Big reactors

Building It[]

Reactors and turbines are multi-block structures: they are made up of individual blocks arranged according to specific rules which together create a large functional machine. Both reactors and turbines must be built as a closed, mostly hollow box with no holes and complete edges, including corners. The edges of this box must be Reactor Casing or Turbine Housing, and the faces Reactor Glass or Turbine Glass, respectively.

In addition to these containment blocks, a number of other blocks are necessary to make a functioning reactor or turbine. None of the these blocks can be placed on the edge or corner; they must be somewhere in the faces of the reactor, sometimes in very specific places. Right clicking on the reactor casing or turbine housing will tell you if anything is missing.

Important: Ensure there are no metallic blocks within a 1 block radius of your turbine! Doing so results in unpredictable behavior with the turbine.

Download this spreadsheet to calculate the required materials and their cost for any size Reactor structure.

Use this Big Reactor Simulator to test the efficiency of different Reactor design. 

GUI[edit]

Passive Cooling Modeedit

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In this mode the reactor will produce Redstone Flux energy that can be interfaced with a Reactor Power Tap.

  1. Core Temperature:

    Temparature needs to be high enough to be efficient, too high increases fuel usage. The efficiency of heat transferred to the casing is dependant on the interior design of the reactor.

  2. Energy Output: Energy output in Redstone Flux per tick. When the energy produced is over 1,000 RF/t it switches to Kilo RF/t, so 1.20 KiRF/t is 1,200 RF/t.
  3. Fuel Burnup Rate: How quickly fuel is turned into waste, measured in mB/t. One ingot of Yellorium or Blutonium is the same as 1000mB of fuel.
  4. Fuel Reactivity: This is determined by the design of the fuel rod environment. The higher the percentage the more efficient the reactor is at converting fuel to energy.
  5. Core Fuel Status: Shows the ratio of fuel to waste in the core, yellow is fuel, cyan is waste. Hovering over this will show precise numbers for fuel, waste and number of fuel rods in the reactor.
  6. Casing Heat: Heat of the reactor’s casing. High heat increases energy output and coolant to steam conversion.
  7. Core Heat: Same as Core Temperature.
  8. Energy Buffer: The reactor has an internal energy storage of 10 million RF. Excess energy generated once the buffer is full will simply be wasted, and the reactor will eventually auto-shutdown after a while to save on fuel.
  9. Waste Options: With these three buttons you can decide what to do with the waste Cyanite generated. The three options are:
    • Auto-Eject Waste: Waste will be sent automatically to Reactor Access Ports. If a pipe is connected to the port it will eject into the pipe.
    • Do Not Auto-Eject Waste: Waste will build up in the rods until ejected manually by the player or by Redstone or computer signals.
    • Eject Waste Now: Used to manually eject waste into the Reactor Access Ports, when more than 1,000mB of waste has accumulated .
  10. Activate / Deactivate: the Arrow button will activate the reactor, the No Entry Sign button will power off the reactor.

Active Cooling Modeedit

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In this mode the reactor will produce super heated fluid (Steam) from coolant (Water) instead of energy. This can be used to run a Big Reactors Turbine (or other steam powered things from other mods) to produce energy. Hot fluid and coolant are both inserted and extracted using a Reactor Coolant Port. Adding at least one of these to a reactor will turn it into an active cooling reactor.

  1. Core Temperature:

    Temparature needs to be high enough to be efficient, too high increases fuel usage. The efficiency of heat transferred to the casing is dependant on the interior design of the reactor.

  2. Hot Fluid Output: Displays the amount of superheated fluid (Steam only at the moment) being produced at the moment in milliBuckets per tick (mB/t).
  3. Fuel Burnup Rate: How quickly fuel is turned into waste, measured in mB/t. One ingot of Yellorium or Blutonium is the same as 1000mB of fuel.
  4. Fuel Reactivity: This is determined by the design of the fuel rod environment. The higher the percentage the more efficient the reactor is at converting fuel to energy.
  5. Core Fuel Status: Shows the ratio of fuel to waste in the core, yellow is fuel, cyan is waste. Hovering over this will show precise numbers for fuel, waste and number of fuel rods in the reactor.
  6. Casing Heat: Heat of the reactor’s casing. High heat increases energy output and coolant to steam conversion.
  7. Core Heat: Same as Core Temperature.
  8. Power Buffer: How much power the reactor currently holds, in both units of RF and percentage of capacity. Not used in active cooling mode.
  9. Waste Options: With these three buttons you can decide what to do with the waste Cyanite generated. The three options are:
    • Auto-Eject Waste: Waste will be sent automatically to Reactor Access Ports. If a pipe is connected to the port it will eject into the pipe.
    • Do Not Auto-Eject Waste: Waste will build up in the rods until ejected manually by the player or by Redstone or computer signals.
    • Eject Waste Now: Used to manually eject waste into the Reactor Access Ports, when more than 1,000mB of waste has accumulated .
  10. Activate / Deactivate: the Arrow button will activate the reactor, the No Entry Sign button will power off the reactor.
  11. Coolant Fluid Tank: Amount of coolant in the reactors coolant buffer tank.
  12. Hot Fluid Tank: Hot fluid will go here first as a buffer and must be pumped out of the reactor using a Reactor Coolant Port.

Note[edit]

  1. It is important to note that the coolant discussed in this section is completely unrelated to the Reactor Coolant Port. These would be more accurately described as the moderating material of the reactor, whereas the coolant port accepts only water for the generation of steam.
  2. Fantasy Metals: Mithril, Orichalcum, Quicksilver, Haderoth, Celenegil, Tartarite and Manyullyn may also be used as coolant material.
  3. ↑ Some of the materials above don’t work in the Big Reactor on MC 1.6.4
  4. As of v0.3.4A2, any material will have a mass of 10 units per block. In the future the mod developer plans to allow the rotor to be constructed out of different materials.
  5. ↑ These six materials only work if the use of fantasy metals is enabled in the Big Reactor config file.

Optimal High Speed Turbines (1840 RPM)[edit]

  • All optimal high speed turbines operate at 1840 RPM.
  • Built with exactly 49 coil blocks. That’s 1 more than 6 complete rings.
  • They use between 1800 and 2000 mB/t of steam.
  • Longer turbines are marginally more efficient.

Enderium, Titanium, Platinum, Celengil, etc. are listed here for comparison. Although they operate at under 2000 RPM they behave like Ultra High Speed turbines. See above for the construction of their optimal designs.

Block Coils Steam Energy RF/t/coil
 Enderium 37 1,800 24,075 650
Titanium Titanium 41 1,800 20,330 495
Celenegil Celenegil 49 1,800 21,640 440
 Platinum 44 1,800 19,660 445
 Shiny 44 1,800 19,660 445
Tartarite Tartarite 44 1,800 19,660 445
Haderoth Haderoth 70 1,820 17,650 360
 Electrum 56 1,980 14,700 300
Quicksilver Quicksilver 46 1,980 13,760 280
Orichalcum Orichalcum 42 1,960 11,500 235
 Gold 44 1,960 10,290 210
Mithril Mithril 35 1,940 9,700 200
 Silver 36 1,820 7,500 150
 Invar 32 1,930 6,800 125
 Steel 29 1,930 5,730 115
 Aluminum 29 1,930 5,730 115
 Brass 26 1,980 4,940 100
 Osmium 26 1,980 4,940 100
 Copper 26 1,980 4,240 85
 Iron 21 1,870 2,141 60

Note[edit]

  1. It is important to note that the coolant discussed in this section is completely unrelated to the Reactor Coolant Port. These would be more accurately described as the moderating material of the reactor, whereas the coolant port accepts only water for the generation of steam.
  2. Fantasy Metals: Mithril, Orichalcum, Quicksilver, Haderoth, Celenegil, Tartarite and Manyullyn may also be used as coolant material.
  3. ↑ Some of the materials above don’t work in the Big Reactor on MC 1.6.4
  4. As of v0.3.4A2, any material will have a mass of 10 units per block. In the future the mod developer plans to allow the rotor to be constructed out of different materials.
  5. ↑ These six materials only work if the use of fantasy metals is enabled in the Big Reactor config file.

BigReactors.cfg

GenerateYelloriteOre=true – включить генерацию Yellorite в мире. Рекомендуется отключить, если в клиенте установлен IC2 во избежание дисбаланса в игре, т.к. при обжигании руды игрок сразу получит обогащенный уран. Автозамена Yellorite Ingot на слитки урана отключается параметром autoAddUranium=false, но большой разницы я не вижу: фактически, будет один вид «халявного» топлива, и один не очень… Для «честной» игры с IC2 лучше руду не включать и использовать уран.

Запасы Yellorium Ore в мире так же настраиваются: количество кластеров, их размер, амплитуда высот.

enableWorldGen=true — генерация руды Yellorite включена для всех биомов, кроме Нижнего мира и Края.

enableWorldRegeneration=false – генерация руды в уже созданном чанке. По-умолчанию отключена.

Для тех, кому кажется, что количество вырабатываемой энергии в аддоне слишком завышено, существует коэффициент в параметре powerProductionMultiplier – множитель мощности реакторов. Другой вариант — указать максимальные размеры каркаса: maxReactorHeight (высота) и maxReactorSize (длина и ширина), тем самым ограничив энергетические мощности машин.

Аддон появился совсем недавно, еще даже не вышел со стадии альфа-тестирования, тем не менее, он заслуживает внимания. Это то, чего так долго не хватало BuildCraft’у! Возможно, Big Reactors еще пока не сбалансирован, забагован и сырой, но в будущем автор обещает его намного усложнить и разнообразить.

На этом все. С вами был therapy session, wiki, google-translate, paint.net, ms word, немного энтузиазма и замечательное творение от Erogenous Beef — Big Reactors. Удачи в начинаниях и развитии!

Construction[edit]

Time lapse assembly of a small Reactor Structure.

Reactors and turbines are multi-block structures made up of individual blocks arranged according to specific rules, which together create a large functional machine. Both reactors and turbines must be built as a closed, mostly hollow box with no holes and complete edges, including corners. The edges of this box can be, but not necessarily built from Reactor Casing or Turbine Housing blocks, and the faces of Reactor Glass or Turbine Glass blocks, respectively.

In addition to these containment blocks, a number of other blocks are necessary to make a functioning reactor or turbine. None of these blocks can be placed on the edge or corner; they must be somewhere in the faces of the reactor, sometimes in very specific places. Right clicking on the reactor casing or turbine housing will display a message of what is missing.

Important: Ensure that there aren’t any metallic blocks within a 1 block radius of the turbine! Doing so results in unpredictable behavior with the turbine.

Optimal Ultra High Speed Turbines (> 2,000 RPM)[edit]

  • Usually operate above 2000 RPM, except for the highest tier materials.
  • Built with exactly 80 rotor blades.
  • They use the maximum of 2000 mB/t of steam.
Block Coils Speed Energy RF/t/coil
 Ludicrite 32 1,782.4 28,073 877
 Enderium 37 1,798.4 24,090 651
Orichalcum Orichalcum 26 4,500 15,090 580
Haderoth Haderoth 37 2,690 17,650 530
Titanium Titanium 41 1,803.3 20,415 497
Celenegil Celenegil 49 1,800 21,640 440
 Platinum 44 1,814.7 19,721 448
 Shiny 44 1,814.7 19,721 448
Tartarite Tartarite 44 1,800 19,660 445
 Electrum 37 2,690 16,370 440
Quicksilver Quicksilver 41 2,690 17,040 415
 Gold 42 2,700 13,100 310
Mithril Mithril 49 2,700 14,400 295
 Steel 34 4,485 9,810 290
 Aluminum 34 4,485 9,810 290
 Invar 39 3,620 9,740 250
 Silver 49 2,700 11,140 225
 Brass 46 3,590 9,170 200
 Osmium 46 3,590 9,170 200
 Copper 46 3,590 7,860 170
 Iron 44 4,500 6,530 150

Reactor[edit]

Partsedit

Reactor Controller

All reactors must have exactly one Reactor Controller block, which provides the main interface for monitoring the status of the reactor.

Access Ports are buffers that contain unused fuel and waste. Right-clicking a port brings up an interface that allows to add fuel, remove waste, and toggle inlet/outlet mode. An active reactor will use the fuel from the ‘Inlet’ port and dump waste into the ‘Outlet’ port. A Big Reactor needs at least one access port.

The core of the reactor is an arrangement of Yellorium Fuel Rods. These must be stacked to stretch the entire interior height of the reactor. The entire volume of the reactor may be filled with fuel rods, but it does not have to be. The Reactor will usually be more efficient with the Fuel Rods placed diagonally in a checker board pattern with a coolant filling the gaps.

Above each stack of Fuel Rods there must be a Reactor Control Rod, which allows the Player to adjust the depth of the Rod. It also tells the reactor where the fuel rods are so it can fill them with fuel.

Reactors that provide RF energy directly need to have at least one Reactor Power Tap as part of the structure.

The Power Tap can attach to any compatible Cable or Conduit that accepts RF power.

Coolant Ports allow fluids to be injected into and steam drained from the reactor to be transported to feed a turbine.

Reactor Computer Port

The Computer Port installed on a Reactor, allows ComputerCraft and OpenComputers blocks and items to control it.

Reactor RedNet Port

Like the Computer Port, the RedNet Port allows a reactor to interface with a RedNet network.

Reactor Temperatureedit

The fuel inside the fuel rods generates power, radiation and heat. Heat is transferred to the adjacent 4 blocks from the fuel rods into a coolant or fuel rod block, and likewise radiation is transferred up to 4 blocks (dependant on adjacent block absorption) in the cardinal directions (North,South,East,West).

Excess radiation and heat could cause the temperature in the reactor to rise above efficient levels and consume more fuel, since there is a penalty to fuel consumption at too high an operating temperature.

Temperature (C) < 200 200 to 1000 1000 to 2000
Loss (%) None 0 to 10 10 to 66

Reactor Coolantedit

A coolant reduces the temperature of a reactor, and moves heat from the reactor core to the reactor casing. The higher the casing heat, the higher the energy output and heat transfer rate of coolants .

Any fluid used as coolant must be manually added to the reactor during construction, exactly as you would with solid coolant materials. Those looking to fill large reactors with fluids that fall, such as Gelid Cryotheum, may want to consider using a Flood Gate of Fluid Outlet.

Each coolant material has various parameters that govern how it affects the reactor :

  • Absorption: How much radiation this material absorbs to convert to heat. Ranges from 0 (none) to 1 (all).
  • Heat Efficiency: How efficiently absorbed radiation is converted to heat. Ranges from 0 (none) to 1 (all).
  • Moderation: How well this material moderates radiation. This is a divisor, and greater than or equal to 1.
  • Conductivity: Amount of heat transfered on each exposed face.
Block Absorption Heat Efficiency Moderation Conductivity
 Iron 0.5 0.75 1.4 0.6
 Gold 0.52 0.8 1.45 2
 Diamond 0.55 0.85 1.5 3
 Emerald 0.55 0.85 1.5 2.5
 Graphite 0.1 0.5 2 2
 Glass 0.2 0.25 1.1 0.3
 Ice 0.33 0.33 1.15 0.1
 Snow 0.15 0.33 1.05 0.05
 Copper 0.5 0.75 1.4 1
 Osmium 0.51 0.77 1.41 1
 Brass 0.51 0.77 1.41 1
 Bronze 0.51 0.77 1.41 1
 Zinc 0.51 0.77 1.41 1
 Aluminum 0.5 0.78 1.42 0.6
 Steel 0.5 0.78 1.42 0.6
 Invar 0.5 0.79 1.43 0.6
 Silver 0.51 0.79 1.43 1.5
 Lead 0.75 0.75 1.75 1.5
 Electrum 0.53 0.82 1.47 2.2
 Fluxed Electrum 0.54 0.83 1.48 2.4
 Platinum 0.53 0.86 1.58 2.5
 Shiny 0.53 0.86 1.58 2.5
Titanium Titanium 0.53 0.87 1.59 2.7
 Enderium 0.53 0.88 1.6 3
 Water 0.33 0.5 1.33 0.1
 Destabilized Redstone 0.75 0.55 1.6 2.5
 Energized Glowstone 0.2 0.6 1.75 1
 Gelid Cryotheum 0.66 0.95 6.0 3
 Resonant Ender 0.9 0.75 2.0 2
 Blazing Pyrotheum 0.66 0.9 1.0 0.6
 Life Essence 0.7 0.55 1.75 2

Ресурсы

Yellorite Ore – руда, добавленная в генерацию мира. Основной ресурс, с которого можно получить топливо для реактора.
Yellorium Ingot – крафтится путем переплавки Yellorite Ore или Yellorite Dust в печи. Используются как основной вид топлива для реактора: производит энергию, тепло и Cyanite Ingot (отходы). Если установлен IC2, вместо Yellorium игрок получит сразу обогащенный уран*.
Cyanite Ingot – отработанный ресурс в реакторе. Получается путем отработки Yellorium или Blutonium в реакторе.
Blutonium Ingot – переработанный Cyanite Ingot в блоке Cyanite Reprocessor. Используется как топливо для реактора: вырабатывает энергию, тепло и снова Cyanite Ingot. По-сути, не имеет отличий с Yellorium Ingot в плане производства энергии и тепла.
Graphite Bar – материал, используемый для цепочек крафта множества блоков реактора. Можно получить путем обжигания угля или древесного угля в печи.

Optimal Unattended Enderium Designs[edit]

Note: This guide was written before Ludicrite was added to the game. Ludicrite is now the best material.
For instance, a turbine spinning at a suboptimal 1781 RPM (using 32 blocks of Ludicrite) generates 28050 RF.

All optimal end game designs use 37 Enderium coil blocks (3 blocks short of 5 full rings) with a supply of 2,000mB/t of steam.

Note: only includes designs with a constant rotor speed.

Dimensions include turbine housing blocks. Height is the axis with the rotor shaft. Amount of Cyanite does not include that needed by fluid ports, controllers, power ports, etc. because that amount is independent of turbine dimensions.

Width Height Cyanite Total Vol. Empty Vol. RPM RF/t RF/t/m³ RF/t/cyan Comment
5 27 547 675 83 1,797.4 24,077 35.67 44 Highest energy per cubic metre.
7 17 529 833 243 1,797.4 24,077 28.9 45.5 Highest energy per cyanite ingot.
13 11 739 1,859 963 1,797.4 24,077 12.95 32.5 Highest energy per height.

The first example above with the highest energy per cubic metre needs:

— 80 Turbine Rotor Blades

— 25 Turbine Rotor Shafts

— 37 Enderium Blocks

— 132 Turbine Housing

~ 312 Turbine Glass

— 1 each: Turbine Power Port, Turbine Controller, Turbine Rotor Bearing

— at least 2 Turbine Fluid Ports (1 input and 1 output)

(edit: properly adjusted requirements)

Using the most space efficient design, each turbine block consumes ~3 mB of steam and produces 35.67 RF per tick = ~12 RF/t/mB/m³. Mekanism 9 (available for Minecraft 1.7.10+) now produces even more power, and for a cheaper, faster, and smaller setup.

Construction[edit]

Time lapse assembly of a small Reactor Structure.

Reactors and turbines are multi-block structures made up of individual blocks arranged according to specific rules, which together create a large functional machine. Both reactors and turbines must be built as a closed, mostly hollow box with no holes and complete edges, including corners. The edges of this box can be, but not necessarily built from Reactor Casing or Turbine Housing blocks, and the faces of Reactor Glass or Turbine Glass blocks, respectively.

In addition to these containment blocks, a number of other blocks are necessary to make a functioning reactor or turbine. None of these blocks can be placed on the edge or corner; they must be somewhere in the faces of the reactor, sometimes in very specific places. Right clicking on the reactor casing or turbine housing will display a message of what is missing.

Important: Ensure that there aren’t any metallic blocks within a 1 block radius of the turbine! Doing so results in unpredictable behavior with the turbine.

Note

  1. It is important to note that the coolant discussed in this section is completely unrelated to the Reactor Coolant Port. These would be more accurately described as the moderating material of the reactor, whereas the coolant port accepts only water for the generation of steam.
  2. Fantasy Metals: Mithril, Orichalcum, Quicksilver, Haderoth, Celenegil, Tartarite and Manyullyn may also be used as coolant material.
  3. ↑ Some of the materials above don’t work in the Big Reactor on MC 1.6.4
  4. As of v0.3.4A2, any material will have a mass of 10 units per block. In the future the mod developer plans to allow the rotor to be constructed out of different materials.
  5. ↑ These six materials only work if the use of fantasy metals is enabled in the Big Reactor config file.

Как все происходит на деле?

Размер рамки реактора составляет от 3х3х3 до 32х32х48 (согласно файлу конфигурации). От размера реактора напрямую зависит его мощность. Но для чего строить огромную махину, если энергию потом будет некуда девать? Начнем с маленького 3х3х3.

Нижний слой выкладываем из обшивки. В центре можно воткнуть стеклянный блок, если угодно.

Средний слой состоит из главного контроллера, порта IN-OUT, «крана», стеклянного блока обшивки. В центре стоит прозрачный топливный стержень. Также, мы помним, что ребра должны состоять только из обшивки.

Последний слой полностью из обшивки, в центре стоит Reactor Control Rod прямо над топливным стержнем. Если конструкция собрана правильно – мы визуально это заметим, как на рисунке.

Какова будет мощность реактора? Один топливный стержень способен максимально вырабатывать ~4MJ\t. Если построить реактор 3х3х12, то стержней будет 10 (12 общая высота и минус 2 блока: низ обшивки и верх Control Rod) эквивалентом ~40MJ\t. Круто? Еще бы! Теоретически, при максимальном размере реактора производится энергия 165 600 MJ\t! *GregTech курит в сторонке*

Выводить энергию лучше всего с помощью труб из Thermal Expansion, особенно, если мощности нужны очень высокие. Если использовать трубы из BuildCraft, то сперва придется подключать деревянную электрическую, как и к любому двигателю, максимальная пропускная способность которой равна 32MJ\t.

Взрывается ли реактор, если накопит максимальное количество энергии и которую некому будет отдавать? Лично мне пока не удалось разогреть его до таких критических температур. Отмечу только, что в конце реактор сбавляет мощность, но продолжает работать. Автоматических систем его отключения, к сожалению, пока не предусмотрено. Гейты BuildCraft никак не реагируют на Big Reactors, кроме IN-OUT портов.

Coolant[]

A coolant reduces the temperature of a reactor, and moves heat from the reactor core to the reactor casing. The higher the casing heat, the higher the energy output and heat transfer rate of coolants.

It is important to note that the coolant discussed in this section is completely unrelated to the Reactor Coolant Port. These would be more accurately described as the moderating material of your reactor, whereas the coolant port accepts only water for the generation of steam. Any fluid coolants must be manually added to the reactor during construction, exactly as you would with solid coolant materials. Those looking to fill large reactors with fluids that fall, such as Gelid Cryotheum, may want to consider using buildcraft’s Flood Gate.

Each material has various parameters that govern how it affects the reactor:

  • Absorption: How much radiation this material absorbs and converts to heat. Ranges from 0 (none) to 1 (all).
  • Heat Efficiency: How efficiently radiation is converted to heat. Ranges from 0 (none) to 1 (all).
  • Moderation: How well this material moderates radiation. This is a divisor, and greater than or equal to 1.
  • Conductivity: Amount of heat transfered on each exposed face.
Block Absorption Heat Efficiency Moderation Conductivity
Iron 0.5 0.75 1.5 0.6
Gold 0.52 0.8 1.45 2
Diamond 0.55 0.85 1.5 3
Emerald 0.55 0.85 1.5 2.5
Graphite 0.1 0.5 2 2
Glass 0.2 0.25 1.1 0.3
Ice 0.33 0.33 1.15 0.1
Snow 0.15 0.33 1.05 0.05
Copper 0.5 0.75 1.4 1
Osmium 0.51 0.77 1.41 1
Brass 0.51 0.77 1.41 1
Bronze 0.51 0.77 1.41 1
Zinc 0.51 0.77 1.41 1
Aluminum 0.5 0.78 1.42 0.6
Steel 0.5 0.78 1.42 0.6
Invar 0.5 0.79 1.43 0.6
Silver 0.51 0.79 1.43 1.5
Lead 0.75 0.75 1.75 1.5
Electrum 0.53 0.82 1.47 2.2
Fluxed Electrum 0.54 0.83 1.48 2.4
Platinum 0.53 0.86 1.58 2.5
Shiny 0.53 0.86 1.58 2.5
Titanium 0.53 0.87 1.59 2.7
Enderium 0.53 0.88 1.6 3
Water 0.33 0.5 1.33 0.1
Destabilized Redstone 0.75 0.55 1.6 2.5
Energized Glowstone 0.2 0.6 1.75 1
Gelid Cryotheum 0.66 0.95 6.0 3
Resonant Ender 0.9 0.75 2.0 2
Blazing Pyrotheum 0.66 0.9 1.0 0.6
Life Essence 0.7 0.55 1.75 2

Turbine[edit]

A Turbine produces energy from Steam generated by an active cooling Reactor or generated using one of 6 other mods methods. Steam is converted back into water, which may be recycled into a Reactor to produce more steam.

Turbine Coil Materialedit

The three values are always averaged together to give the resulting values for the entire turbine coil. A higher efficiency will always produce more power. A higher drag will produce more power, but will slow down the rotor more when induction is enabled. A higher bonus will also always produce more power.

Block Efficiency Drag Bonus
 Iron 0.33 0.1 1
 Copper 0.396 0.12 1
 Osmium 0.462 0.12 1
 Brass 0.462 0.12 1
 Aluminum 0.495 0.13 1
 Steel 0.495 0.13 1
 Invar 0.495 0.14 1
 Silver 0.561 0.15 1
 Gold 0.66 0.175 1
 Electrum 0.825 0.2 1
Fluxed Electrum Fluxed Electrum 0.825 0.22 1.01
 Platinum 0.99 0.25 1
Shiny Shiny 0.99 0.25 1
 Titanium 1.023 0.27 1
Enderium Enderium 0.99 0.3 1.02
Ludicrite Ludicrite 1.155 0.35 1.02
 Mithril 0.726 0.15 1
Orichalcum Orichalcum 0.759 0.17 1
 Quicksilver 0.858 0.18 1
Haderoth Haderoth 0.99 0.2 1
Celenegil Celenegil 1.089 0.225 1
Tartarite Tartarite 0.99 0.25 1

Turbine Optimizationedit

  • Turbines convert steam into water at an even ratio, and produce a certain amount of RF per tick depending on the coil material and turbine design.
  • Steam intake is always between 0 and 2,000 mB per tick.
  • The rotor speed gauge only shows between 0 and 2,200 RPM, but the actual rotor speed can be higher.
  • Generated energy is always positive or 0.
  • The width of the turbine frame is not a factor of energy output.
  • The number of rotor shafts isn’t a very large factor of energy output. Dimensions used are at the Player’s discretion.
  • If maximum rotor speed is unlimited and 2,000 mB per tick of steam is available, it is most efficient to use 80 rotor blades. If the rotor speed is limited to 2,000 RPM, perhaps more rotor shafts and fewer rotor blades would be preferable in order to keep the rotor speed above 1,796.27 but below 2,000 RPM while optimizing energy output.
  • All blocks of the coil do not need to be made of the same material, but are averaged together to determine the turbine’s score in each of the three coil traits. This makes it possible to make composite coils that use cheap filler metals in balance with high end metals to maximize limited resources. It also means, however, that adding a ring of a low performing metal to a turbine with several rings of a high-perfomance metal may actually reduce the output.

Turbine Equationedit

  • BladeSurfaceArea = Number of rotor blades in the turbine.
  • RotorMass = Total combined mass of the rotor blades and rotor shafts. See the table above for the mass of each block.
  • CoilSize = The number of coil blocks in the turbine.
  • InductorEfficiency, InductorDrag, InductorBonus = The average Efficiency, Drag, and Bonus of each coil block (from the table above).
  • RotorSpeed = The speed of the rotor as displayed in the turbine controller GUI.

The turbine is at maximum efficiency (100%) at 898.134 RPM and 1796.27 RPM. It has an efficiency of 50% when less than 500 RPM, and at 1347.2 RPM. This doesn’t mean, however, that a turbine is most energy efficient at 1796 RPM.

Rotor energy in terms of ticks elapsed:

Where C is a constant that must be calculated based on initial values. If the turbine is just being started, then C is zero. OR, in terms of the RotorEnergy of the previous tick:

Rotor energy when turbine is running continuously:

a and b are both constant and are only dependent on the design of the turbine and the control values in the turbine controller.

If the turbine inductor is disengaged then InductionTorque equals zero.

Reactor Parts[]

Reactor Controller

All reactors must have exactly one Reactor Controller block. This block provides the main interface for monitoring the status of the reactor.

Reactor Access Port

Access Ports are buffers that contain unused fuel and waste. Right-clicking a port brings up an interface that allows to add fuel, remove waste, and toggle inlet/outlet mode. An active reactor will use the fuel from the ‘Inlet’ port and dump waste into the ‘Outlet’ port.

A Big Reactor needs at least one access port.

Yellorium Fuel Rod

The core of the reactor is an arrangement of Yellorium Fuel Rods. These must be stacked to stretch the entire interior height of the reactor. The entire volume of the reactor may be filled with fuel rods, but it does not have to be.

Reactor Control Rod

Above each stack of fuel rods there must be a Reactor Control Rod, this block tells the reactor where the fuel rods are so it can fill them with fuel.

Reactor Power Tap

Reactors that provide RF energy directly need to have at least one Reactor Power Tap as part of the structure.

The Power Tap can attach to any compatible Cable or Conduit that accepts RF power.

Reactor Coolant Port

Coolant Ports allow fluids to be injected into and drained from the reactor. Reactors that provide RF directly use coolant ports to keep the core at a safe operating temperature. Those that run steam turbines use coolant ports to feed the turbine with steam.

Reactor Computer Port

The Computer Port intalled on a Reactor, allows ComputerCraft blocks and items to control it.

Reactor RedNet Port

Like the Computer Port, the RedNet Port allows a reactor to interface with a RedNet network.

Reactor

Parts

Reactor Controller64px

All reactors must have exactly one Reactor Controller block, which provides the main interface for monitoring the status of the reactor.

Reactor Access Port

64px

Access Ports are buffers that contain unused fuel and waste. Right-clicking a port brings up an interface that allows to add fuel, remove waste, and toggle inlet/outlet mode. An active reactor will use the fuel from the ‘Inlet’ port and dump waste into the ‘Outlet’ port. A Big Reactor needs at least one access port.

Yellorium Fuel Rod

64px

The core of the reactor is an arrangement of Yellorium Fuel Rods. These must be stacked to stretch the entire interior height of the reactor. The entire volume of the reactor may be filled with fuel rods, but it does not have to be. The Reactor will be most efficient with the Fuel Rods placed diagonally in a checker board pattern with a coolant filling the gaps.

Reactor Control Rod

64px

Above each stack of Fuel Rods there must be a Reactor Control Rod, which allows the Player to adjust the depth of the Rod. It also tells the reactor where the fuel rods are so it can fill them with fuel.

Reactor Power Tap

64px

Reactors that provide RF energy directly need to have at least one Reactor Power Tap as part of the structure.

The Power Tap can attach to any compatible Cable or Conduit that accepts RF power.

Reactor Coolant Port

64px

Coolant Ports allow fluids to be injected into and steam drained from the reactor to be transported to feed a turbine.

Reactor Computer Port64px

The Computer Port installed on a Reactor, allows ComputerCraft and OpenComputers blocks and items to control it.

Reactor RedNet Port64px

Like the Computer Port, the RedNet Port allows a reactor to interface with a RedNet network.

Reactor Temperature

The fuel inside the fuel rods generates power, radiation and heat. Heat is transferred to the adjacent 4 blocks from the fuel rods into a coolant or fuel rod block, and likewise radiation is transferred up to 4 blocks (dependant on adjacent block absorption) in the cardinal directions (North,South,East,West).

Excess radiation and heat could cause the temperature in the reactor to rise above efficient levels and consume more fuel, since there is a penalty to fuel consumption at too high an operating temperature.

Temperature (C) < 200 200 to 1000 1000 to 2000
Loss (%) None 0 to 10 10 to 66

Reactor Coolant

A coolant reduces the temperature of a reactor, and moves heat from the reactor core to the reactor casing. The higher the casing heat, the higher the energy output and heat transfer rate of coolants .  

Any fluid used as coolant must be manually added to the reactor during construction, exactly as you would with solid coolant materials. Those looking to fill large reactors with fluids that fall, such as Gelid Cryotheum, may want to consider using a Flood Gate.

Each coolant material has various parameters that govern how it affects the reactor :

Absorption: How much radiation this material absorbs and converts to heat. Ranges from 0 (none) to 1 (all).

Heat Efficiency: How efficiently radiation is converted to heat. Ranges from 0 (none) to 1 (all).

Moderation: How well this material moderates radiation. This is a divisor, and greater than or equal to 1.

Conductivity: Amount of heat transfered on each exposed face.

Block Absorption Heat Efficiency Moderation Conductivity
Iron Iron 0.5 0.75 1.4 0.6
Gold Gold 0.52 0.8 1.45 2
Diamond Diamond 0.55 0.85 1.5 3
Emerald Emerald 0.55 0.85 1.5 2.5
Graphite Graphite 0.1 0.5 2 2
Glass Glass 0.2 0.25 1.1 0.3
Ice Ice 0.33 0.33 1.15 0.1
Snow Snow 0.15 0.33 1.05 0.05
Copper Copper 0.5 0.75 1.4 1
Osmium Osmium 0.51 0.77 1.41 1
Brass Brass 0.51 0.77 1.41 1
Bronze Bronze 0.51 0.77 1.41 1
Zinc Zinc 0.51 0.77 1.41 1
Aluminum Aluminum 0.5 0.78 1.42 0.6
Steel Steel 0.5 0.78 1.42 0.6
Invar Invar 0.5 0.79 1.43 0.6
Silver Silver 0.51 0.79 1.43 1.5
Lead Lead 0.75 0.75 1.75 1.5
Electrum Electrum 0.53 0.82 1.47 2.2
Fluxed Electrum Fluxed Electrum 0.54 0.83 1.48 2.4
Platinum Platinum 0.53 0.86 1.58 2.5
Shiny Shiny 0.53 0.86 1.58 2.5
Titanium Titanium 0.53 0.87 1.59 2.7
Enderium Enderium 0.53 0.88 1.6 3
Water Water 0.33 0.5 1.33 0.1
Destabilized Redstone Destabilized Redstone 0.75 0.55 1.6 2.5
Energized Glowstone Energized Glowstone 0.2 0.6 1.75 1
Gelid Cryotheum Gelid Cryotheum 0.66 0.95 6.0 3
Resonant Ender Resonant Ender 0.9 0.75 2.0 2
Blazing Pyrotheum Blazing Pyrotheum 0.66 0.9 1.0 0.6
Life Essence Life Essence 0.7 0.55 1.75 2
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