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===Production Progression Chart=== | |||
{| class="wikitable" style="text-align:center; background-color:#0b161c | |||
|+ Critical Photon-based production | |||
! Stage 1 | |||
! Stage 2 | |||
! Stage 3 | |||
|- | |||
| {{riq|Titanium Ore|120}} | |||
| {{riq|Smelter|2}} {{to}} {{riq|Titanium Ingot|60}} | |||
|rowspan=2| {{riq|Assembling Machine Mk.II|3}} {{to}} {{riq|Hydrogen Fuel Rod|60}} {{riq|Antimatter|300}} | |||
|- | |||
| {{riq|Critical Photon|300}} | |||
| {{riq|Miniature Particle Collider|5}} {{to}} {{riq|Hydrogen|300}} {{riq|Antimatter|300}} | |||
|} | |||
{| class="wikitable" style="text-align:center; background-color:#0b161c | |||
|+ Fire Ice-based production | |||
! Stage 1 | |||
! Stage 2 | |||
! Stage 3 | |||
|- | |||
| {{riq|Titanium Ore|120}} | |||
| {{riq|Smelter|2}} {{to}} {{riq|Titanium Ingot|60}} | |||
|rowspan=2| {{riq|Assembling Machine Mk.II|3}} {{to}} {{riq|Hydrogen Fuel Rod|60}} {{riq|Graphene|600}} | |||
|- | |||
| {{riq|Fire Ice|600}} | |||
| {{riq|Chemical Plant|10}} {{to}} {{riq|Hydrogen|300}} {{riq|Graphene|600}} | |||
|} | |||
{| class="wikitable" style="text-align:center; background-color:#0b161c | |||
|+ Crude Oil-based production | |||
! Stage 1 | |||
! Stage 2 | |||
! Stage 3 | |||
! Stage 4 | |||
|- | |||
| {{riq|Titanium Ore|120}} | |||
| {{riq|Smelter|2}} {{to}} {{riq|Titanium Ingot|60}} | |||
| {{ppc skip}} | |||
|rowspan=3| {{riq|Assembling Machine Mk.II|3}} {{to}} {{riq|Hydrogen Fuel Rod|60}} {{riq|Hydrogen|15}} {{riq|Energetic Graphite|210}} | |||
|- | |||
|rowspan=2| {{riq|Crude Oil|210}} | |||
|rowspan=2| {{riq|Oil Refinery|7}} {{to}} {{riq|Refined Oil|210}} {{riq|Hydrogen|105}} | |||
| {{riq|Oil Refinery|14}} {{to}} {{riq|Hydrogen|315}} {{riq|Energetic Graphite|210}} | |||
|- | |||
| {{ppc back}} {{riq|Hydrogen|315}} | |||
|} | |} | ||
Revision as of 10:32, 23 February 2021
Hydrogen Fuel Rod
End Product, Fuel
With a further development of cryo-technology, we can liquefy hydrogen to make fuel rod with higher energy. The higher the energy of the fuel rod, the more increase of the mecha fuel power.
| Fuel Type | Chemical | |
| Energy | 54.0 MJ | |
| Fuel Chamber Gen. | +200% | |
| Made In | Assembler | |
| Hand-Make | Replicator | |
| Stack Size | 30 |
Summary
With a further development of cryo-technology, we can liquefy hydrogen to make fuel rod with higher energy. The higher the energy of the fuel rod, the more increase of the mecha fuel power.
Production Chain
Production Progression Chart
Player Tips & Tricks
- The recipe requires 5 Hydrogen at 8 MJ each, while the finished product has 40 MJ. This means there is no gross energy gain when burning Hydrogen when burning in a Thermal Power Station but there will be a loss of 1 Titanium Ingot.
- However a stack of Hydrogen Fuel Rods stack better (30 * 40 MJ = 1.2 GJ) as compared to a stack of Hydrogen (20 * 8 MJ = 0.16 GJ).
- A full Storage Tank of Hydrogen has 80 GJ of energy (8 MJ * 10000 slots)
- A full Storage Mk.II of Hydrogen Fuel Rods has 72 GJ of energy (40 MJ * 60 slots * 30 stack size)
- Hydrogen Fuel Rods also have an added 100% Fuel Chamber Generation bonus from component Hydrogen.
- As a result, Hydrogen Fuel Rods should typically be used to fuel the mech as needed, and raw Hydrogen used for Thermal Power Station power generation.
- However a stack of Hydrogen Fuel Rods stack better (30 * 40 MJ = 1.2 GJ) as compared to a stack of Hydrogen (20 * 8 MJ = 0.16 GJ).