Supply, Installation And Integration A Various Electrical Machineries & Equipments Etc
Tender Overview
Project Description
Supply, Installation And Integration A Various Electrical Machineries & Equipments Etc-1 Circuits And Networks Lab 1.01 To Measure And Calculate Currents And Voltages For A Given Resistive Circuit And Verify Kcl And Kvl. 1.02 To Verify Superposition Theorem Experimentally For A Given Resistive Circuit Consisting Two Independent Sources 1.03 To Verify Thevenin’S Theorem Experimentally For A Given Circuit. 1.04 To Verify Maximum Power Transfer Theorem Experimentally For A Given Circuit 1.05 To Verify Reciprocity Theorem Experimentally For A Given Circuit 1.06 To Measure And Calculate Rc Time Constant For A Given Rc Circuit 1.07 To Measure And Calculate Rc Time Constant For A Given Rl Circuit 1.08 To Measure And Analyze ( Settling Time, Overshoot, Undershoot, Etc. ) Step Response Of For A Given Series Rlc Circuit For Following Cases: ( 1 ) Ζ =1 ( Critically Damped System ) , ( 2 ) Ζ >1 ( Over Damped System ) , ( 3 ) Ζ <1 ( Under Damped System ) . Choose Appropriate Values Of R, L, And C To Obtain Each Of Above Cases One At A Time 1.09 To Measure And Calculate Z-Parameters For A Given Two-Port System 1.10 To Measure And Calculate Y-Parameters For A Given Two-Port System. 1.11 To Measure And Calculate H-Parameters For A Given Two-Port System 1.12 To Measure And Calculate Abcd-Parameters For A Given Two-Port System 2 Digital Electronics Lab 2.01 Verification Of Truth Table Of Logic Gates 2.02 Implementation Of Various Logic Gates Using Only Nand Gates 2.03 Implementation Of Various Logic Gates Using Only Nor Gate 2.04 Verification Of Function Of Half / Full Adder Circuits 2.05 Verification Of Function Of Half / Full Subtractor Circuits 2.06 Verification Of Function Of Binary To Grey Code Conversion 2.07 Verification Of Function Of Grey To Binary Code Conversion 2.08 Verification Of Function Of 2 Line To 4 Line Decoder 2.09 Verification Of Function Of 4 Line To 2 Line Encoder 2.10 Verification Of Function Of 4 To 1 Multiplexer 2.11 Verification Of Function Of 1 To 4 Demultiplexer 2.12 Study Of Parity Generator 2.13 Verification Of Function Of Latch And Flip-Flop 2.14 Verification Of Shift Left / Right Register 2.15 Verification Of Counter Circuit Like Binary Up / Down Counter, Decimal Counter, Ring Counter, Johnson Counter Etc 2.16 Verification Of Sequential Circuits Other Than Counter And Shift Registers 2.17 Verification Of Specification And Performance Indices Of D / A And A / D Converters 2.18 To Study The D / A And A / D Converter Ic With Its Specifications 2.19 Bread Board Having 1380 Contact Points & 2 Terminals 2.20 Bread Board Having 1580 Contact Points & 2 Terminals 2.21 Bread Board Having 1680 Contact Points & 3 Terminals 2.22 Power Project Board ( Having 2420 Contact Points & 4 Terminals With 5V, 1Amp. And ± 2 To15v, 500Ma Power Supplies ) 2.23 Bread Board Circuit Lab ( With A.C. / D.C Power Supplies Pulser, Clock Generator, Gates And 2 Dpm’S ) . 2.24 3Mhz Microcontroller Based Function Pulse Generator With 40Mhz Frequency Counter 2.25 30Mhz Analog Oscilloscope 2.26 Digital Logic Trainer Kits : Study Of Or Logic Gate, And Logic Gate, Not Logic Gate, Ex_Or Logic Gate, Or / Nor Logic Gate, And / Nand Logic Gate, Not / Buffer Logic Gate, Ex_Or / Ex_Nor Logic Gate, Study Of All Digital Seven Logic Gates. 2.27 Multimeter 2.28 Single Power Supply 0-30V, 2 A 2.29 Dual Power Supply ( 2 X 0-30V - 2A ) 2.30 Function Generator 2.31 Oscilloscope 3 Dc Machine Lab 3.01 Squirrel Cage Induction Motor Connected To Self Excited Dc Generator 3.02 Slip Ring Induction Motor Connected To Self Excited Dc Generator 3.03 Single Phase Induction Motor 3.04 Cut Section Models Of 3.05 Dc Shunt Motor Coupled To A Three Phase Alternator - Preferably Salient Pole Type ( Two Sets ) 3.06 Auto Synchronous Motor 4 Ac Machine Lab 4.01 Design Of Three Phase Squirrel Cage Induction Motor 4.02 Design Of Three Phase Slip Ring Induction Motor 4.03 Design Of Single Phase Induction Motor 4.04 Design Of Salient Pole Low Speed Alternator 5 Electrical Measurements And Measuring Instruments Lab 5.01 Measurement Of Resistance Using Wheastone’S Bridge 5.02 Measurement Of Resistance Using Kelvin Double Bridge 5.03 Extension Of Range Of Wattmeter Using Ct & Pt 5.04 Measurement Of Displacement Using Lvdt With Ordinary Scale: 5.05 Measurement Of Displacement Using Lvdt With Using Dial Gage: 5.06 Measurement Of Current / Voltage Using Hall Effect Transducer 5.07 Thermocouple Based On – Off Controller 5.08 Measurement Of Physical Quantities – Strain, Torque And Angle, Strain Gage Module With Cantilever Beam: 5.09 Measurement Of Physical Quantities – Strain Gage Module With Industrial Load Cell: 5.10 Measurement Of Physical Quantities – Digital Torque Measurement Model 5.11 Digital Static Torque Measurement 5.12 Optical Encoder For Angle Measurement 5.13 Measurement Of Temperature By Rtd Method 5.14 Measurement Of Low Resistance By Kelvin‟S Double Bridge 5.15 Measurement Of Voltage, Current And Resistance Using Dc Potentiometer 5.16 Study Of Linear Potentiometer For Displacement Measurement 5.17 Measurement Of Inductance By Hay‟S Bridge 5.18 Measurement Of Inductance By Maxwell‟S Bridge 5.19 Measurement Of Inductance By Anderson‟S Bridge 5.20 Measurement Of Capacitance By Owen‟S Bridge 5.21 Measurement Of Capacitance By De Sauty Bridge 5.22 Measurement Of Capacitance By Schering Bridge 5.23 Measurement Of Flow Rate By Anemometer 6 Elements Of Electrical Design 6.01 Cut Section Models Of Transformer 6.02 Cut Section Models Of Dc Machine 6.03 Small Transformers Starters 3 Point Starter 6.04 Small Transformers Starters 2 Point Starter 6.05 Small Transformers Starters 4 Point Starter 6.06 Small Transformers Starters Automatic Star- Delta Starter Dol Starter9single Phase0 6.07 Choke Coils ( Capacitor Load ) Single Phase 6.08 Choke Coils ( Capacitor Load ) Three Phase 6.09 Charts To Explain Various Parts Of Machines 7 Power Electronics-1 7.01 Static And Dynamic Characteristics Of An Scr 7.02 Static And Dynamic Characteristics Of An Scr V-I Characteristics Of Scr ( C106m ) 7.03 Static And Dynamic Characteristics Of An Scr V-I Characteristics Of Scr ( C106m ) With 3 Meters 7.04 Static And Dynamic Characteristics Of An Scr V‐I Characteristics Of Diac ( Db3 ) Using Cro 7.05 Static And Dynamic Characteristics Of An Scr V‐I Characteristics Of Diac ( Db3 ) With 2 Meters 7.06 Static And Dynamic Characteristics Of An Scr V‐I Characteristics Of Diac ( Db3 ) 7.07 Static And Dynamic Characteristics Of An Scr V‐I Characteristics Of Triac ( Bt136 ) Using Cro 7.08 Static And Dynamic Characteristics Of An Scr V‐I Characteristics Of Triac ( Bt136 ) 7.09 Static And Dynamic Characteristics Of An Scr V‐I Characteristics Of Triac ( Bt136 ) With 3 Meters 7.10 Output Characteristics And Transfer Characteristics Of Power Mosfet 7.11 R And Rc Triggering Scheme And To Determine The Firing Angle Control Range 7.12 Principle Of Voltage Commutation And Current Commutation To Turn Off An Scr 7.13 Line Synchronized Ujt Triggering And Its Use For Firing The Scrs Of Ac-Dc Converter 7.14 Use Of Triac As A Fan Regulator 7.15 Performance 1-Phase Semi Converter & 1 – Phase Fully Controlled ( Bridge ) Converter With R And Rl Load Single Phase Half-Wave Controlled Converter With Power Supply 7.16 Performance 1-Phase Semi Converter & 1 – Phase Fully Controlled ( Bridge ) Converter With R And Rl Load Single Phase Fully-Controlled Bridge Converter 7.17 Performance 1-Phase Semi Converter & 1 – Phase Fully Controlled ( Bridge ) Converter With R And Rl Load Single Phase Fully Controlled Converter And Half Controlled Converter. ( Combined Unit 7.18 Time Ratio Control For Regulating The Output Voltage Of A Step-Down Chopper D.C. Step Down Mosfet Chopper With Power Supply 7.19 Time Ratio Control For Regulating The Output Voltage Of A Step-Down Chopper Step Down Chopper 7.20 Time Ratio Control For Regulating The Output Voltage Of A Step-Up Chopper Step-Up Chopper 7.21 Time Ratio Control For Regulating The Output Voltage Of A Step-Up Chopper Step Up Chopper 7.22 Time Ratio Control For Regulating The Output Voltage Of A Step-Up Chopper Step Down Chopper 7.23 Performance Of Three Phase Fully Controlled And Half Controlled Converter With R And R-L Laod 7.24 Performance Of Three Phase Fully Controlled And Half Controlled Converter With R And R-L Laod 7.25 Speed Cotnrol Of Dc Seperately Excited Motor With Phase Controlled Converter Or Dc-Dc Converter 7.26 Power Semiconductor Devices 7.27 Power Electronic Converter Kit 7.28 Cro / Dso 7.29 Choke Coil ( Induction Load ) Single Phase ( Range : 1.25 Kw ( 5 A ) ) 7.30 Choke Coil ( Induction Load ) Single Phase ( Range : 2 Kw ( 8 A ) ) 7.31 Choke Coil ( Induction Load ) Single Phase ( Range : 2.5 Kw ( 10 A ) 7.32 Choke Coil ( Induction Load ) Three Phase 7.33 Choke Coil ( Induction Load ) Three Phase ( Range : 2 Kw ( 8 A ) 7.34 Choke Coil ( Induction Load ) Three Phase Range : 2.5 Kw ( 10 A ) 7.35 Load Bank ( Resistive Load ) Single Phase Range : 1.25 Kw ( 5 A ) 7.36 Load Bank ( Resistive Load ) Single Phase Range : 2 Kw ( 8 A ) 7.37 Load Bank ( Resistive Load ) Single Phase Range : 2.5 Kw ( 10 A ) 7.38 Load Bank ( Resistive Load ) Three Phase Range : 1.25 Kw ( 5 A ) 7.39 Load Bank ( Resistive Load ) Three Phase Range: 2 Kw ( 8 A ) 7.40 Load Bank ( Resistive Load ) Three Phase Range: 2.5 Kw ( 10 A ) 8 Microprocessor & Micro Controller Interfacing 8.01 8051 Microcontroller Development Board Specification
BOQ
| Sl.No. | Item Description | Item Code / Make | Quantity | Units | |
|---|---|---|---|---|---|
| 1 | 1 | CIRCUITS AND NETWORKS LAB | |||
| 2 | 1.01 | TO MEASURE AND CALCULATE CURRENTS AND VOLTAGES FOR A GIVEN RESISTIVE CIRCUIT AND VERIFY KCL AND KVL. | 1 | Nos | |
| 3 | 1.02 | TO VERIFY SUPERPOSITION THEOREM EXPERIMENTALLY FOR A GIVEN RESISTIVE CIRCUIT CONSISTING TWO INDEPENDENT SOURCES | 1 | Nos | |
| 4 | 1.03 | TO VERIFY THEVENIN’S THEOREM EXPERIMENTALLY FOR A GIVEN CIRCUIT. | 1 | Nos | |
| 5 | 1.04 | TO VERIFY MAXIMUM POWER TRANSFER THEOREM EXPERIMENTALLY FOR A GIVEN CIRCUIT | 1 | Nos | |
| 6 | 1.05 | TO VERIFY RECIPROCITY THEOREM EXPERIMENTALLY FOR A GIVEN CIRCUIT | 1 | Nos | |
| 7 | 1.06 | TO MEASURE AND CALCULATE RC TIME CONSTANT FOR A GIVEN RC CIRCUIT | 1 | Nos | |
| 8 | 1.07 | TO MEASURE AND CALCULATE RC TIME CONSTANT FOR A GIVEN RL CIRCUIT | 1 | Nos | |
| 9 | 1.08 | TO MEASURE AND ANALYZE (SETTLING TIME, OVERSHOOT, UNDERSHOOT, ETC.) STEP RESPONSE OF FOR A GIVEN SERIES RLC CIRCUIT FOR FOLLOWING CASES: (1) ? =1 (CRITICALLY DAMPED SYSTEM), (2) ? >1(OVER DAMPED SYSTEM), (3) ? <1 (UNDER DAMPED SYSTEM). CHOOSE APPROPRIATE VALUES OF R, L, AND C TO OBTAIN EACH OF ABOVE CASES ONE AT A TIME | 1 | Nos | |
| 10 | 1.09 | TO MEASURE AND CALCULATE Z-PARAMETERS FOR A GIVEN TWO-PORT SYSTEM | 1 | Nos | |
| 11 | 1.1 | TO MEASURE AND CALCULATE Y-PARAMETERS FOR A GIVEN TWO-PORT SYSTEM. | 1 | Nos | |
| 12 | 1.11 | TO MEASURE AND CALCULATE H-PARAMETERS FOR A GIVEN TWO-PORT SYSTEM | 1 | Nos | |
| 13 | 1.12 | TO MEASURE AND CALCULATE ABCD-PARAMETERS FOR A GIVEN TWO-PORT SYSTEM | 1 | Nos | |
| 14 | 2 | DIGITAL ELECTRONICS LAB | |||
| 15 | 2.01 | VERIFICATION OF TRUTH TABLE OF LOGIC GATES | 1 | Nos | |
| 16 | 2.02 | IMPLEMENTATION OF VARIOUS LOGIC GATES USING ONLY NAND GATES | 1 | Nos | |
| 17 | 2.03 | IMPLEMENTATION OF VARIOUS LOGIC GATES USING ONLY NOR GATE | 1 | Nos | |
| 18 | 2.04 | VERIFICATION OF FUNCTION OF HALF/FULL ADDER CIRCUITS | 1 | Nos | |
| 19 | 2.05 | VERIFICATION OF FUNCTION OF HALF/FULL SUBTRACTOR CIRCUITS | 1 | Nos | |
| 20 | 2.06 | VERIFICATION OF FUNCTION OF BINARY TO GREY CODE CONVERSION | 1 | Nos | |
| 21 | 2.07 | VERIFICATION OF FUNCTION OF GREY TO BINARY CODE CONVERSION | 1 | Nos | |
| 22 | 2.08 | VERIFICATION OF FUNCTION OF 2 LINE TO 4 LINE DECODER | 1 | Nos | |
| 23 | 2.09 | VERIFICATION OF FUNCTION OF 4 LINE TO 2 LINE ENCODER | 1 | Nos | |
| 24 | 2.1 | VERIFICATION OF FUNCTION OF 4 TO 1 MULTIPLEXER | 1 | Nos | |
| 25 | 2.11 | VERIFICATION OF FUNCTION OF 1 TO 4 DEMULTIPLEXER | 1 | Nos | |
| 26 | 2.12 | STUDY OF PARITY GENERATOR | 1 | Nos | |
| 27 | 2.13 | VERIFICATION OF FUNCTION OF LATCH AND FLIP-FLOP | 1 | Nos | |
| 28 | 2.14 | VERIFICATION OF SHIFT LEFT/ RIGHT REGISTER | 1 | Nos | |
| 29 | 2.15 | VERIFICATION OF COUNTER CIRCUIT LIKE BINARY UP/DOWN COUNTER, DECIMAL COUNTER, RING COUNTER, JOHNSON COUNTER ETC | 1 | Nos | |
| 30 | 2.16 | VERIFICATION OF SEQUENTIAL CIRCUITS OTHER THAN COUNTER AND SHIFT REGISTERS | 1 | Nos | |
| 31 | 2.17 | VERIFICATION OF SPECIFICATION AND PERFORMANCE INDICES OF D/A AND A/D CONVERTERS | 1 | Nos | |
| 32 | 2.18 | TO STUDY THE D/A AND A/D CONVERTER IC WITH ITS SPECIFICATIONS | 1 | Nos | |
| 33 | 2.19 | Bread Board Having 1380 Contact points & 2 terminals | 1 | Nos | |
| 34 | 2.2 | Bread Board Having 1580 Contact points & 2 terminals | 1 | Nos | |
| 35 | 2.21 | Bread Board Having 1680 Contact points & 3 terminals | 1 | Nos | |
| 36 | 2.22 | Power Project Board (Having 2420 Contact points & 4 terminals with 5V,1Amp. and ± 2 to15V, 500mA Power Supplies) | 1 | Nos | |
| 37 | 2.23 | Bread Board Circuit Lab (with A.C./ D.C Power Supplies Pulser, Clock Generator, Gates and 2 DPM’s). | 1 | Nos | |
| 38 | 2.24 | 3MHz Microcontroller Based Function Pulse Generator with 40MHz Frequency Counter | 1 | Nos | |
| 39 | 2.25 | 30MHz Analog Oscilloscope | 1 | Nos | |
| 40 | 2.26 | DIGITAL LOGIC TRAINER KITS : Study of OR Logic Gate,AND Logic Gate,NOT Logic Gate,Ex_OR Logic Gate,OR / NOR Logic Gate,AND / NAND Logic Gate,NOT / Buffer Logic Gate,Ex_OR / Ex_NOR Logic Gate,Study of all Digital seven Logic Gates. | 1 | Nos | |
| 41 | 2.27 | MULTIMETER | 1 | Nos | |
| 42 | 2.28 | SINGLE POWER SUPPLY 0-30V, 2 A | 1 | Nos | |
| 43 | 2.29 | DUAL POWER SUPPLY (2 X 0-30V - 2A) | 1 | Nos | |
| 44 | 2.3 | Function Generator | 1 | Nos | |
| 45 | 2.31 | OSCILLOSCOPE | 1 | Nos | |
| 46 | 3 | DC MACHINE LAB | |||
| 47 | 3.01 | SQUIRREL CAGE INDUCTION MOTOR CONNECTED TO SELF EXCITED DC GENERATOR | 1 | Nos | |
| 48 | 3.02 | SLIP RING INDUCTION MOTOR CONNECTED TO SELF EXCITED DC GENERATOR | 1 | Nos | |
| 49 | 3.03 | SINGLE PHASE INDUCTION MOTOR | 1 | Nos | |
| 50 | 3.04 | CUT SECTION MODELS OF | 1 | Nos | |
| 51 | 3.05 | DC SHUNT MOTOR COUPLED TO A THREE PHASE ALTERNATOR - PREFERABLY SALIENT POLE TYPE (TWO SETS) | 1 | Nos | |
| 52 | 3.06 | AUTO SYNCHRONOUS MOTOR | 1 | Nos | |
| 53 | 4 | AC MACHINE LAB | |||
| 54 | 4.01 | DESIGN OF THREE PHASE SQUIRREL CAGE INDUCTION MOTOR | 1 | Nos | |
| 55 | 4.02 | DESIGN OF THREE PHASE SLIP RING INDUCTION MOTOR | 1 | Nos | |
| 56 | 4.03 | DESIGN OF SINGLE PHASE INDUCTION MOTOR | 1 | Nos | |
| 57 | 4.04 | DESIGN OF SALIENT POLE LOW SPEED ALTERNATOR | 1 | Nos | |
| 58 | 5 | ELECTRICAL MEASUREMENTS AND MEASURING INSTRUMENTS LAB | |||
| 59 | 5.01 | MEASUREMENT OF RESISTANCE USING WHEASTONE’S BRIDGE | 1 | Nos | |
| 60 | 5.02 | MEASUREMENT OF RESISTANCE USING KELVIN DOUBLE BRIDGE | 1 | Nos | |
| 61 | 5.03 | EXTENSION OF RANGE OF WATTMETER USING CT & PT | 1 | Nos | |
| 62 | 5.04 | MEASUREMENT OF DISPLACEMENT USING LVDT with ordinary scale: | 1 | Nos | |
| 63 | 5.05 | MEASUREMENT OF DISPLACEMENT USING LVDT with using dial gage: | 1 | Nos | |
| 64 | 5.06 | MEASUREMENT OF CURRENT/ VOLTAGE USING HALL EFFECT TRANSDUCER | 1 | Nos | |
| 65 | 5.07 | THERMOCOUPLE BASED ON – OFF CONTROLLER | 1 | Nos | |
| 66 | 5.08 | MEASUREMENT OF PHYSICAL QUANTITIES – STRAIN, TORQUE AND ANGLE,\nSTRAIN GAGE MODULE WITH CANTILEVER BEAM: | 1 | Nos | |
| 67 | 5.09 | MEASUREMENT OF PHYSICAL QUANTITIES – STRAIN GAGE MODULE WITH INDUSTRIAL LOAD CELL: | 1 | Nos | |
| 68 | 5.1 | MEASUREMENT OF PHYSICAL QUANTITIES – DIGITAL TORQUE MEASUREMENT MODEL | 1 | Nos | |
| 69 | 5.11 | DIGITAL STATIC TORQUE MEASUREMENT | 1 | Nos | |
| 70 | 5.12 | OPTICAL ENCODER FOR ANGLE MEASUREMENT | 1 | Nos | |
| 71 | 5.13 | MEASUREMENT OF TEMPERATURE BY RTD METHOD | 1 | Nos | |
| 72 | 5.14 | MEASUREMENT OF LOW RESISTANCE BY KELVIN?S DOUBLE BRIDGE | 1 | Nos | |
| 73 | 5.15 | MEASUREMENT OF VOLTAGE, CURRENT AND RESISTANCE USING DC POTENTIOMETER | 1 | Nos | |
| 74 | 5.16 | Study of linear potentiometer for displacement measurement | 1 | Nos | |
| 75 | 5.17 | MEASUREMENT OF INDUCTANCE BY HAY?S BRIDGE | 1 | Nos | |
| 76 | 5.18 | MEASUREMENT OF INDUCTANCE BY MAXWELL?S BRIDGE | 1 | Nos | |
| 77 | 5.19 | MEASUREMENT OF INDUCTANCE BY ANDERSON?S BRIDGE | 1 | Nos | |
| 78 | 5.2 | MEASUREMENT OF CAPACITANCE BY OWEN?S BRIDGE | 1 | Nos | |
| 79 | 5.21 | MEASUREMENT OF CAPACITANCE BY DE SAUTY BRIDGE | 1 | Nos | |
| 80 | 5.22 | MEASUREMENT OF CAPACITANCE BY SCHERING BRIDGE | 1 | Nos | |
| 81 | 5.23 | MEASUREMENT OF FLOW RATE BY ANEMOMETER | 1 | Nos | |
| 82 | 6 | ELEMENTS OF ELECTRICAL DESIGN | |||
| 83 | 6.01 | CUT SECTION MODELS OF TRANSFORMER | 1 | Nos | |
| 84 | 6.02 | CUT SECTION MODELS OF DC MACHINE | 1 | Nos | |
| 85 | 6.03 | SMALL TRANSFORMERS STARTERS 3 Point Starter | 1 | Nos | |
| 86 | 6.04 | SMALL TRANSFORMERS STARTERS 2 Point Starter | 1 | Nos | |
| 87 | 6.05 | SMALL TRANSFORMERS STARTERS 4 Point Starter | 1 | Nos | |
| 88 | 6.06 | SMALL TRANSFORMERS STARTERS Automatic Star- Delta Starter DOL Starter9Single Phase0 | 1 | Nos | |
| 89 | 6.07 | CHOKE COILS (CAPACITOR LOAD) Single Phase | 1 | Nos | |
| 90 | 6.08 | CHOKE COILS (CAPACITOR LOAD) Three Phase | 1 | Nos | |
| 91 | 6.09 | CHARTS TO EXPLAIN VARIOUS PARTS OF MACHINES | 1 | Nos | |
| 92 | 7 | POWER ELECTRONICS-1 | |||
| 93 | 7.01 | STATIC AND DYNAMIC CHARACTERISTICS OF AN SCR | 1 | Nos | |
| 94 | 7.02 | STATIC AND DYNAMIC CHARACTERISTICS OF AN SCR V-I characteristics of SCR (C106M) | 1 | Nos | |
| 95 | 7.03 | STATIC AND DYNAMIC CHARACTERISTICS OF AN SCR V-I characteristics of SCR (C106M) with 3 meters | 1 | Nos | |
| 96 | 7.04 | STATIC AND DYNAMIC CHARACTERISTICS OF AN SCR V-I characteristics of DIAC (DB3) using CRO | 1 | Nos | |
| 97 | 7.05 | STATIC AND DYNAMIC CHARACTERISTICS OF AN SCR V-I characteristics of DIAC (DB3) with 2 meters | 1 | Nos | |
| 98 | 7.06 | STATIC AND DYNAMIC CHARACTERISTICS OF AN SCR V-I characteristics of DIAC (DB3) | 1 | Nos | |
| 99 | 7.07 | STATIC AND DYNAMIC CHARACTERISTICS OF AN SCR V-I characteristics of TRIAC (BT136) using CRO | 1 | Nos | |
| 100 | 7.08 | STATIC AND DYNAMIC CHARACTERISTICS OF AN SCR V-I characteristics of TRIAC (BT136) | 1 | Nos | |
| 101 | 7.09 | STATIC AND DYNAMIC CHARACTERISTICS OF AN SCR V-I characteristics of TRIAC (BT136) with 3 meters | 1 | Nos | |
| 102 | 7.1 | OUTPUT CHARACTERISTICS AND TRANSFER CHARACTERISTICS OF POWER MOSFET | 1 | Nos | |
| 103 | 7.11 | R AND RC TRIGGERING SCHEME AND TO DETERMINE THE FIRING ANGLE CONTROL RANGE | 1 | Nos | |
| 104 | 7.12 | PRINCIPLE OF VOLTAGE COMMUTATION AND CURRENT COMMUTATION TO TURN OFF AN SCR | 1 | Nos | |
| 105 | 7.13 | LINE SYNCHRONIZED UJT TRIGGERING AND ITS USE FOR FIRING THE SCRs OF AC-DC CONVERTER | 1 | Nos | |
| 106 | 7.14 | USE OF TRIAC AS A FAN REGULATOR | 1 | Nos | |
| 107 | 7.15 | PERFORMANCE 1-PHASE SEMI CONVERTER & 1 – PHASE FULLY CONTROLLED (BRIDGE) CONVERTER WITH R AND RL LOAD Single Phase Half-Wave Controlled Converter with Power Supply | 1 | Nos | |
| 108 | 7.16 | PERFORMANCE 1-PHASE SEMI CONVERTER & 1 – PHASE FULLY CONTROLLED (BRIDGE) CONVERTER WITH R AND RL LOAD Single Phase fully-controlled Bridge Converter | 1 | Nos | |
| 109 | 7.17 | PERFORMANCE 1-PHASE SEMI CONVERTER & 1 – PHASE FULLY CONTROLLED (BRIDGE) CONVERTER WITH R AND RL LOAD SINGLE PHASE FULLY CONTROLLED CONVERTER AND HALF CONTROLLED CONVERTER.(COMBINED UNIT | 1 | Nos | |
| 110 | 7.18 | TIME RATIO CONTROL FOR REGULATING THE OUTPUT VOLTAGE OF A STEP-DOWN CHOPPER D.C. STEP DOWN MOSFET CHOPPER WITH POWER SUPPLY | 1 | Nos | |
| 111 | 7.19 | TIME RATIO CONTROL FOR REGULATING THE OUTPUT VOLTAGE OF A STEP-DOWN CHOPPER STEP DOWN CHOPPER | 1 | Nos | |
| 112 | 7.2 | TIME RATIO CONTROL FOR REGULATING THE OUTPUT VOLTAGE OF A STEP-UP CHOPPER STEP-UP CHOPPER | 1 | Nos | |
| 113 | 7.21 | TIME RATIO CONTROL FOR REGULATING THE OUTPUT VOLTAGE OF A STEP-UP CHOPPER STEP UP CHOPPER | 1 | Nos | |
| 114 | 7.22 | TIME RATIO CONTROL FOR REGULATING THE OUTPUT VOLTAGE OF A STEP-UP CHOPPER STEP DOWN CHOPPER | 1 | Nos | |
| 115 | 7.23 | PERFORMANCE OF THREE PHASE FULLY CONTROLLED AND HALF CONTROLLED CONVERTER WITH R AND R-L LAOD | 1 | Nos | |
| 116 | 7.24 | PERFORMANCE OF THREE PHASE FULLY CONTROLLED AND HALF CONTROLLED CONVERTER WITH R AND R-L LAOD | 1 | Nos | |
| 117 | 7.25 | SPEED COTNROL OF DC SEPERATELY EXCITED MOTOR WITH PHASE CONTROLLED CONVERTER OR DC-DC CONVERTER | 1 | Nos | |
| 118 | 7.26 | POWER SEMICONDUCTOR DEVICES | 1 | Nos | |
| 119 | 7.27 | POWER ELECTRONIC CONVERTER KIT | 1 | Nos | |
| 120 | 7.28 | CRO/DSO | 1 | Nos | |
| 121 | 7.29 | CHOKE COIL (INDUCTION LOAD) Single Phase (Range : 1.25 kw (5 A)) | 1 | Nos | |
| 122 | 7.3 | CHOKE COIL (INDUCTION LOAD) Single Phase (Range : 2 kw (8 A)) | 1 | Nos | |
| 123 | 7.31 | CHOKE COIL (INDUCTION LOAD) Single Phase (Range : 2.5 kw (10 A) | 1 | Nos | |
| 124 | 7.32 | CHOKE COIL (INDUCTION LOAD) Three Phase | 1 | Nos | |
| 125 | 7.33 | CHOKE COIL (INDUCTION LOAD) Three Phase (Range : 2 kw (8 A) | 1 | Nos | |
| 126 | 7.34 | CHOKE COIL (INDUCTION LOAD) Three Phase Range : 2.5 kw (10 A) | 1 | Nos | |
| 127 | 7.35 | LOAD BANK (RESISTIVE LOAD) Single Phase Range : 1.25 kw (5 A) | 1 | Nos | |
| 128 | 7.36 | LOAD BANK (RESISTIVE LOAD) Single Phase Range : 2 kw (8 A) | 1 | Nos | |
| 129 | 7.37 | LOAD BANK (RESISTIVE LOAD) Single Phase Range : 2.5 kw (10 A) | 1 | Nos | |
| 130 | 7.38 | LOAD BANK (RESISTIVE LOAD) Three Phase Range : 1.25 kw (5 A) | 1 | Nos | |
| 131 | 7.39 | LOAD BANK (RESISTIVE LOAD) Three Phase Range: 2 kw (8 A) | 1 | Nos | |
| 132 | 7.4 | LOAD BANK (RESISTIVE LOAD) Three Phase Range: 2.5 kw (10 A) | 1 | Nos | |
| 133 | 8 | Microprocessor & micro controller interfacing | |||
| 134 | 8.01 | 8051 MICROCONTROLLER DEVELOPMENT BOARD Specification | 1 | Nos |
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