Guide to power: Difference between revisions

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{{Template:Needs revision|This is ported from the Yogstation wiki. Needs a once-over for inaccuracies between servers, plus missing power values, plus revision for the additional SMES in engineering.}}
= Introduction =
= Introduction =
Understanding the intricacies of the power dynamic in the station is key to keeping the station in order. Many, especially the [[Head of Personnel|HoP]], believe that the [[Captain]] is the seat of power on the station. This is untrue as having the Captain wired into the station's power grid provides minimal power at best.  
Understanding the intricacies of the power dynamic in the station is key to keeping the station in order. Many, especially the [[Head of Personnel|HoP]], believe that the [[Captain]] is the seat of power on the station. This is untrue as having the Captain wired into the station's power grid provides minimal power at best.  


The real source of power comes from [[Engineering]] because without [[Station Engineer]]s to set up the power sources at the beginning of a shift, the station would cease to function normally and devolves into a degenerative society with have no more power than a uncivilized horde of lowly [[Assistant]]s, who, it should be noted, also provide even less power when wired directly to the grid.
The real source of power comes from [[Engineering]] because without [[Station Engineer]]s to set up the power sources at the beginning of a shift, the station would cease to function normally and devolve into a degenerative society with no more power than a uncivilized horde of lowly [[Assistant]]s, who, it should be noted, also provide even less power when wired directly to the grid.


Typically the Station needs between 160-180 kW of power. More will be needed to charge the SMES and/or BSA.
= Power Sources =
= Power Sources =
Station power can be confusing, if you are a beginner and not doing engineering at least learn how to set up '''solar''', see below.


== Singularity Engine ==
== [[Supermatter| Supermatter Engine]] ==
The singularity engine is the primary source of power on the station. By harnessing radiant energy produced by a locally-controlled cosmic [[Singularity]] (otherwise known as a man-made black hole), and converting the radiation to electrical power via [[#Radiation Collectors|Radiation Collectors]], an enormous amount of energy can be generated for the station.
The supermatter is a giant pile of exotic material capable of emitting both ionizing radiation and (flammable) gases. While the generation of these elements is normally rather low, the supermatter can be "activated" into releasing more by, well, most anything: even gasses can start the delamination process if they hold enough energy (heat, usually). You see where this is going? That's right, self-induced chain reactions. Your main job as an engineer will be to cool the supermatter down to prevent it from exploding (luckily a very easy job), while simultaneously exciting it to harvest radiation pulses. It's not an unforgiving engine, some would say it's even too stable to sabotage in a timely manner; read the [[Supermatter| Guide]] carefully and it will be hard to mess it up.
 
== Singularity/Tesla Engine ==
''See [[Singularity Engine]] for how to activate the sing without fucking up.''
[[File:Singularity_engine.png|thumb|300px]]
 
The singularity and tesla engines are the primary source of power only on [[PubbyStation]]. By harnessing either the radiant energy produced by a locally-controlled cosmic [[Singularity]] (otherwise known as a man-made black hole), or straight-up capturing the electric arcs from a giant ball of lightning, an enormous amount of energy can be generated for the station.
=== Singularity ===
=== [[Singularity Engine]] ===
 
The usable power emitted by a singularity takes the form of ionizing radiation pulses. These can interact with the mysterious substance called "plasma" so as to generate electricity. The more plasma available, and the stronger and more frequent the pulses, the more power is generated. The net power output can be measured directly by using a multitool on the collector's wire, checking the first SMES unit connected for available power, or by looking it up on a power monitoring console (though the latter will give skewed results if other power sources such as solars are connected).
The radiant energy produced by the singularity is dependent on its size. The exact amount of energy is estimated implicitly by measuring the power available provided by a bank of Radiation Collectors (here, the 6 used in Engineering) with filled [[Plasma Tank]]s. The power output can be measured by looking at a connected SMES status screen (such as the Singlo SMESs), or by measuring the wattage directly from the power lines from the collectors using a multitool.
=== [[Tesla Engine]] ===
 
This giant ball of incandescent energy regularly regurgitates power in the form of electric arcs. These arcs can be partially captured by tesla coils, and will generally flow along the most conductive/least resisting path. Metal structures are prime target for its strikes, and grounding rods are the safest there is, drawing arcs to themselves and subsequently dissipating them into the whole station. The latter are regularly used to direct lighting through tesla coils, and are best deployed between the engine and anything you hold dear. Don't forget to turn on the shield generators so the energy ball doesn't fly out of engineering.
{| class="wikitable"
|+ Power Generation by Singularity Size
! Size !! Max Power Generated
|-
| L1 || TBD
|-
| L2 || TBD
|-
| L3 || ≥3.33MW
|-
| L4 || ≥3.33MW
|}
 
=== Radiation Collectors ===
 
While nothing can tame LORD SINGULOTH, the Radiation Collector at least is able to translate the beast's fatal radiant bombardments into something usable by the crew. Converting radiation directly into power by using a plasma gas catalyst, the Radiation Collectors are the direct producers of electricity in the Singularity Engine set-up.  
 
Their power output is directly dependent on how full their Plasma Tanks are and how much Radiation is being emitted by the Singularity.
 
== Solar Arrays ==
== Solar Arrays ==
''See [[Solars]]''
[[File:Solars.png|thumb|300px]]
''See [[Solars]].''


The solar arrays act as a secondary power source. They are composed of 60 panels per array and there are 4 arrays on the station. Each panel can produce 1.5kW of power for a total of 90kW per array.  
The solar arrays act as a secondary power source. They are composed of 60 panels per array and there are 4 arrays on the station. Each panel can produce 1.5 kW of power for a total of 90 kW per array.  


The solar arrays only produce power when directly facing the local star. (The star is off-screen from the station and cannot be located by the player directly.) A solar tracking module can wired into the solar array circuitry and, with the help of a solar power console, the solar panels can be made to automatically track the local star, which maximizes the power generation for each panel. However, as the station revolves around the star (which, again, is unseen by the player), the solar arrays often land in the shadow of the station which prevents solar power generation at the affected arrays. This effectively gives the solar arrays a solar day-night cycle, where it generates power during the day cycle and does not generate power during the night cycle. Because of the solar cycle, a given array will be able to generate power about 50% (estimated but unconfirmed) of the time, which can be translated to an average 45kW per unit time, rather than the full 90kW.
The solar arrays only produce power when directly facing the local star. (The star is off-screen from the station and cannot be located by the player directly.) A solar tracking module can be wired into the solar array circuitry and, with the help of a solar power console, the solar panels can be made to automatically track the local star, which maximizes the power generation for each panel. However, as the station revolves around the star (which, again, is unseen by the player), the solar arrays often land in the shadow of the station which negatively affects solar power generation at the affected arrays. This effectively gives the solar arrays a solar day-night cycle, where it generates power during the day cycle and does not generate power during the night cycle. Because of the solar cycle, a given array will be able to generate power about 50% (estimated but unconfirmed) of the time, which can be translated to an average 45 kW per unit time, rather than the full 90 kW.


The solar panels themselves can be, and often are, broken by debris floating in space. Each broken panel reduces the total power generation of the array.
The solar panels themselves can be, and often are, broken by debris floating in space. Each broken panel reduces the total power generation of the array.


The solar arrays can typically power the entire station on their own, once the arrays are wired properly.
The solar arrays can typically power the entire station on their own, once the arrays are wired properly.
{| class="wikitable"
{| class="wikitable"
|+ Solar Power Generated
|+ Solar Power Generated
Line 52: Line 33:
|+
|+
! per panel !! per array !! per array
! per panel !! per array !! per array
|-  
|-
| 1500W (1.5kW) || 90000W (90kW) || 45000W (45kW)
| 1500 W (1.5 kW) || 90000 W (90 kW) || 45000 W (45 kW)
|}
|}
=== Connecting Solars to the Grid ===
=== Connecting Solars to the Grid ===
There are two main schools of thought when wiring the solar arrays:  
There are two main schools of thought when wiring the solar arrays:  
* use the Solar SMESs to distribute power into the grid
* use the Solar SMESs to distribute power into the grid
* wire the solar array directly into the power grid
* wire the solar array directly into the power grid
==== Distributing via SMESs ====
Distributing solar power through the SMESs is the generally preferred method of wiring the solars, mainly because it provides a steady power output and requires no extra wiring. One benefit of the pre-laid wiring to the SMES is that during a night cycle of the solar array the Engineer does not need insulated gloves to wire the solar array.


==== Distributing via SMESs ====
The maximum power generation of a typical solar array is 90 kW, and it is advised to set SMES inputs to the maximum 200 kW.


Distributing solar power through the SMESs is the generally preferred method of wiring the solars, mainly because it provides a steady power output and requires no extra wiring. One benefit of the pre-laid wiring to the SMES is that during a night cycle of the solar array the Engineer does not need insulated gloves to wire the solar array.
The output on the SMES should be at most 50% of the 90 kW generated by the cells due to the revolution of the station around the local star (percentage estimated but unconfirmed). Since the solar has to collect enough energy in the day cycle of the array to output for both day and night, it's usually good to round down a little more. Additionally, if the solar is initially wired during its day cycle, it typically won't be able to collect enough to keep it charged for the first night cycle, resulting in a little bit of lag in the output of the solars.
For example, if the solar cells generate 85500 W (85.5 kW), the output shouldn't be bigger than 42750 W (42.75 kW). Typically, 40 kW is a good round number for long-term power output.  


While the maximum power generation of a given solar array is 90kW, it is advised to set SMES inputs to slightly lower level to account for solar panels that might break during the course of the shift. 
For example, setting the SMES input levels to 85.5kW may not collect all 90kW produced by the array, but allows for the SMES to charge even when up to three panels get broken on the array. 
Otherwise, should the Engineer set SMES input levels to 90kW and should a single panel get hit by space debris and break, the array will always produce less than 90kW, so the SMES with a required 90kW input will not charge. 
 
The output on the SMES should be at most 50% of the input level due to the revolution of the station around the local star (percentage estimated but unconfirmed). Since the solar has to collect enough energy in the day cycle of the array to output for both day and night, it's usually good to round down a little more. Additionally, if the solar is initially wired during its day cycle, it typically won't be able to collect enough to keep it charged for the first night cycle, resulting in a little bit of lag in the output of the solars. 
For example, if the input is set to 85500W (85.5kW), the output shouldn't be bigger than 42750W (42.75kW). Typically, 40kW is a good round number for long-term power output. 
 
If more power storage is desired, say in the initial stage of the set-up, the engineer may want to reduce or even eliminate power output for the first few solar cycles, before setting the long-term power output.  
If more power storage is desired, say in the initial stage of the set-up, the engineer may want to reduce or even eliminate power output for the first few solar cycles, before setting the long-term power output.  
 
Once all four Solar SMESs are adequately charged and outputting long-term power, they will provide a very dependable power output with almost no oversight needed. In our example, the station would receive 160kW (4 arrays x 40kW SMES output) from solars, which is usually more than enough to sustain the station on its own without the singlo. This system is also modular, so that even if only three out of four Solar SMESs are used, the total power output is reduced accordingly but still completely steady.


That being said, if unchecked, power sinks can drain the solar SMESs, which if depleted would need to go through a solar cycle again before being able to provide steady, adequate power to the station.
Once all four Solar SMESs are adequately charged and outputting long-term power, they will provide a very dependable power output with almost no oversight needed. In our example, the station would receive 160 kW (4 arrays x 40 kW SMES output) from solars, which is usually more than enough to sustain the station on its own without the engine. This system is also modular, so that even if only three out of four Solar SMESs are used, the total power output is reduced accordingly but still completely steady.
 
 
The biggest failure of the Solar SMES system is more often the fault of the Engineer, not the power sink. A rookie Engineer usually sets input levels and output levels too high or too low to meaningfully sustain the station, and/or fails to re-set the SMESs to a more adequate output level after initially charging the SMES.
That being said, if unchecked, power sinks can drain the solar SMESs, which if depleted would need to go through a solar cycle again before being able to provide steady, adequate power to the station.  
 
 
'''Pros:''' steady power supply, no additional wiring necessary, stores power, modular, does not require insulated gloves<br />
The biggest failure of the Solar SMES system is more often the fault of the Engineer, not the power sink. A rookie Engineer usually forgets to set input levels and output levels to meaningfully sustain the station.
'''Cons:''' lag due to first night cycle and initial SMES charging, prone to being set up improperly, some power loss to correct for potentially broken panels, can be drained by power sinks
 
'''Pros:''' Steady power supply, no additional wiring necessary, stores power, modular, does not require insulated gloves.


'''Cons:''' Lag due to first night cycle and initial SMES charging, prone to being set up improperly, some power loss to correct for potentially broken panels, can be drained by power sinks.
==== Wiring to the Grid ====
==== Wiring to the Grid ====
Wiring the solar arrays directly to the grid is often used as a more straight-forward approach to hooking up the solars, which benefits the Engineer by bypassing the intricacies of the SMES and generating a generally larger power output but at the expense of a less steady, less modular electrical source. This is often helpful in the emergency circumstance when the singlo is loose or otherwise not available, effectively making the solar arrays the primary power source.
Wiring the solar arrays directly to the grid is often used as a more straight-forward approach to hooking up the solars, which benefits the Engineer by bypassing the intricacies of the SMES and generating a generally larger power output but at the expense of a less steady, less modular electrical source. This is often helpful in the emergency circumstances where the supermatter crystal has delaminated, taking out the whole of Engineering with it, or when the Singularity or Tesla gets loose.


To achieve this, the Engineer usually just wires together the cable leading from the array directly to the cable leading out from the solar maintenance room. Typically, insulated gloves are a necessity since the Engineer will need to tap the solar power lines into the main power grid. However, as easy as that sounds, rookie Engineers tend to mangle the wiring so much that the array power lines never make it to the grid.
To achieve this, the Engineer usually just wires together the cable leading from the array directly to the cable leading out from the solar maintenance room. Typically, insulated gloves are a necessity since the Engineer will need to tap the solar power lines into the main power grid. However, as easy as that sounds, rookie Engineers tend to mangle the wiring so much that the array power lines never make it to the grid.


Once all the arrays are wired, and because of the day-night cycle, on average, about two solar arrays worth of power will be generated at any given time, equating to about 180kW of power. However, the exact number will fluctuate depending on how much light reaches individual panels. Additionally, if not all of the solars are wired to the grid, the output will be drastically lower and may cause brown outs in the station.
Once all the arrays are wired, and because of the day-night cycle, on average, about two solar arrays worth of power will be generated at any given time, equating to about 180 kW of power. However, the exact number will fluctuate depending on how much light reaches individual panels. Additionally, if not all of the solars are wired to the grid, the output will be drastically lower and may cause brown outs in the station.  
 
 
On the plus side, wiring the solars directly to the grid prevents wiring sabotage since anyone cutting the wires also needs insulated gloves. Also, power sinks pose little risk as the solar power is immediate and not distributed from an SMES.
On the plus side, wiring the solars directly to the grid prevents wiring sabotage since anyone cutting the wires also needs insulated gloves. Also, power sinks pose little risk as the solar power is immediate and not distributed from an SMES.


'''Pros:''' straight-forward explanation, avoids setting SMES, deters sabotage, acts as primary power source, not prone to power sinks<br />
'''Pros:''' Straight-forward explanation, avoids setting SMES, deters sabotage, acts as primary power source, not prone to power sinks.
'''Cons:'''  minor fluctuations in power if fully implemented, severe fluctuations if incompletely implemented, requires insulated gloves, often incorrectly wired


'''Cons:''' Minor fluctuations in power if fully implemented, severe fluctuations if incompletely implemented, requires insulated gloves, often incorrectly wired.
==== Dual-Wiring: The Best of Both Worlds ====
==== Dual-Wiring: The Best of Both Worlds ====
There is another, less used option that utilizes the benefits from both wiring ideologies while mitigating the risk: dual-wire the solar arrays both to the Solar SMESs and directly into the grid at the same time.
There is another, less used option that utilizes the benefits from both wiring ideologies while mitigating the risk: dual-wire the solar arrays both to the Solar SMESs and directly into the grid at the same time.


Initially, the Engineer would want to charge the SMESs enough to where they could give an adequate supply of power. Then, if the Engineer is skilled enough at wiring, both the SMES and the solar arrays can be wired to the grid at the same time. Since the station only draws about 150kW, but the solars wired to grid produce 180kW, there's a spare 30kW to split between the Solar SMESs for recharging. Setting all four Solar SMESs to charge at 6kW is feasible (reduced from 7.5kW to account for broken solar panels). The output setting on the SMES can be any value so long as the station draws full power from the solars wired directly. This effectively makes the Solar SMESs a backup power source.
Initially, the Engineer would want to charge the SMESs enough to where they could give an adequate supply of power. Then, if the Engineer is skilled enough at wiring, both the SMES and the solar arrays can be wired to the grid at the same time. Since the station only draws about 150 kW, but the solars wired to grid produce 180 kW, there's a spare 30 kW to split between the Solar SMESs for recharging. Setting all four Solar SMESs to charge at 6 kW is feasible (reduced from 7.5 kW to account for broken solar panels). The output setting on the SMES can be any value so long as the station draws full power from the solars wired directly. This effectively makes the Solar SMESs a backup power source.


The drawbacks though are that the Solar SMES input levels should not be put higher than 6kW since a Solar SMES located at an array going through the night cycle will attempt to draw power from a Solar SMES higher upstream in the [[#power queue]], cannibalistically draining that SMES.  
The drawbacks though are that the Solar SMES input levels should not be put higher than 6 kW since a Solar SMES located at an array going through the night cycle will attempt to draw power from a Solar SMES higher upstream in the [[#power queue]], cannibalizing the power from that SMES.  


Also, the 2 conventional Backup SMESs can't be charged for the same reason of the power queue. However, since the 4 Solar SMESs act as backups, this trade-off is in favor of the dual-wiring of the solars.
Also, the 2 conventional Backup SMESs can't be charged for the same reason of the power queue. However, since the 4 Solar SMESs act as backups, this trade-off is in favor of the dual-wiring of the solars.
Line 109: Line 84:
The drawback that all solars must be wired directly to the grid to prevent severe fluctuation. The same is not true of the SMES-side of this set-up. Each SMES acts like an independent backup, so any undesired SMESs don't have to be set, making the system semi-modular.
The drawback that all solars must be wired directly to the grid to prevent severe fluctuation. The same is not true of the SMES-side of this set-up. Each SMES acts like an independent backup, so any undesired SMESs don't have to be set, making the system semi-modular.


'''Pros:''' acts primary and backup power source, deters sabotage, resistant to power sinks, semi-modular, resistant to brownouts<br />
'''Pros:''' acts primary and backup power source, deters sabotage, resistant to power sinks, semi-modular, resistant to brownouts
 
'''Cons:''' severe fluctuations if incompletely implemented, requires insulated gloves, often incorrectly wired, requires initial charging and follow up on the SMESs before implementation
'''Cons:''' severe fluctuations if incompletely implemented, requires insulated gloves, often incorrectly wired, requires initial charging and follow up on the SMESs before implementation
== Gas Turbine Generator ==
== Gas Turbine Generator ==
 
[[File:Incinerator.png|thumb]]
''See: [[Incinerator]]''
''See: [[Incinerator]]''


The gas turbine generator is a tertiary power source that was recently installed in the incinerator. By utilizing the temperature differential between very hot air and very cold air, the turbine generator is able to create a nominal amount of electricity. The hot air is created by burning plasma and oxygen gas mixtures. The cold air is creating by passing air through cooling tubes located in space.  
The gas turbine generator is a tertiary power source that was recently installed in the incinerator. By utilizing the temperature differential between very hot air and very cold air, the turbine generator is able to create a nominal amount of electricity. The hot air is created by burning plasma and oxygen gas mixtures. The cold air is creating by passing air through cooling tubes located in space.  


Although it's usually the last power source set up on the station, it's the only power source that can be accessed by Atmospherics. Also, they're the only ones who can turn on and mix the gas feed needed to sustain the generator without the use of gas canisters. The exact gas mixture for optimal power generation is unknown at this point, but some Engineers have reported values as high as 100kW and in typical Engineer fashion forgot to write down their recipe. Be prepared to field questions from <s>overprotective</s> proactive [[AI]]s who notice plasma in the mixtank.
Although it's usually the last power source set up on the station, it's the only power source that can be accessed by Atmospherics. Also, they're the only ones who can turn on and mix the gas feed needed to sustain the generator without the use of gas canisters. The exact gas mixture for optimal power generation is unknown at this point, but some Engineers have reported values as high as 100 kW and in typical Engineer fashion forgot to write down their recipe. Be prepared to field questions from <s>overprotective</s> proactive [[AI]]s who notice plasma in the mixtank.
 
== Thermal-electric Generator ==
See: [[Thermo-Electric Generator]]


The Thermal-Electric Generator has the potential to generate the most power for the station up to and over a '''TeraWatt'''. PubbyStation, CorgStation, MiniStation starts with a TEG and you can get their machine boards easily from an engineering protolathe. Setting up TEG requires some understanding of atmospherics: it requires hot and cold air piped in to generate power and will transfer heat between the two.
If you use the basic SM setup to harvest Oxygen and plasma, burn it and feed it to the TEG it will generate 2-6 MW of power depending on how much cooling you have set up.
== Portable Generators ==
== Portable Generators ==
Portable generators are failsafes when all other systems fail. They require fuel that is fed directly into the generator by hand. The type of fuel is dependent which type of generator is being used.
Portable generators are failsafes when all other systems fail. They require fuel that is fed directly into the generator by hand. The type of fuel is dependent which type of generator is being used.


Portable generators can be upgraded using parts created by a protolathe.
Portable generators can be upgraded using parts created by a protolathe.
{| class="wikitable"
{| class="wikitable"
|+ Fuel Required by Portable Generator Type
|+ Fuel Required by Portable Generator Type
Line 136: Line 115:
| S.U.P.E.R.P.A.C.M.A.N. Portable Generator || Uranium
| S.U.P.E.R.P.A.C.M.A.N. Portable Generator || Uranium
|}
|}
 
One PACMAN generator is located in the SMES room, with plasma located in secure storage, and it is suggested to use it while setting up the singularity or tesla to prevent early release.
One PACMAN generator is located in the SMES room, with plasma located in secure storage, and it is suggested to use it while setting up the singularity to prevent early release.
 
== Power Cells ==
== Power Cells ==
Power cells are used to power devices smaller than the station such as APCs and cyborgs. Constructed with a protolathe, typical power cells come in several different flavors, in increasing capacity: the default power cell, the high-capacity power cell, the super-capacity power cell, or the hyper-capacity power cell.
Power cells are used to power devices smaller than the station such as APCs and cyborgs. Constructed with a protolathe, typical power cells come in several different flavors, in increasing capacity: the default power cell, the high-capacity power cell, the super-capacity power cell, or the hyper-capacity power cell.


There are also atypical cells such as a potato cell and a slime core cell.
There are also atypical cells such as a potato cell and a slime core cell. A potato cell's capacity is depended on its potency, with 100 at 40MJ. Slime core cells can recharge on its own over time.
 
{| class="wikitable"
{| class="wikitable"
|+ Power Capacity by Type of Cell
|+ Power Capacity by Type of Cell
! Type !! Capacity (W)
! Type !! Capacity (MJ)
|+
|+
! colspan = "2" style = "text-align:center;"| Typical Cells
! colspan = "2" style = "text-align:center;"| Typical Cells
Line 158: Line 133:
|-
|-
| Hyper-Capacity Power Cell || 30000
| Hyper-Capacity Power Cell || 30000
|-
|Bluespace Power Cell
|40000
|+
|+
! colspan = "2" style = "text-align:center;"| Atypical Cells
! colspan = "2" style = "text-align:center;"| Atypical Cells
|-
|-
| Potato Cell || 300
| Potato Cell (max potency) || 40000
|-
| Charged Slime core cell || 10000
|-
|-
| Slime Core Cell || 10000
|HyperCharged Slime core cell
|20000
|}
|}
 
It is possible to power the entire station for around two hours with three SMES filled with Charged Slime core cells.
= Power Distribution =
= Power Distribution =
== Power Grid ==
== Power Grid ==
 
To most people they're just wires that burn the shit out of you when you try to cut them without wearing insulated gloves. But really, the power grid is the electrical backbone of the station, powering everything from the emitters containing the singularity to the APC that controls the bathrooms in the locker room that you never go to. Also, it burns the shit out of you if you try to cut it without wearing insulated gloves. At 14MW it instantly husks you.
To most people they're just wires that burn the shit out of you when you try to cut them without wearing insulated gloves. But really, the power grid is the electrical backbone of the station, powering everything from the emitters containing the singularity to the APC that controls the bathrooms in the locker room that you never go to. Also, it burns the shit out of you if you try to cut it without wearing insulated gloves.
 
== SMES ==
== SMES ==
[[File:SMES_Charging.gif]]


A Superconducting Magnetic Energy Storage (SMES) Cell is the spess version of a giant rechargeable battery. The standard set-up for an SMES involves:
A Superconducting Magnetic Energy Storage (SMES) Cell is the spess version of a giant rechargeable battery. The standard set-up for an SMES involves:
Line 179: Line 158:


2. a wiring output to the local power grid, or to a closed system like the AI or mining stations
2. a wiring output to the local power grid, or to a closed system like the AI or mining stations
=== SMES Properties ===
=== SMES Properties ===
 
SMES have a modifiable storage capacity, dependent on the [[power cell]]s installed in the SMES upon fabrication. All SMESs present at the beginning of a typical shift have a default capacity of 3.33 MW.
SMES have a modifiable storage capacity, dependent on the [[power cell]]s installed in the SMES upon fabrication. All SMESs present at the beginning of a typical shift have a default capacity of 3.33MW.
 
{| class ="wikitable"
{| class ="wikitable"
|+ SMES Capacity vs Power Cell
|+ SMES Capacity vs Power Cell
Line 191: Line 167:
|-
|-
! colspan = 3|Typical
! colspan = 3|Typical
|-
| [[Power Cell|Standard]] || TBD || TBD
|-
|-
| High-Capacity || TBD || TBD
| [[Power Cell|Standard]] || 10000 || 50000
|-
|-
| Super-Capacity || TBD || TBD
| High-Capacity || 15000 || 75000
|-
|-
| Hyper-Capacity || TBD || TBD
| Super-Capacity || 20000 || 100000
|-
| Hyper-Capacity || 30000 || 150000
|-
|Bluespace
|40000
|200000
|+
|+
! colspan = 3|Atypical
! colspan = 3|Atypical
|-
|-
| [[Potato Cell]] || TBD || TBS
| [[Potato Cell]] (Max potency) || 40000 || 200000
|-  
|-
| [[Cyborg Cell]] || TBD || TBD
| [[Cyborg Cell|Charged Slime core cell]] || 10000 || 50000
|-
|-
| [[Slime Core/SMES Cell]] || TBD || TBD
| [[Slime Core/SMES Cell|Hypercharged Slime core cell]] || 20000 || 100000
|}
|}
 
SMES input (charging) and output levels can be modified using [[capacitor]]s. All SMESs present at the beginning of a typical shift have a basic capacitor with default i/o levels of 200 kW.  
SMES input (charging) and output levels can be modified using [[capacitor]]s. All SMESs present at the beginning of a typical shift have a basic capacitor with default i/o levels of 200kW.  
 
{| class ="wikitable"
{| class ="wikitable"
|+ SMES Input/Output Levels vs Capacitor
|+ SMES Input/Output Levels vs Capacitor
! Capacitor !! Max Input Level !! Max Output Level
! Capacitor !! Max Input Level !! Max Output Level
|-
| [[Capacitor|Basic]] || 200000W (200kW) || 200000W (200kW)
|-
|-
| Advanced  || 400000W (400kW) || 400000W (400kW)
| [[Capacitor|Basic]] || 200000 W (200 kW) || 200000 W (200 kW)
|-
|-
| Super  || 600000W (600kW) || 600000W (600kW)
| Advanced  || 400000 W (400 kW) || 400000 W (400 kW)
|-
| Super  || 600000 W (600 kW) || 600000 W (600 kW)
|-
|Quadratic
|800000 W (800 kW)
|800000 W (800 kW)
|}
|}
SMESs will only output when the level of charge is above the output level specified on the SMES settings panel.
== [[APC|APCs]] ==
[[File:APC2.gif]]


SMESs will only charge when the input power is equal or higher to the input levels specified on the SMES settings panel.
APCs, or Automated Power Controllers, are found on the walls of the room they're powering or, more likely, in maintenance just outside the room. They can be used to toggle the room's equipment, lighting and environmental (a.k.a. ventilation) systems on and off. Their cells can be changed or upgraded to provide more capacity.
 
Likewise, SMESs will only output when the level of charge is above the output level specified on the SMES settings panel.
 
== APCs ==
 
APCs, or Automated Power Controllers, are found in or, more likely, in maintenance just outside every room with power.
 
Actions available on the APC:
* ''Main Breaker: On/Off'' - Toggles power to the room
* ''Equipment: Auto/On/Off'' - Toggles power to computers, doors, and other electronic equipment.
* ''Lighting: Auto/On/Off'' - Toggles power to lighting in the area.
* ''Environmental: Auto/On/Off'' - Toggles power to the ventilation in the area, as well as the [[Air Alarm]].
* ''Cover Lock: Engaged/Disengaged'' - Provides a cover to protect the battery.
 
Remember, 'Auto' power settings slowly cuts off each breaker when power runs low in this order:<br><30 % = Equipment off,  <15% = Lighting and Environment off.</b>
 
===Replacing the APC's Battery:===
 
To replace the APC battery, you need an ID with sufficient access to unlock the APC itself. An engineer's ID will suffice.<br>
 
#[[File:Id_regular.png|link=Identification_Card]] Swipe ID with ''power equipment'' access to unlock the interface.
#Open the panel and disengage the cover lock.
#[[File:Crowbar.png|link=#Crowbar]] Use a crowbar on the APC to open the cover.
#[[File:Hud-hands.gif]] Take the battery out with a free hand.
#[[File:Power_cell.png|link=#Power_Cell]] place in the new battery.
#[[File:Crowbar.png|link=#Crowbar]] Close the cover again with your crowbar.
# Re-engage the cover lock.
#[[File:Id_regular.png|link=Identification_Card]] Swipe ID to secure the interface.
 
= Concepts =
= Concepts =
== System Power ==
== System Power ==
System power is the amount of power available to the station at any given time. Power is made available through charged SMESs outputting power and through immediate power from power sources wired directly to the grid.
System power is the amount of power available to the station at any given time. Power is made available through charged SMESs outputting power and through immediate power from power sources wired directly to the grid.
Line 261: Line 216:


== Power Queue ==
== Power Queue ==
To maintain a stable source of power for station equipment, the station power grid follows a ''power queue'' where an electrical component with higher rank on the queue has its power draw from the grid evaluated before an electrical component with a lower priority. APCs are typically the lowest priority since they only draw power, while the power sources on the station are the highest priority since they only produce power.
To maintain a stable source of power for station equipment, the station power grid follows a ''power queue'' where an electrical component with higher rank on the queue has its power draw from the grid evaluated before an electrical component with a lower priority. APCs are typically the lowest priority since they only draw power, while the power sources on the station are the highest priority since they only produce power.
{| class="wikitable"
{| class="wikitable"
|+  
|+  
Line 272: Line 225:
|1 ||colspan = 2|All Power Sources
|1 ||colspan = 2|All Power Sources
|-
|-
|2 ||colspan = 2|Power Sink
|2 ||Power Sink ||On the station power console, look where all the power is dropping to
|-
|-
|3 ||Solar SMES #1 ||Starboard Forward Solar Access
|3 ||Solar SMES #1 ||Starboard Forward Solar Access
Line 282: Line 235:
|6 ||Solar SMES #4 ||Port Aft Solar Access
|6 ||Solar SMES #4 ||Port Aft Solar Access
|-
|-
|7 ||Singlo SMES #1 || SMES Room
|7 ||Singlo/SM SMES #1 || SMES Room
|-
|-
|8 ||Singlo SMES #2 || SMES Room
|8 ||Singlo/SM SMES #2 || SMES Room
|-
|-
|9 ||Singlo SMES #3 || SMES Room
|9 ||Singlo/SM SMES #3 || SMES Room
|-
|-
|?? ||Gas Turbine SMES || Incinerator Access (Gas Turbine Power Room)
|?? ||Gas Turbine SMES || Incinerator Access (Gas Turbine Power Room)
Line 298: Line 251:
!colspan = 3|Isolated SMESs
!colspan = 3|Isolated SMESs
|-
|-
|NA ||Gravity SMES || Gravity Generator Chamber
|N/A ||Gravity SMES || Gravity Generator Chamber
|-
|-
|NA ||AI SMES || AI Chamber
|N/A ||AI SMES || AI Chamber
|-
|-
|NA ||Mining Output SMES || Mining Outpost
|N/A
|AI maintenance SMES
|AI satellite maintenance
|-
|-
|NA ||North Mining Output SMES || North Mining Outpost
|N/A ||Mining Output SMES || Mining Outpost
|-
|NA ||West Mining Output SMES || West Mining Outpost
|}
|}
=== Power Output and the Power Queue ===
=== Power Output and the Power Queue ===
 
The most visible effect of the power queue is that if there is not enough output power available on the grid because a component with higher rank is requesting it, then a lower rank component will not charge. For example, if the Backup SMESs are set to input 200 kW each from the grid and the APCs draw 150 kW, but the grid only provides 250 kW total, then the second Backup SMES will not charge and around two out of three APCs will go unpowered as well.
The most visible effect of the power queue is that if there is not enough output power available on the grid because a component with higher rank is requesting it, then a lower rank component will not charge. For example, if the Backup SMESs are set to input 200kW each from the grid and the APCs draw 150kW, but the grid only provides 250kW total, then the second Backup SMES will not charge and around two out of three APCs will go unpowered as well.
 
=== SMES Charging and the Power Queue ===
=== SMES Charging and the Power Queue ===
[[File:SMES_Room_markup.png|thumb|right|400px|The three Singlo SMESs in the SMES Room.]]
[[File:SMES_Room_markup.png|thumb|right|400px|The three Singlo SMESs in the SMES Room.]]
Similarly, if a higher rank component has a high enough output level to handle the station's power draw, then the station will draw all of its power from the higher rank component instead of splitting the draw with a lower rank component. This phenomenon is seen often when the singlo is set up. An unaware Engineer will purposefully set all three Singlo SMESs to output at a very high value, say 100 kW, or 300 kW, thinking that this will be more than enough to power the station. While this is technically correct, it isn't advised since it slows down the time it takes until all SMESs are completely full.


Similarly, if a higher rank component has a high enough output level to handle the station's power draw, then the station will draw all of its power from the higher rank component instead of splitting the draw with a lower rank component. This phenomenon is seen often when the singlo is set up. An unaware Engineer will purposefully set all three Singlo SMESs to output at a very high value, say 100kW, or 300kW, thinking that this will be more than enough to power the station. While this is technically correct, it isn't advised since it slows down the time it takes until all SMESs are completely full.
An example is the best way to see this. The total power draw on the station is usually near 150 kW. This means the station will draw 100 kW from Singlo SMES #1, 50 kW from Singlo SMES #2, and 0 kW from Singlo SMES #3, resulting in different charging rates of the SMESs. Since SMESs have a capacity of 3,333,333 W (3.33 MW) and assuming an input level of 200 kW, it should take 33.3 cycles before all the SMESs are completely charged (9.99 MW total power stored).
 
An example is the best way to see this. The total power draw on the station is usually near 150kW. This means the station will draw 100kW from Singlo SMES #1, 50kW from Singlo SMES #2, and 0kW from Singlo SMES #3, resulting in different charging rates of the SMESs. Since SMESs have a capacity of 3,333,333W (3.33MW) and assuming an input level of 200kW, it should take 33.3 cycles before all the SMESs are completely charged (9.99MW total power stored).
 
{| class="wikitable"
{| class="wikitable"
|+ Singlo SMES Non-optimized Charging for 150kW Power Draw
|+ Singlo SMES Non-optimized Charging for 150 kW Power Draw
!colspan = 4| !! colspan = 3|Charge at n Cycles
!colspan = 4| !! colspan = 3|Charge at n Cycles
|+
|+
! Singlo Cell !! Input Level !! Draw !! Charge Rate !! 17 !! 23 !! 34
! Singlo Cell !! Input Level !! Draw !! Charge Rate !! 17 !! 23 !! 34
|-
|-
| SMES #1 || 200kW || 100kW || 100kW || 1.70MW || 2.30MW || ''3.33MW''
| SMES #1 || 200 kW || 100 kW || 100 kW || 1.70 MW || 2.30 MW || ''3.33 MW''
|-
|-
| SMES #2 || 200kW || 50kW || 150kW || 2.55MW || ''3.33MW'' || ''3.33MW''
| SMES #2 || 200 kW || 50 kW || 150 kW || 2.55 MW || ''3.33 MW'' || ''3.33 MW''
|-
|-
| SMES #3 || 200kW || 0kW || 200kW || ''3.33MW'' || ''3.33MW'' || ''3.33MW''
| SMES #3 || 200 kW || 0 kW || 200 kW || ''3.33 MW'' || ''3.33 MW'' || ''3.33 MW''
|-
|-
|'''Total''' || '''600kW''' || '''150kW''' || '''450kW''' || '''7.58 MW''' || '''8.96MW''' || '''''9.99MW'''''
|'''Total''' || '''600 kW''' || '''150 kW''' || '''450 kW''' || '''7.58 MW''' || '''8.96 MW''' || '''''9.99 MW'''''
|}
|}
 
A better way is to set output levels on Singlo SMESs #1 and #2 to a third of the total power draw of the station (here, 50 kW), while allowing the remainder (also, 50 kW) to draw from Singlo SMES #3, which would be set higher than that to account for power fluctuations. For the same case where the total draw was 150 kW, we would set SMES #1 and #2 to 50 kW and SMES #3 to something higher like 200 kW. This would have all three SMESs charged in 22.2 cycles -- 33% faster than the situation above.
A better way is to set output levels on Singlo SMESs #1 and #2 to a third of the total power draw of the station (here, 50kW), while allowing the remainder (also, 50kW) to draw from Singlo SMES #3, which would be set higher than that to account for power fluctuations. For the same case where the total draw was 150kW, we would set SMES #1 and #2 to 50kW and SMES #3 to something higher like 200kW. This would have all three SMESs charged in 22.2 cycles -- 33% faster than the situation above.
 
[[File:SMES_Output_v_Cycles_to_Full_v01.png|thumb|400px|right|The optimal number of cycles it takes to charge the singlo SMESs is dependent on both not outputting too little, and not outputting too much.]]
[[File:SMES_Output_v_Cycles_to_Full_v01.png|thumb|400px|right|The optimal number of cycles it takes to charge the singlo SMESs is dependent on both not outputting too little, and not outputting too much.]]
{| class="wikitable"
{| class="wikitable"
|+ Singlo SMES Optimized Charging for 150kW Power Draw
|+ Singlo SMES Optimized Charging for 150 kW Power Draw
!colspan = 4| !! colspan = 2|Charge at n Cycles
!colspan = 4| !! colspan = 2|Charge at n Cycles
|+
|+
! Singlo Cell !! Input Level !! Draw !! Charge Rate !! 17 !! 23
! Singlo Cell !! Input Level !! Draw !! Charge Rate !! 17 !! 23
|-
|-
| SMES #1 || 200kW || 50kW || 150kW || 2.55MW || ''3.33MW''
| SMES #1 || 200 kW || 50 kW || 150 kW || 2.55 MW || ''3.33 MW''
|-
|-
| SMES #2 || 200kW || 50kW || 150kW || 2.55MW || ''3.33MW''
| SMES #2 || 200 kW || 50 kW || 150 kW || 2.55 MW || ''3.33 MW''
|-
|-
| SMES #3 || 200kW || 50kW || 150kW || 2.55MW || ''3.33MW''
| SMES #3 || 200 kW || 50 kW || 150 kW || 2.55 MW || ''3.33 MW''
|-
|-
|'''Total''' || '''600kW''' || '''150kW''' || '''450kW''' || '''7.65 MW''' || '''''9.99MW'''''
|'''Total''' || '''600 kW''' || '''150 kW''' || '''450 kW''' || '''7.65 MW''' || '''''9.99 MW'''''
|}
|}
= ENGINEERING WHY ARE WE LOSING POWER =
= ENGINEERING WHY ARE WE LOSING POWER =
Sooner or later, on every barely functional space station, the power will go out. This is where you -- YES, YOU, YOU LAZY FUCK -- come in! Power can go out for many reasons. Your first port of call should be the Power Monitoring console in engineering, assuming it still exists. Then, ask yourself what's going on:
Sooner or later, on every barely functional space station, the power will go out. This is where you - YES, YOU, YOU LAZY FUCK - come in and call out to recall that shuttle because you can fix it! Power can go out for many reasons. Your first port of call should be the Power Monitoring console in engineering, assuming it still exists. Then, ask yourself what's going on:
 
*'''Power goes out everywhere, in under 10 seconds or so?''' This is most likely a power sink. Power sinks have the odd quirk of still powering the area they are placed in, so your best bet is to get searching for somewhere where the lights are still on, or if it's in maint, where you don't have to crowbar the doors.
*'''Power goes out everywhere, in under 10 seconds or so?''' This is most likely a power sink. Power sinks have the odd quirk of still powering the area they are placed in, so your best bet is to get searching for somewhere where the lights are still on, or if it's in maint, where you don't have to crowbar the doors.
*'''Power goes out everywhere, but gradually, section by section?''' This means there's a problem in Engineering itself as the rest of the station is being topped up with charge. It'll be immediately obvious if the engine isn't on/has escaped. Your next port of call should be the SMES cells. Check they're outputting enough power to overcome the drain OR if no APCs are showing on the Power Monitoring computer, it means a wire has been cut either inside or immediately outside the Engineering area and is not being supplied to the rest of the station.
*'''Power goes out everywhere, but gradually, section by section?''' This means there's a problem in Engineering itself as the rest of the station is being topped up with charge. It'll be immediately obvious if the engine isn't on/has escaped. Your next port of call should be the SMES cells. Check they're outputting enough power to overcome the drain OR if no APCs are showing on the Power Monitoring computer, it means a wire has been cut either inside or immediately outside the Engineering area and is not being supplied to the rest of the station.
*'''Power is out across a small area?''' This is most commonly a broken wire, the easiest way to find it is with familiarity with the power-net and using that in conjunction with the power monitoring computer. If an area has had all wires sending power to it snipped, its APCs will no longer show on the power monitoring computer. For example, if Medbay as a whole has lost power and isn't showing any of its APCs on the power monitor. The wire cut is most likely in the maint tunnel behind Medbay. The more familiar you become with the power nets, the quicker you will be able to work out where the break is and be able to recognize common spots used.
*'''Power is out across a small area?''' This is most commonly a broken wire, the easiest way to find it is with familiarity with the power-net and using that in conjunction with the power monitoring computer. If an area has had all wires sending power to it snipped, its APCs will no longer show on the power monitoring computer. For example, if Medbay as a whole has lost power and isn't showing any of its APCs on the power monitor, the wire cut is most likely in the maint tunnel behind Medbay. The more familiar you become with the power nets, the quicker you will be able to work out where the break is and be able to recognize common spots used.
*'''Power is out across 2 small rooms or in one room?''' This is most likely an APC that has been tampered with in some way. Either hacked by an AI/Saboteur, destroyed somehow or just had its cell ripped out. Again, if the APC doesn't show up on the Power Monitoring computer, it means it's been severed from the power net and wire either inside that room or very close to the APC has been cut.
*'''Power is out across 2 small rooms or in one room?''' This is most likely an APC that has been tampered with in some way. Either hacked by an AI/Saboteur, destroyed somehow or just had its cell ripped out. Again, if the APC doesn't show up on the Power Monitoring computer, it means it's been severed from the power net and wire either inside that room or very close to the APC has been cut.
*'''Power is intermittent across the station. Stuff turns off for a while, starts working, then goes off again?''' Your SMES aren't outputting enough power to keep the APCs charged. This happens most often when the output is just under the drain so therefore some APCs get enough power, while others don't.
*'''Power is intermittent across the station. Stuff turns off for a while, starts working, then goes off again?''' Your SMES aren't outputting enough power to keep the APCs charged. This happens most often when the output is just under the drain so therefore some APCs get enough power, while others don't.
*'''Power isn't actually out?''' Either someone is crying wolf or something else has happened to make it ''look'' like power went out, most likely an   [[Random_event#Electrical_Storm|electrical storm]].
*'''The smes'es cycle between getting power and not getting power for seemingly no reason''' Bug. admin help it. Can be fixed by admins by restarting the master controller.
 
*'''Power isn't actually out?''' Either someone is crying wolf or something else has happened to make it ''look'' like power went out, most likely an [[Random_event#Electrical_Storm|electrical storm]].
Now that you know what's wrong with power, it's your job to [[Beyond the impossible|fix it]]! If the singularity is about to be fucked, ''TURN OFF THE PA IMMEDIATELY'' (it may be worth asking the AI) and wire solars, if they aren't already wired. It might also be necessary to replace equipment. There is a PACMAN located in the SMES room and a spare SMES unit located in [[Electrical Maintenance]], both of which no one ever remembers. You could also rebuild everything. The tools to build a new SMES are located in [[Tech Storage]], and cargo can order new solar equipment and even a new goddamn PA! ...Assuming they haven't already done so and pointed it your way, that is.
Now that you know what's wrong with power, it's your job to [[Beyond the impossible|fix it]]! If the singularity is about to be fucked, ''TURN OFF THE PA IMMEDIATELY'' (it may be worth asking the AI) and wire solars, if they aren't already wired. It might also be necessary to replace equipment. There is a PACMAN located in the SMES room and a spare SMES unit located in [[Electrical Maintenance]], both of which no one ever remembers. You could also rebuild everything. The tools to build a new SMES are located in [[Tech Storage]], and cargo can order new solar equipment, and even a new goddamn PA! ...Assuming they haven't already done so and pointed it your way, that is.
 
[[Category:Guides]]
[[Category:Guides]]

Latest revision as of 18:40, 22 November 2023

Introduction

Understanding the intricacies of the power dynamic in the station is key to keeping the station in order. Many, especially the HoP, believe that the Captain is the seat of power on the station. This is untrue as having the Captain wired into the station's power grid provides minimal power at best.

The real source of power comes from Engineering because without Station Engineers to set up the power sources at the beginning of a shift, the station would cease to function normally and devolve into a degenerative society with no more power than a uncivilized horde of lowly Assistants, who, it should be noted, also provide even less power when wired directly to the grid.

Typically the Station needs between 160-180 kW of power. More will be needed to charge the SMES and/or BSA.

Power Sources

Station power can be confusing, if you are a beginner and not doing engineering at least learn how to set up solar, see below.

Supermatter Engine

The supermatter is a giant pile of exotic material capable of emitting both ionizing radiation and (flammable) gases. While the generation of these elements is normally rather low, the supermatter can be "activated" into releasing more by, well, most anything: even gasses can start the delamination process if they hold enough energy (heat, usually). You see where this is going? That's right, self-induced chain reactions. Your main job as an engineer will be to cool the supermatter down to prevent it from exploding (luckily a very easy job), while simultaneously exciting it to harvest radiation pulses. It's not an unforgiving engine, some would say it's even too stable to sabotage in a timely manner; read the Guide carefully and it will be hard to mess it up.

Singularity/Tesla Engine

The singularity and tesla engines are the primary source of power only on PubbyStation. By harnessing either the radiant energy produced by a locally-controlled cosmic Singularity (otherwise known as a man-made black hole), or straight-up capturing the electric arcs from a giant ball of lightning, an enormous amount of energy can be generated for the station.

Singularity Engine

The usable power emitted by a singularity takes the form of ionizing radiation pulses. These can interact with the mysterious substance called "plasma" so as to generate electricity. The more plasma available, and the stronger and more frequent the pulses, the more power is generated. The net power output can be measured directly by using a multitool on the collector's wire, checking the first SMES unit connected for available power, or by looking it up on a power monitoring console (though the latter will give skewed results if other power sources such as solars are connected).

Tesla Engine

This giant ball of incandescent energy regularly regurgitates power in the form of electric arcs. These arcs can be partially captured by tesla coils, and will generally flow along the most conductive/least resisting path. Metal structures are prime target for its strikes, and grounding rods are the safest there is, drawing arcs to themselves and subsequently dissipating them into the whole station. The latter are regularly used to direct lighting through tesla coils, and are best deployed between the engine and anything you hold dear. Don't forget to turn on the shield generators so the energy ball doesn't fly out of engineering.

Solar Arrays

See Solars.

The solar arrays act as a secondary power source. They are composed of 60 panels per array and there are 4 arrays on the station. Each panel can produce 1.5 kW of power for a total of 90 kW per array.

The solar arrays only produce power when directly facing the local star. (The star is off-screen from the station and cannot be located by the player directly.) A solar tracking module can be wired into the solar array circuitry and, with the help of a solar power console, the solar panels can be made to automatically track the local star, which maximizes the power generation for each panel. However, as the station revolves around the star (which, again, is unseen by the player), the solar arrays often land in the shadow of the station which negatively affects solar power generation at the affected arrays. This effectively gives the solar arrays a solar day-night cycle, where it generates power during the day cycle and does not generate power during the night cycle. Because of the solar cycle, a given array will be able to generate power about 50% (estimated but unconfirmed) of the time, which can be translated to an average 45 kW per unit time, rather than the full 90 kW.

The solar panels themselves can be, and often are, broken by debris floating in space. Each broken panel reduces the total power generation of the array.

The solar arrays can typically power the entire station on their own, once the arrays are wired properly.

Solar Power Generated
Maximum Average
per panel per array per array
1500 W (1.5 kW) 90000 W (90 kW) 45000 W (45 kW)

Connecting Solars to the Grid

There are two main schools of thought when wiring the solar arrays:

  • use the Solar SMESs to distribute power into the grid
  • wire the solar array directly into the power grid

Distributing via SMESs

Distributing solar power through the SMESs is the generally preferred method of wiring the solars, mainly because it provides a steady power output and requires no extra wiring. One benefit of the pre-laid wiring to the SMES is that during a night cycle of the solar array the Engineer does not need insulated gloves to wire the solar array.

The maximum power generation of a typical solar array is 90 kW, and it is advised to set SMES inputs to the maximum 200 kW.

The output on the SMES should be at most 50% of the 90 kW generated by the cells due to the revolution of the station around the local star (percentage estimated but unconfirmed). Since the solar has to collect enough energy in the day cycle of the array to output for both day and night, it's usually good to round down a little more. Additionally, if the solar is initially wired during its day cycle, it typically won't be able to collect enough to keep it charged for the first night cycle, resulting in a little bit of lag in the output of the solars. For example, if the solar cells generate 85500 W (85.5 kW), the output shouldn't be bigger than 42750 W (42.75 kW). Typically, 40 kW is a good round number for long-term power output.

If more power storage is desired, say in the initial stage of the set-up, the engineer may want to reduce or even eliminate power output for the first few solar cycles, before setting the long-term power output.

Once all four Solar SMESs are adequately charged and outputting long-term power, they will provide a very dependable power output with almost no oversight needed. In our example, the station would receive 160 kW (4 arrays x 40 kW SMES output) from solars, which is usually more than enough to sustain the station on its own without the engine. This system is also modular, so that even if only three out of four Solar SMESs are used, the total power output is reduced accordingly but still completely steady.

That being said, if unchecked, power sinks can drain the solar SMESs, which if depleted would need to go through a solar cycle again before being able to provide steady, adequate power to the station.

The biggest failure of the Solar SMES system is more often the fault of the Engineer, not the power sink. A rookie Engineer usually forgets to set input levels and output levels to meaningfully sustain the station.

Pros: Steady power supply, no additional wiring necessary, stores power, modular, does not require insulated gloves.

Cons: Lag due to first night cycle and initial SMES charging, prone to being set up improperly, some power loss to correct for potentially broken panels, can be drained by power sinks.

Wiring to the Grid

Wiring the solar arrays directly to the grid is often used as a more straight-forward approach to hooking up the solars, which benefits the Engineer by bypassing the intricacies of the SMES and generating a generally larger power output but at the expense of a less steady, less modular electrical source. This is often helpful in the emergency circumstances where the supermatter crystal has delaminated, taking out the whole of Engineering with it, or when the Singularity or Tesla gets loose.

To achieve this, the Engineer usually just wires together the cable leading from the array directly to the cable leading out from the solar maintenance room. Typically, insulated gloves are a necessity since the Engineer will need to tap the solar power lines into the main power grid. However, as easy as that sounds, rookie Engineers tend to mangle the wiring so much that the array power lines never make it to the grid.

Once all the arrays are wired, and because of the day-night cycle, on average, about two solar arrays worth of power will be generated at any given time, equating to about 180 kW of power. However, the exact number will fluctuate depending on how much light reaches individual panels. Additionally, if not all of the solars are wired to the grid, the output will be drastically lower and may cause brown outs in the station.

On the plus side, wiring the solars directly to the grid prevents wiring sabotage since anyone cutting the wires also needs insulated gloves. Also, power sinks pose little risk as the solar power is immediate and not distributed from an SMES.

Pros: Straight-forward explanation, avoids setting SMES, deters sabotage, acts as primary power source, not prone to power sinks.

Cons: Minor fluctuations in power if fully implemented, severe fluctuations if incompletely implemented, requires insulated gloves, often incorrectly wired.

Dual-Wiring: The Best of Both Worlds

There is another, less used option that utilizes the benefits from both wiring ideologies while mitigating the risk: dual-wire the solar arrays both to the Solar SMESs and directly into the grid at the same time.

Initially, the Engineer would want to charge the SMESs enough to where they could give an adequate supply of power. Then, if the Engineer is skilled enough at wiring, both the SMES and the solar arrays can be wired to the grid at the same time. Since the station only draws about 150 kW, but the solars wired to grid produce 180 kW, there's a spare 30 kW to split between the Solar SMESs for recharging. Setting all four Solar SMESs to charge at 6 kW is feasible (reduced from 7.5 kW to account for broken solar panels). The output setting on the SMES can be any value so long as the station draws full power from the solars wired directly. This effectively makes the Solar SMESs a backup power source.

The drawbacks though are that the Solar SMES input levels should not be put higher than 6 kW since a Solar SMES located at an array going through the night cycle will attempt to draw power from a Solar SMES higher upstream in the #power queue, cannibalizing the power from that SMES.

Also, the 2 conventional Backup SMESs can't be charged for the same reason of the power queue. However, since the 4 Solar SMESs act as backups, this trade-off is in favor of the dual-wiring of the solars.

The Solar SMESs will still be prone to power sinks, but since the solars are wired directly to the grid it doesn't matter much.

The drawback that all solars must be wired directly to the grid to prevent severe fluctuation. The same is not true of the SMES-side of this set-up. Each SMES acts like an independent backup, so any undesired SMESs don't have to be set, making the system semi-modular.

Pros: acts primary and backup power source, deters sabotage, resistant to power sinks, semi-modular, resistant to brownouts

Cons: severe fluctuations if incompletely implemented, requires insulated gloves, often incorrectly wired, requires initial charging and follow up on the SMESs before implementation

Gas Turbine Generator

See: Incinerator

The gas turbine generator is a tertiary power source that was recently installed in the incinerator. By utilizing the temperature differential between very hot air and very cold air, the turbine generator is able to create a nominal amount of electricity. The hot air is created by burning plasma and oxygen gas mixtures. The cold air is creating by passing air through cooling tubes located in space.

Although it's usually the last power source set up on the station, it's the only power source that can be accessed by Atmospherics. Also, they're the only ones who can turn on and mix the gas feed needed to sustain the generator without the use of gas canisters. The exact gas mixture for optimal power generation is unknown at this point, but some Engineers have reported values as high as 100 kW and in typical Engineer fashion forgot to write down their recipe. Be prepared to field questions from overprotective proactive AIs who notice plasma in the mixtank.

Thermal-electric Generator

See: Thermo-Electric Generator

The Thermal-Electric Generator has the potential to generate the most power for the station up to and over a TeraWatt. PubbyStation, CorgStation, MiniStation starts with a TEG and you can get their machine boards easily from an engineering protolathe. Setting up TEG requires some understanding of atmospherics: it requires hot and cold air piped in to generate power and will transfer heat between the two.

If you use the basic SM setup to harvest Oxygen and plasma, burn it and feed it to the TEG it will generate 2-6 MW of power depending on how much cooling you have set up.

Portable Generators

Portable generators are failsafes when all other systems fail. They require fuel that is fed directly into the generator by hand. The type of fuel is dependent which type of generator is being used.

Portable generators can be upgraded using parts created by a protolathe.

Fuel Required by Portable Generator Type
Type Fuel
P.A.C.M.A.N. Portable Generator Plasma
M.R.S.P.A.C.M.A.N. Portable Generator Diamond
S.U.P.E.R.P.A.C.M.A.N. Portable Generator Uranium

One PACMAN generator is located in the SMES room, with plasma located in secure storage, and it is suggested to use it while setting up the singularity or tesla to prevent early release.

Power Cells

Power cells are used to power devices smaller than the station such as APCs and cyborgs. Constructed with a protolathe, typical power cells come in several different flavors, in increasing capacity: the default power cell, the high-capacity power cell, the super-capacity power cell, or the hyper-capacity power cell.

There are also atypical cells such as a potato cell and a slime core cell. A potato cell's capacity is depended on its potency, with 100 at 40MJ. Slime core cells can recharge on its own over time.

Power Capacity by Type of Cell
Type Capacity (MJ)
Typical Cells
Power Cell 10000
High-Capacity Power Cell 15000
Super-Capacity Power Cell 20000
Hyper-Capacity Power Cell 30000
Bluespace Power Cell 40000
Atypical Cells
Potato Cell (max potency) 40000
Charged Slime core cell 10000
HyperCharged Slime core cell 20000

It is possible to power the entire station for around two hours with three SMES filled with Charged Slime core cells.

Power Distribution

Power Grid

To most people they're just wires that burn the shit out of you when you try to cut them without wearing insulated gloves. But really, the power grid is the electrical backbone of the station, powering everything from the emitters containing the singularity to the APC that controls the bathrooms in the locker room that you never go to. Also, it burns the shit out of you if you try to cut it without wearing insulated gloves. At 14MW it instantly husks you.

SMES

A Superconducting Magnetic Energy Storage (SMES) Cell is the spess version of a giant rechargeable battery. The standard set-up for an SMES involves:

1. a wiring input from a power source, such as Solars or the Singularity Engine, or from the power grid itself, in the case of the Backups SMESs, and

2. a wiring output to the local power grid, or to a closed system like the AI or mining stations

SMES Properties

SMES have a modifiable storage capacity, dependent on the power cells installed in the SMES upon fabrication. All SMESs present at the beginning of a typical shift have a default capacity of 3.33 MW.

SMES Capacity vs Power Cell
Power Cell Capacity
per cell installed per 5 cells installed
Typical
Standard 10000 50000
High-Capacity 15000 75000
Super-Capacity 20000 100000
Hyper-Capacity 30000 150000
Bluespace 40000 200000
Atypical
Potato Cell (Max potency) 40000 200000
Charged Slime core cell 10000 50000
Hypercharged Slime core cell 20000 100000

SMES input (charging) and output levels can be modified using capacitors. All SMESs present at the beginning of a typical shift have a basic capacitor with default i/o levels of 200 kW.

SMES Input/Output Levels vs Capacitor
Capacitor Max Input Level Max Output Level
Basic 200000 W (200 kW) 200000 W (200 kW)
Advanced 400000 W (400 kW) 400000 W (400 kW)
Super 600000 W (600 kW) 600000 W (600 kW)
Quadratic 800000 W (800 kW) 800000 W (800 kW)

SMESs will only output when the level of charge is above the output level specified on the SMES settings panel.

APCs

APCs, or Automated Power Controllers, are found on the walls of the room they're powering or, more likely, in maintenance just outside the room. They can be used to toggle the room's equipment, lighting and environmental (a.k.a. ventilation) systems on and off. Their cells can be changed or upgraded to provide more capacity.

Concepts

System Power

System power is the amount of power available to the station at any given time. Power is made available through charged SMESs outputting power and through immediate power from power sources wired directly to the grid.

(System Power) = (Total Output Power of SMESs) + (Power Sources Wired to the Grid)


Power Queue

To maintain a stable source of power for station equipment, the station power grid follows a power queue where an electrical component with higher rank on the queue has its power draw from the grid evaluated before an electrical component with a lower priority. APCs are typically the lowest priority since they only draw power, while the power sources on the station are the highest priority since they only produce power.

Power Queue
Rank Category Location
1 All Power Sources
2 Power Sink On the station power console, look where all the power is dropping to
3 Solar SMES #1 Starboard Forward Solar Access
4 Solar SMES #2 Port Forward Solar Access
5 Solar SMES #3 Starboard Aft Solar Access
6 Solar SMES #4 Port Aft Solar Access
7 Singlo/SM SMES #1 SMES Room
8 Singlo/SM SMES #2 SMES Room
9 Singlo/SM SMES #3 SMES Room
?? Gas Turbine SMES Incinerator Access (Gas Turbine Power Room)
10 Backups SMES #1 Electrical Maintenance
11 Backups SMES #2 Electrical Maintenance
12 Station APC Queue
Isolated SMESs
N/A Gravity SMES Gravity Generator Chamber
N/A AI SMES AI Chamber
N/A AI maintenance SMES AI satellite maintenance
N/A Mining Output SMES Mining Outpost

Power Output and the Power Queue

The most visible effect of the power queue is that if there is not enough output power available on the grid because a component with higher rank is requesting it, then a lower rank component will not charge. For example, if the Backup SMESs are set to input 200 kW each from the grid and the APCs draw 150 kW, but the grid only provides 250 kW total, then the second Backup SMES will not charge and around two out of three APCs will go unpowered as well.

SMES Charging and the Power Queue

File:SMES Room markup.png
The three Singlo SMESs in the SMES Room.

Similarly, if a higher rank component has a high enough output level to handle the station's power draw, then the station will draw all of its power from the higher rank component instead of splitting the draw with a lower rank component. This phenomenon is seen often when the singlo is set up. An unaware Engineer will purposefully set all three Singlo SMESs to output at a very high value, say 100 kW, or 300 kW, thinking that this will be more than enough to power the station. While this is technically correct, it isn't advised since it slows down the time it takes until all SMESs are completely full.

An example is the best way to see this. The total power draw on the station is usually near 150 kW. This means the station will draw 100 kW from Singlo SMES #1, 50 kW from Singlo SMES #2, and 0 kW from Singlo SMES #3, resulting in different charging rates of the SMESs. Since SMESs have a capacity of 3,333,333 W (3.33 MW) and assuming an input level of 200 kW, it should take 33.3 cycles before all the SMESs are completely charged (9.99 MW total power stored).

Singlo SMES Non-optimized Charging for 150 kW Power Draw
Charge at n Cycles
Singlo Cell Input Level Draw Charge Rate 17 23 34
SMES #1 200 kW 100 kW 100 kW 1.70 MW 2.30 MW 3.33 MW
SMES #2 200 kW 50 kW 150 kW 2.55 MW 3.33 MW 3.33 MW
SMES #3 200 kW 0 kW 200 kW 3.33 MW 3.33 MW 3.33 MW
Total 600 kW 150 kW 450 kW 7.58 MW 8.96 MW 9.99 MW

A better way is to set output levels on Singlo SMESs #1 and #2 to a third of the total power draw of the station (here, 50 kW), while allowing the remainder (also, 50 kW) to draw from Singlo SMES #3, which would be set higher than that to account for power fluctuations. For the same case where the total draw was 150 kW, we would set SMES #1 and #2 to 50 kW and SMES #3 to something higher like 200 kW. This would have all three SMESs charged in 22.2 cycles -- 33% faster than the situation above.

File:SMES Output v Cycles to Full v01.png
The optimal number of cycles it takes to charge the singlo SMESs is dependent on both not outputting too little, and not outputting too much.
Singlo SMES Optimized Charging for 150 kW Power Draw
Charge at n Cycles
Singlo Cell Input Level Draw Charge Rate 17 23
SMES #1 200 kW 50 kW 150 kW 2.55 MW 3.33 MW
SMES #2 200 kW 50 kW 150 kW 2.55 MW 3.33 MW
SMES #3 200 kW 50 kW 150 kW 2.55 MW 3.33 MW
Total 600 kW 150 kW 450 kW 7.65 MW 9.99 MW

ENGINEERING WHY ARE WE LOSING POWER

Sooner or later, on every barely functional space station, the power will go out. This is where you - YES, YOU, YOU LAZY FUCK - come in and call out to recall that shuttle because you can fix it! Power can go out for many reasons. Your first port of call should be the Power Monitoring console in engineering, assuming it still exists. Then, ask yourself what's going on:

  • Power goes out everywhere, in under 10 seconds or so? This is most likely a power sink. Power sinks have the odd quirk of still powering the area they are placed in, so your best bet is to get searching for somewhere where the lights are still on, or if it's in maint, where you don't have to crowbar the doors.
  • Power goes out everywhere, but gradually, section by section? This means there's a problem in Engineering itself as the rest of the station is being topped up with charge. It'll be immediately obvious if the engine isn't on/has escaped. Your next port of call should be the SMES cells. Check they're outputting enough power to overcome the drain OR if no APCs are showing on the Power Monitoring computer, it means a wire has been cut either inside or immediately outside the Engineering area and is not being supplied to the rest of the station.
  • Power is out across a small area? This is most commonly a broken wire, the easiest way to find it is with familiarity with the power-net and using that in conjunction with the power monitoring computer. If an area has had all wires sending power to it snipped, its APCs will no longer show on the power monitoring computer. For example, if Medbay as a whole has lost power and isn't showing any of its APCs on the power monitor, the wire cut is most likely in the maint tunnel behind Medbay. The more familiar you become with the power nets, the quicker you will be able to work out where the break is and be able to recognize common spots used.
  • Power is out across 2 small rooms or in one room? This is most likely an APC that has been tampered with in some way. Either hacked by an AI/Saboteur, destroyed somehow or just had its cell ripped out. Again, if the APC doesn't show up on the Power Monitoring computer, it means it's been severed from the power net and wire either inside that room or very close to the APC has been cut.
  • Power is intermittent across the station. Stuff turns off for a while, starts working, then goes off again? Your SMES aren't outputting enough power to keep the APCs charged. This happens most often when the output is just under the drain so therefore some APCs get enough power, while others don't.
  • The smes'es cycle between getting power and not getting power for seemingly no reason Bug. admin help it. Can be fixed by admins by restarting the master controller.
  • Power isn't actually out? Either someone is crying wolf or something else has happened to make it look like power went out, most likely an electrical storm.

Now that you know what's wrong with power, it's your job to fix it! If the singularity is about to be fucked, TURN OFF THE PA IMMEDIATELY (it may be worth asking the AI) and wire solars, if they aren't already wired. It might also be necessary to replace equipment. There is a PACMAN located in the SMES room and a spare SMES unit located in Electrical Maintenance, both of which no one ever remembers. You could also rebuild everything. The tools to build a new SMES are located in Tech Storage, and cargo can order new solar equipment, and even a new goddamn PA! ...Assuming they haven't already done so and pointed it your way, that is.