China Best Sales Industrial AC Servo Motor IEC Standard Premium Efficiency Asynchronous AC Induction Motor vacuum pump booster

Product Description

Product Description


Three Phase Asynchronous motor is the AC motors, the modular for 3 phase motor offers millions of possible drive combinations.

For the high efficiency electric motor, we have YE3, YE4, YE5 series, from 0.75kW to 315kW. For different voltage, frequency and different power, we can do the customized.

 Product Description

MOTOR TYPE Asynchronous motor, YE3, YE4, YE5.
STRUCTURE Iron Cast or Aluminum Housing, Customized.
VOLTAGE 380V, 400V, 440V, 660V, Customized.
FREQUENCY 50Hz(60Hz Available).
OUTPUT POWER 0.75kW~315kW.
PHASE Three Phase.
POLE 2pole, 4pole, 6pole, 8pole, 10pole.
COOLING METHOD IC 411/Customized.
DUTY S1 (24Hour continuous working).
ALTITUDE Not exceeding 1000m above sea level
MOUNTING TYPE B3,B5,B35, V1, V3,Customized.
STHangZhouRD IEC International Standard, China CCC, ISO 9001, CE.
PACKAGE Carton or Wooden Case, well protection, easy loading and delivery. 
APPLICATION Water Pump, Assembly line, Air Compressor, Packing and Food Machinery, Mill Machinery, fan, and other equipment.
WARRANTY 1 year except for the wear parts.
DELIVERY TIME 10-30 working days.

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Application: Industrial
Operating Speed: Constant Speed
Number of Stator: Three-Phase


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Currency: US$
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induction motor

Can induction motors be adapted for use in both residential and industrial settings?

Yes, induction motors can be adapted for use in both residential and industrial settings. Here’s a detailed explanation:

Induction motors are versatile and widely used in various applications due to their robustness, efficiency, and reliability. They can be found in both residential and industrial environments, albeit with some variations in design and performance characteristics.

Residential Use:

  • In residential settings, induction motors are commonly found in household appliances such as refrigerators, air conditioners, washing machines, fans, and pumps.
  • These motors are typically smaller in size and power compared to their industrial counterparts, as they are designed to meet the specific requirements of residential applications.
  • Residential induction motors are often single-phase motors, as most residential electrical systems are single-phase.
  • They are designed for easy installation, low noise operation, and energy efficiency to meet the demands of residential users.
  • These motors are typically optimized for specific applications, such as providing the necessary torque and speed control for appliances like washing machines or maintaining the desired temperature in air conditioners.

Industrial Use:

  • In industrial settings, induction motors are widely employed in a wide range of applications, including pumps, compressors, conveyor systems, machine tools, fans, blowers, and many more.
  • Industrial induction motors are available in a wide range of power ratings and sizes, allowing them to meet the diverse needs of industrial processes.
  • They are often three-phase motors, as most industrial electrical systems utilize three-phase power distribution.
  • Industrial motors are designed to handle heavy loads, operate under harsh conditions, and provide high levels of reliability and durability.
  • These motors can be adapted for specific industrial requirements, such as motors with explosion-proof enclosures for hazardous environments or motors with enhanced protection against dust and moisture.
  • Industrial induction motors may also incorporate advanced control features, such as variable frequency drives (VFDs), to enable precise speed control, energy savings, and integration into automated industrial systems.


While there are differences in design and performance characteristics between residential and industrial induction motors, the fundamental principles and technology behind them remain the same. Induction motors can be adapted to meet the specific needs of both residential and industrial settings by adjusting factors such as size, power rating, number of phases, construction materials, and control features.

Manufacturers cater to the distinct requirements of residential and industrial users by producing a wide variety of induction motors tailored to each application. This adaptability allows for the efficient use of induction motors in diverse settings, from small-scale residential applications to large-scale industrial operations.

In conclusion, induction motors can be successfully adapted for use in both residential and industrial settings by considering the specific requirements and optimizing the motor’s design and performance characteristics accordingly.

induction motor

How do induction motors handle challenges like variations in voltage and frequency?

Induction motors are designed to handle challenges such as variations in voltage and frequency, and they have mechanisms in place to ensure reliable operation under these conditions. Here’s a detailed explanation of how induction motors handle these challenges:

Voltage Variations:

Induction motors are typically designed to operate within a certain voltage range. However, they can handle variations in voltage to some extent. Here’s how they handle voltage variations:

  • Stator Windings: The stator windings of an induction motor are designed to withstand voltage fluctuations. The insulation materials used in the windings provide protection against voltage surges and dips. The winding design and the number of turns are optimized to ensure the motor can operate within the specified voltage range while maintaining reliable performance.
  • Voltage Regulation: Voltage regulators or voltage stabilizers can be used to control and regulate the voltage supplied to an induction motor. These devices ensure that the motor receives a stable voltage within the acceptable range, even in the presence of fluctuations in the power supply. Voltage regulation helps maintain consistent motor performance and prevents damage that could occur due to excessively high or low voltages.
  • Motor Protection Devices: Induction motors are often equipped with protective devices such as overvoltage relays and undervoltage relays. These devices monitor the incoming voltage and trigger appropriate actions if the voltage exceeds or falls below the predefined thresholds. For example, if the voltage exceeds a certain limit, the overvoltage relay may trip and disconnect the motor from the power supply to prevent damage.

Frequency Variations:

Induction motors are designed to operate at a specific frequency, typically 50 or 60 Hz, depending on the region. However, they can handle certain variations in frequency while maintaining reasonably stable performance. Here’s how induction motors handle frequency variations:

  • Synchronous Speed: The speed of an induction motor is determined by the frequency of the power supply and the number of poles in the motor. When the frequency varies, the synchronous speed of the motor changes accordingly. However, the motor’s actual operating speed, known as the slip speed, remains relatively constant. This allows the motor to maintain its output power and torque, although the speed may vary slightly.
  • Motor Design: The design of induction motors takes into account the expected frequency variations in the power supply. The number of poles and the winding configuration are selected to ensure that the motor can operate within an acceptable range of frequencies while maintaining optimal performance. The motor’s mechanical and electrical characteristics are carefully matched to achieve the desired operating parameters under different frequency conditions.
  • Frequency Converters: In some cases, frequency converters or Variable Frequency Drives (VFDs) are used to control the speed of induction motors. These devices can vary the frequency supplied to the motor, allowing precise control of the motor speed. Frequency converters are particularly useful in applications where the motor needs to operate at different speeds or where the power supply frequency is not compatible with the motor’s design.
  • Motor Protection Devices: Similar to voltage variations, induction motors can be equipped with protective devices to monitor the frequency of the power supply. These devices can detect significant deviations from the expected frequency and trigger appropriate actions, such as shutting down the motor or providing an alarm signal. Protecting the motor against extreme frequency variations helps prevent damage and ensures safe operation.

In conclusion, induction motors are designed to handle challenges such as variations in voltage and frequency. Through appropriate design considerations, voltage regulation mechanisms, protective devices, and the use of frequency converters, induction motors can operate reliably and maintain reasonably stable performance even in the presence of fluctuations in the power supply. These features contribute to the versatility and resilience of induction motors in various industrial applications.

induction motor

What is an induction motor and how does it function?

An induction motor is a type of AC (alternating current) electric motor widely used in various applications. It operates based on the principle of electromagnetic induction. Here’s a detailed explanation of how an induction motor functions:

  • Construction:
    • An induction motor consists of two main parts: the stator and the rotor.
    • The stator is the stationary part of the motor and contains a set of windings, typically made of copper wire, arranged in a specific pattern. These windings are connected to the power supply.
    • The rotor is the rotating part of the motor and is typically made of laminated iron cores with conductor bars or short-circuited conductive loops. The rotor is not directly connected to the power supply.
  • Principle of Operation:
    • When an AC voltage is applied to the stator windings, it produces a rotating magnetic field.
    • This rotating magnetic field induces a current in the rotor conductors through electromagnetic induction.
    • The rotor current creates its own magnetic field, which interacts with the stator’s rotating magnetic field.
    • The interaction between the two magnetic fields generates a torque in the rotor, causing it to rotate.
  • Slip:
    • In an induction motor, there is a speed difference, known as slip, between the rotating magnetic field of the stator and the rotor’s actual rotational speed.
    • The slip is necessary for the motor to generate torque. As the rotor accelerates, the slip decreases until the motor reaches its synchronous speed.
    • The synchronous speed is the speed at which the rotating magnetic field of the stator completes one full cycle. It is determined by dividing the frequency of the power supply by the number of poles in the motor.
    • The difference between the synchronous speed and the actual rotor speed is what allows the motor to develop torque and perform useful work.
  • Types of Induction Motors:
    • Induction motors can be classified into two main types: squirrel cage motors and wound rotor motors.
    • In squirrel cage motors, the rotor consists of conductive bars shorted at both ends by end rings, resembling a squirrel cage. They are simple, rugged, and commonly used in various industrial applications.
    • Wound rotor motors have a rotor with windings similar to the stator windings. These windings can be externally connected to resistors or other external devices. Wound rotor motors offer better control over motor characteristics.
  • Advantages and Applications:
    • Induction motors have several advantages, including simplicity, reliability, and high efficiency.
    • They are widely used in various applications such as pumps, fans, compressors, conveyor systems, and industrial machinery due to their robustness and ability to handle heavy loads.
    • Induction motors are also used extensively in household appliances, HVAC systems, and electric vehicles.

In summary, an induction motor functions by utilizing the principle of electromagnetic induction to produce a rotating magnetic field that interacts with the rotor, inducing current and generating torque. The slip between the stator’s rotating magnetic field and the rotor’s speed allows the motor to develop torque and perform mechanical work across a wide range of applications.

China Best Sales Industrial AC Servo Motor IEC Standard Premium Efficiency Asynchronous AC Induction Motor   vacuum pump booster	China Best Sales Industrial AC Servo Motor IEC Standard Premium Efficiency Asynchronous AC Induction Motor   vacuum pump booster
editor by CX 2024-04-11