, Poland The standard utility pole in the United States is about tall and is buried about in the ground. In order to meet clearance
regulations, poles can, however, reach heights of at least 120 feet (40 meters). They are typically spaced about apart in urban areas, or about in rural areas, but distances vary widely based on terrain. Joint-use poles are usually owned by one utility, which leases space on it for other cables. In the United States, the
National Electrical Safety Code, published by the
Institute of Electrical and Electronics Engineers (IEEE) (not to be confused with the
National Electrical Code published by the
National Fire Protection Association [NFPA]), sets the standards for construction and maintenance of utility poles and their equipment.
Pole materials Most utility poles are made of wood, pressure-treated with some type of
preservative for protection against rot, fungi and insects.
Southern yellow pine is the most widely used species in the United States; however, many species of long straight trees are used to make utility poles, including
Douglas fir,
jack pine,
lodgepole pine,
western red cedar, and
Pacific silver fir. Traditionally, the preservative used was
creosote, but due to environmental concerns, alternatives such as
pentachlorophenol, copper
naphthenate and
borates are becoming widespread in the United States. In the United States, standards for wood preservative materials and wood preservation processes, along with test criteria, are set by
ANSI,
ASTM, and
American Wood Protection Association (AWPA) specifications. Despite the preservatives, wood poles decay and have a life of approximately 25 to 50 years depending on climate and soil conditions, therefore requiring regular inspection and remedial preservative treatments.
Woodpecker damage to wood poles is the most significant cause of pole deterioration in some parts of the U.S. Other common utility pole materials are aluminum, steel and concrete, with composites (such as
fiberglass) also becoming more prevalent. One particular
patented utility pole variant used in Australia is the
Stobie pole, made up of two vertical steel posts with a slab of concrete between them.
Power distribution wires and equipment : (
A,
B,
C) 3-phase primary distribution wires (mounted on a crossarm), (
D) neutral wire, (
E)
fuse cutout, (
F)
lightning arrester, (
G) single-phase distribution transformer, (
H) ground wire to transformer case, (
J) "triplex" service drop cable carries secondary current to customer, (
K) phone and cable TV wires On poles carrying both electrical and communications wiring, the electric
power distribution lines and associated equipment are mounted at the top of the pole above the communication cables, for safety. The vertical space on the pole reserved for this equipment is called the
supply space. The wires themselves are usually uninsulated, and supported by
insulators, commonly mounted on a horizontal beam (''''''). Power is transmitted using the
three-phase system, with three wires, or phases, labeled "A", "B", and "C". Sub transmission lines comprise only these 3 wires, plus sometimes an overhead ground wire (OGW), also called a "static line" or a "neutral", suspended above them. The OGW acts like a
lightning rod, providing a low
resistance path to ground thus protecting the phase conductors from lightning. Distribution lines use two systems, either grounded-wye ("Y" on
electrical schematics) or delta (Greek letter
"Δ" on electrical schematics). A delta system requires only a conductor for each of the three phases. A grounded-wye system requires a fourth conductor, the
neutral, whose source is the center of the "Y" and is grounded. However, "spur lines" branching off the main line to provide power to side streets often carry only one or two phase wires, plus the neutral. A wide range of standard distribution voltages are used, from 2,400 V to 34,500 V. On poles near a
service drop, there is a pole-mounted step-down
distribution transformer to transform the high distribution voltage to the lower secondary voltage provided to the customer. In
North America, service drops provide 240/120 V
split-phase power for residential and light commercial service, using cylindrical single-phase transformers. In Europe and most other countries, 230 V
three phase (230Y400) service drops are used. The transformer's primary is connected to the distribution line through protective devices called
fuse cutouts. In the event of an overload, the fuse melts and the device pivots open to provide a visual indication of the problem. They can also be opened manually, usually by
linemen using a long insulated rod called a
hot stick to disconnect the transformer from the line. The pole may be
grounded with a heavy bare
copper or
copper-clad steel wire running down the pole, attached to the metal pin supporting each insulator, and at the bottom connected to a metal rod driven into the ground. Some countries ground every pole while others only ground every fifth pole and any pole with a transformer on it. This provides a path for leakage currents across the surface of the insulators to get to ground, preventing the current from flowing through the wooden pole which could cause a fire or shock hazard. It provides similar protection in case of
flashovers and lightning strikes. A
surge arrester or
lightning arrester may also be installed between the line (ahead of the cutout) and the ground wire for lightning protection. The purpose of the device is to conduct extremely high voltages present on the line directly to ground. If
uninsulated conductors touch each other due to wind or fallen trees, the resultant sparks can start
wildfires. To reduce this problem,
aerial bundled conductors are being introduced.
Communication cables The communications cables are attached below the electric power lines, in a vertical space along the pole designated the
communications space. The communications space is separated from the lowest electrical conductor by the
communication worker safety zone, which provides room for workers to maneuver safely while servicing the communication cables, avoiding contact with the power lines. The most common communication cables found on utility poles are copper or
fibre-optic cable (FOC) for
telephone lines and
coaxial cable for
cable television (CATV). Coaxial or optical fibre cables linking
computer networks are also increasingly found on poles in urban areas. The cable linking the
telephone exchange to local customers is a thick cable lashed to a thin supporting cable, containing hundreds of
twisted pair subscriber lines. Each twisted pair line provides a single telephone circuit or
local loop to a customer. There may also be FOCs interconnecting telephone exchanges. Like electrical distribution lines, communication cables connect to service drops when used to provide local service to customers.
Other equipment Utility poles may also carry other equipment such as
street lights, supports for
traffic lights and
overhead wires for
electric trolleys, and
cellular network antennas. They can also carry fixtures and decorations specific for certain holidays or events specific to the city where they are located. Solar panels mounted on utility poles may power auxiliary equipment where the expense of a power line connection is unwanted. Streetlights and holiday fixtures are powered directly from secondary distribution. ==Pole attachment hardware==