Could a tank or land vehicle be nuclear powered?

In summary, the conversation discusses the possibility of using nuclear power in vehicles, specifically submarines and tanks. It is mentioned that nuclear reactors can be made small and compact, but the issue of shielding and heat removal is a concern. The possibility of using electromagnetic shielding is brought up, but it is noted that heat removal is still a challenge. The conversation also mentions a prototype mobile nuclear power reactor called Pamir, but it was ultimately scrapped in 1986. The discussion also touches on the use of nitrogen tetraoxide as a coolant in a closed Brayton cycle for potential performance improvements. The conversation ends with a mention of the US's design of a nuclear-powered airplane.
  • #1
ensabah6
695
0
Submarines are nuclear powered.

How small of a nuclear-fission powered unit be made and could it be fitted inside a tank or other land vehicles?
 
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  • #2
Nuclear reactors can be made small and compact. With high-enriched Uranium you can make a reactor the size of a toaster (although its maximum power would be limited due to material constraints). I'm not sure how small steam turbines can be scaled down and still be efficient but I bet a tank-sized one would be possible. I think Ford actually conceptualized some sort of nuclear powered car in the 50's.

The problem is that shielding does not scale down as well. You still need heavy lead shielding and thick hydrocarbon materials to reflect neutrons. For a tank it might not be out of the question; but a car, in order to protect both the driver and the public, would be far too heavy.
 
  • #3
QuantumPion said:
Nuclear reactors can be made small and compact. With high-enriched Uranium you can make a reactor the size of a toaster (although its maximum power would be limited due to material constraints). I'm not sure how small steam turbines can be scaled down and still be efficient but I bet a tank-sized one would be possible. I think Ford actually conceptualized some sort of nuclear powered car in the 50's.

The problem is that shielding does not scale down as well. You still need heavy lead shielding and thick hydrocarbon materials to reflect neutrons. For a tank it might not be out of the question; but a car, in order to protect both the driver and the public, would be far too heavy.

Does it have to be a steam turbine and, not say, an air turbine? How many miles can you get and would the power output be enough say for reactive electromagnetic armor, electromagnetic gun, and drive train and onboard sensors and computers and electronics?

I guess the size of the nuclear reactor, along with shielding, would be the size of a M1 Abram's gas turbine engine. Use of electromagnetic armor and gun may reduce weigth of armor and size of projectiles allowing more room and weight for nuclear reactor and shielding.
 
  • #4
It isn't the turbine that is the concern (unless you come up with a BWR-like concept), you would want a PWR to remove heat from the core more quickly with less power needed for the pump. Mileage is a difficult thing to measure without reactor size, fuel enrichment, mass of the transport, among other things. The reactor with shielding would probably be much bigger than an Abram could carry. I'm not completely sure, but I think most of the back half of a nuclear powered submarine is for the plant and turbine.
 
  • #5
theCandyman said:
It isn't the turbine that is the concern (unless you come up with a BWR-like concept), you would want a PWR to remove heat from the core more quickly with less power needed for the pump. Mileage is a difficult thing to measure without reactor size, fuel enrichment, mass of the transport, among other things. The reactor with shielding would probably be much bigger than an Abram could carry. I'm not completely sure, but I think most of the back half of a nuclear powered submarine is for the plant and turbine.

If the tank was remote controlled and had no humans on board during military operation (obviously it needs maintance) could the shielding be considerably reduced?
 
  • #6
A tank is something that is going to be shot at, you'll want shielding regardless of whether people are in it or not.
 
  • #7
theCandyman said:
A tank is something that is going to be shot at, you'll want shielding regardless of whether people are in it or not.

with enough electrical power can't electromagnetic shielding be used? there's a colloidal solution with magentic-iron particles nanoparticles that cluster around electric fields forming extreme hardness.

then there's the emp gun
 
  • #8
You haven't addressed the heat removal aspect that Candyman brought up. What do a submarine and a fixed reactor have that a mobile vehicle doesn't have?
 
  • #9
I'm surprised no one mentioned Pamir. The former Soviet Union built (prototype) mobile reactors on large trucks - they were not self-propelled, but they were on wheels. Of course the conclusions in this thread are entirely correct - the system ran on HEU (45%), was very big (much larger than an ordinary tank), and used small gas turbines rather than steam turbines - with a very exotic working fluid, dinitrogen tetroxide (N2O4) gas.

http://www.nti.org/e_research/profiles/Belarus/Nuclear/facilities_sosny.html [Broken]
According to Belarusian nuclear scientists, the now-restructured Belarusian Institute of Nuclear Power Engineering (INPE) designed a mobile nuclear power reactor with a 700 kW capacity (according to Yermashkevich, 630 kW) and created a working model, called Pamir.[3,4] This reactor was designed for military purposes and for territories, such as the desert or tundra, where it is difficult to connect to an electricity grid. This mobile plant was designed to work in conditions from -50 degrees Celsius to +50 degrees Celsius without any water resources.[3] The Pamir reactor used uranium enriched to 45 percent U-235 for fuel, with nitrogen tetraoxide for the coolant. Tests were performed using critical assemblies and the model itself for at least 3,500 hours starting in 1985.[3,4,5] Approximately 60 emergency shutdowns took place, some of which resulted in the release of nitrogen tetraoxide and radioactive particles.[4] The project was scrapped in 1986 by a decision of the Belarusian government.

There's a longer description in a Russian-language news article:

http://translate.google.com/translate?hl=en&sl=auto&tl=en&u=http://news.tut.by/society/98447.html

359h9pj.jpg


It's quite far from being nuclear-propelled, if you consider the specs. The system takes up four large trucks, the reactor one weighing 60 tons - but the electric output is only 630 kW = 845 hp. (Experts - is it cooling that is the limiting factor here?)

I also found a related paper on the N2O4 Brayton cycle from 1979 - it makes extensive reference to Russian research:

"Potential performance improvement using a reacting gas (nitrogin tetroxide) as the working fluid in a closed Brayton cycle"

http://ntrs.nasa.gov/search.jsp?R=7...=false&qs=Ns=ArchiveName%7c0&N=4294946812+295

("reacting gas" means it dissociates during the thermodynamic cycle: N2O4 <--> 2 NO2.)

Perhaps you may be interested in nuclear propelled airplanes? The US designed such a system, and found it viable.

http://www.ornl.gov/info/ornlreview/rev25-34/net425.html [Broken]

There are photos of the test engines on wikipedia (they are located at Idaho National Lab):

800px-Aircraft_reactor_experiments_2001.jpg


http://en.wikipedia.org/wiki/Aircraft_Reactor_Experiment
 
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  • #10
berkeman said:
You haven't addressed the heat removal aspect that Candyman brought up. What do a submarine and a fixed reactor have that a mobile vehicle doesn't have?

How much heat does a toaster sized fission box need to have removed?
 
  • #11
ensabah6 said:
How much heat does a toaster sized fission box need to have removed?

According to wiki, an M1 Abrams tank's engine is 1500 HP. So at 30% thermodynamic efficiency, ~3700 kW. That's quite a bit of heat flux for a toaster! :)
 
  • #12
QuantumPion said:
According to wiki, an M1 Abrams tank's engine is 1500 HP. So at 30% thermodynamic efficiency, ~3700 kW. That's quite a bit of heat flux for a toaster! :)
good point
 
  • #13
QuantumPion said:
According to wiki, an M1 Abrams tank's engine is 1500 HP. So at 30% thermodynamic efficiency, ~3700 kW. That's quite a bit of heat flux for a toaster! :)
It might a bit more efficient than that, the Abrams uses a turbine engine - at least when running at full power it should exceed 30% efficiency.
 
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  • #14
While miniature nuclear reactors are interesting, miniaturization is not the main problem to my mind. The question is how does one make the reactor safe in the case of a catastrophic accident (or attack for a military vehicle) AND relatively useless from a weapons proliferation stand point. I don't know how to answer these two questions. What type of reactor would be most benign if the vehicle carrying it hit an IED or was hit by a train at a crossing? CANDU? Anyone?
 
  • #15
mheslep said:
While miniature nuclear reactors are interesting, miniaturization is not the main problem to my mind. The question is how does one make the reactor safe in the case of a catastrophic accident (or attack for a military vehicle) AND relatively useless from a weapons proliferation stand point.


I don't know how to answer these two questions. What type of reactor would be most benign if the vehicle carrying it hit an IED or was hit by a train at a crossing? CANDU? Anyone?

If you don't want the enemy to be able to steal your reactor and make it into a weapon, you can use reactor-grade plutonium (pu+239 + pu-240).

As for making a reactor sturdy enough to survive conditions related to warfare, I'd imagine some sort of self-contained metal cooled reactor would be best. But no matter what the design is, even if heavily shielded and protected, a direct hit from a big bomb or armor penetrating shell or what have you will ruin your day. :p
 
  • #16
QuantumPion said:
If you don't want the enemy to be able to steal your reactor and make it into a weapon, you can use reactor-grade plutonium (pu+239 + pu-240).
Alright, if we somehow lose reactor grade plutonium (> 19% Pu-240) that's been in an operational reactor, what's the difficulty in separating out the Pu-239 to weapons grade Pu? We want that to be at least hugely difficult if not impossible. Would it require a separation process on a grand scale requiring the resources of a nation state?

As for making a reactor sturdy enough to survive conditions related to warfare, I'd imagine some sort of self-contained metal cooled reactor would be best. But no matter what the design is, even if heavily shielded and protected, a direct hit from a big bomb or armor penetrating shell or what have you will ruin your day. :p
Well some of these small reactors (http://www.world-nuclear.org/info/inf33.html" [Broken]) are designed so that the fission reaction stops by default if the reactor gas/liquid metal flow stops for any reason, so that should eliminate the run away case. Then we're left with the escape to the atmosphere of what products? What dosage is possible?
 
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  • #17
mheslep said:
Alright, if we somehow lose reactor grade plutonium (> 19% Pu-240) that's been in an operational reactor, what's the difficulty in separating out the Pu-239 to weapons grade Pu? We want that to be at least hugely difficult if not impossible. Would it require a separation process on a grand scale requiring the resources of a nation state?

Separating Pu-240 from Pu-239 is much much harder than separating U-235 from natural uranium. If you had the technology to do isotopic separation to begin with you wouldn't bother trying to separate highly radioactive reactor fuel when you can dig uranium out of the ground.

mheslep said:
Well some of these small reactors (http://www.world-nuclear.org/info/inf33.html" [Broken]) are designed so that the fission reaction stops by default if the reactor gas/liquid metal flow stops for any reason, so that should eliminate the run away case. Then we're left with the escape to the atmosphere of what products? What dosage is possible?

Depends on many factors, such as the fuel composition, burnup, and how it is dispersed. I wouldn't want to be anywhere nearby though. :p
 
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  • #18
What about if they boost the efficiency of a beta-voltaic type battery, or nuclear thermal battery. You might eventually reach a power density where it could propel a car or something, without having to worry about a full reactor that can runaway. Just crazy drivers and accident lawsuits.


If my deadly nuclear tank gets hit on enemy territorry, dosage from leaking fuel elements is their problem. (evil laugh).
 
  • #19
QuantumPion said:
Separating Pu-240 from Pu-239 is much much harder than separating U-235 from natural uranium. If you had the technology to do isotopic separation to begin with you wouldn't bother trying to separate highly radioactive reactor fuel when you can dig uranium out of the ground.
This seems to suggest that reactor grade Pu presents no proliferation risk. Yet Pu output from commercial nuclear operations is cited as a proliferation risk, by e.g. the MIT Nuclear report.

QuantumPion said:
Depends on many factors, such as the fuel composition, burnup, and how it is dispersed. I wouldn't want to be anywhere nearby though. :p
Well I wouldn't want to be anywhere near a 500,000 gal fuel depot that was attacked, but we consider that an acceptable risk - a baseline if you will. I'm curious in weighing the risk against such a baseline for smallish reactors.
 
  • #20
mheslep said:
This seems to suggest that reactor grade Pu presents no proliferation risk. Yet Pu output from commercial nuclear operations is cited as a proliferation risk, by e.g. the MIT Nuclear report.

There's still a large amount of Pu-239 in reactor grade fuel, more than 50% if I remember right. It would be very difficult and require a lot of energy, but it could be separated out. Also, Pu-240 is fertile, so if it could potentially be used as well.
 
  • #21
Other than reducing the need to re-fuel, why would you want a nuclear fueled tank? It seems the risks would outweigh the benefits.
 
  • #22
theCandyman said:
There's still a large amount of Pu-239 in reactor grade fuel, more than 50% if I remember right. It would be very difficult and require a lot of energy, but it could be separated out.
I'm sure its possible given the resources. The idea here is to assess the risk, level of difficulty. [/QUOTE]I believe it is safe to say from what I've read here that if one tossed a lump of mixed Pu into Bin Laden's cave, it would utterly useless to him as a fissile weapon.

Also, Pu-240 is fertile, so if it could potentially be used as well.
Well the only useful decay path is to Pu-241. Then given a small reactor w/ a small fuel load of 240, one would have to wait ~6000 years to get half as much 241. Maybe neutron bombardment in a reactor would accelerate that route?
 
  • #23
WhoWee said:
Other than reducing the need to re-fuel, why would you want a nuclear fueled tank? It seems the risks would outweigh the benefits.

How would you power electro-magnetic armor, electro-magnetic shield, electro-magnetic guns, plasma guns, laser guns, microwave heat rays?
 
  • #24
You might be able to do it with separate gas turbine for power and a large fuel supply. It depends on what you want to do with it.
 
  • #25
ensabah6 said:
How would you power electro-magnetic armor, electro-magnetic shield, electro-magnetic guns, plasma guns, laser guns, microwave heat rays?

Maybe a space-based system would be better than a fleet of nuclear powered tanks?
 
  • #26
mheslep said:
This seems to suggest that reactor grade Pu presents no proliferation risk. Yet Pu output from commercial nuclear operations is cited as a proliferation risk, by e.g. the MIT Nuclear report.

Reactor grade Pu cannot be made into a bomb. In order to get weapons-grade Pu from a commercial reactor, it has to be a plant type that allows for online-refueling. Mainly, a RBMK-type reactor (although it might be possible with a CANDU as well, I'm not sure).

Without having read the MIT report I would venture to say it is baloney. Why are they concerned about western nations (whom already have nuclear weapons) diverting reactor fuel for weapons (which no one does as far as I know). The real, actual risks for proliferation lie with Iran and North Korea, whom we know are trying to make weapons. Yet no one wants to do anything about them. How is banning reprocessing of fuel in the United States, while ignoring Iran's uranium centrifuges make sense? Ok I'm done ranting now. :)
 
  • #27
QuantumPion said:
Reactor grade Pu cannot be made into a bomb. In order to get weapons-grade Pu from a commercial reactor, it has to be a plant type that allows for online-refueling. Mainly, a RBMK-type reactor (although it might be possible with a CANDU as well, I'm not sure).

Without having read the MIT report I would venture to say it is baloney. Why are they concerned about western nations (whom already have nuclear weapons) diverting reactor fuel for weapons (which no one does as far as I know). The real, actual risks for proliferation lie with Iran and North Korea, whom we know are trying to make weapons. Yet no one wants to do anything about them. How is banning reprocessing of fuel in the United States, while ignoring Iran's uranium centrifuges make sense? Ok I'm done ranting now. :)

Reprocessing inevitably increases the amount of stored Pu in the world. The current PUREX/MOX process produces weapons usable Pu. The authors associate some non-zero risk with each kg - that it can fall into the wrong hands. Small risk perhaps, but its not baloney.
http://web.mit.edu/nuclearpower/"
From the http://web.mit.edu/nuclearpower/pdf/nuclearpower-summary.pdf":

I posted a summary earlier:
https://www.physicsforums.com/showpost.php?p=1723712&postcount=201

BTW:
QP said:
Iran and North Korea...Yet no one wants to do anything about them.
Hyperbole
 
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  • #28
How about that for a deterrence weapon? "No, of course we're not carrying WMDs into battle. Yes, our nuclear tanks, when hit, will explode but it won't be like an atomic bomb. More like a dirty bomb, irradiating the land and rendering it unhabitable for the next thousand years."
 
  • #29
oops double post.
 
  • #30
mheslep said:
Reprocessing inevitably increases the amount of stored Pu in the world. The current PUREX/MOX process produces weapons usable Pu. The authors associate some non-zero risk with each kg - that it can fall into the wrong hands. Small risk perhaps, but its not baloney.
http://web.mit.edu/nuclearpower/"
From the http://web.mit.edu/nuclearpower/pdf/nuclearpower-summary.pdf":

I posted a summary earlier:
https://www.physicsforums.com/showpost.php?p=1723712&postcount=201
Reprocessing doesn't magically create plutonium out of nothing. It extracts it from spent fuel, the isotopic mix of which is such that it can never be used for a bomb. In fact, if we were to reprocess fuel more, then that plutonium would become increasingly less capable of being used for a weapon each time it was recycled, as the relative concentration of Pu-242 would gradually increase.

mheslep said:
BTW:Hyperbole

So what argument do you have that my statement was hyperbole? You haven't addressed it at all.

Iran just announced they had even more uranium centrifuges then anyone (even the vaunted UN) knew about, on the eve of the United States president announcing his wish to get rid of all nuclear weapons. And no one has done anything about it. North Korea made a reactor to produce weapons plutonium after promising they would not, when the UN knew what they were up to nothing was done in that case either.

The UN clearly has no intention of acting to prevent other countries from producing weapons grade material and nuclear weapons. So why are they concerned about Western nations reprocessing reactor fuel?
 
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  • #31
QuantumPion said:
So what argument do you have that my statement was hyperbole? You haven't addressed it at all.

QuantumPion said:
...The real, actual risks for proliferation lie with Iran and North Korea, whom we know are trying to make weapons. Yet no one wants to do anything about them. How is banning reprocessing of fuel in the United States, while ignoring Iran's uranium centrifuges make sense? Ok I'm done ranting now. :)

mheslep said:
BTW:Hyperbole

QuantumPion said:
So what argument do you have that my statement was hyperbole? You haven't addressed it at all.

Iran just announced they had even more uranium centrifuges then anyone (even the vaunted UN) knew about, on the eve of the United States president announcing his wish to get rid of all nuclear weapons. And no one has done anything about it.
This is off topic, but I can't find an appropriate Iranian nuclear program thread.

Using the unarguable 'no one wants' instead of the arguable 'no one has done' is a textbook case of hyperbole, as I think you must know. It's inflammatory, leading off to another locked thread. Reverting to at least the arguable, what would qualify as something being 'done' in your mind? BTW, one won't find any apologizing for Iranian nuclear efforts and threats in my posts historically, but this kind of hand waving about nobody wanting to do anything is annoying. It reflects a lack of investigation into what has been done, what can be done in the future, and it indicates at least a disinterest in the consequences of more drastic action.Edit: Brief timeline on what has been done vis Iran:
2005: IAEA finds Iran in breech of IPT, reports out to UN SC
1. Finds that Iran’s many failures and breaches of its obligations to comply with its NPT Safeguards Agreement, as detailed in GOV/2003/75, constitute non compliance in the context of Article XII.C of
the Agency’s Statute;
2. Finds also that the history of concealment of Iran’s nuclear activities referred to in the Director General’s report,...
http://www.iaea.org/Publications/Documents/Board/2005/gov2005-77.pdf

2006: UN SC passes resolution 1737 by unanimous vote, imposes multilateral sanctions

2007: UN SC 2nd round of sanctions
http://www.globalpolicy.org/component/content/article/202-sanctions/41855.html
 
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  • #32
mheslep said:
This is off topic, but I can't find an appropriate Iranian nuclear program thread.

Using the unarguable 'no one wants' instead of the arguable 'no one has done' is a textbook case of hyperbole, as I think you must know. It's inflammatory, leading off to another locked thread. Reverting to at least the arguable, what would qualify as something being 'done' in your mind? BTW, one won't find any apologizing for Iranian nuclear efforts and threats in my posts historically, but this kind of hand waving about nobody wanting to do anything is annoying. It reflects a lack of investigation into what has been done, what can be done in the future, and it indicates at least a disinterest in the consequences of more drastic action.


Edit: Brief timeline on what has been done vis Iran:
2005: IAEA finds Iran in breech of IPT, reports out to UN SC

http://www.iaea.org/Publications/Documents/Board/2005/gov2005-77.pdf

2006: UN SC passes resolution 1737 by unanimous vote, imposes multilateral sanctions

2007: UN SC 2nd round of sanctions
http://www.globalpolicy.org/component/content/article/202-sanctions/41855.html

You keep using the word hyperbole but I don't think you know what it means. Hyperbole, for example, is when someone says "it's a billion degrees outside" on a hot summer day.

When I said the world has done nothing about Iran and North Korea, that is a statement of fact. While the UN have made sanctions, no action has been taken to prevent either country from continue to develop nuclear weapons. Your two linked articles are from 2005 and 2006 which go on about how the NIE report proves that Iran posed no proliferation risk. That report was proved to be laughably false in the wake of Iran's announcement of weapons enrichment this year.

Anyway, this has gotten off topic and I'm done arguing about it. You still keep using this red herring and ignoring the original issue - which is about fuel reprocessing. If you want to pose some sort of actual argument on this matter I'll be happy to address it, but otherwise I am done.
 
  • #33
QuantumPion said:
You keep using the word hyperbole but I don't think you know what it means. Hyperbole, for example, is when someone says "it's a billion degrees outside" on a hot summer day.
Or, its when some says "Yet no one wants to do anything about them", your original statement, since you can't possibly know what everyone wants to do, nor even know what everyone has done.
 
  • #34
You could fit a reactor in a tank. You just need to take a page from the Germans and go big like the P. 1000 Ratte, or the P.1500 Monster. I definitely would not want to be on the business end of a 1000 to 1500 tonne tank.
 
  • #35
This thread is a little too silly for PF. Locked.
 

1. Can a tank or land vehicle be powered by nuclear energy?

Yes, it is possible for a tank or land vehicle to be powered by nuclear energy. In fact, several countries have developed and tested nuclear-powered tanks in the past.

2. What are the benefits of using nuclear power in tanks or land vehicles?

One of the main benefits of using nuclear power in tanks or land vehicles is that it provides a nearly unlimited source of energy. This means that the vehicle can operate for extended periods of time without needing to refuel. Additionally, nuclear power is more efficient and produces less emissions compared to traditional fossil fuel-powered vehicles.

3. Are there any safety concerns with using nuclear power in tanks or land vehicles?

While there are safety concerns with any use of nuclear energy, proper precautions can be taken to ensure the safety of nuclear-powered tanks and land vehicles. These include rigorous training for operators, proper maintenance and monitoring of the nuclear reactor, and strict safety protocols in case of accidents.

4. How does a nuclear-powered tank or land vehicle work?

Nuclear-powered tanks and land vehicles use a small nuclear reactor to generate heat, which is then used to produce steam. The steam is then used to power a turbine, which in turn drives the vehicle's engine. This process is similar to how nuclear power plants generate electricity.

5. What are the challenges of using nuclear power in tanks or land vehicles?

One of the main challenges of using nuclear power in tanks or land vehicles is the size and weight of the nuclear reactor. This can make the vehicle larger and less maneuverable. Additionally, the cost of developing and maintaining a nuclear-powered vehicle can be high. There are also concerns about the safe disposal of nuclear waste from these vehicles.

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