Personal thoughts and work sharing on the purification of aquatic product line process
Author: @CX9881, @void
Abstract
Starting from EV, purified water begins to be added to the game process, and as the level of cut wafers increases, the required purified water level also increases. Therefore, a good automated purified water production line can save a lot of trouble (although, given that purified water can be produced in parallel as long as it is powered, you can also manually craft the later water with full power for a while). This article is based on the mod included in the pack, providing ideas and corresponding tasks for automated purified water production from levels 1 to 8.
Unless otherwise specified, the switch ME input chambers mentioned in this articleall use machine control covers, and the machine coversare all set to activate the machine when the redstone signal is greater than the set value.
This article was written in version 0.5, and levels 1-4 water may be reconstructed later. If you see a description that does not match the machine, please do not copy it directly. You can wait for the author to update or research it yourself.
Frequently Asked Questions about Water Purification
Q:Why is my primary water plant not working?
A:Backwash requires output bus output waste, parallel requires greater than 1000.
Q:Why can't my water purification plant work simultaneously?
A:Insufficient power. Take first-grade water as an example: each parallel processing of 1mb of water consumes 1eu. Advanced purified water consumes more energy. See the tooltips of the water purification plant for details. When parallelism is too high, it will cause a certain level of purified water to monopolize all power, causing other water plants to stop working.
Q: AdjustWhy does the water plant stop working after parallel adjustment?
A:After adjusting parallelism, if the main plant does not automatically refresh, try restarting the purified water main plant.
Central Control Purification Treatment Plant
Purify water central control multi-block structure, controls nearby water plants at all levels and supplies power. The main block of each level of water plant can be automatically connected as long as it is within the sphere of the display range in the GUI of the purification treatment plant. This 120s is a fixed processing cycle, cannot be accelerated by overclocking/power increase methods, but can be accelerated by time warp (not recommended).
T1 clarifier purification device
The easiest automated purified water, just follow the instructions. The ME input bus provides water + advanced purified water. If not available, don't add for now. Remember to add it later when you get to that part.
According to the tooltip, we still need to add air for backwashing. Given that the ordinary input bin is far from sufficient in the EV stage, an additional ME input bin is added here to input air.
Then let this ME input port be a separate network, connect the ME chest (fluid storage component) outside, and place an air collector to input air into this ME network.
After placement, remember to come to the main block GUI and adjust the parallelism according to the electric power you provide. Later,After each level of purified water is done, manually adjust the parallelism. 1 parallelism corresponds to processing 1mb of input water.
T2 Ozone Purification Device
According to the tooltip, the best way is to always keep 1024B ozone in the input hatch; the simplest method is still to use the ME input hatch marker. Prepare two ME input hatches, the first input hatch connects to the main network, used to input the previous level purified water and the advanced purified water used to increase success rate.
Second me input chamber marks 1024B whole ozone, not connected to the main network, like T1 water/air input it has its own separate network, then externally connect an arc generator to produce ozone and input it into the network.
T3 Flocculation Purification Unit
The key to T3 water automation is to input exactly 1000B of polyaluminum chloride in a single processing cycle. There are roughly two approaches here: timing control and state control, but the core is to control the switch of the me input silo to control the input of aluminum chloride.
The timing control principle is to input once every 120s. Please refer to the figure below. Since it was not made by me, I won't go into details.
The state control principle is to output a signal after the machine completes to control the input of polyaluminum chloride. The principle here is that after the recipe is completed, the me output hatch (not connected to the main network) outputs through two storage buses. The upper storage bus is marked flocculation water, and the lower storage bus facing the tungsten steel bucket is marked flocculation waste liquid. On the left side of the tungsten steel bucket, a fluid calibrator is used to output to the left me super interface (12500mb/t). A fluid detector cover (default settings) is placed below to control the lower me input hatch to open for a period of time when the recipe is completed. The me input hatch is marked 1000B polyaluminum chloride. During the first run, manually open it to input 1000B polyaluminum chloride and then close it. After that, it can run automatically.
Remember to additionally set up a distillation to recover the flocculation waste liquid.
T4 pH Neutralization and Purification Device
T4 water can have two pH detectors, therefore detecting the upper and lower edges of the range. When exceeded, output a redstone signal to adjust the corresponding ME input bus/input bus switch (if acidic, add alkali; if alkaline, add acid).
Left pH sensor range is 7.05-14, right is 0-6.95. Left is ME input bus, labeled 40ml hydrochloric acid, right is ME input bus, labeled 4 sodium hydroxide powder. Connect using redstone p2p.All ME compartments have machine control covers placed.
T5 Extreme Temperature Fluctuation Purification Device
The automation task is to complete three temperature cycles within 120 seconds, similar to the previous T4 water. The approach is also similar to T4 water.
The core redstone circuit is roughly as follows (actually only one latch).
P2P redstone of the same color is one channel.
Red is the overheat sensor line, personal setting is 10000-12500.
Blue is the subcool sensor line, personal setting is 0-10.
White is the helium plasma control line, the me input chamber is marked 20ml helium plasma.
Black is the liquid helium control line, the me input chamber is marked 400ml liquid helium.
A single sensor can also complete it, but it's a bit troublesome.
T6 High-Energy Laser Purification Device
Periodic inner cycle lens, there are quite a few schemes, including super box queue, Ender conduit + redstone, but personally I think the most convenient is the pure AE order scheme from Xieying in the group. The control structure of the AE order scheme is shown below.
The output bus (with crafting card) under the barrel marks the order, the super-cube binds the lens chest, and the input bus (with redstone card) on the right side of the super-cube is responsible for extracting lenses. The crafting template is placed in the template supplier above the super-cube. The template is as follows (pay attention to the lens order).
After placement, manually align the lens with the machine lens sequence. The general operation is to break the redstone, wait until the GUI indicates that the lens matches the lens in the chamber, then connect the redstone.
T7 Residual Pollutant Degassing Purification Device
It can decode, but not as good as direct redstone signal strength selection + enumeration to relax the brain, just takes a bit more space. The general idea is to first determine the signal strength, then input the corresponding fluid into the machine on the corresponding signal line. The complete control structure is as follows.
Specifically divided into two parts: redstone signal strength selection and fluid output. The 1-15 part single chips are as follows. The left side of the steel drum is a storage bus, and the right side is a precise output bus. The emitted redstone strength signal, after selection, only activates this column of single chips. The precise output bus of the redstone torch at the upper right (containing a crafting card, a redstone card, set to pulse activation) receives a rising edge signal and performs one output to the steel drum. The row of storage buses on the left forms a separate network, connected to the ME storage input hatch of the machine to achieve automatic input.
Signal strength 0 single chip is roughly placed like this. The picture below shows the control part containing only the signal strength selector. The degassing signal output position is at the silica rock frame, and it is emitted at two positions through redstone p2p.
After completion, mark the corresponding amount of liquid on the precise output bus with the corresponding signal strength. Given that the precise output bus can only output 8B at a time, gaseous helium and liquid helium need to set up an additional output according to Figure 2, outputting 8B to the steel drum and 2B to the super cylinder.
Given that the exact output bus of EAE cannot adjust the quantity (not sure if it's a bug in EAE or GTO), here is a workaround. Use the ME huge interface to mark the corresponding liquid, then adjust the quantity, then press A to bookmark it to the left favorites, then drag the mark on the exact output bus page.
T8 Absolute Baryon Perfect Purification Device
For mechanisms like T8 water that have no signal indication, we can only solve them by traversal. Below is a most convenient ordering method solution for T8 water.
First, it is necessary to determine the initial order to prevent writing confusion (for example, set the top, bottom, top, bottom, odd, charm as 123456), then divide into groups A, B, C, D, E, F, 6 groups, each group has six catalysts and name them with the group number (for example, group A uses the stamping machine naming mold to name all 6 catalysts as A). Then determine the arrangement order:
Group A: 123456
Group B: 246135
Group C: 146325
Group D: 523641
Group E: 531642
Group F: 654321
Since the end of Group C and the beginning of Group D are both catalyst No. 5, one catalyst No. 5 is omitted. Finally, arrange them in the order of ABCDEF, then add 35*0.144=5.04b of quark-gluon plasma and a certain amount of degassed water to obtain the following sample.
12345624613514623523641531642654321 This sequence contains all 30 adjacent cases.
Finally, distribute using subnet.(Please use iv input bus)