Classification of Motors
What is an Electrical Motor
The engine or electric motor is a device that has provided one of the biggest advancements in engineering and technology ever since the advent of electricity. An electric motor is a machine that converts electrical energy to mechanical energy. The behaviour is based on the idea that when a current conductor is placed in a magnetic field, the engine is nothing but an electromechanical system that converts electrical energy into mechanical energy.
In simple words, we can conclude that a system that generates rotational force is a motor. The very basic principle of the functioning of the electric motor lies in the fact that the force is experienced in the direction perpendicular to the magnetic field and the current when the field and the current are made to interact with each other.
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Classification of Motors or Different Types of Motor
The primary classification of the motor or motor type can be tabulated as shown below -
AC Motors
AC motors have a much larger installed base than DC motors, and are highly flexible in many features, including speed control (VSD-Variable Speed Drives). Some of the major benefits are:
Low power demand on start
Controlled acceleration
Adjustable operational speed
Controlled starting current
Adjustable torque limit
Reduced power line disturbances
Types of AC Motor Include:
Synchronous
In this type of engine, the rotation of the rotor is synchronized with the frequency of the supply current and the speed stays constant under varying loads, making it suitable for moving equipment at a constant speed and used in high-precision positioning devices such as robots, instrumentation, machines and process control.
Induction (Asynchronous)
This type of engine uses electromagnetic induction from the magnetic field of the stator winding to produce an electrical current in the rotor and therefore in the torque. They are the most common type of AC motor and are important in the industry due to their load capacity.
DC Motors
DC motors were the first type of engine commonly used and the initial costs of the systems (motors and drives) appear to be usually lower than AC systems for low power units, but with higher power, the total maintenance costs rise and should be taken into account. DC Motor speed can be controlled by varying the supply voltage and is available in a wide range of voltages, although the most common form is 12 & 24V, with some of the advantages being:
Easy installation
Speed control over a wide range
Quick Starting, Stopping, Reversing and Acceleration
High Starting Torque
Linear speed-torque curve
DC Motors are commonly used and it can be used from small tools and appliances to electric vehicles, lifts and hoists.
The two common types of dc motor are -
Brushed
These are the extra traditional type of engine and are generally used in value-sensitive applications where the monitoring system is incredibly easy, such as for consumer applications and more fundamental industrial equipment, such types of engines can be broken down as -
Series Wound – This is where the field winding is connected in series with the rotor winding and the speed control is by varying the supply voltage, but this type offers poor speed control, and, as the engine torque increases, the speed drops. Applications include automotive, hoists, lifts and cranes, as they have a high starting torque.
Shunt Wound – This type has one supply voltage and the field winding is linked parallel to the winding of the rotor and can deliver increased torque without reducing the speed by increasing the engine current. It has a medium starting torque with constant speed, so suitable for applications include lathes, vacuum cleaners, conveyors, and grinders.
Compound Wound – This is a cumulative of the Series and Shunt, where the polarity of the shunt winding is such that it adds to the field series. This type has a high starting torque and runs smoothly when the load varies slightly and is used for driving compressors, circular saws, scissors, variable-head centrifugal pumps, rotary presses, circular saws, scissors, elevators, and continuous conveyors.
Permanent Magnet – As the name suggests, a permanent magnet is used instead of an electromagnet and is used in applications where precise control and low torque are used, such as robotics, servo systems.
The benefits of this system are long life, low maintenance, and high performance (85-90 per cent), while the drawbacks are higher initial costs and more complex controls. These types of engines are generally used for speed and position control with applications such as fans, pumps, and compressors, where reliability and robustness are required. There is an example of a brushless design in Stepper Motors.
FAQs on Types of Motors
1. What are the main types of motors studied in Physics for CBSE 2025–26?
The main types of motors are AC motors and DC motors. AC motors are further classified into synchronous and induction (asynchronous) motors, while DC motors include brushed, brushless, series wound, shunt wound, compound wound, and permanent magnet motors.
2. How does an AC motor differ from a DC motor in terms of operation and applications?
AC motors use alternating current and are suited for applications needing variable speed and constant load, such as large industrial machinery. DC motors use direct current and are preferred for applications requiring precise speed control, such as lifts, hoists, and electric vehicles.
3. What advantages do synchronous motors offer compared to induction motors?
Synchronous motors run at a constant speed regardless of load, which is ideal for high-precision equipment like robotics and instrumentation. In contrast, induction motors can experience speed changes with load but are robust and widely used in industry for their simplicity and reliability.
4. How is speed controlled in DC motors, and why is this important?
Speed in DC motors is controlled by varying the supply voltage, allowing for precise control across a wide range. This is crucial in applications such as electric vehicles and industrial machines, where different operations may require different speeds and torque.
5. Why are brushless DC motors often chosen over brushed motors in modern devices?
Brushless DC motors are preferred because they have longer life, generate less maintenance, and offer higher efficiency than brushed motors. They are commonly used in computers, drones, and robotics where reliability and smooth operation are needed.
6. What role do permanent magnets play in certain types of DC motors?
In permanent magnet DC motors, magnets provide the field instead of electromagnets. This results in high efficiency and compact design, making these motors suitable for precision devices and low-torque applications like robotics and servo mechanisms.
7. How does the series connection of windings in a series wound DC motor impact its performance?
In a series wound DC motor, the field winding is connected in series with the armature winding. This design delivers high starting torque but offers poor speed regulation, making these motors suitable for heavy-duty applications like cranes and hoists.
8. Can you explain a real-world analogy to understand how an induction motor works?
An induction motor operates like a moving bicycle tire placed near a running fan; the air from the fan (magnetic field) induces movement in the tire (rotor) without direct contact, just as the changing magnetic field in the stator induces current and movement in the rotor of the motor.
9. What are the typical misconceptions students have about the direction of force in a motor?
A common misconception is that the force on the conductor is along the same direction as the current or magnetic field. In reality, according to Fleming's left-hand rule, the force acts perpendicular to both the magnetic field and the direction of current.
10. How can understanding the classification of motors help in selecting the right motor for an industrial application?
Knowing the classification of motors helps select the most efficient and appropriate motor based on operational needs such as required torque, speed control, precision, and cost. For example, a synchronous motor is chosen for constant speed, while a series DC motor is ideal for high starting torque demands.
