Incandescent lighting was the standard for 100 years. This technology is so inefficient that scientists spent decades searching for an alternative, and since the 1980s most engineers assumed that Light Emitting Diodes would be the end game. However, LED technology was not ready for commercialization because bulbs could not meet market requirements for color and cost. An entire industry, Compact Flu- orescent lighting, sprang up to transition from legacy to LED. Patents were filed, factories built, and distribution channels created, but all of this was temporary. When was the last time anyone bought a CFL bulb?
Immersing electronics in air is the legacy technology for data center cooling. Like incandescent bulbs, this is extraordinarily inefficient because air does not conduct heat. Massive fan power is required to overcome the natural inclination of air to keep heat moving from where it is generated to where it needs to be rejected. In addition, air conditioning, either direct expansion or evaporative cooling, usually is required to promote heat transfer. As a result, half the energy consumed by most data centers is wasted cooling the electronics.
Two transition technologies sprung up to partially address air-cooling deficiencies, Cold Plates and In- Row Cooling.
Cold Plates, originally developed to cool high-power processors in computer gaming machines, are being modified for data center applications. Standard heat spreaders mounted on processors are replaced with heat exchangers that transfer energy from the processor to a fluid, usually water, which is pumped to a second exchanger that rejects the heat to air. Cold Plates are often referred to as “direct contact” systems, but there is no direct contact; only the hottest electronic components are covered by Cold Plates and there is a thermal barrier between the processor and transfer fluid. Furthermore, only about half the heat generated in a server is removed by the fluid; the rest is blown into the room by fans.
In-Row Cooling technology makes the room smaller. In legacy data centers a huge volume of air is cooled to remove heat generated in racks that occupy only about half of the floor space. In-Row Cooling, essentially mini-HVAC systems comprising fans and water-to-air heat exchangers, are installed in the racks to reduce the volume of air that must be cooled. This technology removes heat but is expensive and introduces water to the data center.
Total Immersion, where all heat generating components are immersed in a heat-conductive but electri- cally non-conductive medium, is the end game for cooling electronics, but most approaches are not ready for prime time. There are two forms of Total Immersion cooling, Two-Phase and Single-Phase.
Two-Phase systems are Tank-Based. Electronic components are submerged in a refrigerant bath. Boiling occurs on the surface of heat generating components and the refrigerant vapor passively rises to the top of the enclosure, where it condenses on water-cooled coils and falls back into the tank. This technology has major drawbacks which include:
Rack-Based Single-Phase Total Immersion is the ultimate solution for cooling data centers. This technol- ogy, perfected by Liquid Cooled Solutions, overcomes negative perceptions the market may have had relating to immersion cooling.
In data center applications Rack-Based Single-Phase Immersion hardware is:
· Neat and easy to maintain -