It won't be long now before some company realizes that they can make small, safe nuclear reactors for the home and the car. Then we can get rid of the electric companies and oil companies, and have a small reactor with a couple of fuel pellets that will last for a hundred years.
Nuclear Reactors For Investors
https://www.zerohedge.com/markets/nuclear-reactors-investors"Our design will utilize proven technologies"
"The design makes our reactor 'walk-away safe'"
There's a growing list of public and private companies that are working to build reactors for various purposes. These reactors vary widely in their design, size, output, and potential purpose. Everything is on the table: from using the same designs we've used for decades to novel ideas still only on the drawing board.
This article is designed to serve as a point of reference when reading about a new company and the reactor they're designing. Some of the features companies discuss are less novel than they sound, and vice versa. Hopefully, the information provided here can provide a more clear picture for the investor to make an informed decision.
Reactor Designs Features
Skipping the nuclear physics details, since the basic principles are consistent across the designs we'll explore, a nuclear reactor facilitates the controlled fission of uranium atoms, harnessing the resulting energy for various applications. After that, the differences we see in reactor designs are mostly in the choice of the fuel, moderator, and coolant.
If we include all the variations that have been used over time and the novel ideas yet to be produced, this will get out of hand. We'll only be focusing on the most common options.
Fuel
Uranium is king when it comes to fuel for nuclear reactors. Compared to the other fuel options, thorium and plutonium, uranium wins out mostly due to natural abundance and path dependence. You don't just drop in a chunk of uranium from the ground though. It's often enriched and comes in a few different forms:
Uranium Oxide (UO2) - The most common fuel for water-cooled reactors. The pellets are stacked inside fuel rods and loaded into the reactor core, and then replaced about every two years. The design holds major historical preference, but is less useful in high temperature applications, such as in reactors intended for industrial heat processes.
Uranium Zirconium (U-Zr) - This alloy improves on the UO2 fuel design in respect to thermal conductivity. U-Zr has improved conductivity and no oxygen, which makes it ideal for use in reactors with liquid sodium. But, with a lower melting point, it isn't able to be used in gas-cooled reactors.
Uranium Zirconium Hydride (U-ZrH) - This fuel is unique with its addition of hydrogen. The hydrogen acts as a balance to help shutdown reactors when temperature gets out of control and spikes up. This is why U-ZrH is typically found in research reactors at universities and national laboratories; when combined with additional cooling measures and engineered hydrogen management, the fuel offers a near "walk-away safe" capability.
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