This tutorial is from MC Encyclopedia (MCMOD.CN) using the CC By-NC-SA protocol.

Most of this article refers to the content of the original author of FTBWIKI, and is authorized by the same CC protocol.

Source address: https://ftb.gamepedia.com/nuclearcraft

A standard fission reactor is composed of reactor housing, reactor controller, reactor unit, reactor cooler cooler, which can add the reactor port and reactor reduction (only graphite blocks and crickets, which are currently the same as the same effect).

In the interior space of the reactor, the default size can be selected from 3x3x3 to 24x24x24.The controller can be used as part of the shell or as part of the edge.

A 4X3X5 fission reactor, the picture comes from FTBWIKI

A fission reactor of 4x3x5, the picture comes from FTBWIKI

The reactor unit is the core of a fission reaction, and it can do fission work with it.The quantity of the unit core affects the combustion efficiency and duration of fuel.

The controller can be detected by the comparator to monitor the calories.The controller can also be controlled by the redstone signal to turn on/off the controller.During the construction process, it is not recommended to supplement the side line, which will cause the reactor shell integrity to determine errors.

The difficulty of control of the fission reactor is how to design the placement of internal units, coolers and reducers, so that the heat will not be too high, the highest efficiency of power generation and the least consumables at the same time.

For lazy players, you can pile the reactor unit and the reactor reducer in the reactor and not add the cooling unit for the time being. After the case is sealed, put down the controller.Open the controller to view the heating rate and power generation rate.Subsequently adjust the cooling unit of the cooling unit or consider reducing the reactor unit.After the reactor is placed, the shell can be disassembled to adjust the size and internal component position. This process should keep the controller not move and not work.

For players who need to study in -depth research, a detailed calculation formula is listed here.

Each fuel rod has different calories and power generation rates. Press Shift to check the heating rate and power generation rate of this fuel rod.

The basic efficiency of each reactor unit is 1.When it is adjacent to a reactor unit, its efficiency is +1.That is, if a reactor unit is adjacent to 6 reactors, its basic efficiency (recorded as BE) is 7.

The adjacent to the reactor and the reactor can increase its efficiency.Heating efficiency is different from power generation efficiency. Each connection to a decelerator is +1/3 (recorded as MH), and the power generation efficiency is +1/6 (recorded as MR).If a reactor unit is connected to the three subtraction, then the MH of this unit is 1 and MR is 1/2.It should be noted that if the reducer does not connect to any reactor unit, it will increase the heating rate, but it will not increase the power generation rate, so it is necessary to remove the useless reducer.

So the power generation efficiency of this reactor unit = be*(mr+1), the heating efficiency = be*(be+1)/2+be*mh.

The efficiency and the basic thermal efficiency and basic electricity efficiency of the fuel have obtained the thermal efficiency and electrical efficiency of this unit.

Adding the thermal efficiency of all units indoor units and electrical efficiency, the overall thermal efficiency and electrical efficiency are obtained.

When the fuel is put into the pile, its power generation time is based on the number of combustion time/reactor units.This also means that the higher design efficiency reactor can make the same fuel emit more electricity.If the product that needs to be obtained as soon as possible, add more the number of reactor units and try to keep the efficiency at 100%as much as possible.

A example is provided here.

As shown in the figure, a reactor unit is adjacent to three reducers (called A), and the other is only adjacent to A (called B).Put the LEU-235 fuel rod (120RF/T, 50H/T) in the controller.

It can be seen that both A and B are both 2, A's MR is 1/2, and B's mr is 0, so the electricity efficiency of A is 3, and B's electrical efficiency is 2.The total power generation efficiency is 120*3+120*2 = 600RF/T;

A MH is 1, B is 0, so A's thermal efficiency is 5, B's thermal efficiency is 3, and the total heating efficiency is 50*5+50*3 = 400h/t.

The basic duration of Leu-235 is 60min, and it can be burned for 30 minutes in this reactor.

In addition, when the mouse moves to the two metering strips on the left side of the figure, the efficiency and thermal efficiency will be seen.Here is a way to quickly calculate power generation power and heat power:

Power generation power = fuel basic power*Number of reactor units*Electricity efficiency;

Heating power = fuel basic thermal rate*Number of reactor units*thermal efficiency.

Cooling units can reduce the heat of the reactor, and hold down Shift to view their working conditions.Only the cooling unit under the correct conditions will work normally.Other cooling units can work as long as they are put in, but the liquid cooling device must be injected into the coolant by buffering to work normally.At this time, the liquid cooler needs to be placed inside the reaction room, and the buffer can replace the reactor shell.If your reactor temperature is too high (filling the groove), it will be leaked, and a large amount of core melting material will flow out of it, and the components of many reactors will be replaced.

Next we list all the fuel stick data (based on the data in the game, you can see the mouse moved to the fuel and press shift):

燃料棒名称 "> Time(min)

Data: IMAGE/SVG+XML,%3C%3FXML%20Version%3d%221.0%22%20enCoding%3d%22utf-8%22%3F%3E%3CSVG%3d%22Http%2FWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWW.w3.org%2F2000%2Fsvg%22%20viewBox%3D%220%200%2021%204%22%20height%3D%224%22%20width%3D%2221%22%3E%0A%20%20%20%20%3cpath%20d%3d%22M6.5%204-4%204%204z%22F%3e%3C%2fsvg%3e%0A ");; background-posity: right center; word-break: break-all; "> Basic capacity (RF/T)

"> Basic heat production (H/T) TBU1206018TBU OXIDE1208422.5LEN-236859036lep-23976.610540leu-2356012050Len-236 513854leu-23353.314460lep-239 Oxide76.614750Mox-239701557.5lecm-24556.6268lep-24176.616570LEU-235 Oxide6016862.5LEB-248 Oxide71.718965Lea-2424519294Lecm-247 Oxide65193.267.5leu-233 Oxide53.3201.675lecm-24343210112leCF-2495 0216.0116lecf-25148.3225120lecm-245 Oxide56.6226.885lep-241 oxide76.623187.5mox-24146243.697.5.5LEA-242 Oxide45268.8117.5LECm-243 Oxide43.3294140LECf-249 Oxide50302.4145LECf-251 Oxide48.3315150HEN-23685360216HEP-23976.6420240HEU-23560480300HEN-236 Oxide85504270HEB-24871.7540312HECm-24765552324HEU-23353.3576.0360HEP-239 Oxide76.6588300HECm-24556.6648408HEP-24176.6660420HEU-235 Oxide60672375HEB-248 Oxide71.7756398HEA-24245768564HECm-247 Oxide65772.8405HEU-233 Oxide53.3806.4450HECm-24343.3840672HECf-24950864696HECf-25148.3900720HECm-245 Oxide56.6907.2510HEP-241 Oxide76.6924525HEA-242 Oxide451075.2705HECm-243 Oxide43.31176840HECF-249 OXIDE501209.6870HECF-251 Oxide48.31260900 is followed by the related data:

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Data: IMAGE/SVG+XML,%3C%3FXML%20Version%3d%221.0%22%20enCoding%3d%22utf-8%22%3F%3E%3CSVG%3d%22Http%2FWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWWW.w3.org%2F2000%2Fsvg%22%20viewBox%3D%220%200%2021%209%22%20height%3D%229%22%20width%3D%2221%22%3E%0A%20%20%20%20%3cpath%20d%3d%22m14.5%205L-4%204-4ZM14.5%204L-4-4%204Z%2F%3E%3E%3C%2FSVG%3E%0A"); Cursor: Pointer; Background-Repeat: No-Repeat; Background-Position: Right Center; Word-Break: Break-ALL;"> heat multiplier graphite block 1/61/61 block 1/61/3 Cooling related data for reference here.