three phase circuit - GTU e
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Transcript three phase circuit - GTU e
S.P.B.Patel Engineering College,Mehsana
Electrical Department
• Student Name:-1.Shah Yash J.
2.Jibsonjacob
3.Deep Ajay P.
4.Lakhani Raja A.
5.Ajmeri Arifhusen A.
• Faculty Name:- Snehal V.Malvi
THREE PHASE
CIRCUIT
Objectives
• Explain the differences between singlephase, two-phase and three-phase.
• Compute and define the Balanced ThreePhase voltages.
• Determine the phase and line
voltages/currents for Three-Phase
systems.
SINGLE PHASE TWO WIRE
V p
SINGLE PHASE SYSTEM
• A generator connected through a pair
of wire to a load – Single Phase Two
Wire.
• Vp is the magnitude of the source
voltage, and is the phase.
SINLGE PHASE THREE WIRE
V p
V p
SINGLE PHASE SYSTEM
• Most common in practice: two
identical sources connected to two
loads by two outer wires and the
neutral: Single Phase Three Wire.
• Terminal voltages have same
magnitude and the same phase.
POLYPHASE SYSTEM
• Circuit or system in which AC
sources operate at the same
frequency but different phases
are known as polyphase.
TWO PHASE SYSTEM THREE WIRE
V p
V p 90
POLYPHASE SYSTEM
• Two Phase System:
– A generator consists of two coils placed
perpendicular to each other
– The voltage generated by one lags the
other by 90.
POLYPHASE SYSTEM
• Three Phase System:
– A generator consists of three coils placed
120 apart.
– The voltage generated are equal in
magnitude but, out of phase by 120.
• Three phase is the most economical
polyphase system.
THREE PHASE FOUR WIRE
IMPORTANCE OF THREE PHASE SYSTEM
• All electric power is generated and
distributed in three phase.
– One phase, two phase, or more than
three phase input can be taken from
three phase system rather than
generated independently.
– Melting purposes need 48 phases
supply.
IMPORTANCE OF THREE PHASE SYSTEM
• Uniform power transmission and less
vibration of three phase machines.
– The instantaneous power in a 3 system
can be constant (not pulsating).
– High power motors prefer a steady
torque especially one created by a
rotating magnetic field.
IMPORTANCE OF THREE PHASE SYSTEM
• Three phase system is more
economical than the single phase.
– The amount of wire required for a three
phase system is less than required for an
equivalent single phase system.
– Conductor: Copper, Aluminum, etc
THREE PHASE GENERATION
FARADAYS LAW
•
Three things must be present in
order to produce electrical current:
a) Magnetic field
b) Conductor
c) Relative motion
•
•
Conductor cuts lines of magnetic
flux, a voltage is induced in the
conductor
Direction and Speed are important
GENERATING A SINGLE PHASE
S
N
Motion is parallel to the flux.
No voltage is induced.
GENERATING A SINGLE PHASE
S
N
Motion is 45 to flux.
Induced voltage is 0.707 of maximum.
GENERATING A SINGLE PHASE
S
x
N
Motion is perpendicular to flux.
Induced voltage is maximum.
GENERATING A SINGLE PHASE
S
N
Motion is 45 to flux.
Induced voltage is 0.707 of maximum.
GENERATING A SINGLE PHASE
S
N
Motion is parallel to flux.
No voltage is induced.
GENERATING A SINGLE PHASE
S
N
Notice current in the
conductor has reversed.
Motion is 45 to flux.
Induced voltage is
0.707 of maximum.
GENERATING A SINGLE PHASE
S
N
Motion is perpendicular to flux.
Induced voltage is maximum.
GENERATING A SINGLE PHASE
S
N
Motion is 45 to flux.
Induced voltage is 0.707 of maximum.
GENERATING A SINGLE PHASE
S
N
Motion is parallel to flux.
No voltage is induced.
Ready to produce another cycle.
THREE PHASE GENERATOR
GENERATOR WORK
• The generator consists of a rotating
magnet (rotor) surrounded by a
stationary winding (stator).
• Three separate windings or coils with
terminals a-a’, b-b’, and c-c’ are
physically placed 120 apart around
the stator.
• As the rotor rotates, its magnetic field
cuts the flux from the three coils and
induces voltages in the coils.
• The induced voltage have equal
magnitude but out of phase by 120.
GENERATION OF THREE-PHASE AC
S
x
x
N
THREE-PHASE WAVEFORM
Phase 1
120
Phase 2
Phase 3
120
120
240
Phase 2 lags phase 1 by 120.
Phase 3 lags phase 1 by 240.
Phase 2 leads phase 3 by 120.
Phase 1 leads phase 3 by 240.
GENERATION OF 3 VOLTAGES
Phase 1Phase 2 Phase 3
S
x
Phase 1 is ready to go positive.
Phase 2 is going more negative.
Phase 3 is going less positive.
x
N
THREE PHASE QUANTITIES
BALANCED 3 VOLTAGES
• Balanced three phase voltages:
– same magnitude (VM )
– 120 phase shift
v an (t ) VM cos t
vbn (t ) VM cos t 120
vcn (t ) VM cos t 240 VM cos t 120
BALANCED 3 CURRENTS
• Balanced three phase currents:
– same magnitude (IM )
– 120 phase shift
ia (t ) I M cos t
ib (t ) I M cos t 120
ic (t ) I M cos t 240
PHASE SEQUENCE
van (t ) VM cos t
vbn (t ) VM cost 120
vcn (t ) VM cost 120
Van VM 0
Van VM 0
Vbn VM 120
Vbn VM 120
Vcn VM 120
Vcn VM 120
POSITIVE
SEQUENCE
NEGATIVE
SEQUENCE
PHASE SEQUENCE
EXAMPLE # 1
• Determine the phase sequence of
the set voltages:
van 200 cost 10
vbn 200 cost 230
vcn 200 cost 110
BALANCED VOLTAGE AND LOAD
• Balanced Phase Voltage: all phase
voltages are equal in magnitude and
are out of phase with each other by
120.
• Balanced Load: the phase
impedances are equal in magnitude
and in phase.
THREE PHASE CIRCUIT
• POWER
– The instantaneous power is constant
p(t ) pa (t ) pb (t ) pc (t )
VM I M
3
cos
2
3Vrms I rms cos( )
THREE PHASE CIRCUIT
• Three Phase Power,
S T S A S B S C 3 S
THREE PHASE QUANTITIES
QUANTITY
SYMBOL
Phase current
I
Line current
IL
Phase voltage
V
Line voltage
VL
PHASE VOLTAGES and LINE VOLTAGES
• Phase voltage is measured between
the neutral and any line: line to
neutral voltage
• Line voltage is measured between any
two of the three lines: line to line
voltage.
PHASE CURRENTS and LINE CURRENTS
• Line current (IL) is the current in
each line of the source or load.
• Phase current (I) is the current in
each phase of the source or load.
THREE PHASE CONNECTION
SOURCE-LOAD CONNECTION
SOURCE
LOAD
CONNECTION
Wye
Wye
Y-Y
Wye
Delta
Y-
Delta
Delta
-
Delta
Wye
-Y
SOURCE-LOAD CONNECTION
• Common connection of source: WYE
– Delta connected sources: the
circulating current may result in the
delta mesh if the three phase voltages
are slightly unbalanced.
• Common connection of load: DELTA
– Wye connected load: neutral line may
not be accessible, load can not be
added or removed easily.
WYE CONNECTION
WYE CONNECTED GENERATOR
Ia
a
Van
Vab
n
Vbn
Ib
Vca
b
Vcn
Vbc
Ic
c
WYE CONNECTED LOAD
a
a
Y
Z
ZY
b
OR
b
Load
ZY
c
n
c
n
ZY
ZY
ZY
Load
BALANCED Y-Y CONNECTION
PHASE CURRENTS AND LINE CURRENTS
• In Y-Y system:
IL Iφ
PHASE VOLTAGES, V
• Phase voltage is
measured between
the neutral and any
line: line to neutral
voltage
Ia
a
VVanan
n
VVbnbn
Vab
Ib
Vca
b
VVcn
cn
Vbc
Ic
c
PHASE VOLTAGES, V
Van VM 0
volt
Vbn VM 120 volt
Vcn VM 120
volt
LINE VOLTAGES, VL
Ia
• Line voltage is
measured between
any two of the three
lines: line to line
voltage.
a
Van
V
Vab
ab
n
Vbn
Ib
b
Vcn
V
V bc
bc
Ic
c
VVca
ca
LINE VOLTAGES, VL
Vab Van Vbn
Vbc Vbn Vcn
Vca Vcn Van
Vab 3VM 30
Vbc 3VM 90
Vca 3VM 150
Van VM 0
volt
Vbn VM 120 volt
Vcn VM 120 volt
LINE
VOLTAGE
(VL)
PHASE
VOLTAGE (V)
Vab 3 VM 30 volt
Vbc 3 VM 90 volt
Vca 3 VM 150 volt
PHASE DIAGRAM OF VL AND V
Vca
Vcn
Vab
30°
120°
Vbn
Vbc
-Vbn
Van
PROPERTIES OF PHASE VOLTAGE
• All phase voltages have the same
magnitude,
= V
=
V Van
bn Vcn
• Out of phase with each other by 120
PROPERTIES OF LINE VOLTAGE
• All line voltages have the same
magnitude,
= V
=
VL Vab
bc Vca
• Out of phase with each other by 120
RELATIONSHIP BETWEEN V and VL
1. Magnitude
VL 3 V
2. Phase
- VL LEAD their corresponding V by 30
VL V 30
EXAMPLE 1
• Calculate the line currents
DELTA CONNECTION
DELTA CONNECTED SOURCES
DELTA CONNECTED LOAD
OR
BALANCED - CONNECTION
PHASE VOLTAGE AND LINE VOLTAGE
• In - system, line voltages equal to
phase voltages:
VL Vφ
PHASE VOLTAGE, V
• Phase voltages are equal to the
voltages across the load impedances.
PHASE CURRENTS, I
• The phase currents are obtained:
VBC
VCA
VAB
I AB
, I BC
, I CA
ZΔ
ZΔ
ZΔ
LINE CURRENTS, IL
• The line currents are obtained from the
phase currents by applying KCL at
nodes A,B, and C.
LINE CURRENTS, IL
I a I AB I CA
I b I BC I AB
I c I CA I BC
I a 3 I AB 30
I b I a 120
I c I a 120
PHASE
CURRENTS (I)
I AB
I BC
I CA
VAB
ZΔ
VBC
ZΔ
VCA
ZΔ
LINE CURRENTS (IL)
I a 3 I AB 30
I b I a 120
I c I a 120
PHASE DIAGRAM OF IL AND I
PROPERTIES OF PHASE CURRENT
• All phase currents have the same
magnitude,
Iφ I AB I BC ICA
Vφ
ZΔ
• Out of phase with each other by 120
PROPERTIES OF LINE CURRENT
• All line currents have the same
magnitude,
I L Ia I b Ic
• Out of phase with each other by 120
RELATIONSHIP BETWEEN I and IL
1. Magnitude
I L 3 I
2. Phase
- IL LAG their corresponding I by 30
I L I 30
EXAMPLE
A balanced delta connected load having
an impedance 20-j15 is connected to
a delta connected, positive sequence
generator having Vab = 3300 V.
Calculate the phase currents of the load
and the line currents.
Given Quantities
ZΔ 20 j15 25 36.87
Vab 3300
Phase Currents
VAB
3300
I AB
13.236.87A
ZΔ
25 36.87
I BC I AB 120 13.2 - 83.13A
I CA I AB 120 13.2156.87A
Line Currents
I a I AB 3 30
13.236.87 3 30 A
22.866.87
I b I a 120 22.86 - 113.13A
I c I a 120 22.86126.87A
BALANCED WYE-DELTASYSTEM
EXAMPLE 2
A balanced positive sequence Yconnected source with Van=10010 V
is connected to a -connected
balanced load (8+j4) per phase.
Calculate the phase and line currents.
THREE PHASE POWER
MEASUREMENT
EXAMPLE 3
Determine the total power (P), reactive
power (Q), and complex power (S) at the
source and at the load
EXAMPLE #4
A three phase motor can be
regarded as a balanced Y-load. A
three phase motor draws 5.6 kW
when the line voltage is 220 V and
the line current is 18.2 A. Determine
the power factor of the motor
THANK YOU