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BRUSHLESS DC ELECTRIC MOTOR
A microprocessor-controlled BLDC motor powering a micro remote-controlled airplane. This external rotor motor weighs 5 grams, consumes approximately 11 watts (15 millihorsepower) and produces thrust of more than twice the weight of the plane.
Brushless DC motors (BLDC motors, BL motors) also known as electronically commutated motors (ECMs, EC motors) are synchronous electric motors powered by direct-current (DC) electricity and having electronic commutation systems, rather than mechanical commutators and brushes. The current-to-torque and voltage-to-speed relationships of BLDC motors are linear.
BLDC motors may be described as stepper motors, with fixed permanent magnets and possibly more poles on the stator than the rotor, or reluctance motors. The latter may be without permanent magnets, just poles that are induced on the rotor then pulled into alignment by timed stator windings. However, the term stepper motor tends to be used for motors that are designed specifically to be operated in a mode where they are frequently stopped with the rotor in a defined angular position; this page describes more general BLDC motor principles, though there is overlap.
Brushless versus brushed DC motors
Brushed DC motors have been in commercial use since 1886,. BLDC motors, however have only been commercially possible since 1962.
Limitations of brushed DC motors overcome by BLDC motors include lower efficiency and susceptibility of the commutator assembly to mechanical wear and consequent need for servicing, at the cost of potentially less rugged and more complex and expensive control electronics. BLDC motors develop maximum torque when stationary[citation needed] and have linearly decreasing torque[citation needed] with increasing speed as shown in the adjacent figure
A BLDC motor has permanent magnets which rotate and a fixed armature, eliminating the problems of connecting current to the moving armature. An electronic controller replaces the brush/commutator assembly of the brushed DC motor, which continually switches the phase to the windings to keep the motor turning. The controller performs similar timed power distribution by using a solid-state circuit rather than the brush/commutator system.
The interface circuitry between a digital controller and motor. The waveforms show multiple transitions between high and low voltage levels, approximations to a trapezoid or sinusoid which reduce harmonic losses. The circuit compensates for the induction of the windings, regulates power and monitors temperature.
BLDC motors offer several advantages over brushed DC motors, including more torque per weight and efficiency[citation needed], reliability, reduced noise, longer lifetime (no brush and commutator erosion), elimination of ionizing sparks from the commutator, more power, and overall reduction of electromagnetic interference (EMI). With no windings on the rotor, they are not subjected to centrifugal forces, and because the windings are supported by the housing, they can be cooled by conduction, requiring no airflow inside the motor for cooling. This in turn means that the motor's internals can be entirely enclosed and protected from dirt or other foreign matter.
The maximum power that can be applied to a BLDC motor is exceptionally high, limited almost exclusively by heat, which can weaken the magnets. (Magnets demagnetize at high temperatures, the Curie point, and for neodymium-iron-boron magnets this temperature is lower than for other types.) A BLDC motor's main disadvantage is higher cost, which arises from two issues. First, BLDC motors require complex electronic speed controllers to run. Brushed DC motors can be regulated by a comparatively simple controller, such as a rheostat (variable resistor). However, this reduces efficiency because power is wasted in the rheostat. Second, some practical uses have not been well developed in the commercial sector. For example, in the Radio Control (RC) hobby, even commercial brushless motors are often hand-wound while brushed motors use armature coils which can be inexpensively machine-wound. (Nevertheless, see "Applications", below.)
BLDC motors are often more efficient at converting electricity into mechanical power than brushed DC motors. This improvement is largely due to the absence of electrical and friction losses due to brushes. The enhanced efficiency is greatest in the no-load and low-load region of the motor's performance curve. Under high mechanical loads, BLDC motors and high-quality brushed motors are comparable in efficiency.
AC induction motors require induction of magnetic field in the rotor by the rotating field of the stator; this results in the magnetic and electric fields being out of phase. The phase difference requires greater current and current losses to achieve power. BLDC motors are microprocessor-controlled to keep the stator current in phase with the permanent magnets of the rotor, requiring less current for the same effect and therefore resulting in greater efficiency.
In general, manufacturers use brush-type DC motors when low system cost is a priority but brushless motors to fulfill requirements such as maintenance-free operation, high speeds, and operation in explosive environments where sparking could be hazardous.
Controller implementations
Because the controller must direct the rotor rotation, the controller requires some means of determining the rotor's orientation/position (relative to the stator coils.) Some designs use Hall effect sensors or a rotary encoder to directly measure the rotor's position. Others measure the back EMF in the undriven coils to infer the rotor position, eliminating the need for separate Hall effect sensors, and therefore are often called sensorless controllers. Like an AC motor, the voltage on the undriven coils is sinusoidal, but over an entire commutation the output appears trapezoidal because of the DC output of the controller.
The controller contains 3 bi-directional drivers to drive high-current DC power, which are controlled by a logic circuit. Simple controllers employ comparators to determine when the output phase should be advanced, while more advanced controllers employ a microcontroller to manage acceleration, control speed and fine-tune efficiency.
Controllers that sense rotor position based on back-EMF have extra challenges in initiating motion because no back-EMF is produced when the rotor is stationary. This is usually accomplished by beginning rotation from an arbitrary phase, and then skipping to the correct phase if it is found to be wrong. This can cause the motor to run briefly backwards, adding even more complexity to the startup sequence. Other sensorless controllers are capable of measuring winding saturation caused by the position of the magnets to infer the rotor position.
The controller unit is often referred to as an "ESC", meaning Electronic Speed Controller


PRESENTED BY:-
Diptirekha Sahoo

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BRUSHLESS DC MOTOR PRINCIPLE AND APPLICATION
INTRODUCTION
T.G Wilson & P.H Tricky made a dc machine with solid state commutation (1962)
BLDC is also called ECMs
No need of commutator & brushes
Not directly operate from a dc voltage source
Combination of synchronous motor & a frequency inverter
WHY BLDC?
Limitations of conventional dc motor
Brushes may get displaced with increasing in speed
Difficulty in maintaining contact
Brushes & commutator requires maintanance
Limitation of synchronous motor
Speed can’t be varied
Problems with instability at any speed
WHY BLDC(contd.)
PRINCIPLE OF BLDC MOTOR
Frequency inverter used as commutator
Commutation depends on rotor position
Speed control by motor voltage
Angle between mmfs of stator & rotor is fixed to 90 deg (el.)
Motor behaves like a dc motor
No commutation occurs on the spinning shaft
THEORY OF OPERATION
Mode of Electronic commutation
(i)Sensor based(use of hall sensor)
- hall sensors are placed at every 120 deg.
- hall sensors sense the position of coil
6 commutation (phase) can be possible
The decoder circuit turns appropriate swithes on & off
The voltage through specific coil turns the motor
(i)Sensorless (use of MCUs)
- MCU measures back emf which determines the position of magnet & rot
THEORY OF OPERATION(Contd.)
How it Works
CONSTRUCTION OF BLDC
Shape is either cylindrical or pancake
Cylindrical BLDC(direction of magnetic flux is radial wrt rotational axis)
Inrunner(rotor inside)
Ex: hard disk drives
(ii) outrunner(rotor outside)
Ex: BLDC fan motors outrunner inrunner
CONSTRUCTION(contd.)
Pancake BLDC(direction of magnetic flux is parallel wrt axis of rotation)
(i)Single stator(lower torque)
Ex: floppy disk drive motors
(ii)Double stator(high torque) single stator double stator
Brushless pancake motor
ADVANTAGES OF BLDC
No brushes or commutators to wear out
no generation of EMI
High torque to inertia ratio
No windings on the rotor but supported by housing
High efficiency(up to 97%)
High heat transfer efficiency
No sparks & longer life
Maintenance free
Good weight/size to power ratio
DISADVANTAGES OF BLDC
Higher cost
Must rotate at minimal speed to generate sufficient back emf for the drive to sense
Sudden changes in load causes back emf to become out of synchronous resulting loss of speed & torque
Hall effect sensors might not work properly
Requires additional sensors
Requires complex drive circuitary
APPLICATION OF BLDC
Low power BLDC
(i)Consumer electronics
(ii)Medical field
(a)sleep apnea treatment
(b) Optimising power
density
©Heat transfer efficient
(d)Medical analyser
APPLICATION
High power BLDC
(i)Transport
(ii)Heating & ventilation
(iii)Model Engg.
CONCLUSION
Due to all those advantages BLDC is now replacing the conventional dc motor & increasing popularity
various researches are going on for reducing its complexity in drive circuit with different types of sensors
As sensor less brushless DC drives continue to develop and costs are reduced, the attractiveness of brushless DC motors will continue to increase.

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INTRODUCTION
Brushless Direct Current (BLDC) motors are one of the
motor types rapidly gaining popularity. BLDC motors
are used in industries such as Appliances, Automotive,
Aerospace, Consumer, Medical, Industrial Automation
Equipment and Instrumentation.
As the name implies, BLDC motors do not use brushes
for commutation; instead, they are electronically commutated.
BLDC motors have many advantages over
brushed DC motors and induction motors. A few of
these are:
• Better speed versus torque characteristics
• High dynamic response
• High efficiency
• Long operating life
• Noiseless operation
• Higher speed ranges
Construction & working principle
BLDC motors are a type of synchronous motor. This
means the magnetic field generated by the stator and
the magnetic field generated by the rotor rotate at the
same frequency. BLDC motors do not experience the
“slip” that is normally seen in induction motors.
BLDC motors come in single-phase, 2-phase and
3-phase configurations. Corresponding to its type, the
stator has the same number of windings. Out of these,
3-phase motors are the most popular and widely used.
This application note focuses on 3-phase motors
STATOR
The stator of a BLDC motor consists of stacked steel
laminations with windings placed in the slots that are
axially cut along the inner periphery (as shown in
Figure 3). Traditionally, the stator resembles that of an
induction motor; however, the windings are distributed
in a different manner. Most BLDC motors have three
stator windings connected in star fashion. Each of
these windings are constructed with numerous coils
interconnected to form a winding. One or more coils are
placed in the slots and they are interconnected to make
a winding. Each of these windings are distributed over
the stator periphery to form an even numbers of poles.
There are two types of stator windings variants:
trapezoidal and sinusoidal motors. This differentiation
is made on the basis of the interconnection of coils in
the stator windings to give the different types of back
Electromotive Force (EMF). Refer to the “What is
Back EMF?” section for more information