Utilizes a large set of centrifuges to concentrate uranium-235 isotope out of natural uranium (a process called isotope separation). The resulting product is fissile uranium, ready to undergo a chain reaction in a nuclear reactor.
The reactor will operate as long as it is supplied the minimum amount of fuel shown below. When fuel is depleted it will be replaced with a new one and spent fuel or any other corresponding product will be returned.
By dragging the orange slider to the right, you define the desired power level maintained in the reactor. This affects the amount of steam the reactor generates and how fast it burns through the fuel. All the heat generated needs to be used. Any extra heat can slowly build up, eventually leading to a reactor overheating. Basic reactors don’t have automated power regulation which makes their heat output fixed.
Nuclear reactor was critically overheated and is shutting down. Depending on severity, this may cause loss of loaded fuel, damage to the building (loss of maintenance), and leak of radiation.
Cooling is deployed in case the reactor starts to overheat, and that typically happens when water is not supplied fast enough to be converted into steam (or steam output gets stuck). Cooling is not mandatory if you are not using automatic power regulation. However, it is highly recommended to have it as it provides extra protection and helps to avoid any potential overheating.
Thermal reactor that maintains nuclear chain reaction from enriched uranium rods. The reaction releases a large amount of energy utilized for steam generation. This plant can be set up to effectively provide up to {0} MW of electricity when running on full power. Beware that spent fuel is radioactive and can harm the population if not stored in a specialized facility.
メクハイブ
大型の遠心分離機を使って、天然ウランからウラン235の同位体を濃縮する (取り出すために、大型の遠心分離機を使用します(同位体分離と呼ばれる)工程)。その結果、核分裂性ウランのペレットができ、核分裂反応炉で連鎖反応を起こす事が出来る様になる。このペレットはまだ放射能を帯びていないので、手作業で扱う事が出来るが得られ、原子炉で連鎖反応を起こすことができるようになります。