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Asynchronous Vectorial Motors
asynchronous vectorial motors
High-efficiency control: Asynchronous vector motors (AVM) can accurately adjust the current and speed of the motor by applying advanced vector control technology, thereby achieving high-efficiency operation. Vector control technology makes the motor's operating state more in line with the actual load requirements and optimizes the motor's energy efficiency ratio. Specifically, this technology controls the current and magnetic flux by decoupling, so that the motor can maintain the best operating efficiency under different loads and working conditions. Compared with traditional control methods, AVM can significantly reduce energy loss and improve the overall energy efficiency of the system. This high-efficiency feature is particularly suitable for applications that require high dynamic response, such as industrial automation systems and elevator drives, where precise control of the motor directly affects the operating performance and energy saving of the equipment.
Excellent dynamic performance: Asynchronous vector motors have excellent dynamic response capabilities, allowing them to quickly adjust their operating state during load fluctuations or startup. AVM can quickly respond to load changes and achieve smooth acceleration and deceleration. This feature is particularly important in production line automation devices and robotic systems, because these applications often require frequent starting, stopping or speed adjustment. Conventional motors may be slow to respond or unstable in these situations, but AVM, through its precise dynamic control, can ensure smoother and more efficient operation of the equipment, improving the overall efficiency and reliability of the production line.
Stability and reliability: Stability and reliability are one of the important features of asynchronous vector motors. Through optimized design and selection of high-quality materials, AVM can maintain stable performance over long periods of operation. This stability is due to improvements in the internal structure of the motor, such as reducing friction and vibration, thereby reducing the probability of mechanical wear and failure. In addition, the durable design of the motor also reduces the need for maintenance and overhaul, reducing operating costs. This high reliability makes AVM excel in situations where long-term stable operation is required, such as large industrial equipment and infrastructure systems.
Precise torque control: Asynchronous vector motors can provide extremely precise torque control, which is particularly important in applications with strict load requirements. AVM's torque control system can maintain stable torque output under various operating conditions, ensuring reliable operation of the motor under both high and low load conditions. This precise control is critical for high-precision machining and complex processing processes, as these applications require the motor to provide stable and consistent power output under different load conditions. AVM's precise torque control not only improves processing quality, but also optimizes production efficiency, making it particularly outstanding in situations where performance requirements are extremely high.
Technical Specifications
| Specification | Description |
|---|---|
| Motor Type | Asynchronous Vectorial Motor |
| Voltage Rating | 380V ± 10% (Three-Phase) |
| Frequency | 50Hz or 60Hz |
| Power Range | 0.75 kW to 500 kW |
| Frame Size | IEC Frame Sizes 56 to 400 |
| Insulation Class | Class F (155°C) or Class H (180°C) |
| Protection Class | IP55 (dust and water resistant) |
| Efficiency Class | IE2 (Standard) or IE3 (High Efficiency) |
| Cooling Method | IC411 (Air-to-Air) or IC416 (Air-to-Water) |
| Speed Range | 0 to 3600 RPM |
| Starting Torque | 150% of Full Load Torque at Start |
| Rated Torque | Up to 300% of Rated Torque (for brief periods) |
| Control Type | Vector Control with Closed Loop Feedback |
| Mounting Type | B3 (Foot Mount) or B5 (Flange Mount) |
| Vibration Level | < 1.0 mm/s (for standard mounting and operation) |
| Ambient Temperature | -20°C to +40°C |
| Altitude | Up to 1000 meters above sea level |
| Bearing Type | Rolling Bearings with Lifetime Lubrication |
| Certification | CE, UL, ISO 9001 |
| Additional Features | Built-in thermal protection, over-voltage and under-voltage protection |
Application areas of asynchronous vectorial motors
Industrial Automation:
These motors are pivotal in the realm of industrial automation, where precise control over machinery and production processes is crucial. These motors excel in applications requiring exact speed and torque regulation. In conveyor systems, they facilitate smooth and controlled movement of materials, enhancing production efficiency and reducing bottlenecks. For assembly lines, their ability to maintain consistent performance despite varying loads ensures high-quality manufacturing and minimizes downtime. Additionally, in robotic arms, vectorial motors provide the fine-tuned control necessary for delicate operations and complex maneuvers.
The advanced vector control technology of these motors enables them to handle dynamic load conditions with ease. They can adjust their speed and torque in real-time based on the demands of the process, ensuring optimal performance and energy efficiency. This adaptability is particularly valuable in environments with fluctuating operational requirements or where precision is paramount. Overall, these motors contribute significantly to the reliability and efficiency of industrial automation systems, making them indispensable in modern manufacturing settings.
Agricultural Machinery:
In agricultural settings, these motors play a crucial role in enhancing the efficiency and reliability of various equipment. For irrigation systems, these motors ensure precise control over water flow and pressure, optimizing water usage and reducing waste. In harvesters, their robust design allows them to handle the demanding conditions of crop harvesting, providing consistent power and performance even in challenging environments. Feed mixers benefit from the motors' adaptability, enabling precise control of mixing speeds and consistency, which is essential for maintaining the quality of animal feed. Overall, the durability and advanced control features of these motors contribute significantly to improved automation, efficiency, and productivity in agricultural machinery, supporting better operational outcomes and resource management.
Installation Method:
| Structure and installation type (IM code)) |
IM B3 | IM B8 | IM B5 | IM B6 | IM V5 | IM V1 | IM B7 | IM V6 | IM V3 |
| Installation diagram |  |
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| Frame size | 63-450 | 63-160 | 63-280 | 63-160 | 63-160 | 63-450 | 63-160 | 63-160 | 63-160 |
| Structure and installation type (IM code)) |
IM V37 | IM V17 | IM B34 | IM V19 | IM V18 | IM B14 | IM V35 | IM V15 | IM B35 |
| Installation diagram |  |
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| Frame size | 63-132 | 63-13 | 63-132 | 63-132 | 63-132 | 63-132 | 63-160 | 63-160 | 63-450 |
FAQ
1.What are the key advantages of using this type of motor in industrial applications?
This type of motor offers significant advantages in industrial settings due to its precise control over speed and torque. Its ability to adjust performance in real-time based on load conditions makes it ideal for applications requiring accurate and dynamic response, such as conveyor systems and robotic arms. Additionally, the motor's efficiency in varying operational environments helps reduce energy consumption and operational costs. Its robustness and reliability ensure consistent performance even under challenging conditions, contributing to overall system stability and productivity.
2.How does this motor handle varying loads and operational conditions?
The motor is designed with advanced control mechanisms that allow it to handle a wide range of load variations. Its vector control technology enables precise adjustment of both speed and torque in response to changing load demands. This capability ensures stable operation and minimizes performance fluctuations, making it suitable for applications where load conditions frequently change. The motor's adaptability to different operational environments ensures reliable performance across various industrial processes.
3.What maintenance requirements are associated with this motor?
Maintenance for this motor is relatively straightforward due to its robust design and durable construction. Regular checks on components such as bearings, insulation, and connections are recommended to ensure optimal performance and longevity. The motor's design often includes features that minimize wear and tear, reducing the need for frequent maintenance. Periodic inspections and timely lubrication of bearings can help extend the motor's operational life and prevent unexpected downtimes.
4.Can this motor be used in applications that require high precision?
Yes, this motor is well-suited for applications requiring high precision due to its advanced control capabilities. The motor's vector control technology allows for accurate regulation of speed and torque, which is crucial for applications like CNC machines and automated assembly lines. Its ability to deliver consistent performance and respond swiftly to control signals ensures that it can meet the stringent precision requirements of such applications.
5.What are the energy efficiency benefits of using this motor?
The motor is designed to be highly energy-efficient, thanks to its ability to adjust performance based on real-time load conditions. This adaptability helps minimize energy waste, as the motor only uses the amount of power necessary for the current operational demands. By reducing excess energy consumption and optimizing performance, the motor contributes to lower operational costs and supports sustainability goals by reducing the overall energy footprint.
6.How does this motor perform in harsh environmental conditions?
The motor is engineered to withstand harsh environmental conditions, including extreme temperatures, dust, and moisture. Its robust construction and protective features, such as high IP (Ingress Protection) ratings, ensure reliable performance even in challenging environments. This makes it suitable for use in outdoor applications or industrial settings where environmental factors may impact performance.
7.What control methods are available for this motor?
This motor supports various control methods, including vector control and closed-loop feedback systems. Vector control allows for precise adjustment of speed and torque, enhancing performance in applications requiring dynamic and accurate control. Closed-loop feedback systems further enhance control by continuously monitoring and adjusting the motor's performance based on real-time data. These control methods enable versatile application in a wide range of industrial processes, offering flexibility and improved operational efficiency.
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