Talk:Molten-salt reactor
This is the talk page for discussing improvements to the Molten-salt reactor article. This is not a forum for general discussion of the article's subject. |
Article policies
|
Find sources: Google (books · news · scholar · free images · WP refs) · FENS · JSTOR · TWL |
Archives: 1Auto-archiving period: 12 months |
This level-5 vital article is rated B-class on Wikipedia's content assessment scale. It is of interest to the following WikiProjects: | |||||||||||||||||||||||||||||||
|
Please post new threads at the foot of this page. The replies to the original posts can be signed with --~~~~
Molten Chloride Fast Reactor or MCFR
[edit]MCFR currently redirects to this page but not to any section or anchor. I think we should do better than that. There is a little information at TerraPower, whose design this is, but that page needs updating too.
See
- https://www.energy.gov/ne/articles/southern-company-and-terrapower-prep-testing-molten-salt-reactor a secondary source
- https://www.terrapower.com/our-work/molten-chloride-fast-reactor-technology/ for the TerraPower page on the MCFR, it has been archived on the Wayback Machine but the graphics and relevant text seem to have been lost there somehow
It's an interesting design, maybe not so promising as their Natrium reactor but probably more so than their Traveling Wave Reactor. Andrewa (talk) 15:30, 25 January 2022 (UTC)
- Both MCFR and Natrium are fast neutron reactors. I see no advantage of molten sodium over molten salt, and one clear disadvantage - the flammability of sodium. So I am favoring the MCFR, but I can't get any info from Terrapower for our article in Citizendium. I think Terrapower may be following an under-the-radar strategy on public relations: We got our funding. Let's get our demo up and running before the anti-nukers take notice. David MacQuigg 14:25, 26 May 2022 (UTC)
Gaseous fission products
[edit]We need a nuclear engineer to clarify what happens with radioactive gases (Xe and Kr) that are produced in fission reactors. It is my understanding that those gases accumulate in solid fuel rods, where they crack the fuel pellets causing voids and absorption of neutrons, which "poisons" the reaction and results in early replacement of the spent fuel. These same gases in a molten salt reactor can bubble out[1] without causing any damage, thereby greatly extending the life of the fuel. I made a revision to clarify this, and it was reverted. What is the truth? David MacQuigg|David MacQuigg 10:50, 15 April 2022 (UTC)
- @Macquigg I also remembered the same 'bubble-out' statement from my own study of the design for Liquid fluoride thorium reactor#Removal of fission products. It means the design decisions for a 1GWe (1 gigawatt electrical) molten salt fission reactor (called the Can) will have already been made, as in the 2018 Thorcon TMSR-500 proposal to the Indonesian regulatory group (restarted 2022).
- The MSRE (Oak Ridge molten salt reactor experiment) had to deal with the same issues, of course. (China, beginning in 2011, followed their own Thorium reactor development path based on the MSRE, and is proceeding on their Thorium molten salt fission reactor scale-up as of September 2021.) I assume your 'without causing any damage' statement is about damage to the prismatic graphite moderator rods (which is evidenced by expansion of the rods). In addition, I am not considering the case of solid fuel. (The MSRE discovered that Hastalloy solved the problem of the piping material. Embrittlement of the grains in the material was observed.) Thorcon's Can contains a Pot with the graphite moderator, and Primary heat exchanger. A Secondary heat exchanger is external to the Cans (the ThorCon nuclear reactor article does not show the Secondary heat exchanger which remains with the power generation building when a Can is recycled). Since China's Thorium reactor scale-up is underway, and since Thorcon was proposing a scale-up in the Indonesian proposal, a search of the Chinese documentation can confirm whether their processing of the byproducts (including Xe and Kr gases) is being handled the same way that Thorcon is proposing. Water is used to absorb the excess heat from the byproducts (Thorcon calls the structure for remediating excess heat from the Can, the cold wall).
- The ThorCon_nuclear_reactor#Leakage of radioactivity article appears to cover the chemically-bound byproducts: "iodine-131, strontium-90 and cesium-13" would manifest in the molten-salt mixture; tritium is mitigated in a third salt loop; and the radioactive xenon and krypton gases bubble out of the molten salt into a header tank, where their radioactivity is left to decay away (so those gases can be handled separately, later). Henry's law comes into play for the gases dissolved in the molten salt, such as the Xe and Kr: when the gases are constrained to a container, such as a fuel rod; they would push against the walls of the rod, or TRISO layer, etc. This would manifest as a rip in the containing material, or a void in the solid material in a rod (not applicable to an MSR, of course, in this case, the gases bubble-out of the top surface of the molten salt, where it is not constrained by its holding vessel).
- The gaseous fission byproducts in the Thorcon design are simply separated by bubble-out into a separate tank from the molten salt mixture, which remains at high temperature. The byproducts are left to cooldown (to eventually be reprocessed when a Can is swapped out— an alternate Can then receives the molten salt). The remaining molten salt is pumped back upward to the top of the Can to a secondary salt loop, and the heat from the molten salt mixture from both the primary and secondary molten salt loops is harvested to generate steam (this description is simplified: there is another salt loop in this two-fluid design —tritium is mitigated using the oxygen in the CO2 cycle of the supercritical CO2 phase -- the temperature and pressure there suffice to capture the tritium). The steam drives the electrical generation process (Thorcon emphasizes this is then standard electrical power generation technology), and the molten salt flows downward through the Can again, in a cycle. If the process overheats, a freeze plug (at the base of the piping below the Pot and heat exchangers) warms up and opens, which dumps the molten salt mixture into fuelsalt drain tanks by gravity, which stops the reactor, in an automatic fail-safe.
- Since Thorium is fertile, but not fissile, the neutron flux that is slowed down by the graphite moderator amplifies the conversion of Thorium into fissionable fuel. The MSR article states that Xe absorbs neutrons. Thorium needs all the slow neutrons so it can convert into fissionable fuel. Thus control of the purification process of the molten salt in its cycle (removal of any Xe, Kr, tritium, etc.) would actually stabilize the operating temperature for a Thorium molten salt reactor. Understanding the conditions to maintain the operating temperature is good for electical power generation, not for conversion into weapons materiel, which is the danger for a fast neutron process. The power generation process simply consumes the weaponizable materiel and produces heat for four years, the design life of the Can. The electric power vendor can then recycle the Can, for compensation, with much less waste than coal (a factor of thousands, at least). --Ancheta Wis (talk | contribs) 15:41, 15 April 2022 (UTC)
- ^ See discussion of xenon and krypton at https://thorconpower.com/safety/
Drain tank
[edit]Extended content
|
---|
What happens after an emergency stop by which all salt ended up in the drain tank, and how does it differ from possible other systems? --Wickey (talk) 13:30, 16 April 2022 (UTC)
|
- Please read WP:NOTAFORUM. Please confine commentary to direct discussion of article improvement. Speculation, criticism, how is this or that done, etc, are not the purpose of the article talk page. If you have changes that you think are needed in the article, and have reliable sources to support them, please do so. Otherwise, this is not a productive discussion. There are other venues to chat about this stuff. cheers. anastrophe, an editor he is. 18:48, 2 October 2022 (UTC)
- B-Class level-5 vital articles
- Wikipedia level-5 vital articles in Technology
- B-Class vital articles in Technology
- B-Class Engineering articles
- Unknown-importance Engineering articles
- WikiProject Engineering articles
- B-Class physics articles
- Low-importance physics articles
- B-Class physics articles of Low-importance
- B-Class energy articles
- High-importance energy articles