4.7 MULTILEVEL INVERTERS (MLI) - PowerPoint PPT Presentation

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4.7 MULTILEVEL INVERTERS (MLI)

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... Interconnection of two DCMIs back-to-back with a DC capacitor link (suitable for specific applications only UPFC, frequency changer, phase shifter) ... – PowerPoint PPT presentation

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Title: 4.7 MULTILEVEL INVERTERS (MLI)


1
4.7 MULTILEVEL INVERTERS (MLI)
  • Main feature
  • Ability to reduce the voltage stress on each
    power device due to the utilization of multiple
    levels on the DC bus
  • Important when a high DC side voltage is imposed
    by an application (e.g. traction systems)
  • Even at low switching frequencies, smaller
    distortion in the multilevel inverter AC side
    waveform can be achieved (with stepped modulation
    technique)
  • 3 main MLI circuit topologies

2
MLI (2)
  • Diode-clamped multilevel inverter (DCMI)
  • Extension of NPC
  • Based on concept of using diodes to limit power
    devices voltage stress
  • Structure and basic operating principle
  • Consists of series connected capacitors that
    divide DC bus voltage into a set of capacitor
    voltages
  • A DCMI with nl number of levels typically
    comprises (nl-1) capacitors on the DC bus
  • Voltage across each capacitor is VDC/(nl-1)
  • ( nl nodes on DC bus, nl levels of output
    phase voltage , (2nl-1) levels of output line
    voltage)

3
MLI (3)
4
MLI (4)
  • Output phase voltage can assume any voltage level
    by selecting any of the nodes
  • DCMI is considered as a type of multiplexer that
    attaches the output to one of the available nodes
  • Consists of main power devices in series with
    their respective main diodes connected in
    parallel and clamping diodes
  • Main diodes conduct only when most upper or lower
    node is selected
  • Although main diodes have same voltage rating as
    main power devices, much lower current rating is
    allowable
  • In each phase leg, the forward voltage across
    each main power device is clamped by the
    connection of diodes between the main power
    devices and the nodes

5
MLI (5)
  • Number of power devices in ON state for any
    selection of node is always equal to
  • (nl-1)
  • Output phase voltage with corresponding switching
    states of power devices for a 5-level DCMI

6
MLI (6)
  • General features
  • For three-phase DCMI, the capacitors need to
    filter only the high-order harmonics of the
    clamping diodes currents , low-order components
    intrinsically cancel each other
  • For DCMI employing step modulation strategy, if
    nl is sufficiently high, filters may not be
    required at all due to the significantly low
    harmonic content
  • If each clamping diode has same voltage rating
    as power devices, for nl-level DCMI,
  • number of clamping diodes/phase (nl-1) x
    (nl-2)
  • Each power device block only a capacitor voltage

7
MLI (7)
  • Clamping diodes block reverse voltage (Dc1, Dc2,
    Dc3 block VDC/4, 2VDC/4 and 3VDC/4 respectively)
  • Unequal conduction duty of the power devices
  • DCMI with step modulation strategy have problems
    stabilizing/balancing capacitor voltages
  • Average current flowing into corresponding inner
    nodes not equal to zero over one cycle
  • Not significant in SVC applications involving
    pure reactive power transfer

8
MLI (8)
  • Overcoming capacitor voltage balancing problem
  • Line-to-line voltage redundancies (phase voltage
    redundancies not available due to structure)
  • Carefully designed modulation strategies
  • Replace capacitors with controlled constant DC
    voltage source such as PWM voltage regulators or
    batteries
  • Interconnection of two DCMIs back-to-back with a
    DC capacitor link (suitable for specific
    applications only UPFC, frequency changer,
    phase shifter)

9
MLI (9)
  • Imbricated cell multilevel inverter
  • Capable of solving capacitor voltage unbalance
    problem and excessive diode count requirement in
    DCMI
  • Also known as flying capacitor multilevel
    inverter (capacitors are arranged to float with
    respect to earth)
  • Structure and basic operating principle
  • Employs separate capacitors precharged to
  • (nl-1)/(nl-1)xVDC, (nl-2)/(nl-1)xVDC
    nl-(nl-1)/nl-1xVDC
  • Size of voltage increment between two capacitors
    defines size of voltage steps in ICMI output
    voltage waveform

10
MLI (10)
  • nl-level ICMI has nl levels output phase voltage
    and (2nl-1) levels output line voltage

11
MLI (11)
  • Output voltage produced by switching the right
    combinations of power devices to allow adding or
    subtracting of the capacitor voltages
  • Constraints capacitors are never shorted to
    each other and current continuity to the DC bus
    capacitor is maintained
  • 5-level ICMI 16 power devices switching
    combinations (SWC) . To produce VDC and 0 (1 SWC
    all upper devices ON, all lower devices ON),
    VDC/2 (6 SWC), VDC/4 and 3VDC/4 (4 SWC)
  • Example - capacitor voltage combinations that
    produce an output phase voltage level of VDC/2

12
MLI (12)
  • VDC - VDC/2
  • VDC 3VDC/4 VDC/4
  • VDC - 3VDC/4 VDC/2 VDC/4
  • 3VDC/4 VDC/2 VDC/4
  • 3VDC/4 VDC/4
  • VDC/2
  • Power devices switching states of a 5-level ICMI

13
MLI (13)
  • General features
  • With step modulation strategy, with sufficiently
    high nl, harmonic content can be low enough to
    avoid the need for filters
  • Advantage of inner voltage levels redundancies -
    allows preferential charging or discharging of
    individual capacitors, facilitates manipulation
    of capacitor voltages so that their proper values
    are maintained
  • Active and reactive power flow can be controlled
    (complex selection of power devices combination,
    ?switching frequency/losses for the former)
  • Additional circuit required for initial charging
    of capacitors

14
MLI (14)
  • Assuming each capacitor used has the same voltage
    rating as the power devices, nl-level ICMI
    requires
  • (nl 1) x (nl 2)/2 auxiliary capacitors
    per phase
  • (nl 1) main DC bus capacitors
  • Unequal conduction duty of power devices
  • Modular structured multilevel inverter (MSMI)
  • Referred to as cascaded-inverters with Separate
    DC Sources (SDCs) or series connected H-bridge
    inverters
  • Structure and basic operating principle

15
MLI (15)
  • Consists of (nl1)/2 or h number of single-phase
    H-bridge inverters (MSMI modules)
  • MSMI output phase voltage
  • Vo Vm1 Vm2 .. Vmh

  • Vm1 output voltage of module 1
  • Vm2 output voltage of module 2
  • Vmh output voltage of module h
  • Structure of a single-phase nl-level MSMI

16
MLI (16)
17
MLI (17)
  • Power devices switching states of a 5-level MSMI

18
MLI (18)
  • General features
  • Known to eliminate the excessively large number
    of bulky transformers required by the multipulse
    inverters, clamping diodes required by the DCMIs
    and capacitors required by the ICMIs
  • Simple and modular configuration
  • Requires least number of components
  • Comparison of power devices requirements per
    phase leg among three MLI (assuming all power
    devices have same voltage rating, not necessary
    same current rating, each MSMI module represented
    by a full-bridge, DCMI and ICMI use half-bridge
    topology)

19
MLI (19)
  • Flexibility in extending to higher number of
    levels without undue increase in circuit
    complexity simplifies fault finding and repair,
    facilitates packaging
  • Requires DC sources isolated from one another for
    each module for applications involving real power
    transfer
  • Adaptation measures have to be taken in complying
    to the separate DC sources requirement for ASDs
    applications

20
MLI (20)
  • Feed each MSMI module from a capacitively smooth
    fully controlled three-phase rectifier, isolation
    achieved using specially designed transformer
    having separate secondary windings/module
  • Employ a DC-DC converter with medium to high
    frequency transformers (between rectifier output
    and each MSMI module input), allows bidirectional
    power flow
  • Isolated DC sources not required for applications
    involving pure reactive power transfer (SVG) ?
    pure reactive power drawn, phase voltage and
    current 90º apart ? balanced capacitor charge and
    discharge

21
MLI (21)
  • Originally isolated DC voltages, alternate
    sources of energy (PV arrays, fuel cells)
  • Advantage of availability of output phase voltage
    redundancies
  • Allows optimised cyclic use of power devices to
    ensure symmetrical utilization, symmetrical
    thermal problems and wear
  • Design of power devices utilization pattern
    possible
  • Overall improvement in MSMI performance high
    quality output voltage etc.

22
MLI (22)
  • Modulation strategies for multilevel inverters
  • Step modulation
  • Space vector modulation
  • Optimal/programmed PWM technique
  • Sigma delta modulation (SDM)
  • High-dynamic control strategies
  • Multilevel hysterisis modulation strategy
  • Sliding mode control based on theory of Variable
    Structure Control System (VSCS)
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