RENO, Nev. (June 19, 2017) — Reno A&E (RAE) is pleased to introduce the PLA Series of Prefabricated Saw-Cut Loops for access control applications. RAE has manufactured prefabricated loops for the access, traffic and railway control industries for more than 20 years.

The ultra-lightweight PLA Series loops are extremely flexible even in cold temperature environments and are designed with Cross-linked Polyethylene (XLPE) insulation. The loops can be installed in 1/8 inch wide (0.32 cm) saw cuts or larger and eliminate the need to cut 45-degree relief corners which provides a longer life cycle of the roadway surface. This series of loops also incorporate a tinned 20 AWG, 4-conductor, stranded copper wire for corrosion resistance.

The PLA Series of Prefabricated Saw-Cut Loops is the newest addition to RAE’s product suite of prefabricated loops for saw-cut and direct burial applications. The PLB Series, a saw-cut and direct burial type, is designed for concrete, paver applications or asphalt applications with a sand or dirt barrier. The PLH Series, a direct burial type, is designed for cement or hot asphalt roadway applications.

For more information on RAE’s new PLA Series of Prefabricated Saw-Cut Loops or other prefabricated loops, contact us at +1.775.826.2020 and visit

About Reno A&E – An ISO 9001:2008 Registered Company

Reno A&E is recognized as a worldwide developer and manufacturer of reliable high-performance products designed to enhance and augment safety monitoring for traffic, access and railway control systems. The company produces signal monitors, vehicle detectors, bicycle detectors, power supplies, flashers, load switches, flash transfer relays and other vital safety critical infrastructure devices. Reno A&E, a wholly-owned subsidiary of Eberle Design Inc., is headquartered in Reno, Nev. and works with preferred resellers throughout the U.S. and Canada.

Media Contacts:

Birgit Olson, Marketing Communications Specialist, Eberle Design Inc., 602.396.1277,

Sabrina McGowan, SQM Communications, 240.401.2092,