wind engineers have unveiled the world’s largest portable hurricane wind and rain simulator. Mounted on a trailer, the simulator is composed of eight 5’ industrial fans powered by four marine diesel engines that together produce 2,800 horsepower. To cool the engines, the system taps water from a 5,000-gallon tank aboard a truck that doubles as the simulator’s tow vehicle.
UF civil and coastal engineers plan to use the simulator to blast vacant homes with winds of up to 130mph, Category 3 on the Saffir-Simpson Hurricane Scale, and high-pressure water jets that mimic wind-driven torrential rain.
The goal is to learn more about exactly how hurricanes damage homes, and how to modify them to best prevent that damage.
‘We want to conduct experiments to evaluate real homes in communities that are impacted by hurricanes,’ said Forrest Masters, an assistant professor of civil and coastal engineering and the leader of the project. ‘This simulator also gives us the ability to test home retrofits and new building products aimed at preventing hurricane damage.’
The simulator, which cost about $500,000 in parts and labour, was designed and constructed entirely by Masters, lab manager Jimmy Jesteadt and a team of undergraduate students.
University of Florida wind engineering researcher Forrest Masters stands on a newly completed, fully portable hurricane wind simulator
Unlike previous, smaller simulators, the new simulator uses an innovative hydraulic system, rather than chains or mechanical drive trains, to transfer power from the engines to the fans. Designed by Linde Hydraulics Corporation and Cunningham Fluid Power Inc, the engines spin pumps, which then drive fluid through motors housed in the fans. The result is lighter, less bulky and safer than traditional drive systems, Masters said.
At full power, the fans turn at about 1,800 revolutions per minute, producing wind speeds of about 100mph. A custom-built duct reduces the space available for the air to flow through, ratcheting up the wind speeds to a potential 130mph. Steering vanes allow the engineers to direct the air wherever they want it to blow.
Implanted in the vanes, the water jets can simulate the most extreme rainfall of up to 35 inches per hour, although eight inches per hour is more typical, Masters said.
The simulator is the latest addition to a growing arsenal of hurricane research equipment designed and assembled by UF wind engineering researchers trying to learn more about ground-level hurricane winds and how they affect structures. In a related project, the researchers built several portable hurricane wind monitoring towers that were deployed in the path of land-falling hurricanes in recent years.
‘When this program first started, we brought the lab to the hurricane,’ Masters said. ‘Now, we’re bringing the hurricane back to the lab.’
Rick Dixon, executive director of the Florida Building Commission, said state officials began to tap UF research for help in strengthening the state’s hurricane-related building codes shortly after Hurricane Andrew in 1992.
The 2004 storms showed that while improved codes were effective in preventing catastrophic building failures, challenges remained in blocking wind and water intrusion, he said. It will take more research to learn how to protect windows, doors, soffits, roof coverings and other so-called ‘components and claddings’ – research for which the new wind simulator will be pivotal, he said.