NationStates Jolt Archive

TransURanic Atomic Power and Nuclear Services Corporation
http://xs135.xs.to/xs135/09040/uranium_atom750.gif
"Quality engineering without compromise."

In the wake of the Clandonian Nuclear Excursion, the worst nuclear disaster in world history, the Spizanian and Izistani governments decided to form a joint-venture for-profit organization dedicated to the production of safe, affordable electrical power for the good of the world. This goal would be met by the mutual nuclear engineering experience of both nations and a desire to prevent another disaster on the scale of the one that rendered Clandonian Southern Haven a wasteland.

TURatomic is the result of that cooperation. We are one of the most skilled nuclear engineering firms in the world, with continuing cutting edge research ongoing at the TURatomic Advanced Nuclear Engineering Facility at the University of Battleford.

Reactors.

Exotic.

HEXPSR subcritical photodisintegration breeder reactor. (http://forums2.jolt.co.uk/showpost.php?p=14440062&postcount=2)

Power Generation.

WCCR-1050 Nuclear Reactor 1050 GWe water cooled, carbon-moderated. (http://forums.jolt.co.uk/showpost.php?p=14464769&postcount=27)

Plutonium Production.

NUR-50000 MWe gas cooled, natural uranium reactor. A massive scale up from the NUR-50. Also produces enough Pu-239 to build 6,000 thermonuclear bomb triggers a year! (http://forums2.jolt.co.uk/showpost.php?p=14447703&postcount=15)

Research and Training.


NUR-50 50 MWe gas cooled, natural uranium reactor. Don't have any reactors? Start here! (http://forums2.jolt.co.uk/showpost.php?p=14440401&postcount=6)


Warranty.

All of our reactors come with a 20 year warranty for maintenance or systems upgrade (for a nominal fee, we will match competitors prices). Warranty extensions may be paid for at any time.

Demolition Services.


Need a canal dug really fast? How about a harbor? Blow a pass through the mountains? Divert rivers? Dig a really big ditch? Ask about our sequential nuclear explosion civil engineering programs! Our engineering charges are all designed to limit neutron activation through Hafnium radiation cases, and we'll provide weather and fallout migration services!

Decommissioning and Clean up.

Special Purpose Projects.

Fuel Services.


Reactors in operation/under construction!
Merkonian HEXPSR's: Psychlum Reactor Plant, Derstadt Reactor Plant, Derstadt Reactor Plant #2
Chazakain NUR-50's: Phegues Reactor #1 and Reactor #2, Oceanus Reactor #1, Axion Reactor #1, Aegir Reactor #1, Helios Reactor #1, Ochun Reactor #1 and Reactor #2, Nix Reactor #1 and Reactor #2.
Izistani NUR-50000's: Reactors A and B, located at the Sakharov National Special Production Facility.

HEXPSR

High Energy X-ray Photodisintegration Subcritical Reactor.

A subcritical reactor developed off the pioneering Howell/Popov PDUHR-1 photodisintegration reactor developed at the University of Battleford. HEXPSR is a subcritical breeder reactor optimized for the production and enrichment of fissile material.

Abstract

Betatron accelerated electrons at 300 MeV are decelerated by a magnetic field in the core of the reactor. This produces gamma rays. The liner and outer layer of the fuel "drum" (really four separate curved fuel elements are composed of depleted uranium. When the gamma ray interacts with the DU liner, causing photodisintegration of the DU, a cascade of neutrons is produced. As a subcritical reactor, the HEXPSR is inherently safe, cutting the power to the Betatron or turning it off stops the nuclear reaction.

What can I use it for?

1) Conversion of depleted uranium into fissile plutonium or uranium-233 with minimum loss in the process.

2) -Generation of tritium through neutron bombardment of heavy water.

3) The DU liner can be replaced by any heavy metal (atomic mass over 55) for breeding useful isotopes.

4) Concealable covert production of highly enriched uranium.

How much is this going to cost me?

$250 million universal standard dollars or equivalent sum.

Advances in plasma wake field acceleration hold the promise of a compact 50 GeV acceleration system. This system will eventually be available with HEXPSR II and promises increased efficiency and significant decreases in size and cost.

To: TransURanic Atomic Power Corporation
From: The Federation of Merkonia, Agriculture and Energy Department

The Federation of Merkonia is interested in purchasing three of your HEXPSR systems. We were wondering if construction for the systems could be done by TransURanic Atomic Power employees to insure the best possible construction.

We will pay a total of $ 1.3 Billion (USD) for the construction of these three reactors.

Thank you,

Dr. Ursal Timor

To: TransURanic Atomic Power Corporation
From: The Federation of Merkonia, Agriculture and Energy Department

The Federation of Merkonia is interested in purchasing three of your HEXPSR systems. We were wondering if construction for the systems could be done by TransURanic Atomic Power employees to insure the best possible construction.

We will pay a total of $ 1.3 Billion (USD) for the construction of these three reactors.

Thank you,

Dr. Ursal Timor

To: The Federation of Merkonia, Agriculture and Energy Department
From: TransURanic Atomic Power Corporation, Export Operations.

It would be no trouble at all for our contractors to construct the reactors. The most complex part of them in fact, is the betatron. But as those are basically modified electrical transformers our electrical engineering division should have little trouble coming up with a knocked down solution. In addition, we'll provide training to whatever workers you want.

Incidentally if you have need of any reactors, we've got a really nice gas cooled reactor, the NUR-50, runs off natural uranium and produces plutonium as a waste process (Fuel Services can handle reprocessing and such for you if you want).

To: TransURanic Atomic Power Corporation
From: The Federation of Merkonia, Agriculture and Energy Department

What does the NUR-50 cost, installation included?

Furthermore is it possible to modify the HEXSPR system to produce enriched Uranium-235? If not do you currently support a system that can produce U-235, also U-238 is of great interest to the Merkonian government.

Thank you,

Dr. Ursal Timor

TURatom NUR-50 Nuclear Reactor
TURatom Natural Uranium Reactor-50MWe
Abstract
In this age of increasing electricity consumption, the NUR-50 will provide small to medium sized communities an electricity supply that is not dependant on a grid which is inefficient and is deployed mainly to give continious supply to those in cities, who tend to be the largest users of electricity, in addition grid maintainance is expensive, and this expense is likely to be heaped disproportionately on rural users.

The other major market is for nations who are just making their first tentative forays into reactor technology for power generation, and who wish to purchase a small reactor with which to develop a trained core of personell familiar with the vagaries of practical reactor operations in the modern era. As such the reactor is designed to use natural uranium fuel to reduce the requirement for massively expensive enrichment operations that may increase the cost of fuel to beyond the reach of a new entrant into the field.

Finally this reactor will product approximately 2kg of weapons Grade Pu-239 per tonne of fuel irradiated, which combined with the 12 tonne annual fuel consumption of the reactor, will allow for some 24kg of Plutonium to be produced from natural uranium fuel per year, which is sufficient for a startup nuclear program if the country wishes to undertake one.

Fuel Elements
The fuel bundles, of which there are 300 in the reactor, contain approximately 20kg of natural uranium metal inside 43 identical zirconium-alloy tubes, the fuel itself being formed numerous cast uranium metal pellets. The fuel elements, similar to those used in Heavy Water moderated CANDU type reactors, are approximately half a metre in length and approximately ten centimetres in diameter, weighing in at approximately 22kg, with two zircalloy plates welded to the ends of the bundle to facilitate partial gas seal during refueling/defueling operations.

The fuel elements are capable of a burn up of approximately 4.5GWd/MTU [Gigawatt-days per metric tonne of Uranium] and are changed half yearly, while this fuel irradiation is a small fraction of that of common Generation III PWRs or similar, which now attain 60GWd/MTU, the fuel contains a higher percentage of Pu-239[<90%], which is useful both for the production of higher grade MOX fuel or for use in nuclear weapons for defence purposes, in addition the fuel for this reactor does not require enrichment, reducing costs substantially for those who do use large amounts of enriched uranium fuel.

Reactor Design
The reactor core itself is approximately four metres tall, four metres wide and about 6 metres long, consisting primarily of a array of graphite blocks, some of which have been machined to contain the channels used to carry the fuel and coolant through the reactor. The coolant channels are approximately five centimetres in diameter and are spread throughout the moderator mass, whereas the fuel channels are the requisite 10cm in diameter with 1cm deep and wide slots cut into them at sixty degree intervals to allow carbon dioxide to return between the end plates of the fuel elements during ordinary operation, with carbon dioxide passing through both the special cooling channels and the fuel channels, improving cooling of both elements.

All the fuel channels are cooled in the direction of fuel travel from the charge face to the discharge face, with the cooling channels in the moderator counterflowing/flowing in a proportion required to provide equal coolant flow in both directions, with the flowing and counterflowing coolant channels distributed throughout the moderator mass.

The reactor is situated snug with the inner containment structure, which runs the length of the rectangular building, being approximately three thick metre thick ferroconcrete, with both of the ends blocked off by additional fifty centimeter thick walls lead doped ferroconcrete walls, which contain two addition fuel bundles per channel, one not having been exposed to the nuclear reaction, and the other undergoing cooling following the reaction, this first wall is also penetrated by the cooling channels, ensuring that the bundle undergoing preliminary cooling does not overheat during its two week stay.

There are twelve control rod channels, penetrating the reactor vertically, at staggered intervals in such a manner that ten of them are capable of shutting the reactor down completely, by absorbing sufficient neutron flux to strangle the already borderline chain reaction, they consist of conventional hafnium alloy rods, controlled in normal operation by the automatic reactor computer using a rapid worm and screw mechanism, which is clutch detachable to allow the fuel rods to be completely inserted in approximately a tenth of a second when the emergeancy water pressure based release mechanism is activated, with water pressure being provided by a water tower located above the reactor structure, directly above the hump in the containment building associated with the reactors 4 metre long control rods.

There are 25 fuel channels, arranged in five rows of five, with each channel containing twelve bundles of fuel at any one time [with an additional two which are in the channel but outside the reactor]. To reload the fuel channel, which typically occurs every fifteen days, the two robotic assemblages posistioned on the charge and discharge face maneuvre a bundle holder to the correct channel and both activate seals which press the holder against the face and prevent venting of high temperature coolant gas during the fueling procedure.

The gate on the appropriate channel [a tungsten alloy plate on the outer face of the concrete containment walls] is now opened and the fresh fuel bundle is inserted into the channel using an EM ram, while at the opposite end of the reactor, the fuel bundle that had been undergoing preliminary cooling will be forced from the channel into the discharge face holder, the gate is then closed and the gas seal broken, the pre cooled rod, still at 390 degrees celsius is then taken to the spent fuel pond, which is situated immediately beyond the discharge face, and lowered into the appropriate rack for its one year storage period. The machine is capable of achieving these operations without any additional human supervision beyond that which is normally situated in the reactor control room. The reactor would in normal course of operations conduct this procedure approximately once every fourteen and a half hours.

Steam Generation Equipment
The reactor system possesses two steam generators, one at each end of the stack, located at the ends of the primary containment structure, with one immediately "infront" of the charge face machinery, and the other located beyond the cooling pond system at the back of the primary containment structure, carbon dioxide from the cooling and fuel channels is athered inside the ferroconcrete shield at the appropriate face of the reactor and passes through one of two shielded insulated conduits in the roof of the reactor building over the intervening machinery, here it is used in a steam generator to produce steam at 360 degrees celsius (reactor carbon dioxide outlet temperature is 390 degrees) before being returned to the reactor core and passed through the opposing direction coolant channels with a reentrant temperature of approximately 270 degrees, sufficiently high to prevent significant buildup of Wigner energy in any part of the reactor, increasingly stability and safety.

Each one of these steam generators consumes approximately half of the reactors 150MW thermal output and passes through approximately 24kg of water and 694kg of Carbon Dioxide per second, transforming the former into steam at approximately 360 degrees, with the later being pumped through using a pair of high pressure pumps powered either directly from the turbine sets or by backup diesel generators in an emergeancy or during a scheduled shutdown procedure, which are capable of being up to speed in approximately six seconds.

Turbine and Secondary Containment Building
The steam from each steam generator is fed through the sides of the steam generator rooms out of the primary containment structure into the secondary containment building, which exists purely to act as a secondary biological shield and to contain any radioactivity in the course of a reactor accident, although such an accident would require the reinforced concrete primary shield to have been breached, it also contains the area where fuel that has been removed from the cooling pond, [which is located in the primary coolant structure and nominally contains the fuel irradiated in the previous year, approximately 12 tonnes in the form of 600 bundles for nominal output] are loaded into canisters for transport by road rail or sea to the reprocessing facility, and the turbine hall, where the pair of 25MWe Turbine Sets are located, which approach nearly 75% of possible carnot efficiency, before passing the now saturated 100 degree celsius steam to a condensing heat exchanger before the water passes back into the primary containment structure and back to the steam generators

Secondary Cooling System
Since the reactor has the relatively low operating temperature of 390 degrees celsius, maximum carno efficiency is approximately 40%, while in the real world non-ideal case the reactor manages approximately 33% efficiency, producing a 50MWe output from the 150MWt produced by the reactor itself, although the additional 100MW Of low grade heat could be discarded into the sea or into a cooling tower, this would be exceptionally wasteful, and either be damaging to the enviroment, in the case of the former, or require an expensive cooling tower, in the case of the later. So in this design the hot water, heated by the condensor, is fed from the secondary containment structure to a secondary building, which can contain one of the following (if the reactor is built by TURatom services on a standard contract).

1] A Multi Stage Flash (MSF) Desalination Plant with a capacity of approximately 1100kg of water per second
2] A District Heating Program with an output of 100MW (obviously?)
3] An Absorption Refrigerator with an effectively 45000 "Tons of Refrigeration", for use in freezing fish type products or similar foodstuffs, in a tropical environment

Emergeancy Procedures
In the event of an emergeancy, the four diesel powered coolant pumps can be at full output in approximately six seconds, while the control rods can be introduced to hard-stop a fission reaction in a tenth of a second, after this has occured the fuel rods are locked into posistion until the plant control officer releases them to move again, the water from the compressed water tower is then used in an emergeancy evaporative coolant mechanism, bypassing the steam turbine set, and boiling in a special array located in both steam generator rooms, the water provided in the pressure tower being sufficient to cool the shut down reactor to the point where thermal core damage is no longer an issue, and maintain said cooling against radioactive decay for over an hour, giving time for additional cooling to be provided, although the core can survive in this stage, even with only conduction and convection based cooling in both the carbon dioxide and secondary loops indefinately.

Pricing:
$85 million for construction using own labour force + $15 million for plant designs and licences for one reactor = $100 million
$95 million for TURatom Personel Construction, in partnership with local engineering firm, including tertiary heat recycling component = $95 million

To: TransURanic Atomic Power Corporation
From: The Federation of Merkonia, Agriculture and Energy Department

Interesting. If all goes well with the HEXSPR I will likely be inclined to purchase 5-8 of these reactors to supply Merkonians with environmentally safe energy production.

Thank you,

Dr. Ursal Timor

To: TransURanic Atomic Power Corporation
From: The Federation of Merkonia, Agriculture and Energy Department

What does the NUR-50 cost, installation included?

Furthermore is it possible to modify the HEXSPR system to produce enriched Uranium-235? If not do you currently support a system that can produce U-235, also U-238 is of great interest to the Merkonian government.

Thank you,

Dr. Ursal Timor

To: The Federation of Merkonia, Agriculture and Energy Department
From: TransURanic Atomic Power Corporation, Export Operations.

Enriching U-235 is pretty simple and it is well within the technical capabilities of the HEXSPR. As for the U-238, basically 99% of natural uranium is composed of it. The NUR is well suited for this particular task, a full load out of eight reactors would produce 192 kilograms of Pu-239 a year: a simple high efficiency, tritium boosted, tactical weapon of 20 kilotons would require about 2 to 2.5 kilograms of Pu-239. Ergo something like ~75 of these bombs could be theoretically produced a year.

We await your decision on the NUR-50's.

[Also Spiz wants to know if you could furnish us with the power plant names cause we wanna put a big list of OMG LOOK AT THESE REACTORS GUYS :p ]

To: TransURanic Atomic Power Corporation
From: The Chazakain Kingdom, Energy Department

The Chazakain Kingdom is interested in purchasing ten of your HEXPSR systems.
We are also interested in contracting your employees to build the plants.
We are willing to offer an additional 100 million dollars per plant for this making our subtotal $3,500,000,000.

We also wish to purchase 10 TURatom NUR-50 Nuclear Reactors using this scheme:
Pricing: $85 million for construction using own labour force + $15 million for plant designs and licences for one reactor = $100 million
for a subtotal of $1,000,000,000

Our total will be 4.5 Billion USD, with half of the money being wired upon confirmation of order and the remainder after the plants become operational.

To: TransURanic Atomic Power Corporation
From: The Federation of Merkonia, Agriculture and Energy Department

The HEXSPR names are as follows: Psychlum Reactor Plant, Derstadt Reactor Plant, Derstadt Reactor Plant #2

[OOC: Simple I know, lol]

To: The Chazakain Kingdom, Energy Department.
From: TransURanic Atomic Power Corporation, Export Operations.

We had the damnedest feeling we'd hear from you. At any rate, we have zero problems with the transaction and our workers should be able to easily assemble the HEXPSR's in a matter of months with prefabricated parts and concrete! If you need any help reprocessing the fuel or extracting the Pu-239, we can help with that as well. We could also aid in the manufacture of any "peaceful nuclear devices"*cough* you might require.


[If you could supply a list of the power plant names that'd be great. :D Also readers may be interested in our coming reactors designed for optomized production of steam to crack hydrocarbons (waste treatment? more like sewage to oil with no fancy deploymerization or bacteria), disposal of plastics (into fuel), capturing and turning atmospheric CO2 into syngas to turn into oil (LOL BLOCKADES CAN SUCK IT). Oh, and heating/cooling a entire city!

And the 500 GWe monster that will turn entire rivers into fish and plant farms (not just rice paddies!) as a byproduct of its cooling cycle!!]

Encryption Level: Experimental (Quantum encryption)
To: TransUranic Atomic Power Corporation
From: private@eddnet.tee, private@milnet.tee (EDDP to TCP/IP bridge)
Subject: A business proposal for your perusal.

http://upload.wikimedia.org/wikipedia/commons/thumb/3/3b/A3.JPG/117px-A3.JPG
EconNet Atomic Consortium

http://www.nationstates.net/images/flags/uploads/solar_communes.jpg
Milnet Orbital Solutions

As nearly a hundred percent of the demanding energy needs of the Confederacy of Third Spanish States are supplied by nuclear power, the Atomic Consortium is always seeking potential breakthroughs in the field to allow more efficient power generation with reduced radioactive byproducts, and hopefully practical fusion power in the next two decades. However, due to the critical dependence on nuclear power of the Confederacy, we unfortunately cannot allow technological dependence over foreign companies to attend such critical need for any modern civilization.

Instead, what we seek is a joint research and knowledge trade deal to combine our expertises. The Atomic Consortium speciality is, beyond some of the, if not the best softwares for nuclear power management, to adapt safe fission power infrastructure to highly sensitive habitats like enclosed arcologies, floating cities and submerged towns, where even the slightest mistake might bring disastrous and conditions demand different engineering challenges. With the success of enclosed life support system experiments in the Tienda del Coche Automobile Federation Arcology, and the potential venues of applications of nuclear power that will certainly come in the short and medium-term future, coupled with the dwindling supplies of fossil fuels, we have joined efforts with the local Milnet Orbital Solutions to start a new project, and after reviewing the qualifications of your company, we believe you may be excellent partners in this scientific endeavor. Solar power has always been limited, and although it suffices for now ubiquitous applications like satellites, we believe it is time to step further in the development of outer space. This project I mention, named Rain, seeks to develop a high performance template nuclear powerplant, and all additional required infrastructure, made specifically for orbital applications from orbital manufacture facilities that shall serve for, in the medium and long term, the construction of spacecrafts propelled by nuclear power among other potential applications, to allow the Confederacy to thrive from such untapped potential for other purposes beyond the military facilities of the Orbital Forces, and to prepare for the next centuries.

If you are interested in either offering contractors to support this project or joining it to gather the fruits of its end results, please reply back. We would welcome the services of your engineers in exchange of either monetary payment or know-how, depending on what you prefer, and particularly of those who participated of the HEXPSR, as we need to establish the foundations of an entire orbital infrastructure, as self sufficient as possible, and considering our current costs for launching materials, an orbital facility for enriching depleted fissiles was deemed a practical possibility.

Edward Perlman
Engineer

(*OOC Edit: I know bull about this stuff, so if there is something blatantly absurd, treat it as an OOC mistake rather than as an IC one)

To: TransURanic Atomic Power Corporation, Export Operations.
From: The Chazakain Kingdom, Energy Department.

Ah so you have heard of our other projects, we very well may be seeking your expertise for it. but on to the names.

Phegues Reactor #1 and Reactor #2, Oceanus Reactor #1, Axion Reactor #1, Aegir Reactor #1, Helios Reactor #1, Ochun Reactor #1 and Reactor #2, Nix Reactor #1 and Reactor #2.
map of chazakain with a list of cities (http://i268.photobucket.com/albums/jj31/chazsapphire/ChazakainCitiesMark2.png)

Encryption Level: Experimental (Quantum encryption)
To: private@eddnet.tee, private@milnet.tee (EDDP to TCP/IP bridge)
From: From: TransURanic Atomic Power Corporation, Board of Directors, r. Semyon Popov.
Subject: Re: A business proposal for your perusal.

Given the conditions you require the facilities to operate in, the subcritical nature of the HEXPSR is perfect. Combined with a suitably large solar thermal power supply and plasma wakefield acceleration...it should be easy to produce all the fissile material you require. Easier then a breeder, the radiator requirements are far better (I'd still recommend lithium droplet radiators).

You might want to base the operation out at L1 however, not only does this prevent radioactive contamination in the event of reentry, and LEO debris damage (let alone Kessler...), but it puts you in a superior position for access to lunar thorium deposits! I'm confident that this facility could operate autonomously as well.

I will have to confer with Dr. Howell, but I can't see any objection to the development of this.

TURatom NUR-50000 Nuclear Reactor

Abstract
This reactor, the largest planned output reactor in the NUR series, will produce vast quantities of electrical and thermal energy, easily sufficient for all but the largest cities, using little more than natural uranium fuel, providing cheap electricity as well as performing essential production of weapons grade Pu-239 for military or civilian purposes, in addition the short irradiation time will increase the purity of the available medical isotopes, increasing their value to medical and research customers.

The reactors basic operation is designed to be similar to that of the smaller members of the family, to allow personel that gained experience with the smaller, and some would say saner, members of the family to operate this, monster, design with minimal additional training, saving time and money in bringing the reactor to operational status and keeping it that way.

Like the other members of the NUR family, this reactor will product approximately 2kg of weapons Grade Pu-239 per tonne of fuel irradiated, which combined with the 12000 tonne annual fuel consumption of the reactor, will allow for some 24 tonnes of weapons grade Plutonium to be produced from natural uranium fuel per year, which is sufficient for all but the most excessively sized nuclear weapons program, allowing for the production of 6,000 typical thermonuclear trigger devices to be produced in a year, from this one reactor alone.

Fuel Elements
The fuel bundles, of which there are 300,000 in the reactor, contain approximately 20kg of natural uranium metal inside 43 identical zirconium-alloy tubes, the fuel itself being formed numerous cast uranium metal pellets. The fuel elements, similar to those used in Heavy Water moderated CANDU type reactors, are approximately half a metre in length and approximately ten centimetres in diameter, weighing in at approximately 22kg, with two zircalloy plates welded to the ends of the bundle to facilitate partial gas seal during refueling/defueling operations. The fuel elements are capable of a burn up of approximately 3.5GWd/MTU [Gigawatt-days per metric tonne of Uranium] and are changed half yearly, while this fuel irradiation is a small fraction of that of common Generation III PWRs or similar, which now attain 60GWd/MTU, the spent fuel contains a higher percentage of Pu-239[<90%], which is useful both for the production of higher grade MOX fuel or for use in nuclear weapons for defence purposes, in addition the fuel for this reactor does not require enrichment, reducing costs substantially considering the amount of fuel expended. In addition, unlike its smaller cousins the reactor is cleared to use 1% Plutonium/Reprocessed Natural Uranium Mixed Metallic Fuel (1% PRUMMF), to help burn through the massive stocks of Reprocessed Uranium produced by the NUR series and the amount of reactor grade Plutonium produced by the Gas Cooled Breeder Reactors expected to be offered by TURatom in the near future.

Reactor Design
The reactor core itself is approximately forty metres tall, forty metres wide and about sixty metres long, consisting primarily of a array of graphite blocks, some of which have been machined to contain the channels used to carry the fuel and coolant through the reactor. The coolant channels are approximately five centimetres in diameter and are spread throughout the moderator mass, whereas the fuel channels are the requisite 10cm in diameter with 1cm deep and wide slots cut into them at sixty degree intervals to allow carbon dioxide to return between the end plates of the fuel elements during ordinary operation, with carbon dioxide passing through both the special cooling channels and the fuel channels, improving cooling of both elements.
All the fuel channels are cooled in the direction of fuel travel from the charge face to the discharge face, with the cooling channels in the moderator counterflowing/flowing in a proportion required to provide equal coolant flow in both directions, with the flowing and counterflowing coolant channels distributed throughout the moderator mass.

The reactor is situated snug with the inner containment structure, which runs the length of the rectangular building, being approximately five thick metre thick ferroconcrete, with both of the ends blocked off by additional two metre thick walls lead doped ferroconcrete walls, which contain four additional fuel bundles per channel, two not having been exposed to the nuclear reaction, and the other two undergoing cooling following the six month long irradiation, this first wall is also penetrated by the cooling channels, ensuring that the bundles undergoing preliminary cooling do not overheat during its eighteen hour stay.

There are one hundred and thirty six control rod channels, penetrating the reactor vertically, at staggered intervals in such a manner that one hundred and twenty five of them are capable of shutting the reactor down completely, by absorbing sufficient neutron flux to strangle the already borderline chain reaction, they consist of conventional hafnium alloy rods, controlled in normal operation by the automatic reactor computer using a rapid worm and screw mechanism, which is clutch detachable to allow the fuel rods to be completely inserted in approximately a tenth of a second when the emergeancy water pressure based release mechanism is activated, with water pressure being provided by a water tower located above the reactor structure, directly above the hump in the containment building associated with the reactors 40 metre long control rods.

There are 2500 fuel channels, arranged in fifty rows of fifty, with each channel containing one hundred and twenty bundles of fuel at any one time [with an additional four which are in the channel but outside the reactor]. To reload the fuel channel, which typically occurs every eighteen, the two robotic assemblages posistioned on the charge and discharge face maneuvre a bundle holder to the correct channel and both activate seals which press the holder against the face and prevent venting of high temperature coolant gas during the fueling procedure.

The gate on the appropriate channel [a tungsten alloy plate on the outer face of the concrete containment walls] is now opened and the fresh fuel bundle is inserted into the channel using an EM ram, while at the opposite end of the reactor, the fuel bundle that had been undergoing preliminary cooling will be forced from the channel into the discharge face holder, the gate is then closed and the gas seal broken, the pre cooled rod, still at 390 degrees celsius is then taken to the spent fuel pond, which is situated immediately beyond the discharge face, and lowered into the appropriate rack for its one year storage period. The machine is capable of achieving these operations without any additional human supervision beyond that which is normally situated in the reactor control room. The reactor would in normal course of operations conduct this procedure approximately once every fifty two seconds.

Steam Generation Equipment
The reactor system possesses two steam generators, one at each end of the stack, located at the ends of the primary containment structure, with one immediately "infront" of the charge face machinery, and the other located beyond the cooling pond system at the back of the primary containment structure, carbon dioxide from the cooling and fuel channels is athered inside the ferroconcrete shield at the appropriate face of the reactor and passes through one of two shielded insulated conduits in the roof of the reactor building over the intervening machinery, here it is used in a steam generator to produce steam at 360 degrees celsius (reactor carbon dioxide outlet temperature is 390 degrees) before being returned to the reactor core and passed through the opposing direction coolant channels with a reentrant temperature of approximately 270 degrees, sufficiently high to prevent significant buildup of Wigner energy in any part of the reactor, increasingly stability and safety.

Each one of these steam generators consumes approximately half of the reactors 150GW thermal output and passes through approximately 24 metric tonnes of water and 694 metric of Carbon Dioxide per second, transforming the former into superheated steam at approximately 360 degrees, with the later being pumped through using a quartet of high pressure pumps powered either directly from the turbine sets or by backup diesel generators in an emergeancy or during a scheduled shutdown procedure, which are capable of being up to speed in approximately fifty five seconds, during which time it is expected that the core (if it has been shut down currently) will not overheat considerably due to its extremely low power density and huge thermal mass.

Turbine and Secondary Containment Building
The steam from each steam generator is fed through the sides of the steam generator rooms out of the primary containment structure into the secondary containment building, which exists purely to act as a secondary biological shield and to contain any radioactivity in the course of a reactor accident, although such an accident would require the reinforced concrete primary shield to have been breached, it also contains the area where fuel that has been removed from the cooling pond, [which is located in the primary coolant structure and nominally contains the fuel irradiated in the previous year, approximately 12 tonnes in the form of 600,000 bundles for nominal output][Fuel removed using a second co located handling arm, similar to the one used to load and unload the reactor] are loaded into canisters for transport by road rail or sea to the reprocessing facility, and the turbine hall, where the decet of 5GWe Turbine Sets are located, incidentally some of the largest turbine sets in the world, which approach nearly 75% of possible carnot efficiency, before passing the now saturated 100 degree celsius steam to a condensing heat exchanger before the water passes back into the primary containment structure and back to the steam generators

Secondary Cooling System
Since the reactor has the relatively low operating temperature of 390 degrees celsius, maximum carnot efficiency is approximately 40%, while in the real world non-ideal case the reactor manages approximately 33% efficiency, producing a 50GWe output from the 150GWt produced by the reactor itself, although the additional 100GW Of low grade heat could be discarded into the sea or into a cooling tower, this would be exceptionally wasteful, and either be damaging to the enviroment, in the case of the former, or require an expensive cooling tower, in the case of the later. So in this design the hot water, heated by the condensor, is fed from the secondary containment structure to a secondary building, which can contain one of the following (if the reactor is built by TURatom services on a standard contract).

1] A Multi Stage Flash (MSF) Desalination Plant with a capacity of approximately 1100 tonnes of water per second
2] A District Heating Program with an output of 100GW or 265 million pounds of steam per hour (Suitable for providing heating to the community, Absorbtion Air Conditioning and desalination if steam raised from seawater)
3] An Absorption Refrigerator with an effectively 45 million "Tons of Refrigeration", for use in freezing fish type products or similar foodstuffs, in a tropical environment, as well as regional air conditioning to surrounding buildings

Emergeancy Procedures
In the event of an emergeancy, the four diesel powered coolant pumps can be at full output in approximately fifty seconds, while the control rods can be introduced to hard-stop a fission reaction in a tenth of a second, after this has occured the fuel rods are locked into posistion until the plant control officer releases them to move again, the water from the compressed water tower is then used in an emergeancy evaporative coolant mechanism, bypassing the steam turbine set, and boiling in a special array located in both steam generator rooms, the water provided in the pressure tower being sufficient to cool the shut down reactor to the point where thermal core damage is no longer an issue, and maintain said cooling against radioactive decay for over an hour, giving time for additional cooling to be provided, although the core can survive in this stage, even with only conduction and convection based cooling in both the carbon dioxide and secondary loops indefinately.

Pricing:
$90 billion for construction using own labour force + $30 billion for plant designs and licences for one reactor = $120 billion
$115 billion for TURatom Personel Construction, in partnership with local engineering firm, including tertiary heat recycling component = $115 billion

[Yes ladies and gentlemen, consider what happens when you operate more then one NUR-50000...]

[bump]

To: TURatomic Nuclear Services
From: The Federation of Osea

We wish to purchase 10 NUR-50000 and 200 NUR-50 reactors. This should have a total cost of $1.34 Trillion USD, which will be sent once the order is confirmed.

To: TURatomic Nuclear Services
From: The Federation of Osea

We wish to purchase 10 NUR-50000 and 200 NUR-50 reactors. This should have a total cost of $1.34 Trillion USD, which will be sent once the order is confirmed.

[We'll get back to you.]

Official Message from Kazansky Heavy Industries, Inc.

Though the owner of the corporation is in prison, KHI continues under new management - and we want a NUR-50000. 115 billion will be transferred upon confirmation.

Official Message from Kazansky Heavy Industries, Inc.

Though the owner of the corporation is in prison, KHI continues under new management - and we want a NUR-50000. 115 billion will be transferred upon confirmation.

To: Kazansky Heavy Industries Incorporated.
From: TransURanic Atomic Power Corporation, Export Operations.

This is agreeable. If you need any of our fuel services, give us a call.

A Year Later

Official Message from Kazansky Heavy Industries, Inc.

We are happy to report that this has been one of our best purchases. The reactor is supplying over 30 million people in New Bavaria with power, and running a thermal depolimerization plant to boot, as well as used for other needs. We thank your company for its rapid and expedient service.

OOC: A different hat, if you permit.

IC:

Official Message from the Confederacy of Sovereign States

Seeing the success of your wonderful reactors in private hands across the world, we wish to purchase 10 [that's ten] NUR-500 reactors, for construction in New Bavaria, as part of our economic aid package to that area. We will pay you the full price of 1.15 trillion dollars for constructing the ten reactors for us.

Once complete, the reactors will be privatized to various hands within New Bavaria, and will provide nuclear power to 330 million men and women with the newly-colonized area, as well as fossil fuel to those who need it.

OOC: A different hat, if you permit.

IC:

Official Message from the Confederacy of Sovereign States

Seeing the success of your wonderful reactors in private hands across the world, we wish to purchase 10 [that's ten] NUR-500 reactors, for construction in New Bavaria, as part of our economic aid package to that area. We will pay you the full price of 1.15 trillion dollars for constructing the ten reactors for us.

Once complete, the reactors will be privatized to various hands within New Bavaria, and will provide nuclear power to 330 million men and women with the newly-colonized area, as well as fossil fuel to those who need it.

"Oh my god."

To: Confederacy of Allanea.
From: TransURanic Atomic Power Corporation, Export Operations.

We have no problem with that. In fact, we've got company transports loading up right now.

---

Later that night someone filled the company hot tub with caviar and a good time was had by all (except the cleaning personel).

To: TransURanic Atomic Power Corporation
From: The Federation of Merkonia, Agriculture and Energy Department

After applause from local energy officials regarding the NEXSPR systems the government has opted to buy 2 NUR-50000 Nuclear Reactors at a price of $230 Billion USD. Once again TransURanic construction personnel will be required to construct these facilities I hope this is not a problem.

Site names are the following: Merkingrad NUR Reactor, Peyhot MFNR

Thank you,

Dr. Ursal Timor

M.A.C Heavy Industries

We wish to purchase the following items:


- 55x - TURatom NUR-50000 Nuclear Reactor

- 65x - NUR-50 50 MWe Gas Cooled Natural Uranium Reactor

- 85x - HEXPSR Subcritical Photodisintegration Breeder Reactor

Government Budget: $10,639 billion

------------------------------------------

Observations : If possible we would like to spread the payment over a period of 6 years.

For any inquiries please contact us:

M.A.C Direct Line: 21-456-3450

Thank you,

M.A.C Heavy Industries Management.

TURatom WCCR-1050 Nuclear Reactor
TURatom Water Cooled Carbon-moderated Reactor-1050MWe

Abstract
The WCCR Reactor is designed simply to produce electricity as cheaply as possible, and thus emphasises on-load refueling and other technologies designed to promote efficient use of nuclear fuel. It functions on a rather unusual, Mixed Metallic Fuel alloy, helping to avoid the use of expensive enrichment technologies when simpler chemical processes would ordinarily suffice. This dictated the choice of the fuel, and also the enrichment, high enough to achieve significant breeding and high burnup utilising ordinarily useless reprocessed depleted uranium as the fertile matrix, but low enough to ensure good controlability of the reactor. This resulted in the choice of 2.5% Plutonium, which when combined with the reactors breeding ratio of 0.8, should be sufficient to ensure that nearly 12.5% of the depleted uranium is fissioned by this startup mass of plutonium through the large number of fuel cycles that it will be reprocessed through, after being "pepped up" with fresh Plutonium to make up for overall fission losses to keep the Pu content at 2.5%.

Fuel Elements
The Fuel elements depart from the arrangement of the NUR, which is not practical due to the use of a vertical core orientation and the need to retain on load refueling without push-through-capability. Instead, the reactor fuel will be packaged in 4 metre long fuel assemblies, consisting of a long zircalloy tube with internal spacing structures, extruded in a single peice and then welded onto the end plates prior to installation into the reactor, which keep the columns of fuel pellets seperate in the reactor while allowing gasseous fission products to diffuse out of the pellets and move around inside the assembly, there are two "layers" of pellet spaces in the fuel assembly, an inner layer of six pellet columns and an outer layer of twelve pellet columns. Each pellet being a right-angle cylinder approximately 1cm in diameter and length, containing approximately fifteen grammes of heavy metal each. The fuel assembly itself is approximately 7 centimetres in diameter. The metallic pellets in each are compressed into the bottom two and a half metres of the assembly by an array of springs installed on the loading end just prior to the tube being sealed up. Two fuel assemblies are loaded into each channel, with the lower one being of slightly different design and loaded upside down, with the latch mechanism to permit the docking of a winch crane with the upper end of that fuel assembly, keeping the heavy metals near the centre of the reactor.
The open arrangement of the fuel ensures that the gasseous and volatile solid fission products produce during the core exposure are able to diffuse throughout the fuel assembly, and since the assemblies have a total length of 8 metres in a six metre tall reactor assembly, approximately one metre above and one metre below the boundaries of the reactor there is a region that is reachable by the gasseous products but contains no fuel and thus is in the path of no useful neutrons. The gasses produced during fission will disperse throughout the rod, and a large part of them (due to the absence of fuel, this area contains the bulk of the empty space in the assembly), will end up in this part of the assembly and will not absorb any useful neutron flux, largely abrogating the spectre of Xenon poisoning and other such effects that reduce the breeding efficiency of the reactor.
Each fuel mass contains 18 columns of fuel pellets, each two hundred and fifty pellets tall, so each 4 metre long fuel assembly contains some three thousand pellets, equating to some 45kg of Heavy Metals, with 90kg in the entire channel.
Since the fuel has an "enhanced" breeding ratio, it can attain burnups in the region of some 60GWd/MTU, far higher than the paltry 3.5GWd achieved by the NUR series, albiet with the greater expensive of handling reprocessed fuel and the lack of the ability to produce weapons grade plutonium. Thus, during its three year stay in the reactor assembly, the fuel rod will produce 2.7GWd of thermal energy, at an average rate of about 2.7MW, for a total of 5.4MW per fuel channel.

Reactor Design

The reactor is a fairly standard mass of graphite blocks with multiple fuel channels, approximately six hundred in this 3GWt design, each fuel channel being lined with a small zircalloy tube which has an internal diameter of approximately 9cm in diametre, leading to a jacket of water one centimetre thick surrounding the fuel assembly with a cross sectional water flow area of approximately 25.1 square centimeters. Assuming the coolant is light water heated from 30 degrees celsius to 390 degrees at supercritical pressure, the channel will require a coolant flow of 2.7 kilogrammes per second, which translates to an outlet flow velocity of 2.84 metres per second, with the input flow being approximately one third of this, the coolant being put through the bottom fo the reactor and collected off of the top, with the graphite blocks alligned to give improved lateral heat flow, allowing individual channels to be turned off at nominal power without significant alterations of the heating state of the core. As each fuel channel turns out 5.4MWt at nominal power, and the reactor runs at a relatively low core temperature, the plant requires approximately six hundred fuel channels, arrayed in a 24 by 25 rectangle, requiring a feed of a total of 1620kg of water per second, while turnign out an astonishing 3,240MWt at 390 degrees celsius, which is tapped off from the top of the reactor in the form of superheated steam.
There are thirty six control channels, lined with zircalloy tubes, penetrating the reactor vertically, at staggered intervals in such a manner that the activation of approximately twenty two of them are capable of shutting the reactor down completely, by absorbing sufficient neutron flux to strangle the chain reaction in the core, they consist of a rather unconventional solution, above the reactor containment building is a concrete filled water tower, which pressurises the water at the bottom of said water tower to some 330 bar, the pressure attained in a Pressurised Water reactor, and this water is allowed to slowly spray into each control channel, with pumps operating connected to the bottom of the channel which remove the water and pass it through a heat exchanger with the incoming coolant water, before pumping it up above the complex and back into the pressuriser tower, in an emergeancy these pumps would be shut off, and if the "Rapid Emergeancy Defence" system activated, electromagnetic grapples would disengage, permitting the opening of spring loaded valves which bypass the flow limiters at the top of the control channels, rapidly flooding the control channels and strangling the thermal output of the reactor to radioactive decay levels in a few tens of seconds, as well as cooling the reactor enormously for the period prior to such a cool off.

To reload one of the fuel channel, which typically occurs just over every thirty-six hours or so, the robotic winch assembly on the loading deck is posistioned above the correct fuel channel, the coolant flow into that particular channel is then temporarily suspended and the coolant vented from the bottom of the channel into the coolant recycling pond below and beside the reactor, the tungsten allow channel top cover is then retracted and the winch is maneuvred so that the coupling connects with the appropriate loop on the top of the upper fuel assembly, which is then lifted clear of the reactor and moved to a fuel rod holder attached to the assembly, the winch is then lowered into the fuel channel and the same procedure is used to extract the lower fuel rod in the assembly, once this has also been placed in the fuel rod holder the procedure is repeated in reverse with the two fresh fuel rods held in said holder, the entire procedure taking approximately two minutes, the channel is then closed up again and the coolant flow valves reopened, cooling the channel, which has already been preheated to the average reactor temperature with minimal loss of power output. With 600 fuel channels and one changed every ~44 hours, this requires approximately 1090 days to change every channge assembly once, giving the average fuel residence time of 3 years.
After the reloading the winch assembly automatic travels along its track from above the reactor loading deck to the fuel pond, which is seperated from the former by a three metre thick lead doped ferroconcrete wall within the twelve metre metre tall containment structure, which is sufficient to withdstand all but the most catastrophic breach of the reactor assembly, with primary containment provided by the zircalloy steam tubes. The fuel rods are then loaded vertically into racks at the bottom of the spent fuel pond and stored there for approximately ten years before being packed and shipped off for refueling. Therefore the fuel pond stores approximately 12,000 fuel assemblies totaling approximately one thousand and eighty tonnes of heavy metals.

Turbine Equipment
The reactors pair of 500MWe turbine sets are located within the containment structure opposite the fuel pond, and process approximately half of the supercritical water flow from the reactor each, with the triple expansion turbines exhausting approximately one hundred degree saturated steam, which is then passed to an otherwise standard condensor assembly and from there into the coolant recycling, unfortunately the decay of light isotopes of hydrogen and oxygen formed by irradiation of the coolant water neccesitates light gamma shielding around the turbines while they are in use, however a small amount of supercritical steam can be tapped off and used by supercritical waste disposal and depolymerisation systems, with it being replaced by fresh water introduced to the recycling pond. The pair of turboalternators driven by the turbines have a maximum output of approximately 1050MWe, approximately 32% or approximately 75% of that available according to the laws of Carnot Efficiency.

Secondary Cooling System
Since the reactor has the relatively low operating temperature of 390 degrees celsius it can only produce a ~1GWe output from the 3.24GWt produced by the reactor itself, although the additional ~2.2GW Of low grade heat could be discarded into the sea or into a cooling tower, this would be exceptionally wasteful, and either be damaging to the enviroment, in the case of the former, or require an expensive cooling tower, in the case of the later. So in this design the hot water, heated by the condensor, is fed from the secondary containment structure to a secondary building, which can contain one of the following (if the reactor is built by TURatom services on a standard contract).

1] A Multi Stage Flash (MSF) Desalination Plant with a capacity of approximately 24.2 tonnes of water per second
2] A District Heating Program with an output of 2.2GW or 5.8 million pounds of steam per hour (Suitable for providing heating to the community, Absorbtion Air Conditioning and desalination if steam raised from seawater)
3] An Absorption Refrigerator with an effectively one million "Tons of Refrigeration", for use in freezing fish type products or similar foodstuffs, in a tropical environment, as well as regional air conditioning to surrounding buildings

Emergeancy Procedures
In the event of an emergeancy, the four diesel powered coolant pumps can be at full output in approximately fifty seconds, while the control channels can be activated (via "Rapid Emergeancy Defence") to hard-stop a fission reaction in a tenth of a second, after this has occured the control channel control valves are locked in the full open posistion until the plant control officer releases them to move again, the water from the coolant recycling pond is then used in an emergeancy evaporative coolant mechanism, bypassing the steam turbine set, and boiling in a special array located at the far turbine end of the containment structure, the water provided in the coolant recycling pond being sufficient to cool the shut down reactor to the point where thermal core damage is no longer an issue, and maintain said cooling against radioactive decay for over an hour, giving time for additional cooling to be provided, although the core can survive in this stage, even with only conduction and convection based cooling in both the carbon dioxide and secondary loops indefinately.


$1.4 billion for construction using own labour force + $100 million for plant designs and licences for one reactor = $1.5 billion
$1.6 billion for TURatom Personel Construction, in partnership with local engineering firm, including tertiary heat recycling component = $1.6 billion

To: TransURanic Atomic Power Corporation
From: The Federation of Merkonia, Agriculture and Energy Department

After applause from local energy officials regarding the NEXSPR systems the government has opted to buy 2 NUR-50000 Nuclear Reactors at a price of $230 Billion USD. Once again TransURanic construction personnel will be required to construct these facilities I hope this is not a problem.

Site names are the following: Merkingrad NUR Reactor, Peyhot MFNR

Thank you,

Dr. Ursal Timor

To: The Federation of Merkonia, Agriculture and Energy Department.
From: TransURanic Atomic Power Corporation.

Its not a problem at all, we've been recruiting right out of the polytechs and universities, especially since that sudden infusion of a trillion dollars...Can't create positions fast enough really. Anyway we should be able to get them up and running relatively fast.

To: M.A.C Heavy Industries
From: TransURanic Atomic Power Corporation.

Well the spread out payment would work just fine with us, we accept paypal, moneyorders, rare minerals, antimatter, and currency equivalent to 1 USD. You really are going to have a lot of plute there...

To: The Federation of Merkonia, Agriculture and Energy Department.
From: TransURanic Atomic Power Corporation.

Its not a problem at all, we've been recruiting right out of the polytechs and universities, especially since that sudden infusion of a trillion dollars...Can't create positions fast enough really. Anyway we should be able to get them up and running relatively fast.

To: M.A.C Heavy Industries
From: TransURanic Atomic Power Corporation.

Well the spread out payment would work just fine with us, we accept paypal, moneyorders, rare minerals, antimatter, and currency equivalent to 1 USD. You really are going to have a lot of plute there...



M.A.C Heavy Industries

Please add the following to our order:


- 60x - TURatom WCCR-1050 Nuclear Reactor

We are going to pay the sum in cash,Universal Standard Dollars.
To pay for the interest (since we are paying in more than 1 year) we shall transfer to your country 60 tonnes of gold as well.

------------------------------------------


For any inquiries please contact us:

M.A.C Direct Line: 21-456-3450

Thank you,

M.A.C Heavy Industries Management.

To MAC Heavy Industries:
Your order for the additional 60 Reactors is approved, have a nice day, and thanks for the little gift.
-Office of the executive board of the TURatom Corporation

OOC:
On another note, thats 60 WCCR-1050s and 353 NUR series reactors sold :)
Buy more NURs, they are cheeeeecheap :D and you can never have enough plutonium
and remember:
Reprocessing is included in the fuel prices when fuel purchased from TURatom, all Pu-239 and other important isotopes will be returned free of charge (we keep the DU/unwanted Transuranics and the rest of the fission products)

Reprocessing is included in the fuel prices when fuel purchased from TURatom, all Pu-239 and other important isotopes will be returned free of charge (we keep the DU/unwanted Transuranics and the rest of the fission products)

[Coming soon! Our cheap and totally insane space launch program...]

Gawd damnit spiiizzzz

420 smoke thorium everyday

In A.D. 1953
War was beginning.
Edward Teller: What happen ?
Stanislaw Ulam: Somebody set up us the bomb.
Leo Szilard : We get signal.
Edward Teller: What !
Leo Szilard : Main screen turn on.
Edward Teller: It's you !!
Sakharov : How are you gentlemen !!
Sakharov : All your tritium are belong to us.
Sakharov : You are on the way to destruction.
Edward Teller: What you say !!
Sakharov : You have no chance to survive make your time.
Sakharov : Ha ha ha ha ....
Leo Szilard: Captain !! *
Curtis LeMay: Take off every 'B-36'!!
Curtis LeMay: You know what you doing.
Curtis LeMay: Move 'B-36'.
Curtis LeMay: For great justice.

ooc: 'ello 'ello wots this guv'nor? Newbs that want bombs? HEY. ALL YOU NUCLEAR COALITION PEOPLE. LOOK HERE.

Official Message from Kazansky Heavy Industries

As our production capacity has been currently overloaded by orders, we require twenty additional NUR-50000 reactors, to be constructed in Reichskamphen. Ten of them are to be formed into the Emperor Thompson Memorial Reactor Complex, and ten into the Emperor Paisley Memorial Reactor Complex. 2.6 trillion dollars will be wired upon confirmation of this order.

To: TURatomic Nuclear Services
From: The Federation of Osea

We wish to purchase 10 NUR-50000 and 200 NUR-50 reactors. This should have a total cost of $1.34 Trillion USD, which will be sent once the order is confirmed.

OOC: Izistan, you said you would get back to me on this.

Both Orders are hereby Confirmed, sorry for any inconvenience caused

- [TURatom incorporated]

lol lets see these CAN people try something D:<

OOC: Why are my reactor complexes not listed?

Official Message from Taggart Trains, Incorporated:

We require ten NUR-5000 reactors to be built as part of the Nathaniel Taggart Special Power Generation Complex in Axackal. 1.35 trillion dollars will be wired upon confirmation.

The White Corporation of Alanea would like assistance in building a reactor. Please respond.

White Corp. Rep.

OOC: Why are my reactor complexes not listed?

Official Message from Taggart Trains, Incorporated:

We require ten NUR-5000 reactors to be built as part of the Nathaniel Taggart Special Power Generation Complex in Axackal. 1.35 trillion dollars will be wired upon confirmation.

[Too bored to think of post. But approved!]

To: White Corporation of Alanea.
From: TURatomic Sales Div.

Yes?