Feature
Data Center Design and Cooling for Sensitive Electronics
Marc Caiola, Global Category Director - IT/DATACOM
Pentair/Schroff
Processing power and the speed at which crucial data center infrastructure equipment runs is steadily increasing to keep up with
user application demands. Through technology advances, the size
of these electronics is shrinking, resulting in greater board population density and higher power consumption. This yields increased
heat generation throughout the data center where equipment is
housed and operated. All equipment must be kept below a specified temperature range, high heat levels can damage networking
equipment and potentially eliminate a company's ability to effectively process, communicate and store information. Since nearly all
power consumed by equipment processors is converted to heat,
data center equipment must be effectively cooled to maintain
maximum availability and operational efficiency. Implementing the
proper cooling solution will not only protect data centers from
costly damage, but also ensure continuous access to company
data and communications in an economically and environmentally
responsible way.
Cooling solutions have become more sophisticated, providing new methods for improving cooling while enhancing overall
efficiency to adapt to changing networking equipment and data
center designs. Data center managers can select and implement
the ideal solution that adequately addresses individual cooling
requirements by understanding the evolution of modern cooling
solutions, along with their advantages and disadvantages.
Cubic Feet per Minute (CFM)
Another way to increase the amount of heat dissipated or
removed from network equipment is by increasing the airflow, expressed in CFM. An increase of CFM, the amount of airflow across
a given area in a given time, results in increased heat removal.
CFM can be achieved through the use of fans. The larger the fan,
the more CFM it provides. An increase in RPM (the speed at which
the fan circulates) as well as the size or quantity of fan blades
results in a higher CFM, but as these factors increase, so do several
others that can be detrimental to the data center equipment. For
example, acoustic noise is one consequence of high levels of CFM.
Additionally, at very high CFM, physical forces also come into play
that can cause damage to electrical equipment. Plus, the higher
the CFM, the higher the upfront capital costs, as well as ongoing
operational expenses.
Calculating Heat Dissipation Requirements
When it comes to cooling a data center, one equation is key:
Watts = 0.316 x CFM x ΔT. Whereas, Cold intake air and airflow
(CFM) are both required to cool network equipment. These two
factors work directly to dissipate the heat that network equipment
produces. While increasing either factor will increase the amount of
heat that is dissipated, there are limits. Air that is too cold results in
thermal expansion and condensation issues. Airflow that is too high
results in acoustic and physical limitations. A cooling system that
relies on too much of only one of these factors usually results in
higher capital and operating costs. Finding an ideal balance between
cold air and airflow allows optimal heat dissipation, protecting network equipment from the consequences of overheating.
Measured in degrees Fahrenheit, ΔT (Delta T) refers to the difference between equipment intake air and exhaust air. A greater
temperature differential signifies more heat being removed. While
it is difficult to constantly deliver the coldest air to all equipment,
in particular equipment installed in upper rack units, ideal configurations maintain a range between 10°F and 30°F ΔT.
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The data center must provide enough CFM to the equipment to
prevent overheating. CFM in = CFM out
Diverse Cabinet Level Cooling Configurations
Cabinet configurations are available in a variety of options, ranging from simple and inexpensive to costly and complex. The goal of
each configuration is the same: help deliver the necessary amount
of cool air to each server in the most efficient means possible.
Hot Aisle/Cold Aisle
Hot aisle/cold aisle cooling systems are designed to separate
hot exhaust from cold intake air. Cabinets located on both sides
of the cold aisle draw cold air from perforated floor tiles and
through their front intakes. Hot exhaust exits through cabinet
rears and is directed to Computer Room Air Conditioning (CRAC)/
Computer Room Air Handler (CRAH) units, which remove the heat
and redistribute air to the cold aisles.
Playing a crucial role in airflow management, hot aisle/cold
aisle configurations provide numerous benefits. By separating hot
and cold air, the energy required to maintain the optimal data
center temperature is minimized, allowing facilities to significantly
reduce their utility costs. However, it is important for managers
to understand that hot aisle/cold aisle designs are typically only
able to accommodate heat dissipations between 3 to 5 kW. Once
rack densities reach 5 kW and above, the system can no longer
compensate for the increased heat loads. According to multiple
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Table of Contents for the Digital Edition of Electronics Protection - Fall 2015