boiler stops at the desalination facility, injection rate into unit 1 reactor declined to 3.2 m³/hour, and one air-control compressor breaks down at unit 1 at 5:06 AM. The small leak at SFP4 cooling system was found at 5:27 AM.
http://www.chunichi.co.jp/s/article/2011081290085007.html It has been found that just below Tsuruga nuclear power plant's reactors, faults called "crush zones" could move under the influence of the Urasoko active fault. Crush zones were previously thought as having "no activity", and they were not taken into account in the nuclear plant's earthquake safety design, but it was discovered that in the Great Eastern Japan Earthquake, this kind of fault had moved. Thinking the consequences for the plant again, Japco will disclose its opinion on the matter by the end of August. Hiroshi Une said: "the commonly held opinion that normal faults don't move has collapsed". Fast breeding reactor Monju is close to the Shiraki-Nyu active fault, and crush zones of the normal fault type were confirmed below the reactor. Tectonic geomorphology professor Mitsuhisa Watanabe of Toyo University says : "however robust a reactor is made, if the ground tilts, it will get broken. Keeping normal faults out of one's thought was a mistake and that must be revised".
zapperzero said:Speaking of news. TEPCO says tritium was detected in intake water canal and sub-drain of unit 2, on June 13.
http://www.tepco.co.jp/en/press/corp-com/release/betu11_e/images/110624e10.pdf
http://www.tepco.co.jp/en/press/corp-com/release/betu11_e/images/110624e7.pdf
H/T the tireless ex-skf
rmattila said:My recollection from the documentation published by TEPCO is that there would have been enough water on the secondary side to boil off the decay heat for 90 minutes, which does sound rather a short time window. Still, a lot can be accomplished in that time, if there are practised EOPs in place. It would be really interesting to hear the details why they failed to restart the IC after the tsunami, as the IC is something many of the the new BWR designs rely heavily upon in cases of emergency.
"It is possible that a worker may have manually closed the valve (of the isolation condenser) to prevent a rapid decrease in temperature, as is stipulated by a reactor operating guideline," Tepco spokesman Hajime Motojuku told The Japan Times.
A worker may have stopped the condenser to keep cold water from coming into contact with the hot steel of the reactor to prevent it from being damaged.
However, nuclear reactors are designed to withstand this procedure in case of an emergency, said Hiromi Ogawa, a former nuclear plant engineer at Toshiba Corp.
According to Tepco, the isolation condenser's valve was confirmed open at 6:10 p.m. March 11 but it is unknown whether it was open between 3 p.m. and 6:10 p.m.
The valve was confirmed closed at 6:25 p.m. and confirmed open again at 9:30 p.m. Finally, the condenser was shut down due to a pump malfunction at 1:48 a.m. March 12, roughly eight hours after the tsunami, matching the battery life of the isolation condenser.
(http://search.japantimes.co.jp/cgi-bin/nn20110517x1.html" )
MadderDoc said:I reckon you'll be interested in http://www.tepco.co.jp/en/press/corp-com/release/betu11_e/images/110618e15.pdf", on the logs and testimony of operator response during the first days after the earthquake.
From the available evidence and testimony, the operators do in fact appear to have opted for the use of just one of the IC systems (the 'A' system) for the control of reactor pressure, judging it to be sufficient to keep the vessel at 6-7MPa, while they initially relied on the HPCI system for the control of the reactor water level.
joewein said:It appears the initial shutdown of the IC was prompted by the rapid fall in temperature after the IC was activated. There was a spec for the maximum drop in temperature per hour. It sounds there was concern about stressing the steel of the RPV:rmattila said:It would be really interesting to hear the details why they failed to restart the IC after the tsunami,
rmattila said:I would imagine re-activating the IC would be among the first tasks instructed by the EOP at station blackout. However, the details of what actually happened at that time are somewhat unclear to me: did they attempt to restart the IC and if they did, why did it not prevent the core uncovery?
joewein said:If there was enough water in the IC to last for only 90 minutes (can you still find the source for that),
Following a reactor isolation and scram, the energy added to the coolant will cause reactor pressure to increase and may initiate the isolation condenser. The capacity of this system is equivalent to the decay heat rate generation 5 minutes following the scram and isolation. With no makeup water, the volume of water stored in the isolation condenser will be depleted in 1 hour and 30 minutes. This allows sufficient time to initiate makeup water flow to the shell side of the condenser.
Nuclear reactors suspended for regular checkups need to undergo "stress tests" before resuming operations, but the central government has said that the case of the Tomari reactor is not a restart because the reactor is already activated
http://mdn.mainichi.jp/mdnnews/news/20110813p2g00m0dm010000c.html