Fractionator: Difference between revisions

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(→‎Player Tips & Tricks: - Added formula for calculating expected deuterium output of multiple fractionator conveyor loop setups)
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** Note, however, that Fractionators necessarily desaturate the loop, albeit at a low rate, so with a single entry point of Hydrogen, there is approximately a 1% loss per fractionator, which cascades to further Fractionators along the loop.
** Note, however, that Fractionators necessarily desaturate the loop, albeit at a low rate, so with a single entry point of Hydrogen, there is approximately a 1% loss per fractionator, which cascades to further Fractionators along the loop.
*** e.g. if there are 10 Fractionators on a Conveyor Belt Mk.III loop, the first will operate at 100% efficiency, processing 0.3 deuterium/s. The second will operate at ~99% efficiency, as the conveyor belt is ~99% saturated, while the third will operate at 98% efficiency due to desaturation by previous fractionators on the loop.
*** e.g. if there are 10 Fractionators on a Conveyor Belt Mk.III loop, the first will operate at 100% efficiency, processing 0.3 deuterium/s. The second will operate at ~99% efficiency, as the conveyor belt is ~99% saturated, while the third will operate at 98% efficiency due to desaturation by previous fractionators on the loop.
*** The total expected output of such a Fractionator setup can be calculated using the following amended equation: [Belt Speed] * [Initial Saturation Percentage] *(1 - (0.99 ^ [Number of Fractionators] ) ) = Total Deuterium Production Speed
*** This equation gives the expected total production of a 100 Fractionator setup on a Conveyor Belt Mk.III loop as 19.019 Deuterium/second, or a system conversion rate of 63.4%
*** As a result, having multiple entry points in the conveyor loop for Hydrogen to replenish saturation, or multiple conveyor loops is recommended.
*** As a result, having multiple entry points in the conveyor loop for Hydrogen to replenish saturation, or multiple conveyor loops is recommended.
** In order to prevent product stacking, the inflowing Hydrogen conveyor must be joined to the conveyor loop in either T-shape or via [[Splitter]] with the returning Hydrogen input set as prioritized.
** In order to prevent product stacking, the inflowing Hydrogen conveyor must be joined to the conveyor loop in either T-shape or via [[Splitter]] with the returning Hydrogen input set as prioritized.

Revision as of 02:02, 22 June 2021

Fractionator
Fractionation Facility
Taking advantage of the high vapor pressure ratio of hydrogen and liquid deuterium at a certain temperature, deuterium is fractionated from liquid hydrogen with a certain separation efficiency. Use a conveyor belt to introduce hydrogen from one side, after fractional distillation, export from the other side, and export the deuterium from the front port.
Icon Fractionator.png
Work Consumption720 kW
Idle Consumption18.0 kW
Made InAssembler
Hand-MakeReplicator
Stack Size30

Icon Fractionator.png
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3 s
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Summary

The fractionator takes any conveyor input and output in its side connections, and will transform 1% of the hydrogen going through itself into Deuterium going out of its front connection. In the UI, the left-hand Hydrogen symbol show the input buffer, and the right-hand symbols are the output buffers.


Production Chain

Recipe Building Replicator? Technology
Icon Fractionator.png
1
3 s
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8
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4
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4
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1
Icon Assembling Machine Mk.I.pngIcon Assembling Machine Mk.II.pngIcon Assembling Machine Mk.III.pngIcon Re-composing Assembler.png
Tech Deuterium Fractionation.png

Production Progression Chart

Stage 1 Stage 2 Stage 3 Stage 4 Stage 5
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24
Icon Iron Ingot.png
24
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8
White arrow right.svg
Icon Fractionator.png
1
Icon Stone.png
4
Icon Stone Brick.png
4
White arrow right.svg White arrow right.svg
Icon Stone.png
8
Icon Glass.png
4
White arrow right.svg White arrow right.svg
Icon Silicon Ore.png
8
Icon High-Purity Silicon.png
4
Icon Microcrystalline Component.png
2
Icon Processor.png
1
Icon Copper Ore.png
2
Icon Copper Ingot.png
2
Icon Iron Ore.png
2
Icon Iron Ingot.png
2
Icon Circuit Board.png
2
Icon Copper Ore.png
1
Icon Copper Ingot.png
1

Player Tips & Tricks

  • The Fractionator recipe is unique in the fact that it is based on percentage of materials moving through the Fractionator. This means the Fractionator necessarily needs one input of Hydrogen, and one output of Hydrogen, and another output of Deuterium. It also means that conversion speed is directly proportional to belt speed (1% of belt speed) and saturation rate of the input & output for Hydrogen.
    • Belt Speed * 0.01 * Saturation Percentage = Deuterium Production Speed
    • A Conveyor Belt Mk.I that is 100% saturated with Hydrogen (6 Hydrogen/s), will allow a single Fractionator to produce 3.6 Deuterium/minute, or 0.06 Deuterium/second
    • A Conveyor Belt Mk.II that is 100% saturated with Hydrogen (12 Hydrogen/s), will allow a single Fractionator to produce 7.2 Deuterium/minute, or 0.12 Deuterium/second
    • A Conveyor Belt Mk.III that is 100% saturated with Hydrogen (30 Hydrogen/s), will allow a single Fractionator to produce 18 Deuterium/minute, or 0.3 Deuterium/second
  • It is useful to build Fractionators in a conveyor loop, with one entry point for Hydrogen. This allows cycling of Hydrogen already on the belt for further conversion to Deuterium, requiring only the replacement of Hydrogen that was converted.
    • Any conveyor loop that is fully saturated with Hydrogen, for any type of Conveyor Belt, can serve up to 100 Fractionators at a time.
    • Note, however, that Fractionators necessarily desaturate the loop, albeit at a low rate, so with a single entry point of Hydrogen, there is approximately a 1% loss per fractionator, which cascades to further Fractionators along the loop.
      • e.g. if there are 10 Fractionators on a Conveyor Belt Mk.III loop, the first will operate at 100% efficiency, processing 0.3 deuterium/s. The second will operate at ~99% efficiency, as the conveyor belt is ~99% saturated, while the third will operate at 98% efficiency due to desaturation by previous fractionators on the loop.
      • The total expected output of such a Fractionator setup can be calculated using the following amended equation: [Belt Speed] * [Initial Saturation Percentage] *(1 - (0.99 ^ [Number of Fractionators] ) ) = Total Deuterium Production Speed
      • This equation gives the expected total production of a 100 Fractionator setup on a Conveyor Belt Mk.III loop as 19.019 Deuterium/second, or a system conversion rate of 63.4%
      • As a result, having multiple entry points in the conveyor loop for Hydrogen to replenish saturation, or multiple conveyor loops is recommended.
    • In order to prevent product stacking, the inflowing Hydrogen conveyor must be joined to the conveyor loop in either T-shape or via Splitter with the returning Hydrogen input set as prioritized.


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