Difference between revisions of "Heatsink"
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|{{SB Infobox Device IO | |{{SB Infobox Device IO | ||
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|heatTransfer=750 per second | |heatTransfer=750 per second | ||
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|{{SB Infobox Device IO | |{{SB Infobox Device IO | ||
| | |heatDissipation=50 per second | ||
|heatCapacity=15,000 | |heatCapacity=15,000 | ||
|heatTransfer=750 per second | |heatTransfer=750 per second | ||
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|{{SB Infobox Device IO | |{{SB Infobox Device IO | ||
| | |heatDissipation=50 per second | ||
|heatCapacity=15,000 | |heatCapacity=15,000 | ||
|heatTransfer=750 per second | |heatTransfer=750 per second |
Revision as of 09:50, 30 March 2022
A heatsink is an integral part to most high-performance power plants, and is used to rapidly store or transfer heat away from generators.
Types
Heatsink, Cube
Size 96×96×96 cm
Mass 5,074.5 kg
Volume 510.0 kv
Corrosion resistance 440
Primary material Bastium
Input / Output
Heat capacity 15,000
Heat transfer 750 per second
Heat dissipation 50 per second
Modular interfaces 6
Composition
Heatsink, Plate
Size 192×192×24 cm
Mass 5,074.5 kg
Volume 510.0 kv
Corrosion resistance 440
Primary material Bastium
Input / Output
Heat capacity 15,000
Heat transfer 750 per second
Heat dissipation 50 per second
Modular interfaces 6
Composition
Usage
Heatsinks facilitate the interaction between devices that produce heat (such as generators, fuel chambers, and mounted weapons) and the devices that can dissipate heat (such as radiators). Heatsinks can be used to effectively bypass the transfer limitation for heat that exists between devices and radiators, as their thermal transfer limitation is significantly higher. Despite their significant visual differences, each heatsink style has the same effective mass and thermal properties.