Electrical engineering experiments

Note continued: Calibration of A.C. Wattmeter by a Standard Voltmeter and Ammeter -- Experiment 42 -- Calibration of an Ampere-Hour Meter by a Standard Ammeter -- Experiment 43 -- To Find an Unknown Inductance with Hays Bridge -- Experiment 44 -- To Determine a Value of High Resistance by the Loss of Charge Method -- Experiment 45 -- Calibration of a Wattmeter and Ammeter by Crompton's Potentiometer -- Experiment 46 -- Study of an Impulse Generator (1.6 Million Volts) -- Experiment 47 -- To Determine the Breakdown Voltage of an Oil Sample -- Experiment 48 -- To Determine the Breakdown Characteristics of -- (a).Sphere-Sphere Gap -- (b).Rod-Rod Gap -- (c).Needle-Needle Gap -- Experiment 49 -- To find the voltage distribution across a string of a suspension insulator having five units, and to determine the efficiency of a string of insulators and to plot a graph between percentage voltage and the number of insulators from the line end.;Machine generated contents note: Experiment 1 -- To Determine Internal Resistance of a Battery -- Experiment 2 -- Load Test on a D.C. Series Generator -- Experiment 3 -- Load Test on a D.C. Series Motor -- Experiment 4 -- Load Test on a D.C. Shunt Motor -- Experiment 5 -- Load Test on a D.C. Shunt Generator -- Experiment 6 -- Load Test on a D.C. Compound Motor -- Experiment 7 -- Load Test on a D.C. Compound Generator -- Experiment 8 -- No-Load Test on a Separately Excited D.C. Generator (Magnetization Characteristic) -- Experiment 9 -- No-Load Test on a D.C. Shunt Generator (Magnetization Characteristic) -- Experiment 10 -- No-Load Test on a D.C. Shunt Motor (Swinburne Test) -- Experiment 11 -- To Perform a Hopkinson Test on Two Identical D.C. Shunt Machines -- Experiment 12 -- Open-Circuit Test and Short-Circuit Test on a Single-Phase Transformer -- Experiment 13 -- Load Test on a Single-Phase Transformer -- Experiment 14;Contains 49 experiments on electrical engineering concepts, including electricity, magnetism, currents, voltage, generators, transformers, relays, alternators, resistance and gaps. Each experiment includes its object, setup and method, results and questions with answers. The final chapter contains 189 questions with answers on general electricity and electronics knowledge.;Note continued: To Determine Regulation of a Three-Phase Alternator for Full Load at a Power Factor Using the Zero Power Factor Method or the Potier Triangle Method -- Experiment 24 -- To Determine the Regulation of a Three-Phase Alternator at a Load and Its Power Factor by the MMF Method -- Experiment 25 -- To Measure the Iron Loss at Different Flux Densities with a Lloyd Fisher Magnetic Square -- Experiment 26 -- Study of Overcurrent Relay (I.D.M.T. Type) and Determination of the Time-Current Characteristic -- Experiment 27 -- Study of the Instantaneous Relay and Determination of the Pickup and Reset Values -- Experiment 28 -- Study of the Directional Overcurrent Relay -- Experiment 29 -- Study of the Percentage Differential Relay -- Experiment 30 -- To Plot Burden Current Characteristics of the Given Current Transformers -- Experiment 31 -- For the Given Current Transformer and Burden to Find the Ratio and Phase Angle Error at -- (a).100% Rated Current and;Note continued: (b).50% Rated Current by the Mutual Inductance (Absolute) Method -- Experiment 32 -- To Plot the Power-Angle Curve of a Three-Phase Salient Pole Synchronous Generator -- Experiment 33 -- Determination of Xd and Xq by Slip Test -- Experiment 34 -- To Study the Effect of the Brush Separation and Brush Shift on the Speed and Power Factor of the Schrage Motor -- Experiment 35 -- To Plot Magnetization Characteristics and Load Characteristics of Metadyne Generators -- Experiment 36 -- To Plot the Magnetization Characteristic and Load Characteristic of an Amplidyne Generator -- Experiment 37 -- To Determine Negative Sequence and Zero Sequence Reactions of a Synchronous Machine -- Experiment 38 -- To Determine Parameters of a Single-Phase Induction Motor -- Experiment 39 -- Measurement of a Small Resistance by Kelvins Double Bridge -- Experiment 40 -- Calibration of a Watt-Hour Meter by a Standard Wattmeter -- Experiment 41;Note continued: Back-to-Back Test on Two Identical Transformers (Sumpner Test) -- Experiment 15 -- Separation of Losses in a Single-Phase Transformer (Separation of Eddy Current and Hysteresis Loss) -- Experiment 16 -- Separation of Losses in a D.C. Shunt Motor -- Experiment 17 -- To Perform a Load Test on a Three-Phase Slip-Ring Induction Motor -- Experiment 18 -- To Perform a No-Load and Blocked Rotor Test on a Three-Phase Squirrel Cage Induction Motor -- Experiment 19 -- No-Load Test and Short-Circuit Test on a Three-Phase Alternator -- Experiment 20 -- A Load Test on a Three-Phase Synchronous Generator -- Experiment 21 -- To Determine Regulation of a Three-Phase Alternator at Full Load, Lagging Power Factor, and Leading Power Factor -- Experiment 22 -- To Determine the V-Curve and Inverted V-Curve of a Synchronous Motor -- Experiment 23 Machine generated contents note: Experiment 1 -- To Determine Internal Resistance of a Battery -- Experiment 2 -- Load Test on a D.C. Series Generator -- Experiment 3 -- Load Test on a D.C. Series Motor -- Experiment 4 -- Load Test on a D.C. Shunt Motor -- Experiment 5 -- Load Test on a D.C. Shunt Generator -- Experiment 6 -- Load Test on a D.C. Compound Motor -- Experiment 7 -- Load Test on a D.C. Compound Generator -- Experiment 8 -- No-Load Test on a Separately Excited D.C. Generator (Magnetization Characteristic) -- Experiment 9 -- No-Load Test on a D.C. Shunt Generator (Magnetization Characteristic) -- Experiment 10 -- No-Load Test on a D.C. Shunt Motor (Swinburne Test) -- Experiment 11 -- To Perform a Hopkinson Test on Two Identical D.C. Shunt Machines -- Experiment 12 -- Open-Circuit Test and Short-Circuit Test on a Single-Phase Transformer -- Experiment 13 -- Load Test on a Single-Phase Transformer -- Experiment 14 Note continued: Back-to-Back Test on Two Identical Transformers (Sumpner Test) -- Experiment 15 -- Separation of Losses in a Single-Phase Transformer (Separation of Eddy Current and Hysteresis Loss) -- Experiment 16 -- Separation of Losses in a D.C. Shunt Motor -- Experiment 17 -- To Perform a Load Test on a Three-Phase Slip-Ring Induction Motor -- Experiment 18 -- To Perform a No-Load and Blocked Rotor Test on a Three-Phase Squirrel Cage Induction Motor -- Experiment 19 -- No-Load Test and Short-Circuit Test on a Three-Phase Alternator -- Experiment 20 -- A Load Test on a Three-Phase Synchronous Generator -- Experiment 21 -- To Determine Regulation of a Three-Phase Alternator at Full Load, Lagging Power Factor, and Leading Power Factor -- Experiment 22 -- To Determine the V-Curve and Inverted V-Curve of a Synchronous Motor -- Experiment 23 Note continued: To Determine Regulation of a Three-Phase Alternator for Full Load at a Power Factor Using the Zero Power Factor Method or the Potier Triangle Method -- Experiment 24 -- To Determine the Regulation of a Three-Phase Alternator at a Load and Its Power Factor by the MMF Method -- Experiment 25 -- To Measure the Iron Loss at Different Flux Densities with a Lloyd Fisher Magnetic Square -- Experiment 26 -- Study of Overcurrent Relay (I.D.M.T. Type) and Determination of the Time-Current Characteristic -- Experiment 27 -- Study of the Instantaneous Relay and Determination of the Pickup and Reset Values -- Experiment 28 -- Study of the Directional Overcurrent Relay -- Experiment 29 -- Study of the Percentage Differential Relay -- Experiment 30 -- To Plot Burden Current Characteristics of the Given Current Transformers -- Experiment 31 -- For the Given Current Transformer and Burden to Find the Ratio and Phase Angle Error at -- (a).100% Rated Current and Note continued: (b).50% Rated Current by the Mutual Inductance (Absolute) Method -- Experiment 32 -- To Plot the Power-Angle Curve of a Three-Phase Salient Pole Synchronous Generator -- Experiment 33 -- Determination of Xd and Xq by Slip Test -- Experiment 34 -- To Study the Effect of the Brush Separation and Brush Shift on the Speed and Power Factor of the Schrage Motor -- Experiment 35 -- To Plot Magnetization Characteristics and Load Characteristics of Metadyne Generators -- Experiment 36 -- To Plot the Magnetization Characteristic and Load Characteristic of an Amplidyne Generator -- Experiment 37 -- To Determine Negative Sequence and Zero Sequence Reactions of a Synchronous Machine -- Experiment 38 -- To Determine Parameters of a Single-Phase Induction Motor -- Experiment 39 -- Measurement of a Small Resistance by Kelvins Double Bridge -- Experiment 40 -- Calibration of a Watt-Hour Meter by a Standard Wattmeter -- Experiment 41 Note continued: Calibration of A.C. Wattmeter by a Standard Voltmeter and Ammeter -- Experiment 42 -- Calibration of an Ampere-Hour Meter by a Standard Ammeter -- Experiment 43 -- To Find an Unknown Inductance with Hays Bridge -- Experiment 44 -- To Determine a Value of High Resistance by the Loss of Charge Method -- Experiment 45 -- Calibration of a Wattmeter and Ammeter by Crompton's Potentiometer -- Experiment 46 -- Study of an Impulse Generator (1.6 Million Volts) -- Experiment 47 -- To Determine the Breakdown Voltage of an Oil Sample -- Experiment 48 -- To Determine the Breakdown Characteristics of -- (a).Sphere-Sphere Gap -- (b).Rod-Rod Gap -- (c).Needle-Needle Gap -- Experiment 49 -- To find the voltage distribution across a string of a suspension insulator having five units, and to determine the efficiency of a string of insulators and to plot a graph between percentage voltage and the number of insulators from the line end. Electrical_Engineering_Experiments_2nd-Pass_00 1 Electrical_Engineering_Experiments_2nd-Pass_01 11 Electrical_Engineering_Experiments_2nd-Pass_02 15 Electrical_Engineering_Experiments_2nd-Pass_03 19 Electrical_Engineering_Experiments_2nd-Pass_04 23 Electrical_Engineering_Experiments_2nd-Pass_05 29 Electrical_Engineering_Experiments_2nd-Pass_06 33 Electrical_Engineering_Experiments_2nd-Pass_07 39 Electrical_Engineering_Experiments_2nd-Pass_08 43 Electrical_Engineering_Experiments_2nd-Pass_09 47 Electrical_Engineering_Experiments_2nd-Pass_10 51 Electrical_Engineering_Experiments_2nd-Pass_11 57 Electrical_Engineering_Experiments_2nd-Pass_12 61 Electrical_Engineering_Experiments_2nd-Pass_13 67 Electrical_Engineering_Experiments_2nd-Pass_14 71 Electrical_Engineering_Experiments_2nd-Pass_15 75 Electrical_Engineering_Experiments_2nd-Pass_16 79 Electrical_Engineering_Experiments_2nd-Pass_17 83 Electrical_Engineering_Experiments_2nd-Pass_18 89 Electrical_Engineering_Experiments_2nd-Pass_19 95 Electrical_Engineering_Experiments_2nd-Pass_20 101 Electrical_Engineering_Experiments_2nd-Pass_21 105 Electrical_Engineering_Experiments_2nd-Pass_22 109 Electrical_Engineering_Experiments_2nd-Pass_23 113 Electrical_Engineering_Experiments_2nd-Pass_24 119 Electrical_Engineering_Experiments_2nd-Pass_25 123 Electrical_Engineering_Experiments_2nd-Pass_26 131 Electrical_Engineering_Experiments_2nd-Pass_27 135 Electrical_Engineering_Experiments_2nd-Pass_28 137 Electrical_Engineering_Experiments_2nd-Pass_29 141 Electrical_Engineering_Experiments_2nd-Pass_30 145 Electrical_Engineering_Experiments_2nd-Pass_31 151 Electrical_Engineering_Experiments_2nd-Pass_32 157 Electrical_Engineering_Experiments_2nd-Pass_33 163 Electrical_Engineering_Experiments_2nd-Pass_34 167 Electrical_Engineering_Experiments_2nd-Pass_35 173 Electrical_Engineering_Experiments_2nd-Pass_36 179 Electrical_Engineering_Experiments_2nd-Pass_37 183 Electrical_Engineering_Experiments_2nd-Pass_38 187 Electrical_Engineering_Experiments_2nd-Pass_39 193 Electrical_Engineering_Experiments_2nd-Pass_40 197 Electrical_Engineering_Experiments_2nd-Pass_41 201 Electrical_Engineering_Experiments_2nd-Pass_42 203 Electrical_Engineering_Experiments_2nd-Pass_43 205 Electrical_Engineering_Experiments_2nd-Pass_44 209 Electrical_Engineering_Experiments_2nd-Pass_45 213 Electrical_Engineering_Experiments_2nd-Pass_46 217 Electrical_Engineering_Experiments_2nd-Pass_47 223 Electrical_Engineering_Experiments_2nd-Pass_48 229 Electrical_Engineering_Experiments_2nd-Pass_49 237 Electrical_Engineering_Experiments_2nd-Pass_50 241