em-ii lab manual_1 (1).pdf

7/24/2019 EM-II Lab Manual_1 (1).pdf

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TAGORE ENGINEERING COLLEGE

EE-2305 ELECTRICAL MACHINES-II

LAB MANUAL

Anna University[Regulation 2008]

III / V SEMESTER

DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING


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INDEX

SL.NO DATE NAME OF EXPERIMENTDATE OF

SUBMISSIONMARKS

REMARKS

1Regulation of 3-phase alternatorby EMF and MMF methods.

2Regulation of 3-phase alternator

by ZPF and ASA methods.

3Regulations on 3-phase salient

pole alternator by Slip test.

4V and inverted V curve of

synchronous motors.

5Load test on 3-phase inductionmotor.

6No load and blocked rotor test

on 3-phase induction motor.

7Separation of losses in three-

phase induction motor.

8

Load test on 1-phase induction

motor.

9No load and blocked rotor test

on 1-phase induction motor.

10

Measurement of negative

sequence and zero sequence

impedance of alternator

Lab in charge Internal marks


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PREFACE

This Laboratory book in Electrical MachinesII has been revised in order to be up to date with

Curriculum changes, laboratory equipment upgrading and the latest circuit simulation.

Every effort has been made to correct all the known errors, but nobody is perfect, if you find any

Additional errors or anything else you think is an error, Please contact the HOD/EEE.

The Authors thanked all the staff members from the department for their valuable Suggestion and

Contribution


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TABLE OF CONTENTS

Safety Rules and operating Procedures

Laboratory Safety information

Guidelines for Laboratory Notebook

I

II

III

SI.NO Experiment Name Page No1. Regulation of 3-phase alternator by EMF and MMF methods.

2.

Regulation of 3-phase alternator by ZPF and ASA methods.

3. Regulations on 3-phase salient pole alternator by Slip test.

4. V and inverted V curve of synchronous motors.

5. Load test on 3-phase induction motor.

6. No load and blocked rotor test on 3-phase induction motor.

7. Separation of losses in three-phase induction motor.

8.

Load test on 1-phase induction motor.

9. No load and blocked rotor test on 1-phase induction motor.

10. Measurement of negative sequence and zero sequence

impedance of alternator

Appendix


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LABORATORY PRACTICE

SAFETY RULES

1. SAFETYis of paramount importance in the ElectricalEngineeringLaboratories.

2.Electricity NEVER EXECUSES careless persons. So, exercise enough care and attention in handling

electricalequipment and follow safetypractices in the laboratory. (Electricity is a good servant but a bad

master).

3.Avoid direct contact with any voltage source and power line voltages. (Otherwise, any such contact maysubject you to electricalshock)

4.Wear rubber-soled shoes. (To insulate you from earth so that even if you accidentally contact a livepoint, current will not flow through your body to earth and hence you will be protected from electrical

shock)

5.Wear laboratory-coat and avoid loose clothing. (Loose clothing may get caught on an

equipment/instrument and this may lead to an accident particularly if the equipment happens to be arotating machine)

6.Girl students should have their hair tucked under their coat or have it in a knot.

7.Do not wear any metallic rings, bangles, bracelets, wristwatches and neck chains. (When you move your

hand/body, such conducting items may create a short circuit or may touch a live point and thereby subjectyou to electricalshock)

8.Be certain that your hands are dry and that you are not standing on wet floor. (Wet parts of the bodyreduce the contact resistance thereby increasing the severity of the shock)

9.Ensure that the power is OFF before you start connecting up the circuit.(Otherwise you will be touchingthe live parts in the circuit)

10.Get your circuit diagram approved by the staff member and connect up the circuit strictly as per theapproved circuit diagram.

11.Check power chords for any sign of damage and be certain that the chords use safetyplugs and do notdefeat the safetyfeature of these plugs by using ungrounded plugs.

12.When using connection leads, check for any insulation damage in the leads and avoid such defective

leads.

13.Do not defeat any safetydevices such as fuse or circuit breaker by shorting across it. Safetydevices

protect YOU and your equipment.


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14.Switch on the power to your circuit and equipment only after getting them checked up and approved

by the staff member.

15.Take the measurement with one hand in your pocket. (To avoid shock in case you accidentally touch

two points at different potentials with your two hands)

16.Do not make any change in the connection without the approval of the staff member.

17.In case you notice any abnormal condition in your circuit ( like insulation heating up, resistor heating

up etc ), switch off the power to your circuit immediately and inform the staff member.

18.Keep hot soldering iron in the holder when not in use.

19.After completing the experiment show your readings to the staff member and switch off the power to

your circuit after getting approval from the staff member.

20.While performing load-tests in the ElectricalMachinesLaboratory using the brake-drums:

i. Avoid the brake-drum from getting too hot by putting just enough water into the brake-

drum at intervals; use the plastic bottle with a nozzle (available in the laboratory ) to pour

the water.(When the drum gets too hot, it will burn out the braking belts)

ii. Do not stand in front of the brake-drum when the supply to the load-test circuit is switchedoff. (Otherwise, the hot water in the brake-drum will splash out on you)

iii. After completing the load-test, suck out the water in the brake-drum using the plastic

bottle with nozzle and then dry off the drum with a spongewhich is available in thelaboratory.(The water, if allowed to remain in the brake-drum, will corrode it)

21.Determine the correct rating of the fuse/s to be connected in the circuit after understanding correctly

the type of the experiment to be performed: no-load test or full-load test, the maximum current expected inthe circuit and accordingly use that fuse-rating.(While an over-rated fuse will damage the equipment and

other instruments like ammeters and watt-meters in case of over load, an under-rated fuse may not allowone even to start the experiment)

22. At the time of starting a motor, the ammeter connected in the armature circuit overshoots, as thestarting current is around 5 times the full load rating of the motor. Moving coil ammeters being very

delicate, may get damaged due to high starting current. A switch has been provided on such meters todisconnect the moving coil of the meter during starting. This switch should be closed after the motor

attains full speed. Moving iron ammeters and current coils of wattmeters are not so delicate and hencethese can stand short time overload due to high starting current. No such switch is therefore provided onthese meters. Moving iron meters are cheaper and more rugged compared to moving coil meters. Moving

iron meters can be used for both a.c. and d.c. measurement. Moving coil instruments are however more

sensitive and more accurate as compared to their moving iron counterparts and these can be used for d.c.measurements only. Good features of moving coil instruments are not of much consequence for you as

other sources of errors in the experiments are many times more than those caused by these meters.

23.Some students have been found to damage meters by mishandling in the following ways:


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i. Keeping unnecessary material like books, labrecords, unused meters etc. causing meters to

fall down the table.ii. Putting pressure on the meter (specially glass) while making connections or while talking

or listening somebody.

STUDENTS ARE STRICTLY WARNED THAT FULL COST OF THE METER WILL BE

RECOVERED FROM THE INDIVIDUAL WHO HAS DAMAGED IT IN SUCH AMANNER.

Copy these rulesin your Lab Record. Observe these yourself and

help your friends to observe..

I have read and understand these rules and procedures. I agree to abide by these rules

and procedures at all times while using these facilities. I understand that failure to follow

these rules and procedures will result in my immediate dismissal from the laboratory and

additional disciplinary action may be taken.

Signature


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GUIDELINES FOR LABORATORY NOTEBOOK

The laboratory notebook is a record of all work pertaining to the experiment. Thisrecord should be sufficiently complete so that you or anyone else of similartechnical background can duplicate the experiment and data by simply followingyour laboratory notebook. Record everything directly into the notebook during the

experiment. Do not use scratch paper for recording data. Do not trust your memoryto fill in the details at a later time.

Organization in your notebook is important. Descriptive headings should be used toseparate and identify the various parts of the experiment. Record data inchronological order. A neat, organized and complete record of an experiment is justas important as the experimental work.

1. Heading:The experiment identification (number) should be at the top

of each page.Your name and date should be at the top of the first page of each day'sexperimental work.

2.Object:

A brief but complete statement of what you intend to find outor verify in the experiment should be at the beginning of each experiment

3.Diagram:

A circuit diagram should be drawn and labeled so that theactual experiment circuitry could be easily duplicated at any time in the future.Be especially careful to record all circuit changes made during the experiment.

4.Equipment List:

List those items of equipment which have a direct effect onthe accuracy of the data. It may be necessary later to locate specific items ofequipment for rechecks if discrepancies develop in the results.

5.Procedure:

In general, lengthy explanations of procedures areunnecessary. Be brief. Short commentaries along side the corresponding datamay be used. Keep in mind the fact that the experiment must be reproducible fromthe information given in your notebook.

6.Data:Think carefully about what data is required and prepare

suitabledata tables. Record instrument readings directly. Do not use calculated resultsin place of direct data; however, calculated results may be recorded in the same tablewith the direct data. Data tables should be clearly identified and each data columnlabeled and headed by the proper units of measure.

7.Calculations:

Not always necessary but equations and sample calculations are often given toillustrate the treatment of the experimental data in obtaining the results.


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8.Graphs:Graphs are used to present large amounts of data in a concise

visual form. Data to bepresented in graphical form should be plotted in thelaboratory so that any questionable datapoints can be checked while theexperiment is still set up. The grid lines in the notebook can be used for most

graphs. If special graph paper is required, affix the graph permanently into thenotebook. Give all graphs a short descriptive title. Label and scale the axes.Use units of measure. Label each curve if more than one on a graph.

9.Results:The results should be presented in a form which makes the

interpretation easy. Large amounts of numerical results are generally presented ingraphical form. Tables are generally used for small amounts of results.Theoretical and experimental results should be on the same graph or arrange in thesame table in a way for easy correlation of these results.

10.Conclusion:This is your interpretation of the results of the experiment as

an engineer. Be brief and specific. Give reasons for important discrepancies.


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EXP.NO. 1 DATE:

REGULATION OF 3PHASE ALTERNATOR BY EMF AND MMF METHODS

AIM:

To predetermine the regulation of 3-phase alternator by EMF and MMF methods and also

draw the vector diagrams.

APPARATURS REQUIRED:

SL.NO Name of the Apparatus Type Range Quantity

1 Ammeter MC 01/2 A 12 Ammeter MI 05/10 A 13 Voltmeter MC 010 V 14 Voltmeter MI 0600 V 15 Rheostat Wire wound 250 , 1.5 A 1

6 Rheostat Wire wound 1200, 0.8 A 17 Tachometer Digital --- 18 TPST knife switch -- -- 1

THEORY:The regulation of a 3-phase alternator may be predetermined by conducting the Open

Circuit (OC) and the Sort Circuit (SC) tests. The methods employed for determination ofregulation are EMF or synchronous impedance method, MMF or Ampere Turns method and the

ZPF or Potier triangle method. In this experiment, the EMF and MMF methods are used. The OC

and SC graphs are plotted from the two tests. The synchronous impedance is found from the OC

test. The regulation is then determined at different power factors by calculations using vector

diagrams. The EMF method is also called pessimistic method as the value of regulation obtainedis much more than the actual value. The MMF method is also called optimistic method as the

value of regulation obtained is much less than the actual value. In the MMF method the armatureleakage reactance is treated as an additional armature reaction. In both methods the OC and SC

test data are utilized.

PRECAUTIONS:

(i) The motor field rheostat should be kept in the minimum resistance position.

(ii) The alternator field potential divider should be kept in the minimum voltageposition.

(iii)

Initially all switches are in open position.

PROCEDURE: (FOR BOTH EMF AND MMF METHODS)

1.Note down the name plate details of the motor and alternator.2. Connections are made as per the circuit diagram.

3. Switch ON the supply by closing the DPST switch.


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4. Using the Three point starter, start the motor to run at the synchronous speed by adjustingthe motor field rheostat.

5. Conduct Open Circuit test by varying the potential divider for various values of field

current and tabulate the corresponding Open Circuit Voltage readings.

6. Conduct Short Circuit test by closing the TPST switch and adjust the potential divider toset the rated armature current and tabulate the corresponding field current.

7. The Stator resistance per phase is determined by connecting any one phase stator winding

of the alternator as per the circuit diagram using MC voltmeter and ammeter of suitableranges.

PROCEDURE TO DRAW GRAPH FOR EMF METHOD:1. Draw the Open Circuit Characteristic curve (Generated Voltage per phase VS Field

current).

2. Draw the Short Circuit Characteristics curve (Short circuit current VS Field current)

3. From the graph find the open circuit voltage per phase (E1 (ph) for the rated shortcircuit current (Isc).

4. By using respective formulae find the Zs, Xs, Eo and percentage regulation.

PROCEDURE TO DRAW GRAPH FOR MMF METHOD:

1. Draw the Open Circuit Characteristic curve (Generated Voltage per phase VS Fieldcurrent).

2. Draw the Short Circuit Characteristics curve (Short circuit current VS Field current)

3. Draw the line OLto represent

FORMULAE:1. Armature Resistance Ra =

2.

Synchronous Impedance Zs = O.C. voltageS.C. current

3. Synchronous Reactance Xs = Zs2Ra2

4. Open circuit voltage for lagging p.f = (Vcos + IaRa)2+ (Vsin + IaXs)2

5. Open circuit voltage for leading p.f. = (Vcos + IaRa)2+ (Vsin IaXs)2

6. Open circuit voltage for unity p.f = (V + IaRa)2+ ( IaXs)2

7.

Percentage regulation = EoV x 100V

RESULT:Thus the regulation of 3-phase alternator has been predetermined by the EMF and MMF

methods.


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VIVA QUESTIONS:

1. What is meant by voltage regulation?

2. What is meant by Synchronous Impedance?

3. What is OC test ?

4. What is SC test?

5. What is meant by mmf or field ampere turns?


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REGULATION OF 3-PHASE ALTERNATOR BY EMF AND MMF METHODS

TABULAR COLUMNS

OPEN CIRCUIT TEST:

S.No.

Field Current (If) Open Circuit Line

Voltage (VoL)

Open circuit Phase

Voltage (Voph)

Amps Volts Volts

SHORT CIRCUIT TEST:

S.No. Field Current (If)

Short Circuit Current (120%

to 150% of rated current)

(ISC)

Amps Amps


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REGULATION OF 3-PHASE ALTERNATOR BY EMF AND MMF METHODS

TABULAR COLUMNS

EMF METHOD:

SL.NO. Power

factor

Eph (V) % Regulation

Lag Lead Lag Lead

MMF METHOD:

SL.NO. P.F Vph

(V)

If1

(A)

If2

(A)

Ifr

(A)

Eph (V) % Regulation

Lag Lead Lag Lead Lag Lead


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EXP.NO. 2 DATE:

REGULATION OF 3-PHASE ALTERNATOR BY POTIER AND ASA METHODS

AIM:To predetermine the regulation of three phase alternator by Potier and ASA methods and

also to draw the vector diagrams.

APPARATURS REQUIRED:

SL.NO Name of the Apparatus Type Range Quantity1 Ammeter MC 01/2 A 12 Ammeter MI 05/10 A 13 Voltmeter MC 010 V 14 Voltmeter MI 0600 V 15 Rheostat Wire wound 250 , 1.5 A 16 Rheostat Wire wound 1200, 0.8 A 1

7 Tachometer Digital --- 18 TPST knife switch -- -- 1

FORMULAE USED:

Percentage regulation = EoVrated x 100 (For both POTIER & ASA methods)

Vrated

PRECAUTION:

(i) The motor field rheostat should be kept in the minimum resistance position.(ii) The Alternator field potential divider should be in the position of minimum

potential.(iii) Initially all switches are in open position.

PROCEDURE FOR BOTH POTIER AND ASA METHODS:

1. Note down the complete nameplate details of motor and alternator.2. Connections are made as per the circuit diagram.

3. Switch on the supply by closing the DPST main switch.

4. Using the Three point starter, start the motor to run at the synchronous speed by varying

the motor field rheostat.5. Conduct an Open Circuit Test by varying the Potential Divider for various values of

Field current and tabulate the corresponding Open circuit voltage readings.6. Conduct a Short Circuit Test by closing the TPST knife switch and adjust the potential

divider the set the rated Armature current, tabulate the corresponding Field current.

7. Conduct a ZPF test by adjusting the potential divider for full load current passing through

either an inductive or capacitive load with zero power and tabulate the readings.8.

Conduct a Stator Resistance Test by giving connection as per the circuit diagram and

tabulate the voltage and Current readings for various resistive loads.


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PROCEDURE TO DRAW THE POTIER TRIANGLE (ZPF METHOD):(All the quantities are in per phase value)

1. Draw the Open Circuit Characteristics (Generated Voltage per phase VS Field Current)2. Mark the point A at X-axis, which is obtained from short circuit test with full load

armature current.

3.

From the ZPF test, mark the point B for the field current to the corresponding ratedarmature current and the rated voltage.

4. Draw the ZPF curve which passing through the point A and B in such a way parallel to

the open circuit characteristics curve.5. Draw the tangent for the OCC curve from the origin (i.e.) air gap line.

6. Draw the line BC from B towards Y-axis, which is parallel and equal to OA.

7. Draw the parallel line for the tangent from C to the OCC curve.

8. Join the points B and D also drop the perpendicular line DE to BC, where the line DErepresents armature leakage reactance drop (IXL)

BE represents armature reaction excitation (Ifa).

PROCEDURE TO DRAW THE VECTOR DIAGRAM (ZPF METHOD)

1. Select the suitable voltage and current scale.

2. For the corresponding power angle ( Lag, Lead, Unity) draw the voltage vector andcurrent vector OB.

3. Draw the vector AC with the magnitude of IRa drop, which should be parallel to the

vector OB.4. Draw the perpendicular CD to AC from the point C with the magnitude of IXLdrop.

5. Join the points O and D, which will be equal to the air gap voltage (Eair).

6. Find out the field current (Ifc) for the corresponding air gap voltage (Eair) from the OCC

curve.

7.

Draw the vector OF with the magnitude of Ifcwhich should be perpendicular to thevector OD.

8. Draw the vector FG from F with the magnitude Ifa in such a way it is parallel to thecurrent vector OB.

9. Join the points O and G, which will be equal to the field excitation current (If).

10.Draw the perpendicular line to the vector OG from the point O and extend CD in such amanner to intersect the perpendicular line at the point H.

11.Find out the open circuit voltage (Eo) for the corresponding field excitation current (If)

from the OCC curve.

12.Find out the regulation from the suitable formula.

PROCEDURE TO DRAW THE POTIER TRIANGLE (ASA METHOD):(All the quantities are in per phase value)

1. Draw the Open Circuit Characteristics (Generated Voltage per phase VS Field Current)

2. Mark the point A at X-axis, which is obtained from short circuit test with full load

armature current.3. From the ZPF test, mark the point B for the field current to the corresponding rated

armature current and the rated voltage.


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4. Draw the ZPF curve which passing through the point A and B in such a way parallel tothe open circuit characteristics curve.

5. Draw the tangent for the OCC curve from the origin (i.e.) air gap line.

6. Draw the line BC from B towards Y-axis, which is parallel and equal to OA.

7. Draw the parallel line for the tangent from C to the OCC curve.

8. Join the points B and D also drop the perpendicular line DE to BC, where the line DE

represents armature leakage reactance drop (IXL)

BE represents armature reaction excitation (Ifa).9. Extend the line BC towards the Y-axis up to the point O. The same line intersects the air

gap line at point G.

10.Mark the point I in Y-axis with the magnitude of Eair and draw the line from I towardsOCC curve which should be parallel to X-axis. Let this line cut the air gap line at point H

and the OCC curve at point F.

11.Mention the length OG, HF and OA.

PROCEDURE TO DRAW THE VECTOR DIAGRAM (ASA METHOD)

(To find the field Excitation current If)

1. Draw the vector with the magnitude OG.2. From G draw a vector with the magnitude of GH (OA) in such a way to make an angle of

(90 ) from the line OG [ (90 + ) for lagging power factor and (90 ) for leadingpower factor]

3. Join the points O and, H also extend the vector OF with the magnitude HF. Where OFis the field excitation current (If).

4. Find out the open circuit voltage (Eo) for the corresponding field excitation current (If)

from the OCC curve.

5. Find out the regulation from the suitable formula.

RESULT:

Thus the regulation of 3-phase alternator has been predetermined by the Potier and ASA

methods.

VIVA QUESTIONS:

1. What is meant by ZPF Test?

2. What is Potier reactance? How is it determined by Potier triangle?

3. What is meant by armature reaction reactance?

4. What is the significance of the ASA modification of MMF method?

5. What is air gap line in Potier method?


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EXP.NO. 3 DATE:

REGULATION OF 3-PHASE SAILENT POLE ALTERNATOR

BY SLIP TEST

AIM:

To conduct a slip test on 3- alternator and pre-determine the regulation through vectordiagram.

APPARATUS REQUIRED:

S.no Name of

Apparatus

Range Type Quantity

1 Ammeter (0-5)A MI 1

(0-1)A MC 1

2 Voltmeter (0-150)V MI 1

(0-5)V MC 1

3 Rheostat 250 /1.5A 14 Tachometer Digital 1

5 TPST Switch 1

6 ConnectingWires

As reqd.

FUSE RATING:

(a)For Motor- 125% of rated current

= 125% of 17A=21.25A=25A

(b)For Alternator- 125% of rated current=125% of 4A= 5A

THEORY:

In a salient pole alternator, the reactance of magnetic circuit along is along its quad stator axis.

The alternator is driven by auxiliary prime mover at a speed slightly less than the synchronous

speed under these conditions. The armature current is when the armature current mmf is in line

with the field poles. The reactance by the magnetic field current is minimum. The ratio ofmaximum voltage to minimum current gives the direct axis impedance and the ratio of minimum

voltage to maximum current gives the armature axis impedance.

PRECAUTIONS:

1. The motor field rheostat should be kept in minimum.

2. The direction of the rotation due to prime mover and the alternator on the motor shouldbe the same.

3. Initially all the switches are kept open.


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PROCEDURE:

1. Note down the name plate details of motor and alternator.

2. Connections are made as per the circuit diagram.

3. Give the supply by closing the DPST switch.4. Using the three point starter, start the motor to run at the synchronous speed by varying

the motor field rheostat at the same time check whether the alternator field has been

opened or not.5. Apply 20% to 30% of the rated voltage to the armature of the alternator by adjusting the

autotransformer.

6. To obtain the slip and the maximum oscillation of pointers the speed is reduced slightlylesser than the synchronous speed.

7. Maximum current, minimum current, maximum voltage and minimum voltage are noted.

8. Find out the direct and quadrature axis impedances.

PROCEDURE TO DRAW THE VECTOR DIAGRAM:

1. Draw the line OA that represents the rated voltage V.

2.

Draw the line OBvector to represent the rated current I,which makes an angle (it maylag/lead/in phase) with the voltage.

3. Draw the line ACvector to represent IRa drop, which is parallel to OB vector.

4. Draw the perpendicular line CDto the line AC(IRa drop)that represents IXqdrop.5. Draw the line from the origin through the point D, which represents the no load voltage

(Eo).

6. Draw the pole axis through origin, which should be perpendicular to vector OD.7. Draw a perpendicular line to the pole axis from the same point Ewhich should pass

through the point B[where vector OErepresents Direct Axis Current (Id) and Vector EB

represents Quadrature Axis Current (Iq)].

8. Find out the reactive voltage drops IdXd and IqXq.

9.

Draw a parallel line (ie perpendicular to Id) toODvector from the point C, with themagnitude of the drop IdXd (Line CF).

10.Draw a parallel line (ie perpendicular to Iq) toOEvector from the point F, with themagnitude of the drop IqXq (Line FG).

11.Let the point at where the IqXq drop meets the OD line be G. here the vector OG

represents the no load voltage (Eo).12.Find out the voltage regulation by using the suitable formula.

FORMULAE USED:

1. Rac=1.6Rac

2. Zd = Vmax/Imin

3. Zq = Vmin/Imax

4. Xd = Zd2Rd2

5. Xq = Zq2Rd2


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6. Id = Ia sin amps

7. Iq = Ia cos amps

8. %Reg = (Eo-V/V)*100

Where,

Zd = direct axis impedance in Zq = quadrate axis impedance in Xd = direct axis reactance in Xq = quadrate axis reactance in Id = direct axis current in amps

Ia = quadrate axis current in amps

GRAPH:

Power Factor VS % regulation.

RESULT:

Thus the pre-determination of regulation of 3-phase alternator by vector diagram was

obtained.

VIVA QUESTIONS:

1. What is the purpose of slip test on 3 phase alternator?

2. What is meant by direct axis reactance?

3. What is meant by quadrature axis reactance?

4. How is the regulation of alternator predetermined by slip test?

5. What is the difference between salient pole alternator and cylindrical rotor typealternator?


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SLIP TEST ON 3-PHASE ALTERNATOR

TABULAR COLUMNS

(i) To find the Direct Axis and Quadrature axis impedances:

S.NO Vmax Vmin Imax Imin

1

2

(ii)To predetermine % Regulation:

S.NO

Power Factor % Regulation

Lagging Leading Unity

1 0.2 --

2 0.4 --

3 0.6 --

4 0.8 --

5 1.0


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EXP.NO. 4 DATE:

V AND INVERTED V CURVE OF THREE PHASE

SYNCHRONOUS MOTOR

AIMTo draw the V and inverted V curves of a 3 phase Synchronous Motor.

NAME PLATE DETAILS:

3SYNCHRONOUS MOTOR DC EXCITATION

FUSE RATING:

125% of rated current (full load current)For DC excitation:For synchronous motor:]

APPARATUS REQUIRED:

S.No Name of the

apparatus

Type range Quantity

1

2.

3.

4.

5.

Ammeter

Voltmeter

Ammeter

Rheostat

Wattmeter

MI

MI

MC

UPF

(0-5)A

(0-600)V

(0-2)A

200,15A

600V,5A

2

2

1

1

2


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PRECAUTION:(1)The Potential barrier should be in maximum position.

(2) The motor should be started without load .

(3)Initially TPST switch is in open position.

PROCEDURE:(1)Note down the name plate details of the motor.

(2)Connections are made as pr the circuit diagram..

(3)Close the TPST switch.(4)By adjustingthe autotransformer from the minimum position to the maximum

position the rated supply is given to motor. The motor starts as an induction motor.

(5)In order to give the excitation to the field for making it to run as the synchronous

motor, close the DPST switch.(6)By varying the field rheostat note down the excitation current, armature current and

the power factor for various values of excitation.

(7)The same process has to be repeatedfor loaded condition.

(8)

Later the motor is switched offand the graph is drawn.

GRAPH:The graph is drawn for-

(1) Armature current Vs Excitation current.

(2) Power factor Vs Excitation current.

RESULT:

The V-curves and inverted V-curves of the 4 phase synchronous motor have been drawn.


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EXP.NO.5 A DATE:

LOAD TEST ON 3-PHASE SQUIRREL CAGE INDUCTION MOTOR

AIM:To draw the performance characteristics of 3-phase squirrel cage induction motor by

conducting load test.

APPARATUS REQUIRED:

S.No Name ofapparatus

Range Type Qty.

1. Ammeter (0-5)A MI 1

2. Voltmeter (0-600)V MI 1

3. Wattmeter (600V,5A) UPF 2

4. Tachometer Digital 1

5. 3-

autotransformer

1

FUSE RATING;

125% of 4.8A=6A=10A

THEORY:

A 3-phase induction motor consists of stator and rotor with the other associated parts. In thestator, a 3-phase winding is provided. The windings of the three phase are displaced in space by

120.A 3-phase current is fed to the 3-phase winding. These windings produce a resultant

magnetic flux and it rotates in space like a solid magnetic poles being rotated magnetically.

PRECAUTIONS:

1. TPST switch is kept open initially.

2. Autotransformer is kept at min. voltage position.

3. There must be no load when starting the load.

PROCEDURE:

1. Connections are given as per circuit diagram.2.3- induction motor is started with DOL starter.3. If the pointer of one of the wattmeter readings reverses, interchange the current coil terminals

and take the reading as negative.3. The no load readings are taken.

4. The motor is loaded step by step till we get the rated current and the readings of the voltmeter,

ammeter, wattmeters, spring balance are noted.


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FORMULAE USED:

1) % slip= (Ns-N/Ns)*100

2) Input Power = (W1+W2)watts

3) Output Power = 2NT/60 watts4) Torque = 9.81*(S1-S2)*R N-m

5) % efficiency = (o/p power/i/p power)* 100

GRAPHS:

1) Output Power vs Efficiency2) Output Power vs Torque

3) Output Power vs Speed

4) Output Power vs %s

RESULT

Thus the performance characteristics of a 3- squirrel cage induction motor by conducting loadtest has been drawn.


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EXP.NO. 5 B DATE:

LOAD TEST ON 3-PHASE SLIP RING INDUCTION MOTOR

AIM:To conduct a direct load test on a 3-phase slip ring induction motor and to draw the

performance characteristics.

APPARATUS REQUIRED:

S.NO NAME OF

APPARATUS

RANGE TYPE QTY.

1 Ammeter(0-10)A

MI 1


3 Wattmeter (600V,10A) UPF 2

4 Tachometer Digital 1

FUSE RATING-

FOR- STATOR- 125% 0f 7.5A = 10A

FOR ROTOR125% of 11A = 15A

THEORY:

Slip ring induction motor is also called as phase wound motor. The motor is wound for as many

poles as the no. of stator poles and always wound 3- even while the stator is wound two-phase.The other three windings are brought out and connected to three insulated slip-rings mounted on

the shaft with brushes resting on them. These three brushes are further externally connected to a

three phase star connected rheostat. This makes possible the introduction of an additionalresistance in the rotor circuit during starting period for increasing starting torque of the motor.

PRECAUTIONS:

1. TPST switch is kept open initially.

2. The external resistance in the rotor circuit should be kept at max. value.

PROCEDURE:1. Connections are given as per circuit diagram.

2. After observing precautions motor is started on no load.

3. As speed increases, the external resistance is gradually cut out.4. The no-load readings are taken.

5. If the pointer in one of the wattmeter reverses, interchange the current coil terminals and

take the reading as negative.6. The meter readings are then noted for various load conditions.


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FORMULAE USED:

1. Torque= (S1-S2)*9.81*100 N-m

2. O/P Power= 2NT/60 watts3. I /P Power = (W1+W2) watts

4. % = (o/p power/ i/p power)*1005.

%s = (Ns-N)/Ns*100

GRAPHS:

1. O/P power vs Speed

2. O/P power vs Torque

3. O/P Power vs 4. O/P Power vs slip5. Torque vs Speed

6. Torque vs Slip

RESULT:

The load test on 3- slip ring induction motor was conducted and the performancecharacteristics curves were plotted.


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EXP.NO.6 DATE:

NO LOAD AND BLOCKED ROTOR TEST ON 3- PHASE

INDUCTION MOTOR

AIM: To conduct the no load & blocked rotor test on 3- phase induction motor

& to draw the equivalent circuit of 3- phase squirrel cage induction motor.

APPARATUS REQUIRED:

FUSE RATING :-

125/100 * 7.5 A 10A

THEORY :-

A 3-phase induction motor consists of stator, rotor & other associated parts. In the stator

,a 3- phase winding (provided) are displaced in space by 120. A3- phase current is fed to thewinding so that a resultant rotating magnetic flux is generated. The rotor starts rotating due to the

induction effect produced due the relative velocity between the rotor

Winding & the rotating flux.

PRECAUTIONS :-

NO LOAD TEST

(1). Initially TPST switch is kept open.

(2). Autotransformer must be kept at minimum potential position.

(3). The machine must be started at no load.

S.NO NAME OFAPPARATUS

RANGE TYPE QTY

1. Voltmeter (0-600)V

(0-150)V

MI

MI

01

012. Ammeter (0-10)A MI 01

3. Wattmeter (600V,5A)

(150V,10A)

UPF

LPF

01

01

4. Connecting wire As required


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BLOCKED ROTOR TEST

(1). Initially the TPST switch is kept open.(2). Autotransformer must be kept at minimum potential position.

(3). The machine should be started on full load.

PROCEDURE

NO LOAD TEST

(1). Connections are given as per the circuit diagram.

(2). Precautions are observed and motor is started on the no load.(3). Autotransformer is varied to have rated voltage applied.

(4). The meter readings are then tabulated.

BLOCKED ROTOR TEST :-

(1). Connections are given as per circuit diagram.(2). Precautions are observed and motor is started on full load or blocked rotor position.

(3). Autotransformer is varied to have rated current flowing in motor.

(4). The meter readings are then tabulated.

FORMULA USED-

FOR NO LOAD TEST-

Wsc = 3 Vo IoCOS wattsIw = Io cos ampsRo= V0/ Iw

Xo= Vo/Iu

FOR BLOCKED ROTOR TEST-

Wsc =3I2*Ro watts

Ro1 = Wsc/3(Isc)2 Zo1 = Vsc/Isc

Xo1 = Zo1^2-Ro1^2

RESULT:-

Thus the no load and blocked rotor test on 3-squirrel cage induction motor is performedand the equivalent circuit of 3-phase squirrel cage induction motor has been drawn.


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TABULAR COLUMNS

NO LOAD TEST:

S.No Voltage

Voc

Volts

Current

Ioc

Amps

Wattmeter

readings (W1)

W1 x

mf1

Wattmeter

readings (W2)

W2 x

mf2

Observed Actual

Watts

Observed Actual

Watts

1

Voc= open circuit voltage

Ioc = open circuit current

BLOCKED ROTOR TEST:

S.No. Voltage

Vsc

Volts

Current

Isc

Amps

Wattmeter

readings(W1)

W1 x

mf1

Wattmeter

readings(W2)

W2 x

mf2

Observed ActualWatts

observed ActualWatts

1.

Vsc = short circuit voltage

Isc = short circuit current


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EXP.NO. 7 DATE:

SEPARATION OF NO LOAD LOSSES OF THREE PHASE INDUCTION

MOTOR

AIM:

To separate the no load losses of a 3 phase squirrel cage induction motor as iron lossesand mechanical losses.

NAME PLATE DETAILS:

3 induction motor Auto Transformer

FUSE RATING:

No load :10% of rated current (full load current).

APPARATUS REQUIRED:

S.No Name of the apparatus Type Range Quantity

1.

2.

3.

4.

5.

Ammeter

Voltmeter

Wattmeter

3- Auto Transformer

Rheostat

MI

MC

MI

MC

LPF

(0-10)A

(0-1)A

(0-600)V

(0-5)V

600V,5A

(415/0-

470)V

1200/0.8A

1

1

1

1

2

1

1

PRECAUTIONS:(1) The autotransformer should be kept in minimum voltage position.

(2) The motor should not be loaded throughout the experiment.


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PROCEDURE:

(1) Connections should be made as per the circuit diagram.(2) by giving three phase supply , start the motor.

(3)vary the autotransformer till rated speed is attainsd and note the input power, voltage and

current.(4)repeat the same procedure for and tabulate the reading.

(5)find the stator copper loss and constant loss by respective formulas.

(6)draw the suitable graph to find the mechanical losses.(7)obtain the core los by separating the mechanical loss fom constant losses.

GRAPH:The graph drawn between constant losses(watts) and input voltage(volts).

MODEL CALCULATIONS:

1. Input power(W) =(W1+W2)in watts

2. Stator copper loss =3I2Rs in watts

3. Constant loss/phase(Wc)= (W-3I2Rs)/3 in watts4 Core loss/phase (Wi)= (constant loss/phase)-mechanical loss

RESULT:

Thus the no load losses of 3-phase squirrel cage induction motor was separated as core

losses and mechanical losses.


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EXP.NO. 8 DATE:

LOAD TEST ON SINGLE PHASE INDUCTION MOTOR

AIM:To determine the performance characteristic of a given single phase capacitor start

induction motor by conducting load test.

APPARATUS REQUIRED:

SL. NO APPARATUS RANGE TYPE QUANTITY

1 Voltmeter (0-300)V MI 12 Ammeter (0-10)A MI 1

3 Wattmeter 300 V, 10A UPF 14 Tachometer 1

5 Connecting wires As required

FUSE RATING:

Fuse rating = 125% of rated current = 125/100 * 7.5

10A

THEORY:

The single phase induction motor is more or less a polyphase induction motor. The only

difference is that is given supply in single phase. This motor connect and motor function

without any initial start the motor having some part which is called starter and rotor.

Theseare two types of starting a 1 phase induction motor namely capacitor-start and other is

split-

phase. These motors are widely used in domestic purpose.

PRECAUTION:

1) Before switching on the supply the variac is kept in minimum position.

2) Initially these should be on no load while starting the motor.


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PROCEDURE:

1) Connections are given as per the circuit diagram.

2) Switch on the supply at no load condition.

3) Apply the rotor voltage to the motor using the variac and note down the readings atammeter

And wattmeter.

4) Vary the load in suitable steps and note down all the meter readings till fill load

condition.

FORMULA USED:

1) Torque ,T = (S1~S2)*9.81*R N.m

2) Output power = 2 NT/60*W

3)

Effecting (%) = 0/P Power/I/p Power*1004) Slip (%S) = NSN/NS*1005) Power factor = Cos =W/VI

GRAPH :

1) Output Power Vs speed2) Output power Vs Torque

3) Output power Vs Effecting

4) Output power Vs slip5) Output power Vs Power factor

RESULT:

Thus load test on the single phase induction motor has been conducted and its

performance characteristics determined.


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TABULAR COLUMN

m.f =

Sl.No. VLV

ILA

Speed(N)

RPM

S1Kg

S2Kg

S1~ S2Kg

Torque

N-m

Wattmeter Reading Output

Power

W

Efficiency

%

PF= cosObserved Actual

1

2

3

4

5

6

7

8

MODEL CALCULATION:

Input power = W x m.f = Watts % slip = (NsN)/Ns x 100 pf= cos = W/VLILOutput power = 2NT/ 60 Watts

Torque T= (S1~S2)*9.81*R N-m, where R is the radius of the brake drum in metre

Output power

Efficiency = x 100Input power


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EXP.NO. 9 DATE:

NO LOAD AND BLOCKED ROTOR TEST ON SINGLE PHASE INDUCTION MOTOR

AIM:To draw the performance characteristics of a single phase induction motor by conducting

the no-load and blocked rotor test.

APPARATUS REQUIRED:

S.No Name of

Apparatus

Range Type Qty.


(0-150)V MI 1

2 Ammeter (0-10)A MI 1

(0-2)A MI 1

3 Wattmeter (330V,10A) UPF 1

(300V,5A) LPF 1

4 Connectingwires

As reqd.

FUSE RATING:

125% of 7.6A=10A

THEORY:

A 1- induction motor consists of stator,rotor and other associated parts.In the rotor of a singlephase winding is provided.The windings of a 1- winding(provided) are displaced in space by120.A single phase current is fed to the windings so that a resultant rotating magnetic flux isgenerated.The rotor starts rotating due to the induction effect produced due to the relative

velocity between the rotor winding and the rotating flux.

PRECAUTIONS:

NO LOAD TEST:

Initially TPST Switch is kept open.

Autotransformer is kept at minimum potential position. The machines must be started on no load.


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BLOCKED ROTOR TEST:

Initially the TPST Switch is kept open.

Autotransformer is kept at minimum potential position.

The machine must be started at full load (blocked rotor).

PROCEDURE:

NO LOAD TEST:

1. Connections are given as per the circuit diagram.

2. Precautions are observed and the motor is started at no load.

3. Autotransformer is varied to have a rated voltage applied.

BLOCKED ROTOR TEST:

1. Connections are given as per the circuit diagram.

2. Precautions are observed and motor is started on full load or blocked rotor position.

3. Autotransformer is varied to have rated current flowing in motor.

4. Meter readings are the noted.

Reff = 1.5*Rdc

FORMULAE-

NO LOAD TEST-

cos = Wo/VoIo Iw = Io cos Im = Io sin Ro = Vo/Iw

Xo = Vo/Im

BLOCKED ROTOR TEST-

Zsc = Vsc/Isc Rsc = Wsc/Isc2 Xsc = (Zsc2Rsc2)


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RESULT-

Thus the no load and blocked rotor test on the single phase induction motor has been conducted

and the equivalent circuit has been drawn.

TABULATION

NO LOAD TEST

S.No. Vo(volts) Io(amps) Wo(watts)

m.f Observed Acual

BLOCKED ROTOR TEST

S.No. Vsc(volts) Isc(amps) Wsc(watts)

m.f Observed Actual


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Negative sequence

Zero sequence


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EXP.NO. 2 DATE:

MEASUREMENT OF NEGATIVE SEQUENCE AND ZERO SEQUENCE IMPEDANCE

OF ALTERNATOR

AIM:Determination of negative sequence and zero sequence Impedance of a synchronous generator.

APPARATUS REQUIRED:

SL.NO Name of the Apparatus Type Range Quantity

1 Ammeter MI (0-5)A 1

2 Ammeter MC (0-2)A 1

3 Voltmeter MC (0-300)V 1

4 Voltmeter MC (0-75)V 1

5 Dimmer Stat 1 phase 230V 1

6 Wattmeter 150V,5A 1

7 Tachometer Digital --- 1

THEORY:

When a synchronous generator is carrying an unbalanced load its operation may be

analyzed by symmetrical components. In a synchronous machine the sequence current produce

an armature reaction which is stationary with respect to reactance and is stationary with respect

to field poles. The component currents therefore encounter exactly same as that by a balanced

load as discussed. The negative sequence is produced and armature reaction which rotates around

armature at synchronous speed in direction to that of field poles and therefore rotates part thefield poles at synchronous speed. Inducing current in the field damper winding and rotor iron.

The impendence encountered by the negative sequence is called the ve sequence impedance of

the generator. The zero sequence current produce flux in each phase but their combined armature

reaction at the air gap is zero. The impedance encountered by their currents is therefore different

from that encountered by + ve and ve sequence components and is called zero sequence

impedance of generator.

Negative sequence:

The ve sequence impedance may be found by applying balanced ve sequence voltage

to the armature terminals. While the machine is drive by the prime mover at its rated

synchronous speed with the field winding short circuited. The ratio of v/ph and Ia/ph gives ve

sequence Z/ph. The reading of the wattmeter gives I2 R losses. This loss /ph divided by Iph


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required gives theve sequence R/ph from the impedance and reactance/ph. ve sequence can be

calculated. Another method of measuring ve sequence reactance is found to be connect the arm

terminals. The machine is driven at synchronous speed and field current adjusted until rated

current flows in the phases shorted through armature and current coil of wattmeter respectively

Zero sequence:

The sequence impedance may be determined by the connecting the armature windings of

the three phase in series and then connecting them to the single phase source of power. If the

machine is driven at synchronous speed with field winding shorted, then ZO=V/3I practically the

same results will be obtained with rotor stationary.

If windings are connected in parallel, then

PROCEDURE

A. For Negative Sequence

(1) Make connection as shown in circuit diagram.(2) Run DC motor with synchronous speed.

(3) Keeping the speed constant, vary the excitation and measure the voltmeter,ammeter and wattmeter reading.

(4) Take 3-4 readings for different excitation.(5) The excitation should not be increased beyond the rated capacity ofsynchronous machine i.e. 4.2 A


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B. For Zero Sequence

(1)Make connection as shown in circuit diagram.(2)Set the dimmer stat output to zero volts and switch on the supply.(3) Gradually increase dimmer stat output and note the ammeter reading for

Suitable voltage applied.

(4) Repeat reading for suitable voltage applied.

(5) It should be kept in mind that the ammeter reading should not exceed the ratedcurrent

Capacity of the machine i.e. 4.2 A.

RESULT:

The negative sequence reactance and zero sequence reactance of an alternator wasdetermined.


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TABULATION

Negative sequence Impedance

Voltmeter(V) Wattmeter (W) Ammeter (A)

Zero sequence Impedance

Voltmeter(V) Wattmeter (W) Ammeter (A)

em-ii lab manual_1 (1).pdf

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