You think the Navy wants to cut corners on safety on a $Bn sub? If there is an alarm you can hardly run away!jamesb-uk said:On nuclear powered aircraft carriers/submarines/icebreakers, do the crew have to follow similar precautions as people who work in nuclear power plants such as clothing, film badges etc?
Generally more - people tend not to fire 18" shells at civilian reactors.Also, how much more protection does the reactor core have compared to a civilian power plant?
mgb_phys said:You think the Navy wants to cut corners on safety on a $Bn sub? If there is an alarm you can hardly run away!
Generally more - people tend not to fire 18" shells at civilian reactors.
Do searches on 'Admiral Rickover' the man behind the US's nuclear navy
James,jamesb-uk said:On nuclear powered aircraft carriers/submarines/icebreakers, do the crew have to follow similar precautions as people who work in nuclear power plants such as clothing, film badges etc? Also, how much more protection does the reactor core have compared to a civilian power plant?
On the other hand a submarine reactor is inside a steel or titanium tube designed to withstand 200-1500m of water pressure.That shielding is made of high density concrete. A nuclear power plant doesn't have to float - so it can have LOTS and LOTS of concrete around the reactor. A US Navy ship can't have that much concrete.
A commercial power plant has MUCH better protected for the reactor than does a US Navy ship.
mgb_phys,mgb_phys said:Generally more - people tend not to fire 18" shells at civilian reactors.
Agreed, the accident comments in the news links are a distraction. I'd like to concentrate on the exposure of HEU that these floating reactors present. There is some US or international official body (IAEA ?) that has a near term goal the elimination of all commercial use of HEU - completely zero it out - and this move by the Russians would seem to fly in the face of that goal.mgb_phys said:"They point to a history of naval and nuclear accidents in Russia and the former Soviet Union, including the Chernobyl disaster of 1986."
This is a PWR not an RBMK - it's hardly a comparison.
Why does nobody object to gas powered generating stations? Bhopal was a gas leak and it killed 25,000 people.
I suppose they have to balance the safety of an existing proven sub reactor design with developing a new LEU model and they must have a bunch of HEU around from weapons disarmaments.mheslep said:There is some US or international official body (IAEA ?) that has a near term goal the elimination of all commercial use of HEU - completely zero it out - and this move by the Russians would seem to fly in the face of that goal.
I doubt they're reusing weapons HEU. Probably making more.mgb_phys said:I suppose they have to balance the safety of an existing proven sub reactor design with developing a new LEU model and they must have a bunch of HEU around from weapons disarmaments.
Not the Iranians, they would then be subject to retaliation. More likely some non-state actors - something like the Taliban-Pakistani gang that hit Mumbai - direct attack or infiltration. Appears this would be manned by a commercial oil/gas drilling rig crew - ie anyone - and not Russian military.I can't see the Iranians capturing a Russian power station and sailing it to Iran without the Russian navy noticing - as an alternative to enriching their own fuel.
mgb_phys,mgb_phys said:S
Most (all?) naval reactors are also PWRs which have a bunch of inherent safety features and are relatively small.
James,jamesb-uk said:When the nuclear submarine 'Kursk' sank in 2000, there was a large explosion onboard due to a very large torpedo stored onboard. When the ship was discovered, the nuclear reactor was still intact. I was aware that civilian power stations have a lot greater quantity of protection around them in the form of concrete, but I thought that as a naval power plant would inevitably be much smaller, It would be able to have protection around it sufficient to withstand a greater impact.
I didn't know if there had been some other possibly secret designs.Morbius said:ALL naval reactors in current use are PWRs.
I had heard of Rickover doing a Feynman type demonstration with sodium in a water glass at a meeting to explain why he didn't want any more sodium cooled reactors on a boat!The US Navy did send one liquid sodium cooled reactor to sea in the original Seawolf (SSN 575):
mheslep,mheslep said:So this why Russia's pending deployment of 70MW KLT-40 reactors for oil and gas drilling in the Arctic are troubling. KLT-40's apparently use 90% HEU. I am not concerned about waste, or even accidents, but proliferation. I'm unaware of a more exposed use of HEU.
mgb_phys,mgb_phys said:I didn't know if there had been some other possibly secret designs.
I thought somebody might have tried AGRs, to get higher power and perhaps the gas coolant could be made quieter (for subs) than the cooling pumps on a PWR.
Multiple sources report the Hiroshima weapon was 80% HEU. And the topic at the moment is not the ability to enrich, but to steal or divert existing HEU, especially from platforms at sea.QuantumPion said:90% HEU is still far off from being weapons grade. If you had the technology to enrich 90% HEU to 99+% then you could go from natural to 99% anyway.
Candyman,theCandyman said:Criticality is a function of geometry and material composition, bombs need high criticality. My friends and I once joked about having a bomb made out of natural uranium if you had enough of it, not sure if that is possible though.
QuantumPion,QuantumPion said:90% HEU is still far off from being weapons grade. If you had the technology to enrich 90% HEU to 99+% then you could go from natural to 99% anyway.
There are several safety precautions in place for nuclear energy at sea, including rigorous training and certification for crew members, redundant safety systems, and constant monitoring of reactor conditions. Additionally, all nuclear-powered vessels are required to have a dedicated team of highly trained engineers and technicians on board to ensure safe operation of the reactor.
The reactor core on a nuclear-powered vessel is protected by multiple layers of steel and other materials, such as lead and boron, which act as shielding to contain radiation. The reactor is also equipped with various safety systems, including control rods that can be inserted to stop the nuclear reaction if necessary.
In the event of a nuclear emergency at sea, the crew is trained to follow established emergency procedures to ensure the safety of the ship and its personnel. This may include shutting down the reactor, activating backup systems, and potentially evacuating the vessel if necessary. Additionally, all nuclear-powered vessels are equipped with communication systems to alert authorities and coordinate a response if needed.
Crew members on a nuclear-powered vessel follow strict protocols to minimize their exposure to radiation. This includes wearing protective gear, such as radiation suits and dosimeters, and rotating crew members to limit the amount of time they spend in areas with higher radiation levels. The vessel is also equipped with ventilation and filtration systems to prevent the spread of any radioactive material.
All nuclear-powered vessels have strict protocols in place for the safe disposal of nuclear waste. This includes storing the waste in specially designed containers, monitoring and tracking the waste, and following international regulations for disposal when the vessel returns to port. Additionally, nuclear waste is not released into the ocean and is only disposed of at designated facilities on land.