Wire & Cable ASIA – September/October 2007

52

March/April 2013

www.read-wca.com

Abstract

This article will attempt to compare mechanical perfor-

mance parameters of waveguide cables with optical

performance of both conventional fibres and reduced bend

radius fibres. The coordination of mechanical and optical

test data can point to more appropriate test criteria for

cables with reduced bend radius fibres. This will ensure a

more robust characterisation criterion appropriate to this

new class of fibre.

Introduction

The advent of both single mode and multi-mode bend

insensitive fibres has brought into question whether

existing cable test plans accurately characterise a cable

design to provide expected lifetimes.

Presently, most published test plans rely on delta

attenuation values at discrete wavelengths as pass/

fail criteria for various mechanical criteria. With the

introduction and use of new reduced bend radius fibre

types, less robust cable designs can now pass such

standardised cable tests.

This result can lead to possible substandard cable designs

that can generate future failures in the field. Long-term

stresses may be placed on the optical waveguides and

not be reflected in the delta attenuation measurement

protocols currently prescribed by standardised tests such

as Telcordia GR-409 and GR-20.

Fibre improvements

Telcordia GR-409 is the current standard of specifications

for indoor fibre cables, while Telcordia GR-20 provides

technical reference for outdoor cables.

Some companies, such as Verizon, have more

sophisticated versions that reference GR-20 and GR-409,

but also add additional qualifications. Together, this

specification documentation dictates the mechanical

performance standards agreed upon by the customer and

manufacturer. More recently, however, fibre improvements,

particularly in reduced bend radius fibres, are challenging

the industry to revisit the test standards for fibre.

With the increased performance features of reduced bend

radius fibres versus conventional fibres, existing standards

may no longer be a “one size fits all” measurement.

Several optical fibre manufacturers developed con-

ventional optical fibres in the 1970s. Over the years,

there have been few significant improvements outside

of coating developments to improve the fibre’s inherent

ability to withstand mechanical forces on its environment.

But aside from innovations during the draw process,

improving the overall empirical tensile properties of optical

waveguides, improvements to optical fibre designs have

been relatively minor until about five years ago. At that

time, several concepts emerged to improve on other fibre

characteristics, such as physical strength and bending

characteristics. This was the introduction of reduced bend

radius fibres.

Reduced bend radius fibres include several viable

technologies.

❍

❍

Figure 1

: Fibre with <1% shrinkage

❍

❍

Figure 2

: Fibre with >4.5% shrinkage

❍

❍

Figure 3

: <5% shrinkage cable connector interface

3.0mm Jacket

3.0mm Jacket

900 Micron Tight Buffer

900 Micron Tight Buffer

Test methods for cables

incorporating reduced

bend radius fibres

By Wayne Kachmar, ADC Telecommunications, USA