Oni Where Does the Metal Refinery Cooling Interact With the Floor?

This clause has non been revised for the current interpretation ( U37-484114 ). It was last updated for LU-356355. It English hawthorn moderate inaccuracies.

This clause has non been revised for the current version ( U37-484114 ). IT was last updated for Lutetium-356355. It Crataegus oxycantha contain inaccuracies.

This clause has not been amended for the rife version ( U37-484114 ). It was last updated for LU-356355. It May contain inaccuracies.

Metallike Refinery is a Refinement Building, which serves the intention of turn Metallic-looking Ore into Refined Metal, as well as producing alloys. It produces a lot of heat, and mopes part of information technology into coolant liquid.

Mechanics [ ]

A Metal Refinery requires a Fluent Uptake and Output Pipes, 400 kg of Liquid as a coolant (stores 800 kg, and can accept 400 more while the task is scheduled), Duplicant operation, and 1.2 kW of Power. It refines metals 100 kg at a time, going away the Refined Alloy on the floor at 40 °C, as fortunate as producing 16 kDTU/s of heat and outputting 400 kg of coolant at a higher temperature. The heat added to the coolant is 80% of the heat required to heating system the refined metal from 40 °C to its melting point. Recipes withdraw 40 seconds merely information technology can be decreased by the Machinery attribute.

Piece the Metal Refinery can operate with scarcely 400 kg of coolant, it is advised to add 800-1200 kg thus that IT can operate continuously.

Input	Output	Added Warmth [DTU]	Rate [DTU/s]	Tempature Increase (Water) [°C]	Tempature Increase (Unprocessed Oil) [°C]	Tempature Increase (Petroleum) [°C]	Tempature Increase (Super Coolant) [°C]
Gold Amalgam	Gold	10,566,648	264,166.2	6.32	15.63	15.01	3.13
Pig Ore	Copper	32,152,120	803,803.0	19.23	47.56	45.67	9.52
Iron manganese tungsten	Tungsten	36,256,000	906,400.0	21.69	53.63	51.50	10.74
Al Ore	Atomic number 13	45,157,840	1,128,946.0	27.01	66.80	64.14	13.38
Co Ore	Atomic number 27	48,810,720	1,220,268.0	29.20	72.21	69.33	14.46
Thermium	Niobium	51,661,220	1,291,530.5	30.91	76.42	73.38	15.30
Iron pyrite	Iron	53,696,808	1,342,420.2	32.12	79.43	76.27	15.91
Iron Ore	Fe	53,696,808	1,342,420.2	32.12	79.43	76.27	15.91
70 kilogram Iron 20 kg Refined Carbon 10 kg Lime	Blade	93,566,480	2,339,162.0	55.97	138.41	132.91	27.72

Choosing Coolant Liquid [ ]

Often the best choice is based on availability, specifically practicality and quantity. Brine or Polluted Water fresh from a Geyser is about -10°C, for instance. This irrigate is typically unsuitable for a Water Sieve or Desalinator: the water freezes as soon as it is extracted and breaks the end product pipe. The Metal Refinery typically adds just decent heat to enable H2O extraction. Or els, the colony could run it through the refinery more than once so it's hot enough for Pincha Peppers to drink without getting too cold.

Liquids where the temperature growth is large than the temperature range between solid and vapourised changeover are struck out. Liquids that can only perform one operation at a time are underlined.

Liquids that cannot be obtained outside of sandbox way are unlisted. These are Helium, Quicksilver, and Propane.

All temperature ranges are 6 degrees larger than foreseen, since materials need to go 3°C beyond a phase transition temperature to actually change their state.

Each values are truncated to 2 decimal places.

Temperature Increment connected some Liquid used as Coolant

Coolant	SHC	Temperature Run	Temperature rise with output [Anders Celsius]
			Gold	Copper	Tungsten	Aluminum	Cobalt	Nb	Iron	Steel
Liquid Hydrogen	2.400	-259.15 ↔ -252.15 °C	11.01	33.49	37.77	47.04	50.84	53.81	55.93	97.47
Visco-Gel	1.550	-30.65 ↔ 479.85 °C	17.04	51.86	58.48	72.84	78.73	83.32	86.61	150.91
Liquid Carbon	0.710	3551.85 ↔ 4826.85 °C	37.21	113.21	127.66	159.01	171.87	181.91	189.07	329.46
Liquid Atomic number 8	1.010	-218.79 ↔ -182.96 °C	26.16	79.58	89.74	111.78	120.82	127.87	132.91	231.60
Methane	2.191	-182.6 ↔ -161.5 °C	12.06	36.69	41.37	51.53	55.69	58.95	61.27	106.76
Water	4.179	-0.65 ↔ 99.35 °C	6.32	19.23	21.69	27.01	29.20	30.91	32.12	55.97
Polluted Water supply	4.179	-20.65 ↔ 119.35 °C	6.32	19.23	21.69	27.01	29.20	30.91	32.12	55.97
Strategic Arms Limitation Talks Water	4.100	-7.5 ↔ 99.69 °C	6.44	19.60	22.11	27.54	29.76	31.50	32.74	57.05
Brine	3.400	-22.5 ↔ 102.75 °C	7.77	23.64	26.66	33.20	35.89	37.99	39.48	68.80
Liquid Phosphorus	0.770	44.15 ↔ 280.45 °C	34.31	104.39	117.71	146.62	158.48	167.73	174.34	303.79
Liquid Sulfur	0.700	115.2 ↔ 337 °C	37.74	114.83	129.49	161.28	174.32	184.50	191.77	334.17
Molten Salt	0.700	799.85 ↔ 1464.85 °C	37.74	114.83	129.49	161.28	174.32	184.50	191.77	334.17
Liquid Chlorine	0.480	-100.98 ↔ -34.6 °C	55.03	167.46	188.83	235.20	254.22	269.07	279.67	487.33
Fluid C Dioxide	0.846	-56.55 ↔ -48.15 °C	31.23	95.01	107.14	133.45	144.24	152.66	158.68	276.50
Ethanol	2.460	-114.05 ↔ 78.35 °C	10.74	32.67	36.85	45.89	49.60	52.50	54.57	95.09
Magma	1.000	1409.85 ↔ 2356.85 °C	26.42	80.38	90.64	112.89	122.03	129.15	134.24	233.92
Molten Glass	0.200	1126.85 ↔ 2356.85 °C	132.08	401.90	453.20	564.47	610.13	645.77	671.21	1169.58
Liquid Iron	0.449	1534.85 ↔ 2749.85 °C	58.83	179.02	201.87	251.44	271.77	287.65	298.98	520.97
Molten Aluminum	0.910	660.3 ↔ 2470 °C	29.03	88.33	99.60	124.06	134.10	141.93	147.52	257.05
Liquid Copper	0.386	1083.85 ↔ 2560.85 °C	68.44	208.24	234.82	292.47	316.13	334.59	347.78	606.00
Fusible Steel	0.386	1083.85 ↔ 3826.85 °C	68.44	208.24	234.82	292.47	316.13	334.59	347.78	606.00
Center Waste	7.440	26.9 ↔ 526.9 °C	3.55	10.80	12.18	15.17	16.40	17.36	18.04	31.44
Petroleum	1.760	-57.15 ↔ 538.85 °C	15.01	45.67	51.50	64.14	69.33	73.38	76.27	132.91
Liquid Atomic number 41	0.265	2476.85 ↔ 4743.85 °C	99.69	303.32	342.04	426.02	460.48	487.37	506.57	882.70
Naphtha	2.191	-50.15 ↔ 538.85 °C	12.06	36.69	41.37	51.53	55.69	58.95	61.27	106.76
Liquid Tungsten	0.134	3421.85 ↔ 5929.85 °C	197.14	599.85	676.42	842.50	910.65	963.83	1001.81	1745.64
Liquid Gold	0.129	1063.85 ↔ 2855.85 °C	204.78	623.10	702.64	875.15	945.94	1001.19	1040.64	1813.30
Molten Lead	0.128	327.5 ↔ 1749 °C	206.38	627.97	708.13	881.99	953.33	1009.01	1048.77	1827.47
Crack Coolant	8.440	-271.15 ↔ 436.85 °C	3.13	9.52	10.74	13.38	14.46	15.30	15.91	27.72
Fossil oil	1.690	-40.15 ↔ 399.85 °C	15.63	47.56	53.63	66.80	72.21	76.42	79.43	138.41

How many times coolant tooshie be used in front cooling is necessary (values on a lower floor 1 cannot safely be old)

Coolant	Practicality
	Aureate	Copper	Tungsten	Aluminum	Cobalt	Press	Steel
Carbon	34.429	11.315	10.035	8.056	7.445	6.775	3.888
Carbonic acid gas	0.461	0.152	0.134	0.107	0.100	0.091	0.052
Cl	1.316	0.432	0.383	0.307	0.284	0.259	0.149
Copper	21.670	7.122	6.316	5.070	4.686	4.264	2.447
Crude Embrocate	28.533	9.377	8.316	6.676	6.170	5.615	3.222
Ethanol	18.476	6.072	6.308	4.323	4.151	3.635	2.086
Gold	8.780	2.886	2.559	2.054	1.899	1.728	0.992
Hydrogen	1.181	0.388	0.344	0.276	0.255	0.232	0.133
Iron	20.753	6.820	6.049	4.856	4.487	4.084	2.344
Sulfur	6.036	1.984	1.759	1.412	1.305	1.188	0.682
Magma	36.076	11.856	10.515	8.441	7.801	7.099	4.074
Methane	2.248	0.739	0.655	0.525	0.486	0.442	0.254
Molten Glass	9.358	3.075	2.727	2.189	2.023	1.841	1.057
Molten Leave	6.917	2.273	2.016	1.619	1.496	1.361	0.781
Naphtha	49.349	16.218	14.383	11.547	10.671	9.711	5.573
Atomic number 41	22.802	7.494	6.646	5.335	4.930	4.487	2.575
Oxygen	1.598	0.525	0.466	0.373	0.346	0.314	0.180
Crude	40.108	13.181	11.690	9.385	8.672	7.893	4.529
Phosphorus	7.066	2.322	2.059	1.653	1.528	1.390	0.798
Impure Water	23.097	7.591	6.732	5.404	4.994	4.545	2.608
Sword	40.168	13.201	11.708	9.399	8.686	7.904	4.536
Super Coolant	228.152	74.981	66.498	53.386	49.332	44.897	25.766
Tungsten	12.752	4.191	3.717	2.983	2.757	2.509	1.440
Visco-Colloidal gel	30.306	9.960	8.833	7.091	6.553	5.964	3.422
Water	16.769	5.511	4.887	3.923	3.626	3.300	1.894

Tips [ ]

• Even one Golden Refinery can generate adequate inflame to lam Steam Turbine, and is power-positive when making aluminum, niobium, iron, or steel smooth with a duplicant with low machinery attribute.
  • Yet, assuming that the output coolant would exist used to heat steam through Radiant Thawed Piping, this requires the use of coolant that can be heated to 125 degrees and in a higher place; either Urine or Polluted Water will be unfit, and the early pragmatical coolant is Crude.
    • In the Spaced Impossible (DLC), getting a coolant that can do this is eve more disobedient, referable the starting asteroid lacking any Oil Biome. The earliest possible coolant would have to obtained from melt Plastic, and using the resultant Naphtha.
      • In practice this may alone follow possible on the Sandstone starting asteroid as the Mucky starting asteroid does not deliver dreckos to ranch.
  • Otherwise, an Aquatuner will be needed to extract heat from the coolant; the power needful to run the Aquatuner would balance out whatsoever gains from having a Steam clean Turbine change over heating system to electricity.
• Due to its massive energy drain assigning a skilled operator to it and even placing a light-source close goes a mindful way in terms of efficiency.
• When coolant containing Germs is used, each time Metal Refinery finishes refining, it gains rise germs and must be disinfected, which is not precise practical.

Crude Oil Purification [ ]

Due to its unique mechanism, Silver Refinery could heat liquid to unlimited high temperature without breaking itself. This makes information technology a perfect tool for purification Petroleum into Fossil oi by heat. Piece the transformation from Crude Inunct into Petroleum would collapse pipes, Petroleum produced by bursting pipes could be used as heat-transfer-runny to bring heat to a sealed transmutation chamber where Rock oil is heated and converted into Petroleum.

The whole setup process works like the following:

• Produce 1200 kg Fossil oi away heating system Crude Oil through Metal Refinery operation. Your pipe will burst so hold bac fixing it until all Petroleum is out.
• Build a sealed Petroleum heat chamber the same elbow room you do with a magma heat source.
• Instead of heating from magma, circle radiant liquid pipe inside the bedchamber to transfer heat to the Earthy Oil contained in the chamber.
• Setup organ pipe mechanisation such that exclusive heat-transfer-fluid that went below 403°C gets out of the circle, where IT flows back to the Metal Refinery for reheating. Runny higher up 403°C shall keep circling inside the chamber.
• Pipe the coolant output of the Metal Refinery such that graceful terminated 405°C would snuff it to the transformation bedchamber, entering the circle mentioned above, liquid below 405°C goes right back into the Metal Refinery.
• Set back the 1200 kg Petroleum produced in the first step into the pipe.
• Start running Metal Refinery.

Notes:

• If your pipeline is not long enough, you power need a liquid artificial lake at either the coolant input operating theatre coolant output of the Metal Refinery to prevent blocking.
• The most efficient heating process is Nerve production, which heats 400 kg Petroleum by 132.91°C. With Crude aerify at 538.85°C, the safe temperature limit for Petroleum to date back into Metal Refinery is 538.85°C - 132.91°C = 405.94°C. This is also fair slimly higher than the 399.85°C needed to transform Crude Oil, signification all single pretermit of Petroleum that could not safely come back to Metal Refinery for heating system is hot sufficient to transform Crude Inunct, making the whole process a truly neat setup.
• Transformed Crude oil exits heat chamber at around 400°C, which contains a lot of heat that can either be composed by the Steam Turbine, or used to pre-heat energy the Raw Oil moving towards the warmth chamber.

History [ ]

• AT-242372: Introduced.

Oni Where Does the Metal Refinery Cooling Interact With the Floor?

Source: https://oxygennotincluded.fandom.com/wiki/Metal_Refinery