This tutorial is set by the author to use the CC By-NC-SA protocol.

*The nuclear power process version in the tutorial is 2.18U-MC version 1.12.2. If there is an error, it may be a version problem, or I may have a mistake, please forgive and point out.

来 -250 can be used to make RTGs with constant 400RF/T/single, which can be described as cheap, once and for all.However, in view of the consumption and product intricate of the steps in the 锎-250 line, it may be a waste of nuclear raw materials, so I use the Excel table to consolidate the consumption and output of each step, and make the same level as much as possible to make the final final to make the final end to the endThere are more products.As shown in the figure.

explain:

First and second lines 27 lines: processing steps, such as "centrifugal uranium, 565" represents 565 uranium ingots to obtain uranium-235 and uranium-238 (not written here for centrifugal ingots); "H U235,16"H represents high density (L represents low density), U235 represents the fuel name, and the whole represents 16 high-density uranium-235 fuel (can be converted into a fluid) and then exhausted and recycled; TH232 is TBU fuel; "CF251-CM247"116" representatives accelerated the decline of 116 锎 251 to 锔 247.

Cenage C to Type Z: The statistics of each material obtained during the processing process (negatively consumed).Except for the 29th, the other parts are used as a unit for convenience.For example, the uranium-233 of column D, obtained 592 small pinch of uranium -233 in the steps of [37 钍 232 fuel], and consumed 585 small hint of uranium in the steps of [65 low concentration of uranium 233 fuel]-233, in the end of the 28th, a total of 7 small hint of uranium-233 was obtained, and the 29th line was converted to 0.777 ... (7/9) An uranium-233.The form of colorful forms is to distinguish different types of materials and fuels: light green represents raw materials, dark green represents uranium, blue of H and i column represents 镎, gray represents 钚, purple represents 锔;238 and 镅 241, they are also used to do the sub -final product of RTG; the blue of X column represents the 锎 250; the part of the 29th line is similar. Green is the consumption of raw materials, blue is the middle product, and light red is the ultimate event.Product, red is the final output of the 锎 -250.

Others: The green A30 grid is the total amount of raw materials consumed. The brown B30 grid is the ratio of the total amount of raw material for the 锎 -250 output and the consumed raw material. It can be seen that it is about 13.26 %. It is pretty good.I guess it should be improved, but it is difficult to let me go.

However, this form can only solve part of the problem, and the order of processing needs to be practiced.The processing order cannot be directly in the order of this form. For example, a part of the 镅 -243 rely on the supplement of the decay 锔-247, and you do not consume some 镅-243 to process it.step.Therefore, I have predicted and measured (I tested in the Sky Factory 4 integrated package.The operation order was found in the worst situation (except for uranium and crickets without any other nuclear materials).The steps of the connection of the increase can be performed at the same time, and the steps connected to the arrow may not be performed at the same time, but it should be performed in order.If you have a lot of nuclear raw materials in advance, you can merge some steps according to your own situation (such as directly taking the table above?), Instead of upside downThe fuel is exhausted and recycled. Low 镎 236*19 represents 19 low-density 镎 -236 fuel to dry and recycle it):

Centrifugal ingot*333->

Centrifugal uranium ingot*565->

7 232*37->

High uranium 235*16->

Low uranium 233*65->

Low 236*19->

High 236*3->

Low 239*18->

Low 241*28->

High 239*8->

High 镅 242*3 + low 镅 242*28->

High 锔 243*2 + high 锔 245*7 + low 锔 247*1->

Low 锔 243*24 + low 锔 245*9 + high 锔 247*6->

Low 248*14 + high 锫 248*3->

Low 249*16->

Low 249*9->

Low 锎 249*5->

为 251 Dechat to 1 247*58->

为 247 Dechat to 7 243*55->

Low 242*7->

Low 锔 245*6 + low 锔 243*7 + high 锔 247*2->

High 锫 248*6->

Low 249*9->

Low 锎 249*5->

为 251 Dechat to 1 247*23->

为 247 Dechat to 7 243*24->

Low 242*3->

Low 锔 243*2->

High 锫 248*1->

Low 249*3->

Low 锎 249*2->

Low 249*1->

为 251 Dechat to 1 247*7->

High 锔 247*3->

为 251 Dechat to 1 247*8->

High 锔 247*2->

High 锫 248*1->

Low 249*3->

Low 249*1->

Low 249*1->

Low 249*1->

为 251 Dechat to 1 247*11->

High 锔 247*2->

为 251 Dechat to 1 247*5->

High 锔 247*2->

为 251 Dechat to 1 247*4->

High 锔 247*1->

High 锫 248*1->

Low 锎 249*2->

Low 锎 249*2->

Low 锎 249*1.

According to your own needs, you can multiply the amount of processing of the entire process by appropriate integer multiple (of course, the original process material amount is already quite large).In the end, every 333 cricket ingots and 565 uranium ingots can be obtained, and a bunch of by-products can be obtained.result:

In fact, it is not impossible

The RF output is indeed very high, but the larger fission piles can be achieved, and the fusion pile is far exceeding, not to mention some other MOD generators (such as MEK's fusion pile, compared with it, 119 锎 RTG's forty forts of the forty RTG 40A few krf/t is at most a zero head).Therefore, this tutorial is indeed the writing that I can write (the workload is still quite large), and the actual application is not large.

Behind the scene: How did I use the excel form to "match the flat" 锎 -250 line?The above form, A, B, B, and the 1, 28, 29, 30, have explained it on it. So how did the "main part" of C2: Z27 come from?Taking the high-density uranium-235 fuel of the fourth line as an example, the number here is written in the B4 grid. The consumption and obtaining the processing steps of the high-density uranium-235 fuel are as follows: 36 small sets of uranium-235 and 45 small sips for each consumptionUranium-238, obtained 20 small sets of uranium-238, 16 small bun-237, 4 钚 -239 and 24 钚 -242, so the function of the "main part" of the fourth line of the fourth line is: uranium-235F4 grid = -36*B4, uranium-238 G4 grid = -25*b4 (ie (-45+20)*B4), 镎 -237's i4 grid = 16*b4, 钚 -239 K4 grid =4*B4, 4 -242 m4 grid = 24*b4.Like this, changing the number of B4 grids can get the corresponding consumption and output.If you add the "synthetic table" of each step on the production line, you can manually adjust the processing quantity of column B to "distribute".Of course, the process of Pingping also needs to observe the form carefully to find better solutions.Finally, I practiced in the game and got the detailed steps.The method of adjusting the production line and visual production lines with Excel tables may be applied in more places.Of course, even so, the actual application of this tutorial is not large.