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Difference between revisions of "H2 Combustor"

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  | name            = H2 Combustor
 
  | name            = H2 Combustor
 
  | image            = [[File:H2 Combustor.jpg]]
 
  | image            = [[File:H2 Combustor.jpg]]
  | power_usage      = 20W
+
  | power_usage      = 10W
 
  | placed_with_item = [[Kit (Atmospherics)]]
 
  | placed_with_item = [[Kit (Atmospherics)]]
 
  | placed_on_grid  = Small Grid
 
  | placed_on_grid  = Small Grid
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<!--T:1-->
 
<!--T:1-->
 
=Description=
 
=Description=
Burns a mix of volatiles and oxygen to create [[Water]] and heat. A [[Kit (Volume Pump)|Volume pump]] before the Combustor is a must because up to 350 mol may be processed all at once, far too quickly for one to be able to cool using an [[Kit (Atmospherics) Air Conditioner|AC unit]].
+
Burns a fuel mixture of volatiles and oxygen to produce high-temperature [[Water|Steam]]. The H2 Combustor should be fed a 2:1 ratio of volatiles to oxygen.  It will output mix of gases at 2500 C, made up of approximately 46.67% [[Carbon Dioxide]], 30% [[Water|Steam]], and 23.33% [[Pollutant||Pollutants]], plus trace amounts of unburnt volatiles and oxygen.
  
 
To generate electricity with fuel instead, see the [[Kit (Gas Fuel Generator)|Gas Fuel Generator]]. Alternatively, the heat generated by the H2 Combustor may be used with a [[Kit (Stirling Engine)|Stirling Engine]] to generate power at a much lower efficiency.
 
To generate electricity with fuel instead, see the [[Kit (Gas Fuel Generator)|Gas Fuel Generator]]. Alternatively, the heat generated by the H2 Combustor may be used with a [[Kit (Stirling Engine)|Stirling Engine]] to generate power at a much lower efficiency.
  
Using a [[Kit (Heat Exchanger)]] to power a [[Stirling Engine]] is a preferred first step due to it's speed and efficiency on certain planets outside to help cool your water and generate up to 8kW before AC Units are used to get the water down to 0-100 to be consumable, making it possibly a zero-loss system in perfect conditions. Alternatively, the outputs may be air-cooled using radiators on cooler planets or in a vacuum.
+
However, while lower efficiency than a Gas Fuel Generator, in terms of energy output per mole of fuel input, a [[Stirling Engine]] is a practical and effective first step for cooling the output due to the fact that it generates power from cooling, rather than consuming power to cool the output (such as with an [[Air Conditioner]]). Depending on the exact setup, and how efficiently the Stirling Engine can be cooled (best on cold non-vacuum planets like Europa and Mars), it's possible for the Stirling Engine to offset the power cost of H2 Combustor, Filtration, and the entire rest of the cooling system, resulting in a zero-loss or even net-positive system. Alternatively, the outputs may be air-cooled using radiators on cooler planets or in a vacuum.
 +
 
 +
200 Moles of Volatiles and 100 Moles of Oxygen will produce 135 Moles of Water + Waste products.
  
 
<!--T:2-->
 
<!--T:2-->
 
=Characteristics=
 
=Characteristics=
* Consumes up to 350 mol of [[Fuel]] per tick.
+
* Consumes fuel from the input, requiring a 2:1 mix of volatiles to oxygen.  Imprecise ratios will result in lower production rate, and the unburnt excess in the output.
* It converts H2 and O2 to H2O at a conversion ratio of 2:1.
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* Produces approximately 46% more moles output than the fuel input consumed.
* 2H2 + 1O2 = 1H2O
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* Rate of fuel consumption from the input, and thus rate of production, is based on the pressure of the input.  The unit will consume 3.42 L of fuel from the input each tick.
* Casing is not insulated, will significantly heat up the surrounding environment.
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* Has an internal volume of 100L, where the product of the combustion is stored before being pushed to the output pipe. 
* H2 combuster may be placed in a Vacuum or inside a Frame if the temperature wants to be kept for manufacturing hot gasses.
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* The unit, and gas inside it, will interact with the surrounding environment, as well as radiating heat in a vacuum (and thus cooling the gas inside it).  In an air-filled room, this will significantly heat the surroundings.
* In one tick, if given a 2000L input network of fuel at 6MPa, will consume 350 mol of Fuel to output 350 Mol of Water at '''7000''' Celcius.  
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* The initial temperature of the products is 2500 C.
* Gas output is optional, will output unburned fuel at 4000 Celcius.
+
* The water in the output is initially produced as a liquid before rapidly evaporating due to the temperature.  This results in noticeable innate cooling of the output, up to ~100 C.  Further losses from radiation or convection cooling of the surroundings also assist with this.
 
+
* Each tick that the unit is ''turned on'', it will first equalize its internal volume with the output pipe network, before pulling in and combusting more fuel to add to the internal volume.
<!--T:3-->
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** This only occurs when the unit is turned on, so if the unit is switched off, whatever gas remains in the unit will continue cooling through radiation or convection without equalizing to the output pipe.
=Notes=
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** Since the equalization occurs before more fuel is pulled in, after the first tick the unit is on, it will have gases stored inside it but won't have pushed any to the output pipe yet.
* Best not used indoors, output is incredibly difficult to cool down.
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** Has a ''Mode'' variable that can be set to 0 to allow the unit to be kept on, and continue to push gases to the output, without pulling more fuel in.
 +
* Consumes only 10 W of power even when running.
  
 
{{Logic}}
 
{{Logic}}
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! Parameter !! Type !! Access !! Description
 
! Parameter !! Type !! Access !! Description
 
|-
 
|-
| Activate || Boolean || Read/Write || 1 if a device is activated (usually meaning running), otherwise 0.
+
| On || Boolean || Read/Write || The current state of the device, 0 for off, 1 for on.
 
|-
 
|-
| On || Boolean || Read/Write || The current state of the device, 0 for off, 1 for on.
+
| Mode || Boolean || Read/Write || Whether the unit pulls in more fuel input, if the unit is also turned on.  1 (default) for pulling more fuel in, 0 to disable input.
 +
|-
 +
| Activate || Boolean || Read/Write || Same effect as, and synced with, the ''Mode'' var.
 
|-
 
|-
| RequiredPower|| Float || Read-only || Idle operating power quantity, does not necessarily include extra demand power.
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| RequiredPower|| Float || Read-only || Idle and active operating power quantity.  10W.
 
|-
 
|-
 
| Error || Boolean || Read-only || 1 if the device is in error state, otherwise 0.
 
| Error || Boolean || Read-only || 1 if the device is in error state, otherwise 0.
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| Power || Float  || Read-only || Can be read to return if the device is correctly powered or not, set via power system, return 1 if powered and 0 if not.
 
| Power || Float  || Read-only || Can be read to return if the device is correctly powered or not, set via power system, return 1 if powered and 0 if not.
 
|-
 
|-
| Setting || Integer || Read/Write || Volume to output on the exhaust pipe (0-100)
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| Setting || Integer || Read/Write || No apparent effect.
 
|-
 
|-
 
| Lock || Boolean || Read/Write || 1 if a device is locked, otherwise 0, can be set in most devices and prevents the user from writing values.
 
| Lock || Boolean || Read/Write || 1 if a device is locked, otherwise 0, can be set in most devices and prevents the user from writing values.

Latest revision as of 01:25, 27 June 2024


H2 Combustor
H2 Combustor.jpg
Operation
Power Usage 10W
Construction
Placed with Kit (Atmospherics)
Placed on Small Grid
Stage 1
Deconstruction
Deconstructed with Drill
Item received Kit (Atmospherics)

Description[edit]

Burns a fuel mixture of volatiles and oxygen to produce high-temperature Steam. The H2 Combustor should be fed a 2:1 ratio of volatiles to oxygen. It will output mix of gases at 2500 C, made up of approximately 46.67% Carbon Dioxide, 30% Steam, and 23.33% |Pollutants, plus trace amounts of unburnt volatiles and oxygen.

To generate electricity with fuel instead, see the Gas Fuel Generator. Alternatively, the heat generated by the H2 Combustor may be used with a Stirling Engine to generate power at a much lower efficiency.

However, while lower efficiency than a Gas Fuel Generator, in terms of energy output per mole of fuel input, a Stirling Engine is a practical and effective first step for cooling the output due to the fact that it generates power from cooling, rather than consuming power to cool the output (such as with an Air Conditioner). Depending on the exact setup, and how efficiently the Stirling Engine can be cooled (best on cold non-vacuum planets like Europa and Mars), it's possible for the Stirling Engine to offset the power cost of H2 Combustor, Filtration, and the entire rest of the cooling system, resulting in a zero-loss or even net-positive system. Alternatively, the outputs may be air-cooled using radiators on cooler planets or in a vacuum.

200 Moles of Volatiles and 100 Moles of Oxygen will produce 135 Moles of Water + Waste products.

Characteristics[edit]

  • Consumes fuel from the input, requiring a 2:1 mix of volatiles to oxygen. Imprecise ratios will result in lower production rate, and the unburnt excess in the output.
  • Produces approximately 46% more moles output than the fuel input consumed.
  • Rate of fuel consumption from the input, and thus rate of production, is based on the pressure of the input. The unit will consume 3.42 L of fuel from the input each tick.
  • Has an internal volume of 100L, where the product of the combustion is stored before being pushed to the output pipe.
  • The unit, and gas inside it, will interact with the surrounding environment, as well as radiating heat in a vacuum (and thus cooling the gas inside it). In an air-filled room, this will significantly heat the surroundings.
  • The initial temperature of the products is 2500 C.
  • The water in the output is initially produced as a liquid before rapidly evaporating due to the temperature. This results in noticeable innate cooling of the output, up to ~100 C. Further losses from radiation or convection cooling of the surroundings also assist with this.
  • Each tick that the unit is turned on, it will first equalize its internal volume with the output pipe network, before pulling in and combusting more fuel to add to the internal volume.
    • This only occurs when the unit is turned on, so if the unit is switched off, whatever gas remains in the unit will continue cooling through radiation or convection without equalizing to the output pipe.
    • Since the equalization occurs before more fuel is pulled in, after the first tick the unit is on, it will have gases stored inside it but won't have pushed any to the output pipe yet.
    • Has a Mode variable that can be set to 0 to allow the unit to be kept on, and continue to push gases to the output, without pulling more fuel in.
  • Consumes only 10 W of power even when running.

Logic[edit]

These are all the logic parameters of the device.

Parameter Type Access Description
On Boolean Read/Write The current state of the device, 0 for off, 1 for on.
Mode Boolean Read/Write Whether the unit pulls in more fuel input, if the unit is also turned on. 1 (default) for pulling more fuel in, 0 to disable input.
Activate Boolean Read/Write Same effect as, and synced with, the Mode var.
RequiredPower Float Read-only Idle and active operating power quantity. 10W.
Error Boolean Read-only 1 if the device is in error state, otherwise 0.
Power Float Read-only Can be read to return if the device is correctly powered or not, set via power system, return 1 if powered and 0 if not.
Setting Integer Read/Write No apparent effect.
Lock Boolean Read/Write 1 if a device is locked, otherwise 0, can be set in most devices and prevents the user from writing values.
PrefabHash Integer Read-only The hash of the structure.
Maximum Float Read-only Maximum setting of the device.
Ratio Float Read-only Context specific value depending on the device, 0 to based ratio.

See Also[edit]