The new fiber-optic installation standard

Nov. 1, 1999
An installation standard for optical cable didn't exist until a little more than a year ago. Certainly the National Electrical Code (NEC) has been covering optical cable for longer than that, but the NEC requirements cover fire safety, installation with electrical conductors, and not a whole lot more. The primary installation note in Article 770 is in 770-8, where the NEC says that the work must be

An installation standard for optical cable didn't exist until a little more than a year ago. Certainly the National Electrical Code (NEC) has been covering optical cable for longer than that, but the NEC requirements cover fire safety, installation with electrical conductors, and not a whole lot more. The primary installation note in Article 770 is in 770-8, where the NEC says that the work must be done in "a neat and workmanlike manner." But what exactly is a neat and workmanlike manner? The new fiber installation standard defines that term-and much more.

The proper name of the standard is ANSI/NEIS 301, and it was developed as a joint venture of the National Electrical Contractors Association, (NECA), Bethesda, Md., and the Fiber Optic Association. It's part of the ANSI's (American National Standards Institute) National Electrical Installation Standards program. It was approved and published in late 1998.

The general section of the standard describes "procedures for installing, testing, and commissioning of systems that use fiber- optic cables and related components to carry signals for telecommunications, control, and similar purposes."

The intent of the standard is to define "a minimum level of quality for fiber-optic cable installations."

Cable installation

No major surprises pop up in these sections of the standard. The first requirement is that, "All fiber-optic cables should be installed in accordance with their listings and manufacturers' instructions." Obviously. But the support section gives precise details on how cables must be supported: All optical cables shall be securely supported, and shall have the supports spaced closely enough that there will be no excessive force placed on the cable. In general, horizontal indoor cables shall be supported at intervals not exceeding 3 ft (91 cm). Supports may be placed up to 5 ft (1.52 m) apart for armored cables, or cables more than 1/2 in. (1.3 cm) in diameter. Cables directly buried require no additional support. Cables in raceways are considered to be adequately supported by the raceway.

Another important section is concerned with the tightness of supports. With power wiring, we are seldom concerned with supports being over-tightened, but with data cables (not only fiber), over-tightening is a frequent source of cable damage, and must be avoided. The section reads as follows:

"All straps or supports placed on fiber-optic cables shall be tight enough to hold the cable securely, but shall not be tight enough to substantially deform the shape of the cable. Where possible, rounded or padded supports shall be used. Cable ties shall not be cinched too tightly, and shall have the free tab cut off, to prevent over-tightening in the future."

The standard also gives general rules to be followed when pulling cables into place. After mentioning that manufacturer's instructions take pre-eminence, the following general rules are given:

1. When pulling optical cables into conduits, cable trays, or raceways, the strength member(s) of the cable shall bear all or nearly all of the pulling force. Cable jackets shall not be directly pulled unless designed for the purpose, or unless the run is very short and requires a minimal pulling force. Optical cables shall not be pulled into place by applying tension directly to the fibers (pulling the fibers).

2. Optical cables shall be attached to a pulling line only by methods recommended by the manufacturer of the cable.

3. Unless stated otherwise by the cable manufacturer, the maximum pulling tensions used for optical cables shall be 300 lbs. (136 kG) for multi-fiber indoor cables, and 600 (273 kG) lbs. for outdoor cables. The pulling force shall be uniform and consistent; cables shall not be jerked.

4. Cable pulling shall be done by hand, except when tension meters, tension-controlled or break-away swivels are used.

5. When powered pulling equipment is used to install optical cable, tension monitoring equipment or break-away swivels shall be used. Swivels shall be used when pulling optical cables into conduits. Exceptions shall be made to this requirement only for very short runs which require a minimum pulling force. 6. Continuous cable pulls shall be used whenever possible, avoiding splice points. 7. Boxes used with optical cables shall be designed for the purpose, and shall be equipped with cable supports. Pull boxes shall be sized so that no cables in the box shall be tightly bent.

8. A length of free cable shall be provided at each end of a cable pull. Loops of cable (commonly called service loops) shall be provided at all intermediate pulling points, such as in manholes and pull boxes. The cables' minimum bending radii shall not be violated.

9. When pulls are accomplished in two or more stages, and spare cable must be unreeled, it shall be configured in large figure-eights on a safe, flat surface, such as the ground or a clean floor.

10. When pulling fiber-optic cable through non-metallic raceways (or non-metallic 907 elbows) with rope, maximum speed through a duct shall be about 3 ft (91 cm) per second. If mule tape is used, the top speed shall be 9 ft (274 cm) per second. The intent of this requirement is that the nonmetallic conduit or elbows will not be cut or grooved by the pulling process.

11. When underground raceways containing optical cables enter a structure, the raceway shall be sealed to prevent the entry of gases into the structure. The entry of outside plant cables into a structure may require special fire safety considerations.

Safety precautions

As I have noted before, two primary safety hazards are associated with optical-fiber systems. The most commonly talked about hazard is retina damage due to looking into the ends of live fibers. In real life, however, this is a real rarity. Few fiber systems have enough power to cause eye damage (cable TV systems being the exception), and most broken fiber ends will diffuse the light coming through them anyway. Nonetheless, this is a legitimate concern. The second concern, however, is far more serious. This is the hazard posed by broken pieces of fiber. These are essentially small glass needles, and can be quite dangerous: painful when stuck in the skin as a splinter, and potentially life-threatening if ingested. Hence the safety requirements of this standard, which follow:

Live optical fiber ends (live fibers are those with signals being sent through them) shall not be inspected by technicians; fibers shall be dark (no signal being transmitted) when inspected. Care shall be taken in verifying that the fibers are not live, since the light used in most optical systems is not visible to the human eye.

If there is a risk of fibers being inspected live, especially when the system light source is a laser, all technicians working on the system shall wear protective glasses which have infrared filtering.

Fiber-optic work areas shall be clean, organized, well-lit, and shall be equipped with a bottle or other suitable container for broken or stray fiber pieces.

No food, drink, or smoking shall be allowed in areas where fiber-optic cables are spliced or terminated, or in any area where bare fibers are being handled.

Technicians making fiber terminations or splices or working with bare fiber shall be supplied with double-sided tape, or some other effective means, for picking up broken or stray pieces of fiber. All work areas where bare fiber may exist shall be repeatedly and consistently cleared of all bare fiber pieces. All bare fiber pieces shall be disposed of so that they cannot escape and cause a hazard. (For example, bare fibers should be sealed in some type of bottle or container before being dumped into a wastebasket.)

All technicians working on bare fiber shall thoroughly wash their hands immediately when leaving the work area. They shall also check their clothing, and pat themselves with clean tape to remove any stray pieces of bare fiber.

Documentation

Another area where data cabling differs from power wiring is in testing and documentation. For most electrical installations, the only testing done is flipping on the light switch or pushing a Wiggy into the outlets. But for data, every run of cable must be tested separately, and the results written down permanently. This is not especially difficult to do, but it does require time and effort. More importantly, it requires a change of mind-set for workers that cut their teeth on power wiring.

The requirements of this section are as follows:

All optical test results shall be thoroughly and accurately documented, and copies of the test results saved in a permanent form (typically in both hard-copy and on computer disk).

In general, documentation of test results shall include the following information: 1. Cable type and length.

2. Splice and termination points.

3. Fiber type and size.

4. Connector types.

5. Splice types.

6. Cable paths.

7. End-to-end losses of completed transmitter-to-receiver links. 8. (Optional) End-to-end losses of individual fiber links.

About the Author

Paul Rosenberg

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