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ELECTRICAL BASICS (Chapter 8)

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Title: ELECTRICAL BASICS (Chapter 8)


1
ELECTRICAL BASICS (Chapter 8)
  • Electrical terms
  • Electricity magnetism
  • Electricity
  • Circuits
  • Magnetism
  • Electrical units
  • Electric potential or eletromotive force
  • Electric current
  • Resistance
  • resistance of a conductor is affected by
    (additional information)
  • type of material
  • length directly proportional to the length of a
    conductor
  • cross-section area or thickness
  • temperature directly proportional to the
    temperature of a conductor
  • Electrical power
  • Energy (additional information)
  • The term energy is used to express work
  • Energy PowerTime
  • Unit of energy is kilowatt-hour (kWh)

2
ELECTRICAL BASICS
  • Calculations and examples
  • Ohm's Law (additional information)
  • Current (I or A), electric potential (V or E),
    and resistance (R) are related to each other, and
    a variance in one will affect the others. This
    relationship is known as Ohm's Law.
  • Current (I or A) is directly proportional to
    voltage (V or E)
  • Current (I or A) is inversely proportional to
    resistance (R)
  • Power formulas

3
GENERATION AND DISTRIBUTION (Chapter 9)
  • Power, work, and energy
  • Demand and consumption
  • Electric current DC or AC
  • Generating efficiency
  • Cogeneration

4
GENERATION AND DISTRIBUTION (Chapter 9)
  • Direct current (DC) (additional information)
  • In DC, electrons always move in the same
    direction
  • Polarity of the generator remains always the
    same.
  • Alternating current (AC) (additional information)
  • polarity of the generator or alternator reverses
    periodically
  • current varies periodically in value and
    directions, first flowing in one direction in the
    circuit and then flowing in the opposite
    direction
  • Generation of AC (additional information)
  • generated using a combination of physical motion
    and magnetism
  • simplest form of AC generator is constructed
    using a single loop of wire placed between the
    poles of a permanent magnet and then rotating it
    by some suitable mechanical means.
  • magnetic lines of force are interrupted with the
    rotation of loop
  • an electromagnetic force is induced in the loop
  • EMF thus produced exists between the two ends of
    the loop
  • slip rings and brushes attached to each end of
    the loop apply the generated EMF to an external
    circuit.

5
GENERATION AND DISTRIBUTION
  • How the current alternates (additional
    information)
  • When the loop is parallel to the magnetic lines
    of force, no magnetic flux is interrupted and no
    EMF is induced to the loop. As it begins to
    rotate, it cuts the magnetic flux at an
    increasing rate reaching a maximum when it has
    rotated a quarter turn (i.e. 90).
  • As the rotation continues, the EMF is still in
    the same direction but is decreasing in value. A
    half revolution (i.e. 180 ), the loop is again
    parallel to the magnetic lines and no magnetic
    flux is interrupted EMF at this point equals 0.
    As the rotation continues further, the sides of
    the loop reverse position and the induced EMF
    reverses polarity therefore, direction of the
    flow of current also reverses. The EMF increases
    to a maximum again at 3/4 turn (i.e. 270 ) and
    declines to 0 when the rotation is completed.
  • Cycle of AC (additional information)
  • Each complete rotation by the loop of wire (or
    armature coil) within the poles of magnet is
    called a cycle.
  • Frequency of AC (additional information)
  • The number of cycles per second is known as the
    frequency of the voltage or current
  • The unit used to measure this frequency is Hertz
  • In the United States, the frequency for
    alternating current is 60 Hertz.
  • Use of AC results in the reduction of
    transmission loss.

6
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7
GENERATION AND DISTRIBUTION (Chapter 9)
  • Example of transmission loss reduction
  • Watt Current2 x Resistance
  • If current (A or I) 20 and resistance (R) 4,
    then transmission loss (W) 202x4 1600
  • The loss can be reduced by decreasing R. If R
    were decreased by half to 2, then W 202x2 800
  • The loss can also be reduced by decreasing
    current. If it were decreased by half to 10,
    then W 102x4 400
  • It is obvious that if current is decreased by
    half, transmission loss would be reduced by a
    factor of 4.
  • In case AC, the stepping up and stepping down of
    current and voltage can be achieved by using a
    transformer.

8
GENERATION AND DISTRIBUTION (Chapter 9)
  • Single-phase and three-phase power
  • Single-phase (additional information)
  • a single armature coil creates a complete cycle
    of voltage and current
  • requires one 'hot' wire and a neutral wire
  • Three phase (additional information)
  • use of three separate coil conductors equally
    spaced (_at_ 120 ) around generator armature
  • in order to obtain the value of line voltage,
    phase voltage (either neutral-to-phase or
    phase-to-phase) has to be multiplied by ?3 or
    1.73 (e.g. if single-phase voltage is 208, then
    the corresponding three-phase voltage would be
    208 ?3 360)
  • a three-phase system with an Y-connection
    requires 3 'hot' wires and a neutral wire.

9
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10
GENERATION AND DISTRIBUTION (Chapter 9)
  • Transformers
  • Power distribution
  • Transformers (additional information)
  • Used for stepping up or stepping down voltages
    and current
  • Consists of iron core surrounded by two circuit
    loops (windings)
  • Capacity rated in kVA
  • Power factor (PF)
  • Grounding

11
ELECTRICAL RATING OF EQUIPMENT (Additional
information)
  • Voltage rating
  • Maximum voltage that can be safely applied
    continuously to an equipment. The rating is
    primarily determined by
  • Type and quantity of conductor insulation used
  • Physical spacing between electrically energized
    parts of the equipment
  • Current rating
  • Determined by the maximum operating temperature
    at which the components of an equipment can
    operate continuously and properly
  • maximum operating temperature is determined by
    the type of insulation of the conductor
  • the maximum safe operating temperature of
    conductors having cotton braid as insulation
    would be 65 C
  • Current which will be producing this temperature
    would be the maximum permissible current for the
    conductor
  • the maximum safe operating temperature of
    conductors having silicone or glass compound
    would be 150 C
  • Consequently, the maximum permissible temperature
    for the same conductor would increase
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