saving energy resources

• significantly reduced carbon foot print by
• 90% less energy costs for cooling and 25-30 % less electrical costs overall (Datacenter)
• multiple usage of energies due to direct usage of high temperature cooling water for industrial or commercial processes

saving natural resources

• saving of rare earth elements as a result of longer lifecycle
• almost no physical stress - hardware can be re-used in further applications

improved performance of hardware:

• the heat energy of capacity components (like CPU, GPU, voltage converter, resistors, …) will be absorbed by the technical fluid and transferred into evaporation process
• stable temperature limit of entire hardware at boiling point (+/- 2 - 5K) of technical fluid
• almost no temperature gap between capacity component and technical fluid as cooling medium (air cooled equipment temp. gap ~30 – 50K)

improved reliability and extended lifecycle of equipment

• due to no rotating parts, reduced physical stress by fast temperature changes and less environmental contamination of the submerged equipment, a longer lifecycle is expected.

infrastructure and planning

• 8 - 12 weeks to go live at 10 - 25% lower CAPEX
• up to 4-5 higher hardware density per RU and IT densities up to of 6kW/RU are easy to handle
• 75% less footprint of the cooling system and 50% less facility costs & expenses
• integration into existing 19'' Datacenter infrastructures

operation and maintenance

• 90% less energy costs for cooling and 25-30 % less electrical costs overall Datacenter operations 
• 60% less maintenance costs (no chiller, no CRAC units, reduced fire extinguishing system, ...)