Low sloped roofs, common in Florida and other hurricane prone areas, are the most difficult to protect from the wind damage inflicted by high winds.
Hurricanes can lift the entire roof off a building and expose it to the wind, rain and other damaging conditions, even after the worst of the wind has passed.
There are some steps homeowner can take to protect their roofs from blowing away in a hurricane force wind, but the solutions are often very expensive and make future repairs on the roof difficult.
An Inexpensive Vent May Solve The Problem
A Virginia roofer together with Virginia Tech faculty members from architecture and engineering, and a graduate student have devised an inexpensive vent that can reduce roof uplift on buildings during high winds, even a hurricane.
Low-sloped roof buildings around Wytheville, Va., where Virginia Tech alumnus Chuck Johnson and his brother, Pat Johnson, operate a roofing business, have sprouted foot-high plastic structures that look vaguely like alien technology – a flying saucer connected by three narrow columns to a dome.
Chuck Johnson, an irresistible pitchman, has also persuaded Travel Centers of America in South Carolina, the Gaston County government complex in North Carolina, a Nestlé’s distribution center in Tel Aviv, and VTKnowledgeWorks in the Virginia Tech Corporate Research Center to use the revolutionary Venturi Vent Technology (V2T™), designed for membrane roofing systems.
Current Roofing Safeguards Are Too Expensive
Hurricane Andrew (August 24, 1992) resulted in $26 billion worth of damage. It was the first big event that created changes in the roofing industry, said Johnson. “Now, so many fasteners are required that roofing is very expensive and the integrity of the deck is compromised,” he said. “Plus, if you ever have to take the roof off, you have to take it off in pieces and recycling the material is impossible. It’s all very labor intensive.”
But the V2T system could revolutionize the way roofing is done, Johnson said. “We are using physics instead of mechanical fasteners or adhesives. The harder the wind blows, the better it works.”
The Venturi Effect
The physics is the Venturi effect. You know – wind forced through an opening speeds up. Covered porches create a breeze. Winds blow harder through mountain passes and between city buildings. Cars at any speed split the air, so when you crack the car window to get rid of cigarette smoke, the lower pressure outside sucks the smoke out the window.
Sitting at their kitchen table about six years ago, the Johnson brothers asked, “What if we could split the wind blowing over a roof and create a vacuum to suck the roof down instead of up?”
The result was V2T.
V2T splits the airflow, speeding up the wind that is forced through the vent (between the upper saucer and the lower dome), which drops the pressure and creates a vacuum.
The saucer has a hole on the bottom and the columns are tubes from the saucer to the dome and the underside of the roof membrane. The wind pressure draws the air out of the saucer and from under the membrane, pulling the membrane down tight against the substrate.
“The pressure being created under the membrane is lower than the uplifting pressure of the wind over the roof. The result is a low pressure condition that prevents the uplift and detachment of the roof membrane,” said Jim Jones, associate professor of architecture at Virginia Tech.
Keeping Up With Changing Winds
The Johnsons took their idea to Virginia’s Center for Innovative Technology (CIT), which referred them to Jones. “Their concept was a tube shaped vent that would rotate to catch the wind,” Jones said.
He saw that keeping up with changing wind direction could be a problem and decided to investigate whether the Venturi concept could be applied to an omni-directional design “so it wouldn’t matter which way the wind came from.”
Designing With Geometry
Jones and his graduate student, Elizabeth Grant, started exploring the geometry of a pyramidal base with an inverted pyramid on top – like an hour-glass with a space in the middle for the wind to pass through.
They presented that idea to Demetri Telionis, the Frank Maher Professor of Engineering Science and Mechanics, an aerodynamics expert, who suggested a similar but rounded shape – the dome and saucer.
“Once we decided on the geometry, the fine tuning became Grant’s thesis. She created a model with an adjustable distance between the dome and bowl and began wind-tunnel tests.”
Wind Tunnel Tests Work
With funding from the CIT and the Johnsons’ company, Acrylife (http://www.acrylife.com), the team designed and built several prototypes – with different shapes, distances, and connecting columns, with the goal of enhancing the vacuum — and tested them in Virginia Tech’s stability wind tunnel, where winds can reach 150 miles an hour, and in the NASA full scale wind tunnel at Langley Air Force Base. These tests demonstrated the ability of the vent to generate low pressure that could be used to counter the uplifting forces from high winds.
The team figured out how to take a force of nature and harness it, using geometry and physics, “So the very force that could destroy a building is used to save it,” Grant said.
The height of the dome was partially dictated by consideration of rain and snow levels on a roof, Jones said. “The hole was placed in the bottom of the bowl to avoid admitting water. So with the hole in the top unit, the columns had to be hollow.”
Questions Still Need To Be Answered
Jones said at least two questions remain to be answered.
One is concerned with the spacing of the units. Although Johnson has a degree of confidence in the current spacing, he agrees. “It is important to verify this with testing in order to take out the guess work. We need to establish a set of rules that define where the units should be placed for each different roof type.”
Jones suggests, “To maximize the economic benefits of the V2T, spacing should depend on a variety of factors, such as building geometry, parapet wall height, and infiltration rate through the roof deck; and therefore some further study is needed.”
The second question is what happens to the vacuum that holds the membrane down if there are cracks in the substrate or sub roof? “We have scheduled a series of wind tunnel tests to better understand this situation as we begin to develop design guidelines for the system,” Jones said.
UL testing is also in the works.
Real Time Monitoring
Meanwhile, also with an introduction and funding from the CIT, Acrysoft (http://www.acrysoft.net) is developing hardware and software to provide real-time monitoring of the vent. A sensor board developed in conjunction with the Space Alliance Technology Outreach Program will measure the pressures created in the vent and the forces on and under the roof membrane, said Mark Howard, a partner at Acrysoft. “This information has not been available.”
He said such data is critical to engineers. “They want this data before their company invests in a roof system,” said Howard. The sensor, along with cameras, will substantiate initial performance and provide long-term monitoring, “for example, in case there is a tear during an AC repair or some other activity on the roof,” Howard said.
Although the Johnson brothers have been putting their systems on roofs, it would be better if it were provided to roofers by the manufacturers of the roof membrane materials as part of a complete roof assembly, said Chuck Johnson.
Source: Virginia Tech Intellectual Properties Press Release