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This is the Guide to [[Atmospherics]]. When properly initialized, | This is the Guide to [[Atmospherics]]. When properly initialized, Atmosia can keep the station aired-up through nearly any emergency. Improperly initialized, it's a waste of space at best and an outright fire hazard at worst. | ||
When worked by a master, atmospherics grants powers many consider to be... Unnatural. | When worked by a master, atmospherics grants powers many consider to be... Unnatural. | ||
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If you're new to the job, feel free to jump straight to the [[#Setting Up Atmospherics|how to set up Atmos -section]]. If you're ready to really learn about the atmospheric system, read on. By reading this guide you will learn how to transform Atmos from a waste of space to an actually useful addition. We will go through all kinds of theory, so this may be tough, but it will also ensure you know exactly how and more importantly '''how''' Atmos works the way it does, making you ready for all kinds of situations. | If you're new to the job, feel free to jump straight to the [[#Setting Up Atmospherics|how to set up Atmos -section]]. If you're ready to really learn about the atmospheric system, read on. By reading this guide you will learn how to transform Atmos from a waste of space to an actually useful addition. We will go through all kinds of theory, so this may be tough, but it will also ensure you know exactly how and more importantly '''how''' Atmos works the way it does, making you ready for all kinds of situations. | ||
[[File:Atmospherics.png|thumb|600px]] | [[File:Atmospherics.png|thumb|600px]] | ||
See also: | See also: | ||
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==The Gases and Their Functions== | ==The Gases and Their Functions== | ||
Let's start with some theory about the gases. Below are the different gases that can be found in-game. | Let's start with some theory about the gases. Below are the different gases that can be found in-game. | ||
===[[File:O2_Canister.png]]O<sub>2</sub>=== | ===[[File:O2_Canister.png]]O<sub>2</sub>=== | ||
Oxygen. All humans, pets, and lizard-people need more than 16 kPa of oxygen in the air or internals to breathe. Any less and the creature starts to suffocate. | Oxygen. All humans, pets, and lizard-people need more than 16 kPa of oxygen in the air or internals to breathe. Any less and the creature starts to suffocate. | ||
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Oxygen is an invisible gas. To detect it, use your [[PDA]] or a wall mounted [[Air Alarm]]. Oxygen [[canister]]s are marked in blue. [[Emergency Oxygen Tank]]s, filled with about 300 kPa, spawn in your emergency [[Internals Box]]. Larger [[Oxygen Tank]]s are in [[Emergency Locker]]s all across ship, which start with about 600 kPa. Can be mined from Lavaland with a bit of ingenuity, but generally will never need to be done unless using an extreme tritium synthesis setup. | Oxygen is an invisible gas. To detect it, use your [[PDA]] or a wall mounted [[Air Alarm]]. Oxygen [[canister]]s are marked in blue. [[Emergency Oxygen Tank]]s, filled with about 300 kPa, spawn in your emergency [[Internals Box]]. Larger [[Oxygen Tank]]s are in [[Emergency Locker]]s all across ship, which start with about 600 kPa. Can be mined from Lavaland with a bit of ingenuity, but generally will never need to be done unless using an extreme tritium synthesis setup. | ||
===[[File:N2_Canister.png]]N<sub>2</sub>=== | ===[[File:N2_Canister.png]]N<sub>2</sub>=== | ||
{{anchor|Nitrogen}} | {{anchor|Nitrogen}} | ||
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Can be found in Atmospherics in red canisters. Can also be gasmined from lavaland. | Can be found in Atmospherics in red canisters. Can also be gasmined from lavaland. | ||
===[[File:Air_Canister.png]]Air=== | ===[[File:Air_Canister.png]]Air=== | ||
A 1:4 gasmix of O2 and N2 (20% O2, 80% N2). The station is filled with this. | A 1:4 gasmix of O2 and N2 (20% O2, 80% N2). The station is filled with this. | ||
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Air canisters, marked in white, can be found in emergency storages. | Air canisters, marked in white, can be found in emergency storages. | ||
===[[File:Water_vapor.png]]Water Vapor=== | ===[[File:Water_vapor.png]]Water Vapor=== | ||
{{anchor|Water Vapor}} | {{anchor|Water Vapor}} | ||
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The [[Janitor]] starts with a tank in his closet. Outside of atmospherics, it can be used to clean large areas very quickly. | The [[Janitor]] starts with a tank in his closet. Outside of atmospherics, it can be used to clean large areas very quickly. | ||
===[[File:CO2_Canister.png]]CO<sub>2</sub>=== | ===[[File:CO2_Canister.png]]CO<sub>2</sub>=== | ||
{{anchor|Carbon Dioxide}} | {{anchor|Carbon Dioxide}} | ||
What the fuck is Carbon Dioxide!? It's an invisible, heavy gas. It chokes people effectively and quickly, and if you can be bothered to set the alarms up, will result in a invisible room that kills those in it. Takes some setup and can be very, very annoying. Causes people to ''gasp'' at low levels. Also used as fuel for fusion, with an absolute minimum of 250 moles, though you generally want more. | What the fuck is Carbon Dioxide!? It's an invisible, heavy gas. It chokes people effectively and quickly, and if you can be bothered to set the alarms up, will result in a invisible room that kills those in it. Takes some setup and can be very, very annoying. Causes people to ''gasp'' at low levels. Also used as fuel for fusion, with an absolute minimum of 250 moles, though you generally want more. | ||
Can be found in Atmospherics in black canisters. | Can be found in Atmospherics in black canisters. | ||
===[[File:N2O_Canister.png]]N<sub>2</sub>O=== | ===[[File:N2O_Canister.png]]N<sub>2</sub>O=== | ||
Nitrous Oxide, a.k.a. Sleeping Agent. A white-flecked gas. | Nitrous Oxide, a.k.a. Sleeping Agent. A white-flecked gas. | ||
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Can be found in Atmospherics in red canisters with a white stripe on them. | Can be found in Atmospherics in red canisters with a white stripe on them. | ||
===[[File:Plasma_Canister.png]][[Plasma]]=== | ===[[File:Plasma_Canister.png]][[Plasma]]=== | ||
Toxins. One of the two flammable gases on the station, plasma is purple and highly toxic. Used primarily for fusion, an absolute minimum of 250 moles is required to start the process, though you generally want to use more. | Toxins. One of the two flammable gases on the station, plasma is purple and highly toxic. Used primarily for fusion, an absolute minimum of 250 moles is required to start the process, though you generally want to use more. | ||
Heating this in the presence of a large amount of oxygen will cause the formation of tritium, an even more flammable gas that burns hotter, brighter and far deadlier than plasma. | Heating this in the presence of a large amount of oxygen will cause the formation of tritium, an even more flammable gas that burns hotter, brighter and far deadlier than plasma. | ||
===[[File:BZ_canister.png]]BZ=== | ===[[File:BZ_canister.png]]BZ=== | ||
BZ gas is a potent hallucinogenic that also put slimes into stasis, degenerates changeling chemicals and suppresses their hivemind. As a side effect, affected people will take low brain damage, but breathing it long enough will cause brain death. An extremely insidious gas that is much harder to detect than N20 or Plasma, or at least until the hallucinations start. | BZ gas is a potent hallucinogenic that also put slimes into stasis, degenerates changeling chemicals and suppresses their hivemind. As a side effect, affected people will take low brain damage, but breathing it long enough will cause brain death. An extremely insidious gas that is much harder to detect than N20 or Plasma, or at least until the hallucinations start. | ||
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Export Price per Mole: 4 | Export Price per Mole: 4 | ||
===[[File:Nitryl_no2.png]]Nitryl (NO<sub>2</sub>)=== | ===[[File:Nitryl_no2.png]]Nitryl (NO<sub>2</sub>)=== | ||
Nitryl (formerly Brown Gas) speeds you up - pretty good until the acid eats your lungs. Generally produced only as a precursor to stimulum, or when somebody's pet star gets loose and starts turning the station into its burning core. | Nitryl (formerly Brown Gas) speeds you up - pretty good until the acid eats your lungs. Generally produced only as a precursor to stimulum, or when somebody's pet star gets loose and starts turning the station into its burning core. | ||
The result of heating Oxygen and Nitrogen to 25000k at a 1:1 ratio, with at least 5 moles of N2O. The requisite heat is often only produced in tritburns, but the necessary heat energy as well as the natural heat decay caused by water vapor causes nitryl production via heat exposure over a turf (such as the burn chamber) very slow and generally not worth it. Fusion temperatures are advised. | The result of heating Oxygen and Nitrogen to 25000k at a 1:1 ratio, with at least 5 moles of N2O. The requisite heat is often only produced in tritburns, but the necessary heat energy as well as the natural heat decay caused by water vapor causes nitryl production via heat exposure over a turf (such as the burn chamber) very slow and generally not worth it. Fusion temperatures are advised. | ||
===[[File:Tritium.png]]Tritium=== | ===[[File:Tritium.png]]Tritium=== | ||
{{anchor|Tritium}} | {{anchor|Tritium}} | ||
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Export price Per Mole: 5 | Export price Per Mole: 5 | ||
===[[File:Freon_canister.png]]Hyper-Noblium=== | ===[[File:Freon_canister.png]]Hyper-Noblium=== | ||
Extremely inert, Hyper-Noblium stops other gases from reacting. (Specifically, it stops reactions when >5 moles). The rarest and most precious gas in the game and for good reason. Each mole synthesized contributes 1000 research points into the R&D servers and can later be sold for 1000 credits each. Synthesizing 500 moles in a shift is usually enough to get all the researches and give cargo a practically limitless budget. | Extremely inert, Hyper-Noblium stops other gases from reacting. (Specifically, it stops reactions when >5 moles). The rarest and most precious gas in the game and for good reason. Each mole synthesized contributes 1000 research points into the R&D servers and can later be sold for 1000 credits each. Synthesizing 500 moles in a shift is usually enough to get all the researches and give cargo a practically limitless budget. | ||
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Export price Per Mole: 1000 | Export price Per Mole: 1000 | ||
===[[File:Stimulum.png]]Stimulum=== | ===[[File:Stimulum.png]]Stimulum=== | ||
An experimental gas that makes you stun and sleep immune while also speeding you up. While incredibly cumbersome to manufacture, its effects give the enterprising technician a decisive advantage in combat as it has no addictive or negative effects. Try giving it to security so they can robust traitors and lings, or don't because security is more likely to arrest you for making meth gas because they don't have any idea what the hell stimulum is. Better yet, export it via cargo for some very high margins. While not as valuable as Hypernoblium, you can generally synthesize more moles of it and make more money, it's just even more of a chore to make than fusion. Also generates 40 Research Points per mole synthesized, making it a very nice gas overall if you can somehow produce large batches of it. | An experimental gas that makes you stun and sleep immune while also speeding you up. While incredibly cumbersome to manufacture, its effects give the enterprising technician a decisive advantage in combat as it has no addictive or negative effects. Try giving it to security so they can robust traitors and lings, or don't because security is more likely to arrest you for making meth gas because they don't have any idea what the hell stimulum is. Better yet, export it via cargo for some very high margins. While not as valuable as Hypernoblium, you can generally synthesize more moles of it and make more money, it's just even more of a chore to make than fusion. Also generates 40 Research Points per mole synthesized, making it a very nice gas overall if you can somehow produce large batches of it. | ||
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Export price Per Mole: 100 | Export price Per Mole: 100 | ||
===[[File:Pluoxium.png]]Pluoxium=== | ===[[File:Pluoxium.png]]Pluoxium=== | ||
A non-reactive Oxygen substitute that delivers eight times as much O2 to the bloodstream, with as little 3 kPa minimum pressure required for internals! | A non-reactive Oxygen substitute that delivers eight times as much O2 to the bloodstream, with as little 3 kPa minimum pressure required for internals! | ||
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Export price Per Mole: 5 | Export price Per Mole: 5 | ||
===[[File:MiasmaCanister.png]]Miasma=== | ===[[File:MiasmaCanister.png]]Miasma=== | ||
Miasma is created from rotting corpses, gibs, and other things. Miasma smells bad and can cause diseases to spontaneously appear. The higher concentration of miasma in the air, the higher level symptoms can appear. Can be converted back into oxygen by heating it to 373.15K. Also generates a small amount of research points when converted this way. Miasma production consumes oxygen and will not be produced from bodies in space or the oxygen level reaches a partial pressure of 18 kPa. | Miasma is created from rotting corpses, gibs, and other things. Miasma smells bad and can cause diseases to spontaneously appear. The higher concentration of miasma in the air, the higher level symptoms can appear. Can be converted back into oxygen by heating it to 373.15K. Also generates a small amount of research points when converted this way. Miasma production consumes oxygen and will not be produced from bodies in space or the oxygen level reaches a partial pressure of 18 kPa. | ||
Export price per mol: 10 credits. | Export price per mol: 10 credits. | ||
===[[File:Dilithium_canister.png]]Dilithium=== | ===[[File:Dilithium_canister.png]]Dilithium=== | ||
Dilithium is procured from lavaland crystals by miners, then stuffed into a blender and mixed with water. This way, each crystal generates about 200 moles of gas. It lowers the temperature threshold required for fusion asymptotically to 425K depending on the amount. This makes it completely impractical and useless, unless it's used with a ''very specific and complicated Supermatter Engine setup''... | Dilithium is procured from lavaland crystals by miners, then stuffed into a blender and mixed with water. This way, each crystal generates about 200 moles of gas. It lowers the temperature threshold required for fusion asymptotically to 425K depending on the amount. This makes it completely impractical and useless, unless it's used with a ''very specific and complicated Supermatter Engine setup''... | ||
===[[File:Freon.png]]Freon=== | ===[[File:Freon.png]]Freon=== | ||
On temperature lower than 0°C (273.15 K) Freon will create an endothermic reaction with O<sub>2</sub>, meaning it will absorb heat from the atmosphere, down to a minimum close to 50K. Adding Proto-Nitrate will catalyse the reaction so that it may begin at temperatures up to 310 kelvin, which is above room temperature. This reaction produces CO<sub>2</sub> and if the temperature is between 120-160K the reaction has a small chance to also produce solid sheets of hot ice . | On temperature lower than 0°C (273.15 K) Freon will create an endothermic reaction with O<sub>2</sub>, meaning it will absorb heat from the atmosphere, down to a minimum close to 50K. Adding Proto-Nitrate will catalyse the reaction so that it may begin at temperatures up to 310 kelvin, which is above room temperature. This reaction produces CO<sub>2</sub> and if the temperature is between 120-160K the reaction has a small chance to also produce solid sheets of hot ice . | ||
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'''Export price per mol:''' 15 credits | '''Export price per mol:''' 15 credits | ||
==== Hot Ice ==== | ==== Hot Ice ==== | ||
Hot ice is a solid byproduct of the cooled Freon+O<sub>2</sub> reaction at 120-160K. Can be sold to cargo at a high price. It holds a great amount of power inside. Can be ground to produce 25 units of Hot Ice Slush. | Hot ice is a solid byproduct of the cooled Freon+O<sub>2</sub> reaction at 120-160K. Can be sold to cargo at a high price. It holds a great amount of power inside. Can be ground to produce 25 units of Hot Ice Slush. | ||
If hit with a welder or burned the hot ice will melt, releasing the power stored inside. This releases large amounts of hot plasma into the air. (''Moles of plasma released = 150 '''x''' number of sheets'') and (''Heat released = 20 '''x''' number of sheets '''+''' 300K''). | If hit with a welder or burned the hot ice will melt, releasing the power stored inside. This releases large amounts of hot plasma into the air. (''Moles of plasma released = 150 '''x''' number of sheets'') and (''Heat released = 20 '''x''' number of sheets '''+''' 300K''). | ||
===[[File:H2.png]]Hydrogen=== | ===[[File:H2.png]]Hydrogen=== | ||
Hydrogen is a flammable gas which when ignited burns similarly to tritium. It is also an integral part of fusion reactions. Hydrogen is made by electrolizing Water Vapor with an electrolyzer machine. Hydrogen is solidified in a reaction with BZ as catalyst at high heat and pressure (over 1e6 for both) to produce metal hydrogen , which can be used to make armor, a fireaxe , and golems. | Hydrogen is a flammable gas which when ignited burns similarly to tritium. It is also an integral part of fusion reactions. Hydrogen is made by electrolizing Water Vapor with an electrolyzer machine. Hydrogen is solidified in a reaction with BZ as catalyst at high heat and pressure (over 1e6 for both) to produce metal hydrogen , which can be used to make armor, a fireaxe , and golems. | ||
'''Export price per mol:''' 1 credits | '''Export price per mol:''' 1 credits | ||
===[[File:Healium.png]]Healium=== | ===[[File:Healium.png]]Healium=== | ||
Healium is a red gas which acts as a stronger sleeping agent than N<sub>2</sub>0, while healing burns, bruises, suffocation and toxin damage. It is created by exposing Freon to BZ in an exothermic reaction at temperatures between 25-300 Kelvin (keep it chill). Freon is consumed at around 11x the rate of BZ. | Healium is a red gas which acts as a stronger sleeping agent than N<sub>2</sub>0, while healing burns, bruises, suffocation and toxin damage. It is created by exposing Freon to BZ in an exothermic reaction at temperatures between 25-300 Kelvin (keep it chill). Freon is consumed at around 11x the rate of BZ. | ||
'''Export price per mol:''' 19 credits | '''Export price per mol:''' 19 credits | ||
===[[File:Pluonium.png]]Pluonium=== | ===[[File:Pluonium.png]]Pluonium=== | ||
Pluonium is a highly reactive gas, but non-toxic when breathed. It is created in an endothermic reaction when Pluoxium is exposed to H<sub>2</sub> at temperatures between 5000-10000 K. Hydrogen is consumed at around 10x the rate of Pluoxium. | Pluonium is a highly reactive gas, but non-toxic when breathed. It is created in an endothermic reaction when Pluoxium is exposed to H<sub>2</sub> at temperatures between 5000-10000 K. Hydrogen is consumed at around 10x the rate of Pluoxium. | ||
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'''Export price per mol:''' 5 credits | '''Export price per mol:''' 5 credits | ||
===[[File:Halon.png]]Halon=== | ===[[File:Halon.png]]Halon=== | ||
Halon acts as a fire suppressant by removing oxygen in the air (while producing CO2) in an exothermic reaction if the air temperature is above 100 C or 373.15 K. The oxygen suppresion rate is 20 O2 : 1 Halon. It is created by combining BZ and Tritium in an endothermic reaction between 30-55 K. Tritium is consumed at around 16x the rate of BZ. | Halon acts as a fire suppressant by removing oxygen in the air (while producing CO2) in an exothermic reaction if the air temperature is above 100 C or 373.15 K. The oxygen suppresion rate is 20 O2 : 1 Halon. It is created by combining BZ and Tritium in an endothermic reaction between 30-55 K. Tritium is consumed at around 16x the rate of BZ. | ||
'''Export price per mol:''' 9 credits | '''Export price per mol:''' 9 credits | ||
===[[File:Zauker.png]]Zauker=== | ===[[File:Zauker.png]]Zauker=== | ||
Zauker is an incredibly deadly gas if inhaled. It is made by mixing Hyper-Noblium and Stimulum in an endothermic reaction at temperatures between 50000-75000 K. Stimulum is consumed at around 50x the rate of Hyper-Noblium. It is worthy to note that Noblium stops reactions when it is present in quantities above 5 moles, prepare accordingly! | Zauker is an incredibly deadly gas if inhaled. It is made by mixing Hyper-Noblium and Stimulum in an endothermic reaction at temperatures between 50000-75000 K. Stimulum is consumed at around 50x the rate of Hyper-Noblium. It is worthy to note that Noblium stops reactions when it is present in quantities above 5 moles, prepare accordingly! | ||
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Zauker also decomposes exothermically into a 30/70 O2/N2 mix when exposed to Nitrogen. | Zauker also decomposes exothermically into a 30/70 O2/N2 mix when exposed to Nitrogen. | ||
'''Export price per mol:''' 1050 credits | '''Export price per mol:''' 1050 credits | ||
===[[File:Hexane.png]]Hexane=== | ===[[File:Hexane.png]]Hexane=== | ||
Hexane is a very dangerous gas that makes you hallucinate, gives you brain damage (33% chance to do 5 damage every time you breathe it in until you hit 150 damage), prevents you from using changeling chat, gives you a slow down and lets you see dead chat. | Hexane is a very dangerous gas that makes you hallucinate, gives you brain damage (33% chance to do 5 damage every time you breathe it in until you hit 150 damage), prevents you from using changeling chat, gives you a slow down and lets you see dead chat. | ||
'''Export price per mol:''' TBD | '''Export price per mol:''' TBD | ||
==The Atmos Devices== | ==The Atmos Devices== | ||
'''This will be a section detailing the overall function, and some specifics, of the various pipes, pumps, and other devices. Some details will be missed, but it will provide a basis. The first instance of a device running into a unique mechanic will be explained in further length.''' | '''This will be a section detailing the overall function, and some specifics, of the various pipes, pumps, and other devices. Some details will be missed, but it will provide a basis. The first instance of a device running into a unique mechanic will be explained in further length.''' | ||
===[[File:Dvalve.webp|frameless]]Digital Valve=== | ===[[File:Dvalve.webp|frameless]]Digital Valve=== | ||
A valve that opens when clicked, and connects the two pipenets it separates when doing so. A pipenet is any collection of normal pipes connected together, including some sub types. Counter to pumps, it experiences no delay in its gas transfer. It essentially acts as a pipe, which, as all pipes, transfers gas instantly to all connected pipes. Has 200L of volume on one side, and 200L on the other end. This can be operated by both carbon mobs such as humans, excluding xenomorphs, and silicons. | A valve that opens when clicked, and connects the two pipenets it separates when doing so. A pipenet is any collection of normal pipes connected together, including some sub types. Counter to pumps, it experiences no delay in its gas transfer. It essentially acts as a pipe, which, as all pipes, transfers gas instantly to all connected pipes. Has 200L of volume on one side, and 200L on the other end. This can be operated by both carbon mobs such as humans, excluding xenomorphs, and silicons. | ||
===[[File:Pvalve.webp|frameless]]Pressure Valve=== | ===[[File:Pvalve.webp|frameless]]Pressure Valve=== | ||
An activatable valve that lets gas pass through if the pressure on the input side is higher than the set pressure. Good for situations where you need to relieve | An activatable valve that lets gas pass through if the pressure on the input side is higher than the set pressure. Good for situations where you need to relieve | ||
===[[File:Mvalve.webp|frameless]]Manual Valve=== | ===[[File:Mvalve.webp|frameless]]Manual Valve=== | ||
Acts identically to a Digital Valve, however, the manual valve does not allow silicons to operate it. Good for when you do not want the AI interfering with atmos. | Acts identically to a Digital Valve, however, the manual valve does not allow silicons to operate it. Good for when you do not want the AI interfering with atmos. | ||
===[[File:Ppump.png|frameless]]Pressure Pump=== | ===[[File:Ppump.png|frameless]]Pressure Pump=== | ||
An oddball case. Like all pumps, it separates connected pipenets if there is nothing else connecting them. Has a maximum pressure of 4500 kPa. All pumps work by pumping the contents within them to the other side, which is 200L on one side, and 200L on the other. Any pump can not pump gas that is not actually in it, which means that very large connected pipenets will have lower pump speeds. Pressure pumps work by gradually building up to its set pressure per tick. Because of this, pressure pumps slow down when approaching their target pressure, and will not quite match their pressure after a very long time, but will get very close. | An oddball case. Like all pumps, it separates connected pipenets if there is nothing else connecting them. Has a maximum pressure of 4500 kPa. All pumps work by pumping the contents within them to the other side, which is 200L on one side, and 200L on the other. Any pump can not pump gas that is not actually in it, which means that very large connected pipenets will have lower pump speeds. Pressure pumps work by gradually building up to its set pressure per tick. Because of this, pressure pumps slow down when approaching their target pressure, and will not quite match their pressure after a very long time, but will get very close. | ||
===[[File:Vpump.webp|frameless]]Volume Pump=== | ===[[File:Vpump.webp|frameless]]Volume Pump=== | ||
The volume pump is similar to the pressure pump, but operates differently. It has a pressure limit of 9000 kPa. However, this limit only kicks in when the output pipenet is currently over 9000 kPa. The pump will work if the output pipenet is below 9000 kPa, even if the resulting pressure of this action would be way higher than 9000 kPa. Counter to the pressure pump, this pump works on a L/s basis. This has a 2x200L volume as well, so you pick how much of the volume in the pump is actually pumped to the other side by changing the number. Because its max speed is 200 L/s, it will always outpace and outpressure the pressure pump. Can be overclocked using a multitool, which will cause its pressure limit to be dependent on the input pipenet, which will tend to make the maximum output pressure higher. However, this will cause 10% of gas running through it to spill. | The volume pump is similar to the pressure pump, but operates differently. It has a pressure limit of 9000 kPa. However, this limit only kicks in when the output pipenet is currently over 9000 kPa. The pump will work if the output pipenet is below 9000 kPa, even if the resulting pressure of this action would be way higher than 9000 kPa. Counter to the pressure pump, this pump works on a L/s basis. This has a 2x200L volume as well, so you pick how much of the volume in the pump is actually pumped to the other side by changing the number. Because its max speed is 200 L/s, it will always outpace and outpressure the pressure pump. Can be overclocked using a multitool, which will cause its pressure limit to be dependent on the input pipenet, which will tend to make the maximum output pressure higher. However, this will cause 10% of gas running through it to spill. | ||
===[[File:Pgate.webp|frameless]]Passive Gate=== | ===[[File:Pgate.webp|frameless]]Passive Gate=== | ||
These are a combination of pumps and valves. They work up to their set pressure, with a maximum of 4500 kPa. These can never do more than equalise the two connected pipenets, just as valves do. However, they only work one way, rather than mixing the gas between the two pipenets perfectly as valves do. Very rarely used as the pressure valve tends to fill most of its use cases, but can be used in situations where one needs pressure control for a pipenet that needs to remain between two values, the upper bound being the set pressure and the lower bound being the output pipenet pressure, such as a BZ reactor. | These are a combination of pumps and valves. They work up to their set pressure, with a maximum of 4500 kPa. These can never do more than equalise the two connected pipenets, just as valves do. However, they only work one way, rather than mixing the gas between the two pipenets perfectly as valves do. Very rarely used as the pressure valve tends to fill most of its use cases, but can be used in situations where one needs pressure control for a pipenet that needs to remain between two values, the upper bound being the set pressure and the lower bound being the output pipenet pressure, such as a BZ reactor. | ||
===Temperature Gate=== | ===Temperature Gate=== | ||
A gate that only lets gas through when they are on one side of the set temperature threshold (either greater, or lower). The mode can be changed by using a multitool on the device. Excellent for precise thermal regulation and failsafes for the SM engine. | A gate that only lets gas through when they are on one side of the set temperature threshold (either greater, or lower). The mode can be changed by using a multitool on the device. Excellent for precise thermal regulation and failsafes for the SM engine. | ||
===[[File:Vent.webp|frameless]]Unary Vent=== | ===[[File:Vent.webp|frameless]]Unary Vent=== | ||
The vent will pump gas into the room it is in, depending on the air alarm settings of the room. The air alarm has two settings to worry about, External, or Internal. External works by making the vent pump gas from its connected pipenet into the room until the room, or more accurately, the tile, matches the pressure that is set. The max pressure you can configure for External is 5066 kPa, and it slows down when approaching the set limit, as pressure pumps do. Internal works by pumping gas into the room from the pipenet until the pressure set matches the pressure in the connected pipenet. Examples: a vent set to External 200 will pump gas into the room until it is 200 kPa. A vent set to Internal 300 will pump gas into the room until the connected pipenet's pressure is 300 kPa, regardless of room pressure. As such, Internal 0 will always pump at full strength. This same effect can be achieved by turning off both External and Internal. The vent has a maximum speed it can pump at, even when extremely pressurised. | The vent will pump gas into the room it is in, depending on the air alarm settings of the room. The air alarm has two settings to worry about, External, or Internal. External works by making the vent pump gas from its connected pipenet into the room until the room, or more accurately, the tile, matches the pressure that is set. The max pressure you can configure for External is 5066 kPa, and it slows down when approaching the set limit, as pressure pumps do. Internal works by pumping gas into the room from the pipenet until the pressure set matches the pressure in the connected pipenet. Examples: a vent set to External 200 will pump gas into the room until it is 200 kPa. A vent set to Internal 300 will pump gas into the room until the connected pipenet's pressure is 300 kPa, regardless of room pressure. As such, Internal 0 will always pump at full strength. This same effect can be achieved by turning off both External and Internal. The vent has a maximum speed it can pump at, even when extremely pressurised. | ||
===[[File:Injector atmos.webp|frameless]]Injector=== | ===[[File:Injector atmos.webp|frameless]]Injector=== | ||
The injector is similar to the vent in that it pumps gas onto the tile it is on. However, it is not controlled by an air alarm, but rather works by hand. It is also in L/s units again, similarly to the volume pump. Also similarly to the volume pump, it is the faster one when compared to its pressure based cousin, the vent. It does not have a maximum pressure change per second, as vents do, and will always outpace them. This comes at the cost of the control that vents give you. | The injector is similar to the vent in that it pumps gas onto the tile it is on. However, it is not controlled by an air alarm, but rather works by hand. It is also in L/s units again, similarly to the volume pump. Also similarly to the volume pump, it is the faster one when compared to its pressure based cousin, the vent. It does not have a maximum pressure change per second, as vents do, and will always outpace them. This comes at the cost of the control that vents give you. | ||
===[[File:Scrubber.png|frameless]]Scrubber=== | ===[[File:Scrubber.png|frameless]]Scrubber=== | ||
The gas sucking cousin of the vent, which sucks gas into the connected pipenet. Scrubbers are operated using the connected air alarm. They only suck in gas that is on their tile, unless you set their range to Expanded, in which case it'll suck in a 3x3. Setting them to Siphon will make them suck in every gas. If the scrubber is not on siphon, you can select specific gases for it to suck into its pipenet. Maximum pressure they can reach in the internal pipenet is 5066kpa before they stop scrubbing/siphoning, very important for SM engines! | The gas sucking cousin of the vent, which sucks gas into the connected pipenet. Scrubbers are operated using the connected air alarm. They only suck in gas that is on their tile, unless you set their range to Expanded, in which case it'll suck in a 3x3. Setting them to Siphon will make them suck in every gas. If the scrubber is not on siphon, you can select specific gases for it to suck into its pipenet. Maximum pressure they can reach in the internal pipenet is 5066kpa before they stop scrubbing/siphoning, very important for SM engines! | ||
===[[File:Heat Exchanger.png|frameless]]Heat Exchanger=== | ===[[File:Heat Exchanger.png|frameless]]Heat Exchanger=== | ||
Place two of these next to each other, facing each other, and they will equalize the temperature of the gases inside them. The heat exchanger is not part of the heat exchange pipes system and therefore does not bleed heat into its turf. | Place two of these next to each other, facing each other, and they will equalize the temperature of the gases inside them. The heat exchanger is not part of the heat exchange pipes system and therefore does not bleed heat into its turf. | ||
===[[File:Atmosfilter.png|frameless]]Filter=== | ===[[File:Atmosfilter.png|frameless]]Filter=== | ||
The filter is the first device that connects 3 pipenets. It can be set to a single gas, and it will dump this gas to the side it is pointing in. All gas that is not selected will continue straight forward, as the arrow is pointing in a single line. When set to Nothing, it will allow all gas through the straight path. The filter works in L/s, and as such does not experience pressure related slowdowns, however, it has a pressure maximum of 4500 kPa. When EITHER OUTPUT SIDE is 4500 kPa or above, the filter will not function, not allowing any gas to pas. That is, both in a straight line and on its offshoot, the pressure must be less than 4500 kPa. | The filter is the first device that connects 3 pipenets. It can be set to a single gas, and it will dump this gas to the side it is pointing in. All gas that is not selected will continue straight forward, as the arrow is pointing in a single line. When set to Nothing, it will allow all gas through the straight path. The filter works in L/s, and as such does not experience pressure related slowdowns, however, it has a pressure maximum of 4500 kPa. When EITHER OUTPUT SIDE is 4500 kPa or above, the filter will not function, not allowing any gas to pas. That is, both in a straight line and on its offshoot, the pressure must be less than 4500 kPa. | ||
===[[File:Atmosmixer.png|frameless]]Mixer=== | ===[[File:Atmosmixer.png|frameless]]Mixer=== | ||
The mixer also requires 3 connections to function, as the filter does. The mixer will mix the two incoming gases using the ratio the user inputs, starts off at 50/50. Node 1 is the input in a straight line with the ouput, Node 2 is the offshoot compared to the output. Both inputs need to have gas in them to function unless a side with gas in it is set to 100%, in which case it will function and purely let that side through. Is pressure based, with the associated properties. Also has a pressure maximum of 4500 kPa. The mixing is influenced by temperature following the ideal gas law. When one of the input sides is hotter compared to the other input, it will let less of this side's gas through, mol-wise. This will give you scuffed ratios if you do not equalise temperatures, if you need the precision, make sure they're equal. | The mixer also requires 3 connections to function, as the filter does. The mixer will mix the two incoming gases using the ratio the user inputs, starts off at 50/50. Node 1 is the input in a straight line with the ouput, Node 2 is the offshoot compared to the output. Both inputs need to have gas in them to function unless a side with gas in it is set to 100%, in which case it will function and purely let that side through. Is pressure based, with the associated properties. Also has a pressure maximum of 4500 kPa. The mixing is influenced by temperature following the ideal gas law. When one of the input sides is hotter compared to the other input, it will let less of this side's gas through, mol-wise. This will give you scuffed ratios if you do not equalise temperatures, if you need the precision, make sure they're equal. | ||
===[[File:HEpipe.png|frameless]]Heat Exchange pipes=== | ===[[File:HEpipe.png|frameless]]Heat Exchange pipes=== | ||
Functions like regular pipe, however, this will attempt to equalise the temperature between the pipenet and the space it is in. This is based on heat capacity, which can be found on this page. Higher heat capacity means a gas will soak in more energy, which means it is better at cooling when cold, and better at heating when hot. These pipes commonly see use in Supermatter setups, to cool down the coolant by using these pipes in space. However, they can also be used to heat up places, of course. Has a 10K efficiency loss. Space is 2.7K, but heat exchange pipes will only cool the gas in them to be about 12.7K. | Functions like regular pipe, however, this will attempt to equalise the temperature between the pipenet and the space it is in. This is based on heat capacity, which can be found on this page. Higher heat capacity means a gas will soak in more energy, which means it is better at cooling when cold, and better at heating when hot. These pipes commonly see use in Supermatter setups, to cool down the coolant by using these pipes in space. However, they can also be used to heat up places, of course. Has a 10K efficiency loss. Space is 2.7K, but heat exchange pipes will only cool the gas in them to be about 12.7K. | ||
===[[File:HEjunc.png|frameless]]Heat Exchange Junction=== | ===[[File:HEjunc.png|frameless]]Heat Exchange Junction=== | ||
These are used to transfer from normal pipes to heat exchange pipes. These need to be between a pipe, or pump, etc. and heat exchange pipes for gas to actually be transferred between the two different kinds of pipe. While this pipe looks partially like a heat exchange pipe, it does not equalise temperature in the way that heat exchanging pipes do. It only looks like it does, so these can be safely connected to any pipe in a normal room without risk. | These are used to transfer from normal pipes to heat exchange pipes. These need to be between a pipe, or pump, etc. and heat exchange pipes for gas to actually be transferred between the two different kinds of pipe. While this pipe looks partially like a heat exchange pipe, it does not equalise temperature in the way that heat exchanging pipes do. It only looks like it does, so these can be safely connected to any pipe in a normal room without risk. | ||
===[[File:Lmanifold.png|frameless]]Layer Manifold=== | ===[[File:Lmanifold.png|frameless]]Layer Manifold=== | ||
Connects the 5 different layers of pipenets. For most stations, the red scrubber network will be on layer 2 while the blue air supply pipes will be on layer 4. Default layer is 3. Pipes on different layers do not interact with one another. | Connects the 5 different layers of pipenets. For most stations, the red scrubber network will be on layer 2 while the blue air supply pipes will be on layer 4. Default layer is 3. Pipes on different layers do not interact with one another. | ||
==Physical Characteristics of Gases== | ==Physical Characteristics of Gases== | ||
TL;DR | TL;DR | ||
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Ideal gas law: '''''PV = nRT''''' | Ideal gas law: '''''PV = nRT''''' | ||
Where '''R (ideal, or universal, gas constant) = 8.31''', the following are linked by this equation. | Where '''R (ideal, or universal, gas constant) = 8.31''', the following are linked by this equation. | ||
'''Pressure (P)''': Measured in kPa, [http://en.wikipedia.org/wiki/Pascal_(unit) kiloPascals], Pressure is lethal above 750 kPa's. A pressure in a room above 1000 kPa's necessitates internals to breathe properly. | |||
<!-- We don't have a pressure cap on breathing air in general, just minimum O2. ~Scottzar --> | |||
'''Volume (V)''': Another unseen variable, [ | '''Volume (V)''': Another unseen variable, [http://en.wikipedia.org/wiki/Volume Volume] is how much the area/canister/tank or piped tank has space inside it. This helps dictate how much gas it can hold. Volume is essentially the 'mole divider' when converting between a canister/air pump to your tank; having a higher volume essentially makes the tank that much more efficient, proportionally, so an Extended Emergency Oxygen Tank has twice the contained air per kPa in comparison to a regular Emergency Oxygen Tank. | ||
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'''Moles (n)''': [ | '''Moles (n)''': [http://en.wikipedia.org/wiki/Mole_(unit) Moles] are the amount of particles of a gas in the air. It is moles that cause odd effects with a certain chemical. As it dumps so many moles to a tile, to keep the pressure acceptable, the moles have to be very, very cold, causing the infectious effect. Moles can be calculated by a form of the ideal gas law. n=(P*V)/(R*T) | ||
'''Temperature (T)''': Measures in K, [ | '''Temperature (T)''': Measures in K, [http://en.wikipedia.org/wiki/Kelvin Kelvin], Temperature above 360 K and below 260 K causes burn damage to humans. Bomb making usually relies on a temperature at or in excess of 90 000 K. Canisters rupture when the air surrounding them is over 1550 K. | ||
'''Heat Capacity''': A gasmix has heat capacity, and it is calculated by taking into account the quantity of all of the gases in the air and their specific heat. Heat capacity defines how much energy it takes to raise the temperature of a gas. The normal air mix (%30 O2, %70 N2) has a specific heat capacity of about 20 which doesn't impede heat transfer very much. Fires spreads quicker in gases with low heat capacity, and slower in gases with high heat capacity. | '''Heat Capacity''': A gasmix has heat capacity, and it is calculated by taking into account the quantity of all of the gases in the air and their specific heat. Heat capacity defines how much energy it takes to raise the temperature of a gas. The normal air mix (%30 O2, %70 N2) has a specific heat capacity of about 20 which doesn't impede heat transfer very much. Fires spreads quicker in gases with low heat capacity, and slower in gases with high heat capacity. | ||
{| class="wikitable sortable mw-collapsible mw-collapsed" | {| class="wikitable sortable mw-collapsible mw-collapsed" | ||
|- | |- | ||
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|- | |- | ||
|} | |} | ||
'''Fire''': An effect caused by burning plasma, fire comes in two different forms of hotspot. It causes massive burn damage, and a strong fire will not be stopped by standard firesuits. Plumbing N2 into a room might work, but heavy firefighting is not the point of this section. Fire will ignite any form of combustibles in near tiles. Sufficiently hot fires use less oxygen as they rise in temperature. This is due to the fact that fires remove X plasma and X*(1.4-Y, Y< or = 1) oxygen. X CO2 is produced. Ideal Burnmix is: 10x more O2 than plasma, and with as high a temperature as can achieve. | '''Fire''': An effect caused by burning plasma, fire comes in two different forms of hotspot. It causes massive burn damage, and a strong fire will not be stopped by standard firesuits. Plumbing N2 into a room might work, but heavy firefighting is not the point of this section. Fire will ignite any form of combustibles in near tiles. Sufficiently hot fires use less oxygen as they rise in temperature. This is due to the fact that fires remove X plasma and X*(1.4-Y, Y< or = 1) oxygen. X CO2 is produced. Ideal Burnmix is: 10x more O2 than plasma, and with as high a temperature as can achieve. | ||
<!-- Not too much more to say, but you're welcome to codebrowse for the variables I've indicated with x, y and similar. Hawk. --> | |||
'''In short the colder the gas and the higher the container volume, the more moles you can fit inside.''' This is why hot gases clog the red waste pipes - they expand, allowing fewer moles to be transported. | |||
==Atmospherics Layout== | ==Atmospherics Layout== | ||
{| class="wikitable" | {| class="wikitable" | ||
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Atmospherics is pretty simple, but the pipe layout makes it slightly confusing for the untrained eye. There are 4 major pipe "loops": | Atmospherics is pretty simple, but the pipe layout makes it slightly confusing for the untrained eye. There are 4 major pipe "loops": | ||
<br><br> | <br><br> | ||
*The '''<span style="color:blue">dark blue pipe loop</span>''' is the distribution loop. It sends air to all the vents on the station for the crew to breathe. | *The '''<span style="color:blue">dark blue pipe loop</span>''' is the distribution loop. It sends air to all the vents on the station for the crew to breathe. | ||
<br> | <br> | ||
*The '''<span style="color:cyan">cyan air mix pipe loop</span>''', which is specialized to mix and provide the air mix to the distribution loop, and is used to fill air pumps outside the front door of Atmospherics. | *The '''<span style="color:cyan">cyan air mix pipe loop</span>''', which is specialized to mix and provide the air mix to the distribution loop, and is used to fill air pumps outside the front door of Atmospherics. | ||
<br> | <br> | ||
*The '''<span style="color:red">red/<span style="color:green">green</span></span> pipe loop''', which retrieves the gas in the station via the air scrubbers (red loop) and passes them through a set of filters (green loop). | *The '''<span style="color:red">red/<span style="color:green">green</span></span> pipe loop''', which retrieves the gas in the station via the air scrubbers (red loop) and passes them through a set of filters (green loop). | ||
<br> | <br> | ||
*The '''<span style="color:yellow">yellow</span> pipe loop''', internal to Atmospherics, which is used for custom gas mixes that can be fed into the canister charging station in the middle of atmospherics, or fed into the mixing tank. | *The '''<span style="color:yellow">yellow</span> pipe loop''', internal to Atmospherics, which is used for custom gas mixes that can be fed into the canister charging station in the middle of atmospherics, or fed into the mixing tank. | ||
<br> | <br> | ||
The tanks (the small rooms in space just outside of Atmos) of the station's atmospherics network, unlike in the rest of the station, are rooms filled with very high pressure of the appropriate gas. The output of these rooms are controlled by their respective Supply Control Computer, an on/off valve, and an output pump for each loop. Note that '''these rooms can be depleted''', especially if [[Traitor|someone]] makes a hole in a tank's external wall. | The tanks (the small rooms in space just outside of Atmos) of the station's atmospherics network, unlike in the rest of the station, are rooms filled with very high pressure of the appropriate gas. The output of these rooms are controlled by their respective Supply Control Computer, an on/off valve, and an output pump for each loop. Note that '''these rooms can be depleted''', especially if [[Traitor|someone]] makes a hole in a tank's external wall. | ||
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To understand how the breatheable air mix is mixed, try following these steps and looking at the map at the same time, it starts on the south end of Atmospherics, like so: | To understand how the breatheable air mix is mixed, try following these steps and looking at the map at the same time, it starts on the south end of Atmospherics, like so: | ||
#The gasses are pumped through the '''<span style="color:cyan">cyan tubes</span>''' from their respective tanks ('''N2''', '''O2'''). | |||
#The gasses are pumped through the '''<span style="color:cyan">cyan tubes</span>''' from their respective tanks ('''N2''', '''O2'''). | |||
#They are mixed in the air tank ('''Air''') to a 1/5 mix of O2 and N2. | #They are mixed in the air tank ('''Air''') to a 1/5 mix of O2 and N2. | ||
#The breathable gas is then pumped through the '''<span style="color:cyan">cyan loop</span>''' to the north of Atmospherics. | #The breathable gas is then pumped through the '''<span style="color:cyan">cyan loop</span>''' to the north of Atmospherics. | ||
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Next let's make up an example situation to see how the waste system works in action: | Next let's make up an example situation to see how the waste system works in action: | ||
#Scientist Bill messes up and fills the [[Toxins Lab]] with plasma but fortunately manages to evacuate the room safely. | #Scientist Bill messes up and fills the [[Toxins Lab]] with plasma but fortunately manages to evacuate the room safely. | ||
#Being an otherwise ideal situation Atmos-wise, the Toxins Lab's air scrubbers have been set to filter out all hazardous gases (they're not set by default, this has to be done through the Air Alarm manually or by asking the AI to do it) and plasma starts to get sucked through the scrubber into the waste pipes. | #Being an otherwise ideal situation Atmos-wise, the Toxins Lab's air scrubbers have been set to filter out all hazardous gases (they're not set by default, this has to be done through the Air Alarm manually or by asking the AI to do it) and plasma starts to get sucked through the scrubber into the waste pipes. | ||
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==Setting Up Atmospherics== | ==Setting Up Atmospherics== | ||
It's about time we stop with the theory <s>and throw it out the window</s> and get down to business. The two machines at the top can dispense infinite pipes, and your wrench can disconnect and connect pipes to each other. Remember, you cannot disconnect pumps if they have too much pressure in them. | It's about time we stop with the theory <s>and throw it out the window</s> and get down to business. The two machines at the top can dispense infinite pipes, and your wrench can disconnect and connect pipes to each other. Remember, you cannot disconnect pumps if they have too much pressure in them. | ||
[[File:AtmosDerp.png|thumb|300px|right|The dumbass-version of the Atmospheric pipe system. See the steps what each colored circle means. {{Outdated}}]] | [[File:AtmosDerp.png|thumb|300px|right|The dumbass-version of the Atmospheric pipe system. See the steps what each colored circle means. {{Outdated}}]] | ||
Next up is a very simple step by step guide how to set up the Atmospherics pipe system to be (nearly) as efficient as possible. Note that this is only one style how to set up the pipes, there are many ways and they all have their own pros and cons! | Next up is a very simple step by step guide how to set up the Atmospherics pipe system to be (nearly) as efficient as possible. Note that this is only one style how to set up the pipes, there are many ways and they all have their own pros and cons! | ||
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*'''For the love of Nanotrasen, at least do this:''' | *'''For the love of Nanotrasen, at least do this:''' | ||
#Get a Volume Pump from the [[Pipe Dispenser]] at the north side of Atmos and replace the '''<span style="color:green">green circled</span>''' normal pump with a volume pump, making the waste gas -system >100x more efficient. We want the waste gas sucked from the station into the waste system as soon as possible! | #Get a Volume Pump from the [[Pipe Dispenser]] at the north side of Atmos and replace the '''<span style="color:green">green circled</span>''' normal pump with a volume pump, making the waste gas -system >100x more efficient. We want the waste gas sucked from the station into the waste system as soon as possible! | ||
#Set all '''<span style="color:red">red circled</span>''' filters ON and set them to maximum pressure (4500 kPa) so waste gases will actually be moved. | #Set all '''<span style="color:red">red circled</span>''' filters ON and set them to maximum pressure (4500 kPa) so waste gases will actually be moved. | ||
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*'''This is good as well:''' | *'''This is good as well:''' | ||
#Go through the N2 and O2 (besides southern wall) and set their output to 4500 kPa. | #Go through the N2 and O2 (besides southern wall) and set their output to 4500 kPa. | ||
#Set the pumps next to the computers at 4500 kPa also, so the gases being pushed out of the gas-room get moved fast too. | #Set the pumps next to the computers at 4500 kPa also, so the gases being pushed out of the gas-room get moved fast too. | ||
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'''Pros and cons of this whole setup:''' | '''Pros and cons of this whole setup:''' | ||
::'''+ Quick toxin filtering:''' In case of a toxin leak, waste gas will be sucked out quickly (if the area's air alarms are set to filter out all the toxins, that is, by default they are NOT filtering anything). | ::'''+ Quick toxin filtering:''' In case of a toxin leak, waste gas will be sucked out quickly (if the area's air alarms are set to filter out all the toxins, that is, by default they are NOT filtering anything). | ||
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::'''- Air Alarm sabotages:''' The station is more vulnerable for sabotage through [[Air alarm|air alarms]]. Someone can quite easily hack an air alarm somewhere and set the vents to push out air at maximum pressure, resulting in overpressurization. | ::'''- Air Alarm sabotages:''' The station is more vulnerable for sabotage through [[Air alarm|air alarms]]. Someone can quite easily hack an air alarm somewhere and set the vents to push out air at maximum pressure, resulting in overpressurization. | ||
::'''- Space wind:''' In case of a breach, until the hole is fixed, you'll probably spend a small while fighting against the huge air current, a.k.a. "space wind", if you don't switch the vents off during the repair. This is mostly just annoying. | ::'''- Space wind:''' In case of a breach, until the hole is fixed, you'll probably spend a small while fighting against the huge air current, a.k.a. "space wind", if you don't switch the vents off during the repair. This is mostly just annoying. | ||
::'''- Very slow pipe manipulating:''' If you suddenly have to modify any of the distribution pipes around the station, you need to lower the pressure to under 303.9 kPa if you don't want to be flung around like a leaf in the space wind, which can take a long time. | ::'''- Very slow pipe manipulating:''' If you suddenly have to modify any of the distribution pipes around the station, you need to lower the pressure to under 303.9 kPa if you don't want to be flung around like a leaf in the space wind, which can take a long time. | ||
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Done correctly, Atmosia should be pumping good air just faster than it's lost, and draining bad air away as fast as the traitors can set it on fire or alternatively draining good air away as fast as a malf AI can siphon it. You can go kick back in the bar like a boss and wait for the inevitable minor station damage and cries of "Call the shuttle!" on the radio from folks who don't even know it ain't a big deal. | Done correctly, Atmosia should be pumping good air just faster than it's lost, and draining bad air away as fast as the traitors can set it on fire or alternatively draining good air away as fast as a malf AI can siphon it. You can go kick back in the bar like a boss and wait for the inevitable minor station damage and cries of "Call the shuttle!" on the radio from folks who don't even know it ain't a big deal. | ||
==After the Work is Done== | ==After the Work is Done== | ||
There is a short list of things which fall under your stead: | There is a short list of things which fall under your stead: | ||
*First and by far most important: make sure pipes don't get broken and if they do, fix them. | *First and by far most important: make sure pipes don't get broken and if they do, fix them. | ||
*Go around swiping your ID on [[Air Alarm]]s, setting the operating mode to contaminated, and then re-swiping to lock it. You can ask the AI to do this as well, and probably should. | *Go around swiping your ID on [[Air Alarm]]s, setting the operating mode to contaminated, and then re-swiping to lock it. You can ask the AI to do this as well, and probably should. | ||
*Fill all the air pumps with air using a volume pump (more air pumps can be found from the locker room). | *Fill all the air pumps with air using a volume pump (more air pumps can be found from the locker room). | ||
*Make extremely extended oxygen tanks for internals use (instructions below). | *Make extremely extended oxygen tanks for internals use (instructions below). | ||
#Go to the red lockers, get a hard hat, gas mask and everything else that might be of use. Remember that you need both a fire suit and a hard hat to be resistant to weak fires. One will be useless without the other. | #Go to the red lockers, get a hard hat, gas mask and everything else that might be of use. Remember that you need both a fire suit and a hard hat to be resistant to weak fires. One will be useless without the other. | ||
#Go grab the Fire Axe from the wall mount and hide it somewhere so the [[Clown|chucklefucks]] won't get it and go killing. DON'T take it with you and go walking through the hallways trying to look like a badass, you'll be the prime target of any antagonist/griffon who needs an efficient weapon. | #Go grab the Fire Axe from the wall mount and hide it somewhere so the [[Clown|chucklefucks]] won't get it and go killing. DON'T take it with you and go walking through the hallways trying to look like a badass, you'll be the prime target of any antagonist/griffon who needs an efficient weapon. | ||
*Least importantly, maintain the disposals system. You can generate pipes, but it needs welding and is generally a pain in the ass. You can also make fun slides, though. | *Least importantly, maintain the disposals system. You can generate pipes, but it needs welding and is generally a pain in the ass. You can also make fun slides, though. | ||
===Optimizing Internals=== | ===Optimizing Internals=== | ||
*On a basic view, a 16 kPa minimum O2 requirement in internals. Pure O2 is theoretically toxic in real life, but has no representation for this in code, and takes a while to be really dangerous anyway (they use it to treat certain diseases, for example), and thus using a tank filled with air for internals is fairly inefficient. | *On a basic view, a 16 kPa minimum O2 requirement in internals. Pure O2 is theoretically toxic in real life, but has no representation for this in code, and takes a while to be really dangerous anyway (they use it to treat certain diseases, for example), and thus using a tank filled with air for internals is fairly inefficient. | ||
*Cold O2 has more moles per kPa, and because people breathe in moles, and filling tanks usefully for internals are largely capped by the 1000 kPa release pressure, means cooling your O2 before using it in internals is important! Cooled down O2, such as from a freezer-ed canister, is the most efficient way to set up internals. Cooling it below 264 K will result in icicles inside in your lungs, though! | *Cold O2 has more moles per kPa, and because people breathe in moles, and filling tanks usefully for internals are largely capped by the 1000 kPa release pressure, means cooling your O2 before using it in internals is important! Cooled down O2, such as from a freezer-ed canister, is the most efficient way to set up internals. Cooling it below 264 K will result in icicles inside in your lungs, though! | ||
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===Fun Projects=== | ===Fun Projects=== | ||
*The Atmospherics system is far from optimal, and we're talking about just the pipe configuration! Break out that wrench and start experimenting (just make sure you know what's what)! | *The Atmospherics system is far from optimal, and we're talking about just the pipe configuration! Break out that wrench and start experimenting (just make sure you know what's what)! | ||
*Extremely high-temperature gases (like those from a panic siphoned fire) can really clog the waste loop. Could you do something to correct that? | *Extremely high-temperature gases (like those from a panic siphoned fire) can really clog the waste loop. Could you do something to correct that? | ||
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*The brigs distribution system is set up to be potentially independent of the rest of the station's distribution loop, maybe other places can be set up like this as well? | *The brigs distribution system is set up to be potentially independent of the rest of the station's distribution loop, maybe other places can be set up like this as well? | ||
*The mining station doesn't have air recycling. Very long rounds might make this a problem for any miners working there. | *The mining station doesn't have air recycling. Very long rounds might make this a problem for any miners working there. | ||
==The Less Well Known Hazards of Gases== | ==The Less Well Known Hazards of Gases== | ||
*Any gas at pressure over 1000 kPa will cause you to start suffocating as in a vacuum. You can just use internals, though. | *Any gas at pressure over 1000 kPa will cause you to start suffocating as in a vacuum. You can just use internals, though. | ||
*N2O is invisible at low pressures. If you start giggling, put on your internals to avoid passing out. | *N2O is invisible at low pressures. If you start giggling, put on your internals to avoid passing out. | ||
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==ATMOS Resin== | ==ATMOS Resin== | ||
The Backpack Firefighter Tank[[File:waterbackpack atmos.png]] can switch modes to launch transparent ATMOS resin instead of extinguisher. This resin has the following effects: | The Backpack Firefighter Tank[[File:waterbackpack atmos.png]] can switch modes to launch transparent ATMOS resin instead of extinguisher. This resin has the following effects: | ||
*Repairs hull breaches similarly to [[Guide_to_chemistry#Smart Metal Foam|Metal Foam]]. | *Repairs hull breaches similarly to [[Guide_to_chemistry#Smart Metal Foam|Metal Foam]]. | ||
*Cleans the air from toxins. | *Cleans the air from toxins. | ||
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==Useful Atmos Trivia== | ==Useful Atmos Trivia== | ||
*Your holobarriers let people walk through, yet block gases. Very useful for cleaning up Plasma spills, fixing hull breaches and keeping fires in check. | *Your holobarriers let people walk through, yet block gases. Very useful for cleaning up Plasma spills, fixing hull breaches and keeping fires in check. | ||
*Using H/E pipes in space you can cool things down to a very low temperature very quickly. By making a cross with two off them you can have two on one tile, which is known as 'sequesteral' cooling. | *Using H/E pipes in space you can cool things down to a very low temperature very quickly. By making a cross with two off them you can have two on one tile, which is known as 'sequesteral' cooling. | ||
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*A scrubber connected to a very large spaceloop is much more effective than a scrubber connected to a freezer. This is because of the added volume allowing the scubber to dump more moles of gas into the connected pipenet. | *A scrubber connected to a very large spaceloop is much more effective than a scrubber connected to a freezer. This is because of the added volume allowing the scubber to dump more moles of gas into the connected pipenet. | ||
*Using a pump of any kind after a scrubber is highly redundant and drastically lowers the effectiveness of the scrubber as it separates the pipenets and cuts off volume. The SM and the incinerator's scrubbers can be massively improved by simply replacing the pump with a straight pipe. | *Using a pump of any kind after a scrubber is highly redundant and drastically lowers the effectiveness of the scrubber as it separates the pipenets and cuts off volume. The SM and the incinerator's scrubbers can be massively improved by simply replacing the pump with a straight pipe. | ||
==Fusion== | ==Fusion== | ||
'''NOTE: The following guide covers the bare essentials of fusionv6 and should be enough for you to get started with your first few fusion canisters. The more complex bits regarding the kicked rotor, open-tile fusion and SM utilization will be provided at a later date, the essentials are being rushed out so that there's at least something there to work with.''' | '''NOTE: The following guide covers the bare essentials of fusionv6 and should be enough for you to get started with your first few fusion canisters. The more complex bits regarding the kicked rotor, open-tile fusion and SM utilization will be provided at a later date, the essentials are being rushed out so that there's at least something there to work with.''' | ||
===The fluff=== | ===The fluff=== | ||
Plasmic fusion is distinctly different from stellar nucleosynthesis in real life. While standard fusion consists of a one-way transformation of light elements into heavier elements with leftover energies being released as light and heat, Plasmic fusion uses a completely different method of converting plasma into CO2 and vice versa while consuming tritium. This process is poorly understood and subject to heavy internal debate by leading Nanotresen scientists and atmospheric technicians, as such what can be currently provided is subject to corrections once the mechanism is understood. | Plasmic fusion is distinctly different from stellar nucleosynthesis in real life. While standard fusion consists of a one-way transformation of light elements into heavier elements with leftover energies being released as light and heat, Plasmic fusion uses a completely different method of converting plasma into CO2 and vice versa while consuming tritium. This process is poorly understood and subject to heavy internal debate by leading Nanotresen scientists and atmospheric technicians, as such what can be currently provided is subject to corrections once the mechanism is understood. | ||
There are 4 requirements to plasmic fusion: Lots of plasma, lots of CO2, lots of tritium and lots of heat - the result is a LOT more heat (by several orders of magnitude), a lot less of your starting gases and enough rads to make the SM feel thoroughly inadequate. The radiation itself, while deadly enough to kill when a subject experiences 30 seconds of exposure, or is hit by even a single cluster of hyperenergetic decay particles, is a tiny threat compared to the ravaging heat of a newborn star shackled by the confines of your canister, begging to be set free and set the station ablaze. A containment failure of a fusion canister will result in severe consequences and definitely something the gods will notice, so be careful when attempting it. Also, atmos techs are a very closely-knit community and most techs who learned fusion were taught or in some way assisted by a tech who knew it beforehand, if you find a willing tech, ask him to teach you as this is an extremely dangerous and autistic activity. | There are 4 requirements to plasmic fusion: Lots of plasma, lots of CO2, lots of tritium and lots of heat - the result is a LOT more heat (by several orders of magnitude), a lot less of your starting gases and enough rads to make the SM feel thoroughly inadequate. The radiation itself, while deadly enough to kill when a subject experiences 30 seconds of exposure, or is hit by even a single cluster of hyperenergetic decay particles, is a tiny threat compared to the ravaging heat of a newborn star shackled by the confines of your canister, begging to be set free and set the station ablaze. A containment failure of a fusion canister will result in severe consequences and definitely something the gods will notice, so be careful when attempting it. Also, atmos techs are a very closely-knit community and most techs who learned fusion were taught or in some way assisted by a tech who knew it beforehand, if you find a willing tech, ask him to teach you as this is an extremely dangerous and autistic activity. | ||
===The magic ratio=== | ===The magic ratio=== | ||
Disclaimers and safety pronouncements, aside, let's get to what you actually need when doing fusion. There are different recipes for achieving fusion, but the most well-tested, consistent and widely used recipe is the '''6 plasma : 2 CO2: 1 Tritium''' recipe popularized by the first atmosians who birthed stars. One such canister should have 6000 moles of plasma, 2000 moles of CO2 and 1000 moles of tritium - the amount does not need to be exact and can vary by as much as 10% in ratio, as long as the 3:1 ratio between plasma and CO2 is preserved. Technically, a canister can fuse as long as it has a '''minimum of 250 moles of plasma, 250 moles of CO2 and 1 mole of trit''', but the results are not particularly useful or exciting. Any amount of plasma and CO2 are okay, provided that they follow the ratio, and the fusion reaction will continue until it has less than 250 moles of CO2 or plasma, or it runs out of tritium. Once your canister is nicely made, heat it up to 10.000°K via heat pipe exposure over an actively burning tritium chamber (the incinerator has all the necessary equipment, and is probably where you made your tritium to begin with), then '''please unwrench''' it when it hits the 10.000°K mark. | Disclaimers and safety pronouncements, aside, let's get to what you actually need when doing fusion. There are different recipes for achieving fusion, but the most well-tested, consistent and widely used recipe is the '''6 plasma : 2 CO2: 1 Tritium''' recipe popularized by the first atmosians who birthed stars. One such canister should have 6000 moles of plasma, 2000 moles of CO2 and 1000 moles of tritium - the amount does not need to be exact and can vary by as much as 10% in ratio, as long as the 3:1 ratio between plasma and CO2 is preserved. Technically, a canister can fuse as long as it has a '''minimum of 250 moles of plasma, 250 moles of CO2 and 1 mole of trit''', but the results are not particularly useful or exciting. Any amount of plasma and CO2 are okay, provided that they follow the ratio, and the fusion reaction will continue until it has less than 250 moles of CO2 or plasma, or it runs out of tritium. Once your canister is nicely made, heat it up to 10.000°K via heat pipe exposure over an actively burning tritium chamber (the incinerator has all the necessary equipment, and is probably where you made your tritium to begin with), then '''please unwrench''' it when it hits the 10.000°K mark. | ||
Update: The 6:2:1 ratio is still generally very successful and widely used, but a more precise method of creating mixes that work has determined that not all 6:2:1 ratios are optimal. See the section on the mathematical background for more information. If starting out, stick to 6:2:1 until you're confident enough to experiment a bit more. | Update: The 6:2:1 ratio is still generally very successful and widely used, but a more precise method of creating mixes that work has determined that not all 6:2:1 ratios are optimal. See the section on the mathematical background for more information. If starting out, stick to 6:2:1 until you're confident enough to experiment a bit more. | ||
===When it works=== | ===When it works=== | ||
You'll know you're successful when bright shiny multicolored particles start flying out of the canister. Please note that these shiny particles are extremely radioactive and just one of them hitting you is '''guaranteed fucking death''' if you aren't in a radsuit or aren't a radiation immune species such as plasmaman or preternis. | You'll know you're successful when bright shiny multicolored particles start flying out of the canister. Please note that these shiny particles are extremely radioactive and just one of them hitting you is '''guaranteed fucking death''' if you aren't in a radsuit or aren't a radiation immune species such as plasmaman or preternis. | ||
Once your canister is nice, hot, finished and ready; and you aren't a dying radioactive meatbag clinging desperately to his last vestiges of life, you may proceed to use the fusion canister for generating hypernoblium, or maybe nitryl and stimulum, in large batches, for personal consumption or shipping to cargo. A good canister of hypernoblium is easily worth half a million cargo credits, skilled atmos techs consistently make ones worth upwards of several million credits. Alternatively, you can use the fusion canister as a traitor and unleash your newborn star onto the station, killing anything and everything inside as it is engulfed in an expanding cloud of gas hotter than the heart of many suns. | Once your canister is nice, hot, finished and ready; and you aren't a dying radioactive meatbag clinging desperately to his last vestiges of life, you may proceed to use the fusion canister for generating hypernoblium, or maybe nitryl and stimulum, in large batches, for personal consumption or shipping to cargo. A good canister of hypernoblium is easily worth half a million cargo credits, skilled atmos techs consistently make ones worth upwards of several million credits. Alternatively, you can use the fusion canister as a traitor and unleash your newborn star onto the station, killing anything and everything inside as it is engulfed in an expanding cloud of gas hotter than the heart of many suns. | ||
===Help, I am glowing and my skin is made out of acid=== | ===Help, I am glowing and my skin is made out of acid=== | ||
If you are exposed to radiation without the appropriate insulation or '''hit by a particle''', do not panic, take your charcoal/antitox/anti-rad pills and you should be able to tank the toxin damage from the rads and keep some mutadone with you if you mutate (you will). If not in a rad suit, do not immediately run to medical because you will contaminate it and get '''a lot of people killed.''' Instead, scream over radio that you need radiation treatment in the form of more anti-tox or charcoal dropped off in maintenance for you to grab and use. Do not let doctors or paramedics '''get near you''', you'll only get them killed unless they're rad immune already. If hit by three of these, hope that you have enough medicine to keep you alive, as the next 10 to 20 minutes will be hell for you as your radiation damage accumulates and you mutate into a filthy subhuman. If hit by 5 or more of these, even if in a radsuit, isolate yourself and suffer a ''colorful'' death. | If you are exposed to radiation without the appropriate insulation or '''hit by a particle''', do not panic, take your charcoal/antitox/anti-rad pills and you should be able to tank the toxin damage from the rads and keep some mutadone with you if you mutate (you will). If not in a rad suit, do not immediately run to medical because you will contaminate it and get '''a lot of people killed.''' Instead, scream over radio that you need radiation treatment in the form of more anti-tox or charcoal dropped off in maintenance for you to grab and use. Do not let doctors or paramedics '''get near you''', you'll only get them killed unless they're rad immune already. If hit by three of these, hope that you have enough medicine to keep you alive, as the next 10 to 20 minutes will be hell for you as your radiation damage accumulates and you mutate into a filthy subhuman. If hit by 5 or more of these, even if in a radsuit, isolate yourself and suffer a ''colorful'' death. | ||
===I would like to understand the mathematical background of fusion dynamics and/or have severe autism=== | ===I would like to understand the mathematical background of fusion dynamics and/or have severe autism=== | ||
The deeper mathematical background of kicked rotors is not a place you generally want to go unless you're doing some extremely specific shenanigans, or want to add to the code. It has taken me a year of experimentation (sporadic, granted) and testing to understand its full nuances and explaining it in text is not something I can do well enough to teach you. Hell, it took impending retirement to get me to finish writing it down. You will need to do a significant amount of in-game testing and some research on the more mathematical parts of the internet to understand it truly, but hopefully [[AutisticFroggy/The Last Lecture|this lecture]] will help you piece it together much faster than it took me to. | The deeper mathematical background of kicked rotors is not a place you generally want to go unless you're doing some extremely specific shenanigans, or want to add to the code. It has taken me a year of experimentation (sporadic, granted) and testing to understand its full nuances and explaining it in text is not something I can do well enough to teach you. Hell, it took impending retirement to get me to finish writing it down. You will need to do a significant amount of in-game testing and some research on the more mathematical parts of the internet to understand it truly, but hopefully [[AutisticFroggy/The Last Lecture|this lecture]] will help you piece it together much faster than it took me to. | ||
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'''Tips for working with fusion''': | '''Tips for working with fusion''': | ||
*at the highest efficiency roughly 30% of the gas you use will be lost to the pump to the canister and to the heat exchanger to the can so prepare accordingly. | *at the highest efficiency roughly 30% of the gas you use will be lost to the pump to the canister and to the heat exchanger to the can so prepare accordingly. | ||
*'''Work with friends.''' It has high setup and maintenance requirements, and your fellow atmos techs, engineers and toxins scientists are all valuable resources in your pursuit of very hot things. | *'''Work with friends.''' It has high setup and maintenance requirements, and your fellow atmos techs, engineers and toxins scientists are all valuable resources in your pursuit of very hot things. | ||
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*Heat exchangers are your friend for starting your reaction. Connect it to tritium burn chamber or canister to get the heat needed to start it. | *Heat exchangers are your friend for starting your reaction. Connect it to tritium burn chamber or canister to get the heat needed to start it. | ||
*Should you want to release a canister that you used for fusion in a room full of people, consider shooting it to break it open so you aren't right next to it. | *Should you want to release a canister that you used for fusion in a room full of people, consider shooting it to break it open so you aren't right next to it. | ||
'''Beyond the basics''': | '''Beyond the basics''': | ||
*You can harness the radiation produced from fusion to produce power using rad collectors. Earn your keep as a member of engineering. Or just use it for pluoxium production. | *You can harness the radiation produced from fusion to produce power using rad collectors. Earn your keep as a member of engineering. Or just use it for pluoxium production. | ||
*The higher the temperature, the prettier the fire. See if you can get the prettiest color fire. | *The higher the temperature, the prettier the fire. See if you can get the prettiest color fire. | ||
*Traitors can harness fusion reactions to devastating results if done correctly. | *Traitors can harness fusion reactions to devastating results if done correctly. | ||
==Being a Traitorous Scum== | ==Being a Traitorous Scum== | ||
Or: How to get the AI lynched; How to call the shuttle as Atmos Tech, step-by-step: | Or: How to get the AI lynched; How to call the shuttle as Atmos Tech, step-by-step: | ||
#Open valves connected to harmful gas you want to add to the station. | #Open valves connected to harmful gas you want to add to the station. | ||
#Set pumps to the distribution loop to maximum pressure output (4500 kPa). | #Set pumps to the distribution loop to maximum pressure output (4500 kPa). | ||
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A faster process for achieving the same result is to do the following: | A faster process for achieving the same result is to do the following: | ||
#Disconnect, change the direction of, and reconnect the pump that feeds from the air mix to the mix tank in the north-eastern room of atmosia. | #Disconnect, change the direction of, and reconnect the pump that feeds from the air mix to the mix tank in the north-eastern room of atmosia. | ||
#Open the valves for your deathgas mixture of choice. | #Open the valves for your deathgas mixture of choice. | ||
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An extremely fast method that involves a clever use of the waste system is the following: | An extremely fast method that involves a clever use of the waste system is the following: | ||
#Reconfigure the piping to connect the waste system directly into the pure pipes. | #Reconfigure the piping to connect the waste system directly into the pure pipes. | ||
#Find a place with a waste pipe next to a distro pipe, then configure them so that they can be united later. | #Find a place with a waste pipe next to a distro pipe, then configure them so that they can be united later. | ||
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Other antagonistic things to do: | Other antagonistic things to do: | ||
*You can hack an air alarm to use it as a non-Atmos Tech. | *You can hack an air alarm to use it as a non-Atmos Tech. | ||
*Make flamethrowers, complex mixes involving multiple gas types are the best ones, and they only need one puff to render a room uninhabitable | *Make flamethrowers, complex mixes involving multiple gas types are the best ones, and they only need one puff to render a room uninhabitable | ||
*Manufacture bombs like in toxins, except without needing to use a tank transfer valve. | *Manufacture bombs like in toxins, except without needing to use a tank transfer valve. | ||
[[Category:Guides]] | [[Category:Guides]] |