/ News & Press / Video / OXYGEN NOT INCLUDED - THE EASIEST TO BUILD - 1kg_s SOUR GAS BOILER

OXYGEN NOT INCLUDED - THE EASIEST TO BUILD - 1kg_s SOUR GAS BOILER

WEBVTT
Kind: captions
Language: en

00:00:05.690
hello welcome back to a very very quick
00:00:08.870 00:00:08.880 video today we have back with yet
00:00:11.780 00:00:11.790 another sour gas boiler build now before
00:00:15.200 00:00:15.210 I leave you groan this is the last one I
00:00:17.390 00:00:17.400 promise this is the smallest easiest
00:00:21.830 00:00:21.840 build I can make literally I can't get
00:00:24.290 00:00:24.300 much easier than this I've listened to
00:00:27.019 00:00:27.029 the feedback in the previous posts and
00:00:28.519 00:00:28.529 people were talking about for those of
00:00:30.349 00:00:30.359 you hadn't seen the previous two bills
00:00:31.669 00:00:31.679 that have done the sour gas tart and the
00:00:35.720 00:00:35.730 boom box I'll give you a few links of
00:00:37.970 00:00:37.980 those in the video description of some
00:00:39.170 00:00:39.180 cards on your screen now but the general
00:00:41.209 00:00:41.219 feedback was it's all well and good you
00:00:43.459 00:00:43.469 building something in debug but it's
00:00:45.650 00:00:45.660 gonna be hard to build in a normal game
00:00:46.850 00:00:46.860 so I've gone back to basics we've got a
00:00:50.240 00:00:50.250 much much easier system here with very
00:00:52.549 00:00:52.559 little automation very very easy piping
00:00:55.819 00:00:55.829 a little bit of gas piping and this
00:00:58.939 00:00:58.949 build is just beautiful it gives us
00:01:01.580 00:01:01.590 about one kilo a second output in terms
00:01:04.219 00:01:04.229 of natural gas and it consumes just over
00:01:07.640 00:01:07.650 1,100 kilojoules a cycle it does vary a
00:01:10.010 00:01:10.020 little bit but it's about between 1070
00:01:13.310 00:01:13.320 and 1100 kilojoules per cycle that's
00:01:16.010 00:01:16.020 basically two in a bit natural gas Jones
00:01:18.140 00:01:18.150 to run but it gives us enough natural
00:01:20.570 00:01:20.580 gas to run eleven natural gas Jones so
00:01:23.929 00:01:23.939 this is a little build it will get you
00:01:25.580 00:01:25.590 plenty of natural gas and yeah it works
00:01:29.420 00:01:29.430 like an absolute charm so it should be a
00:01:31.580 00:01:31.590 really simple simple explanation here
00:01:33.469 00:01:33.479 just like with the other builds we've
00:01:35.179 00:01:35.189 got an aqua tuna that is boiling oil now
00:01:37.910 00:01:37.920 our oil comes in from this little room
00:01:39.469 00:01:39.479 here and this is just some oil of like
00:01:41.749 00:01:41.759 99 degrees I'll just pause it for a
00:01:43.940 00:01:43.950 second the oil comes in through this
00:01:45.950 00:01:45.960 pump now this pump feeds into a
00:01:47.899 00:01:47.909 reservoir that's sat in our room and
00:01:49.550 00:01:49.560 this basically keeps you know a full
00:01:52.160 00:01:52.170 tank of oil on hand this reservoir is
00:01:55.370 00:01:55.380 connected to this liquid shutoff pipe
00:01:57.800 00:01:57.810 here liquid shutoff which is connected
00:02:00.920 00:02:00.930 to our oil feed now the liquid shutoff
00:02:03.050 00:02:03.060 will come into a gold radiator and into
00:02:06.770 00:02:06.780 a vent okay and this is triggered just
00:02:09.830 00:02:09.840 by a little bit of automation in the
00:02:11.180 00:02:11.190 room which is just a Hydra sensor with
00:02:13.510 00:02:13.520 is where our petroleum will normally sit
00:02:15.310 00:02:15.320 that's set to below 50 kilos and an
00:02:18.220 00:02:18.230 Atmos sensor and that's set to below 20
00:02:21.040 00:02:21.050 kilos and when both of these signals are
00:02:23.470 00:02:23.480 on it goes to a NAND gate on both of
00:02:25.660 00:02:25.670 those are active we get some more oil
00:02:27.010 00:02:27.020 dumped into the system and that's that's
00:02:28.960 00:02:28.970 the the supply of it it really couldn't
00:02:30.790 00:02:30.800 be easier
00:02:31.300 00:02:31.310 there's no automation on the pump it's
00:02:32.740 00:02:32.750 just fully powered and just fills up the
00:02:34.390 00:02:34.400 reservoirs and when it can and the
00:02:36.430 00:02:36.440 liquid shuts off here just dumps of some
00:02:38.020 00:02:38.030 oil in now one thing I'll just mention
00:02:39.640 00:02:39.650 I've mentioned the gold radiant pipes
00:02:41.230 00:02:41.240 here I've tried to make this as cheap a
00:02:44.050 00:02:44.060 build as possible in terms of the space
00:02:46.630 00:02:46.640 materials so one of the main feedbacks I
00:02:49.060 00:02:49.070 got was that there was too much
00:02:51.100 00:02:51.110 supercooled and being used in some of
00:02:52.840 00:02:52.850 the bigger builds or too much thermia so
00:02:55.090 00:02:55.100 what I've basically done this build
00:02:56.500 00:02:56.510 takes around 300 kilos of super coolant
00:02:59.980 00:02:59.990 that's allowing a little buffer in the
00:03:01.750 00:03:01.760 reservoir as well and 1,400 kilos of
00:03:05.260 00:03:05.270 Thurman and that's just for the aqua
00:03:07.300 00:03:07.310 tuner itself and four pieces of fermion
00:03:10.870 00:03:10.880 pipe up here the rest of this is gold
00:03:13.030 00:03:13.040 but where I want it to be Thurman it is
00:03:15.070 00:03:15.080 tharam so a couple of bits of pipe and
00:03:17.320 00:03:17.330 the Aqua tune and that you can't really
00:03:18.730 00:03:18.740 escape that if you want to do a little
00:03:20.530 00:03:20.540 build like this now just to explain
00:03:23.260 00:03:23.270 what's basically happening down here
00:03:24.400 00:03:24.410 it's the same aqua tuna loop that we
00:03:25.900 00:03:25.910 normally use so our super coolant is
00:03:28.030 00:03:28.040 going through the radiator this way so
00:03:29.650 00:03:29.660 this is our exit from our aqua tuner
00:03:31.180 00:03:31.190 here and that goes down this pipe and
00:03:33.220 00:03:33.230 this pipe goes into our bill that it
00:03:35.320 00:03:35.330 goes through a couple of floor tiles
00:03:36.760 00:03:36.770 here and then cycles into this little
00:03:39.250 00:03:39.260 chamber now this little chamber is where
00:03:41.290 00:03:41.300 our sour gas finds itself so when our
00:03:43.870 00:03:43.880 petroleum boils off when it hits about
00:03:45.640 00:03:45.650 540 degrees thus our gas bubbles up here
00:03:48.850 00:03:48.860 and then can find its way into this
00:03:51.010 00:03:51.020 chamber when it hits this fermion pipe
00:03:54.250 00:03:54.260 it pretty pretty quickly turns into
00:03:55.810 00:03:55.820 liquid methane and that liquid methane
00:03:58.390 00:03:58.400 is pumped straight away now I did do
00:04:01.510 00:04:01.520 some testing using a mini pump here
00:04:03.280 00:04:03.290 because and many pump is moving about a
00:04:04.600 00:04:04.610 kilo a second so I thought that might be
00:04:06.130 00:04:06.140 a bit cuter in the space but the mini
00:04:08.470 00:04:08.480 pump takes a little bit more power it's
00:04:09.880 00:04:09.890 not quite as efficient as a full sized
00:04:11.680 00:04:11.690 pump so although it looks a bit more
00:04:13.930 00:04:13.940 clumsy
00:04:14.440 00:04:14.450 it's better off using this pump it's a
00:04:16.000 00:04:16.010 little bit cheaper to run but then once
00:04:19.090 00:04:19.100 the super coolant has gone through the
00:04:20.229 00:04:20.239 room once it's done its cool and you can
00:04:21.909 00:04:21.919 see our super coolant down here is 100
00:04:23.770 00:04:23.780 minus 172 degrees it's gone up this loop
00:04:26.660 00:04:26.670 and again all these pipes here are
00:04:27.800 00:04:27.810 ceramic by the way I'm not using any
00:04:29.270 00:04:29.280 insula or anything in this build but it
00:04:31.490 00:04:31.500 goes up the ceramic pipe goes up through
00:04:32.960 00:04:32.970 our little condensing room and then hits
00:04:34.790 00:04:34.800 this bridge and comes back here and as
00:04:36.410 00:04:36.420 you can see it's minus 161 by the time
00:04:39.200 00:04:39.210 it gets to this point and then goes into
00:04:41.480 00:04:41.490 our reservoir now these temperatures do
00:04:43.070 00:04:43.080 fluctuate a little bit so occasionally
00:04:44.540 00:04:44.550 you do get a little bit of your liquid
00:04:47.210 00:04:47.220 methane boils off but then as soon as
00:04:49.190 00:04:49.200 the natural gas packet finds its way
00:04:50.660 00:04:50.670 back up its here it'll condense again
00:04:52.790 00:04:52.800 and you'll end up with just basically we
00:04:55.970 00:04:55.980 circulate the gas if you like so this
00:04:58.010 00:04:58.020 natural gas in a moment or disappear
00:05:00.460 00:05:00.470 providing it stays in the room and then
00:05:02.690 00:05:02.700 you saw a gas can just flow up there the
00:05:05.930 00:05:05.940 the automation in this room is dead easy
00:05:08.510 00:05:08.520 again the pump itself has no automation
00:05:11.240 00:05:11.250 it's just pumping all the time whenever
00:05:12.920 00:05:12.930 the Sun that could be thin here I want
00:05:14.600 00:05:14.610 it to pump I don't want any liquid
00:05:15.980 00:05:15.990 methane to sit on this plate I want it
00:05:17.900 00:05:17.910 to suck it up straight away there was a
00:05:19.820 00:05:19.830 door here and this door was just to
00:05:21.470 00:05:21.480 prevent too much sour gas coming into
00:05:23.180 00:05:23.190 this room this door is just on an Atmos
00:05:25.640 00:05:25.650 sensor with if it's above 10 kilos of
00:05:29.600 00:05:29.610 pressure at this point I want this door
00:05:31.460 00:05:31.470 to shut and that just lets the sour gas
00:05:33.350 00:05:33.360 pool up outside here this is on a filter
00:05:35.450 00:05:35.460 gate and the filter gate is just set for
00:05:37.190 00:05:37.200 3 seconds so it has to have that that
00:05:39.500 00:05:39.510 that signal for 3 seconds before the
00:05:42.350 00:05:42.360 automation toggles the door reason for
00:05:44.330 00:05:44.340 that is if you do get a little bit of
00:05:45.620 00:05:45.630 natural gas boils off here it can toggle
00:05:48.140 00:05:48.150 the sensor and you don't want that I'll
00:05:50.480 00:05:50.490 just basically mean your doors trying to
00:05:51.920 00:05:51.930 open and close constantly so a little
00:05:53.810 00:05:53.820 filter gate means it has to be a signal
00:05:55.460 00:05:55.470 for at least 3 seconds before that'll
00:05:56.990 00:05:57.000 close I've explained all this down here
00:06:00.020 00:06:00.030 the Aqua tuner itself so the coolant is
00:06:02.510 00:06:02.520 being fed directly in from the reservoir
00:06:04.870 00:06:04.880 the coolant comes down this pipe hits
00:06:07.520 00:06:07.530 this pipe sensor here there's a liquid
00:06:09.170 00:06:09.180 pipe thermo sensitive idea and then goes
00:06:12.590 00:06:12.600 into the Aqua tuner now if the Aqua tune
00:06:15.080 00:06:15.090 is toggled off just like we've done
00:06:16.250 00:06:16.260 before the pipe carries on upwards hits
00:06:18.830 00:06:18.840 this bridge and then goes into the
00:06:20.210 00:06:20.220 output pipe so if our aqua tuner is
00:06:21.890 00:06:21.900 dormant if we don't want it to be
00:06:23.120 00:06:23.130 running if our coolant is cold enough
00:06:24.830 00:06:24.840 then the liquid can just bypass it that
00:06:27.650 00:06:27.660 easy and again couldn't really be easier
00:06:30.080 00:06:30.090 it is a liquid thermal sensor set to
00:06:32.870 00:06:32.880 above minus 172 that says basically if
00:06:36.260 00:06:36.270 the liquid if the super coolant is
00:06:37.700 00:06:37.710 colder than that it can bypass
00:06:39.959 00:06:39.969 dead dead easy up here we have a little
00:06:43.289 00:06:43.299 steam turbine this is just if the room
00:06:44.819 00:06:44.829 gets too hot we have a hydrothermal
00:06:48.389 00:06:48.399 sensor here set to below 240 degrees
00:06:52.339 00:06:52.349 again it's on a filter gate and that's
00:06:55.499 00:06:55.509 set to five seconds so if the room gets
00:06:57.029 00:06:57.039 too toasty for a little while
00:06:58.589 00:06:58.599 the signal will come here this door will
00:07:01.919 00:07:01.929 close which connects these two chambers
00:07:03.779 00:07:03.789 and heats up a steam turbine that gives
00:07:06.359 00:07:06.369 us a bit more power every now and again
00:07:07.529 00:07:07.539 only normally happens every maybe every
00:07:09.689 00:07:09.699 cycle and happens briefly every other
00:07:11.639 00:07:11.649 cycle normally but gives us a little bit
00:07:13.739 00:07:13.749 of power and cools the room down a
00:07:15.149 00:07:15.159 little bit now our liquid methane when
00:07:18.809 00:07:18.819 we've picked up these little packets of
00:07:20.100 00:07:20.110 liquid methane that comes through a
00:07:21.749 00:07:21.759 ceramic pipe up here and you'll see
00:07:23.549 00:07:23.559 these packets all sort of vary in sizes
00:07:25.439 00:07:25.449 this one's 1.6 kilos
00:07:27.479 00:07:27.489 this one's 1.9 this one's 2.2 1.6 1.6
00:07:33.329 00:07:33.339 1.7 this just goes through the ceramic
00:07:35.489 00:07:35.499 pipe and then into a vent up here okay
00:07:37.889 00:07:37.899 that vent the liquid vent drops the
00:07:40.199 00:07:40.209 methane into here where it pulls up and
00:07:42.989 00:07:42.999 instantly boils and I've got a metal
00:07:44.309 00:07:44.319 tile here connected to the room okay the
00:07:47.309 00:07:47.319 events themselves are just pumping
00:07:48.929 00:07:48.939 constantly because this is producing
00:07:50.609 00:07:50.619 just over a kilo it's like 1.1 kilos or
00:07:53.790 00:07:53.800 something it's just over so the vents
00:07:56.669 00:07:56.679 themselves that the pumps themselves are
00:07:58.829 00:07:58.839 going constantly and these go through a
00:08:01.639 00:08:01.649 ceramic pipe ceramic insulated pipe
00:08:04.079 00:08:04.089 before hitting a wolframite radiant pipe
00:08:07.559 00:08:07.569 and that just takes our gas that is
00:08:09.689 00:08:09.699 coming in at minus 109 degrees and uses
00:08:13.229 00:08:13.239 some of that temperature in the gas it's
00:08:15.389 00:08:15.399 a pretty cool live room a little bit
00:08:17.279 00:08:17.289 it's pretty cool in the sour gas a
00:08:18.449 00:08:18.459 little bit before it gets up here so as
00:08:20.789 00:08:20.799 you can see it goes from minus 109 minus
00:08:24.809 00:08:24.819 60 36 109 159 and so on this was
00:08:30.689 00:08:30.699 basically because I didn't need to be
00:08:31.859 00:08:31.869 pumping gas over to here there was at
00:08:33.299 00:08:33.309 minus 160 degrees it was just wasted
00:08:35.490 00:08:35.500 temperatures so I've absorbed some of
00:08:37.469 00:08:37.479 the heat from the room and then that
00:08:38.999 00:08:39.009 goes into a storage room with a vent
00:08:40.679 00:08:40.689 like you've probably seen me done many
00:08:42.240 00:08:42.250 many times before just an over
00:08:44.069 00:08:44.079 pressurize went in here for storage now
00:08:46.829 00:08:46.839 as I say this is producing enough gas
00:08:48.960 00:08:48.970 from these two pumps to run eleven
00:08:50.910 00:08:50.920 natural gas Jones
00:08:52.519 00:08:52.529 and it needs two of those roughly to
00:08:54.980 00:08:54.990 power it well just over two which gives
00:08:57.410 00:08:57.420 you a surplus of another nine natural
00:09:00.439 00:09:00.449 gas Jen's just for power few selves and
00:09:03.290 00:09:03.300 as I say it's converting it a one-to-one
00:09:05.300 00:09:05.310 ratio so for every bit of crude oil that
00:09:07.220 00:09:07.230 we get although we do lose a little bit
00:09:09.230 00:09:09.240 for sulfur for every bit of petroleum
00:09:12.920 00:09:12.930 that's boiled in turn that into sour gas
00:09:15.259 00:09:15.269 from crude oil we get two-thirds of that
00:09:18.019 00:09:18.029 amount is natural gas so it's given us
00:09:20.329 00:09:20.339 quite a throughput as I say that's
00:09:22.879 00:09:22.889 basically the building it couldn't
00:09:24.110 00:09:24.120 really be any easier
00:09:24.949 00:09:24.959 it's powered by by one circuit down here
00:09:27.619 00:09:27.629 for the actual build itself and another
00:09:30.170 00:09:30.180 circuit over here which is just given us
00:09:32.239 00:09:32.249 a pump and a liquid pump down here and
00:09:35.299 00:09:35.309 one thing to point out as well guys this
00:09:37.040 00:09:37.050 is base figures just based off the build
00:09:39.710 00:09:39.720 itself obviously natural gas jens do
00:09:42.139 00:09:42.149 output water and carbon dioxide so i've
00:09:44.299 00:09:44.309 been collecting them down here and we've
00:09:46.369 00:09:46.379 got absolutely shed loads of both of
00:09:48.110 00:09:48.120 those things as well we've got loads of
00:09:49.460 00:09:49.470 water and loads of carbon dioxide and
00:09:51.530 00:09:51.540 carbon dioxide you can feed to
00:09:53.150 00:09:53.160 slicksters to get more oil and obviously
00:09:55.040 00:09:55.050 polluted waters a resource in itself as
00:09:56.990 00:09:57.000 well so that's the the basic premise of
00:09:59.119 00:09:59.129 the build now just some little aside for
00:10:01.040 00:10:01.050 those of you probably going to grumble
00:10:02.840 00:10:02.850 at fermium and the use of it in this
00:10:04.490 00:10:04.500 build i just thought i'd explained
00:10:05.689 00:10:05.699 because a lot of people seem to be
00:10:07.069 00:10:07.079 unaware of this fermium is is not really
00:10:10.460 00:10:10.470 a scarce material when you get to
00:10:12.439 00:10:12.449 late-game fermium is something that we
00:10:14.449 00:10:14.459 can actually manufacture the cost of a
00:10:16.460 00:10:16.470 bit of wolframite or tungsten so
00:10:19.189 00:10:19.199 basically thermians is made from niobium
00:10:22.059 00:10:22.069 niobium you don't actually need masses
00:10:24.860 00:10:24.870 off the first rocket you sent to space
00:10:26.660 00:10:26.670 you first steam rockets if you're lucky
00:10:28.400 00:10:28.410 you'll be able to actually get some
00:10:30.259 00:10:30.269 niobium depending on what your star
00:10:31.850 00:10:31.860 asteroids are now if you look at your
00:10:34.249 00:10:34.259 molecular Forge you can take niobium 5
00:10:37.790 00:10:37.800 kilos of niobium and 95 kilos of
00:10:40.610 00:10:40.620 tungsten and make Thurman okay and if I
00:10:43.819 00:10:43.829 press this button because I'm in debug
00:10:45.230 00:10:45.240 that will give me 200 kilos of sorry 100
00:10:48.769 00:10:48.779 kilos of fermion okay now if you then go
00:10:51.619 00:10:51.629 to your rock granulator or a metal
00:10:55.549 00:10:55.559 refinery depended on what output you
00:10:57.169 00:10:57.179 want if you go to a rock granulator you
00:10:59.480 00:10:59.490 will get 50 kilos of niobium and 50
00:11:03.259 00:11:03.269 kilos of sand if you grind up you
00:11:05.900 00:11:05.910 Thurman okay so you get 50 kilos of each
00:11:09.140 00:11:09.150 so that's ten crafts of this recipe if
00:11:12.710 00:11:12.720 you wanted to get yourself a load of
00:11:14.390 00:11:14.400 Thurman so from this one bit of niobium
00:11:16.760 00:11:16.770 that comes from this craft you can do
00:11:18.590 00:11:18.600 ten further crafts at the cost of a bit
00:11:20.600 00:11:20.610 of tungsten to get yourself an excess of
00:11:22.760 00:11:22.770 Thurman if you don't have any use for
00:11:24.530 00:11:24.540 sand and you've already got a refinery
00:11:26.120 00:11:26.130 in place you can actually convert it a
00:11:27.650 00:11:27.660 one-to-one ratio so 100 kilos of thermia
00:11:30.590 00:11:30.600 becomes 100 kilos of niobium all right
00:11:33.500 00:11:33.510 so that's how you get these late-game
00:11:35.030 00:11:35.040 materials super coolant I'm really not
00:11:37.370 00:11:37.380 even gonna discuss to get 300 kilos of
00:11:39.650 00:11:39.660 supercooled and it's an absolute piece
00:11:40.940 00:11:40.950 of piss that is to crafts of the recipe
00:11:43.120 00:11:43.130 molecular Forge fullerene gold and
00:11:46.900 00:11:46.910 petroleum will give you super coolant
00:11:49.040 00:11:49.050 and you get sorry 100 kilos per craft so
00:11:51.740 00:11:51.750 you need three three kilos of fullerene
00:11:54.280 00:11:54.290 is it 50 kilos per craft of gold I can't
00:11:57.530 00:11:57.540 remember 49.5 kilos of gold and 49.5
00:12:01.100 00:12:01.110 kilos of petroleum so it really is
00:12:03.170 00:12:03.180 nothing to get this much supercooled and
00:12:04.820 00:12:04.830 that's literally three three crafts of
00:12:06.680 00:12:06.690 the recipe but yeah I will as usual I'll
00:12:09.980 00:12:09.990 attach the same for you so you can have
00:12:11.240 00:12:11.250 a play with it yourself it seems to be a
00:12:12.590 00:12:12.600 lovely little mini build and I really
00:12:14.570 00:12:14.580 genuinely can't get much easier than
00:12:16.910 00:12:16.920 this it is as bare bones as I can make
00:12:20.480 00:12:20.490 it and I think I'm doing I've made it as
00:12:21.920 00:12:21.930 small as I can so this is probably the
00:12:23.870 00:12:23.880 smallest little build I'll play with for
00:12:25.310 00:12:25.320 a while now as I say it gives you quite
00:12:27.170 00:12:27.180 a bit of power for what it is
00:12:28.370 00:12:28.380 it used a little bit of oil dead easy to
00:12:30.590 00:12:30.600 build I think this would be an absolute
00:12:31.940 00:12:31.950 dawdle to build in a survival game as
00:12:33.440 00:12:33.450 well got plenty of access liquid lock on
00:12:35.810 00:12:35.820 the outside vacuumed all out and you can
00:12:37.730 00:12:37.740 just hop across the empty tube steady
00:12:39.140 00:12:39.150 easy with a couple of pieces of ladder
00:12:40.220 00:12:40.230 in the middle I think it'd be a piece of
00:12:42.110 00:12:42.120 piss well yeah hope hope that helps any
00:12:44.690 00:12:44.700 feedback any suggestions any tips and
00:12:46.580 00:12:46.590 the improvements let me know I'm always
00:12:49.130 00:12:49.140 interested to see how other people
00:12:50.180 00:12:50.190 approach the same problems as I do but
00:12:52.340 00:12:52.350 yeah guys many folks enjoy thank you bye
00:12:55.280 00:12:55.290 bye

Sales phone