Industrial Turbine: Difference between revisions
Linkhyrule5 (talk | contribs) (Drastically simplified and explained the flow rate equation. It's much simpler than it looks.) |
Linkhyrule5 (talk | contribs) mNo edit summary |
||
Line 61: | Line 61: | ||
MAX_RATE = min(TURBINE_DISPERSER_COUNT * GENERAL_DISPERSER_GAS_FLOW * structure.lowerVolume, TURBINE_VENT_COUNT * GENERAL_VENT_GAS_FLOW) | MAX_RATE = min(TURBINE_DISPERSER_COUNT * GENERAL_DISPERSER_GAS_FLOW * structure.lowerVolume, TURBINE_VENT_COUNT * GENERAL_VENT_GAS_FLOW) | ||
FLOW = min(1, TURBINE_STORED_AMOUNT / MAX_RATE) * (TURBINE_STORED_AMOUNT/TURBINE_MAX_STORED_AMOUNT) | FLOW = min(1, TURBINE_STORED_AMOUNT / MAX_RATE) * (TURBINE_STORED_AMOUNT/TURBINE_MAX_STORED_AMOUNT) * MAX_RATE | ||
==Miscellaneous Notes== | ==Miscellaneous Notes== |
Revision as of 19:31, 10 December 2023
New in v9 is the Turbine Multiblock. This massive structure is used to produce power from the reactor that was introduced with v8.
Contents
Video Tutorials
https://www.youtube.com/watch?v=9EgZTwCnWwA&t - EsquilãoBR Tutorial PT-BR
https://www.youtube.com/watch?v=vrwz3j--Vcs - Tutorial Made by MathewCell
https://www.youtube.com/watch?v=kHJSEUjCsyA - Tutorial Made by AidancBrady
Components
- Turbine Casing
- Turbine Vent
- Pressure Disperser
- Turbine Blades
- Turbine Rotor
- Rotational Complex
- Electromagnetic Coil
- Turbine Valve
- Structural Glass (Optional)
Construction Notes
- Orientation can only be vertical (Unlike BR's turbine)
- Length and Width (x,z) must be equal.
- Maximum shaft height = min(2xLENGTH-5,14) [so blades don't touch sides]
- Maximum total height = min(2xLENGTH-1,18)
- Tank volume = LENGTH^2xROTOR_HEIGHT
- Flow rate is determined by tank volume times dispersers (exact formula inside notes) or by vents - whichever is less. Each vent adds 32,000mB/t of flow rate, and each disperser can disperse 1,280mB/t of flow per block of interior volume.
- Energy production = FLOWxROTOR_HEIGHTx50RF/7
- Because a taller rotor leaves less room for vents, sometimes heightening the rotor could reduce flow and, therefore, energy.
- 1 coil will support 4 blades. You'll never need more than 7 coils.
- Interior may ONLY be dispersers, coils, shaft, blades, rotational complex, or air.
- Multiblock will sparkle red on final block placement, otherwise check your assembly.
- Minimal turbine size is 5x5 base with 5 blocks high.
- Maximum turbine size is 17x17 base with 18 blocks high.
Construction steps
- Build the base out of turbine casings and optional structural glass. (must be square) [the perimeter must be casings not glass]
- Place rotor shafts in the center, from the base to desired height.
- Add turbine blades to the rotor. (two for each rotor shaft)
- Place a rotational complex on top of the rotor.
- Completely fill the interior layer around the rotational complex with pressure dispersers.
- Place electromagnetic coils above the dispersers. They must touch the rotational complex and each other.
- Build the frame (the perimeters of the walls) out of turbine casings. (you may have more empty layers above the coils to make room for more vents)
- Fill the walls, up to the height of the rotor, with turbine casings and/or structural glass and at least 2 turbine valves.
- Fill the remaining walls and ceiling with turbine casings and/or turbine vents.
Flow Rate
- The "flow rate" is really an efficiency ratio: it measures how much of your turbine's maximum output you're actually getting. It can never be larger than 1.
- The actual maximum rate of steam flow (labeled MAX_RATE below) is limited by both the number of dispersers and the number of vents. Each vent can pass 32,000 mB/t; each disperser can disperse 1,280 mB/t *per block of interior volume*.
- "Interior volume" -- labeled `structure.lowerVolume` below -- means the inside volume of the rotor chamber. So if your base is 11x11 and you have 4 blocks of rotor shaft, then your interior volume is 9x9x4=324 blocks, and every disperser disperses 414,720 mB/t.
- The flow rate is the product of two numbers:
- The fill ratio of the turbine: (volume of steam)/(maximum volume of steam)
- The current rate of steam flow, as a fraction of MAX_RATE. Ideally this would just be 1, but you can't move more steam than is actually in your turbine -- so if (volume of steam) < MAX_RATE, you only get (volume of steam)/MAX_RATE.
- In addition, the actual energy gained per tick is capped by the energy storage of the turbine.
- As long as you have room to put the energy, the equation is just:
GENERAL_DISPERSER_GAS_FLOW = 1280 GENERAL_VENT_GAS_FLOW = 32000 MAX_RATE = min(TURBINE_DISPERSER_COUNT * GENERAL_DISPERSER_GAS_FLOW * structure.lowerVolume, TURBINE_VENT_COUNT * GENERAL_VENT_GAS_FLOW) FLOW = min(1, TURBINE_STORED_AMOUNT / MAX_RATE) * (TURBINE_STORED_AMOUNT/TURBINE_MAX_STORED_AMOUNT) * MAX_RATE
Miscellaneous Notes
- Compatible with oredict steam from other mods such as TE/TF/RC/MFR/Big Reactors.
- The marking of "Limiting" on the vents stat simply means that it is not "optimal ratio". You can have fewer down to your desired steam flow rate.
- Turbine shuts down if internal battery fills with energy. It will restart automatically though you may also vent excess steam to prevent it from shutting down.
- A 5x5x8 turbine design will produce the exact same RF/t as the highest tiered turbine from Big Reactors with the same amount of steam.
Images
|
Cookies help us deliver our services. By using our services, you agree to our use of cookies.