Power Electronics Single Phase Uncontrolled Half Wave Rectifiers. Dr. Firas Obeidat

Similar documents
LECTURE.3 : AC-DC CONVERSION

Lecture Note. Uncontrolled and Controlled Rectifiers

Single-Phase Half-Wave Rectifiers

CHAPTER 4 FULL WAVE RECTIFIER. AC DC Conversion

Experiment #2 Half Wave Rectifier

Chapter 33. Alternating Current Circuits

I. Introduction to Simple Circuits of Resistors

Paper-1 (Circuit Analysis) UNIT-I

Chapter 6: Alternating Current. An alternating current is an current that reverses its direction at regular intervals.

CHAPTER 9. Sinusoidal Steady-State Analysis

LINEAR CIRCUIT ANALYSIS (EED) U.E.T. TAXILA 07 ENGR. M. MANSOOR ASHRAF

Chapter 31 Alternating Current

Electronic I Lecture 3 Diode Rectifiers. By Asst. Prof Dr. Jassim K. Hmood

AC Theory and Electronics

Lecture 4 - Three-phase circuits, transformer and transient analysis of RLC circuits. Figure 4.1

CHAPTER 6: ALTERNATING CURRENT

EXPERIMENT 4: RC, RL and RD CIRCUITs

EXPERIMENT 4: RC, RL and RD CIRCUITs

v o v an i L v bn V d Load L v cn D 1 D 3 D 5 i a i b i c D 4 D 6 D 2 Lecture 7 - Uncontrolled Rectifier Circuits III

Unit-3-A. AC to AC Voltage Converters

Three-Phase, Step-Wave Inverter Circuits

Exercise 9: inductor-resistor-capacitor (LRC) circuits

DEPARTMENT OF ELECTRICAL ENGINEERING LAB WORK EE301 ELECTRONIC CIRCUITS

CHAPTER THREE DIODE RECTIFIERS

Electronic Circuits. Diode Applications. Dr. Manar Mohaisen Office: F208 Department of EECE

SIDDHARTH GROUP OF INSTITUTIONS :: PUTTUR (AUTONOMOUS) Siddharth Nagar, Narayanavanam Road QUESTION BANK (DESCRIPTIVE) UNIT I INTRODUCTION

Simple AC Circuits. Introduction

VALLIAMMAI ENGINEERING COLLEGE

Homework Assignment 06

1) Consider the circuit shown in figure below. Compute the output waveform for an input of 5kHz

Sinusoids and Phasors (Chapter 9 - Lecture #1) Dr. Shahrel A. Suandi Room 2.20, PPKEE

Lecture (04) PN Diode applications II

Electromagnetic Oscillations and Currents. March 23, 2014 Chapter 30 1

Power Electronics Lecture No. 7 Dr. Mohammed Tawfeeq. (a) Circuit (b) Waveform Fig.7.1

Circuit Analysis-II. Circuit Analysis-II Lecture # 2 Wednesday 28 th Mar, 18

ECE 2006 University of Minnesota Duluth Lab 11. AC Circuits

BEST BMET CBET STUDY GUIDE MODULE ONE

(A) im (B) im (C)0.5 im (D) im.

Experiment 1 LRC Transients

Bakiss Hiyana binti Abu Bakar JKE, POLISAS BHAB

EXPERIMENT 5 : DIODES AND RECTIFICATION

2.0 AC CIRCUITS 2.1 AC VOLTAGE AND CURRENT CALCULATIONS. ECE 4501 Power Systems Laboratory Manual Rev OBJECTIVE

Power Supplies. Linear Regulated Supplies Switched Regulated Supplies Batteries

Worksheet for Exploration 31.1: Amplitude, Frequency and Phase Shift

KINGS COLLEGE OF ENGINEERING DEPARTMENT OF ELECTRICAL AND ELECTRONICS ENGINEERING QUESTION BANK UNIT I BASIC CIRCUITS ANALYSIS PART A (2-MARKS)

CHAPTER 7. Response of First-Order RL and RC Circuits

PHYSICS - CLUTCH CH 29: ALTERNATING CURRENT.

Power Electronics (25) Please prepare your student ID card (with photo) on your desk for the attendance check.

Lesson 1 of Chapter Three Single Phase Half and Fully Controlled Rectifier

EXPERIMENT 5 : THE DIODE

Real Analog Chapter 10: Steady-state Sinusoidal Analysis

ECE 215 Lecture 8 Date:

Chapter 6: Alternating Current

Circuit operation Let s look at the operation of this single diode rectifier when connected across an alternating voltage source v s.

Sample Question Paper

Figure Derive the transient response of RLC series circuit with sinusoidal input. [15]

Homework Assignment 02

LRC Circuit PHYS 296 Your name Lab section

LENDI INSTITUTE OF ENGINEERING & TECHNOLOGY

INSTITUTE OF AERONAUTICAL ENGINEERING (Autonomous) Dundigal, Hyderabad

Chapter 11. Alternating Current

RC circuit. Recall the series RC circuit.

L02 Operational Amplifiers Applications 1

Başkent University Department of Electrical and Electronics Engineering EEM 214 Electronics I Experiment 2. Diode Rectifier Circuits

2 The Power Diode. 2.1 Diode as a Switch. 2.2 Properties of PN Junction

AC Power Instructor Notes

3.4. Operation in the Reverse Breakdown

POWER ELECTRONICS LAB MANUAL

Basic Electronic Devices and Circuits EE 111 Electrical Engineering Majmaah University 2 nd Semester 1432/1433 H. Chapter 2. Diodes and Applications

Sascha Stegen School of Electrical Engineering, Griffith University, Australia

UNIT I LINEAR WAVESHAPING

EXPERIMENT 8: LRC CIRCUITS

Uncovering a Hidden RCL Series Circuit

ECEN5817 Lecture 4. Transfer function H(s) ) (t) i R. (t) v R

Power Electronics (Sample Questions) Module-1

Alternating current circuits- Series RLC circuits

Module 4. AC to AC Voltage Converters. Version 2 EE IIT, Kharagpur 1

1. Simulate the circuit long enough (about 5 time constants) to capture enough information about the. i s R. S v C. Figure 1: Problem PS3.

Fundamentals of Microelectronics

Examples to Power Supply

Oscillators. An oscillator may be described as a source of alternating voltage. It is different than amplifier.

1Ph_FW_AC-Controller_R-L_Load -- Overview

6. Explain control characteristics of GTO, MCT, SITH with the help of waveforms and circuit diagrams.

Diodes. Sections

Synchro and Resolver Conversion. Appendix F. Appendix F EFFECTS OF QUADRATURE SIGNALS ON SERVO SYSTEMS

EE 42/100: Lecture 8. 1 st -Order RC Transient Example, Introduction to 2 nd -Order Transients. EE 42/100 Summer 2012, UC Berkeley T.

Experiment 7: Undriven & Driven RLC Circuits

Conventional Single-Switch Forward Converter Design

DHANALAKSHMI SRINIVASAN COLLEGE OF ENGINEERING AND TECHNOLY Mamallapuram chennai

Lab 3 Transient Response of RC & RL Circuits

ECE215 Lecture 7 Date:

In-Class Exercises for Lab 2: Input and Output Impedance

AC Circuits. Nikola Tesla

Sheet 2 Diodes. ECE335: Electronic Engineering Fall Ain Shams University Faculty of Engineering. Problem (1) Draw the

ELEC387 Power electronics

ENGR-4300 Electronic Instrumentation Quiz 2 Fall 2011 Name Section

EEE118: Electronic Devices and Circuits

ELEN-325. Introduction to Electronic Circuits: Design Approach. ELEN-325. Part IV. Diode s Applications

WALJAT COLLEGES OF APPLIED SCIENCES In academic partnership with BIRLA INSTITUTE OF TECHNOLOGY Question Bank Course: EC Session:

RC and RL Circuits. Figure 1: Capacitor charging circuit.

Transcription:

Power Electronics Single Phase Uncontrolled Half Wave Rectifiers Dr. Firas Obeidat 1

Table of contents 1 Resistive Load 2 R-L Load 3 R-L Load with Freewheeling Diode 4 Half Wave Rectifier with a Capacitor Filter 2

Introduction A rectifier is an electrical device that converts alternating current (AC) to direct current (DC), which flows in only one direction. The process is known as rectification. There are many applications for rectifiers. Some of them are: variable speed dc drives, battery chargers, DC power supplies and Power supply for a specific application like electroplating. 3

Resistive Load A basic half-wave rectifier with a resistive load is shown in fig. a. The source is ac, and the objective is to create a load voltage that has a nonzero dc component. The diode is a basic electronic switch that allows current in one direction only. For the positive half-cycle of the source in this circuit, the diode is on (forward-biased). Considering the diode to be ideal, the voltage across a forward-biased diode is zero and the current is positive. For the negative half-cycle of the source, the diode is reverse-biased, making the current zero. The voltage across the reverse-biased diode is the source voltage, which has a negative value. 4

Resistive Load The dc component V o of the output voltage is the average value of a half-wave rectified sinusoid V dc = The dc component of the current for the purely resistive load is I dc = The rms values of V o and I o can be written as 5

Resistive Load The Average output dc power is The rms output dc power is p dc = V dc I dc = I dc 2 R = V dc 2 p ac = V rms I rms = I rms 2 R = V rms 2 R = V 2 m π 2 R R = V 2 m 4R Example: For the shown half-wave rectifier, the source is a sinusoid of 120 Vrms at a frequency of 60 Hz. The load resistor is 5 Ω. Determine (a) the average load current, (b) the dc and ac power absorbed by the load and (c) the power factor of the circuit. (a) 6

Resistive Load (b) p dc = V m 2 π 2 R = 169.72 π 2 5 = 583.57 (c) p ac = V rms 2 R = 84.92 5 = 1441.6 The rms current in the resistor is The power factor is pf = p S = p ac V rms I rms = 1441.6 120 17 = 0.707 7

R-L Load Industrial loads typically contain inductance as well as resistance. As the source voltage goes through zero, becoming positive in the circuit of fig. a, the diode becomes forward-biased. The Kirchhoff voltage law equation that describes the current in the circuit for the forward-biased ideal diode is The dc component of the output voltage is V dc = V m 2π 0 β sinωt dωt = V m (1 cosβ) 2π The dc component of the output current is I dc = V m (1 cosβ) 2πR (1) The solution of equation (1) can be obtained by expressing the current as the sum of the forced response and the natural response: 8

R-L Load The forced response for this circuit is the current that exists after the natural response has decayed to zero. In this case, the forced response is the steady-state sinusoidal current that would exist in the circuit if the diode were not present. This steady-state current can be found from phasor analysis, resulting in Where The natural response is the transient that occurs when the load is energized. It is the solution to the homogeneous differential equation for the circuit without the source or diode. 9

R-L Load For this first-order circuit, the natural response has the form Where τ = L R A= constant Adding the forced and natural responses gets the complete solution. The constant A is evaluated by using the initial condition for current: t=0, i(ωt)=0. Using the initial condition and equation (2) to evaluate A yields (2) 10

R-L Load Substituting for A in equation (2) gives The final current equation can be written as (3) The point when the current reaches zero in Eq. (3-12) occurs when the diode turns off. The first positive value of ωt in equation (3) that results in zero current is called the extinction angle β. To find β, substitute ωt= β in equation (3) Which reduces to There is no closed-form solution for β, and some numerical method is required. 11

R-L Load To summarize, the current in the half-wave rectifier circuit with RL load is expressed as The dc component of the output current is Or it can be found as V dc = V m 2π 0 β sinωt dωt = V m (1 cosβ) 2π I dc = I o = V m (1 cosβ) 2πR 12

R-L Load The rms value of I o can be written as Or it can be written as V rms = 1 2π 0 β (V msinωt) 2 dωt = V m 2 4π (β 1 2 sin2β) I rms = V rms Z = V rms R 2 + (ωl) 2 = 1 R 2 + (ωl) 2 V m 2 4π (β 1 2 sin2β) 13

R-L Load Example: For the RL half-wave rectifier, R=100Ω, L=0.1 H, ω=377 rad/s, and V m =100 V. Determine (a) an expression for the current in this circuit, (b) the average current, (c) the rms current, (d) the power absorbed by the RL load, and (e) the power factor. (a) (b) Using a numerical root-finding program, β is found to be 3.50 rad, or 201 o. (A numerical integration program is recommended.) 14

R-L Load Io can be also found from I dc = I o = V m 2πR 1 cosβ = 100 2π100 1 cos201 = 0.308 A (c) I rms can be also found from (d) I rms = 1 R 2 + (ωl) 2 2 V m 4π (β 1 2 sin2β) = 1 106.9 100 2 4π (3.5 1 sin7) = 0.489 A 2 (e) Note that the power factor is not cosθ. 15

R-L Load with Freewheeling Diode A freewheeling diode D 2, can be connected across an RL load as shown in fig. a. Both diodes cannot be forward-biased at the same time. Diode D 1 will be ON when the source is positive, and diode D 2 will be ON when the source is negative. For a positive source voltage, D 1 is on. D 2 is off. The equivalent circuit is the same as that of fig. b. The voltage across the RL load is the same as the source. For a negative source voltage, D 1 is off. D 2 is on. The equivalent circuit is the same at that of fig. c. The voltage across the RL load is zero 16

R-L Load with Freewheeling Diode Since the voltage across the RL load is the same as the source voltage when the source is positive and is zero when the source is negative, the load voltage is a half-wave rectified sine wave. Steadystate load, source, and diode currents are shown in the fig.. Example: Determine the average load voltage and current for the circuit, where R=2 Ω and L=25mH, V m is 100 V, and the frequency is 60 Hz. 17

Half Wave Rectifier with a Capacitor Filter The purpose of the capacitor is to reduce the variation in the output voltage, making it more like dc. The resistance may represent an external load, and the capacitor may be a filter which is part of the rectifier circuit. Assuming the capacitor is initially uncharged and the circuit is energized at ω t=0, the diode becomes forward-biased as the source becomes positive. With the diode on, the output voltage is the same as the source voltage, and the capacitor charges. The capacitor is charged to V m when the input voltage reaches its positive peak at ωt=π/2. As the source decreases after ωt=π/2, the capacitor discharges into the load resistor. At some point, the voltage of the source becomes less than the output voltage, reverse-biasing the diode and isolating the load from the source. The output voltage is a decaying exponential with time constant RC while the diode is off. The angle ωt=θ is the point when the diode turns off in the figure. The output voltage is described by 18

Half Wave Rectifier with a Capacitor Filter (1) where The slopes of these functions are At ωt=θ, the slopes of the voltage functions are equal: 19

Half Wave Rectifier with a Capacitor Filter Solving for θ and expressing θ so it is in the proper quadrant, In practical circuits where the time constant is large, The angle at which the diode turns on in the second period, ωt=2π+α, is the point when the sinusoidal source reaches the same value as the decaying exponential output: The above equation must be solved numerically for α. The current in the resistor is calculated from i R = v o R The current in the capacitor is calculated from Or 20

Half Wave Rectifier with a Capacitor Filter Using v o from equation (1) we, get (2) The source current, which is the same as the diode current, is Peak capacitor current occurs when the diode turns on at ωt=2π+α. From equation (2) Resistor current at ωt=2π+α is obtained from equation (1) Peak diode current is 21

Half Wave Rectifier with a Capacitor Filter The effectiveness of the capacitor filter is determined by the variation in output voltage. This may be expressed as the difference between the maximum and minimum output voltage, which is the peak-to-peak ripple voltage. For the half wave rectifier with a capacitor filter, the maximum output voltage is V m. The minimum output voltage occurs at ωt=2π+α, which can be computed from V m sinα. The peak-to-peak ripple is expressed as If V θ V m and θ=π/2, then (1) evaluated at α=π/2 is The ripple voltage can then be approximated as the exponential in the above equation can be approximated by the series expansion: (3) Substituting the above equation in equation (3). The peak-to-peak ripple is approximately 22

Half Wave Rectifier with a Capacitor Filter The output voltage ripple is reduced by increasing the filter capacitor C. As C increases, the conduction interval for the diode decreases. Therefore, increasing the capacitance to reduce the output voltage ripple results in a larger peak diode current. Example: The half-wave rectifier with a capacitor filter has a 120-V rms source at 60 Hz, R=500 =Ω, and C=100μF. Determine (a) an expression for output voltage, (b) the peak-to-peak voltage variation on the output, (c) an expression for capacitor current, (d) the peak diode current, and (e) the value of C such that V o is 1 percent of V m. Using numerical solution to get α 23

Half Wave Rectifier with a Capacitor Filter (a) an expression for output voltage. (b) the peak-to-peak voltage variation on the output (c) an expression for capacitor current (d) the peak diode current (e) the value of C such that V o is 1 percent of V m. 24

25

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback