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EEE Dept, BVRIT. Electrical Engineering Lab
Padmasri Dr B V Raju Institute of Technology
Narsapur, Medak (Dt)-502313.
Electrical Engineering Laboratory Manual
II B.Tech II-Sem (ECE)
2011-2012
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Instructions to the students to conduct an experiment:
1. Students are supposed to come to the lab with preparation, proper dress code and the set of tools required (1. Cutter, 2. Tester (small size), 3. Plier (6-Inches)).
2. Dress code:
Boys: Shoe & Tuck.
Girls: Apron & Cut shoe.
3. Don’t switch on the power supply without getting your circuit connections verified.
4. Disciplinary action can be taken in the event of mishandling the equipment or switching on the power supply without faculty presence.
5. All the apparatus taken should be returned to the Lab Assistant concerned, before leaving the lab.
6. You have to get both your Observation book and your Record for a particular experiment corrected well before coming to the next experiment.
Guidelines to write your Observation book:
1. Experiment title, Aim, Apparatus, Procedure should be right side.
2. Circuit diagrams, Model graphs, Observations table, Calculations table should be left side.
3. Theoretical and model calculations can be any side as per convenience.
4. Result should always be at the end (i.e. there should be nothing written related to an experiment after its result).
5. You have to write the information for all the experiments in your observation book.
6. You are advised to leave sufficient no of pages between successive experiments in your observation book for the purpose of theoretical and model calculations.
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EEE Dept, BVRIT. Electrical Engineering Lab
ELECTRICAL ENGINEERING LAB
II B.Tech II SEM ECE (A&B) 2011-2012
List of Experiments
1. Verification of KCL & KVL.
2. Series & Parallel resonance-Timing, Resonant frequency, Bandwidth and Q-factor
determination for RLC network.
3. Time response of first order RC/RL network for periodic non sinusoidal input-Time constant
and steady state error determination.
4. Two port network parameters-Z, Y, ABCD and h-Parameters.
5. Verification of Superposition and Reciprocity theorems.
6. Verification of Maximum Power Transfer theorem.
7. Experimental verification of Thevenin’s and Norton’s theorems.
8. Magnetization characteristics of D.C. Shunt Generator.
9. Swinburne’s Test on a DC Shunt Motor.
10. Brake test on DC a Shunt Motor.
11 O C & SC Tests on a 1-φ Transformer.
12. Load test on a 1- φTransformer.
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Expt No: 1
Verification of KVL and KCL.
Aim: To verify Kirchhoff’s Voltage Law and and Kirchhoff’s Current Law theoretically and practically.
Apparatus:
S.No Name of the equipment Range Type Quantity
1. Voltmeters
2. Ammeters
3. Multimeter
4. Connecting wires as per need
Theory:
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EEE Dept, BVRIT. Electrical Engineering Lab
_
+
_+
Fig-1
VS +
−
V1
V_
+ V
_+
V
V
V2 V3
VS
_ +
Fig-2
VS +
−
A
I
I1 _
+A
_+
A
I2
Circuit Diagram of KVL:
Circuit Diagram of KCL:
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Procedure:
1. To verify KVL, Connections are made as shown in the Fig-1
2. Supply is given to the circuit and the readings of the voltmeters are noted down.
3. Kirchhoff’s Voltage law can be verified by Vs=V1+V2+V3.
4. To verify KCL, Connections are made as shown in the Fig-2.
5. Supply is given to the circuit and the readings of the Ammeters are noted down.
6. Kirchhoff’s Current law can be verified by I=I1+I2.
Theoretical Calculations:
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Observations Table:
Vs V1 V2 V3 V1+V2+V3 I I1 I2 I1 +I2
Theoretical Values
Practical Values
Precautions:
1. Making loose connections are to be avoided.
2. Readings should be taken carefully without parallax error.
Result:
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Expt. No: 2
Series and Parallel resonance Aim: To verify Resonant Frequency, Bandwidth & Quality factor of RLC Series and Parallel Resonant circuits. Apparatus: S.No Name of the equipment Range Type Quantity
1. Multimeter
2. Series and parallel resonance kit
3. Connecting wires as per need Theory: Theoretical Calculations: Formulae Required. Series Resonance:
1. Resonant frequency, LC2π
1fo =
2. Quality factor, R
Lf2R
XQ oL π==
3. Bandwidth, QfBW o=
Parallel Resonance:
1. Resonant frequency, 2
2
o1
21f
LR
LC−=
π
2. Quality factor, Lf2
RXRQ
oL π==
3. Bandwidth, QfBW o=
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Procedure: Series Resonance:
1. Circuit is connected as shown in the fig (1).
2. A fixed voltage is applied to the circuit through function generator.
3. The frequency is varied in steps and the corresponding ammeter reading is noted down as Is.
4. A graph is drawn between frequency f and current Is. Resonant frequency (fo) and Half power
frequencies (f1, f2) are marked on the graph.
5. Bandwidth = (f2-f1.) & Quality factor are found from the graph.
6. Practical values of Resonant Frequency, Q-factor and Bandwidth are compared with theoretical
values.
Parallel Resonance: 1. Circuit is connected as shown in the fig (2)
2. A fixed voltage is applied to the circuit through function generator.
3. The frequency is varied in steps and the corresponding ammeter reading is noted down as Ip.
4. A graph is drawn between frequency f and current Ip. Resonant Frequency (fo) and Half power
frequencies (f1, f2) are marked on the graph.
5. Bandwidth = (f2-f1.) & Quality factor are found from the graph.
6. Practical values of Resonant Frequency, Q-factor and Bandwidth are compared with theoretical
values.
BWfQ 0=
BWfQ 0=
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fof1
maxI
f
2maxI
f2
IS
Circuit Diagram of Series Resonance:
Model Graph:
A Is Function generator
Fig-1
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Circuit Diagram of Parallel Resonance:
Model Graph:
fo
IP
f f1
minI
min2I
f2
A Ip
Fig-2
Function generator
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12
Observations:
Series Resonance Parallel Resonance
Result Table:
S.No. Frequency (f) Current(Is)
S.No. Frequency (f) Current(Ip)
Series Resonance Parallel Resonance
Theoretical Practical Theoretical Practical
Resonant frequency(f0)
Bandwidth(BW)
Quality factor(Q)
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Precautions:
1. Making loose connections are to be avoided.
2. Readings should be taken carefully without parallax error.
Result:
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15
Expt. No:3
Time response of Series RL and RC circuits Aim: To draw the time response of first order series RL and RC network for periodic Non- Sinusoidal function and verify the time constant. Apparatus: S.No Name of the equipment Range Type Quantity
1. Function generator 1
2. Decade Resistance box 1
3. Decade Inductance box 1
4. Decade Capacitance box 1
5. CRO 1
6. CRO probes 1
7. Connecting wires As required Theory: Theoretical Calculations: Formulae required:
For RL Series circuit, Time constant,RL
=τ
For RC Series circuit, Time constant, RCτ =
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16
Vin
VL
VC
t
t
t
Circuit diagrams:
Series RL Circuit
Series RC Circuit
Model Graph:
Function Generator
Fig-1
To CRO
Function Generator
Fig-2
To CRO
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Procedure:
Series RL Circuit:
1. Connections are made as shown in the fig-1.
2. Input voltage (Square wave) is set to a particular value.
3. The waveform of voltage across inductor is observed on CRO and the waveform is drawn on a graph sheet.
4. The time constant is found from the graph and verified with the theoretical value.
Series RC Circuit:
1. Connections are made as shown in the fig-2.
2. Input voltage (Square wave) is set to a particular value.
3. The waveform of voltage across the capacitor is observed on CRO and the waveform is drawn on a graph sheet.
4. The time constant is found from the graph and verified with the theoretical value.
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18
Result table:
Series RL Circuit Series RC Circuit
Theoretical Practical Theoretical Practical
Time Constant(τ)
Precautions:
1. Making loose connections are to be avoided.
2. Readings should be taken carefully without parallax error.
Result:
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19
Expt. No:4
Two port network parameters (Z, Y, ABCD and Hybrid parameters)
Aim: To obtain experimentally Z , Y, ABCD and h-parameters and of a given two port network. Apparatus: S.No Name of the equipment Range Type Quantity
1. Ammeter
2. Voltmeter
3. Rheostats
4. DC Power Supply 5. Digital Multimeter 6. Connecting wires as per need
Theory: Theoretical Calculations:
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Formulae required: Z-Parameters:
Y-Parameters:
ABCD Parameters:
Hybrid or h- Parameters:
02
222
02
112
01
221
01
111
11
22
;
;
==
==
==
==
II
II
IVZ
IVZ
IVZ
IVZ
2221212
2121111
IZIZVIZIZV
+=+=
2221212
2121111
VYVYIVYVYI
+=+=
02
222
02
112
01
221
01
111
11
22
;
;
==
==
==
==
VV
VV
VIY
VIY
VIY
VIY
221
221
DICVIBIAVV
−=−=
02
1
02
1
02
1
02
1
22
22
;
;
==
==
−=−=
==
VV
II
IID
IVB
VIC
VVA
2221212
2121111
VhIhIVhIhV
+=+=
02
222
02
112
01
221
01
111
11
22
;
;
==
==
==
==
II
VV
VIh
VVh
IIh
IVh
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21
+V1
⎯
+V2
⎯
Fig-1
+
V1 ⎯
V2
I1
A
V
+
_
+ _
Fig-2
+
V1 ⎯
I2
I1
A
A
+
_
+ _
V1 V2
I1 I2+ +
_ _
A Linear and Passive Network
CIRCUIT DIAGRAMS: When I2 = 0:
When V2 = 0:
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22
Fig-3
+
V1 ⎯V2
I2
A
V
+
_
+ _
Fig-4
+
I1 ⎯V2
I2
A
A
+
_
+_
When I1= 0: When V1= 0:
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Procedure: 1. Open Circuiting Output Terminals (I2 = 0):
a) Connections are made shown in fig (1).
b) Supply is given to input port.
c) The readings of ammeter as I1 and Voltmeter as V2 are noted down.
2. Short circuiting output terminals (V2 = 0):
a) Connections are made shown in fig (2).
b) Supply is given to input port.
c) The readings of ammeters as I1& I2 are noted down.
3. Open circuiting input terminals (I1 = 0):
a) Connections are made shown in fig (3).
b) Supply is given to output port.
c) The readings of ammeter as I1 and Voltmeter as V1 are noted down.
4. Short circuiting input terminals (V1=0):
a) Connections are made shown in fig (4).
b) Supply is given to output port.
c) The readings of ammeters as I1& I2 are noted down.
5. The Z, Y, ABCD, Hybrid parameters are calculated using formulae and verified with theoretical
values.
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Observations:
When I1=0 When I2=0
S.No. V1
I2
V2
When V1=0 When V2=0
S.No. I2
I1
V2
Result Table:
Z Parameters Y Parameters
Z11 Z12 Z21 Z22 Y11 Y12 Y21 Y22
Theoretical
Practical
S.No. V1
I1
V2
S.No. V1
I1
I2
ABCD Parameters Hybrid Parameters
A B C D h11 h12 h21 h22
Theoretical
Practical
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Precautions:
1. Making loose connections are to be avoided.
2. Readings should be taken carefully without parallax error.
Result:
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28
Expt No:5
Superposition theorem and Reciprocity theorems
Aim:To verify Superposition and Reciprocity theorems theoretically and practically.
Apparatus :
S.No Name of the equipment Range Type Quantity
1. Ammeter
2. Rheostats
3. DC Power Supply
4. Multimeter Digital
5. Connecting wires as per need
Theory:
Superposition Theorem Statement
In any linear bilateral network containing two or more energy sources the response at any
element is equal to the algebraic sum of the responses caused by the individual sources.
While considering the effect of individual sources, the other ideal voltage sources and ideal
current sources in the network are replaced by short circuit and open circuits respectively, across the
terminals. This theorem is valid only for linear systems.
Reciprocity Theorem Statement
In any linear bilateral network containing the response at any branch (or) transformation ratio is same even after interchanging the sources.i.e. V/ I1 = V/ I2
Theoretical Calculations:
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29
Procedure:
Superposition Theorem:
1. The circuit is connected as shown in fig (1).
2. Both the voltages V1 and V2 applied and the current through load resistor is noted as IX.
3. Supply voltage V2 is replaced with short circuit and V1 is applied as shown in fig (2) and the current through load resistor is noted down as IY.
4. Supply voltage V1 is replaced with short circuit and V2 applied as shown in fig (3) and the current through load resistor is noted down as IZ.
5. It can be verified that IX = IY + IZ theoretically and practically which proves Superposition theorem.
Reciprocity Theorem:
1. The circuit is connected as shown in fig (1).
2. The ammeter reading is noted down as I1.
3. Now the source and ammeter are interchanged as in fig (2).
4. The ammeter reading is noted down as I2..
5. It can be veried that Vs/ I1 = Vs/ I2 theoretically and practically which proves Reciprocity theorem.
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+
_
Fig-1
VS1 +
− VS2
IX
+
_ A
Fig-2
VS1 +
−
IY
+
_ A
+
_
Fig-3
VS2
IZ
+
_ A
−
Fig-1
VS +
I1
+
_ A
−
Fig-2
VS +
I2
+
_A
Circuit Diagrams of Superposition Theorem:
Circuit Diagrams of Reciprocity Theorem:
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31
Observations:
Superposition Theorem
When both the sources are acting: fig (1) When V1 source alone is acting: fig (2)
When V2 source alone is acting: fig (3)
Reciprocity Theorem:
Before interchanging the sources: fig (1)
After interchanging the sources: fig (2)
VS1 VS2
Theoretical
IX
Practical
IX
VS1 VS2
Theoretical
IY
Practical
IY
VS1 VS2
Theoretical
IZ
Practical
IZ
Vs
Theoretical values Practical values
I1 Vs/ I1 I1 Vs/ I1
Vs
Theoretical values Practical values
I2 Vs/ I2 I2 Vs/ I2
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Precautions:
1. Making loose connections are to be avoided.
2. Readings should be taken carefully without parallax error.
Result:
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33
Expt. No.6
Maximum power transfer theorem
Aim: To verify maximum power transfer theorem on DC with Resistive load theoretically and practically.
Apparatus :
S.No Name of the equipment Range Type Quantity 1. Ammeter
2. Voltmeter
3. Rheostats
4. DC Power Supply 5. Multimeter Digital 6. Double Pole Double Throw Switch 6. Connecting wires as per need
Theory: Theorem Statement It states that the maximum power is transferred from the source to the load, when the load
resistance is equal to the source resistance.
Theoretical Calculations: Formulae required:
TheoreticalthL
thL RR
VI+
=
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Fig-4
VS +
_
+ _A
IL
DMM RL
Fig-1
+
VS RL ⎯
Fig-2
DMM
Rth
Fig-3
+
VS ⎯
+
_ VthV
Circuit Diagrams:
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Fig-5
VS +
_
+ _A
IL
DMM RL
Model Graph:
RL RL corresponding to Pm
Pm
PL
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Procedure:
1. Connections are made as shown in fig (1).
2. RL is varied in steps and the reading of ammeter IL is noted down in each step.
3. The circuit is connected as shown in fig (2) and the effective resistance Rth is measured with
the help of digital multimeter.
4. Power delivered to load PL is calculated in each step.
5. A graph is drawn between PL Vs RL and RL corresponding to maximum power is found from
it.
6. It can be verified that RL corresponding to maximum power from the graph is equal to the Rth
(which is nothing but source resistance RS) which proves the maximum power transfer theorem.
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37
Observations:
Tabular column:
S.No
RL
Theoretical values
Practical values
thL
thL RR
VI+
= PL= IL2RL
IL
PL= IL
2RL
Model Calculations:
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Precautions:
1. Making loose connections are to be avoided.
2. Readings should be taken carefully without parallax error.
Result:
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Expt. No.7
Experimental verification of Thevenin’s & Norton’s theorems Aim: To verify Thevenin’s and Norton’s theorems theoretically and practically. Apparatus:
S.No Name of the equipment Range Type Quantity 1. Ammeter 2. Voltmeter
3. Rheostats
4. DC Power Supply 5. Digital Multimeter 6. Connecting wires as per need
Theory: Statement of Thevenin’s Theorem: Any two terminal linear bilateral network containing of energy sources and impedances can be
replaced with an equivalent circuit consisting of voltage source Vth in series with an impedance, Zth.,
where Vth is the open circuit voltage between the load terminals and Zth is the equivalent impedance
measured between the two terminals with all the energy sources replaced by their internal impedances.
Statement of Norton’s Theorem: Any two terminal linear bilateral network containing of energy sources and impedances can be
replaced with an equivalent circuit consisting of a Current source IN in parallel with an impedance, ZN.,
where IN is the short circuit current across the load terminals and ZN is the equivalent impedance
measured between the two terminals with all the energy sources replaced by their internal impedances.
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RL
Fig-1
+
_
IL
VS +
−
A
Fig-3
+
_ Vth
VS +
−
V
Fig-2
+
_
IN VS +
− A
Circuit Diagrams:
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Vth
Fig-5
+
−
Rth
RL
ILI
+
_ A
VS= 0
Fig-4
Rth DMM
IN
Fig-6
RN
RL
ILI
+
_ A
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Procedure:
1. Connections are made as per the circuit shown in fig (1). 2. DC voltage is applied to the circuit and the current IL flowing through the load is noted down.
3. Circuit is connected as shown in fig (2). DC voltage is applied the reading of Ammeter is noted
down as IN. 4. Circuit is connected as shown in fig (3). DC voltage is applied the reading of Voltmeter is
noted down as Vth. 5. The circuit is connected as shown in fig (4) and the effective resistance Rth / RN is measured
with the help of a multimeter. 6. Thevenin’s equivalent circuit is connected as shown in fig (5) and the ammeter reading is noted
down as IL1
.
7. Thevenin’s theorem can be verified by checking that the currents IL and IL1 are equal.
8. Norton’s equivalent circuit is connected as shown in fig (6) and the ammeter reading is noted
down as IL1
.
9. Norton’s theorem can be verified by checking that the currents IL and IL1 are equal.
Theoretical Calculations:
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Observations:
Thevenin’s Theorem:
Norton’s Theorem:
Precautions:
1. Making loose connections are to be avoided.
2. Readings should be taken carefully without parallax error.
Result:
Vs
Theoretical values
Practical values
IL
Vth Rth
IL1
IL
Vth Rth
IL1
Vs
Theoretical values
Practical values
IL
IN RN
IL1
IL
IN RN
IL1
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Expt No: 8
Magnetization Characteristics of DC Shunt Generator Aim: To conduct an experiment on a D.C Shunt Generator and draw the magnetization
characteristics (Open Circuit Characteristics or OCC) and to determine the Critical Field Resistance (RC) and Critical Speed (NC).
Apparatus: Name plate details:
Theory: Open circuit characteristics or magnetization curve is the graph between the generated emf (Eg) and field current (If) of a dc shunt generator. For field current is equal to zero there will be residual voltage of 10 to 12V because of the residual magnetism present in the machine .If this is absent then the machine can not build up voltage. To obtain residual magnetism the machine is separately excited by a dc source. We can get critical field resistance (RC) and critical speed (NC) from OCC.
Critical field resistance: It is the value of field rresistance above which the machine cannot build up emf. Critical speed: It is the speed below which the machine cannot build up emf.
S. No Apparatus Type Range Qty 1 Voltmeter M.C 0-500V 1
2 Ammeter M.C 0-2A 1
3 Rheostats Wire wound
400Ω/1.7A 1
4 Tachometer Digital - 1
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DPST Switch
(0-300)V MC
(0-2)A MC
− F
FF
V
+400Ω/ 1.7A
−
AA
F
M
FF
230 V DC
Supply
+ DPST Switch
Fuse
3 point starter
FL A
A
Fuse
AA
G
A−
A
+
−
DC Exciter
+
Circuit diagram:
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Procedure:
1. Connections are made as per the circuit diagram.
2. Motor is started with the help of Three Point starter and brought to its rated speed by varying
the field rheostat.
3. The Eg for If =0 is noted and the DPST switch on the DC Exciter side is closed.
4. The DC Exciter is varied in steps and the values of Field current (If) and corresponding
generated voltage (Eg) are noted down in each step, in both ascending and descending orders.
5. Average Eg is calculated from ascending and descending orders.
6. A graph is drawn between Eg & If. From the graph (OCC), Critical field resistance (RC) and
Critical (NC) speed are calculated.
Model Graph:
Q
A
C O
Eg (V)
If (A)
Rf
P
R
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Tabular column:
S.No
Field current
If (A)
Generated Voltage (Eg)
Average Eg (V)
Ascending order
Descending order
Calculations:
From the graph:
Critical field Resistance, OCOAR C =
Critical Speed, ratedC NPRPQN ×=
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Precautions:
1. Loose connections should be avoided.
2. Readings are taken without parallax error.
Result:
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Expt No : 9
Swinburne’s test
Aim: To perform no load test on a DC shunt motor and to predetermine the efficiencies of the machine acting both as a motor and as a generator.
Equipment:
S.No Apparatus Type Range Qty 1 Voltmeter MC 0-250V 1 2 Ammeter MC 0-5A 1 3 Ammeter MC 0-2A 1 4 Rheostats Wire wound 400Ω/1.7A 1
Wire wound 100Ω/5A 1 Name plate details: Theory:
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−
(0-2)A MC
400Ω/ 1.7A
−
AA
M
230 V DC
Supply
+DPST Switch
Fuse
A
A
(0-250)V MC
−
V
+
+
Circuit diagram:
Circuit diagram to find out Ra:
(0-250)V MC
(0-5)A MC
(0-2)A MC
L
−−
+ 400Ω/ 1.7A
−
AA
F M
FF
230 V DC
Supply
+ DPST Switch
Fuse
3 point starter
FA
A
A
+
A
V
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Procedure:
1. Connections as made as per the circuit diagram.
2. Field rheostat is kept in minimum position and the motor is started with the help of 3-Point starter,
and is brought to rated speed by adjusting field rheostat.
3. The readings of both ammeters and voltmeter are noted down.
4. The efficiencies of the machine both as a motor and as a generator are calculated.
5. Graphs are drawn between output Vs efficiency for the Machine acting as a generator and as a
motor.
Model Graph:
η (%)
Motor
Generator
O Output
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No-Load Test Observation table:
IL0 If V N
Calculations:
From No-Load Test:
== L0VIinput Load-No
=−= fL0 IIcurrent Armature Load-No
== aR2a0IlossCu Armature Load-No
=−=−= a2
a0L0C RIVIlossCuArmatureload-No inputload-No Wloss,Constant
=∴ C W
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Machine acting as Generator: V=230V, WC = , Ra= ,If = .
S.No
Voltage, V (Volts)
Load current, IL (A)
Output,
Lout VIP =
Current,Armature
fLa III +=
LossCuArmature
aR2aI
Loss,Total
a2
aCT RIWW +=
Input,
Toutin WPP +=
Efficiency (%),
100PPη
in
out ×=
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Machine acting as Motor: : V=230V, WC = , Ra= ,If = .
S.No
Voltage, V (Volts)
Load current, IL (A)
Input,
Lin VIP =
Current,Armature
fLa III −=
LossCuArmature
aR2aI
Loss,Total
a2
aCT RIWW +=
Output,
Tinout WPP −=
Efficiency (%),
100PPη
in
out ×=
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Model calculation:
To Predetermine the Efficiency as a Motor:
Let IL=
== LVIinputMotor
=+=+= a2
fLCa2
aC R)I-(IWRIWlossTotal
== loss Total-inputMotor OutputMotor
=×=∴ 100Input
Outputη,Efficiency
To Predetermine the Efficiency as a Generator:
Let IL=
== LVIOutput Generator
=++=+= a2
fLCa2
aC R)I(IWRIWlossTotal
=+= loss Totaloutput Generator Input Generator
=×=∴ 100Input
Outputη,Efficiency
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Precautions:
1. Loose connections should be avoided.
2. Readings are taken without parallax error.
Result:
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Expt No: 10
Brake test on a DC Shunt motor Aim: To conduct Brake test on a DC Shunt motor. And to draw its performance curves. Apparatus:
S. No Equipment Range Type Qty 1. Voltmeter 0-250V M.C. 1 2. Ammeter 0-20A M.C 1 3 Ammeter 0-1/2A M.C 1 4 Rheostat 400Ω/1.7A Wire wound 1 5. Tachometer Digital type 1 6. Connecting wires
Name plate details: Theory:
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Procedure:
1. Connections are made as shown in the circuit diagram.
2. Field rheostat is kept in minimum position and the motor is started with the help of 3-Point starter,
and is brought to rated speed by adjusting field rheostat.
3. By varying the load in steps, readings of ammeters, voltmeter, tachometer, spring balances, are
noted down.
4. Performance curves are to be drawn after completing the calculations.
Model graph:
N VS Torque
O
Ia VS N
Output VS η
Ia VS
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(0-2)A MC
−
L
(0-250)V MC
−
V
+ 400Ω/ 1.7A
−
AA
F M
FF
230 V DC
Supply
+ DPST Switch
Fuse
3 Point Starter
FA
A
A
(0-20)A MC
S1 S2
A
+
Circuit diagram:
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Calculations Table: r = .
S.No Voltage, V (Volts)
Line current, IL (A)
Speed, N (rpm)
Spring balance readings (Kgs)
S1 S2
Torque, T=9.81×( S1~ S2)×r
(N-m)
Output,
60NT2Pout
Π=
Input,
Lin VIP =
Efficiency (%),
100PPη
in
out ×=
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Model calculation:
Precautions:
1. Loose connections should be avoided.
2. Readings are taken without parallax error.
Result:
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Expt No: 11
OC & SC tests on 1-φ transformer
Aim: To conduct OC & SC tests on the given 1-Φ Transformer and to calculate its equivalent circuit
parameters and predetermine its Efficiency & Regulation.
Name plate details:
1-φ TRANSFORMER
Capacity 3KVA
I/P voltage 115V
I/P current 26A
O/P voltage 230V
O/P current 13A
Frequency 50Hz
Apparatus required:
S.No Apparatus Range Type Qty
1 Voltmeters 0-150V, 0-75V M.I 1, 1 No
2 Ammeters 0-2A, 0-15A M.I 1, No
3 Wattmeter 2A, 150V, 60W, LPF
15A, 50V, 600W, UPF
Dynamo meter
1, 1 No
4 Auto T/F 230V/0-270V 1-φ wire wound 1 No
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Output power
%Efficiency
Procedure:
OC Test:
1. Connections are done as per the circuit diagram.
2. Supply is switched on and rated voltage is applied to the LV side by varying the Auto
transformer.
3. The readings of Ammeter, Voltmeter & Wattmeter are noted down.
SC Test:
1. Connections are done as per the circuit diagram.
2. Supply is Switched on and rated current is set through the HV winding by varying
the Auto transformer.
3. The readings of Ammeter, Voltmeter & Wattmeter are noted down.
Model graphs:
Power factor
%Regulation
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(0-2)A MI
230V115V
(0-150)V MI
1- Φ 230V 50 Hz AC
Supply
Ph
N 1 Φ -Transformer 3KVA, 230V/ 115V
Open Circuit
DPST
Variac 3KVA, 230V/ (0-270)V
2A, 150V, 60W, LPF
L M
C V
Fig -1
V
A
OC test circuit diagram
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230V 115V (0-15)A MI
(0-50)V MI
1- Φ 230V 50 Hz AC
Supply
Ph
N1 Φ -Transformer 3KVA, 230V/ 115V
Short Circuit
DPST
Variac 3KVA, 230V/ (0-270)V
15A, 50V, 600W, UPF
L M
C
V
Fig -2
V
A
SC test circuit diagram
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Observations:
O.C test: S.C test:
Calculations:
==00
00 IV
WCosφ
== 00 φCosIIW
== 00 φSinIIm
==WI
VR 00
==m
m IVX 0
Note: The Transformer is taken as
step up Transformer.
== 202sc
sc
IWR
==sc
sc
IVZ02
V0 I0 W0
VSC ISC WSC
=−= 202
20202 RZX
===1
2
1
2
EE
NNK
== 202
01 KXX ; == 2
0201 K
RR
scscoi
sci
WxCu loss, WWIron losssWd currentf Full loaFraction oWhere, x
WWCosθIxVCosθIxVEfficency
2
222
222 100
====
=
×++
=
pfLoadCosWherepfLeadforpfLagfor
VSinθXICosθRIgulation%
=−+
×+
=
2
2
20222022
,),(
100Re
θ
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Calculations Table:
Predetermination of Efficiency:
I2= 13A ; V2= 230V ; R02= ; Wi= ; Let Cosθ2=0.8
Predetermination of Regulation:
I2= 13A ; V2= 230V ; R02= ; X02=
Load Cu losses
scCu WxW 2=
Total Losses
SCiT WWW +=
O/P power
222 θCosIxV=
I/P power
TWOutput +=
η (%)
100×=Input
Output
PP
x=0.1
¼Full load(x=0.25)
½ Full Load(x=0.5)
¾ Full Load(x=0.75)
Full Load(x=1)
Load pf % Regulation
lag lead
0.6
0.7
0.8
0.9
1
pfLoadCosθWherepfLeadforpfLagfor
VSinθXICosθRIgulation%
=−+
×+
=
,),(
100Re2
022022
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Equivalent Circuit:
Considering the Step up transformer and Referred to LV side.
Model Calculations:
Ro Xo
Ro1Xo1
Ph
N
Ph
N
V1
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Precautions:
1) The Dimmer stat should be kept at minimum O/P position initially.
2) In OC test, rated voltage should be applied to the Primary of the Transformer.
3) In SC test, the Dimmer stat should be varied up to the rated load current only.
4) The Dimmer stat should be varied slowly & uniformly.
Result:
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Expt No: 12
Load test on a 1-φ transformer
Aim: To conduct Load test on the given 1-Φ Transformer and to calculate its, Efficiency & Regulation.
Name plate details:
1-φ TRANSFORMER
Capacity 3KVA
I/P voltage 115V
I/P current 26A
O/P voltage 230V
O/P current 13A
Frequency 50Hz
Apparatus required:
S.No Apparatus Range Type Qty
1 Voltmeters 0-150V, 0-75V M.I 1, 1 No
2 Ammeters 0-2A, 0-15A M.I 1, No
3 Wattmeter 2A, 150V, 60W, LPF
15A, 50V, 600W, UPF
Dynamo meter
1, 1 No
4 Auto T/F 230V/0-270V 1-φ wire wound 1 No
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Procedure:
1. Connections are made as per the circuit diagram.
2. By varying the Auto transformer, rated voltage is applied to the input side of the
transformer and should be maintained constant throughout the experiment.
3. By varying the load in steps, readings of ammeter, voltmeter, and wattmeter are noted down in
each step.
4. Efficiency and Regulations are calculated in each step and tabulated.
5. Graphs are drawn Output Vs Efficiency and
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230V115V
(0-150)V MI
1- Φ 230V 50 Hz AC
Supply
Ph
N 1 Φ -Transformer 3KVA, 230V/ 115V
DPST
Variac 3KVA, 230V/ (0-270) V
20A, 150V, 60W, LPF
L M
C V
Fig -1
V
(0-15)A MI
A
(0-300)V MI
V
Circuit Diagram
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Calculations table: Rated Secondary Voltage, V2=230V
S.No Secondary Voltage Ι
2V (V)
Secondary Current, I2(A)
Input Power (Watts)(wattmeter reading)
Output Power =V2хI2 (Watts)
100
,
×=Input
Output
PP
Efficiency
η 100
Re%
2
22 ×−
=V
VV
gulationI
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Model calculation: Precautions:
1. The Dimmer stat should be kept at minimum O/P position initially.
2. Rated voltage should be maintained on the Primary of the Transformer.
3. The Dimmer stat should be varied slowly & uniformly.
Result:
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Important Viva-voce questions:
1. What is the principle of operation of a DC Generator?
2. What are the main parts of a DC Generator and their functions?
3. What is the function of a DC Generator?
4. What are the different types of a DC Generator?
5. What is the principle of operation of a DC Motor?
6. What is the function of a DC Motor?
7. What are the different types of a DC Motor?
8. What is the purpose of a Three point starter?
9. What is the purpose of a fuse?
10. Why the field rheostat should be kept in minimum position?
11. What is the purpose of changing the voltage level in AC Transmission?
12. What is the principle of operation of a Transformer?
13. What is the function of a Transformer?
14. What are the different types of a Transformer?
15. What are the different parts of a Transformer?
16. What are the different types of measuring instruments?
17. What is meant by “Pre determination” with respect to electrical machines?
18. What is meant by efficiency and regulation?
19. Can we start the motor without using three point starter? If so, how?
20. What is the purpose of Auto transformer(or Dimmerstat)?
Note: In addition to the above, students are supposed to know the basic theory and things related for
the conduct of a particular experiment.
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