China Good quality Y Series Three Phase Casting Iron AC Synchronous Electric Motor vacuum pump design

Product Description

Y Series Three phase casting iron ac generator motor

Yseries motor is totally enclosed and fan-cooling, 3 phase squirrel cage induction motor,that is newly designed in conformity with the relevant requirements of IEC standards.
Y series motors have outstanding performance, such as high efficiency, energy-saving, high starting torque, low noise, little vibration, reliable operation and easy maintenance,etc. 
Y series motors are widely used in places, where there doesn’t exist combustible, explosive or corrosive gas, tools, pumps, fans, transport machinery, mixer, agriculture machinery and food machines, etc. 

Working Condition

1. Ambient Working Temperature: Ambient temperature varying with seasons should be between 40ºC and -15ºC.

2. Altitude: Not over 1000m above sea level.

3. The average relative humidity in the most moisture month is 90%. And meanwhile, the average lowest temperature should not be over 25ºC.

4. Termination: Y connection below 3KW. Delta connection if over 4KW.

5. Operation Mode(duty): S1.



Frame Size(H80-H160): IM B3, B5, B35, V1, B14, B34, V3,V5, V6, V15, etc.

Frame Size(H180-H280): IM B3, B5, B35, V1.

Frame Size(H315-H355): IM B3, B35, V1


Type Output Current
Eff (%) Speed
Tstart/Tn Ist/In  
Y801-2 0.75 1 1.8 0.84 75 2380 2.2 6.5 2.3
Y802-2 1.1 1.5 2.5 0.86 77 2380 2.2 7 2.3
Y801-4 0.55 0.75 1.5 0.76 73 1390 2.4 6 2.3
Y802-4 0.75 1 2 0.76 74.5 1390 2.3 6 2.3
Y90S-2 1.5 2 3.4 0.85 78 2840 2.2 7 2.3
Y90L-2 2.2 3 4.8 0.86 80.5 2840 2.2 7 2.3
Y90S-4 1.1 1.5 2.8 0.78 78 1400 2.3 6.5 2.3
Y90L-4 1.5 2 3.7 0.79 79 1400 2.3 6.5 2.3
Y90S-6 0.75 1 2.3 0.7 72.5 910 2 5.5 2.2
Y90L-6 1.1 1.5 3.2 0.72 73.5 910 2 5.5 2.2
Y100L-2 3 4 6.4 0.87 82 2870 2.2 7 2.3
Y100L1-4 2.2 3 5 0.82 81 1430 2.2 7 2.3
Y100L2-4 3 4 6.8 0.81 82.5 1430 2.2 7 2.3
Y100L-6 1.5 2 4 0.74 77.5 940 2 6 2.2
Y112M-2 4 5.5 8.2 0.87 85.5 2890 2.2 7 2.3
Y112M-4 4 5.5 8.8 0.82 84.5 1440 2.2 7 2.3
Y112M-6 2.2 3 5.6 0.74 80.5 940 2.2 6 2.2
Y132S1-2 5.5 7.5 11.1 0.88 85.5 2900 2 7 2.3
Y132S2-2 7.5 10 15 0.88 86.2 2900 2 7 2.3
Y132S-4 5.5 7.5 11.7 0.84 85.5 1440 2.2 7 2.3
Y132M-4 7.5 10 15.4 0.85 87 1440 2 7 2.3
Y132S-6 3 4 7.3 0.76 83 960 2 6.5 2.2
Y132M1-6 4 5.5 9.4 0.77 84 960 2 6.5 2.2
Y132M2-6 5.5 7.5 12.6 0.78 85.3 960 2 6.5 2.2
Y160M1-2 11 15 21.8 0.88 87.2 2930 2 7 2.2
Y160M2-2 15 20 29.4 0.88 88.2 2930 2 7 2.2
Y160L-2 18.5 25 35.5 0.89 89 2930 2 7 2.2
Y160M-4 11 15 22.6 0.84 88 1460 2.2 7 2.2
Y160L-4 15 20 30.3 0.85 88.5 1460 2.2 7 2.2
Y160M-6 7.5 10 17 0.78 86 970 2 6.5 2
Y160L-6 11 15 24.6 0.78 87 970 2 6.5 2
Y180M-2 22 30 42.2 0.89 89 2940 2 7 2.2
Y180M-4 18.5 25 35.9 0.86 91 1470 2 7 2.2
Y180L-4 22 30 42.5 0.86 91.5 1470 2 7 2.2
Y180L-6 15 20 31.6 0.81 89.5 970 1.8 6.5 2
Y200L1-2 30 40 56.9 0.89 90 2950 2 7 2.2
Y200L2-2 37 50 69.8 0.89 90.5 2950 2 7 2.2
Y200L-4 30 40 56.8 0.87 92.2 1470 2 7 2.2
Y200L1-6 18.5 25 37.7 0.83 89.8 970 1.8 6.5 2
Y200L2-6 22 30 44.6 0.83 90.2 970 1.8 6.5 2
Y225M-2 45 60 84.4 0.89 91 2970 2 7 2.2
Y225S-4 37 50 69.9 0.87 92.5 1480 2 7 2.2
Y225M-4 45 60 84.7 0.87 92.8 1480 2 7 2.2
Y225M-6 30 40 59.3 0.84 91.5 980 1.8 6.5 2

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Application: Household Appliances
Operating Speed: Constant Speed
Operation Mode: Electric Motor
Magnetic Structure: Inductor Type
Function: Driving
Structure: Rotating Pole Type (Armature Fixed)


electric motor

How do electric motors contribute to the efficiency of tasks like transportation?

Electric motors play a significant role in enhancing the efficiency of various transportation tasks. Their unique characteristics and advantages contribute to improved performance, reduced energy consumption, and environmental benefits. Here’s a detailed explanation of how electric motors contribute to the efficiency of tasks like transportation:

  1. High Energy Conversion Efficiency: Electric motors are known for their high energy conversion efficiency. They can convert a large percentage of electrical energy supplied to them into mechanical energy, resulting in minimal energy losses. Compared to internal combustion engines (ICEs), electric motors can achieve significantly higher efficiencies, which translates to improved energy utilization and reduced fuel consumption.
  2. Instant Torque and Responsive Performance: Electric motors deliver instant torque, providing quick acceleration and responsive performance. This characteristic is particularly advantageous in transportation tasks, such as electric vehicles (EVs) and electric trains, where rapid acceleration and deceleration are required. The immediate response of electric motors enhances overall vehicle efficiency and driver experience.
  3. Regenerative Braking: Electric motors enable regenerative braking, a process where the motor acts as a generator to convert kinetic energy into electrical energy during deceleration or braking. This recovered energy is then stored in batteries or fed back into the power grid, reducing energy waste and extending the vehicle’s range. Regenerative braking improves overall efficiency and helps maximize the energy efficiency of electric vehicles.
  4. Efficient Power Distribution: Electric motors in transportation systems can be powered by electricity generated from various sources, including renewable energy. This allows for a diversified and cleaner energy mix, contributing to reduced greenhouse gas emissions and environmental impact. By utilizing electric motors, transportation tasks can leverage the increasing availability of renewable energy resources, leading to a more sustainable and efficient transport ecosystem.
  5. Reduced Maintenance Requirements: Electric motors have fewer moving parts compared to ICEs, resulting in reduced maintenance requirements. They eliminate the need for components like spark plugs, fuel injection systems, and complex exhaust systems. As a result, electric motors typically have longer service intervals, lower maintenance costs, and reduced downtime. This enhances operational efficiency and reduces the overall maintenance burden in transportation applications.
  6. Quiet and Vibration-Free Operation: Electric motors operate quietly and produce minimal vibrations compared to ICEs. This characteristic contributes to a more comfortable and pleasant passenger experience, especially in electric vehicles and electric trains. The reduced noise and vibration levels enhance the overall efficiency and comfort of transportation tasks while minimizing noise pollution in urban environments.
  7. Efficient Power Management and Control: Electric motors can be integrated with advanced power management and control systems. This allows for precise control over motor speed, torque, and power output, optimizing efficiency for specific transportation tasks. Intelligent control algorithms and energy management systems can further enhance the efficiency of electric motors by dynamically adjusting power delivery based on demand, driving conditions, and energy availability.
  8. Reduction of Emissions and Environmental Impact: Electric motors contribute to significant reductions in emissions and environmental impact compared to traditional combustion engines. By eliminating direct emissions at the point of use, electric motors help improve air quality and reduce greenhouse gas emissions. When powered by renewable energy sources, electric motors enable nearly zero-emission transportation, paving the way for a cleaner and more sustainable transportation sector.

Through their high energy conversion efficiency, instant torque, regenerative braking, efficient power distribution, reduced maintenance requirements, quiet operation, efficient power management, and environmental benefits, electric motors significantly enhance the efficiency of tasks like transportation. The widespread adoption of electric motors in transportation systems has the potential to revolutionize the industry, promoting energy efficiency, reducing reliance on fossil fuels, and mitigating environmental impact.

electric motor

How do electric motors contribute to the precision of tasks like robotics?

Electric motors play a critical role in enabling the precision of tasks in robotics. Their unique characteristics and capabilities make them well-suited for precise and controlled movements required in robotic applications. Here’s a detailed explanation of how electric motors contribute to the precision of tasks in robotics:

  1. Precise Positioning: Electric motors offer precise positioning capabilities, allowing robots to move with accuracy and repeatability. By controlling the motor’s speed, direction, and rotation, robots can achieve precise position control, enabling them to perform tasks with high levels of accuracy. This is particularly important in applications that require precise manipulation, such as assembly tasks, pick-and-place operations, and surgical procedures.
  2. Speed Control: Electric motors provide precise speed control, allowing robots to perform tasks at varying speeds depending on the requirements. By adjusting the motor’s speed, robots can achieve smooth and controlled movements, which is crucial for tasks that involve delicate handling or interactions with objects or humans. The ability to control motor speed precisely enhances the overall precision and safety of robotic operations.
  3. Torque Control: Electric motors offer precise torque control, which is essential for tasks that require forceful or delicate interactions. Torque control allows robots to exert the appropriate amount of force or torque, enabling them to handle objects, perform assembly tasks, or execute movements with the required precision. By modulating the motor’s torque output, robots can delicately manipulate objects without causing damage or apply sufficient force for tasks that demand strength.
  4. Feedback Control Systems: Electric motors in robotics are often integrated with feedback control systems to enhance precision. These systems utilize sensors, such as encoders or resolvers, to provide real-time feedback on the motor’s position, speed, and torque. The feedback information is used to continuously adjust and fine-tune the motor’s performance, compensating for any errors or deviations and ensuring precise movements. The closed-loop nature of feedback control systems allows robots to maintain accuracy and adapt to dynamic environments or changing task requirements.
  5. Dynamic Response: Electric motors exhibit excellent dynamic response characteristics, enabling quick and precise adjustments to changes in command signals. This responsiveness is particularly advantageous in robotics, where rapid and accurate movements are often required. Electric motors can swiftly accelerate, decelerate, and change direction, allowing robots to perform intricate tasks with precision and efficiency.
  6. Compact and Lightweight: Electric motors are available in compact and lightweight designs, making them suitable for integration into various robotic systems. Their small size and high power-to-weight ratio allow for efficient utilization of space and minimal impact on the overall weight and size of the robot. This compactness and lightness contribute to the overall precision and maneuverability of robotic platforms.

Electric motors, with their precise positioning, speed control, torque control, feedback control systems, dynamic response, and compactness, significantly contribute to the precision of tasks in robotics. These motors enable robots to execute precise movements, manipulate objects with accuracy, and perform tasks that require high levels of precision. The integration of electric motors with advanced control algorithms and sensory feedback systems empowers robots to adapt to various environments, interact safely with humans, and achieve precise and controlled outcomes in a wide range of robotic applications.

electric motor

What is an electric motor and how does it function?

An electric motor is a device that converts electrical energy into mechanical energy. It is a common type of motor used in various applications, ranging from household appliances to industrial machinery. Electric motors operate based on the principle of electromagnetism and utilize the interaction between magnetic fields and electric current to generate rotational motion. Here’s a detailed explanation of how an electric motor functions:

  1. Basic Components: An electric motor consists of several key components. These include a stationary part called the stator, which typically contains one or more coils of wire wrapped around a core, and a rotating part called the rotor, which is connected to an output shaft. The stator and the rotor are often made of magnetic materials.
  2. Electromagnetic Fields: The stator is supplied with an electric current, which creates a magnetic field around the coils. This magnetic field is typically generated by the flow of direct current (DC) or alternating current (AC) through the coils. The rotor, on the other hand, may have permanent magnets or electromagnets that produce their own magnetic fields.
  3. Magnetic Interactions: When an electric current flows through the coils in the stator, it generates a magnetic field. The interaction between the magnetic fields of the stator and the rotor causes a rotational force or torque to be exerted on the rotor. The direction of the current and the arrangement of the magnetic fields determine the direction of the rotational motion.
  4. Electromagnetic Induction: In some types of electric motors, such as induction motors, electromagnetic induction plays a significant role. When alternating current is supplied to the stator, it creates a changing magnetic field that induces voltage in the rotor. This induced voltage generates a current in the rotor, which in turn produces a magnetic field that interacts with the stator’s magnetic field, resulting in rotation.
  5. Commutation: In motors that use direct current (DC), such as brushed DC motors, an additional component called a commutator is employed. The commutator helps to reverse the direction of the current in the rotor’s electromagnets as the rotor rotates. By periodically reversing the current, the commutator ensures that the magnetic fields of the rotor and the stator are always properly aligned, resulting in continuous rotation.
  6. Output Shaft: The rotational motion generated by the interaction of the magnetic fields is transferred to the output shaft of the motor. The output shaft is connected to the load, such as a fan blade or a conveyor belt, allowing the mechanical energy produced by the motor to be utilized for various applications.

In summary, an electric motor converts electrical energy into mechanical energy through the interaction of magnetic fields and electric current. By supplying an electric current to the stator, a magnetic field is created, which interacts with the magnetic field of the rotor, causing rotational motion. The type of motor and the arrangement of its components determine the specific operation and characteristics of the motor. Electric motors are widely used in numerous devices and systems, providing efficient and reliable mechanical power for a wide range of applications.

China Good quality Y Series Three Phase Casting Iron AC Synchronous Electric Motor   vacuum pump design		China Good quality Y Series Three Phase Casting Iron AC Synchronous Electric Motor   vacuum pump design
editor by CX 2024-05-17

electric motor

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