Fukushima: Unit 2 Discharge - Why Differs from Units 1 & 3?

In summary, Unit 2 of the Fukushima Daiichi nuclear plant emitted more radioactive material than Units 1 and 3. This may be due to a different pressure situation inside the reactor vessel.
  • #1
clancy688
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Fukushima - Unit 2, what happened different to Units 1 and 3?

There are recent discussions about this topic going on, so I think it deserves its own thread.

According to attachement IV-2, Unit 2 is responsible for more than 90% of the overall emissions. So there's one big question: What was different at Unit 2, compared to Units 1 and 3?

We know for sure that there are three total meltdowns in Units 1-3. Part of the Corium probably penetrated the RPV and is now at the bottom of the primary containment. As for Unit 1, there are probably holes in the secondary containment, but I think that those are mainly ruptured valves. So the primary containment is keeping most of the fission products in check. They would need to go through a labyrinth of pipes and valves to see fresh air.
Unit 3 is a little more tricky. I'd say it's the same situation as in Unit 1, but the big bang which happened is still a mystery.

So let's look at Unit 2 now. Unit 2s RPV lost pressure around one hour before midnight on March 14th, so that's probably the time when the corium penetrated the vessel. It's interesting to see that simultaneously the Drywell pressure (= primary containment) increased.
Then, at 6:00 am, another interesting thing happens - the explosion near the torus, followed by a fast depressurization of both the torus and the RPV.

Now I found the following pdf which deals with containment failures for Mark-I containments:

http://www.osti.gov/bridge/servlets/purl/5835351-nR29Hq/5835351.pdf

It says "Drywell shell melt-through would result in blowdown to torus room or second floor of reactor building". So perhaps that's what happened at Unit 2, but not at Unit 1 and 3. Molten corium attacked the primary containment walls which resulted in a blowdown to either the torus room or the second floor. Or only one of the two. And the following depressurization, maybe coupled with a hydrogen explosion, could have further damaged the building. So that the primary containment would be directly connected to the outside, not through pipes and valves.
If the blowdown occurred in the eastern corner of the building, the shockwave may have deflagrated in the turbine building without even coming near the refueling deck. Which would explain why the outer structure of Unit 2 is still okay.

What do you think?
 
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  • #2
clancy688 said:
It says "Drywell shell melt-through would result in blowdown to torus room or second floor of reactor building". So perhaps that's what happened at Unit 2, but not at Unit 1 and 3. Molten corium attacked the primary containment walls which resulted in a blowdown to either the torus room or the second floor. Or only one of the two. And the following depressurization, maybe coupled with a hydrogen explosion, could have further damaged the building. So that the primary containment would be directly connected to the outside, not through pipes and valves.
If the blowdown occurred in the eastern corner of the building, the shockwave may have deflagrated in the turbine building without even coming near the refueling deck. Which would explain why the outer structure of Unit 2 is still okay.

What do you think?

Thanks for the link to the pdf. Shows the importance of ensuring all efforts are made to cool the core and core debris while it is still in the RPV!

The explosions at U1, 2 and 3 all seem too closely associated with the actions taken to vent the PC. U3 PC was vented sometime early in the morning of 3/15. The explosion was noted at 0614 and torus pressure dropped to 0. Although drywell pressure was almost twice design pressure when the explosion occurred, later in the morning RPV pressure and drywell pressures are not equal to torus pressure. One would think that after RPV breach by core debris and drywell liner melt-thru, pressures in these volumes would be quite low. The reliability of any indications after the explosion is certainly suspect, especially after they found the RPV water level instruments to be reading high when they should have been downscale.

I can't help but think there is some correlation to PC venting. The design of the HPV system at these units shows the drywell and torus vent piping going to the rupture disk then the stack. But, upstream of the rupture disk is a branch to the SBGT System. This branch remains isolated as long as the AOV in the line going to SBGT System is or stays closed. (See vent drawings in Japanese gov't report to IAEA.) Downstream of the AOV is ductwork that would have easily failed at the pressures the PCs were vented. This would result in lots of hydrogen and possible CO from core-concrete interaction in the drywell to escape directly to the RB. The crane way from the ground floor of the RB to the refuel floor is a perfect chimney to get hydrogen to all floors of the RB.

The location of the U2 blast is different from U1 and U3 and was reported to have been in or near the torus area room. I suppose your explanation is possible. Also, if liner melt-thru occurred, the corium causing the melt-thru is not likely to stop at the liner breach location but would flow and be ejected through the failure point along with the combustible gases. So, do we have RB wall melt-thru by core debris?
 
  • #3
Why does this need a separate thread? Not saying it won't be allowed, but there are too many threads being started on the same subject.
 
  • #4
Evo said:
Why does this need a separate thread? Not saying it won't be allowed, but there are too many threads being started on the same subject.

It's a pain in the *** finding something in the main thread. Moreover it's very hard to actually follow a specific topic there.

For example there are three people discussing the explosion of Unit 3. Then suddenly somebody detects steam on the live webcam and posts a nervous response. Five people reply to that, sharing their own conspiracy theories. And perhaps two other new people join the thread in the meantime and ask for a summary, which will be provided by yet another member.
Now anybody following the inital discussion will be doomed. How is he supposed to follow the issues regarding the Unit 3 explosion?

It's already stated that Fukushima is the most complex nuclear accident ever happened. Unraveling its technical dimensions in a single thread is foredoomed to failure.

So I really don't think that your shutting down of the Unit 3 explosion thread is helpful in any way. You're basically preventing what we're doing here for over three months - fact based speculation. It's hard borderline but still not against the rules - overly speculative. That you shut down the thread won't prevent those discussions, but rather create further confusion in the main thread.
 
  • #5
Two questions re Unit #2 (although it's not really related with the quite specific thread title.)

1. Is it established that there was an actual explosion inside containment that caused it to fail or is the leaking containment cause an unknown at this stage?

2. Please correct me if I have misunderstood that in a working Mark I system if the pressure in the torus drops to a given level below that of the containment building one or more vacumn breakers will activate to equalize that pressure difference -

edit : i.e. drawing air (oxygen) from the containment building into the torus?



EDIT: Oh, so is this the right thread or...??

May i suggest these sub threads be nested under the main Fukushima thread if that's possible, that will at least keep the main forum index cleaner. Just a thought :)
 
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  • #6
westfield said:
1. Is it established that there was an actual explosion inside containment that caused it to fail or is the leaking containment cause an unknown at this stage?

There was the sound of a heavy explosion near the torus heard on March 15th, 6:00am, followed by a sudden deprussurization of the Wetwell.
Something did make a bang inside the containment. They don't know why what. Or at least they won't tell.

May i suggest these sub threads be nested under the main Fukushima thread, that will at least keep the main forum index cleaner. Just a thought :)

My wish would be getting an own sub-forum, but it's still six months to Christmas...
 
  • #7
Here is what the report to IAEA says (from IV-64):

With regard to the sounds of an impact around the S/C, we cannot say anything for sure because we are limited in checking the site where the explosion was heard. In addition to severe accident analysis, we conducted numerical fluid dynamics analysis, and at this point, it is presumed that in the reactor, the hydrogen generated when zirconium used in the fuel cladding reacted with water flowing into the S/C when the SRV was opened, leaked from the S/C, and exploded in the torus room.

It may be a very long time before we get anything better than this explanation.

Im stilla bit confused about the exact timing of the release to the environment, because cetain graphs that I posted in the main thread just the other day, seem to suggest that a lot of stuff got into the environment in the hours leading up to the explosion, rather than after the explosion. Thats what their reactor analysis seems to show. But other analysis, based on radiation readings at certain locations on site, seems to have the highest magnitude releases happening after the explosion.

First graph shows stuff going into environment after valve opened, before explosion.

https://www.physicsforums.com/attachment.php?attachmentid=36458&d=1308073787

This graph of estimated total release amounts and the time periods they cover, has highest magnitude releases happening for just a few hours during the 15th, at a time after the explosion:

https://www.physicsforums.com/attachment.php?attachmentid=36462&d=1308080200
 
  • #8
I'm going to respond to a few things that were said in main thread recently, but as they involve release issues with reactor 2 I'll do it here.

MadderDoc said:
Those figures appear to be the results of a modelling attempt based on a selected subset of possible scenarios, and not based on actual release measurements. You cannot base such a strong statement on that.

I need to work harder on translating this document, which explains how release estimates were calculated:

http://www.nsc.go.jp/anzen/shidai/genan2011/genan031/siryo4-2.pdf [Broken]

From what I can tell they did use actual sampling of conditions outside the plant, they were not just relying on other analysis of what may have happened at the reactors.

However there certainly seems to be a reason to have some doubts about the very highest magnitude release estimates from unit 2. From the table on page 4 of the document, we can see that for the time period of the highest estimated releases, 9am to 3pm on the 15th, they had to rely on air sampling only, they did not have any dust sampling data. I believe this is due to the weather conditions of the 15th, I think dust sampling method doesn't work when its raining/snowing.

Quim said:
Not as long as the Pacific Ocean lies outside of the plant.
You do realize that this is just a fluke result of wind direction don't you?

I don't think it is at all safe to make this claim in such a concrete way. As I have pointed out in recent days, there is an issue here, especially with reactor 3 where wind around the time of explosion there makes it hard to imagine the scale of any release being accurately determined by on-land monitoring.

But all this leaves us with is uncertainty, it does not prove that other reactors had the same order of release as reactor 2, only that the possibility exists for them to have underestimated release from other reactors.
 
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  • #9
SteveElbows said:
I don't think it is at all safe to make this claim in such a concrete way.
The guy I was responding to had made a claim (that I see as inaccurate) in a very concrete way:
clancy688 said:
The contamination outside the plant is nearly entirely the fault of Unit 2. Unit 1 and 3 may have been eyecandy, but Unit 2 is the real headache.


BTW
I'm OK with Clancy stating his opinion.
 
  • #10
Hm, okay. Let's see, "TEPCO reports that Unit 2 is probably responsible for nearly all of the contamination."

I think that's better than my previous claim. Of course I'd be interested in how TEPCO decided that Unit 2 released that much radioactivity.

Did they actually measure what was coming out of Units 1, 2 and 3? (I can't really imagine how that would be possible without dozens of sensors in and on the reactor buildings). Did they make that statement based on the course of events? (Big radioactivity spike after the explosion sound in Unit 2 -> Unit 2 is entirely at fault)
Or do they perhaps know more than us?


But you're probably right. Before we can discuss why Unit 2 popped out so much radioactivity, we need to evaluate first if and/or why the report about that is justified.
 
  • #11
To accept premise of this thread requires one to accept a fallacious assumption.

IMO
The thread should be re-titled.*Clancy beat me to it.*
This post is redundant.
 
  • #12
Quim said:
To accept premise of this thread requires one to accept a fallacious assumption.

IMO
The thread should be re-titled.

Yeah, I tried that this morning. Unfortunately, it doesn't work. Perhaps only mods can change thread titles.

I think "Unit 2 - why did the accident take a different course compared to Units 1 and 3" would be fitting description. But as I said, I can't change the title, sorry.
 
  • #13
Quim said:
To accept premise of this thread requires one to accept a fallacious assumption.

There is nothing wrong with the premise of the thread. People took note of the estimations of total release and the resulting INES rating 7, so they should also take note of the fact that these numbers came from analysis where unit 2 was considered mostly to blame.

There exists the possibility that they are wrong, and have either overestimated reactor 2 releases or underestimated reactor 3 or 1 releases, or reactor 4 fuel pool release. But this is just a possibility, not a fact that you have proven.

There are in general not that many certainties at this point, such is the nature of the beast. So for sure the thread title is too certain, but that does not mean the entire premise of the thread is defunct.

Given the on-site readings and data from further afield, I certainly have no reason to downplay the release from reactor 2. Its a big shame they don't have dust sampling for important 9am-3pm period on that date, but even without this it seems more than plausible that reactor 2 was greatly responsible for the contamination which has caused evacuations to the north west. I don't know how we may ever learn whether reactor 3 spat out more contamination than they estimate, but I will be looking again at reactor 1 and seeing if it is possible to learn how much of the north-west contamination came from reactor 1 rather than 2.

Even if there remains a large dispute about reactor 3's contribution to the environment relative to reactor 2's, we can still talk about reactor 2 being responsible for the bulk of things, we just have to rephrase things so that we are talking only about land contamination rather than total release.
 
  • #14
clancy688 said:
Yeah, I tried that this morning. Unfortunately, it doesn't work. Perhaps only mods can change thread titles.

I think "Unit 2 - why did the accident take a different course compared to Units 1 and 3" would be fitting description. But as I said, I can't change the title, sorry.

Unit two was left without minders, so one SRV cycled mindlessly and the steam it released heated up the water in a very small portion of the torus. When burps of superheated steam get into hot water, you get a nasty pressure wave. Basically, that SRV water-hammered the torus wall until it gave out.
 
  • #15
zapperzero said:
Unit two was left without minders, so one SRV cycled mindlessly and the steam it released heated up the water in a very small portion of the torus. When burps of superheated steam get into hot water, you get a nasty pressure wave. Basically, that SRV water-hammered the torus wall until it gave out.

Do you have any sources for that SRV-cycle statement? You're saying one SRV alone (while others were shut?) released superheated steam from the RPV into the torus which finally failed the walls?
But the RPV lost pressure shortly before midnight, while the torus explosion sound was heard seven hours later. Why should the SRV open if the RPV was already depressurized?
 
  • #16
clancy688 said:
Do you have any sources for that SRV-cycle statement? You're saying one SRV alone (while others were shut?) released superheated steam from the RPV into the torus which finally failed the walls?
But the RPV lost pressure shortly before midnight, while the torus explosion sound was heard seven hours later. Why should the SRV open if the RPV was already depressurized?

Umm... yes. Apparently, without operator intervention, only one of the many SRVs opens (the one with the lowest-threshold pressure gage, I suppose). Here's NUCENG reading from the paper traces provided by TEPCO:

https://www.physicsforums.com/showthread.php?p=3309618#post3309618

Also, this.
Breaches in containment at #1 and #2 before the respective explosions:
http://search.japantimes.co.jp/cgi-bin/nn20110526a1.html [Broken]

The utility also hypothesized that a breach roughly 10 cm wide occurred at the No. 2 reactor's containment vessel 21 hours after the quake due to elevated temperatures, among other factors.

They're working off a model here, they don't know where the breach was. Hydrogen would accumulate outside the torus etc etc. I'm not so sure about the timeline.

EDIT: found it again. In one of my own posts no less.
http://www.nrc.gov/reading-rm/doc-collections/nuregs/staff/sr0933/sec3/108.html
 
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  • #17
I can change thread title, but each post has its own tile - and these will be left. I am not sure if it makes sense.
 
  • #18
zapperzero said:
Umm... yes. Apparently, without operator intervention, only one of the many SRVs opens (the one with the lowest-threshold pressure gage, I suppose). Here's NUCENG reading from the paper traces provided by TEPCO:

https://www.physicsforums.com/showthread.php?p=3309618#post3309618

Also, this.
Breaches in containment at #1 and #2 before the respective explosions:
http://search.japantimes.co.jp/cgi-bin/nn20110526a1.html [Broken]

The utility also hypothesized that a breach roughly 10 cm wide occurred at the No. 2 reactor's containment vessel 21 hours after the quake due to elevated temperatures, among other factors.

They're working off a model here, they don't know where the breach was. Hydrogen would accumulate outside the torus etc etc. I'm not so sure about the timeline.

That TEPCO data & post you link to are about the first hour or so after the earthquake hit. For a guide to what may have happened on the 14th and 15th, I use some other TEPCO & NISAs analysis, mostly via the english version of report to IAEA.

http://www.kantei.go.jp/foreign/kan/topics/201106/pdf/attach_04_1.pdf

Table on page 23 of Attachment IV-1 tells us:

9.20pm on 14th they open 2 SRV's and reactor pressure decreases.
11pm it is presumed that the 1 SRV was closed because reactor pressure increased.

The 2nd graph on page 35 shows these reactor pressure trends.

Graphs on page 36 show the D/W and S/C pressures, both measured and those predicted by the model. Note that S/C pressure readings start to go down well before the explosion, at a time when D/W pressure readings are going up.

Graph on page 32 of the document shows us the reason they have also assumed a D/W leak really early on, approx 21 hours after earthquake. This version of graph does not factor in this assumption, and as a result the model says that D/W and S/C pressures would have gone shooting up to very high levels days earlier. The other graphs I already mention do have the assumption of 21 hour D/W damage in them, and as a result the model D/W and S/C pressure values track the ones they actually measured pretty well.

Note that I have chosen analysis case 2 because that's the one that reflects what they learned about bad water level readings at reactor 1, implying less water at the other reactors. This leads to conclusions such as RPV damage having happened. Case 1 was the more optimistic version of events where fuel was only partially melted and RPV damage didnt happen, so I've paid much less attention to it.

Also note that this document is TEPCOs version of analysis, and their versions of the FP existence ratio graphs are not like the ones I posted recently, theirs have only around 1% of stuff getting outside containment.
 
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  • #19
SteveElbows said:
<..>
Im stilla bit confused about the exact timing of the release to the environment, because cetain graphs that I posted in the main thread just the other day, seem to suggest that a lot of stuff got into the environment in the hours leading up to the explosion, rather than after the explosion. Thats what their reactor analysis seems to show. But other analysis, based on radiation readings at certain locations on site, seems to have the highest magnitude releases happening after the explosion.

Assuming both analyses represent reality, it would seem to imply that (some) radioactivity was released from unit 2 before the explosion in the unit (due to venting), and quite a lot more radioactivity was released after the explosion in unit2 -- however not from unit 2 but from one or more of the other units.

First graph shows stuff going into environment after valve opened, before explosion.

https://www.physicsforums.com/attachment.php?attachmentid=36458&d=1308073787

Perhaps I do not fully understand the graph, but it bothers me that it seems to show that all the compartments had the fraction 0 of fission products, until the safety release was opened at about 78h. Also (caveat: judged visually) in the following period there are times when the sum of increases in compartmental fractions seem to be not matched to the sum of decreases.

This graph of estimated total release amounts and the time periods they cover, has highest magnitude releases happening for just a few hours during the 15th, at a time after the explosion:

https://www.physicsforums.com/attachment.php?attachmentid=36462&d=1308080200

There's certainly a peak in the release rate at that time, but the graph also shows the release rate to remain high for days thereafter. in particular as regards I-131. If we think in accumulated releases, the release during the peak would seem dwarfed by the sum of releases followingly.
 
  • #20
SteveElbows said:
That TEPCO data & post you link to are about the first hour or so after the earthquake hit. For a guide to what may have happened on the 14th and 15th, I use some other TEPCO & NISAs analysis, mostly via the english version of report to IAEA.

http://www.kantei.go.jp/foreign/kan/topics/201106/pdf/attach_04_1.pdf

Table on page 23 of Attachment IV-1 tells us:

9.20pm on 14th they open 2 SRV's and reactor pressure decreases.
11pm it is presumed that the 1 SRV was closed because reactor pressure increased.

The 2nd graph on page 35 shows these reactor pressure trends.

Graphs on page 36 show the D/W and S/C pressures, both measured and those predicted by the model. Note that S/C pressure readings start to go down well before the explosion, at a time when D/W pressure readings are going up.

Graph on page 32 of the document shows us the reason they have also assumed a D/W leak really early on, approx 21 hours after earthquake. This version of graph does not factor in this assumption, and as a result the model says that D/W and S/C pressures would have gone shooting up to very high levels days earlier. The other graphs I already mention do have the assumption of 21 hour D/W damage in them, and as a result the model D/W and S/C pressure values track the ones they actually measured pretty well.

Note that I have chosen analysis case 2 because that's the one that reflects what they learned about bad water level readings at reactor 1, implying less water at the other reactors. This leads to conclusions such as RPV damage having happened. Case 1 was the more optimistic version of events where fuel was only partially melted and RPV damage didnt happen, so I've paid much less attention to it.

Also note that this document is TEPCOs version of analysis, and their versions of the FP existence ratio graphs are not like the ones I posted recently, theirs have only around 1% of stuff getting outside containment.

Here's my proposed sequence:

- quake, tsunami, blah blah
- SRV starts cycling
- a small D/W leak appears, steam goes who knows where, in any case some coolant loss happens.
- S/C wall goes pop, pressure drops (you can see it on your graph), water level drops too
- operators prop open two SRVs. Meltdown is now in progress.
- huge pressure spike in the D/W
- some of the new, hydrogen-laden steam makes it out of the S/C out of the water and through the crack. boom.
- water starts gushing out of the S/C
- a short time later, D/W pressure drops, as it is now venting to the outside, through the broken torus.
 
  • #21
zapperzero said:
Here's my proposed sequence:

- quake, tsunami, blah blah
- SRV starts cycling
- a small D/W leak appears, steam goes who knows where, in any case some coolant loss happens.
- S/C wall goes pop, pressure drops (you can see it on your graph), water level drops too
- operators prop open two SRVs. Meltdown is now in progress.
- huge pressure spike in the D/W
- some of the new, hydrogen-laden steam makes it out of the S/C out of the water and through the crack. boom.
- water starts gushing out of the S/C
- a short time later, D/W pressure drops, as it is now venting to the outside, through the broken torus.
That sequence makes sense to me, but I have a couple of questions.
Do you (also) assume that a " huge pressure spike in the D/W" was caused by a hydrogen/oxygen reaction? Why did #2 have so much more oxygen in it than 1&3?

Are you thinking that the " boom" was outside of containment?
Why no damage to the building?
 
  • #22
Quim said:
That sequence makes sense to me, but I have a couple of questions.
Do you (also) assume that a " huge pressure spike in the D/W" was caused by a hydrogen/oxygen reaction? Why did #2 have so much more oxygen in it than 1&3?

Are you thinking that the " boom" was outside of containment?
Why no damage to the building?

By the numbers from the top:
- no, I think that was the water from the RPV boiling off and two open SRVs
- I don't understand that question. Why would it have more?
- yes, somewhere right outside the torus. I don't know if there was damage to the building... no-one went into the sub-basement where the S/C is to check.
 
  • #23
zapperzero said:
By the numbers from the top:
- no, I think that was the water from the RPV boiling off and two open SRVs
- I don't understand that question. Why would it have more?
- yes, somewhere right outside the torus. I don't know if there was damage to the building... no-one went into the sub-basement where the S/C is to check.
I obviously made a false assumption; when you described a "- huge pressure spike in the D/W" I assumed that you believed that to be from an Oxygen/Hydrogen reaction, but since you think the spike was a result of boiling water, my question about where the oxygen came from was superfluous. I apologize for the confusion.

When you say the boom occurred "outside the torus" you were meaning outside the torus but still inside the containment structure.

I wondered if you meant outside both.
 
  • #24
zapperzero said:
- yes, somewhere right outside the torus. I don't know if there was damage to the building... no-one went into the sub-basement where the S/C is to check.

I think damage to the building is very likely. At least if we take those "Unit 2 released over 90% of the radioactivity" claims by TEPCO into consideration.
I don't know the exact building structure, but if an explosion occurred deep down in the torus room AND on the eastern side (speculation), the shock wave may have dispersed in the lower structures of the reactor building and the the turbine building, without triggering the overpressure panels at the roof.

I'm not very familiar with the overall building structure of the Fukushima reactors. I only know that part of the torus is in fact under the connection to the turbine buildings. Is it possible for a blast coming from the torus room and failing its walls to enter the turbine buildings?
 
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  • #25
Quim said:
I obviously made a false assumption; when you described a "- huge pressure spike in the D/W" I assumed that you believed that to be from an Oxygen/Hydrogen reaction, but since you think the spike was a result of boiling water, my question about where the oxygen came from was superfluous. I apologize for the confusion.

When you say the boom occurred "outside the torus" you were meaning outside the torus but still inside the containment structure.

I wondered if you meant outside both.

You may understand this, if so, this is for other readers. To clarify - The drywelll and torus make up primary containment connected by the 8 large vent lines. Everything outside the drywell, vents, and torus in an intact RB is basically part of secondary containment. Units 1 through 4 have apparently had failures in both primary and secondary containment. In the case of Unit 4 the primary containment was opened for maintenance. In the other units failures were due to either overpressure, explosion or overtemperature.
 
  • #26
NUCENG said:
You may understand this, if so, this is for other readers. To clarify - The drywelll and torus make up primary containment connected by the 8 large vent lines. Everything outside the drywell, vents, and torus in an intact RB is basically part of secondary containment.

Units 1 through 4 have apparently had failures in both primary and secondary containment.

In the case of Unit 4 the primary containment was opened for maintenance. In the other units failures were due to either overpressure, explosion or overtemperature.

We are just fumbling with words here, but there is some built in confusion of terms and it wasn't me who started it.:devil:

Originally, when I was first learning about NPPs, I was taught that the first layer of containment for the uranium fuel was the zirconium sheath. Once I realized the clash of naming conventions that brought on, I took on the personal theory that there are but two containments, the RPV and the concrete structure in which it sits. (I do not consider the building itself to be part of the containment.) I see the RPV as the "primary" containment.

I know that I am out of sync with some, but I assume there are some who see it the same way I do.

So knowing this potential for confusion exists I tried to use the term "containment" to mean the concrete shell. But I see that won't work because some apparently consider the building itself to be part of the containment.

So I'll avoid the subject or be very specific in the future.
 
  • #27
in any field of study one starts with vocabulary and progresses to principles.
When one does not use accepted vocabulary communication goes poorly.

in this industry "Defense in Depth" (DID) is a vocabulary term for multiplicity of protections.
There are multiple protective barriers to keep fission products where they belong.
There are also multiple "Engineered Safety Features" which are machines whose job it is to protect the barriers.

WRT fission product barriers DID means these three layers:
1. fuel clad (your Zr sheath),
2. RPV (surrounds fuel & clad),
3. reactor vessel primary containment (usually a metal membrane) surrounding RPV and attachments
(in some texts the UO2 ceramic itself is considered the zeroth layer of defense.)

you might think the RPV would be called "Primary Containment" but it's not.
Primary containment encloses the whole primary system which is the reactor vessel plus its pumps & valves.

In power reactors the primary containment is a thin metal skin (the BWR light bulb) surrounded in turn by a concrete building that's mostly a missile barrier.
The concrete building provides a little bit of "secondary containment" but is basically analogous to a pair of coveralls. It's often called the "Containment Building" because that's what is inside it, the primary containment .

here's a decent paper with drawings..
https://netfiles.uiuc.edu/mragheb/www/NPRE%20457%20CSE%20462%20Safety%20Analysis%20of%20Nuclear%20Reactor%20Systems/Containment%20Structures.pdf [Broken]

But, after all, the sciences have made progress, because philosophers have applied themselves with more attention to observe, and have communicated to their language that precision and accuracy which they have employed in their observations: In correcting their language they reason better.
http://web.lemoyne.edu/~giunta/lavpref.html
 
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  • #28
clancy688 said:
Is it possible for a blast coming from the torus room and failing its walls to enter the turbine buildings?

Water and steam certainly can travel between the two buildings so why not a shock wave? But why do you ask?

Also, the torus rooms' walls are backed with earth, I don't think they could have failed. Ceilings, maybe.
 
  • #29
I remain somewhat frustrated that this aspect of the disaster has not received more focus.

I have just read several details from the second report to the IAEA which are relevant to this topic.

Chapter 2: http://www.meti.go.jp/english/earthquake/nuclear/iaea/pdf/20110911/chapter2.pdf

Towards the end of this document the topic turns to estimated releases. Much is discussed, including a re-evaluation of March 12th-15th release estimates that JAEA conducted in light of NISA's June 3rd disclosure of emergency monitoring data from this period. They added some estimates based on the explosions, but also did something to the march 15th estimates, described as follows on page II-394

Also, as for the release on March 15, by taking into consideration the contribution to the air dose rate of tellurium-132 and its progeny nuclide, iodine-132, which were previously ignored, the estimated release rate of iodine-131 and cesium-137 decreased in relative terms.

Then, on page II-396 there is a table showing estimated release fractions into the environment, which they came up with using MELCOR. I've seen very similar in the past, buried in other reports, except this time there is a Tellurium group.

For Unit 1 they have approx 0.7% Iodine group, 1% Tellurium group, 0.3% Cesium group.

For Unit 2 they have approx 0.4%-7.0% Iodine, 0.4%-3.0% Tellurium and 0.3%-6.0% Cesium.

For Unit 3 they have approx 0.4%-0.8% Iodine, and Tellurium and Cesium at 0.3%-0.6%


Obviously reactor 2 sticks out with these figures compared to the other reactors, just as it did with previous version of these figures. Much higher possible percentage release of core material to the environment, but also a much wider range of approximation, with the lower end comparable to the estimates for units 1 & 3.

We know what sort of environmental monitoring data leads them to believe that bad things happened on March 15th, which forms a different part of their estimated release analysis, but I am really in the dark about what aspects of reactor 2's status, data or other observations post-earthquake cause this wider range of numbers to come out of MELCOR. Suppression chamber damage or some other details?

I also note that elsewhere in this document it seems to indicate that when the first estimates of how the disaster may unfold were being modeled late on march 11th/early march 12th, reactor two was the first one they did this for. This may have nothing to do with what happened later, I haven't spent too much time thinking about this yet.
 
  • #30
From the 2nd report to the IAEA, http://www.meti.go.jp/english/earthquake/nuclear/iaea/pdf/20110911/chapter0-summary.pdf" [Broken]

(Quoted text below is OCR extracted from an image of the page, there may be minor differences to the original)

"- PCV venting
In order to create a situation in which PCV venting can be performed, operations to
open a PCV vent valve (MO valve (motor operated valve)) (open 25% of the stipulated
procedure) was performed at 8:10 on the 13th, and the operation of opening the large
valve of the SC vent (AO valve (air operated valve)) was performed at 11:00 of the
same day to complete the vent line configuration and await the blowout of a rupture
disk. However, after that, the S/C large valve was closed and unable to be re-opened,
affected by the explosion of the reactor building of Unit 3 at 11:01 on the 14th;
nevertheless, efforts were continued to form a line. At around 21:00 on that day the
small valve of the S/C vent (AO valve) was opened slightly, making the vent line
configuration successful again. However, a policy of drywell venting was adopted
because the pressure on the S/C side was lower than the working pressure of the rupture
disk and the pressure on the drywell side was increasing, and an operation to open the
small valve of the drywell vent valve (AO valve) was performed once at 0:02 on the
15th; however, it was confirmed several minutes later that the small valve was closed.
After that, drywell pressure maintained a high level of values; large sounds of impact
occurred between around 6:00 and 6:10 of the lS, while S/C pressure indicated O MPa
abs. Lower drywell pressure was also confirmed at around 11:25 on that day."



My question is - does the abovementioned Drywell direct venting constitute a possible explanation for Unit #2's alleged large contribution to site releases?

This also seems to shed more light on why TEPCO seemed fairly sure something broke in the wetwell area? They were not able to vent from S\C?
 
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  • #31
westfield said:
From the 2nd report to the IAEA, http://www.meti.go.jp/english/earthquake/nuclear/iaea/pdf/20110911/chapter0-summary.pdf" [Broken]

(Quoted text below is OCR extracted from an image of the page, there may be minor differences to the original)

" a policy of drywell venting was adopted
because the pressure on the S/C side was lower than the working pressure of the rupture
disk and the pressure on the drywell side was increasing, and an operation to open the
small valve of the drywell vent valve (AO valve) was performed once at 0:02 on the
15th; however, it was confirmed several minutes later that the small valve was closed.
After that, drywell pressure maintained a high level of values; large sounds of impact
occurred between around 6:00 and 6:10 of the lS, while S/C pressure indicated O MPa
abs. Lower drywell pressure was also confirmed at around 11:25 on that day."

My question is - does the abovementioned Drywell direct venting constitute a possible explanation for Unit #2's alleged large contribution to site releases?

This also seems to shed more light on why TEPCO seemed fairly sure something broke in the wetwell area? They were not able to vent from S\C?

The report raises interesting questions. Why would S/C pressure be lower than drywell? 0 MPa abs means the sensor was off or broken somehow. It measures using a water column? Maybe the water drained?

also
large sounds of impact occurred between around 6:00 and 6:10
sounds. plural.

To your question: yes, the drywell would have been "dirtier".

EDIT: I should probably revise my earlier proposed accident sequence.
 
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  • #32
Via EX-SKF:

http://ex-skf.blogspot.com/2012/03/dry-vent-of-reactor-2-may-have-released.html

It shows the spatial dose of radiation at the front gate of Fukushima I Nuke Plant and the timeline of events at the plant in March. The largest spike seems to be around or after 12AM on March 15, and the label on the spike says "Dry vent at reactor no.2".

What's the difference between a "dry" and a "wet" went? Morever, according to the INPO report, the Unit 2 containment was never vented because the venting line-up wasn't completed (a rupture disk failed to break).
 
  • #33
clancy688 said:
What's the difference between a "dry" and a "wet" went?

Wet venting is venting steam from the RPV through the water in the suppression chamber (aka wetwell) and then out of the suppression chamber into the stack. This scrubs most of the particulates and some of the gasses out of the vented steam, so the radioactive release is diminished.

Dry venting is when the steam goes directly into the outside air by some route or another. Obviously it is very far from being clean.
 
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  • #34
It is good to see that this topic receives attention again, as I am still extremely dissatisfied that reactor 2's possible majority contribution to the total environmental contamination does not get much focus in the wider world. I've been fascinated by this subject for a long time now, but with little new info to help my understanding.

The ICANPS report was certainly much more readable than previous reports, made it easier to be confident about thing we already thought we knew, and added some detail that I don't think was discussed elsewhere.

It doesn't explain the venting contradictions, since it says in detail what we already heard from previous reports, that they had a range of nightmares when trying to vent, and failed. However I read with interest some of the comments on the ex-skf article, where someone has a theory that venting from the drywell may have occurred very briefly around midnight, not for long enough to reduce pressure in a noticeable way, but enough to allow substances to escape. To explore this theory further we would need to know why reports seem so certain that the rupture disk didn't fail.

The report isn't very helpful when it comes to why the measured pressure in the D/W and S/C diverged so much, but the report does emphasise the possibility that the S/C pressure readings developed a fault, especially as a reading of 0 as shown shortly after 6am on the 15th indicated less than atmospheric pressure, which makes no sense.

I think that the main thing from that report that was new to me was the explanation as to why the S/C was in a state that was inappropriate for receiving a load of stream from the reactor. They switched the RCIC to use the S/C water as a source early in the morning of March 12th, but they didn't pay any attention to S/C temperature & pressure until March 14th, nor did they attempt to complete an alternative to the RCIC until the RCIC was on its very last legs. Combine this with the multiple problems when trying to vent, fire truck running out of fuel without anyone noticing for a while, and some reactor pressure fluctuations which would have prevented water injection from working at various points, and we start to get a better idea of just why reactor 2s failure had such large implications for the environment. It will be interesting to perhaps learn one day as to how the fuel damage at this reactor compares to the others, but have a very long wait for that, if ever! Not sure how much we will really find out about the state of the drywall or S/C either.
 
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  • #35
zapperzero said:
Dry venting is when the steam goes directly into the outside air by some route or another. Obviously it is very far from being clean.

I expect that the term dry venting is supposed to mean deliberate venting by one very specific route, as opposed to unplanned escapes from drywell containment due to some kind of containment failure. Most importantly this route still involves the stack, but as you mentioned does not include scrubbing via the S/C so it has larger environmental implications.

Sadly unlike the initial vents at reactors 1 & 3, we have no visual confirmation of anything leaving the stack during any of the reactor 2 venting attempts, mostly because the attempt at dry venting happened at night, and the old 'one published image an hour' camera was no use at night.

What I find especially annoying is that we don't even know exactly when steam was first noticed to be coming from the blowout panel hole in the side of reactor 2. We certainly know that plenty of steam etc came out of this hole later, as we have footage, but not knowing when it began is frustrating. Assuming it was from the reactor rather than the fuel pool, which is a reasonable bet given much later footage showing steam from the reactor arena and the robot-measured radiation readings showing high levels by one side of the floor above the reactor well, we may well imagine that this started on March 15th. But it would be good to know for sure, especially as events at reactor 4 building on the 15th also got in the way of really clear explanations of radiation data on that day.
 
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<h2>1. What caused the difference in discharge from Unit 2 compared to Units 1 and 3 at Fukushima?</h2><p>The main difference in discharge from Unit 2 at Fukushima compared to Units 1 and 3 is due to the damage sustained by the reactor during the 2011 earthquake and tsunami. The damage to Unit 2 was more severe, leading to a higher level of contamination and a longer period of time needed for cleanup and decommissioning.</p><h2>2. Is the discharge from Unit 2 more dangerous than that of Units 1 and 3?</h2><p>The discharge from Unit 2 is not necessarily more dangerous than that of Units 1 and 3. The level of danger depends on the type and amount of radioactive material released, as well as the distance and duration of exposure. However, the damage to Unit 2 may make the cleanup process more challenging and time-consuming.</p><h2>3. How long will it take to clean up and decommission Unit 2 at Fukushima?</h2><p>The cleanup and decommissioning process for Unit 2 at Fukushima is estimated to take around 30-40 years. This is due to the higher level of contamination and damage to the reactor, which will require more extensive and careful measures to ensure the safety of workers and the surrounding environment.</p><h2>4. What measures are being taken to prevent future accidents at Fukushima?</h2><p>Since the 2011 disaster, the operators of the Fukushima plant have implemented various safety measures to prevent future accidents. This includes reinforcing the seawall to protect against tsunamis, installing backup generators and pumps, and improving the training and response protocols for workers in case of emergencies.</p><h2>5. Is it safe to live near the Fukushima plant now?</h2><p>The safety of living near the Fukushima plant depends on the level of contamination in the area. Currently, the Japanese government has lifted evacuation orders for some areas around the plant, but there are still restricted zones due to high levels of radiation. It is important for residents to follow safety guidelines and stay informed about any changes in the situation.</p>

1. What caused the difference in discharge from Unit 2 compared to Units 1 and 3 at Fukushima?

The main difference in discharge from Unit 2 at Fukushima compared to Units 1 and 3 is due to the damage sustained by the reactor during the 2011 earthquake and tsunami. The damage to Unit 2 was more severe, leading to a higher level of contamination and a longer period of time needed for cleanup and decommissioning.

2. Is the discharge from Unit 2 more dangerous than that of Units 1 and 3?

The discharge from Unit 2 is not necessarily more dangerous than that of Units 1 and 3. The level of danger depends on the type and amount of radioactive material released, as well as the distance and duration of exposure. However, the damage to Unit 2 may make the cleanup process more challenging and time-consuming.

3. How long will it take to clean up and decommission Unit 2 at Fukushima?

The cleanup and decommissioning process for Unit 2 at Fukushima is estimated to take around 30-40 years. This is due to the higher level of contamination and damage to the reactor, which will require more extensive and careful measures to ensure the safety of workers and the surrounding environment.

4. What measures are being taken to prevent future accidents at Fukushima?

Since the 2011 disaster, the operators of the Fukushima plant have implemented various safety measures to prevent future accidents. This includes reinforcing the seawall to protect against tsunamis, installing backup generators and pumps, and improving the training and response protocols for workers in case of emergencies.

5. Is it safe to live near the Fukushima plant now?

The safety of living near the Fukushima plant depends on the level of contamination in the area. Currently, the Japanese government has lifted evacuation orders for some areas around the plant, but there are still restricted zones due to high levels of radiation. It is important for residents to follow safety guidelines and stay informed about any changes in the situation.

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