Build Nuclear Power Plant in Record Time - No Red Tape

In summary, it would take 5 years to build a nuclear power plant from drawing board to supplying power. However, this timeframe may be lengthened depending on the design. The limiting factor at the moment is the availability of a suitable steelworks.
  • #1
j.karnuth
2
0
How long would it take to build a nuclear power plant, from drawing board to supplying power?
But with these considerations: No red tape, no hearings, no bureaucracy, public outcry falls on deaf ears.
The actual creation of the facility, building, outfitting, and starting up.
The manpower and funding exist, the citizenry is not considered.
Thanks for any help!
 
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  • #2
I think this depends strongly on whether it is an original design, or whether one is just building "another one in a series". At a certain point, France was cranking out about two NPP per year, but they were part of a series.
 
  • #3
Current optimistic estimate is 60 months or 5 years - which I believe is from ground breaking.

That assumes the site has been approved.
 
  • #4
In the hypothetical scenario I have envisioned, I suppose the permits would be of no issue, as the US military would be rolling these out in a series, and under a "permit" granted by congress. No local or state, or federal approval required. One single design, rolled out like an invasion. Thanks!
 
  • #5
Don't forget nuclear power plants are currently used in all US submarines and aircraft carriers.

There are really only several problems with Nuclear power ...two reasons I did not go into Nuclear Engin eering aftrer college. 1. Metals become brittle,weakened, in the presence of highlevels of radioacitivity...has that been largely solved?? (2) spent fuel is a horror to safely dispose...maybe a third/fourth problem: (3) The public doesn't understand how safe they are, (4) They could be a great terrorist target...to panic a lot of people, produce chaos! also politics gets in the way because of (3).
 
  • #6
I wouldn't call spent fuel "a horror" to dispose of...all the waste generated in the western world has been safely stored or recycled for decades without any problem. Compare to other industrial wastes, e.g. Love Canal, New York.
 
  • #7
The limiting step at the moment is that a single Japanese steelworks is the only place that can forge the steel rector pressure vessel and they are rather busy.
There are a few other companies tooling up to take on the market but nobody is in a hurry to buy their first attempt - ie. don't buy version 1.0 of anything , especialy not in the nuclear reactor business.
The alternative is a CANDU or a pebble bed reactor.
 
  • #8
1. Metals become brittle,weakened, in the presence of highlevels of radioacitivity...has that been largely solved??
(2) spent fuel is a horror to safely dispose...

With respect to 1, the pressure vessel does become embrittled, but not necessarily weakend due to fast neutron exposure, and to a lesser extent to gamma rays. For that reason, the industry has adopted a low leakeage core design methodology to reduce vessel fluence. The vessels can be annealed, but I'm not aware that it's a major effort in the US at the moment. We know what the issue is and we can deal with it.

With respect to 2, it's a political problem, not a technical problem. We need to decide if we are going to reprocess or not. If not, then we use a once through fuel cycle and dispose of spent fuel in special canisters, which are buried in multiple layer repository, currently located a Yucca Mountain, NV. The political problem is that Harry Reid (currently leader of the Senate) and other Nevadans don't want the spent fuel buried in Yucca Mountain. Someone has suggested that the DOE guarantee no leakeage for 100,000 years or so. Well, man-made structures haven't been around more than 2000-3000 years, so we can't exactly guarantee 100 k years, although we can build a system that would probably to that. Come back in 100 k years and see for yourself. :rolleyes:

Reprocessing involves reusing/recycling fissile material and simply burying they fission products. Most fission products are dispersed in an inert glass/synthetic rock matrix where they decay into inert (non-radioactive) isotopes over 10's, 100's, 1000's of years. The more radioactive a substance, the faster it decays, and the shorter time it takes to become inert. Eventually, after several centuries, most of the radwaste is inert and that helps entrap/entrain the longer lived isotopes, which are much less radioactive.

In either case, if the geological formation in which the waste is entombed has been relatively geologically stable for a million years or so, it's probably going to remain so, therefore it seems a reasonable idea to entomb the spent fuel or by-products in such a system.


There is a big problem with ignorance on the part of the public. :uhh: :rolleyes:
 
  • #9
mgb_phys said:
The limiting step at the moment is that a single Japanese steelworks is the only place that can forge the steel rector pressure vessel and they are rather busy.
There are a few other companies tooling up to take on the market but nobody is in a hurry to buy their first attempt - ie. don't buy version 1.0 of anything , especialy not in the nuclear reactor business.
The alternative is a CANDU or a pebble bed reactor.

That said, in the 70-ies, there have been very large outputs of NPP - so I wonder what was so different back then, that we now don't have anymore. After all, back then, there also wasn't any NPP industry "up and running", until, well, it came up and running. So what's the difference between now and back then ?

For instance, in France they first experimented with PWR's in about 1975, and 10 years later, in 1985, they had over 30 of them installed. Nevertheless, you can't say that in 1975, there was an industry that had a lot of experience doing so. So what's the difference with right now ?
 
  • #10
Most of them took much longer and cost much more to build than was planned, a lot of them (at least in the UK) didn't work very well - there was a lot of different designs, mostly pretty experimental.
France went for a most systematic approach (because it doesn't have any oil) but is still took 20years from starting in the mid60s to get to 1985 where they could knock out standard plants quickly - and even this was starting with an established Westinghouse PWR design.

If you want reliable nuclear plants, on time and on budget - you want to buy them from somebody with some experience of building them, not just put out the contract for each part to the cheapest bidder.
 
  • #11
vanesch said:
That said, in the 70-ies, there have been very large outputs of NPP - so I wonder what was so different back then, that we now don't have anymore. After all, back then, there also wasn't any NPP industry "up and running", until, well, it came up and running. So what's the difference between now and back then ?

For instance, in France they first experimented with PWR's in about 1975, and 10 years later, in 1985, they had over 30 of them installed. Nevertheless, you can't say that in 1975, there was an industry that had a lot of experience doing so. So what's the difference with right now ?
Westinghouse, GE, B&W and Combustion Engineering all has casting/forging shops back in the 70's. They all got started with big subsidies from the US government - Naval Nuclear Reactor program. The Naval Nuclear program consolidated as did the commercial program.

Framatome licensed Westinghouse technology. During the late 1970's Framatome took off on their own. The 900 MWe plants are based on the standard three-loop 17x17 plants, and the 4-loopers are based on the 1977 Westinghouse standard design. For whatever reason, Framatome went with 14-ft (4.27 m) core, and the US stayed 12-ft (3.66 m) cores, except for the S. Texas Project. Westinghouse was working on the SNUPPs concept (standardized plant) when TMI-2 had its accident. Then the whole dynamic changed - about 100+ plants were cancelled, and only those far enough along, and without problems were finished. With the cancellations, all the big shops were closed down.

The vendors also consolidated. Westinghouse was sold to BNFL, which then absorbed the remnants of the ABB-Combustion Engineering (ABB-CE) merger. Toshiba just bought a controlling majority in Westinghouse. Siemens had bought out Exxon's nuclear fuel group, which became ANF, then SPC, then SNP, and that is now part of AREVA (formerly Framatome) which had absorbed B&W's commercial side (including BWFC). AREVA is the international merger of Siemens and Framatome. Siemens Nuclear group was a consolidation of the KWU, RBU, AEG (sp?) and other smaller German companies.

TVA stopped work on Watts Bar and Bellefonte - primarily to put their limited resources into fixing the Browns Ferry units, and get them back on-line. Watts Bar 1 was subsequently finished and WB-2 might be (I hope). Bellefonte has been decommissioned AFAIK.

WPPSS (now EnergyNorthwest) defaulted on bonds and stopped work on WNP-1, 3, 4 and 5. Only WNP-2 (Columbia - a GE BWR) was finished. WPPSS made the mistake like NE Utilities (Millstone) of buying 3 different designs.
 
  • #12
Astronuc said:
Westinghouse, GE, B&W and Combustion Engineering all has casting/forging shops back in the 70's. They all got started with big subsidies from the US government - Naval Nuclear Reactor program.

Right, I forgot about that. There was a huge government contracting preceding the commercialisation of NPP. So they were up and running.

And although the French didn't have much experience with pressured-water reactors until beginning of the 70-ies (*), they got a jumpstart with Westinghouse.

(*) they were entirely on graphite-gas reactors until 1972 or 73 if I remember well...
 
  • #13
vanesch said:
Right, I forgot about that. There was a huge government contracting preceding the commercialisation of NPP. So they were up and running.

And although the French didn't have much experience with pressured-water reactors until beginning of the 70-ies (*), they got a jumpstart with Westinghouse.

(*) they were entirely on graphite-gas reactors until 1972 or 73 if I remember well...
The French did build some graphite-moderated, gas-cooled reactors: Chinon A1, A2, A3 were Magnox-type reactors (similar to UK's), St. Laurent A1,A2 were UNGG (French design) and Bugey 1 was a gas-cooled reactor (probably UNGG), in the 1960's. Most western commercial plants are LWR.
 
  • #14
Nuclear power revival gets big lift
http://dailybriefing.blogs.fortune.cnn.com/2008/10/23/nuclear-power-revival-gets-big-lift/ [Broken]
French nuclear power giant AREVA and Northrup Grumman Shipbuilding (NOC) jointly announced Thursday afternoon plans to build a $360 million plant in Newport News, Va., to supply large-scale components for the U.S. nuclear power industry. The announcement follows one earlier this summer by The Shaw Group and Westinghouse of their plans to build a nuclear components plant in Louisiana. Both are important steps toward what AREVA chief executive Anne Lauvergeon, in an exclusive interview with Fortune before the announcement, described as “reviving the capacity of the nuclear industry in the U.S.”

Lauvergeon means the capacity to build new nuclear power plants, which is perhaps the biggest roadblock to the industry’s vision of dramatically increasing nuclear’s share of electricity generation in the United States, currently stalled at 20%. Set aside the safety fears, political opposition, regulatory hurdles and the seemingly irresolvable quandary of how to dispose of the waste and you’re still left with the nagging question of who’s going to build all these new plants.

We used to do it all here. Today there’s just one plant in the world that’s producing the massive steel forgings that form the core of nuclear reactors, in Japan. And until these proposed new plants come online in Virginia and Louisiana, there’s still only one plant left in America — a Babcock & Wilcox facility in Mount Vernon, Ind. — that has the coveted “N” stamp required for large-scale nuclear manufacturing.

One more factor to keep in mind: The potential impact of the global economic crisis on construction plans going forward. Lauvergeon says she’s not worried about that. AREVA has a five-year backlog, she says, and is still forecasting heavy demand for new plant construction in developing countries like China and India.

. . . .
 
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  • #15
That's going to be some fun workplace politics to work through.
 

1. How is it possible to build a nuclear power plant in record time with no red tape?

There are a few key factors that make this possible. First, the construction process is streamlined by using modular components that can be assembled quickly on site. Second, there is a focus on safety and efficiency, which reduces the need for extensive bureaucratic processes. Third, there is a sense of urgency and commitment from all involved parties to complete the project in a timely manner.

2. Is it safe to build a nuclear power plant in record time without going through the usual regulatory processes?

Yes, it is safe. The streamlined construction process still follows all necessary safety protocols and regulations. Additionally, the use of modular components and a focus on safety and efficiency actually reduces the potential for safety risks during construction.

3. Will building a nuclear power plant in record time compromise the quality of the construction?

No, the quality of the construction will not be compromised. In fact, the use of modular components and a focus on safety and efficiency can actually improve the quality of the construction. Additionally, all necessary safety protocols and regulations will still be followed during the construction process.

4. What are the potential benefits of building a nuclear power plant in record time?

There are several potential benefits to building a nuclear power plant in record time. First, it can provide a reliable and affordable source of energy in a shorter amount of time. Second, it can create jobs and boost the economy in the surrounding area. Third, it can help reduce carbon emissions and combat climate change. Fourth, it can improve energy independence for the country.

5. Are there any drawbacks or risks associated with building a nuclear power plant in record time?

As with any large construction project, there are potential risks and challenges. However, by following all necessary safety protocols and regulations, these risks can be minimized. Additionally, the use of modular components and a focus on safety and efficiency can help mitigate any potential issues. Overall, the benefits of building a nuclear power plant in record time far outweigh any potential drawbacks.

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