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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
| Recipe | Building | Replicator? | Technology |
|---|---|---|---|
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✔ |
Production Progression Chart
| Stage 1 | Stage 2 | Stage 3 |
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| Stage 1 | Stage 2 | Stage 3 |
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| Stage 1 | Stage 2 | Stage 3 | Stage 4 |
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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).