Module 3 electric propulsion electric vehicle technology ppt

Subject: ElectricVehicleTechnology
Module 3: Electric Propulsion
VTU – 18EE646
Complied
by
Dr. C.V. Mohan
EEE., Sir. MV IT.,
Bangalore
For VTU – 6th Semester Professional Elective
Reference: Modern Electric, Hybrid Electric, and Fuel CellVehicles
by Mehrdad Ehsani, Yimin Gao, Sebastien E. G & Ali Emadi
Electrical and Electronics Engineering
1

 EV Consideration.
 DC motor drives and speed control.
 Induction motor drives.
 Permanent Magnet Motor Drives.
 Switch Reluctance Motor Drive for
ElectricVehicles.
 Configuration and control of Drives.
Electric Propulsion
By Dr.C.V. Mohan Sir MVIT., Bangalore 2

 Electric propulsion systems are at the heart
of electric vehicles (EVs) and hybrid electric
vehicles (HEVs).
 They consist of electric motors, power
converters,and electronic controllers.
 The electric motor converts the electric
energy into mechanical energy to propel the
vehicle, or, vice versa, to enable regenerative
braking and/or to generate electricity for the
purpose of charging the onboard energy
storage.
Electric Propulsion

Electric Propulsion
 The power converter is used to supply the electric motor
with proper voltage and current.
 The electronic controller commands the power converter
by providing control signals to it, and then controls the
operation of the electric motor to produce proper torque
and speed, according to the command from the drive.
 The electronic controller can be further divided into three
functional units sensor, interface circuitry, and processor.
 The sensor is used to translate measurable quantities such
as current, voltage, temperature, speed, torque, and flux
into electric signals through the interface circuitry.
 These signals are conditioned to the appropriate level
before being fed into the processor. The processor output
signals are usually amplified via the interface circuitry to
drive power semiconductor devices of the power converter.

Fig.1Functional block diagramof a typical electric propulsion system
Electric Propulsion

 The choice of electric propulsion systems for EVs and
HEVs mainly depends on a number of factors, including
driver expectation, vehicle constraints, and energy source.
 Driver expectation is defined by a driving profile, which
includes the acceleration, maximum speed, climbing
capability, braking, and range.
 Vehicle constraints, including volume and weight, depend
on vehicle type, vehicle weight, and payload. The energy
source relates to batteries, fuel cells, ultra capacitors, and
various hybrid sources.
 Differing from the industrial applications of motors, the
motors used in EVs and HEVs usually require frequent
starts and stops, high rates of acceleration/deceleration, high
torque and low-speed hill climbing, low torque and high-
speed and a very wide speed range of operation.

 The motor drives for EVs and HEVs can be classified into
two main groups, namely the commutator motors and
commutatorless motors as shown below.
Fig. 2 Classification of electric motor drives for EV and HEV applications

 Commutator motors mainly are the traditional DC motors,
which include series excited, shunt excited, compound
excited, separately excited, and permanent magnet (PM)
excited motors.
 DC motors need commutators and brushes to feed current
into the armature, thus making them less reliable and
unsuitable for maintenance-free operation and high speed.
 Technological developments have recently pushed
commutatorless electric motors into a new era.
 Advantages include higher efficiency, higher power
density, lower operating cost.
 They are also more reliable and maintenancefree
compared to commutator DC motors. Thus,
commutatorless electric motors have now become more
attractive. By Dr.C.V. Mohan Sir MVIT., Bangalore 8

 Induction motors are widely accepted as a commutatorless
motor type for EV and HEV propulsion. This is because of
their low cost, high reliability, and maintenance-free
operation.
 The conventional control of induction motors such as
variable-voltage variable-frequency (VVVF) cannot
provide the desired performance.
 On introduction of the power electronics and
microcomputer era, the principle of field-oriented control
(FOC) or vector control of induction motors has been
accepted to overcome their control complexity due to their
nonlinearity.
 These EV and HEV motors using FOC still suffer from low
efficiency at low light loads and limited constant-power
operating range.

 The conventional control of induction motors such as
variable-voltage variable-frequency (VVVF) cannot
provide the desired performance. With the advent of the
power electronics and micro computer era, the principle of
field-oriented control (FOC) or vector control of induction
motors has been accepted to overcome their control
complexity due to their nonlinearity.
 Still these EV and HEV motors using FOC still suffer
from low efficiency at low light loads and limited
constant-power operating range.
 The replacement of the field winding of conventional
synchronous motors with PMs, PM synchronous motors
can eliminate conventional brushes, slip rings, and field
copper losses.

 The PM synchronous motors are also called PM brushless
AC motors, or sinusoidal-fed PM brushless motors,
because of their sinusoidal AC current and brushless
configuration. Since these motors are essentially
synchronous motors, they can run from a sinusoidal or
PWM supply without electronic commutation.
 When PMs are mounted on the rotor surface, they behave
as nonsalient synchronous motors because the permeability
of PMs is similar to that of air.
 PMs being inside the magnetic circuit of the rotor causes
an additional reluctance torque, which leads to facilitating
a wider speed range at constant power operation.

 Also we have synchronous reluctance motors, generally
simple and inexpensive, but with relatively low output
power. Similar to induction motors, these PM synchronous
motors usually use FOC for high-performance applications
and because of their inherently high power density and high
efficiency, they have been accepted as having great potential
to compete with induction motors for EV and HEV
applications.
 Next by inverting the stator and rotor of PM, DC motors
(commutator), PM brushless DC motors are generated, the
main advantage of PM brushless DC motor is it produce a
large torque because of the rectangular interaction between
current and flux. these PM brushless DC motors generally
operate with shaft position sensors. Recently, sensorless
control technologies have been developed in the Power
Electronics and Motor Drive Laboratory at Texas A&M
University By Dr.C.V. Mohan Sir MVIT., Bangalore 12

 Next we have switched reluctance (SR) motors have been
recognized to have considerable potential for EV and
HEV applications.
 These motors are direct derivatives of single-stack
variable-reluctance stepping motors. SR motors have the
definite advantages of simple construction, low
manufacturing cost, and outstanding torque–speed
characteristics for EV and HEV applications.
 Although they possess simplicity in construction, this
does not imply any simplicity of their design and control.
Because of the heavy saturation of pole tips and the fringe
effect of pole and slots, their design and control are
difficult and subtle.
 Traditionally, SR motors operate with shaft sensors to
detect the relative position of the rotor to the stator.

 These sensors are usually vulnerable to mechanical
shock and sensitive to temperature and dust. Therefore,
the presence of the position sensor reduces the
reliability of SR motors and constrains some
applications.
 Recently, sensorless technologies have been developed
in the Power Electronics and Motor Drive Laboratory
— again at Texas A&M University
 These technologies can ensure smooth operation from
zero speed to maximum speed.

DC Motor Drives
 DC motor drives have been widely used in applications requiring
adjustable speed, good speed regulation, and frequent starting,
braking and reversing.
 Various DC motor drives have been widely applied to different
electric traction applications because of their technological
maturity and control simplicity.
 The operation principle of a DC motor is straight forward.
Whenever a current carrying conductor placed in magnetic
field, a mechanical force is produced on the conductor.
 This force is perpendicular to the conductor and the
magnetic field as shown in Figure 3. The magnetic force is
proportional to the conductor length, magnitude of the
electric current, and the density of the magnetic field that is
F =B I L newton

DC Motor Drives
T = BIL Cosα N-m

 There are four types of DC motors, depending on the
mutual interconnection between the field and armature
windings. They are separately excited, shunt excited, series
excited, and compound excited as shown in Fig.4.
Fig.4 Wound-field DC motors
DC Motor Drives

 In the case of a separately excited motor, the field and
armature voltage can be controlled independently of one
another. In a shunt motor, the field and armature are
connected in parallel to a common source.
 Independent control of field current and armature or
armature voltage can be achieved by inserting a resistance
into the appropriate circuit.
 This method of control is an inefficient. The efficient
method is to use power electronics-based DC–DC
converters in the appropriate circuit to replace the
resistance and This DC–DC converters can be actively
controlled to produce proper armature and field voltage.
DC Motor Drives

 The steady-state equivalent circuit of the armature of a DC
motor is shown below
 The resistor Ra is the resistance of the armature circuit. For
separately excited and shunt DC motors, it is equal to the
resistance of the armature windings for the series and
compound motors, it is the sum of armature and series
field winding resistances. Basic equations of a DC motor
are
---------- (1)
------- (2)
DC Motor Drives

 Where φ is the flux per pole in Webers, Ia is the armature
current in A, Va is the armature voltage in volt, Ra is the
resistance of the armature circuit in ohms, ωm is the
speed of the armature in rad/sec, T is the torque
developed by the motor in Nm, and Ke is constant.
From equation (1) and (2) we can obtain
-------- (3)
• Equations (1)–(3) are applicable to all the DC motors,
namely, separately (or shunt) excited, series, and
compound motors. In the case of separately excited
motors, if the field voltage is maintained as constant,
one can assume the flux to be practically constant as the
torque changes.
DC Motor Drives

 The independence of armature voltage and field provides
more flexible control of the speed and torque than other types
of DC motors.
 In EV and HEV applications, the most desirable speed–
torque characteristic is to have a constant torque below a
certain speed (base speed), with the torque dropping
parabolically with the increase of speed (constant power) in
the range above the base speed, as shown in Fig.5.
Fig.5 Torque & power limitations in combined armature voltage and field control
Combined ArmatureVoltage and Field Control

 In the range of lower than base speed, the armature current
and field are set at their rated values, producing the rated
torque. From equations (1) to (3), it is clear that the
armature voltage must be increased proportionally with
the increase of the speed.
 At the base speed, the armature voltage reaches its rated
value equal to the source voltage and cannot be increased
further. In order to further increase the speed, the field
must be weakened with the increase of the speed, and then
the back EMF E and armature current must be maintained
constant.
 The torque produced drops parabolically with the increase
in the speed and the output power remains constant, as
shown in Fig.5

Chopper Control of DC Motors
 Choppers are used for the control of DC motors
because of a number of advantages such as high
efficiency, flexibility in control, light weight, small
size, quick response, and regeneration down to very
low speeds.
 At present, the separately excited DC motors are
usually used in traction, due to the control flexibility
of armature voltage and field.
 The chopper offers a number of advantages due to its
high operation frequency.

 The power electronic circuit and the steady-state waveform of a DC
chopper drive are shown in Fig.6. A DC voltage source, V, supplies an
inductive load through a self-commutated semiconductor switch S
Fig.6. Principle of operation of classA chopper and (b) to (e) its waveforms
basic chopper circuit

 A DC voltage source, V, supplies an inductive load through
a self-commutated semiconductor switch S.
 The diode shows the direction in which the device can
carry current. A diode DF is connected in parallel with the
load. The semiconductor switch S is operated periodically
over a period T and remains closed for a time ton=δT with
0 <δ<1 The variable δ= ton / T is called the duty ratio or
duty cycle of a chopper. Fig. 6 also shows the waveform of
control signal ic.
• The direct component or average value of the load voltage
Va is given by
• By controlling δ between 0 and 1, the load voltage can be
varied from 0 to V, thus a chopper allows a variable DC
voltage to be obtained from a fixed voltage DC source.

 The switch S can be controlled in various ways for varying
the duty ratio δ.
 The control technologies can be divided into the following
categories
1. Time ratio control(TRC) or Pulse width Modulation(PWM)
2. Current limit control (CLC)
 The TRC can be further divided as follows
1. Constant frequency TRC:
The chopper period T is kept fixed and the on period of the
switch is varied to control the duty ratio δ.
2. Varied frequency TRC:
Here, δ is varied either by keeping ton constant and
varying T or by varying both ton and T

 In variable frequency control with constant on-time, low-
output voltage is obtained at very low values of chopper
frequencies.
 The operation of a chopper at low frequencies adversely
affects the motor performance. Furthermore, the
operation of a chopper with variable frequencies makes
the design of an input filter very difficult. Thus, variable
frequency control is rarely used.
 In current limit control, δ is controlled indirectly by
controlling the load current between certain specified
maximum and minimum values.
 When the load current reaches a specified maximum
value, the switch disconnects the load from the source
and reconnects it when the current reaches a specified
minimum value. For a DC motor load, this type of control
is, in effect.

 The chopper of Fig. 6. is called a class A chopper. It is one
of a number of chopper circuits that are used for the control
of DC motors.
 This chopper is capable of providing only a positive voltage
and a positive current. It is therefore called a single-
quadrant chopper, capable of providing DC separately
excited motor control in the first quadrant, positive speed,
and positive torque.
 Since it can vary the output voltage from V to 0, it is also a
step-down chopper or a DC to DC buck converter.
 The basic principle involved can also be used to realize a
step-up chopper or DC to DC boost converter

Fig.7 (a) basic chopper circuit (b) to (d) waveforms
• The Presence of control signal ic indicates the duration for
which the switch can conduct and it remains closed for an
interval 0<t<δT and remains open for an interval δT<t<T.
• During the on period, iS increases from iS1 to iS2, thus
increasing the magnitude of energy stored in inductance L.
Principle of operation of class B chopper

 When the switch is opened, current flows through the
parallel combination of the load and capacitor C. Since the
current is forced against the higher voltage, the rate of
change of the current is negative. It decreases from iS2 to iS1
in the switch’s off period.
 The energy stored in the inductance L and the energy
supplied by the low-voltage source are given to the load.
 The capacitor C serves two purposes. At the instant of
opening of switch S, the source current, iS, and load current,
ia, are not the same.
 In the absence of C, the turn off of S will force the two
currents to have the same values. This will cause high
induced voltage in the inductance L and the load inductance.
Another reason for using capacitor C is to reduce the load
voltage ripple.
 The purpose of the diode D is to prevent any flow of current
from the load into switch S or source V

 For understanding the step-up operation, capacitor C is
assumed to be large enough to maintain a constant voltage
Va across the load. The average voltage across the terminal
a, b is given as
(1)
 The average voltage across the inductance L is
(2)
(3)
 The source voltage is
Substituting from equations (1) and (2) into (3) gives
(4)

 According to (4), theoretically the output voltage Va
can be changed from V to ∞ by controlling δ from 0 to
1. In practice, Va can be controlled from V to a higher
voltage, which depends on the capacitor C, and the
parameters of the load and chopper.
 The main advantage of a step-up chopper is the
low ripple in the source current. While most
applications require a step-down chopper, the step-
up chopper finds application in low-power battery-
driven vehicles.
 The principle of the step-up chopper is also used
in the regenerative braking of DC motor drives.

 The application of DC motors on EVs and HEVs requires
the motors to operate in multiquadrants, including
forward motoring, forward braking, backward motoring,
and backward braking.
 For vehicles with reverse mechanical gears, two-quadrant
operation (forward motoring and forward braking is
required.
 A two-quadrant operation consisting of forward motoring
and forward regenerative braking requires a chopper
capable of giving a positive voltage and current in either
direction. This two-quadrant operation can be realized in
the following two schemes.
(i) Single Chopper with a Reverse Switch
(ii) Class C Two-Quadrant Chopper

(i) Single Chopper with a Reverse Switch
Fig. 8 Forward motoring and regenerative braking control with a single chopper
 The Semiconductor switch S, operated periodically such that
it remains closed for a duration of δ T and remains open for
a duration of (1- δ )T.
 C is the manual switch. When C is closed and S is in
operation, the circuit is similar to that of permitting the
forward motoring operation. Under these conditions,
terminal a is positive and terminal b is negative.

 Regenerative braking in the forward direction is obtained when C
is opened and the armature connection is reversed with the help
of the reversing switch RS, making terminal b positive and
terminal a negative.
 During the on-period of the switch S, the motor current flows
through a path consisting of the motor armature, switch S, and
diode D1, and increases the energy stored in the armature circuit
inductance.
 When S is opened, the current flows through the armature diode
D2, source V, diode D1 and back to the armature, thus feeding
energy into the source.

 During motoring, the changeover to regeneration is done
in the following steps. Switch S is deactivated and switch
C is opened.
 This forces the armature current to flow through diode D2,
source V, and diode D1. The energy stored in the armature
circuit is fed back to the source and the armature current
falls to zero.
 After an adequate delay to ensure that the current has
indeed become zero, the armature connection is reversed
and switch S is reactivated with a suitable value of delay
to start regeneration.

(ii) Class C Two-Quadrant Chopper
Fig.9 Forward motoring and regenerative braking control using class C chopper
• For smooth transition from motoring to braking and vice versa,
the class C chopper is used. Switch S1 and diode D1 constitute
one chopper and the switch S2 and diode D2 form another
chopper.
• When the switches S1 and S2 are closed alternately. In the
chopping period T, S1 is kept on for a duration δT, and S2 is
kept on from δT to T.
• To avoid a direct short-circuit across the source, care is taken
to ensure that S1 and S2 do not conduct at the same time. .

ii) Class C Two-Quadrant Chopper
Class C two-quadrant chopper waveforms

 The four-quadrant operation can be obtained by combining
two class C choppers.
Fig.10. Class E four-quadrant chopper
Four-Quadrant Operation

Induction Motor Drives
 Induction motor drives offer a number of advantages
over conventional DC motor drives for the electric
propulsion of EVs and HEVs.
 The AC induction motor drive has additional advantages
such as lightweight nature, small volume, low cost, and
high efficiency. These advantages are particularly
important for EV and HEV applications.
 There are two types of induction motors, namely,
wound-rotor and squirrel cage motors. Because of the
high cost wound-rotor induction motors are less
attractive than their squirrel-cage motors, especially for
electric propulsion in EVs and HEVs. Hence, squirrel-
cage induction motors are loosely termed as induction motors.

Induction Motor Drives
The mmf’s produced by the phase currents can be written as
Fig.11

Torque–slip characteristics of an induction motor
Fig.12

Power Electronic Control
 As EV and HEV propulsion, an induction motor drive is
usually fed with a DC source (battery, fuel cell, etc.),
which has approximately constant terminal voltage.
 A variable frequency and variable voltage DC/AC inverter
is needed to feed the induction motor.
 The general DC/AC inverter is constituted by power
electronic switches and power diodes.
 The commonly used topology of a DC/AC inverter is
shown in Fig.13 which has three legs and six switches
(S1and S4, S3 and S6, and S5 and S2), feeding phases a, b,
and c of Induction motor.
 The inverter can be broadly classified as a voltage source
inverter or a current source inverter.

Pulse width modulation (PWM)
Fig 13. DC/AC inverter with sinusoidal PWM
(a) inverter topology
(b) control signals

 For constant volt/hertz control of an induction motor,
sinusoidal pulse width modulation (PWM) is used
exclusively.
 Three-phase reference voltages Va, Vb, and Vc of variable
amplitudes Aa, Ab, and Ac are compared with a common
isosceles triangular carrier wave Vtr of a fixed amplitude
Am as shown in Figure 6.21(c).
 The outputs of comparators 1, 2, and 3 form the control
signals for the three legs of the inverter. When the
sinusoidal reference voltage Va, Vb, and Vc at a time t is
greater than the triangular waved voltage, turn-on signals
are sent to the switches S1, S3, and S5 and turn-off signals
are sent to S4, S6, and S2. Thus, the three phases of the
induction motor have a positive voltage.

(d) voltage of phase a; (e) voltage of phase b; and (f) voltage of phase c

 On the other hand, when the reference sinusoidal voltage
is smaller than triangular wave voltage, turn-off signals
are sent to the switches S1, S3, and S5 and turn-on signals
are sent to S4, S6, and S2. The three phases of the
induction motor then have a negative voltage.
 The voltages of the three phases are shown in Figure
6.21(d) to (f).
 frequency of the motor voltage can be changed by the
frequency of the reference voltage. The ratio of the
amplitude of the reference wave to that of the
triangular carrier wave, m, is called the modulation
index
 The fundamental voltage increases linearly with m until
m= 1

Field Orientation Control
 The constant volt/hertz control of the induction motor is
more suitably applied to motors that operate with a
relatively slow speed regulation.
 This approach shows poor response to frequent and fast
speed varying, and also results in poor operation
efficiency due to the poor power factor.
 In the last two decades, field orientation control (FOC) or
vector control technology has been successfully
developed.
 This technology mostly overcomes the disadvantages of
the constant volt/hertz control in AC motor drives.
 Vector control, also called field-oriented control (FOC),
is a variable-frequency drive (VFD) control method in
which the stator currents of a three-phase AC or brushless
DC electric motor are identified as two orthogonal
components that can be visualized with a vector.

 The Field Orientated Control (FOC) consists of
controlling the stator currents represented by a vector.
 This control is based on projections which transform a
three phase time and speed dependent system into a two
co-ordinate (d and q co-ordinates) time invariant
system.
 These projections lead to a structure similar to that of a
DC machine control.
 Field orientated controlled machines need two
constants as input references, the torque component
(aligned with the q co-ordinate) and the flux component
(aligned with d co-ordinate).

 As Field Orientated Control is simply based on projections
the control structure handles instantaneous electrical
quantities. This makes the control accurate in every working
operation (steady state and transient) and independent of the
limited bandwidth mathematical model.
 The FOC thus solves the classic scheme problems, in the
following ways:
(i) The ease of reaching constant reference (torque
component and flux component of the stator current)
(ii) The ease of applying direct torque control because in
the (d,q) reference frame the expression of the torque is:
m α ψR iSR
 By maintaining the amplitude of the rotor flux (ψ R ) at a
fixed value we have a linear relationship between torque and
torque component (iSq). We can then control the torque by
controlling the torque component of stator current vector.

SpaceVector definition and projection
 The three-phase voltages, currents and fluxes of AC-motors
can be analyzed in terms of complex space vectors. With
regard to the currents, the space vector can be defined as
follows. Assuming that ia, ib, ic are the instantaneous
currents in the stator phases, then the complex stator
current vector iS is defined by:
 The following diagram shows the stator current complex
space vector:
Stator current space vector and its component in (a,b,c)

 Where (a,b,c) are the three phase system axes. This
current space vector depicts the three phase sinusoidal
system. It still needs to be transformed into a two time
invariant co-ordinate system.
 This transformation can be split into two steps:
• (a,b,c)⇒(α,β) (the Clarke transformation) which
outputs a two co-ordinate time variant
system
• (α,β)⇒(d,q) (the Park transformation) which
outputs a two co-ordinate time invariant
system

The basic scheme for the FOC
 Two motor phase currents are measured. These
measurements feed the Clarke transformation module. The
outputs of this projection are designated i Sα and iSβ.
 These two components of the current are the inputs of the
Park transformation that gives the current in the d,q rotating
reference frame.
 The iSd and iSq components are compared to the references
iSdref (the flux reference) and iSqref (the torque reference).
Fig.14

The basic scheme for the FOC
 The outputs of this projection are vSαref and vSβref which are
the components of the stator vector voltage in the α,β
stationary orthogonal reference frame. These are the inputs
of the Space Vector PWM. The outputs of this block are the
signals that drive the inverter.
 FOC it becomes possible to control, directly and separately,
the torque and flux of AC machines. FOC using in AC
machines increases conversion efficiency and system
reliability.
Fig.15 General block diagram of a vector control system for an induction motor

Permanent Magnetic Brush-Less DC Motor Drives
 A brushless DC electric motor (BLDC motor or BL
motor), also known as an electronically commutated
motor (ECM or EC motor) or synchronous DC motor, is
a synchronous motor using a direct
current (DC) electric power supply.
 By using high-energy permanent magnets as the field
excitation mechanism, a permanent magnet motor drive
can be potentially designed with high power density, high
speed, and high operation efficiency.
 These prominent advantages are quite attractive to the
application on electric and hybrid electric vehicles. Of the
family of permanent magnetic motors, the brush-less DC
(BLDC) motor drive is the most promising candidate for
EV and HEV application.

The major advantages of BLDC motor include
1. High Efficiency
2. Compactness:
3. Ease of control:
4. Ease of cooling:
5. Low maintenance, great longevity, and reliability:
6. Low noise emissions
The major disadvantages of BLDC motor include
1. Cost:
2. Limited constant power range:
3. Safety
4. Magnet demagnetization
5. High-speed capability
6. Inverter failures in BLDC motor drives

High efficiency:
BLDC motors are the most efficient of all electric
motors. This is due to the use of permanent magnets for the
excitation, which consume no power. The absence of a
mechanical commutator and brushes means low mechanical
friction losses and therefore higher efficiency.
Compactness:
The recent introduction of high-energy density
magnets has allowed achieving very high flux densities in the
BLDC motor. This makes it possible to achieve accordingly
high torques, which in turns allows making the motor small
and light.

Ease of control:
The BLDC motor can be controlled as easily as a DC
motor because the control variables are easily
accessible and constant throughout the operation of the
motor.
• Ease of cooling:
There is no current circulation in the rotor. Therefore,
the rotor of a BLDC motor does not heat up. The only
heat production is on the stator, which is easier to cool
than the rotor because it is static and on the periphery
of the motor.

Low maintenance, great longevity, and reliability:
The absence of brushes and mechanical commutators
suppresses the need for associated regular maintenance and
suppresses the risk of failure associated with these elements.
The longevity is therefore only a function of the winding
insulation, bearings, and magnet life-length.
Low noise emissions:
There is no noise associated with the commutation
because it is electronic and not mechanical. The driving
converter switching frequency is high enough so that the
harmonics are not audible

BLDC motor drives also suffer from some disadvantages
such as
Cost:
Rare-earth magnets are much more expensive than
other magnets and result in an increased motor cost.
Limited constant power range:
A large constant power range is crucial to achieving
high vehicle efficiencies. The permanent magnet BLDC
motor is incapable of achieving a maximum speed greater
than twice the base speed.
Safety:
Large rare-earth permanent magnets are dangerous
during the construction of the motor because they may
attract flying metallic objects toward them. In case of
vehicle crash, if the wheel is spinning freely, the motor is
still excited by its magnets and high voltage is present at the
motor terminals that can possibly risk the passengers or
rescuers.

Magnet demagnetization:
Magnets can be demagnetized by large opposing
mmfs and high temperatures. The critical demagnetization
force is different for each magnet material. Great care must
be exercised when cooling the motor, especially if it is
built compact.
High-speed capability:
The surface-mounted permanent magnet motors cannot
reach high speeds because of the limited mechanical
strength of the assembly between the rotor yoke and the
permanent magnets

Inverter failures in BLDC motor drives:
Because of the permanent magnets on the rotor, BLDC
motors present major risks in case of short circuit failures of the
inverter. Indeed, the rotating rotor is always energized and
constantly induces an EMF in the short-circuited windings.
A very large current circulates in those windings and an
accordingly large torque tends to block the rotor. The dangers of
blocking one or several wheels of a vehicle are no negligible. If the
rear wheels are blocked while the front wheels are spinning, the
vehicle will spin uncontrollably.
If the front wheels are blocked, the driver has no
directional control over the vehicle. If only one wheel is blocked, it
will induce a yaw torque that will tend to spin the vehicle, which
will be difficult to control.
In addition to the dangers to the vehicle, it should be noted
that the large current resulting from an inverter short circuit poses
a risk of demagnetizing and destroying the permanent magnets

 Open circuit faults in BLDC motor drives are no direct
threat to vehicle stability.
 The impossibility of controlling a motor due to an
open circuit may, however, pose problems in terms of
controlling the vehicle. Because the magnets are
always energized and cannot be controlled, it is
difficult to control a BLDC motor in order to minimize
the fault.
 This is a particularly important issue when the BLDC
motor operates in its constant power region. Indeed, in
this region, a flux is generated by the stator to oppose
the magnet flux and allow the motor to rotate at higher
speeds.
 If the stator flux disappears, the magnet flux will
induce a large EMF in the windings, which can be
harmful to the electronics or passengers.

Basic Principles of BLDC Motor Drives
 BLDC motor drive consists mainly of the brush-less DC
machine, a DSP based controller, and a power
electronics-based power converter, as shown machine
rotor.
 The rotor position information is fed to the DSP-based
controller, which, in turn, supplies gating signals to the
power converter by turning on and turning off the proper
stator pole windings of the machine. In this way, the
torque and speed of the machines are controlled.
Fig. 16.BLDC motor

BLDC Machine Construction and Classification
 BLDC machines can be categorized by the position of the
rotor permanent magnet, the way in which the magnets are
mounted on the rotor. The magnets can either be surface-
mounted or interior-mounted.
(a) surface-mounted PM rotor and (b) interior-mounted PM rotor
Fig (a) shows the surface-mounted permanent magnet rotor.
Each permanent magnet is mounted on the surface of the
rotor. It is easy to build, and specially skewed poles are
easily magnetized on this surface-mounted type to minimize
cogging torque. But there is a possibility that it will fly apart
during high-speed operations.

 Fig.(b) shows the interior-mounted permanent magnet
rotor. Each permanent magnet is mounted inside the rotor.
It is not as common as the surface-mounted type but it is a
good candidate for high-speed operations.
 In the case of the stator windings, there are two major
classes of BLDC motor drives, both of which can be
characterized by the shapes of their respective back EMF
waveforms, trapezoidal and sinusoidal.
 The trapezoidal-shaped back EMF BLDC motor is
designed to develop trapezoidal back EMF waveforms. It
has the following ideal characteristics:
1. Rectangular distribution of magnet flux in the air gap
2. Rectangular current waveform
3. Concentrated stator windings.

 A sinusoidal-shaped back EMF BLDC motor is designed
to develop sinusoidal back EMF waveforms. It has the
following ideal characteristics:
1. Sinusoidal distribution of magnet flux in the air gap
2. Sinusoidal current waveforms
3. Sinusoidal distribution of stator conductors
• The most fundamental aspect of the sinusoidal-shaped
back EMF motor is that the back EMF generated in each
phase winding by the rotation of the magnet should be a
sinusoidal wave function of rotor angle. The drive
operation of the sinusoidal-shaped back EMF BLDC
machine is similar to the AC synchronous motor. It has a
rotating stator MMF wave like a synchronous motor

There are three classes of permanent magnet materials
currently used for electric motors:
1. Alnicos (Al, Ni, Co, Fe)
2. Ceramics (ferrites), for example, barium ferrets BaO
6Fe2O3 and strontium ferrite SrO 6Fe2O3
3. Rare-earth materials, that is, samarium–cobalt SmCO
and neodymium–iron–boron NdFeB

Control of BLDC Motor Drives
In vehicle traction application, the torque produced is
required to follow the torque desired by the driver and
commanded through the accelerator and brake pedals. Thus,
torque control is the basic requirement.
Fig.17. Block diagram of the torque control of the BLDC motor

 Fig.17. shows a block diagram of a torque control
scheme for a BLDC motor drive. The desired current I*
is derived from the commanded torque T* through a
torque controller. The current controller and
commutation sequencer receive the desired current I*
position information from the position sensors, and
perhaps the current feedback through current
transducers, and then produces gating signals. These
gating signals are sent to the three-phase inverter (power
converter) to produce the phase current desired by the
BLDC machine.

 In traction application, speed control may be required, cruising
control operation, can be obtained through, Fig. 18.
 Many high-performance applications include current
feedback for torque control. At the minimum, a DC bus
current feedback is required to protect the drive and machine
from over currents. The controller blocks, “speed controller”
may be any type of classical controller such as a PI
controller, or a more advanced controller such as an artificial
intelligence control.
Fig.18 Block diagram of the speed control of the BLDC motor

SensorlessTechniques
 As mentioned above, the operation of the BLDC motor
drives relies mostly on position sensors for obtaining the
rotor position information so as to perform the turn on or
turn off of each phase properly.
 The position sensor is usually either a three-element Hall-
effect sensor or an optical encoder. These position sensors
are high-cost, fragile elements. Thus, their presence not
only enhances the cost of the motor drive but also
seriously lowers its reliability and limits its application.
 Position sensorless technology can effectively continue
the operation of the system in case the position sensors
lose their function. This is crucial in some applications,
such as in military vehicles.

SensorlessTechniques
 Several sensorless technologies have been developed.
The majority of them are based on voltage, current, and
back EMF detection. These techniques can be primarily
grouped into four categories:
 Those using measured currents, voltages, fundamental
machine equations, and algebraic manipulations
 Those using observers
 Those using back EMF methods
 Those with novel techniques not falling into the previous
three category

Methods Using Measurables and Math
 This method consists of two subtypes:
(1) Those that calculate the flux linkages using measured
voltages and currents and
(2) Those that utilize a model’s prediction of a
measurable voltage or current, compare the model’s
value with the actual measured voltage or current,
and calculate the change in position, proportional to
the difference between the measured and actual
voltage or current.

 The first subtype is seen in references. The fundamental
idea is to calculate the flux linkage from the measured
voltage and current.
 With a knowledge of initial position, machine
parameters, and the flux linkage's relationship with rotor
position, the rotor position can be determined. By
determining the rate of change of the flux linkage from
the integration results, the speed can also be determined.
An advantage of the flux-calculating method is that line–
line voltages may be used in the calculations and thus no
motor neutral is required.
 This is beneficial, as the most common BLDC
configuration is Y-connected with no neutral.

 The second subtype is shown in references. This method
consists of first developing an accurate d–q model of the
machine. Utilizing the measured currents and a d–q
transformation, the output voltages of the model are
compared to the measured and transformed voltages.
 The difference is proportional to the difference in angular
reference between the model’s coordinate system and the
actual coordinate system, which is the rotor position with
reference to the actual coordinate system’s reference.
 Conversely, they have also used the measured voltages and
found the differences in the currents.
 In either case, the difference between the measured (and
transformed) and the calculated is used as the multiplier in
an updated equation for the rotor position.

Methods Using Observers
 These methods determine the rotor position and/or speed
using observers. The first of these considered are those
utilizing the well-known Kalman filter as a position
estimator.
 One of the first of these to appear in the printed literature
was by M. Schroedl in 1988. In his many publications,
Schroedl utilized various methods of measuring system
voltages and currents, which could produce rough
estimates of the angular rotor position.
 The Kalman filtering added additional refinements to the
first estimates of position and speed. Other observer-based
systems include those utilizing nonlinear, full-order, and
sliding-mode observers

Methods Using Back EMF Sensing
 Using back EMF sensing is the majority approach in
sensorless control technology of the BLDC motor
drive. This approach consists of several methods, such
as
(1) Terminal voltage sensing method: This method is a
good method for steady state; however, phase differences
in the circuits used due to speed variations do not allow
optimal torque/amp over a wide speed range.
(2) Third-harmonic back EMF sensing method: The third
harmonic of the back EMF can be used in the
determination of switching instants in the wye connected
120º current conduction operating mode of the BLDC
motor.

(3) Freewheeling diode conduction: This method uses the
indirect sensing of the zero crossing of the phase back EMF to
obtain the switching instants of the BLDC motor.
In the 120º conducting Y-connected BLDC motor, one of the
phases is always open-circuited. For a short period after
opening the phase, there phase current remains flowing, via a
freewheeling diode, due to the inductance of the windings.
This open-phase current becomes zero in the middle of the
commutation interval, which corresponds to the point where
the back EMF of the open phase crosses zero.
The largest downfall of this method is the requirement of six
additional isolated power supplies for the comparator circuitry
of each freewheeling diode. By Dr.C.V. Mohan Sir MVIT., Bangalore 80

(4) Back EMF integration: In this method, position
information is extracted by integrating the back EMF of
the unexcited phase.
The integration is based on the absolute value of the open
phase’s back EMF. Integration of the voltage divider
scaled-down back EMF starts when the open phase’s back
EMF crosses zero. A threshold is set to stop the
integration, which corresponds to a commutation instant.
This approach is less sensitive to switching noise and
automatically adjusts to speed changes, but the low-speed
operation is poor. With this type of sensorless operation
scheme, up to 3600 rpm has been reported.

Unique SensorlessTechniques
 The following sensorless methods are completely original
and unique. These range from artificial intelligence
methods to variations in the machine structure. The first of
the novel methods to be considered are those utilizing
artificial intelligence, that is, artificial neural networks
(ANN) and fuzzy logic. In reference, they utilized a neural
network using the back-propagation training algorithm
(BPN) to act as a nonlinear function implementation
between measured phase voltages and currents, which
were inputs, and rotor position, which was the output.
Using the equations in the above method, the flux linkage
can be calculated using the measured voltages, currents,
and system parameters.

Switched Reluctance Motor Drives

 The switched reluctance motor (SRM) drive is considered
to be an attractive challenger for variable speed motor
drives due to its low cost, rugged structure, reliable
converter topology, high efficiency over a wide speed
range, and simplicity in control.
 SRM is extremely suitable for EVs, electric traction
applications, automotive applications, aircraft
starter/generator systems, mining drives, washing
machines, door actuators, etc.,
 The SRM has a simple, rugged, and low-cost structure. It
has no PM or winding on the rotor. This structure not only
reduces the cost of the SRM but also offers high-speed
operation capability for this motor and high efficiency
over a wide speed range.

 The SRM has salient poles on both the stator and rotor. It
has concentrated windings on the stator and no winding or
PM on the rotor. There are several configurations for SRM
depending on the number and size of the rotor and stator
poles. The configurations of the 6/4 and 8/6 SRM, which
are more common are shown below Fig.19.
Fig.19.Cross-section of common SRM configurations: (a) a 6/4 SRM and (b) a 8/6 SRM

Working Principle of SRM
 As we know that magnetic flux have a tendency to flow
through lowest reluctance path, therefore rotor always
tends to align along the minimum reluctance path. This is
the basic working principle of Switched Reluctance Motor
or Variable Reluctance Motor.
 Therefore, when stator phase winding A is energized, the
rotor align along this phase as shown in figure below.

 When stator phase winding A is de-energized and winding
B is energized, the rotor align itself along B phase as shown
in figure below.
 Thus rotor rotation in clockwise direction is achieved by
energizing the phase winding in a ABC sequence. If rotor
rotation in anti-clockwise direction is require, stator phase
winding must be energized in ACB sequence.

 It must also be noted that, a particular phase winding must
be energized / de-energized in synchronism with rotor
position.
 This means as soon as the rotor align along the A phase, B
phase must be energized and A phase must be de-
energized if clockwise rotor rotation is required.

Advantages of SRM
Advantages of switched reluctance motor are
 It does not require an external ventilation system as the
stator and rotor slots projected. The airflow maintained
between the slots.
 The rotor does not have winding.
 Since the absence of a permanent magnet, such motors are
available at a cheaper price.
 A simple three or two-phase pulse generator is enough to
drive the motor.
 The direction of the motor can be reversed by changing the
phase sequence.
 Self-starting and does not require external arrangements.
 Starting torque can be very high without excessive inrush
currents.

Advantages of SRM
 High Fault Tolerance.
 Phase losses do not affect motor operations.
 High torque/inertia ratio.
 High starting torque can be achieved.
 Creates Torque ripple at high-speed operation.
 The external rotor position sensor is required.
 Noise level is high.
 At a higher speed, the motor generates harmonics, to reduce
this, we need to install larger size capacitors.
 Since the absence of a Permanent Magnet, the motor has to
designed to carry a high input current. It increases the
converter KVA requirement.
Disadvantages of SRM

A conventional SRM drive system consists of the
switched reluctance motor, power inverter, sensors such as
voltage, current, and position sensors, and control circuitry
such as the DSP controller and its peripherals, as shown
below Fig.20. Through proper control, high performance can
be achieved in the SRM drive system.
By Dr.C.V. Mohan Sir. MVIT., Bangalore 91
Fig. 20.SRM drive system

 The SRM drive inverter is connected to a DC power
supply, which can be derived from the utility lines
through a front-end diode rectifier or from batteries. The
phase windings of the SRM are connected to the power
inverter, as shown below Fig 21.
Fig 21. SRM and its power supply

SRM Drive Converter
It can be seen from Fig.22 that the torque developed by the
motor can be controlled by varying the amplitude and the timing of
the current pulses in synchronism with the rotor position.
Fig 22.Idealized inductance,current,and torque profiles of the SRM

SRM Drive Converter
 The input to the SRM drive is DC voltage, which is
usually derived from the utility through a front-end
diode rectifier or from batteries.
 Unlike other AC machines, the currents in SR motors
can be unidirectional. Hence, conventional bridge
inverters used in AC motor drives are not used in SRM
drives.
 Several configurations have been proposed for an SRM
inverter in the literature, some of the most commonly
used ones are shown in Fig.23.

SRM Drive Converter
 The most commonly used inverter uses two switches
and two freewheeling diodes per phase and is called
the classic converter. The configuration of the classic
converter is shown in Fig.23(a).
Fig. 23 (a) classical half bridge converter

SRM Drive Converter
 The main advantage of the classic converter is its
flexibility in control. All the phases can be controlled
independently, which is essential for very high-speed
operations where there will be a considerable overlap
between the adjacent phase currents
 The operation of the classic converter is shown in Fig.24.
 i
Fig.24 Modes of operation for the classic converter:
(a) turning on phase mode; (b) zero voltage mode; and (c) turning off mode

SRM Drive Converter
In phase A, when the two switches S1 and S2 are turned on
as in Fig 24 (a) the DC bus voltage, Vdc, will be applied to the
phase-1 winding.
Phase-1 current will increase as it flows through the path
consisting of Vdc positive terminal, S1, phase-1 winding, S2, and
Vdc negative terminal.
By turning off S1 and holding on S2, when the phase is
energized, the current freewheels through S2 and D1.
In this mode, phase-1 is not getting or giving energy to the
power supply. When S1 and S2 are turned off, the phase-1 current
will flow through D2, Vdc positive terminal, Vdc negative terminal,
D1, and phase-1 winding.
During this time, the motor phase is subjected to negative DC
bus voltage through the freewheeling diodes.
The energy trapped in the magnetic circuit is returned to the
DC link. The phase current drops due to the negative applied phase
voltage. By turning S1 and S2 on and off, the phase-1 current can be
regulated.

Different inverter topologies for SRM drives
Fig.25. Different inverter topologies for SRM drives are also in operatrion
b) R-dump (c) n+1 switch (Miller converter) (d) 1.5n switch converter (e) C-dump

Sensorless Control
 Excitation of the SRM phases needs to be properly
synchronized with the rotor position for effective
control of speed, torque, and torque pulsation.
 A shaft position sensor is usually used to provide the
rotor position.
 The discrete position sensors not only add complexity
and cost to the system but also tend to reduce the
reliability of the drive system and restrict their
application on some specific environment, such as
military applications.
 Position sensorless technology can effectively
continue the operation of the system, in case the
position sensors lose their function.

Sensorless Control
Generally, the existing sensorless control methods can be
classified
1. Phase flux linkage-based method
2. Phase inductance-based method
3. Modulated signal injected methods
4. Mutual-induced voltage-based method
5. Observer-based methods.

Performance Prediction
 The performance requirements are related to the
dynamic performance of the drive and hence call for an
overall modeling of the drive system including control
and power electronics considerations.
 In order to predict the dynamic performance of the
drive, static characteristics of the machine (phase
inductance and torque–angle profiles) should be
available.
 The improved magnetic equivalent circuit approach
(IMEC) is a shortcut method that gives an
approximation of the steady-state parameters of the
SRM.
 A general design strategy for the SRM drive is adopted
for Effective designs is shown in Fig.26.

Basic design strategy of SRM
Fig.26. Basic design strategy of SRM

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