Cooling Infrastructure

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Choosing the right cooling system saves money and protects your investment.

Cooling is the primary energy user in the data centre. But data centres must be kept cool. Balancing your budget with the need for more efficient cooling technology and the growing demand for power is a challenge, so choosing the best system for your data centre is important.

Fortunately, there are a number of cooling methods to choose from, whether you are building a new data centre or retrofitting one. And emerging green technologies offer exciting possibilities for advances in efficiency and cost savings.

Whether under the floor, above the floor, in the rack, or above the rack, the requirement of data centre cooling remains the same: Warm air must be moved away from equipment and cool air towards it. Understanding the factors that can hinder or even prevent this from happening is one of the first steps to improving data centre efficiency.

Air conditioners and air handlers
The familiar air conditioner (AC) unit, installed in the data centre and connected to outside condensing units, uses a fan system to move cool and hot air where they need to be. It’s much like the systems used in residential settings except that, in building cooling, the evaporator coil and blower are separate from the condenser coil, compressor, and condenser blower, while in electronics cooling they are packaged together in one unit.

Computer room air handlers (CRAH) work much the same way except that they use chilled water instead of refrigerant to remove heat from the air.

You might think that the drier the data centre, the better. But, in fact, the American Society of Heating, Refrigerating, and Air-Conditioning Engineers (ASHRAE) has a recommended range of humidity levels to help ensure server longevity.

Hot aisle/cold aisle
The idea of hot aisle/cold aisle seems simple enough, but it’s filled with potential problems. Ideally, cool air passes in front of parallel rows of racks, being drawn in toward equipment, and hot air comes out the back of the rack or overhead and is exhausted out of the room, producing constant air circulation.

Most major server manufacturers recommend that cabinet doors used in hot aisle/cold aisle installations have at least 63% open area for airflow. You can achieve this by either removing cabinet doors altogether or by buying cabinets that have mesh doors. Also, cabinets with side panels keep the air within each cabinet from mixing with hot air from an adjacent cabinet.

Because most servers and other network devices are equipped with internal fans, open or mesh doors may be the only ventilation you need as long as your data centre has enough air-conditioning to dissipate the heat load.

However, cool air can escape through various holes like cable cutouts, and some hot air doesn’t get exhausted and may enter the cold aisle, resulting in inefficient air handling and the presence of hot spots. These problems can be overcome through various analyses and equipment modifications.

Blanking panels, for example, can prevent cold air from passing through a cabinet too quickly or in the wrong direction and are a simple and economical way to direct cold air through equipment and prevent it from mixing with hot air. Brush strips, although not airtight, can cut down on air leakage while keeping dust and other contaminants out of cabinets.

You can increase ventilation by installing fans to actively circulate air through cabinets. The most common cabinet fans are top-mounted fan panels that pull air from the bottom of the cabinet or through the doors. Or you can use a fan or fan panel that mounts inside the cabinet or choose cabinet doors with built-in fans. For very tightly packed cabinets, an enclosure blower is a specialised high-speed fan that mounts in the bottom of the cabinet to pull cool air from a raised floor across the front of the cabinet where it can be used by equipment. An enclosure blower requires a solid front door with adequate space — usually at least four inches — between the front of your equipment and the cabinet door for air movement. If you’re housing components outside of a temperature-controlled area, you may want a cabinet with its own air conditioner.

Hot aisle/cold aisle containment
In hot aisle/cold aisle containment, barriers are used to enclose the aisles, ensuring cold air and hot air stay where they should be to maximize AC efficiency. Cold air stays near the server intake, and hot air exhaust is shuttled to in-row air conditioners, conditioned, and then returned to the cold aisle.

To keep cool air from mixing with warm air, row ends are closed off with an airflow barrier. This barrier can range from makeshift arrangements of plastic strips to doors made expressly
for this purpose.

Because cold aisle containment concentrates cool air at the front of equipment where it’s most needed, it’s an exceptionally effective cooling method. Cold aisle containment significantly reduces energy costs, lowering power bills as well as reducing data centres’ carbon footprints.

Liquid cooling
Liquid cooling systems are air conditioners that use a liquid to dissipate heat. That may be cold water or refrigerant, but the difference is that the liquid is closer to the heat source, resulting in even more efficient cooling.

Green cooling
The world of data centre cooling is evolving alongside “green” or sustainable technologies, as data centre managers contend with power, cooling, and space limitations.

Servers designed to handle higher temperatures are an example of so-called “adaptive” cooling. “Free” cooling, on the other hand, is almost like simply opening a data centre window, except the windows have filters and louvers for cleanliness and air control. In the right environment, methods such as these can save tremendous amounts of money and energy.

Geothermal cooling is an example of a more involved green system. In a traditional chilled water system, a majority of the water can be lost to evaporation. With geothermal cooling, evaporation can be cut to zero.

Power demands generally vary throughout the day, and systems with variable frequency drives can adjust the power as needed.

These and other evolving technologies may dramatically change the way data centres are cooled in the future.