UVU Bridge snow-melt project combines PP-RCT and PEX-a piping to clear a safe path over interstate highway in Utah

Hybrid snow-melt installation atop a 970-foot walkway joining two sides of Utah’s largest public university becomes first large-scale use of Uponor PP-RCT in North America. Radiant heating specialist Thermal Engineering threads 1,900 feet of PP-RCT through bridgeworks to feed 36,000 feet of PEX snow melt along the pedestrian bridge.

BY MICHAEL NICHOLSON

OREM, UTAH — Contractor Aron Frailey estimates he has installed as many as one thousand radiant snow-melt projects since entering the business right out of college nearly 20 years ago. The jobs have been many and varied — from high-end residential to large commercial. He even spent three weeks in Moscow in 2017 at the behest of the U.S. State Department, building a snow-melt system for the U.S. Embassy there — “although I couldn’t speak a lick of Russian.”

Download/View
Case Study

icon_word_icon MS-Word (.docx)


Image Gallery
Download individual images as lo-res (web ready; .jpg; RGB) or hi-res (print ready; .tif; CMYK)

All photography courtesy of Thermal Engineering LLC, Salt Lake City, Utah

But, Aron’s most unusual job to date is one of his most recent: The UVU Pedestrian Bridge on the Orem campus of Utah Valley University, the largest public university in the state. “It’s the first bridge I have ever done,” says Frailey, who founded Thermal Engineering LLC in Salt Lake City in 2008. After nearly two decades working on some of the largest snow-melt jobs in the world for his own firm and a previous employer, he does not hesitate to label the UVU Bridge “as definitely a learning experience.” By that, he doesn’t mean an easy one.

UVU is a “landlocked” campus, with all student housing located west of the super-busy U.S. Interstate 15. The school itself sits on the opposite side to the east. In the fall of 2019, the Utah Department of Transportation (UDOT), the Utah Transit Authority (UTA), general contractor Kraemer North America (Plain, Wisconsin), and UVU broke ground on the pedestrian walkway that will provide safe egress from one side to the other.

Suspended 22 to 35 feet above ground, the 17-foot-wide bridge spans almost 305 feet across I-15, providing access for up to 6,000 students a day, according to Josh Sletten, project manager for the engineering firm WSP USA. The structure includes bicycle access and elevators to make it ADA-compliant, a covered roof with perforated sides for comfort, and a radiant-heated deck.

Obviously, the project will make transit from one side of the highway to the other far more appealing to university students, staff and visitors. (Not only does the new bridge overarch I-15, but also railroad tracks owned by Union Pacific and the UTA Frontrunner Commuter Rail.) The ability to snow melt the upper landings and the walkway is another critical ingredient to safety, to both walkers and the fast-moving vehicles below. Orem receives, on average, more than 40 inches of snow annually.

“There were concerns about how to incorporate snow melt in a project of this scale,” says Frailey. “But UVU and UDOT saw the liability issue as ample justification for the extra cost.” After all, the logistics of manual snow removal from such a large pathway that high in the air were beyond daunting. As Frailey notes: “How would you get a piece of equipment up there to plow it? If you did, where would all the snow go?”

With snow melt, the bridge’s curving contours will efficiently direct runoff to both sides of the bridge, safely disposing whatever liquid remains from the melting process. As Frailey explains: “The system generates quite a bit of evaporation to help remove the snow.”


PP-RCT + PEX
Frailey’s “learning experience” goes beyond never having put snow melt on a bridge before. The UVU project also represents his largest use of a polymer plastic pipe known as PP-RCT — shorthand for “polypropylene, random copolymer, with modified crystallinity and temperature resistance.” Having used the pipe on two smaller commercial projects in Boston and Cleveland, the Thermal Engineering team was “not unfamiliar with it,” says Frailey. “But we had never used the material on a project this large and this different.”

The UVU Bridge also represents another major first: the first full-scale use of Uponor North America’s PP-RCT pipe and fittings offering, made exclusively for the company through a partnership with Pestan North America. The two companies announced their partnership in September 2019, with a phased rollout throughout 2020, beginning mainly in the Far West. Shipping diameters from ½-inch to 12 inches from stock (up to 24 inches for special orders), Uponor is targeting a wide array of commercial hydronic distribution applications in the U.S. and Canada.

The UVU Bridge is actually a “hybrid” snow-melt installation involving both PP-RCT and the type of polymer plastic pipe Uponor is best-known for: crosslinked polyethylene, or PEX-a. Thirty-six thousand linear feet of 5/8-inch PEX has been installed in a snow-melt grid along the bridge’s pedestrian walkway and landings. In addition, 1,900 linear feet of PP-RCT, ranging in diameter from 2½ inches to 4 inches, performs a supply-and-return function, transporting a warm glycol solution from a boiler in a mechanical room in a tower on the east side of the bridge to the PEX-a snow-melt grid.

Frailey recalls the day he first heard about the project. “My salesperson walked into my office — ‘How do you feel about quoting a snow-melt job for a thousand-foot bridge?’ Wow, I thought: A bridge? Can that even be done?”

Thermal Engineering began communicating with WSP and Kraemer, submitting load calculations based on the engineer’s initial design concepts. But it took some time for the project to gain traction. When it did, Frailey remained unsure.

“Looking at the project in its initial stages on paper, it was difficult to see how we would do it,” he says. “Even with 3D models, we struggled to understand how we would thread roughly 2,000 feet of pipe through all the girders of this bridge structure. There is a whole steel truss we had to work around and through, and I feared it could be a disaster from the standpoint of safety.”


Change the pipe spec
Part of the challenge was the structure’s height. Then there was the original specification, calling for the hydronic-distribution part of the project to be built with the conventional choice for this application type: four-inch steel pipe. A standard length in that diameter weighs in at more than a ton. Numerous installers would need to be involved, and the work would involve welding. Frailey wanted no part of welding — “We don’t have those capabilities” — and he wasn’t excited about grooved pipe, either.

So Thermal Engineering began investigating — and eventually recommended — PP-RCT as a worthy alternative. A non-corrosive plastic polymer would be better able to withstand the salt and magnesium chloride Utah uses for snow and ice melting on its highways. Even with the bridge 30 feet in the air, this was a major concern, because the hydronic piping would be installed in the structure’s underside, facing fast-moving traffic below.

Moreover, PP-RCT would be far easier to handle and therefore less labor-intensive than steel. Shipped in 19-foot lengths, a stick of 4-inch PP-RCT weighs a mere 63 pounds — a tiny fraction of its steel counterpart. Under normal circumstances, a single fitter can handle the pipe connections, using the special heat-fusion machinery and tools required by PP-RCT. (Of course, “circumstances” at the UVU Bridge were anything but normal, requiring a three-man installation crew: more on that in a bit.)

PP-RCT offered one other critical advantage over steel: the ability to move in unison with the bridge. “The structure is intended to move as much as 18 inches and in every direction all the time: left to right, backwards and forwards, up and down,” says Frailey. “I was concerned about the joint integrity of a steel piping system with all that movement, and I really liked the flexibility of PP-RCT to handle it.”

For all these reasons, Thermal Engineering formally asked the engineer to change the specification to PP-RCT. After due consideration, the change was made.

“The engineer understandably had lots of questions,” says Frailey, who came to appreciate the “high level of trust” that flourished among his firm and Kraemer North America, WSP and the rest of the build team on this unusual and highly challenging project.

“We sent samples and demonstrated how to make a heat-fusion pipe connection. We also cut some joints apart, so the engineer could confirm how completely the materials bonded. When we began reviewing the flow and weight characteristics, as well as the integrity of the joints and the ability to flex with the bridge, PP-RCT won the day.”


On-the-job learning
So how did the Thermal Engineering crew finally master the art and science of running a hydronic distribution pipeline across a 970-foot-long bridge that spanned a busy interstate highway? By doing the work, says Frailey.

“I never really understood how we were going to do it until Kraemer North America began prefabricating sections of the bridge offsite before reassembling them over the freeway.”

As it turned out, Frailey’s crew threaded the majority of the PP-RCT through the bridgeworks while it sat on the ground in the prefab steelyard, located roughly a mile and a half from the job site. Using a lift truck fitted with a winch for moving the pipe laterally, the team created a workstation for the McElroy Acrobat heat-fusion machine to connect the 19-foot lengths of PP-RCT.

Although the heat-fusion process normally requires only two fitters, according to Frailey, “we needed a three-man team for this job” to reach the underside of the bridge. The first pipefitter’s task was to maneuver the 19-foot piece of PP-RCT off the ground and up into the bridge’s girder diaphragms. Project superintendent Scot Layland situated himself in the airborne workstation, hooking each length of pipe to the fusion machine and butt-fusing it to another length ahead of it in the line. Meanwhile, a third person manned the boom truck and the winch, pulling the steadily lengthening, fused-pipe assembly through the bridge.

Frailey estimates that each “lift-fuse-pull” cycle spanned 45 minutes, including the cooling time each connection required before it could be eased along and the process begun anew.

The entire UVU Bridge is constructed on two girders. Some sections could be picked up and trucked to the job site with the girders intact, including the butt-fused PP-RCT. But several were too heavy to be transported as pairs. They had to be disassembled, moved and reconnected on the bridge site, where Frailey’s PP-RCT team performed their “lift-fuse-pull” routine as well, sometimes working at night by the interstate highway.

“Our men ran a rope through the girders and attached it to the pipe, pulling it through the girders while working on opposite ends of the bridge, rather than right over the highway,” says Frailey. Because of the PP-RCT’s weight, “the crane pulled the pipe easily — no big deal.”


Don’t give up!
The PP-RCT distribution system connects to the PEX snow-melt grid atop the bridge through two-inch copper manifolds. Why copper instead of PP-RCT? “Material availability at this time,” says Frailey. “The construction schedule would not allow us to wait for the PP-RCT version. Otherwise, I would’ve gone with the latter.”

After the challenges of the hydronic piping, the snow-melt portion of the job was smooth and comparatively uneventful. “For us, PEX for snow-melt is a known entity and installed without any problems.”

In completing the UVU Bridge project, Thermal Engineering had to scale several formidable learning curves never previously encountered, such as how to hoist roughly 100 pounds of heat-fusion equipment into a workable spot beneath the bridgeworks; how to design seven different expansion joints where the bridge’s massive girders connect; how to take into account seismic calculations. “That was a new one!” Frailey says.

He credits the training that Uponor provided — “a little more intense than most new-product situations” — for helping his team through some tough spots. But credit goes as well to Thermal Engineering’s can-do approach in the face of so many installation unknowns.

“I saw the UVU Bridge as a challenge, a feather-in-my-cap, résumé project,” Frailey comments. “Instead of saying it can’t be done, let’s figure out how to do it. We wrestled with it, one little bit at a time, gauging how each piece of the puzzle fits. But now we know how — how to bid, how to design, how to install, how to be productive.”

As one of the few contractors nationwide with PP-RCT experience on a commercial job of this magnitude, does Frailey have any advice for colleagues approaching their first go-round with the product?

“Sure — just don’t give up. PP-RCT is an awesome product, which is why we are already using it on other projects. The flow characteristics of the pipe, its light weight and flexibility, the ease of lifting and maneuvering it — all these benefits are huge compared with steel. The longevity of the system is also so much better.

“Of course, there’s a lot of learning to be done on a first project. You may not be as productive as you’d like on the first try. But, hang in there: It gets much easier once your people begin to work with the product.”


About the author: Michael Nicholson is Business Director, PP-RCT, at Uponor North America in Apple Valley (Minneapolis), Minnesota. He can be reached at: [email protected].

 


###

Agency Contact
John O’Reilly or Payton Meyers
GreenHouse Digital + PR
T 815.469.9100
E  [email protected]
E [email protected]


About Uponor
We mean progress.

Apple Valley, Minn.-based Uponor North America strives to be the partner plumbing and HVAC professionals rely on for smart water and energy solutions. The company is helping to advance the construction industry through innovation, education and advocacy focusing on the defining issues of our time: water, energy and labor. An award-winning manufacturer of PEX piping and provider of plumbing, fire safety, radiant heating/cooling, hydronic piping, and pre-insulated piping systems, Uponor offers solutions for new construction, retrofits and remodels in the residential, light commercial and commercial markets.

Uponor partnered with Belkin International in 2016 to form Phyn, a new intelligent water company that is revolutionizing the way consumers interact with water and helping solve major challenges facing the global water supply. Recognized for best-in-class manufacturing, sustainability, economic development and as a top workplace, the Uponor group of companies employs more than 33,800 worldwide. Uponor’s global headquarters are located in Vantaa, Finland. uponor-usa.com

© 2020 Uponor, Inc.
Uponor is a trademark of Uponor Corporation and Uponor, Inc.



Image Gallery
All photography courtesy of Thermal Engineering LLC, Salt Lake City, Utah


Aron Frailey of Thermal Engineering LLC on the UVU Pedestrian Bridge while still under construction in October 2020: “Definitely a learning experience.”

Download Lo-Res Image
Download Hi-Res Image

 


Aron Frailey of Thermal Engineering LLC on the UVU Pedestrian Bridge while still under construction in October 2020: “How would you get a piece of [snow-removal] equipment up there to plow it? If you did, where would all the snow go?”

Download Lo-Res Image
Download Hi-Res Image


Aerial view of the UVU Pedestrian Bridge with the Utah Valley University campus in the background: Suspended 22 to 35 feet above ground, the 17-foot-wide bridge spans almost 305 feet across I-15 and will provide access for up to 6,000 UVU students a day.

Download Lo-Res Image
Download Hi-Res Image

 


Aerial view of the UVU Pedestrian Bridge with the Utah Valley University campus in the background: Not only does the new bridge overarch I-15, but also railroad tracks owned by Union Pacific and the UTA Frontrunner Commuter Rail.

Download Lo-Res Image
Download Hi-Res Image


Aerial view of the UVU Pedestrian Bridge with the Utah Valley University campus in the background: The UVU Bridge is actually a “hybrid” snow-melt installation involving 1,900 linear feet of PP-RCT and 36,000 linear feet of 5/8-inch PEX-a pipe, installed in a snow-melt grid along the bridge’s pedestrian walkway and landings.

Download Lo-Res Image
Download Hi-Res Image

 


Thermal Engineering project superintendent Scot Layland in his airborne station, where he butt-fused together 19-foot lengths of Uponor PP-RCT and then threaded the pipeline through the UVU Pedestrian Bridge.

Download Lo-Res Image
Download Hi-Res Image


Thermal Engineering project superintendent Scot Layland in his airborne station, where he butt-fused together 19-foot lengths of Uponor PP-RCT and then threaded the pipeline through the UVU Pedestrian Bridge. Frailey’s crew threaded the majority of the PP-RCT through the bridgeworks while it sat on the ground in the prefab steelyard, located roughly a mile and a half from the job site. Using a lift truck fitted with a winch for moving the pipe laterally, the team created this workstation for the McElroy Acrobat heat-fusion machine to connect the lengths of PP-RCT.

Download Lo-Res Image
Download Hi-Res Image

 


Thermal Engineering’s Aron Frailey: “I saw the UVU Bridge as a challenge, a feather-in-my-cap, résumé project. Instead of saying it can’t be done, let’s figure out how to do it.”

Download Lo-Res Image
Download Hi-Res Image

Back to Top