Author: @s6014770
First, attach the full flowchart of the platinum department in the group. If there are places to optimize, just edit directly.
If you want results, directly look at parts one and four.
1. Raw Material Acquisition
Most compounds are written templates relying on requesters, some elements have complete cycles, just recycle them.
Nitric acid: Assuming the End is opened, you can directly use the HV air purifier to collect nitric acid in the End; otherwise, use a requester to maintain inventory.
Sulfuric acid: Similarly, use an air purifier in the Nether.
Hydrochloric acid: requester, chlorine hydrogenation. Hydrochloric acid is also in demand elsewhere, stockpiling some won't hurt.
Obtaining nitrogen, hydrogen, oxygen, and chlorine: For nitrogen and oxygen, just keep a small steam centrifuge running; for hydrogen, use an electrolysis machine to electrolyze water; for gaseous chlorine, rely on an evaporation tower (while also obtaining sodium hydroxide).
Other materials:
Potassium pyrosulfate, soda ash powder, sodium nitrate, sodium chlorate powder, nitrogen dioxide, formic acid, ammonium chloride: Use a requester after writing a template. Note: the byproduct sodium sulfate of formic acid can be recovered by electrolysis.
Salt: produced much and used much, should not be scarce.
Calcium powder: Only platinum powder requires it, electrolyze calcium chloride for complete recovery.
Sulfur Dust: It seems that some places consume sulfur and cannot be fully recycled. If you run out, go to the ore processing area, or centrifuge Blaze Powder (it's EV tier, the slaughterhouse should have it, right?)
Zinc powder: electrolytic zinc sulfate powder can be fully recovered
Two, linear organization of text
There are six initial products in the platinum series, and some steps also produce these initial products.
1. Platinum slag powder, output 6
1.1 High temperature reaction: add 6 platinum slag powder, 11 potassium pyrosulfate, 1 oxygen, produce 5 platinum leaching residue, 0.5 gaseous rhodium sulfate, 7 potassium sulfate powder (electrolytic recovery) (this step consumes 4 oxygen and 1 sulfur).
1.1.1 High-temperature reaction: 40 platinum leaching residue added with 11 soda ash powder and 3 oxygen, producing 20 rare metal mixture and 21 sodium ruthenate, 3 carbon monoxide (electrolysis recovery) (this step sodium-carbon conservation) (this line ends, will be discussed later in inert metal and rare metal processing)
1.2 Gaseous rhodium sulfate in a reaction vessel becomes rhodium sulfate by adding water.
1.3 Dehydrator: rhodium sulfate plus zinc produces crude rhodium metal powder and zinc sulfate powder (electrolytic recovery)
1.4 High-temperature reaction of crude rhodium metal powder, adding salt and gaseous chlorine, produces rhodium salt powder.
1.5 Add water to rhodium salt powder in a blender to produce rhodium salt solution.
1.6 Add oxygen, nitrogen dioxide, and sodium nitrate powder to the rhodium salt solution in the reactor to produce rhodium nitrate powder and salt.
1.7 Screening machine rhodium nitrate powder, producing rhodium filter cake powder,
1.8 Mixer: add water to rhodium filter cake powder, produce rhodium filter cake solution.
1.9 Distillation Room (Caution) Circuit No. 1, produce 6 reprecipitated rhodium powder
1.10 reactor 7 re-precipitate rhodium powder, add hydrochloric acid, produce 1 rhodium powder, 6 ammonium chloride, 1 hydrogen
Congratulations, you have completed the rhodium processing!!!
2. Crude palladium powder, output 3
Formic acid is added to the reactor to obtain palladium powder, ammonia, and carbon monoxide.
3. Coarse platinum powder, output 2
Reactor: 3 crude platinum powder added with 1 calcium powder, yielding 1 platinum powder and 3 calcium chloride (electrolytic recovery of calcium)
4. Platinum sludge, output 2
Centrifuge 5 platinum sludge yields 3 gold powder and 2 silicon dioxide powder
5. Inert metal mixture (output 4) (ruthenium treatment)
5.1 Baler baling
5.2 High temperature reaction: 6 inert metal + 10 sodium nitrate + 1 sulfuric acid, producing 6 sodium ruthenate and 0.6 gaseous rhodium sulfate (rhodium treatment see 1)
5.3 reactor 7 sodium ruthenate + 3 chlorine produce 3 liquid ruthenium tetroxide and 12 salt
5.4 Cracking Machine Circuit 1, 1 liquid ruthenium tetroxide + 1 steam, produces 1 hot ruthenium tetroxide
5.5 Distillation tower 3 hot ruthenium tetroxide produces 2 salt, 1 water, 0.9 ruthenium tetroxide solution
5.9 fluid solidification machine 1 ruthenium tetroxide solution, becomes 5 ruthenium tetroxide powder
5.10 Reactor: 5 ruthenium tetroxide powder + 6 hydrochloric acid, produces 1 ruthenium powder, 2 water, 6 chlorine
6. Rare metal mixture (output 1) (obviously, main source platinum slag powder) (iridium and osmium processing)
6.0.1 baler packaging
6.0.2 high-temperature reaction 7 rare metal mixture + 4 hydrochloric acid, producing 5 iridium metal slag + 1.6 acidic osmium solution
6.1 Iridium Processing
6.1.1 High temperature reaction: 6 Iridium metal slag + 1 Hydrogen + 5 Sodium chlorate powder, producing 3 Iridium dioxide powder, 2 Salt, 1 Dilute hydrochloric acid (distilled recovery of hydrochloric acid), probability of platinum mud slag
6.1.2 Reactor 3 iridium dioxide powder + 1 hydrochloric acid, produces 1 acidic iridium
6.1.3 Reactor 1 acidic iridium + 18 ammonium chloride, producing 4 iridium tetrachloride + 2 ammonia
6.1.4 Reactor: 4 iridium chloride + 3 hydrogen, produces 1 iridium powder + 3 hydrochloric acid
6.2 Osmium processing
6.2.12 Distillation tower acidic osmium solution, produces 5 osmium oxide metal powder + 1 water + 1 hydrochloric acid
6.2.27 Chemical immersion machine: osmium metal powder + 1 sulfuric acid, producing 4 osmium tetroxide powder + 2 dilute sulfuric acid
6.2.35 Reactor osmium tetroxide powder + 4 hydrogen, produces 1 osmium powder + 4 water
Third, organize the input for some recipe categories.
1. High temperature reaction
1.1 platinum slag powder, potassium pyrosulfate, oxygen,
1.2 platinum leaching residue, soda ash powder, oxygen
1.3 crude rhodium metal powder, salt, gaseous chlorine
1.4 Inert metals, sodium nitrate, sulfuric acid
1.5 rare metal mixture, hydrochloric acid
1.6 iridium metal slag, hydrogen, sodium chlorate powder
2. Large chemical reactor
2.1 gaseous rhodium sulfate, water
2.2 rhodium salt solution, oxygen, nitrogen dioxide, sodium nitrate powder
2.3 Re-precipitation of rhodium powder, hydrochloric acid
2.4 crude palladium powder, formic acid
2.5 coarse platinum powder, calcium powder
2.6 sodium ruthenate, chlorine
2.7 ruthenium tetroxide powder, hydrochloric acid
2.8 iridium dioxide powder, hydrochloric acid
2.9 acid iridium, ammonium chloride
2.10 iridium chloride, hydrogen
2.11 osmium tetroxide powder, hydrogen gas
Fluids: water, oxygen, nitrogen dioxide, hydrochloric acid, formic acid, chlorine, hydrogen gas
IV. Specific passive implementation methods
Need reaction furnace, large chemical reactor, distillation tower. No need to make a new one, just use the previous one.
1. Distillation Tower
It is recommended to use me input chamber (or precision output bus) (this is also used for woodification), can mark multiple and not afraid of residual liquid blocking the input, mark hot ruthenium tetroxide, dilute hydrochloric acid, dilute sulfuric acid, acidic osmium solution.
2. High temperature reaction
Assuming your reactor is also used for producing titanium ingots, etc., and the template supplier is facing one input assembly, enable isolation on the original input assembly (although it's not really necessary, as reactors rarely mix recipes).
Add two more input assemblies, isolation optional, enable input limit. Install AE's output bus.
first marked platinum residue powder, potassium pyrosulfate, platinum leaching residue, soda ash powder, crude rhodium metal powder, salt, gaseous chlorine, oxygen
second mark inert metal, sodium nitrate, rare metal mixture, iridium metal slag, sodium chlorate powder, hydrogen, hydrochloric acid, sulfuric acid
3、Large chemical reactor
Same as above, add 3 input assemblies to the large chemical reaction, fully open isolation and input restrictions (in fact, the only thing that needs isolation is hydrogen).
First mark gaseous rhodium sulfate, rhodium salt solution, sodium nitrate powder, oxygen, nitrogen dioxide, water
Second marked reprecipitated rhodium powder, crude palladium powder, crude platinum powder, calcium powder, sodium ruthenate, chlorine, ruthenium tetroxide powder, iridium dioxide powder, formic acid, hydrochloric acid
third marker, acidic iridium, ammonium chloride, iridium chloride, osmium tetroxide powder, hydrogen gas
4. Other simple steps
Most can directly use the output bus of ae. It is recommended to use previous mv, hv small machines (if the machine is still used for sample synthesis, pay attention to whether there will be residues causing blockage). Assuming there is a universal factory, then add an input assembly.
Dehydrator for rhodium sulfate with zinc
Mix rhodium salt powder with water, mix rhodium filter cake powder with water.
screening machine rhodium nitrate powder
Distillation room circuit No. 1, rhodium filter cake solution
Cracking Machine No.1 Circuit, Liquid Ruthenium Tetroxide + Steam (Open a single input assembly)
centrifuge platinum sludge
Ruthenium tetroxide solution for fluid solidification machine
Chemical immersion machine osmium oxide metal powder +1 sulfuric acid
Packaging machine packs two types of small powder (may need precise output bus)
5. Electrolytic recovery of by-products
potassium sulfate powder, carbon monoxide, sodium sulfate (formic acid byproduct), calcium chloride