Basic Electrical Theory.ppt
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About This Presentation
bASIC eLECTRIC THEORY
Slide Content
BASIC ELECTRICAL THEORY
By: Engr. Salman Hameed
By: Engr. Salman Hameed
Charge
The Starting Point: Elements,
Atoms and Charge
Atoms and Charge
Charge
•Charge
–Force that causes two particles to be attracted
to, or repelled from, each other.
–Two types –positive and negative
–Atom –proton (positive), electron (negative),
neutron (electrically neutral)
•Charge
–Force that causes two particles to be attracted
to, or repelled from, each other.
–Two types –positive and negative
–Atom –proton (positive), electron (negative),
neutron (electrically neutral)
•Attraction and Repulsion -Like charges repel
each other and opposite charges attract each other
•Ions
–Outside force can cause an electron to leave its
orbit -atom is referred to as a positive ion
–Outside force can cause an atom to gain an
electron -atom is referred to as a negative ion
•Free Electrons
–An electron that is not bound to any particular
atom
–Can neutralize a positive ion
each other and opposite charges attract each other
•Ions
–Outside force can cause an electron to leave its
orbit -atom is referred to as a positive ion
–Outside force can cause an atom to gain an
electron -atom is referred to as a negative ion
•Free Electrons
–An electron that is not bound to any particular
atom
–Can neutralize a positive ion
Current
Current
•Current –the directed flow of charge
through a conductor
–Thermal energy (heat) is sufficient to free
electrons in copper
–Free electron motion is random unless outside
force is applied
•Current –the directed flow of charge
through a conductor
–Thermal energy (heat) is sufficient to free
electrons in copper
–Free electron motion is random unless outside
force is applied
Current
•Represented by the letter i (for intensity)
•Measured in charge per unit time
•Represented by the letter i (for intensity)
•Measured in charge per unit time
Current
•Coulomb (C) –represents the total charge of
approximately 6.25 x 10
18
electrons
•Unit of Current –Ampere (A) = 1
coulomb/second
•Example: 3 coulombs of charge pass a point in a
wire every two seconds. Calculate current.A 1.5C/s 1.5
s 2
C 3
t
Q
I
•Coulomb (C) –represents the total charge of
approximately 6.25 x 10
18
electrons
•Unit of Current –Ampere (A) = 1
coulomb/second
•Example: 3 coulombs of charge pass a point in a
wire every two seconds. Calculate current.A 1.5C/s 1.5
s 2
C 3
t
Q
I
Electrical Current
Electricalcurrentisthetimerateofflowof
electricalchargethroughaconductoror
circuitelement.Theunitsareamperes(A),
whichareequivalenttocoulombsper
second(C/s).
Electricalcurrentisthetimerateofflowof
electricalchargethroughaconductoror
circuitelement.Theunitsareamperes(A),
whichareequivalenttocoulombsper
second(C/s).
Electrical Current
Electrical Current
•Electron Flow Versus Conventional Current
Insert Figure 1.10
•Electron Flow Versus Conventional Current
Insert Figure 1.10
Direct Current
Alternating Current
When a current is constant with time, we
say that we have direct current,
abbreviated as dc. On the other hand, a
current that varies with time, reversing
direction periodically, is called alternating
current, abbreviated as ac.
Alternating Current
When a current is constant with time, we
say that we have direct current,
abbreviated as dc. On the other hand, a
current that varies with time, reversing
direction periodically, is called alternating
current, abbreviated as ac.
.
Figure 4.17,
4.18
Different Wave Forms
4.18
Different Wave Forms
Current
Insert Figure 1.11
Insert Figure 1.11
Voltage
Voltage
The voltageassociated with a circuit element is the
energy transferred per unit of charge that flows
through the element. The units of voltage are
volts (V), which are equivalent to joules per
coulomb (J/C).
(OR) Pressure required for the flow of electrons.
The voltageassociated with a circuit element is the
energy transferred per unit of charge that flows
through the element. The units of voltage are
volts (V), which are equivalent to joules per
coulomb (J/C).
(OR) Pressure required for the flow of electrons.
Voltage
•Voltage –a “difference of potential” that
generates the directed flow of charge
(current) through a circuit
Insert Figure 1.12
•Voltage –a “difference of potential” that
generates the directed flow of charge
(current) through a circuit
Insert Figure 1.12
Voltage
•Often referred to as electromotive force
(emf)
•Unit of Voltage –volt (V) = 1
joule/coulomb
•Volt –the difference of potential that uses
one joule of energy to move one coulomb of
charge.
•Often referred to as electromotive force
(emf)
•Unit of Voltage –volt (V) = 1
joule/coulomb
•Volt –the difference of potential that uses
one joule of energy to move one coulomb of
charge.
Various representations of an electrical system
Ohm’s Law and Power
Ohm’s Law
•German Physicist –George Simon Ohm
–Found that current is inversely proportional to
resistance for a given voltage
–Known as Ohm’s law
•The Relationship Between Current and Voltage
•The Relationship Between Current and Resistance
•German Physicist –George Simon Ohm
–Found that current is inversely proportional to
resistance for a given voltage
–Known as Ohm’s law
•The Relationship Between Current and Voltage
•The Relationship Between Current and Resistance
Basic Circuit Calculations
•Using Ohm’s Law to Calculate Current
where
R= the circuit resistance
V= the applied voltageR
V
I
•Using Ohm’s Law to Calculate Current
where
R= the circuit resistance
V= the applied voltageR
V
I
Resistance Element
Power
•Power –the amount of energy used per unit
time
•Unit of Power –Watt (W) = 1 joule/second
•Calculating Power
where
P= the power used, in watts (W)
V= the applied voltage, in volts (V)
I= the generated current, in amperes (A)
P = IV
•Power –the amount of energy used per unit
time
•Unit of Power –Watt (W) = 1 joule/second
•Calculating Power
where
P= the power used, in watts (W)
V= the applied voltage, in volts (V)
I= the generated current, in amperes (A)
P = IV
Power
•Other Power Equations
–Use IRin place of V
–Use V/Rin place of IRIIIRVIP
2
R
V
R
V
VVIP
2
•Other Power Equations
–Use IRin place of V
–Use V/Rin place of IRIIIRVIP
2
R
V
R
V
VVIP
2
Power
•Power and Heat
–Resistors and other components convert energy
to heat (transducer)
–If power rating is exceeded, the component will
keep getting hotter and be destroyed
–Common guideline –select a component with
twice the required power-dissipation capability
•Power and Heat
–Resistors and other components convert energy
to heat (transducer)
–If power rating is exceeded, the component will
keep getting hotter and be destroyed
–Common guideline –select a component with
twice the required power-dissipation capability
Power
•Efficiency –the ratio of a circuit or
components output power to its input power
where
= the efficiency, as a percentage
P
o= the output power
P
i= the input power100
i
o
P
P
•Efficiency –the ratio of a circuit or
components output power to its input power
where
= the efficiency, as a percentage
P
o= the output power
P
i= the input power100
i
o
P
P
Circuit Fundamental
•Circuit Loads
–Source –supplies the power
–Load –absorbs (uses) the power
–Full Load –one that draws the maximum
current
–Source –supplies the power
–Load –absorbs (uses) the power
–Full Load –one that draws the maximum
current
A Circuit
•Current flows from the higher voltage terminal of the source
into the higher voltage terminal of the transducer before
returning to the source
+
Source
Voltage
-
I
+ Transducer -
Voltage
The source expends
energy & the transducer
converts it into
something useful
I
•Current flows from the higher voltage terminal of the source
into the higher voltage terminal of the transducer before
returning to the source
+
Source
Voltage
-
I
+ Transducer -
Voltage
The source expends
energy & the transducer
converts it into
something useful
I
Three-Phase Systems
•So far, our discussion of AC systems has been
restricted to single-phasearrangement
–as in conventional domestic supplies
•In high-power industrial applications we often
use three-phasearrangements
–these have three supplies, differing in phase by 120
–phases are labeled red, yellowand blue(R, Y& B)
•So far, our discussion of AC systems has been
restricted to single-phasearrangement
–as in conventional domestic supplies
•In high-power industrial applications we often
use three-phasearrangements
–these have three supplies, differing in phase by 120
–phases are labeled red, yellowand blue(R, Y& B)
•Relationship between the phases in a three-
phase arrangement
phase arrangement
•Three-phase arrangements may use either 3 or 4
conductors
conductors
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