Руководство по токсинам: различия между версиями

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Neok

Experiments

There are currently 9 experiments you can complete with help of the toxins lab, which can all be found by downloading the NT frontier app on your tablet or modular computer. Completing any of these experiments rewards you with research points, as well as money for the department funds. The exact amount depends on the tier and partner selected, higher tiers reward more, and some partners will reward more funding, while others will reward more points. Finally, some tech options are heavily discounted when completing certain experiments:

• BZ Gas Shells Provides an x point discount on

• Noblium Gas shells Provides an x point discount Quantum Electromagnetic Technology

• Reactionless Explosives Provides an x point discount on

The Tank Compressor

The tank compressor, found in the toxins launch room, is the device used for Gas Shell type experiments, as well as compressing hot gas into a tank above what the release valve on a canister can achieve. This device has an input port for the gasses that will be compressed into the tank, a slot inside of it for the tank you wish to fill, and an output gas for retrieving any of the gasses inside of the tank at the moment it ruptures. When using the tank compressor for gas shell experiments, you will want to rapidly pump in gas to the tank to the point the tank either starts leaking, or fails dramatically and explodes. In the case of the former happening, the compressor will indicate a LEAK HAZARD and the tank will slowly drain its contents, removal of the tank will make the experiment data availalbe, but removal before it is empty will result in the contents being freed into the room. If the tank explodes, it will simply cease to exist, and the experiment data will become available in the second tab of the machine. When using the machine to compress gas for use in explosive tests, take care not to exceed 2600 kPa, or the tank will become stuck in the machine.

BZ Formation

For both the BZ Gas shell experiment and for the efficient formation of hyper-noblium, you will need BZ Gas. Thankfully, the ordnance lab comes equipped with a freezer chamber suited to do just this. BZ is the product of a reaction between two mol of plasma and one mol of nitrous oxide, this reaction happens fastest at lower pressures. We will modify the freezer chamber to be fed directly by a gas mixer, fed by one plasma canister, and one nitrous oxide canister. The node with the plasma canister should be set 67%, leaving the other node at 33%, the pressure should be maximized. Next, use the unlocked air alarm on the freezer chamber wall to set the scrubber inside of the chamber to scrub BZ at extended range, and turn it on. Lastly, connect a CO2 or Plasma canister to the cooling port on the side off the freezer, and turn on the thermomachine at the lowest temperature. To start the formation, use the computer console, select the freezer chamber, and change the input to 1l/s before turning it on. The plasma/nitrous oxide mixture will now trickle in, slowly forming BZ, connect a canister or small pump to the output to collect your finished BZ.

Tritium

A number of experiments, including all needed to unlock technology, require tritium. Tritium is created by mixing oxygen with plasma at high temperatures, preferably at a ratio of 99:1 oxygen to plasma. To do this, we will use the burn chamber conveniently provided to us in the toxins mixing chamber.

Initial Piping

Leave the input loop (black loop on the bottom left) alone, as it suits our needs for now. Modify the the green (orange on metastation) loop by adding a cooler to it, you will want to connect the red side of the cooler directly into waste, you can move a cooler by screwing the panel open and then right clicking it with a wrench, left click rotates the cooler. Also replace the pipe directly adjacent to the connector with a volume pump, make sure this is OFF. Next acquire a firesuit, open the outer doors blast doors to expose space, and enter the airlock. Important note: opening the chamber to space and adding this black loop helps efficiency, but you'll take damage because of the cold, drink coffee or skip this step to prevent this. Additionally, make sure to set the scrubber on icebox before opening the blast doors, to prevent co2 from entering the loop from outside Inside of the airlock, place down a connector on layer 1 (shown in purple), and cycle the airlock to exterior. Add a scrubber directly behind the door, and pipe this to the connector. Now add two additional scrubbers to the green loop. Lastly, add a fourth scrubber facing to space, and connect it to a passive vent in space (Also shown in black). This is it for the piping, head back inside.

Use the air alarm next to the burn chamber, and set all scrubbers to extended range. Set the scrubbers connected to the green line to scrub tritium, and turn them all on. Set the black scrubber connected to space to scrub H₂O and CO₂, and turn it on. Set the purple scrubber connected to the connector to plasma, but keep it off for now.

Next, make sure both of the pumps inside of the airlock are set to 4500kPa.

Finally, yell at science for upgrades for the two coolers. Set both coolers to 30 kelvin (43.15 works too if you don't have higher-tier parts), and turn them on.

Tritium production

First, make sure you closed the blast doors, then connect an oxygen canister to the input port and wait untill it is empty, repeat this step two more times untill you have emptied three canisters into the burn chamber. Connect a mini pump to output of the burn mix. Create a tier two canister with 10 metal and 5 plasteel, and wrench this in place on the connector in the airlock (shown in purple). Next, set the input pump back down to 50kPa, and double check your setup, once you are statisfied, connect a plasma tank to the input and hit the igniter on the wall, the plasma will now burn. After several seconds of the chamber heating up, you should see check the output loop with a gas analyzer, and if all goes well you should see it filling up with tritium. Keep an eye on the tank monitor and wait for the mixture to reach around 15 000 kelvin, once this temperature has been reached, turn on the plasma scrubber on the air alarm, and watch the t2 canister fill up with hot plasma. Once your plasma canister reaches around 3500kPA, turn the scrubber back off. Now wait for the rest of the plasma to be converted into tritium, and once it is cooled pump it into small pump, and you should have several hundred moles. If this is not enough, and you have added a loop to dump waste into space, you can simply add more plasma and oxygen as needed. If you do not have a loop to dump waste, open the blast door and vent everything into space, and start anew with three O2 tanks.

High-yield Bombs

For a tier 3 paper on high-yield bombs, you will need to create a 300 radius bomb, this can be easily done with the help of tritium. First of all get an oxygen and plasma tank, and use a portable scrubber to empty them (on maps missing these, you can use the Huge Air Scrubbers, which currently do not have a sprite, alt click the tiles they are on to acces them). Put the plasma tank in your hot plasma cansister, fill up the tank to maximum pressure(Warning: make sure to close the valve before removing tank, unless you like giving medical and atmospherics more work to do). Next, use the gas mixer to pump one O2 canister into a small pump, then cool this pump to 30 kelvin with the free cooler (43.15 works here as well, but cooler is better). Now put the oxygen tank into your small pump with tritium, set the direction to in and the pressure to 850 kPa, and turn on the pump. Once your tank is filled, turn off the pump and take out the tank. Now put this tank into your small pump with O2, max the pressure, and fill the tank in the same way. Connect both tanks to a tank transfer valve (TTV). Now get a remote signaler, and change the frequency to something you can remember (we change this so you don't accidentally have some assistant trying to pulse a vibrator on the default frequency and instead turning you into gibs). Screwdriver the signaler and attach it to the TTV, congratulations, your bomb is done! Now launch your bomb onto the test site, turn on the intercom next to the Doppler-tachyon array to flex on the crew, and blow up your bomb. Download the data into a disk and don't forget to publish a paper with it!

Low-Yield Bombs

Simply do the exact same as High-Yield Bombs, except you can use far less tritium and oyxgen. Using a pressure of 100kPa tritium, and then filling the tank up to 300kPa with oxygen is plenty for tier 3 Low-Yield. This experiment does not unlock anything, but is easy to do and provides extra points for research.

BZ Gas shells

Gas Shell experiments require you to make a tank fail with a specified amount of a specific type of gas in it. For BZ Gas Shells, you will want to steal borrow the BZ tank from xenobio. Pump about 800 mol into an empty small pump, and then cool this pump down as much as possible with a cooler, getting close 10 kelvin is ideal for this. Empty out a tank, and then pump all 800 mol of BZ into your tank, and place it in the compressor located in the toxins range. Simply connect any other gas (nitrogen is a good choice, if you are going to recycle the BZ for later) to the blue input port, and turn on the compressor. Your tank should now either explode or leak, eject it once it is empty if it is leaking, the machine will then generate a log, download this and publish a paper on it!

Noblium Gas shells

Noblium is a gas created by mixing nitrogen and tritium at under 15 kelvin. This reaction creates a large amount of heat, which can be reduced by adding BZ (BZ will not be consumed if used in this way). Cool down one tank of nitrogen to the same temperature as your tritium (30 kelving if you followed the tritium guide), for ease of mixing. Now clear an area and construct a new loop, Connect this loop to a cooler, add one volume pump with a connector for adding BZ, add one filter that connects to a canister, and pumps the rest back into the loop, lastly add a gas mixer with two connector ports leading into the loop. You will want to configure the filter to remove hyper-noblium, and add a T2 canister to the connector. Next add your BZ canister, and very carefully add around 20-30 mol of BZ into the loop (I recommend setting the pump to 5 l/s or lower). Add your nitrogen to node one on the mixer, and your tritium to node two. Set the mix on the mixer to 66.7% nitrogen, and 33.3% tritium. You only to pump in this mixture untill you have usedaround 50-100 mol of tritium, as that will create enough noblium for the gas shell experiment and leave you with enough to complete nitrium gas shells. Once you are satisfied with the amount of hyper-noblium, cool down your canister, and then transfer all the gas into a small pump and finally into an empty tank to be used in the compressor. Pipe in some random gas to explode the tank, and publish your paper!

Hyper-Noblium loop

Nitrium Gas shells

Creating Nitrium, conveniently, uses the exact same gasses as Hyper-Noblium. Specifically, it uses tritium, nitrogen, and BZ in a ratio of 20:20:1, at a temperature of 1500 kelvin. You can use the exact same setup as described above, but by invert the cooler, it will now cool the waste loop, dumping excess heat into your loop and heating it up. Make sure the loop is above 15 kelvin so it doesnt create more Hyper-Noblium, and dump in the rest of your tritium. Now set the filter to filter out Nitrium, and place a new canister to collect it. Cool down your nitrium and transfer it into a portable gas pump, fill a tank, and proceed with the compression test.

Important miscellaneous notes

• Unhooking a tank in a canister that is open will flood the room, doing this with a pump will fill the pump with the surrounding air, this is not good.
• Unwrenching pipes will release the contents, be carefull to empty your pipes before removing them. This does not apply to devices like scrubbers, connectors, and pumps, those can be unwrenched without fear.
• Devices like pumps, filters, and even coolers will hold gasses even if the loops connected to them are empty. To make sure you don't contaminate tanks, especially using coolers, unwrench the scrubber pipe connected to them, rebuild the machine and move them to the rigddddddddht orientation, then rebuild the scrubber.
• Portable air pumps actually pump gas into small portable tanks, allowing you to reach a higher pressure in the tank than in the pump itself, this is the reason its used to fill tanks with cooled gasses. Note however that portable pumps have a low heat tolerance.
• the APC in the test range powers a lot of the mixing lab too, and is disconnected from the powernet by default, yell at engineering to fix this or get an inducer.