Electric Machine Design Using Speed and Motor Cad Pdf
Electric motor
- Motor construction
- Working principle
- Motor classification
- Types of electric motors
- Commutator motors
- Commutatorless motors
- Special motors
- The main parameters of the motor
- Motor torque
- Motor power
- Efficiency
- Rated speed
- Moment of inertia of the rotor
- Rated voltage
- Electrical time constant
- Torque-speed curve
- Comparison of motors characteristics
- Application fields
- Manufacturers
An electric motor - is an
electrical machine by which electrical energy is converted into mechanical energy, for driving various mechanisms. The electric motor is the main element of the
electric drive.
In some operating modes of the electric drive, the electric motor performs the reverse energy conversion, that is, it operates in the mode of an electric generator.
By the type of created mechanical motion, electric motors are divided into rotating, linear, etc. By an electric motor, a rotating motor is most often meant, since it has received the greatest use.
The field of science and technology studying electrical machines is electromechanics. It is considered that its history begins in 1821 when the first electric motor was created by M. Faraday.
Motor construction
The main components of a rotating electric motor are the stator and the rotor. The stator is the fixed part. The rotor is the rotating part.
Standard construction of the rotating motor
For most electric motors the rotor is located inside the stator. Electric motors in which the rotor is located outside the stator are called inside out electric motors.
Working principle of the motor
1. According to
Ampere's law, a force F will act on a conductor with a current I in a magnetic field.
2. If a conductor with current I is bent into a frame and placed in a magnetic field, then the two sides of the frame, which are at right angles to the magnetic field, will experience oppositely directed forces F.
3. The forces acting on the frame, create a torque or moment of force, rotating it.
4. The armature of the produced electric motors has several turns to provide greater constant torque.
5. The magnetic field can be created both by magnets and electromagnets. An electromagnet is usually a wire wound on a core. Thus, according to the
Faraday's law of induction, the current flowing into the frames will induce a current in the windings of an electromagnet, which in turn will create a magnetic field.
- A detailed description of the working principle of electric motors of different types:
- Working principle of single-phase induction motor
- Working principle of a three-phase induction motor
- Working principle of a synchronous motor
Motor classification
Rotating electric motor | ||||
---|---|---|---|---|
Self-Commutated | Externally Commutated | |||
Mechanical-Commutator Motors | Electronic-Commutator Motors1 | Induction motors | Synchronous motors | |
AC | DC | AC2 | AC | |
|
|
|
|
|
Simple electronics | Rectifier, transistors | More elaborate electronics | Most elaborate electronics (VFD) when provided |
Note:
- This category does not represent a separate class of electric motors, since the devices in the category under consideration (BLDC, SRM) are a combination of a brushless motor, an electric converter (inverter) and, in some cases, a rotor position sensor (e.g. Hall sensors). In these devices, the electric converter, in view of its low complexity and small dimensions, is usually integrated into an electric motor.
- The electric motors used in BLDC and SRM are AC motors. However, due to the presence of an electric converter in these devices, they are connected to the DC power grid.
- A stepper motor is not a separate motor class. Structurally, it is the PMSM, SyRM or the hybrid SyRM-PM.
Types of electric motors
Commutator motors
Сommutator machine is a rotating electrical machine, which has at least one of the windings involved in the main process of energy conversion, is connected to a collector [1]. In a collector motor, the brush-collector assembly performs the function of a rotor position sensor and a current switch in the windings.
Universal motor
Can work on AC and DC power supply. It is widely used in hand-held power tools and in some household appliances (in vacuum cleaners, washing machines, etc.). In the USA and Europe, it was used as a traction motor. Received a wide distribution due to its small size, relatively low price and simple control.
Brushed DC electric motor
An electric machine that converts direct current electrical energy into mechanical energy. The advantages of the DC motor are high starting torque, speed, the ability to smoothly control the rotational speed, the simplicity of the device and control. The disadvantage of the motor is the need for maintenance of collector-brush assembly and limited lifetime due to wear of the collector.
- With permanent magnet
- With wound stator
Commutatorless motors
Commutatorless electric motors can have contact rings with brushes, so do not confuse commutatorless electric motors and brushless electric motors.
A brushless machine is a rotating electrical machine in which all electrical connections of the windings involved in the basic process of energy conversion are carried out without sliding electrical contacts [1].
Induction motor
The most common electric motor in the industry. The advantages of the electric motor are the simplicity of design, reliability, low cost, high service life, high starting torque, and overload capacity. The disadvantage of an induction motor is the complexity of the rotational speed control.
- Single phase
- Two phase
- Three phase
Special electric motors
Servomotor
Servo motors are not a separate class of motors. As a servomotor can be used DC and AC electric motors with a rotor position sensor. The servo motor is used in the servo-mechanism for precise control of the angular position, speed, and acceleration of the actuator. To operate, a servomotor requires a relatively complex control system, which is usually developed specifically for a servo drive.
The main parameters of the motor
- Motor torque
- Motor power
- Coefficient of efficiency
- Rated speed
- Moment of inertia of the rotor
- Rated voltage
- Electrical time constant
- Torque-speed curve
Motor torque
Torque (synonyms: a moment of force) is a vector physical quantity equal to the product of the radius-vector, drawn from the axis of rotation to the point of application of force, by the vector of this force.
,
- where M – torque, Nm,
- F – force, N,
- r – radius-vector, m
Tip: Rated torque Mr, Nm, determined by the formula
,
- where Pr – rated motor power, W,
- nr - rated speed, min-1 [4]
The initial starting torque is the motor torque at start-up.
Tip: In the English system of measurement, force is measured in ounce-force (oz, ozf) or pound-force (lb, lbf)
1 oz = 1/16 lb = 0,2780139 N
1 lb = 4,448222 N
torque is measured in ounce-force inch (oz∙in) or pound-force inch (lb∙in)
1 oz∙in = 0,007062 Nm
1 lb∙in = 0,112985 Nm
Motor power
Motor power is the useful mechanical power at the motor shaft.
Mechanical power
Power is a physical quantity that shows what kind of work the mechanism performs per unit of time.
,
- where P – power, W,
- A – work, J,
- t - time, s
Work is a scalar physical quantity equal to the product of the projection of the force on the direction F and the path s traversed by the point of application of force [2].
,
- where s – displacement, m
For rotational motion
,
- where – angle, rad,
,
- where – angular velocity, rad/s,
Thus it is possible to calculate the value of mechanical power on the shaft of a rotating electric motor.
Tip: Rated value is the value of the electrical device parameter specified by the manufacturer, at which it should work, which is the source for counting deviations.
The energy conversion efficiency of the electric motor
Energy conversion efficiency of the electric motor is a characteristic of the machine effectiveness in relation to the conversion of electrical energy into mechanical energy.
,
- where – efficiency of the electric motor,
- P1 - input power (electrical), Вт,
- P2 - useful output power ( mechanical), W
- In this case, losses in electric motors are due to:
- electric losses - in the form of heat as a result of heating of conductors with the current;
- magnetic losses - core remagnetization losses: eddy current losses, hysteresis, and magnetic aftereffects;
- mechanical losses - friction losses in bearings, on ventilation, on brushes (if any);
- additional losses - losses caused by higher harmonics of magnetic fields arising due to the tooth structure of the stator, rotor and the presence of higher harmonics of the magnetomotive force of the windings.
The efficiency of the electric motor can vary from 10 to 99% depending on the type and design.
The International Electrotechnical Commission determines the requirements for the efficiency of electric motors. According to the standard IEC 60034-31: 2010, four efficiency classes are defined for synchronous and induction electric motors: IE1, IE2, IE3, and IE4.
Rated speed
,
- where n - is the rotation speed (frequency) of the electric motor, rev/min
Moment of inertia of the rotor
The moment of inertia - a scalar physical quantity, which is a measure of the inertia of a body in a rotational motion around an axis, is equal to the sum of the products of the masses of material points and the squares of their distances from the axis.
,
- where J – the moment of inertia, kg∙m2,
- m - mass, kg
Tip: In the English system of measures, the moment of inertia is measured in ounce-force-inch (oz∙in∙s2)
1 oz∙in∙s2 = 0,007062 kg∙m2
The moment of inertia is associated with the moment of force as follows
,
- где – angular acceleration, s-2 [2]
,
Rated voltage
Rated voltage - is the voltage to which the power grid or equipment is designed and to which their characteristics is referred [3].
Electrical time constant
The electrical time constant is the time counted from the moment a DC voltage is applied to the electric motor, during which the current reaches a level of 63.21% (1-1/e) of its final value.
,
- где – time constant, s
Torque-speed curve
The torque-speed curve (mechanical characteristic) of the motor is a graphically expressed dependence of the shaft speed from the electromagnetic torque at a DC supply voltage.
Comparison of characteristics of externally commutated motors
Below are the comparative characteristics of externally commutated electric motors, in terms of use as traction motors in vehicles.
-
Comparison of torque-speed curves of different types of electric motors with a limited stator current
-
The dependence of power from the shaft rotation speed for motors of different types with a limited stator current
Parameter | SCIM | SPMSM | IPMSM | SyRM-PM | WRSM |
---|---|---|---|---|---|
Constant power over speed range | |||||
Torque per stator current | |||||
Efficiency over complete operating range | |||||
Weight |
Note:
Orange color is low index; yellow is medium; light yellow is high.
In accordance with the above indicators, a hybrid synchronous electric motor, namely a synchronous reluctance electric motor with incorporated permanent magnets, is most suitable for use as a traction electric motor in the automotive industry (the choice was made for the BMW i3 & BMW i8 concept). The use of reactive torque provides high power in the upper speed range. Moreover, such a motor provides very high efficiency in a wide operating range [7].
Electric motors applications
Electric motors are the largest consumers of electricity in the world, they account for about 45% of the total electricity consumed [6].
- Electric motors are used everywhere, the main applications:
- industry: pumps, fans, compressors, conveyors, driving force for other machines, etc.
- construction: pumps, fans, conveyors, elevators, heating, ventilation and air conditioning systems, etc.
- consumer devices: refrigerators, air conditioners, personal computers and laptops (hard drives, fans), vacuum cleaners, washing machines, mixers, etc.
Motor | Functions | Application |
---|---|---|
Rotating electric motors | Pumps | Water supply and drainage systems |
Heating, cooling and chilling systems, HVAC1, irrigation systems | ||
Sewage system | ||
Oil pipeline | ||
Fans | Room air supply and exhaust, blowers, HVAC1 | |
Compressors | Cooling machines for air conditioning and commercial freezers, refrigerators and freezers, HVAC1 | |
Compressed-air storage and distribution system, pneumatic systems | ||
Liquification systems | ||
Rotating, mix, stir | Roller, rotors: metal, stone, plastics processing | |
Extruder: aluminium, plastics processing | ||
Textile handling: weaving, washing, drying | ||
Mixers, stirring: food, colour, plastics | ||
Transport | Passenger elevator, escalator, conveyor | |
Goods elevator, cranes, hoists, conveyor | ||
Vehicles: train, tram, trolley, cars, buses, electric cars, bikes and bicycles, cog wheel train, cable car, ropeway | ||
Angular position (stepper motors, servomotors) | Valve (open/close) | |
Servo (setting position) | ||
Linear motors | Open/close | Valve |
Sort | Production | |
Grab and place | Robots |
Note:
- HVAC - Heating, Ventilation, & Air Conditioning
Electric motor manufacturers
A country | Manufacturer | Induction motor | Synchronous motor | Universal | Brushed DC motor | |||||
---|---|---|---|---|---|---|---|---|---|---|
SCIM | WRIM | WRSM | PMSM, servo | SyRM, Hysteresis | Stepper | Wound field DC motor (wound stator) | PMDC motor (permanent magnet stator) | |||
Switzerland | ABB Limited | |||||||||
USA | Allied Motion Technologies Inc. | |||||||||
USA | Ametek Inc. | |||||||||
USA | Anaheim automation | |||||||||
USA | Arc System Inc. | |||||||||
Germany | Baumueller | |||||||||
Slovenia | Domel | |||||||||
USA | Emerson Electric Corporation | |||||||||
USA | General Electric | |||||||||
USA | Johnson Electric Holdings Limited | |||||||||
Germany | Liebherr | |||||||||
Switzerland | Maxon motor | |||||||||
Japan | Nidec Corporation | |||||||||
Germany | Nord | |||||||||
USA | Regal Beloit Corporation | |||||||||
Germany | Rexroth Bosch Group | |||||||||
Germany | Siemens AG | |||||||||
Brazil | WEG |
- GOST 27471-87 Rotating electrical machines. Terms and definitions.
- I.V. Saveliev. The course of general physics, volume I. Mechanics, oscillations and waves, molecular physics.-Moscow: 1970.
- IEC 38-83 Standard voltages.
- GOST 16264.0-85 Low power electric motors.
- A.I.Voldek, V.V.Popov. Electrical machines. AC machines: A textbook for universities.- Saint Petersburg.: 2007.
- Paul Waide, Conrad U. Brunner. Energy-Efficiency Policy Opportunities for Electric Motor-Driven Systems. International Energy Agency Working Paper, Energy Efficiency Series.: Paris, 2011.
- Dr. J. Merwerth. The hybrid-synchronous machine of the new BMW i3 & i8 challenges with electric traction drives for vehicles. BMW Group, Workshop University Lund: Lund, 2014.
References
Also read
-
Synchronous reluctance motor
Construction, working principle, and features of a synchronous reluctance motor
-
Brushed DC motor
The construction, types, working principle and main parameters of the brushed DC motor
-
Single-phase induction motor
Types of single-phase induction electric motors, their design, and the principle of operation. Wiring diagrams of single-phase electric motor
-
Hysteresis-reluctance motor
The construction, principle of operation, advantages, and disadvantages of the hysteresis-reluctance synchronous motor
Electric Machine Design Using Speed and Motor Cad Pdf
Source: https://en.engineering-solutions.ru/motorcontrol/motor/