Furnace: Difference between revisions

Furnace
Operation
Prefab Hash	1947944864
Prefab Name	StructureFurnace
Construction
Placed with	Kit (Furnace)
Placed on	Small Grid
Stage 1
	Next Stage Construction
Constructed with tool	Wrench
Constructed with item	2x Iron Sheets
	Deconstruction
Deconstructed with	Crowbar
Item received	Kit (Furnace)
Stage 2
	Next Stage Construction
Constructed with tool	Welding Torch
Constructed with item	2x Iron Sheets
	Deconstruction
Deconstructed with	Crowbar
Item received	2x Iron Sheets
Stage 3
	Deconstruction
Deconstructed with	Angle Grinder
Item received	2x Iron Sheets
	v; t; e;

Kit (Furnace)
Volume	1000 L
Recipes
Autolathe	30g Iron, 10g Copper
Fabricator	30g Iron, 10g Copper
	v; t; e;

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VisualWikitext

Latest revision as of 06:10, 20 March 2026

This article is about the basic furnace. For the advanced version, see Advanced Furnace.

Description

The Furnace is used to smelt ore into ingots and alloys using an oxygen/volatile gas mix gas mix. Oxite and Volatiles can be manually input directly in the furnace in order to create crude gas mixtures, or gases can be fed into the furnace in measure amounts. The furnace can also be used to melt Ices which can then be directly extracted as an easy trick for melting ice.

It features a gas pipe input port (connected to its internal storage through an internal always-open one-way valve), a gas pipe output port (which lacks a one-way valve and acts as a bidirectional gas port), and a liquid output port (which acts as an always-open condensation valve).

If the contents of the furnace are ejected without reaching the required temperature and pressure for smelting, they'll come out as Reagent Mix which can be processed in a Centrifuge to recover the raw ores. Reagent Mix can also be re-smelted if the ingredients and ratios are a valid alloy recipe. This allows an intermission when the resources for reaching the required temperature / pressure are not on hand / need to be gathered first. Effectively, this means that the used metals can be 'reserved' for the intended alloy.

The Furnace can be used to smelt basic ores and to make simpler alloys, but an Advanced Furnace will be required for the more complex alloys.

An Arc Furnace (included in the starting gear) is required to make the metals for manufacturing a Furnace. By comparison, the Furnace can do everything the Arc Furnace can do, but without using electricity, and far more efficiently.

Danger: The furnace is not insulated, so it interacts with the surrounding atmosphere and can heat rooms to dangerous levels within minutes.

All the alloys the furnace can smelt are easily achieved with ice, and they can also be smelted using gases fed into the furnace through the pipe inputs. Regardless of which method is used the furnace gases must be purged thru a working piping setup (a valve and passive vent at bare minimum to vent the internal gasses).

Gaseous fuel can be premixed and fed into the furnace. This can be done by feeding Volatile ices and Oxite ices in an Ice Crusher in the correct ratio to produce fuel. There are a number of different gases mixtures.
The Furnace's output can also be extracted and vented/recycled through a backpressure regulator to maintain furnace pressure. Adding additional gases to the furnace can result in lower temperature if that is desired, but you could also use a volume pump with a lower fuel input setting.

Make sure to put the fuel in first, then press the activate button. Afterwards put in the ingredients and press the handle after you see the "will produce" while hovering over the furnace. Also, You MUST put in exact amounts matching the recipe amounts. For instance, you must put in 12 iron and 4 coal to make 16 steel. You cannot put in 12 iron and 7 coal. The furnace will not manufacture anything if the ingredient ratios are not correct and you will have to eject it all or add resources to balance the recipe.

Smelting

Required conditions for smelting

The following table shows the pressure and temperature conditions required to smelt various ores and alloys.

Ingot	Input	Pressure (MPa)		Temperature (K)		Temperature (°C)
Ingot	Input	Min	Max	Min	Max	Min	Max
1 Charcoal	1 Biomass	0.1 MPa	100 MPa	580 K	100 kK	307°C	99726°C
1 Silicon	1 Silicon	0.1 MPa	100 MPa	900 K	100 kK	627°C	99726°C
1 Iron	1 Iron	0.1 MPa	100 MPa	800 K	100 kK	527°C	99726°C
1 Gold	1 Gold	0.1 MPa	100 MPa	600 K	100 kK	327°C	99726°C
1 Copper	1 Copper	0.1 MPa	100 MPa	600 K	100 kK	327°C	99726°C
1 Silver	1 Silver	0.1 MPa	100 MPa	600 K	100 kK	327°C	99726°C
1 Lead	1 Lead	0.1 MPa	100 MPa	400 K	100 kK	127°C	99726°C
1 Nickel	1 Nickel	0.1 MPa	100 MPa	800 K	100 kK	527°C	99726°C
4 Steel	3 Iron 1 Coal	1 MPa	100 MPa	900 K	100 kK	627°C	99726°C
2 Electrum	1 Silver 1 Gold	0.8 MPa	2.4 MPa	600 K	100 kK	327°C	99726°C
2 Invar	1 Iron 1 Nickel	18 MPa	20 MPa	1.2 kK	1.5 kK	927°C	1227°C
2 Constantan	1 Copper 1 Nickel	20 MPa	100 MPa	1 kK	10 kK	727°C	9726°C
2 Solder	1 Iron 1 Lead	1 MPa	100 MPa	350 K	550 K	77°C	277°C
Update 0.2.2768.13597 - Thu 11/02/2021 /Recipes

Alloy recipes

Ice only recipes

The ices should be loaded into the furnace and ignited, and then the ores should be loaded immediately after. No wait time is necessary. Make sure to put the fuel in first, then press the activate button. Afterwards put in the ingredients and wait for the button to turn green again, or until you see the "will produce" while hovering over the furnace. Then pull the handle and your alloy will be ejected.

Ice Chunks	Ingredients	Temperature	Pressure	Alloy
2 Volatiles 1 Oxite	150 Iron Ore 50 Coal	950 K	6.82 MPa	200 Steel
13 Volatiles 7 Oxite	50 Copper Ore 50 Nickel Ore	1.72 kK	20.8 MPa	100 Constantan
9 Volatiles 24 Oxite	50 Nickel Ore 50 Iron Ore	1.43 kK	18.7 MPa	100 Invar
1 Volatiles 1 Oxite	50 Silver Ingot * 50 Gold Ingot *	1020 K	840 KPa	100 Electrum
1 Volatiles 2 Nitrice 4 Water Ice	50 Lead Ingot * 50 Iron Ore**	526 K	1.26 MPa	100 Solder

*** Ingots are used instead of raw ores to prevent the production of extra gases when making these recipes

Gaseous Fuel Recipes

In this setup fuel is pumped into the furnace from either pre-measured canisters or pumped into the furnace in measured amounts. Fuel and be any number of gas mixtures.

The gas should be pumped into the furnace and ignited; the ores should be placed in the furnace as soon as the gases are ignited. It is not necessary to wait for the furnace to come up to temperature. Make sure to put the fuel in first, then press the activate button. Afterwards put in the ingredients and wait for the button to turn green again, until you see the "will produce" while hovering over the furnace. Then pull the handle and your alloy will be ejected.

Dirty fuel

Dirty Fuel is a 2:1 mixture of Volatile and Oxites gases. The table below shows the correct pressures of gases to load into a canister, but currently omits Hydrogen and Nitrogen quantities.

Canister Pressure @ 0°C	Gases	Ingredients	Temperature	Pressure	Alloy
1,500 KPa Dirty Fuel	24.5 Mols Volatiles 13.8 Mols Oxygen	75 Iron Ore 25 Coal	907 K	4.72 MPa	100 Steel
2,700 KPa Dirty Fuel	44.1 Mols Volatiles 24.8 Mols Oxygen	150 Iron Ore 50 Coal	907 K	9.28 MPa	200 Steel
250 KPa Dirty Fuel	4.09 Mols Volatiles 2.3 Mols Oxygen	50 Silver Ore 50 Gold Ore	695 K	1.62 MPa	100 Electrum
45 KPa Dirty Fuel	0.741 Mols Volatiles 0.417 Mols Oxygen	50 Lead Ore 50 Iron Ore	407 K	1.07 MPa	100 Solder
(2x) 7,500 KPa Dirty Fuel	245 Mols Volatiles 138 Mols Oxygen	50 Copper Ore 50 Nickel Ore	1.83 kK	20.5 MPa	100 Constantan
(2x) 6,000 KPa Dirty Fuel (2x) 9,500 KPa Pressurant	196 Mols Volatiles 110 Mols Oxygen 533 Mols Pressurant ^^^	50 Nickel Ore 50 Iron Ore	1.38 kK	19.2 MPa	100 Invar

^^^These recipes use CO2 @ 0°C as a pressurant. Other pressurants such as Nitrogen, Pollutants, and Oxygen are possible, but they may result in different outcomes.

Tips

Placing 15 ice(volatiles) and 15 ice(oxite) will bring pressure to around 22000kpa and temp 2000k. For Invar, you will have to wait for the temperature to drop before you can process. You can use this time while the pressure is still over 20000kpa to make constantan.
All other alloys can be achieved with a ratio of 2 volatiles to 1 oxite
If atmosphere inside and/or around furnace is too cold to melt ice one can press 'activate' button to manually melt one ice per ignition attempt. You will need to press the ignition button for each piece of ice from the first stack that you put in. Until all solid matter was melted the import slot will remain blocked.
Reagent Mix can be re-melted to continue balancing the recipe should you need to gather more resources or find yourself unable to balance the temperature/pressure manually.
On Vulcan the daytime temperatures allow smelting of many basic alloys right from the start by using an active vent, even high enough for Steel. This will save the very valuable, and limited oxygen of the player, especially on brutal start conditions.
Placing 50 silver ore into an ignited furnace will produce 50 Mol of N2O inside the furnace, which can be further burned in the presence of volatiles resulting in a higher temperature after smelting. This will push the furnace temperature beyond what may be otherwise obtainable (early game daytime Vulcan, for example).

Additional fuel mixes

Prime	FAR	In: Mols		Result			Out: Mols
Prime	FAR	H2	O2	Press.	Celcius	Kelvin	O2	H2	Co2	X
100 kPa	2:1	29	14	2 135	1 953	2 216	1	3	82	33
200 kPa	2:1	59	29	4 500	2 000	2 273	1	5	169	80
200 kPa	3:1	65	21	3 400	1 900	2 173	2	26	118	52
200 kPa	4:1	72	18	3 000	1 800	2 273	1	40	99	42
200 kPa	1:1	43	43	3 493	1 917	2 190	22	2	127	59
200 kPa	1:4	17	68	1 646	1 319	1 592	63	2	50	18
300 kPa	2:1	86	42	6 850	2 109	2 382	2	7	242	115
902.7 kPa	2:1	263	108	19.25 MPa	2 054	2 357	70	7	767	151
1 MPa	2:1	291	120	21.62 MPa	2 061	2 334	74	7	862	170
1.497 MPa	2:1	408	204	35.34 MPa	2 121	2 394	10	20	1163	581

Ore Off-Gassing

Ores being smelted release gases, unless they have been previously sent through a furnace or centrifuge. However both the centrifuge and arc furnace require additional time and energy to remove gases from ores, and the gases will be lost. These gases will increase pressure and lower temperature inside the furnace, but can also be beneficial to the smelting process. For example Solder, requires very little fuel to smelt due to the N20 released from the Lead Ore during smelting. Removing the N20 from the lead ore prior to smelting will result in the need for additional fuel to make up for it's loss.

CAUTION: As Vol is far more reactive with N2O and burns at a rate of 1:1, rather than 2:1 with O2, be cautious to not add additional volatiles after smelting silver or lead ores. Doing so could lead to rapid spikes in pressure and, not managed properly, could lead to a furnace exploding.

Ore	Out: Mols
Ore	Vol	X	N2	CO2	O2	N2O
1 Biomass	8.0	4.0	0.0	0.0	0.0	0.0
1 Coal	0.0	3.0	0.0	10.0	0.0	0.0
1 Silicon	0.0	1.0	1.0	1.0	0.0	0.0
1 Iron	0.0	2.0	0.0	0.5	0.0	0.0
1 Gold	0.0	2.0	0.5	0.2	0.2	0.0
1 Copper	0.0	1.0	0.5	1.0	0.0	0.0
1 Silver	0.0	1.0	0.4	0.0	0.0	1.0
1 Lead	0.0	2.0	1.0	0.4	0.0	0.4
1 Nickel	0.0	1.0	0.5	1.0	0.0	0.0
1 Cobalt	1.0	0.0	3.0	0.0	0.0	0.0

Data Network Properties

These are all Data Network properties of this device.

Data Parameters

These are all parameters that can be written with a Logic Writer, Batch Writer, or Integrated Circuit (IC10).

Parameter Name	Data Type	Description
Activate	Boolean	Activates the Furnace, when set to 1.
ClearMemory	Boolean	When set to 1,clears the counter memory(e.g.ExportCount). Will set itself back to 0 when actioned.
Lock	Boolean	Locks the Furnace, when set to 1. Unlocks it when set to 0.
Mode	Integer	Returns whether the Furnace is smelting. (0 for no, 1 for yes).
Open	Boolean	Opens the Furnace, when set to 1. Closes it, when set to 0.
Setting	Float	(Unknown) Affects the Setting output.

Data Outputs

These are all parameters, that can be read with a Logic Reader or a Slot Reader. The outputs are listed in the order a Logic Reader's "VAR" setting cycles through them.

Output Name	Data Type	Description
Activate	Boolean	Returns if the furnace is active.
Combustion	Boolean	Returns 1 if the furnace atmosphere is on fire.
ExportCount	Integer	How many items exported since last ClearMemory.
ImportCount	Integer	How many items imported since last ClearMemory.
Lock	Boolean	Returns whether the Furnace is locked.
Maximum	Integer	(Unknown) Returns 100.
Mode	Integer	Returns whether the Furnace is smelting. (0 for no, 1 for yes).
Open	Boolean	Returns whether the Furnace is open. (0 for no, 1 for yes).
PrefabHash	Integer	The hash of the structure.
Pressure	Float	Returns the pressure in the Furnace in kilo pascal.
Ratio	Float	(Unknown) Returns 0.5.
RatioCarbonDioxide	Float	Returns a range from 0.0 to 1.0. Returns the percentage ratio of the amount of carbon dioxide in the Furnace.
RatioNitrogen	Float	Returns a range from 0.0 to 1.0. Returns the percentage ratio of the amount of nitrogen in the Furnace.
RatioNitrousOxide	Float	Returns a range from 0.0 to 1.0. Returns the percentage ratio of the amount of nitrous oxide in the Furnace.
RatioOxygen	Float	Returns a range from 0.0 to 1.0. Returns the percentage ratio of the amount of oxygen in the Furnace.
RatioPollutant	Float	Returns a range from 0.0 to 1.0. Returns the percentage ratio of the amount of pollutant in the Furnace.
RatioVolatiles	Float	Returns a range from 0.0 to 1.0. Returns the percentage ratio of the amount of volatiles in the Furnace.
RatioWater	Float	Returns a range from 0.0 to 1.0. Returns the percentage ratio of the amount of water in the Furnace.
Reagents	Float	Returns the amount of reagents (smeltable ores, not counting ice) in the Furnace, in grams.
RecipeHash	int	Current hash of the recipe the device is set to produce.
Setting	Float	(Unknown) Affected by the Setting parameter.
Temperature	Float	Returns the temperature in the Furnace in kelvin.
TotalMoles	Float	Returns the total moles of the furnace.