A Moment Of Clarity

If it appears that the William Paterson University men’s basketball team has a glow around it when it plays, it’s not only because the team has reached two NCAA Final Fours and 13 NCAA Tournaments. Actually, that radiant shine from the basketball court is due to a facility lighting retrofit upgrade that burns brighter lights while using far less energy.

The 10,000-student William Paterson University in Wayne, N.J., is one of nine state colleges and universities in the state, and offers 43 undergraduate and 22 graduate programs through its five colleges. The recreation center includes the 28,000-square-foot basketball gymnasium, an exercise room and various other recreational services. Before the lighting retrofit project, the gym was lit with standard 465-watt, metal-halide fixtures.

According to the Director of Physical Plant Operation, Lou Poandl, some people were skeptical when he first proposed the idea of a lighting retrofit, but after the results were on display, even the naysayers were swayed.

Low Light With High Bills

Over time, the light output of the old lamps deteriorated dramatically, leading to an inadequately lit basketball court. At the same time, energy costs were growing. And when the gymnasium was not in use, the lights were kept on to avoid the lengthy delay for them to fully turn on–a common problem with metal-halide lighting technology.

With a ceiling height of 32 feet, increasing the available light while reducing energy seemed like a contradictory approach. Yet the two objectives were met and even exceeded expectations.

William Paterson University sought competitive bids for the project, looking for the biggest energy savings.

New Technologies Improve Lighting

The solution came in the form of a lighting fixture that employed a new reflective technology called Miro, built into a fixture from Westinghouse Lighting Solutions. Miro material–made by German manufacturer Alanod Aluminum–essentially squeezes every particle of light out of the fixture.

Poandl, who has been with the university for ten years, says that “the Miro makes a highly reflective fixture, so it actually throws more light onto the surface where you want it. Light does not get absorbed by the fixture.” The optimized fixtures are far more efficient than fixtures made with traditional anodized aluminum reflectors.

“In fluorescent lighting, the right reflective material can improve the energy savings by as much as 25 percent,” claims Matthias Weigert, Director of Lighting Technologies for Alanod Aluminum.

But it’s not only the material that makes the new fixtures so efficient. It is also the unique way in which Westinghouse designed the fixture to maximize efficiency. The fixture takes advantage of many new lighting technologies: a light-weight aluminum body to manage heat; precise reflector design, using Miro technology that spreads light beams to specific areas; T5 high-output fluorescent bulbs; and rapid-start ballasts. And for easy maintenance, Westinghouse included protective wire guards to cover the fixtures from impacts and an easy-access design so that no tools are needed to remove the lamps and reflectors to access the ballast.

According to Poandl, “In some cases, contractors were obviously throwing us a low-ball price where we’d know they couldn’t do the job for that price, or they were using the wrong materials. If a vendor did not specify Miro, for example, we knew we wouldn’t be able to save as much energy, and we would question the numbers closely.”

Specialized optic design has become a popular method for lighting-fixture designers to improve energy efficiency. Until Miro was introduced several years ago, anodized aluminum and white painted aluminum were the most common reflector materials.

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