Direct-buried cable

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Cross-section of direct buried cable Direct-buried cable (en).svg
Cross-section of direct buried cable

Direct-buried cable (DBC) is a kind of communications or transmissions electrical cable which is especially designed to be buried under the ground without any kind of extra covering, sheathing, or piping to protect it. [1]

Contents

Most direct-buried cable is built to specific tolerances to heat, moisture, conductivity, and soil acidity. Unlike standard telecommunications and power cables, which have only a thin layer of insulation and a waterproof outer cover, DBC consists of multiple layers of heavy metallic-banded sheathing, reinforced by heavy rubber covers, shock absorbing gel, wrapped thread-fortified waterproof tape, and stiffened by a heavy metal core.

DBC is preferable in some areas since it is more resistant to being the focus of lightning discharges. [2]

Communications

Most cable of this kind is coaxial or bundled fiber-optic cable. In the 20th century much of it was filled cable. Direct-buried cable is cheaper and easier to lay than other kinds of cable that require protection from the earth. [1] However, DBC is also easily cut during digging or other excavations. As a result, most direct-buried cable is found on side roads, not main thoroughfares. [3]

Power

Some power cabling is also direct-buried. This kind of cabling must follow strict regulatory procedures regarding installation [4] and backfilling. This is usually used for undergrounding in areas where overhead cabling is impractical or dangerous.

See also

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References

  1. 1 2 Sterling, Donald J. (2000). Premises Cabling. Thomson Delmar Learning. ISBN   0-7668-1735-0.
  2. Rakov, Vladimir A.; Uman, Martin A. (2003). Lightning: physics and effects. Cambridge University Press. ISBN   0-521-58327-6.
  3. Highhouse, John (1997). A Guide for Telecommunications Cable Splicing. Thomson Delmar Learning. ISBN   0-8273-8066-6.
  4. Salata F., De Lieto Vollaro A., De Lieto Vollaro R. A model for the evaluation of heat loss from underground cables in non-uniform soil to optimize the system design. Thermal Science, DOI REFERENCE: 10.2298/TSCI120528119S