List of equipments

List of equipments

• Error Detector Using Potentiometer and Synchros.
• Time Response Behavior of Different Blocks of Control System.
• System Identification.
• Ziegler-Nichols tuning of PID Controller.
• To study the effect of addition of pole on transient response to the second order closed loop control system by using MATLAB & LABVIEW.
• To study the stability analysis of linear system.
• To study the effect of addition of zero & pole to open loop transfer function of second order unity feedback control system by using root locus technique (using MATLAB& LABVIEW).
• To study the effect of addition of pole on frequency response to the second order closed loop control system by using MATLAB & LABVIEW.
• To study the frequency response of Lag, Lead, Lag-Lead network.
• To study the speed characteristics of BLDC Motor.

List of equipments

• Temp. Control System Trainer
• BLDC Motor trainer system
• PID Controller
• Relay Control System
• Stability analysis of Linear System
• Transducer Instrumentation & Control trainer
• Qbot
• AERO
• Inverted Pendulum

List of equipments

• Study of chopper/DC-DC converter-controlled DC Drive
• Study of Rectifier controlled DC Drive.
• Study of PWM controlled Inverter fed Induction Motor
• Study of electrical braking operation of DC Motor
• Study of electrical braking operation of AC motor
• Study of V/f control operation of 3phase induction motor drive.
• Study of permanent magnet synchronous motor drive fed by PWM Inverter.
• Study of Closed-Loop Control of DC Drives.
• Study of slip power recovery control of induction motors.
• Study of two-quadrant operation of DC-DC Converter.

List of equipments

• DC-Motor Gen System (3kw)-NI LabVIEW based
• Induction Generator System- NI LabVIEW based instruments.
• 3-phase Synch motor gen System, 3 kW
• Three Phase Squirrel Cage Induction –Controlled by NI- LabVIEW and VFD Drives
• Switched reluctance Motor kit 0.3 kW
• 3-Phase Universal Motor Controller
• PM Synch Motor Kit 3 kW
• PMBLDC- Kit 0.25 kW
• Solar and Wind Power Trainer Kit (NI LabView)
• Smart Grid Monitoring Module
• Three-phase half and fully controlled rectifier.
• Variable frequency drives.
• Voltage Source Inverter.

ELECTRIAL MACHINES LABORATORY- I

LIST OF EXPERIMENTS:

• To determine the efficiency of single-phase Transformer by conducting Sumpner’s back- to- back test.
• To conduct load test on DC shunt generator and to draw the external and internal characteristics of DC shunt generator.
• conduct Hopkinson’s test on a pair of identical DC machines to pre-determine the efficiency of the machine as generator and as motor.
• To perform the scott connection of transformer and to obtain the two-phase supply from three phase supply.
• To determine the efficiency of the two given dc series motors which are mechanically coupled.
• To study of the speed control of a dc shunt motor using conventional Ward- Leonard method.
• To draw the magnetization characteristics of dc shunt generator.
• To conduct brake test on DC compound motor for long shunt cumulative &differential connections and to draw the performance characteristics.
• To perform parallel operation of two dissimilar Transformer and determine combined and individual transfer efficiency.
• To perform the Swinburne’s test of the DC machine and pre-determine the efficiency of the machine as generator and as motor.s

ELECTRIAL MACHINES LABORATORY- II

LIST OF EXPERIMENTS:

• To determine speed- torque characteristics of single-phase Induction motor and study the effect of voltage variation.
• To draw the circle diagram of 3-phase induction motor by conducting no load and blocked rotor test.
• To study speed control of three phase Induction motor by varying supply voltage and keeping v/f constant.
• To determine V-curve and inverted V-curve of a three-phase synchronous motor.
• To predetermine the regulation of 3-phase alternator by EMF and MMF methods and also draw the vector diagram.
• To determine the efficiency of 3-phase induction motor by performing load test.
• To study synchronization of an alternator with infinite bus using (A)Dark lamp method (B)Two bright and one dark lamp method
• To determine the percentage regulation of an alternator by ZPF method.
• To study the power angle curve of synchronous generator.
• To determine xd and xq of a salient pole synchronous motor using the slip test.

List of Major Equipment’s

• 3-Phase Rectifier
• DC Shunt Motor
• Squirrel Cage IM
• Dc Power Supply SCR Based
• DC compound Gen Set
• Slip Ring Motor
• Synchronous Motor 4 pole coupled with DC Shunt Generator
• Synchronous Motor, with Induction motor Coupled Dc Shunt gen. 220V,3 kW, 1500rpm
• Synchronous Motor, 1HP, Coupled Dc Shunt gen. 220V, 3kW, 1550 rpm
• Servo Stabilizer 3-ph
• Multi Winding Transformer

List of Experiments:

• Measurement of unknown medium resistance by using Wheat Stone Bridge
• Measurement of unknown small resistance by using Kelvin Double Bridge
• Measurement of unknown medium inductance by using Maxwell Bridge
• Measurement of unknown high inductance by using Hay’ Bridge
• Study of analog meters—PMMC, Electro Dynamo Meter, Moving Iron
• Measurement of small distance variations by using LVDT
• Measurement of weight by using
• Measurement of Torque
• Study of CRO (Cathode Ray Oscilloscope)
• Measurement Wind using Digital Anemometer
• Measurement of solar irradiance using Digital Pyranometer (Solar Power meter)

List of Major Equipment’s

• Wheat Stone Bridge Source-5V R1 -1KΩ, 10KΩ, 100KΩ. R2- 10K. R3-, 10Ω, 100Ω, 1KΩ, 10KΩ, 100KΩ
• Kelvin Double Bridge Source-5V. R1 -1KΩ, 10KΩ, 100KΩ. R2- 100Ω, R3-1KΩ, 10KΩ, 100KΩ.
• Maxwell Bridge Source-1KHz Oscillator R1-10K. R2-0.1mf. R3 -10Ω, 100Ω, 1KΩ, 10KΩ, 100KΩ
• Hay’ Bridge Source-1KHz Oscillator R2 -10Ω, 100Ω, 1KΩ, 10KΩ, 100KΩ. R3 -10Ω. R4 -10Ω
• PMMC, Electro Dynamo Meter, Moving Iron
• LVDT Input 203 AC Display 0-10 V Displacement range 0-20 mm
• Strain Gauge Measuring Range-0-5,Kg Non-linearity Error - ±1% Excitation Source-D.C. Excitation (5Volts) Display- 3(1/2) Digit LED
• Torque Measuring Range-0-2.5Newton meter. Non-linearity Error - ±1% Source-D.C. Excitation (5Volts) ; Working Temperature-0-500C Display- 3(1/2) Digit LED
• CRO (Cathode Ray Oscilloscope)
• Anemometer Display-LCD ,Size-65x25 mm Operating Temperature-0-500C(32-1220F) Air Velocity Sensor Structure- Conventional twisted vane arms and low friction ball-bearing design. Power supply-006P DC 9V battery Power Consumption-Approx DC 9mA Weight-325g/0.72lb(Including Battery)
• Pyranometer (Solar Power meter) Sensor-High Sensitivity Silicon Photodiode Range-0~2000W/m2(0~634BTU/ft2.h) Tilt angle range- 00~90 Store temp .&relative humidity- -100C~600 C(140F~1400FLess than 85%RH) Memory-20 point memory Accessories-9V battery

List of equipments

• To study the V-I characteristics of SCR.
• To study the V-I characteristics of TRIAC.
• To study UJT characteristics.
• To study SCR phase control.
• To study SCR commutation techniques.
• To study the performance of boost converter.
• To study the performance of buck converter.
• To study the operation of full bridge-controlled converter with R-Load.
• To study single phase full bridge inverter.
• 10. To study single phase ac voltage controller a. Based on SCR b. Based on TRIAC

List of Major Equipment’s

• PEC16M1B Trainer Kit
• PEC16M1C Trainer Kit
• ME547D Trainer Kit
• SCR-06 Trainer Kit
• SCR commutation (ME-793) Trainer Kit
• DC-DC Boost converter (VSMPS-06A)
• DC-DC Buck converter (VSMPS-05A)
• SPBC-101 Trainer Kit
• PEC16M3 & 16HV2B Trainer Kit
• PEC14M14AC Trainer Kit

List of Experiments (Soft Computing Techniques Lab)

• Programs on Matrix operations to understand the basic concepts of MatLab.
• To print all the Continues Discrete Membership Functions by using MatLab.
• To perform different fuzzy operations on Membership Functions by using MatLab.
• Design a Fuzzy controller for Air conditioning system/Washing Machine.
• Identification of a system using Perceptron/Radial Base Function Network (RBFN).
• Identification of a system by using Backpropagation algorithm.
• Minimizing the objective function by using Genetic Algorithm (GA)
• Minimizing the objective function by using Particle Swarm Optimization (PSO)
• Minimizing the objective function by using Cuckoo Search Algorithm (CSA)
• Minimizing the objective function by using Ant Colony Optimization (ACO)
• Minimizing the objective function by using Differential Evolutionary (DE) algorithm
• Minimizing the objective function by using Cat Swarm Optimization (CSO)

List of Experiments (Power System Lab)

MATLAB/SIMULINK Based Experiments

• Static Load Flow Analysis of Standard IEEE bus system using N-R method
• Dynamic Analysis of IEEE 9 bus System
• Small signal Stability Analysis of Single Machine Infinite Bus System
• Short circuit Analysis of IEEE 9 bus power system

DIgSilient Power Factory Based Experiments-

• Modeling and Analysis of Low Voltage Distribution Network (Mesh and Radial).
• Study of Relay Coordination and Time grading Calculation using PowerFactory.
• Power Quality and Harmonics Analysis of Power System.
• Modeling IEEE 8 bus power system and analyzing/creating different operation Scenarios using PowerFactory.
• Transient stability & Voltage Stability Analysis of Standard Power System.
• Contingency Analysis of standard Power System
.

List of Software

• DigSalient PowerFactory 2018
• MatLab 2019b
• LabView 2013

Desktop Computer Details

• Total No of Computer- 27
• Specification Intel Core I i5-4590 CPU @3.30 GHz, RAM – 4GB, OS-64bit Microsoft
• Windows 10

List of equipments

• To study the protection of transformer with percentage biased differential relay (Microcontroller based numerical relay).
• To study IDMT over current relay (single phase) and to determine the pickup and reset value and determine the time and current characteristics.
• To study the working of Buchholz relay.
• To analyze the underground cable fault using Varley loop test.
• To study the directional over current protection.
• To study the breakdown voltage of transformer oil by adjusting electrode gap length.
• To study and draw the characteristics of numerical overcurrent relay.
• To study and analyze the different type of symmetrical and unsymmetrical faults occurs in transmission line.
• To study microcontroller based over/under voltage relay.
• To study microcontroller based over/under voltage relay.
• To study the complete protection of alternator unit.
• To study the protection of feeder system.
• To study the principle of reverse power protection.

List of Major Equipment’s

• IDMT over current relay kit (ME2471R)
• Buchholz relay unit
• Varley loop test kit (VPL-83A)
• Transformer oil test kit
• Feeder protection unit
• Symmetrical and unsymmetrical fault analysis (NVI57065)
• Microcontroller based over/under voltage relay (VPL-05)
• Reverse power protection Panel
• Protection of Alternator unit (PWS-3012A)
• Percentage biased differential relay
• (ME2473RD)
• Directional overcurrent relay (JRP 011)
• Numerical overcurrent relay (ANSI NO. 50&51)

List of equipments

• Design simulation of Single phase rectifier with R, RL and RLE loads using MATLAB.
• Study and analysis of open and closed loop control of three phase induction motor using DSP microcontroller board.
• Study and analysis of open and closed loop control of BLDC motor using DSP microcontroller board.
• Study and analysis of open and closed loop control of Switch Reluctance Motor using FPGA.
• Study and analysis of open and closed loop control of PMDC motor using DSP microcontroller board.
• Study and analysis of three level diode clamp three phase MLI for open and closed loop control of Induction motor using FPGA Board.
• Study and analysis of five level cascaded MLI operation through FPGA control Board.
• Study and analysis of various operation by Matrix Converter through FPGA Controlled Board.
• Study and analysis of closed loop control of BLDC and Three Phase Induction Motor parameter on Real Time GUI FPGA platform.

List of Major Equipment’s

• Real Time – GUI FPGA Controller Based



I. Induction Motor Set up




II. DC Motor Drive Set Up




III. BLDC Motor Drive Set up




IV. SR Motor Drive Set up.

• Matrix Converter Power Module
• Three Phase Five Level Cascaded Multilevel Inverter.
• Three Phase Three Level Diode Clamped Multilevel Inverter Power Module.
• DSPIC4011 Microcontroller Based PWM Controller.
• FPGA PWM Controller
• Single IGBT Project card with Opt coupler based driver circuit
• Dual IGBT Project card with Opt coupler based driver circuit
• Opal RT Real Time HIL Simulator and HIL Controller
• Typhoon HIL Simulator.
• Workstation Dell

The Department of Electrical Engineering, NIT Uttarakhand has an Industry Collaborated lab established by Mitsubishi Electric India Pvt. Ltd. under MoU between NITUK and MITSUBISHI Electric India Pvt. Ltd. The following equipment's/software are provided to the Electrical Engineering Department of NIT Uttarakhand under MoU between NITUK and MITSUBISHI Electric India Pvt. Ltd.  

1. MELSOFT MX OPC Server (Integrated solution for plant engineering)

2.MELSOFT MC Works 64  (Integrated solution for plant engineering)

3. FA learning kit; Inverter (FR-A820)and Servo Amplifier(MR-J4W3)

• Aero
• Qbot
• Inverted Pendulum
• FPGA PWM Controller
• OPAL-RT-Real Time Digital HIL Simulator for Power System, Power Electronics Machine and Drives Applications
• Typhoon HIL Hardware in the Loop Real Time Simulator Power Electronics and Renewable Energy (Simulator)
• Digital Signal Processor (TMS320F28335)
• Matrix Converter Power Module
• Three Phase Five Level Cascaded Multilevel Inverter.
• Electrical Vehicle (E-Rickshaw)

Software

• MatLab 2019b
• DigSalient PowerFactory 2018
• Labview 2013