Download World-Class Data Center Realizes Goals of Investment

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DATA CENTER
www.brocade.com
World-Class Data Center Realizes
Goals of Investment Protection,
Energy Efficiency, and Scalability
In March of 2008, Brocade had a vision to build a worldclass campus, including a new data center to demonstrate
the Brocade One concepts of unmatched simplicity, nonstop networking, investment protection, and optimized
applications. In September of 2010, the vision was realized
and we officially dedicated the new campus and data
center.
The new Brocade® campus in San Jose, California, was built to
provide the business with flexibility needed to satisfy growth for our
employees and for R&D and solution labs. Design principles of both
the campus and the data centers were flexibility, scalability, energy
efficiency, and sustainability. And the results were nothing short of
extraordinary. Three buildings provide 562,000 square feet to house
Brocade’s 2,500 employees, labs, data center, café, fitness center,
and so on. An overarching goal was thoughtful investment—and
that guided our decisions with regards to our employees, partners,
customers, and vendors as well.
Prior to the move, we had three data centers and R&D labs in five
locations with a total of about 2000 racks. On the new campus,
labs were consolidated in one building. The highly efficient electrical
and mechanical design of Brocade data center and labs will save
over 10 million Kilowatt-hours of energy consumption annually over
the previous year. And over 4500 tons of carbon dioxide emissions
annually will be offset over the previous year. This paper describes
how we designed and built the data center and labs to achieve these
spectacular results.
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Introduction
Looking back at the planning phase, a number of goals were mandated by the executive staff:
• Energy efficiency and sustainability
• Consolidation of footprint, while maximizing real estate investment
• Investment protection, that is, use as much of the existing equipment as possible
• Create a baseline for future growth and enhancements
The following sections describe how we accomplished these goals—followed by some best
practices and lessons learned about planning and building or refreshing a corporate data
center.
Energy Efficiency and Sustainability
Both industry best practices and innovative design played a part in delivering on the “green”
promise in the new data center.
Hot Aisle/Cold Aisle
As is common in most organization, the IT equipment load is the number one consumer of
electricity at a building level. One of the best ways to handle the heat generated by the many
devices in the data center is by using a hot aisle/cold aisle equipment floor plan. Servers and
network equipment are typically configured in standard 19” (wide) racks and rack enclosures,
in turn, are arranged for accessibility for cabling and servicing. Increasingly, however, the floor
plan for data center equipment distribution must also accommodate air flow for equipment
cooling. This requires that individual units be mounted in a rack for consistent air flow
direction (all exhaust to the rear or all exhaust to the front) and that the rows of racks be
arranged to exhaust into a common space, called a hot aisle/cold aisle plan, as shown in
Figure 1.
COLD aisle
Figure 1.
Hot aisle/cold aisle plan
for consistent air flow.
Equipment row
HOT aisle
Equipment row
Air
flow
COLD aisle
Equipment row
HOT aisle
A hot aisle/cold aisle floor plan provides greater cooling efficiency by directing cold to hot
air flow for each equipment row into a common aisle. Each cold aisle feeds cool air for two
equipment rows while each hot aisle allows exhaust for two equipment rows, thus enabling
maximum benefit for the hot/cold circulation infrastructure. Even greater efficiency is
achieved by deploying equipment with variable-speed fans. Hot row containment provides
a better working environment for IT personnel and temperatures are more comfortable. In
Brocade data center and labs, we can control temperature to the level of a pod if we need
to (two rows of equipment back to back make up a pod). The Solutions Center lab also uses
both high end-doors and more economical curtain system heat containment methods.
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Variable Speed Fans
Variable speed fans increase or decrease their spin rate in response to changes in equipment
temperature. As shown in Figure 2, cold air flow into equipment racks with constant speed
fans favors the hardware mounted in the lower equipment slots and thus nearer to the cold
air feed. Equipment mounted in the upper slots is heated by their own power draw as well
as the heat exhaust from the lower tiers. Use of variable speed fans in equipment racks
enables each unit to selectively apply cooling as needed, with more even utilization of cooling
throughout the equipment rack.
Figure 2.
Variable speed fans in
equipment racks enable more
efficient distribution of cooling.
More
even
cooling
Equipment
at bottom
is cooler
Server rack with constant speed fans
Server rack with variable speed fans
Power Distribution Units
High-voltage power is fed into the data center and labs to Power Distribution Units (PDUs),
which physically sit inside these labs, minimizing the energy and line loss to the end-point.
The PDUs have shadow metering capabilities to monitor and measure energy consumption
with utility-grade precision. Green-labeled PDUs are backed up by UPS and emergency power,
while red-labeled PDUs are backed up by emergency power only. Inside the data center,
equipment is fed from both A and B power sources for redundancy, with A power having UPS
and emergency generator backup.
Figure 3.
PDUs minimize
energy and line loss
to the end-point.
In addition to known best practices in this area, Brocade worked with a trusted vendor to
design and build a custom In-Row Cooling (IRC) system. To quote the vendor, “This may well
be the best system on the market today that’s not on the market … but will be ….” This IRC
unit provides the ultimate solution in flexibility due to its unique custom design. It can fit
into any rack space in the data center because of its similar physical footprint to the rack.
Brocade’s custom IRC is 80 percent more energy efficient than the conventional Clean Room
Air Conditioning Unit (CRAC) and 70 percent more efficient than current alternative IRC units
on the market.
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The IRC unit provides added reliability by utilizing three high-efficiency fans directly driven
by three EMC motors. The motors themselves are the most efficient on the market,
consuming about 70 percent less energy than the nearest competitor. Each motor operates
at 33 percent, and if a fan or motor fails the unit automatically ramps up the remaining fans
to 66 Hz to provide the full cooling capacity of the unit.
Automated Controls with Energy Monitoring
Because vendor wattage and BTU specifications may assume maximum load conditions,
using data sheet specifications or equipment label declarations does not provide an accurate
basis for calculating equipment power draw or heat dissipation. An objective multi-point
monitoring system for measuring heat throughout the data center is really the only means to
observe and proactively respond to changes in the environment.
A number of monitoring options are available today. For example, some vendors are
incorporating temperature probes into their equipment design to provide continuous
reporting of heat levels via management software. Some solutions provide rack-mountable
systems that include both temperature and humidity probes and monitoring through a Web
interface. In addition, new monitoring software products can render a three-dimensional view
of temperature distribution across the entire data center, analogous to an infrared photo of a
heat source.
Starline Busway System
It’s interesting to note that Brocade was
an early adopter of the Starline Busway
System, an electrical power distribution
system for mission-critical facilities. It is
simple, versatile, fast and economical
solution for supplying power to electrical
loads and is unique because the busway
can be tapped instantly at any location,
without losing uptime—giving you the
ability to change or add to floor plans
quickly and easily. Although the Starline
Busway System has been on the
market for a number of years, it’s still
winning awards, most recently the Tech
50 award from the 2009 Pittsburgh
Technology Council in the Advanced
Manufacturing category.
Although monitoring systems add cost to data center design, they are invaluable diagnostic
tools for fine-tuning airflow and equipment placement to maximize cooling and keeping power
and cooling costs to a minimum. An example of a three-dimensional view of temperature in
the Brocade data center is shown in Figure 4.
Figure 4.
A 6 Sigma application generates
heat topologies at different
heights from the floor.
Cooling System
The number two consumer of electricity at the building level are the chiller and then the
pumps to circulate water for cooling to the HVAC units in the lab. Brocade selected the
highest-efficiency chillers at partial loads and cooling towers with variable frequency drives.
As a general rule, chillers never reach 100 percent load, the point at which their highefficiency features are triggered. However, the high-efficiency features of our chillers are
triggered at partial loads below 50 percent load, which helps conserve energy at Day One
loads
Our chilled water system utilizes a water side heat exchanger, which is passive and has
no electrical pumps and is capable of providing 2000 tons of free cooling without the use
of a compressor. This water-side heat exchanger provides free cooling when the outside
temperature permits. Despite what you may have heard, in Silicon Valley the sun doesn’t
shine all the time.
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Finally, we have a primary system only and no secondary pumping system. Before the 1980s,
primary-only systems were the norm. With the growth of high-tech labs and critical labs, a
primary/secondary system has been typically prevalent until very recently. Organizations were
reluctant to do away with primary/secondary systems, because they felt that it made them
vulnerable in the event of a fluctuation differential pressure that might exist in a primary
only system. But in Brocade’s case where through the design and selection of the correct
equipment, automation and controls, and its constant load, there is no concern or need to
utilize a primary/secondary system to regulate pressure in load. We simply don’t need it and
have avoided initial capital investment cost and inefficiencies.
Figure 5.
Main cooling
system substations.
Consolidation
Through the consolidation of three data centers into one we were able to consolidate our
space requirements by decreasing the physical footprint by 30 percent and decreasing data
center energy consumption by 37 percent.
Racks
One of the decisions that we made was to use taller racks—8’ tall instead of 6’—with standard
19” width. We were able to consolidate 2011 racks to the 1860 rack capacity in for all labs.
In 2011, it is projected that we will be occupying 1587 of these racks, with 300 targeted for
growth.
With these taller racks and greater rack count, a question that comes to mind is how to fit
them into the data center and labs. We used a flat floor design, which allows for more vertical
rack space, rather than a raised floor, which requires ramps and stairs for access. A flat
floor design was selected because it allowed 10 percent more rack counts in comparison to
conventional raised floor systems which require ramps and stairs.
Cabling
One of the most critical areas for consolidation is in fact the proliferation of cables in highdensity racks, with high-port-count devices. In both the data center and other labs, two
separate conveyance systems were deployed: structured and horizontal cabling systems
(Systimax) and ad hoc cabling in the data center (Systimax, Tyco) and ad hoc cabling in
the solutions and proof-of-concept labs (Corning, Splice, Tyco, and Systimax). This lab also
features a flexible two-tier cable conveyance design that provides both a structured cable tray
conveyance system for the backbone network and a high capacity open cable conveyance
system for ad-hoc cabling.
In the Proof-of-Concept (PoC) lab, Brocade products are physically connected to an optical
switching matrix that lets us rapidly build out and store network topologies for each customer.
This allows us to share equipment and minimize set up time.
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Investment Protection
The new data center is initially a Tier 1 (no N+1 power or cooling), but the infrastructure is
in place for a Tier 2 infrastructure (generator pads, UPS, additional chillers) on which N+1
systems can be placed when the business requirement exist The data center has installed
the latest in fire suppression technology. This includes a double-action, pre-action dry
pipe system that prevents water leaks and false alarms from interrupting business-critical
applications. Fire and smoke detection is monitored by very early smoke detection, which
senses the smallest amount of combustion or smoke particles and activates a dry green
agent fire suppression system that stops and prevents fire from spreading by removing the
oxygen in the space.
Campus Sustainability
To summarize, by meeting sustainability challenges head on:
• This campus uses 40 percent less water than a standard office or campus building. This
is achieved by the collection of rain and run-off water recycled, filtered, and reused for
irrigation. The selection of sustainable trees and landscaping features, and the selection of
no-water and low-flow water fixtures throughout the campus help us accomplish this.
• The campus utilizes a 550 KW photovoltaic (PV) system attached to our garage structure
that harnesses the suns energy to offset power consumption and the carbon footprint. The
power from the PV system is fed into Building 2. This system is capable of offsetting the
total amount of power consumed by our data center.
• By strategically implementing the best practices at a building and lab level one of the
lowest calculated Power Utilization Factors in Data Center design of 1.3 has been achieved.
The design has also allowed us to exceed California energy code requirements by 16%.
• Due to the selection of a sustainable site, water efficiency, energy efficiency, selection and
reuse of renewable materials, indoor air quality achievements, and innovation of design,
the campus is scheduled to receive accreditation from the U.S. Green Building Council for
Leadership and Energy and Environmental Design (LEED) certification of silver for core and
shell and gold for corporate Interiors.
Figure 6.
Power Usage Effectiveness (PUE):
a measure of data center energy
efficiency calculated by dividing the total
data center energy consumption by the
energy consumption of the IT computing
equipment.
About Brocade
Founded in 1995, Brocade is an industry leader in providing reliable, high-performance
network solutions that help the world’s leading organizations transition smoothly to a
virtualized world where applications and information reside anywhere.
Today, Brocade is extending its proven data center expertise across the entire network with
future-proofed solutions built for consolidation, network convergence, virtualization, and
cloud computing.
Headquartered in San Jose, California, the company has approximately 4000 employees
worldwide and serves a wide range of industries and customers in more than 160 countries.
With a complete family of Ethernet, storage, and converged networking solutions, Brocade
helps organizations achieve their most critical business objectives through:
• Unmatched simplicity to overcome today’s complexity
• Non-stop networking to maximize business uptime
• Optimized applications to increase business agility and gain a competitive advantage
• Investment protection to provide a smooth transition to new technologies while leveraging
existing infrastructure
Brocade combines a proven track record of expertise, innovation, and new technology
development with open standards leadership and strategic partnerships with the world’s
leading IT companies. This extensive partner ecosystem enables truly best-in-class business
solutions. To find out more about Brocade, visit www.brocade.com.
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