Data centers are among the most complex building types, requiring a significant amount of coordination among Building Team members, often with a compressed schedule and in tight spaces. Perhaps no other project type stands to benefit more from coordination using building information modeling and virtual design and construction than data centers.
“Everyone speaks to the benefits of BIM for coordination and clash detection on projects, but when you talk about all of the lines of conduit and other elements that you’re running through what are ultimately very tight spaces, it’s a steroidal environment when you’re talking about a data center,” says Bryant Farland, Senior Vice President and Leader of Skanska’s Mission Critical Center of Excellence. “Coordination becomes just that much more important, therefore, BIM becomes that much more useful.”
Building Design+Construction reached out to several AEC professionals who specialize in data centers to identify the areas of planning, design, and construction where they’re getting the most value out of BIM/VDC coordination. They pinpointed the following:
1. Planning the space
Data centers have huge mechanical and electrical capacities for their footprint—as many as 30 times the typical office building. Furthermore, the equipment is typically concentrated outside the server halls to reduce risk to the IT equipment. Together, these factors create incredibly dense equipment spaces and major duct, pipe, and conduit distribution paths, says Tom Boysen, Senior Project Manager with Sellen Construction (www.sellen.com).
“BIM helps data center designers confirm that the equipment and distribution can all fit, verify maintenance and service clearances, and analyze pressure drop and voltage drop with the actual routing,” says Boysen, who leads Sellen’s data center work. “Underground electrical feeders can be so dense that they could overheat and melt down if not designed properly. BIM’s precise routing allows electrical designers to model the heat dissipation and adjust the electrical duct bank configuration accordingly.”
2. Coordinating prefabrication
Data center clients, whether wholesale operators, tech firms, or financial institutions, are pushing the pace of new construction and retrofit projects. Fast track is passé. Uber fast track is the new standard as clients look to get their facilities online sooner.
To help speed construction, AEC firms are prefabricating many of the building systems and components, from the enclosure to the mechanical and electrical systems. BIM/VDC is vital for designing and testing prefabrication concepts with respect to material handling, path of travel, and installation sequence.
“We’re constantly pushing the amount and types of items we fabricate at our facilities,” says Jason Rahn, Group Vice President with The Hill Group (www.hillgrp.com). “This allows us to minimize the amount of fit-up and welding in a field environment, and it allows us to maintain excellent quality assurance due to the majority of our work being built in a controlled, shop atmosphere.”
Rahn points to a recently completed data center that required 450 welds for the piping systems, of which only 20 needed to be performed in the field. “The reduction in field welding required us to have only one welding machine on site,” he says. “It also decreased the field installation time from about 20 working days to just five.”
One prefabrication tip from Rahn: Make sure to include hangers in the BIM model. “It allows us to fabricate all piping supports and hangers en masse, deliver to the site early, and have installation completed prior to piping and ductwork material deliveries.”
3. Managing project phasing
Data center projects are typically phased to avoid building out expensive capacity that is not needed on day one. Often, the initial capacity target shifts during design and construction due to leasing activity and the difficulty of projecting the need for computer power, says Boysen.
“By adding a phasing element to the BIM model, the team can analyze the cost, schedule, and energy consumption at different phase steps,” says Boysen. “BIM supports phasing by quickly allowing the team to modify the design documents, adding or subtracting modules of power and cooling. Then, after the day-one construction is complete, BIM supports future development with an accurate record of the installed condition, allowing the team to plan future deployments with confidence.”
4. Integrating raised-floor layouts
Raised access floors can be especially tricky, says Rahn, because most floor installers do not model their installations—adjustments for structural bridging and support are typically made in the field. Creating a BIM model of the flooring allows the installer to understand where the MEP systems are located in relationship to the pedestal support systems.
“By coordinating and integrating this into the modeling process, flooring installers can see where they need to modify their support framing early in the process and fabricate the necessary bridging and support components to span across the MEP systems where necessary,” says Rahn. “This eliminates the time and effort it would take to do this in the field once the MEP systems are installed, thus decreasing the field installation time.”
5. Keeping the routing free of conflicts
Transmitting the capacity out of the densely packed equipment requires multiple layers of stacked conduit, duct, and piping. Using the model, the detailers can pick up where the designers left off, adding intelligence to the individual elements. “Tight project schedules don’t allow for field routing to solve conflicts, so the routing must be solved during the detailing stage to allow for 99.99% conflict-free installation,” says Boysen.
6. Enabling commissioning and O&M tasks
Data centers require a robust commissioning process to ensure performance and reliability. Commissioning information tags for each piece of equipment and feeder can be added to the BIM model to keep a live database of commissioning process status.
“As with any new facility construction, the information that is so valuable to the operational staff—namely submittals, O&M manuals, as-built plans, balancing reports, and commissioning reports—is sometimes never transmitted to them, and then often lost over the years as the personnel turn over,” says Boysen.
When this information is inserted into the BIM database, the information can be retained and viewed for each piece of equipment, rather than in separate volumes. “Whether they are facing a problem or trying to improve energy efficiency, data center operators would benefit from a comprehensive set of information,” he says.
7. Analyzing air flow
By incorporating computational fluid dynamic (CFD) simulations into the BIM model, engineers can evaluate and fine tune server layouts based on the thermal modeling. “By incorporating that process into the Revit model, we’re able to visualize how the air will flow inside the data center and see the temperature variation based on the height and how the air is moving,” says Luis Cetrangolo, AIA, Associate at Integrated Design Group (www.idgroupae.com). “It’s especially helpful in being able to see how the servers in a computer room receive cold air and how hot air is removed.”
Cetrangolo says the CFD modeling is used more as a verification of engineering calculations than as a design tool. “It’s really a fine-tuning process.”
We want your ideas! This topic will be an ongoing series on BDCnetwork.com. If you have ideas for how BIM/VDC coordination benefits data center projects, please send them to dbarista@sgcmail.com.
Related Stories
| Aug 11, 2010
ZweigWhite names its fastest-growing architecture, engineering, and environmental firms
Management consulting and research firm ZweigWhite has identified the 200 fastest-growing architecture, engineering, and environmental consulting firms in the U.S. and Canada for its annual ranking, The Zweig Letter Hot Firm List. This annual list features the design and environmental firms that have outperformed the economy and competitors to become industry leaders.
| Aug 11, 2010
SSOE, Fluor among nation's largest industrial building design firms
A ranking of the Top 75 Industrial Design Firms based on Building Design+Construction's 2009 Giants 300 survey. For more Giants 300 rankings, visit http://www.BDCnetwork.com/Giants
| Aug 11, 2010
Guggenheim to host live online discussion of Frank Lloyd Wright exhibition
The Solomon R. Guggenheim Museum launches the Guggenheim Forum, a new series of moderated online discussions among experts from a variety of fields that will occur in conjunction with major museum exhibitions.
| Aug 11, 2010
Best AEC Firms of 2011/12
Later this year, we will launch Best AEC Firms 2012. We’re looking for firms that create truly positive workplaces for their AEC professionals and support staff. Keep an eye on this page for entry information. +
| Aug 11, 2010
Report: Building codes and regulations impede progress toward uber-green buildings
The enthusiasm for super green Living Buildings continues unabated, but a key stumbling block to the growth of this highest level of green building performance is an existing set of codes and regulations. A new report by the Cascadia Region Green Building Council entitled "Code, Regulatory and Systemic Barriers Affecting Living Building Projects" presents a case for fundamental reassessment of building codes.
| Aug 11, 2010
Call for entries: Building enclosure design awards
The Boston Society of Architects and the Boston chapter of the Building Enclosure Council (BEC-Boston) have announced a High Performance Building award that will assess building enclosure innovation through the demonstrated design, construction, and operation of the building enclosure.
| Aug 11, 2010
Portland Cement Association offers blast resistant design guide for reinforced concrete structures
Developed for designers and engineers, "Blast Resistant Design Guide for Reinforced Concrete Structures" provides a practical treatment of the design of cast-in-place reinforced concrete structures to resist the effects of blast loads. It explains the principles of blast-resistant design, and how to determine the kind and degree of resistance a structure needs as well as how to specify the required materials and details.