Electrical Service and Utilization PDF

Summary

This document provides information about electric service, utilization, and various wiring methods. It discusses factors to consider when building overhead or underground electrical systems. The author explains differences between overhead and underground services and types of transformers.

Full Transcript

Service and Utilization direct burial installation with no concrete
encasement.
NEMA (National Electrical
Manufacturers Association) Type I - is
manufactured with a thinner wall and is intended for
ELECTRIC SERVICE
encasement in a minimum of 2 in. (50 mm) of
concrete.
The codes and standards that apply to electric
service include:
Plastic conduit (PVC) - plastic
1. National Electrical Code
2. National Electrical Safety Code
Nonmetallic conduit is most frequently used
3. Standards of the utility supplying electrical
without concrete encasement for low-voltage and
services.
signal wiring and with encasement for high-voltage
wiring. It offers several advantages over steel
*Electrical construction work on private property is
conduit for underground work, such as lower cost
usually at the owner’s expense.
and freedom from corrosion.

Beautification - to decrease the objectionable
Handholes are used for low-voltage power and
appearance of much of their equipment.
signal cables and for runs with a small number of
cables.
Factors to consider when building overhead or
underground:
Manholes are used for high-voltage cables and
Length of the service run
where large duct banks must be accommodated.
Type of terrain
Service voltage
Type SE - basic service entrance cable,
Weather conditions
constructed with a moisture- and flame resistant
covering.

OVERHEAD SERVICE SE type U or simply USE - When it is provided
low cost with moisture proofing for underground use.
Cost saving ranged from 10% to 50%
type UF (underground feeder) - Underground
UNDERGROUND SERVICE cable for other than service runs.
Preferable in areas with severe weather
conditions, called heavy loading areas.
attractiveness, service reliability, and long
SERVICE EQUIPMENT
life.
high cost
Transformer
- interposed between the high-voltage
UNDERGROUND WIRING incoming utility lines and the secondary
service conductors
The methods available for underground wiring are: - required whenever the building utilization
Direct burial - low cost and ease of voltage is different from the service
installation. voltage.
Installation in Type I, concrete-encased
duct - high strength and permanence, but
at the highest price.
TRANSFORMERS
- device that changes or transforms
Installation in Type II, direct burial duct
alternating current (ac) of one voltage to
- median cost but little strength.
alternating current of another voltage.

Nonmetallic duct (conduit) - intended for
Step-down transformer - has a larger number of
underground electric use is commercially available
turns in its primary winding than in its secondary
in two wall thicknesses.
winding.

NEMA (National Electrical
Step-up transformer - has a larger number of turns
Manufacturers Association) Type II - with a heavy
in its secondary winding than in its primary winding.
wall provides the physical protection required for
Low or secondary voltages - 120, 208, 240, 277, greater weight, and larger size than liquid-filled
and 480 V. units.

High or primary voltages - 2400, 4160, 7200,
TRANSFORMER VAULTS
12,470, and 13,200 V.
- a fire-rated enclosure provided because of
the possibility of fire caused by rupture of
Load center transformers are installed in unit
an oil-filled transformer case.
substations, both indoor and outdoor.

Distribution transformers are mounted on a pole SERVICE EQUIPMENT
or on a concrete pad outdoors. ARRANGEMENTS AND METERING

Substation transformers are large and are always Metering must be provided ahead (electrically) of
concrete-pad-mounted. the building’s service entrance switch(es)

*a transformer is specified by type, phase, voltages, If high-voltage service is purchased, then
kVA rating, sound power level, and insulation class transformers and all other equipment
beyond the service connection will be
*A service transformer bank is necessary when furnished by the owner.
the facility utilization voltage is different from the If low-voltage service is purchased, all the
utility voltage. equipment necessary to provide such low
voltage is furnished by the utility.

Single meter - single-occupant building
TRANSFORMERS OUTDOORS Submetering - apartment houses

The advantages of an outdoor transformer up
installation are: SERVICE SWITCHES
No enclosed building space required
Reduced probability of a noise problem The purpose of electric service switches is to
within the building disconnect the normal service to the building.
Lower first cost
Ease of maintenance and replacement
SWITCHES
No interior heat production
Opportunity to use low-cost, long-life,
Mechanical switches close and open an electric
oil-filled units
circuit by physically moving two electrical
conductors into contact with each other to close the
* The most popular type of exterior transformer
circuit and physically separating them to open the
installation is the pad mount.
circuit.
(a) Oil-Insulated Transformers - most oil-filled
Solid-state switches perform the same electrical
transformers must be installed in a fire-resistant
switching function but by a completely different
vault.
process, without moving parts.
(b) “Less-Flammable” Liquid-Insulated
TYPES OF SWITCHES
Transformers - Transformers rated 35 kV or less
that are insulated with a liquid whose fire point is
1. Single-pole single-throw switch
not less than 300ºC may be installed indoors
- one output and one input
without a vault.
- on-off switching
- Basic function: Controls a single circuit
(c) Non Flammable Fluid-Filled Transformers -
from one location.
do not require a vault unless the voltage is very
- Example: A simple light switch in your
high, require a sump or catch basin of sufficient
home.
capacity for all of the contained liquid.

2. Two-pole single-throw switch
(d) Dry-Type Transformers - transformers of
- Basic function: Controls two separate
choice in the majority of indoor installations, despite
circuits from one location. When the switch
having shorter life, higher losses, higher noise level,
 is in the "on" position, it connects both Summarizing, the following adequately describes a
circuits. When it's in the "off" position, it switch: switch, HD, 3P & SN, 200A/150AF, 600 V, in
disconnects both circuits. NEMA 12 enclosure. This “translates” as a
- Example: Used in electrical panels to heavy-duty switch, 3 poles and solid neutral, 200-
control two different branches of a circuit amp rating with 150-amp fuses, 600-V rating, in an
industrial use enclosure.
3. Three-pole and solid-neutral (3P and
SN) Switch. CONTACTORS
- Basic function: Connects or disconnects - A contactor is a switch, a contactor uses
three circuits independently, with a shared contact blocks of silver-coated copper,
neutral. A 3P and SN switch is like a which are forced together to make (close)
three-way switch that controls three or are separated to break (open) a circuit.
separate circuits instead of just one. - a contactor whose contacts are open when
- Example: Commonly used in motor control the coil is not energized is referred to as
applications. normally open (NO), whereas a contactor
whose contacts are closed when de
4. Single-pole double-throw switch also energized is referred to as normally
called, in small sizes, a 3-way switch). closed (NC)
- Basic function: Controls a single circuit
from two locations. It has three terminals:
SPECIAL SWITCHES
one common terminal and two traveler
terminals.
- Example: Used to control a light from both (a) Remote-Control (RC) Switches - contactor that
ends of a hallway. latches mechanically after being operated.

5. Single-pole double-throw switch with (b) Automatic Transfer Switch - on failure of
center “off” position (in control work normal service it automatically transfers to the
called a hand-off automatic switch) emergency service.
- Basic function: Controls a single circuit
from two locations, with a neutral "off" c) Time-Controlled Switches - switches whose
position. operation is time-based.
- Example: Used in control systems to
provide a "manual-automatic" switch.
SOLID-STATE SWITCHES,
6. Use of two single-pole, double-throw (3- PROGRAMMABLE SWITCHES,
way) switches for switching a lighting MICROPROCESSORS, AND
circuit from two locations.
PROGRAMMABLE CONTROLLERS
- Two 3-way switches that can provide more
flexibility in lightning control from two
locations. Solid-state switch - electronic device with a
- Operation: Flipping either switch will conducting state and a nonconducting state,
change the path of electricity, allowing the corresponding to a conventional switch in its closed
light to be turned on or off from either and open positions.
location.
If a small, programmable memory circuit, in the form
of an erasable programmable read-only memory
current rating is the amount of current that the (EPROM) chip is added, the device becomes a
switch can carry continuously and interrupt safely. programmable time switch.

Switches for normal (occasional) use in lighting and A programmable controller is an electronic device
power circuits are called general-duty safety that uses a programmable memory chip for internal
switches. storage of instructions that in turn implement
specific functions such as logic, timing, counting,
Switches for frequent interrupting, high-fault and so on.
currents, and ease of maintenance are rated HD for The internal control/memory is frequently referred to
heavy duty. as a microprocessor; with respect to the overall
programmable controller, it acts as a central
processing unit (CPU).
 Air-circuit breakers
Programmable controllers have all but re-placed (1) molded-case breaker
the ubiquitous hard-wired relay panel in - consist of a complete mechanism
applications. encased in a molded phenolic case.

EQUIPMENT ENCLOSURES (2) large air-circuit breaker
- Is a small structure, cabinet, or vault that - a more complicated and highly adjustable
used to house and protect the equipment device used in larger applications that can
necessary for processing wireless be used in applications that preclude the
communication signals. use of molded-case breakers.

(c) Characteristics of Fuses and Circuit
NEMA Designation: Description
Type Breakers

1 General-purpose Although both fuses and circuit breakers are
circuit-protective devices, their characteristics differ
2 Dripproof
markedly, as seen in the following comparisons.
3 Dust-tight, rain-tight, and sleet-resistant
Fuses—Switch-and-Fuse Combination
3R Rainproof and sleet-resistant ADVANTAGES
3S Dust-tight, rain-tight, and sleet-proof
Simple and foolproof
Constant characteristics (no aging)
4 Watertight and dust-tight Initial economy
Very high interrupting capacity (IC)
4X Watertight, dust-tight, corrosion-resistant
No maintenance
7-9 Hazardous Instantaneous; energy-limiting

12 Industrial use, dust-tight, and drip-tight DISADVANTAGES
Fuses are single-pole only
Necessity for storage of replacement fuses
CIRCUIT-PROTECTIVE DEVICES Nonrenewable (one-time operation)
Nonadjustable
Nonindicatinga
To protect insulation, wiring, switches, and other
No electric or remote controla
apparatus from the destructive effects of overload
Not trip-free
and short-circuit currents, an automatic means for
opening the circuit is required:
Circuit Breakers
ADVANTAGES
(a) Fuses - The fuse is a simple device consisting
Usable as switches
of a fusible link or wire of low melting temperature
Multipole
that, when enclosed in an insulating fiber tube, is
No storage of replacements required
called a cartridge fuse (available up to 6000 A and
Resettable
600 V) and, when enclosed in a porcelain cup, is
Indicates trip
known as a plug fuse (rated 5 to 30 A, 150 V to
Trip-free
ground, maximum).
Remote-control potential
Adjustable
b) Circuit Breakers - electromechanical device that
performs the same protective function as a fuse
DISADVANTAGES
and, in addition, acts as a switch, it can be used in
Low to medium IC, except for special units
lieu of a switch-and-fuse combination to both
Periodic maintenance required
protect and disconnect a circuit.
High initial cost
- The thermal trip acts on overload,
Complex construction changes with age
whereas the magnetic trip acts on a short
circuit.
SWITCHBOARDS AND SWITCHGEAR

switchboard is a large, free-standing assembly of
switches and fuses (and/or circuit breakers), which
normally provides switching and overcurrent
protection to a number of circuits connected to a PRINCIPLES OF ELECTRIC LOAD
single electric source.
CONTROL
- The key to energy conservation and
Modern switchboards are all dead front; that is,
electric demand limitation is load control.
they have all circuit breakers, switches, fuses, and
live parts completely enclosed in a metal structure.
INTELLIGENT PANELBOARDS
Switchgear - low voltage switchboards with large
circuit breakers and all high-voltage equipment - This central panel-mounted controller can
(above 600 V). also accept signal data from individual
remote or network sources and can
a building-type switchboard - when molded-case provide status reports, alarm signals,
circuit breakers are utilized in a switchboard. operational logs, and local bypass and
override functions.
When switchgear is to be installed outdoors, one of
three methods is employed:
1. build a small structure to enclose normal
indoor gear, ELECTRIC MOTORS
2. utilize weatherproof outdoor gear,
3. or utilize switchgear that is built into its (a) Direct-Current Motors - These motors are not
own exterior enclosing structure normally used in building work.

(b) Alternating-Current Motors - These motors fall
UNIT SUBSTATIONS (TRANSFORMER
into three general classifications: poly-phase
LOAD CENTERS) induction motors, poly-phase synchronous motors,
and single-phase motors. Within these categories
unit substation or a load-center substation there are further subdivisions.
- An assembly, comprising a primary
voltage switch and-fuse or circuit breaker, (c) Squirrel-Cage Induction Motors - invented by
a step-down transformer, meters, controls, Nikola Tesla. Squirrel-cage motors are
buswork, and secondary (low-voltage) manufactured in four different NEMA designs to
switchgear. meet different application requirements.
-. Its function is to accept an incoming
high-voltage power supply, transform the (d) Electric Motor Energy Considerations
high voltage to a voltage that can be premium efficiency or PE motors - single-speed,
utilized in the facility, and distribute the poly-phase, squirrel-cage induction motors, designs
low-voltage power through associated A and B, continuous rating, and operating at
low-voltage (secondary) switchgear. 230/460 V, 60 Hz.

PANELBOARDS
- same function as a switchboard except on
a smaller scale. It accepts a relatively large
block of power at some downstream point
in a system and distributes it in smaller MOTOR CONTROL EQUIPMENT
blocks.
- The panelboard components are mounted combination starter - this disconnect switch may
inside an open metal cabinet called a be combined with the starter into a single unit.
backbox.

Backbox WIRING DEVICES: GENERAL
DESCRIPTION
- is prefabricated with knockouts at the top,
bottom, and sides to permit connection of
wiring devices - includes all devices that are
conduits carrying circuit conductors.
normally installed in wall outlet boxes.
WIRING DEVICES: RECEPTACLES SURGE SUPPRESSION

Receptacle The full term for this aspect of power conditioning is
- a contact device installed at the outlet for transient voltage surge suppression (TVSS).
the connection of a single attachment plug. Because transient voltages, also called surges or
- properly called a duplex convenience spikes, can cause major physical damage to
receptacle or duplex convenience outlet computer systems and other types of electronic
- identified by the number of poles, the equipment.
number of wires, and whether the device is
designed for connection of a separate (a) Terminology
equipment ground. Avalanche diode - A solid-state device placed in
- The common wall outlet is properly called parallel with a protected load.
a convenience receptacle outlet, a
receptacle outlet, or a convenience outlet. Clamping voltage - The voltage at which a
shunting device begins to conduct an incoming
voltage surge. The lower a device’s clamping
* The basic components of the entire system are voltage, the better its suppression action.
the control relay and the switches.
EMI/RFI rejection - A measure of the attenuation,
* power line carrier (PLC) - power line carries the by a TVSS device, of electromagnetic interference
control signal (EMI) and RFI.

Gas tube surge protector - A high-energy shunt
device, typically found in high-capacity, good-quality
POWER CONDITIONING
TVSS units that are subject to large surges.
- relatively new electrical term that describes
the process of converting utility-supplied
Isolation transformer - A transformer with two
electrical power, which is frequently
separate windings and no conductive electrical
characterized by transient surges, spikes,
connection between them.
radio frequency noise, and voltage
fluctuation, to a pure (noiseless),
Joule rating - A device’s joule rating is a measure
accurately voltage-regulated sinusoidal
of its capacity to absorb and dissipate heat
waveform, normally referred to as
generated by its action. SI unit of energy.
computer-grade power.
- due to their extreme sensitivity to
Maximum surge current - A measure of a device’s
fluctuations in the power supply voltage
ability to divert and dissipate surge current without
and particularly to random high-frequency
failing.
voltages superimposed on the power
supply voltage, known as radio frequency
Metal-oxide variable resistor (MOV) - A shunt
interference (RFI) or simply radio noise
device somewhat slower than an avalanche diode
but with much higher energy absorption capability
SOURCE OF DISTURBANCE
and higher clamping voltage.
- Utility power systems are designed to
maintain voltage and frequency within
Response time - measure of the rapidity with which
certain limits on an average, long-term
a TVSS device begins to clamp a voltage surge.
basis.

Sinewave tracking - term of uncertain meaning
1. Voltage variations - caused by short-time
found frequently in manufacturers’ literature.
current drain, such as during motor starts,
deliberate voltage reductions (brownouts)
2. Electrical noise - low-amplitude,
higher-frequency voltage that, when superimposed UNINTERRUPTIBLE POWER SUPPLY
on the power line, results in a distorted waveform.
3. Transients - large, short-duration voltage power-conditioning equipment can supply clean
variations, also known as surges or spikes utility power; it cannot, however, supply any power
during a utility outage.

An uninterruptible power supply (UPS) is an
arrangement of normal and backup power supplies
that transfer a facility’s critical load from the normal
to the backup supply in so short a time that no
computer malfunction results. ELECTRICAL EQUIPMENT RATINGS
programmable microprocessors and effective
(a) Voltage - The voltage rating of an item of
sensors and transducers have been added to basic
electrical equipment is the maximum voltage that
UPS systems to produce what is known as
can safely be applied to the unit continuously.
intelligent UPS equipment.
(b) Current - The current rating of a device is
Emergency systems are intended to supply
determined by the maximum operating temperature
electric power to equipment essential for human
at which its components can operate at full load.
safety upon interruption of the normal power supply.

Each electric wiring system is inspected at least
twice by the local inspection authorities: once after INTERIOR WIRING SYSTEMS
raceways (roughing) have been installed and before
the wiring and closing-in of walls, and once after the Electrical power system - primary purpose of a
entire job is complete. system is to distribute electrical energy

Electrical signal or a communication system -
purpose is to transmit information

Wiring and Raceways * how to construct a distribution system that safely
provides the energy required at the desired
THE MAJOR COMPONENTS OF A BUILDING locations?
electrical system can be grouped into three major - isolate all electrically conducting elements
categories: from the building structure, except at those
specific points, such as wall receptacles,
wiring and raceways - conductors and where contact is desired.
raceways of all types
(a) Exposed Insulated Cables - cable
power-handling equipment - construction itself provides the necessary electrical
transformers, switchboards, panelboards, insulation and mechanical protection
large switches, and circuit breakers
(b) Insulated Cables in Open Raceways (Trays) -
utilization equipment - utilization intended for industrial applications, and it relies on
equipment such as lighting, motors, both the cable and the tray for safety.
controls, and wiring devices.
(c) Insulated Conductors in Closed Raceways -
most general type and is applicable to all types of
facilities. In general, the raceway is installed first
SYSTEM COMPONENTS and the wiring is pulled in or laid in later.

* the distribution equipment is largest at the (d) Combined Conductor and Enclosure - cover
supply point, and decreases in size on its way to the all types of factory-prepared and
farthest utilization points. factory-constructed integral assemblies of
conductor and enclosure.
* in collection systems, piping is smallest at the
initial collection points, growing larger (in steps) as
CONDUCTORS
the quantities of fluid increase.
Electrical conductors (“wires”) are the means by
* National Electrical Code (NEC) of the National
which current is conducted through the electrical
Fire Protection Association (NFPA) defines the
system, corresponding to the piping of a hydraulic
fundamental safety measures that must be followed
system. The standard of the U.S. wire and cable
in the selection, construction, and installation of
industry for round cross-section conductors is the
electrical equipment and systems. This code is
American Wire Gauge (AWG).
used by all inspectors, electrical designers,
engineers, contractors, and operating personnel.
a single insulated conductor No. 6 AWG or larger, LIGHT-DUTY BUSWAY, FLAT CABLE
or several conductors of any size assembled into a
ASSEMBLIES, AND LIGHTING TRACK
single unit, are referred to as cable.

Single conductors No. 8 AWG and smaller are (a) Light-Duty Plug-In Busway -. Lightduty
called wire. busways are rated from 20 to 60 A at 300 V, in 2-
and 3-wire construction. Their application is
The AWG numbers run in reverse order to the size principally for direct connection (with overcurrent
of the wire—that is, the smaller the AWG number, protection) of light machinery and industrial lighting.
the larger the size.
(b) Flat-Cable Assemblies - consisting of two,
conductor current–carrying capacity, or three, or four No. 10 AWG conductors is
ampacity, is determined by the maximum safe field-installed in a rigidly mounted standard 15 8-in.
operating temperature of the insulation used on the (41 mm) square structural channel.
conductor.
(c) Lighting Track - a factory-assembled channel
* Most conductors are covered with some type of with conductors for one to four circuits permanently
insulation that provides both electrical isolation and installed in the track (NEC Article 410-R). Power is
a degree of physical protection. Additional physical taken from the track by special tap-off devices that
shielding, where necessary, is provided by a jacket contact the track’s electrified conductors and carry
placed over the insulation. the power to the attached lighting fixture.

* jurisdictions in the United States have banned the
use of aluminum wire in branch circuitry. CABLE TRAY - a continuous open support for
approved cables. The advantages of this system
are free-air-rated cable ampacities, easy installation
and maintenance, and relatively low cost. The
CONDUCTORS FOR GENERAL WIRING
disadvantages are bulkiness and accessibility
- The NEC lists the wire types that are
requirements.
generally installed in raceways and are
referred to by the term building wire.
These wires consist of a copper conductor
covered with insulation and, in some
DESIGN CONSIDERATIONS FOR
instances, with a jacket RACEWAY SYSTEMS

The function of a raceway in such systems is
BUSWAY/BUSDUCT/CABLEBUS largely the same as it is for power wiring: protection
and isolation of the wiring.
- A busway (busduct) is an assembly of
copper or aluminum bars in a rigid metallic design considerations for power systems
housing. Its use is almost always raceways for data and communication systems
preferable, from an economic viewpoint. include:

- In the case of a heavy current requirement, I. Number, type, and location of data-processing
the alternatives to using busways are to terminals
use paralleled sets of round conductors II. Networking requirements:
or a single large conductor. Paralleled III. Number, location, and characteristics of major
sets of conductors are almost always more peripheral devices, such as mass storage, printing,
expensive than a busway of similar current and plotting
capacity because of the high installation IV. Location and type of major subsystems, such as
cost of multiple conduits. computer-aided design/manufacturing space
V. Location of presentation spaces that require
- Cablebus is similar to ventilated busduct, interconnection to computer networks
except that it uses insulated cables instead
of busbars. It carries the ampacity rating of
its cables in free air.
STEEL CONDUIT - It does not require painting.
- drawback is its deleterious effect on many
The purpose of conduit is to: types of concrete, causing spalling and
1. Protect the enclosed wiring from cracking when embedded
mechanical injury and damage from the - rdifficulties frequently encountered are
surrounding atmosphere mechanical freezing of threaded joints
2. Provide a grounded metal enclosure for (because of thread deformation) and
the wiring in order to avoid a shock hazard difficulty in obtaining electrical contact with
3. Provide a system ground path grounding straps
4. Protect surroundings against a fire
hazard as a result of overheating or arcing FLEXIBLE METAL CONDUIT
of the enclosed conductors - consists of an empty, spirally wound,
5. Support the conductors interlocked armor steel or aluminum
raceway. It is known to the trade as
Greenfield and is covered in NEC Article
* the NEC generally requires that all power wiring 350.
be enclosed in a rigid metallic corrosion-resistant - used principally for motor connections and
conduit. other locations where vibration is present,
where movement is encountered, or where
physical obstructions make its use
three types of steel conduit necessary.
- for wiring inside metal partitions. When
1. Heavy-wall steel conduit, also referred to covered with a liquid-tight plastic jacket, it
simply as rigid steel conduit; covered by is suitable for use in wet locations. In this
NEC Article 346. use the threaded fittings configuration, it is most often known by the
trade name Sealtite.
2. Intermediate metal conduit, usually
referred to as IMC; covered by NEC Article
345. use the threaded fittings
NONMETALLIC CONDUIT
- classified under NEC Article 347, is made
3. Metallic tubing, normally known as EMT
from materials such as fiber,
or thin-wall conduit; covered by NEC
asbestos-cement, soapstone, PVC, and
Article 348. uses set-screw and pressure
high-density polyethylene. it may be used
fittings.
without restriction in nonhazardous areas
within the physical limitations of the
the following rules should be observed and
material involved.
included in all specifications for conduit work in
concrete slabs:
1. Conduits shall have an outside diameter (OD) no
greater than one-third the slab thickness, as
SURFACE METAL RACEWAYS
measured at its thinnest point. (METALLIC AND NONMETALLIC)

2. Conduits running parallel to each other shall be These raceways are covered in NEC Article 352.
spaced not less than three times the OD of the Surface metal raceways and multioutlet assemblies
largest conduit center-to-center. may be utilized only in dry, nonhazardous, non
3. Conduit crossings shall be as close to a right corrosive locations and may generally contain only
angle as possible. wiring operating below 300 V. Such raceways are
4. Minimum cover over conduits shall be ¾ in. (19 normally installed exposed, in places not subject to
mm). physical injury.

ALUMINUM CONDUIT OUTLET AND DEVICE BOXES
- being even lighter than EMT - galvanized stamped sheet metal.
- aluminum has better corrosion resistance - used in buildings to protect electrical wiring
in most atmospheres; and hold devices like switches and outlets.
- it is nonmagnetic,
- giving a lower voltage drop;
- it is non sparking,
FLOOR RACEWAYS are supplied by a second set of
rectangular raceways called feeder ducts,
To bring the various electrical and communication usually laid at right angles to the
services to the user, in the absence of any sort of distribution ducts.
overall floor raceway system, the installing
contractor has one of four choices: - single-level underfloor duct system, the
distribution and feeder ducts are on the
1. Channel the floor and install a conduit in the same level, and the interwiring between
channel, connecting it to the nearest wall outlet. them is accomplished in junction boxes.
Patch the chased portion of the floor.
- labor intensive - Because the initial cost of a full underfloor
system is high, an alternative arrangement
2. Install a surface floor raceway. The usefulness of utilizes only feeder ducts
this technique is very limited because it presents a
tripping hazard and problems with routine floor - A two-level underfloor duct system is
cleaning. essentially the same as a single-level
- unsightly and presents a safety hazard system except that the distribution ducts
and feeder ducts are on different levels.
3. Drill through the floor twice and connect the new
outlet to a nearby existing floor or wall outlet via a
conduit on the underside of the floor slab. Floor Underfloor ducts may be cast into the structural slab
penetrations must be fireproof. in lieu of being installed in fill or topping, but the
- disturb the occupants below, slab must be designed to accommodate them. The
use of a fill or topping on the structural slab for an
4. Drill through the floor and run a conduit in or on underfloor duct installation has these advantages:
the ceiling below. When using this technique,
special poke-through fittings are available that 1. Ducts can be run in any direction, without conflict
restore the fire rating of the slab with structural elements.
- disturb the occupants below. 2. Finishing is simplified.
3. Coordination is simplified.
4. Formwork and construction sequence are
The NEC recognizes three types of in-floor simplified.
raceways:
The disadvantages are:
Underfloor raceways—Article 354 1. Additional concrete increases costs directly by
Cellular metal floor raceways—Article 356 increasing the weight of the structure. This is
Cellular concrete floor raceways—Article 358 particularly expensive in seismic designs.
2. The building height may be increased.
All three types are applicable to all types of
structures, and none may be used in corrosive or
hazardous areas. The fundamental difference
between them is that underfloor raceways are
added on to the structure, whereas cellular floor CELLULAR METAL FLOOR RACEWAY
raceways are part of the structure itself—and
therefore have a pronounced effect on architectural The underfloor duct system described previously
coordination. is best applied to rectilinear arrangements. More
free-flowing arrangements, such as those found in
UNDERFLOOR DUCT office landscaping layouts, require a fully accessible
- simply an arrangement of parallel floor—if the floor is to be used for electrification.
rectangular metal or heavy plastic This may be provided by a cellular (metal) floor that
raceways laid on the structural slab and is an integrated structural/electrical system. The
covered with concrete fill. floor can be partially or completely electrified.

- Access to the wiring in these distribution Three types of wiring systems generally run in
ducts is via inserts that connect to separate floor cells and header ducts.
openings in the ducts and terminate in 1. electric power,
floor fittings for both power and signal/data 2. data-transmission wiring,
wiring. Cable feeds to the distribution ducts 3. telephone and signal systems
PRECAST CELLULAR CONCRETE
FLOOR RACEWAYS
- large capacity, versatility in that each cell is a
potential raceway, and flexibility in outlet placement
and movement.
- A cell is defined in NEC Article 358 as a “single,
enclosed, tubular space in a floor made of precast
cellular concrete slabs, the direction of the cell
being parallel to the direction of the floor member.”

FULL-ACCESS FLOOR
- applicable to spaces with very heavy
cabling requirements, particularly if
frequent recabling and reconnection are
required.
- developed for data-processing areas that
require large, fully accessible cable spaces
and large quantities of conditioned air.

UNDER-CARPET WIRING SYSTEM
- this system, which is covered in NEC
Article 328, was originally developed as
both an inexpensive alternative to an
underfloor or cellular floor system and as a
means for providing a flexible floor-level
branch circuit wiring system.

- Essentially, the system consists of a
factory-assembled flat cable (NEC type
FCC), approved for floor installation only
under carpet squares, plus the accessories
necessary for connection to 120-V power
outlets

CEILING RACEWAYS AND
MANUFACTURED WIRING SYSTEMS
- These systems are actually more flexible
than their underfloor counterparts because
they energize lighting, provide power and
telephone facilities, and even supply
outlets for the floor above,
- in addition to permitting very rapid layout
changes at low cost.
- The hung ceiling must consist of lift-out
panels because this type of wiring system
is not permitted in spaces rendered
inaccessible by the building structure.