This tutorial is set by the author's setting without permission.

Continue fast learning to build the MEK nuclear clustering reactor. Please consume this tutorial under the premise of the previous tutorial.

The MEK fusion reactor is injecting only 氘 and 氚, and the maximum power generation itself is 10mrf/T.

If the fuel (also known as DT fuel) is injected, it can break the upper limit of 10mrf/T to reach a maximum 100mrf/T.

Gas 氚 氚 化 化 can be mixed with DT fuel in the chemical irrigation. If you want to use DT fuel to generate electricity, you need a lot of 氘 氚 氚.Therefore, the production volume in the previous tutorial is not enough, so this tutorial will explain in detail how to build the production line of 氘 and 氚.

All machines in this tutorial are upgraded.

1. Production 氚

We need to build a distilled tower for salt water and produce liquid lithium distillers with saline water.

300MB of salt water can only produce 30MB liquid lithium, so we can use a maximum of ten salt water towers to provide a lithium tower.

In the demonstration archive of this tutorial, I built four salt water towers to provide a lithium tower.

The location of the distilled tower interface is no longer shown in detail, please arrange for players to arrange it by themselves.

For details of the construction of the distillation tower, please refer to the thermal distillation tower.

The following figure shows the five distilled tower in the archive.

The 7 electric pumps can just meet the water supply demand of a salt water tower, or use other MOD machines to supply water. The sink in the lazy kitchen is easy to use.

The picture below shows the water supply facility of the salt water tower in the archive.

Next, the liquid lithium becomes a gaseous lithium through a rotary gas -liquid converter, and then converted into a pupae through the solar neutron activator.

Since the solar neutron activator works only during the day, in order to prevent the reactor from extinguishing the reactor at night, we increase the buffer area of ​​the gaseous lithium and the cushion area of ​​the cricket. Each buffer area consists of 9 ultimate gas storage tanks.

The front of the ultimate gas storage tank is the output surface, and the other surface is the input surface.

2. Production 氘

After using the filtering and upgraded electric pump to extract heavy water, a total of 20 electric pumps were used in the archives of an electrolytic separator.

There is also a buffer area.

3. Production of DT fuel

Enter the chemical irrigation of 氘 and 氚 to generate DT fuel, and enter the dt fuel, 氘, and 氚 氚 together to enter the fusion reactor.

For details of the establishment of a fusion reactor, please refer to the fusion reactor.

4. Build laser arrays and put the black body radiation cavity into the reactor.

Laser energy can be saved to 400mrf to ignite the reactor.

After igniting the reactor, it can be seen that in the case of providing DT fuel, the power generation of the reactor easily exceeded 10mrf/T.

At this time, the ultimate general -purpose cable cannot be output the power in a timely manner.

We put five reactor ports on the side of the reactor and adjust to the output mode, and then make a guide matrix and it paste, so that the electricity can be transferred in time.

For details of the construction of the guidance matrix, please refer to the guidance matrix.

The production line in the tutorial is not enough to make the reactor reach 100mrf/T, so do not adjust the fuel input rate too high.

The figure below shows a large -scale production line.