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DC Choppers

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Thyristor converter offers greater efficiency, faster response, lower maintenance, smaller size and smooth control. Choppers are of Two Types Step-down choppers. – PowerPoint PPT presentation

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Title: DC Choppers


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DC Choppers
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Prof. T.K. Anantha Kumar, EE Dept., MSRIT
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Introduction
  • Chopper is a static device.
  • A variable dc voltage is obtained from a constant
    dc voltage source.
  • Also known as dc-to-dc converter.
  • Widely used for motor control.
  • Also used in regenerative braking.
  • Thyristor converter offers greater efficiency,
    faster response, lower maintenance, smaller size
    and smooth control.

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Choppers are of Two Types
  • Step-down choppers.
  • Step-up choppers.
  • In step down chopper output voltage is less than
    input voltage.
  • In step up chopper output voltage is more than
    input voltage.

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Principle Of Step-down Chopper
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  • A step-down chopper with resistive load.
  • The thyristor in the circuit acts as a switch.
  • When thyristor is ON, supply voltage appears
    across the load
  • When thyristor is OFF, the voltage across the
    load will be zero.

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Methods Of Control
  • The output dc voltage can be varied by the
    following methods.
  • Pulse width modulation control or constant
    frequency operation.
  • Variable frequency control.

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Pulse Width Modulation
  • tON is varied keeping chopping frequency f
    chopping period T constant.
  • Output voltage is varied by varying the ON time
    tON

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Variable Frequency Control
  • Chopping frequency f is varied keeping either
    tON or tOFF constant.
  • To obtain full output voltage range, frequency
    has to be varied over a wide range.
  • This method produces harmonics in the output and
    for large tOFF load current may become
    discontinuous

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Step-down ChopperWith R-L Load
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  • When chopper is ON, supply is connected across
    load.
  • Current flows from supply to load.
  • When chopper is OFF, load current continues to
    flow in the same direction through FWD due to
    energy stored in inductor L.

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  • Load current can be continuous or discontinuous
    depending on the values of L and duty cycle d
  • For a continuous current operation, load current
    varies between two limits Imax and Imin
  • When current becomes equal to Imax the chopper is
    turned-off and it is turned-on when current
    reduces to Imin.

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Expressions For Load CurrentiO For Continuous
Current Operation When Chopper Is ON (0 ? t ?
tON)
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When Chopper is OFF
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Principle Of Step-up Chopper
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  • Step-up chopper is used to obtain a load voltage
    higher than the input voltage V.
  • The values of L and C are chosen depending upon
    the requirement of output voltage and current.
  • When the chopper is ON, the inductor L is
    connected across the supply.
  • The inductor current I rises and the inductor
    stores energy during the ON time of the chopper,
    tON.

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  • When the chopper is off, the inductor current I
    is forced to flow through the diode D and load
    for a period, tOFF.
  • The current tends to decrease resulting in
    reversing the polarity of induced EMF in L.
  • Therefore voltage across load is given by

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  • A large capacitor C connected across the load,
    will provide a continuous output voltage .
  • Diode D prevents any current flow from capacitor
    to the source.
  • Step up choppers are used for regenerative
    braking of dc motors.

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Expression For Output Voltage
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Performance Parameters
  • The thyristor requires a certain minimum time to
    turn ON and turn OFF.
  • Duty cycle d can be varied only between a min.
    max. value, limiting the min. and max. value of
    the output voltage.
  • Ripple in the load current depends inversely on
    the chopping frequency, f.
  • To reduce the load ripple current, frequency
    should be as high as possible.

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Problem
  • A Chopper circuit is operating on TRC at a
    frequency of 2 kHz on a 460 V supply. If the load
    voltage is 350 volts, calculate the conduction
    period of the thyristor in each cycle.

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Problem
  • Input to the step up chopper is 200 V. The output
    required is 600 V. If the conducting time of
    thyristor is 200 ?sec. Compute
  • Chopping frequency,
  • If the pulse width is halved for constant
    frequency of operation, find the new output
    voltage.

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Problem
  • A dc chopper has a resistive load of 20? and
    input voltage VS 220V. When chopper is ON, its
    voltage drop is 1.5 volts and chopping frequency
    is 10 kHz. If the duty cycle is 80, determine
    the average output voltage and the chopper on
    time.

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Problem
  • In a dc chopper, the average load current is 30
    Amps, chopping frequency is 250 Hz, supply
    voltage is 110 volts. Calculate the ON and OFF
    periods of the chopper if the load resistance is
    2 ohms.

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  • A dc chopper in figure has a resistive load of R
    10? and input voltage of V 200 V. When
    chopper is ON, its voltage drop is 2 V and the
    chopping frequency is 1 kHz. If the duty cycle is
    60, determine
  • Average output voltage
  • RMS value of output voltage
  • Effective input resistance of chopper
  • Chopper efficiency.

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Problem
  • A chopper is supplying an inductive load with a
    free-wheeling diode. The load inductance is 5 H
    and resistance is 10?.. The input voltage to the
    chopper is 200 volts and the chopper is operating
    at a frequency of 1000 Hz. If the ON/OFF time
    ratio is 23. Calculate
  • Maximum and minimum values of load current in one
    cycle of chopper operation.
  • Average load current

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Problem
  • A chopper feeding on RL load is shown in figure,
    with V 200 V, R 5?, L 5 mH, f 1
    kHz, d 0.5 and E 0 V. Calculate
  • Maximum and minimum values of load current.
  • Average value of load current.
  • RMS load current.
  • Effective input resistance as seen by source.
  • RMS chopper current.

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Classification Of Choppers
  • Choppers are classified as
  • Class A Chopper
  • Class B Chopper
  • Class C Chopper
  • Class D Chopper
  • Class E Chopper

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Class A Chopper
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  • When chopper is ON, supply voltage V is connected
    across the load.
  • When chopper is OFF, vO 0 and the load current
    continues to flow in the same direction through
    the FWD.
  • The average values of output voltage and current
    are always positive.
  • Class A Chopper is a first quadrant chopper .

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  • Class A Chopper is a step-down chopper in which
    power always flows form source to load.
  • It is used to control the speed of dc motor.
  • The output current equations obtained in step
    down chopper with R-L load can be used to study
    the performance of Class A Chopper.

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Class B Chopper
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  • When chopper is ON, E drives a current through
    L and R in a direction opposite to that shown in
    figure.
  • During the ON period of the chopper, the
    inductance L stores energy.
  • When Chopper is OFF, diode D conducts, and part
    of the energy stored in inductor L is returned to
    the supply.

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  • Average output voltage is positive.
  • Average output current is negative.
  • Therefore Class B Chopper operates in second
    quadrant.
  • In this chopper, power flows from load to source.
  • Class B Chopper is used for regenerative braking
    of dc motor.
  • Class B Chopper is a step-up chopper.

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Expression for Output Current
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Class C Chopper
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  • Class C Chopper is a combination of Class A and
    Class B Choppers.
  • For first quadrant operation, CH1 is ON or D2
    conducts.
  • For second quadrant operation, CH2 is ON or D1
    conducts.
  • When CH1 is ON, the load current is positive.
  • The output voltage is equal to V the load
    receives power from the source.
  • When CH1 is turned OFF, energy stored in
    inductance L forces current to flow through the
    diode D2 and the output voltage is zero.

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  • Current continues to flow in positive direction.
  • When CH2 is triggered, the voltage E forces
    current to flow in opposite direction through L
    and CH2 .
  • The output voltage is zero.
  • On turning OFF CH2 , the energy stored in the
    inductance drives current through diode D1 and
    the supply
  • Output voltage is V, the input current becomes
    negative and power flows from load to source.

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  • Average output voltage is positive
  • Average output current can take both positive and
    negative values.
  • Choppers CH1 CH2 should not be turned ON
    simultaneously as it would result in short
    circuiting the supply.
  • Class C Chopper can be used both for dc motor
    control and regenerative braking of dc motor.
  • Class C Chopper can be used as a step-up or
    step-down chopper.

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Class D Chopper
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  • Class D is a two quadrant chopper.
  • When both CH1 and CH2 are triggered
    simultaneously, the output voltage vO V and
    output current flows through the load.
  • When CH1 and CH2 are turned OFF, the load
    current continues to flow in the same direction
    through load, D1 and D2 , due to the energy
    stored in the inductor L.
  • Output voltage vO - V .

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  • Average load voltage is positive if chopper ON
    time is more than the OFF time
  • Average output voltage becomes negative if tON
    lt tOFF .
  • Hence the direction of load current is always
    positive but load voltage can be positive or
    negative.

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Class E Chopper
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Four Quadrant Operation
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  • Class E is a four quadrant chopper
  • When CH1 and CH4 are triggered, output current
    iO flows in positive direction through CH1 and
    CH4, and with output voltage vO V.
  • This gives the first quadrant operation.
  • When both CH1 and CH4 are OFF, the energy stored
    in the inductor L drives iO through D2 and D3
    in the same direction, but output voltage vO
    -V.

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  • Therefore the chopper operates in the fourth
    quadrant.
  • When CH2 and CH3 are triggered, the load current
    iO flows in opposite direction output voltage
    vO -V.
  • Since both iO and vO are negative, the chopper
    operates in third quadrant.

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  • When both CH2 and CH3 are OFF, the load current
    iO continues to flow in the same direction D1 and
    D4 and the output voltage vO V.
  • Therefore the chopper operates in second quadrant
    as vO is positive but iO is negative.

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Effect Of Source Load Inductance
  • The source inductance should be as small as
    possible to limit the transient voltage.
  • Also source inductance may cause commutation
    problem for the chopper.
  • Usually an input filter is used to overcome the
    problem of source inductance.

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  • The load ripple current is inversely proportional
    to load inductance and chopping frequency.
  • Peak load current depends on load inductance.
  • To limit the load ripple current, a smoothing
    inductor is connected in series with the load.

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Problem
  • For the first quadrant chopper shown in figure,
    express the following variables as functions of
    V, R and duty cycle d in case load is
    resistive.
  • Average output voltage and current
  • Output current at the instant of commutation
  • Average and RMS free wheeling diode current.
  • RMS value of output voltage
  • RMS and average thyristor currents.

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Impulse Commutated Chopper
  • Impulse commutated choppers are widely used in
    high power circuits where load fluctuation is not
    large.
  • This chopper is also known as
  • Parallel capacitor turn-off chopper
  • Voltage commutated chopper
  • Classical chopper.

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  • To start the circuit, capacitor C is initially
    charged with polarity (with plate a positive)
    by triggering the thyristor T2.
  • Capacitor C gets charged through VS, C, T2 and
    load.
  • As the charging current decays to zero thyristor
    T2 will be turned-off.
  • With capacitor charged with plate a positive
    the circuit is ready for operation.
  • Assume that the load current remains constant
    during the commutation process.

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  • For convenience the chopper operation is divided
    into five modes.
  • Mode-1
  • Mode-2
  • Mode-3
  • Mode-4
  • Mode-5

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Mode-1 Operation
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  • Thyristor T1 is fired at t 0.
  • The supply voltage comes across the load.
  • Load current IL flows through T1 and load.
  • At the same time capacitor discharges through T1,
    D1, L1, C and the capacitor reverses its
    voltage.
  • This reverse voltage on capacitor is held
    constant by diode D1.

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Mode-2 Operation
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  • Thyristor T2 is now fired to commutate thyristor
    T1.
  • When T2 is ON capacitor voltage reverse biases
    T1 and turns if off.
  • The capacitor discharges through the load from
    V to 0.
  • Discharge time is known as circuit turn-off time.

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  • Capacitor recharges back to the supply voltage
    (with plate a positive).
  • This time is called the recharging time and is
    given by
  • The total time required for the capacitor to
    discharge and recharge is called the commutation
    time and it is given by

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  • At the end of Mode-2 capacitor has recharged to
    VS and the free wheeling diode starts
    conducting.

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Mode-3 Operation
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  • FWD starts conducting and the load current
    decays.
  • The energy stored in source inductance LS is
    transferred to capacitor.
  • Hence capacitor charges to a voltage higher than
    supply voltage, T2 naturally turns off.

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Mode-4 Operation
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  • Capacitor has been overcharged i.e. its voltage
    is above supply voltage.
  • Capacitor starts discharging in reverse
    direction.
  • Hence capacitor current becomes negative.
  • The capacitor discharges through LS, VS, FWD, D1
    and L.
  • When this current reduces to zero D1 will stop
    conducting and the capacitor voltage will be same
    as the supply voltage

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Mode-5 Operation
  • Both thyristors are off and the load current
    flows through the FWD.
  • This mode will end once thyristor T1 is fired.

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Disadvantages
  • A starting circuit is required and the starting
    circuit should be such that it triggers thyristor
    T2 first.
  • Load voltage jumps to almost twice the supply
    voltage when the commutation is initiated.
  • The discharging and charging time of commutation
    capacitor are dependent on the load current and
    this limits high frequency operation, especially
    at low load current.

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  • Chopper cannot be tested without connecting load.
  • Thyristor T1 has to carry load current as well
    as resonant current resulting in increasing its
    peak current rating.

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