TECHNICAL SPECIFICATIONS

Schneider Electric ATV312H055N4

The Schneider Electric ATV312H055N4 variable speed drive (VSD) is intended for three-phase asynchronous motor control. It is part of the Altivar ATV312 series, noted for its compact size, adaptability, and dependable motor control.

Technical Features of ATV312H055N4:

The ATV312H055N4 can handle up to 0.55 kW of motor power and runs at a voltage range of 380 - 500V AC. The VSD allows customers to adjust motor speed precisely, reducing energy usage and improving process control. The variable speed range allows for smooth and efficient motor running under various load circumstances.

It has motor protection capabilities to protect the motor from damage caused by overcurrent, overheating, or other electrical issues. This guarantees that the motor operates reliably and safely.

Due to its compact size, it is ideal for applications with limited space. Its compact design makes it simple to install in control panels or cabinets, maximizing space utilization. Short-circuit protection, motor phase loss protection, and safe torque off (STO) capability are all included in the drive. These safety measures improve personnel and equipment protection.

Product Compliance:

The Schneider Electric ATV312H055N4 variable speed drive (VSD) is designed and built to meet a variety of product compliance criteria, assuring safe and dependable operation in industrial applications.

The model meets electromagnetic compatibility (EMC) standards such as IEC 61800-3. This guarantees that the VSD meets the emission and immunity standards, preventing interference with other electrical equipment and allowing it to operate reliably in a variety of electromagnetic situations.

Another crucial aspect is environmental compliance. Schneider Electric complies with environmental rules and regulations to ensure that the ATV312H055N4 VSD meets applicable standards.

Compliance with guidelines such as the Restriction of Hazardous Compounds (RoHS) shows the company's commitment to environmental sustainability by limiting the use of hazardous compounds in the product.

Quality requirements are also prioritized in the production of the ATV312H055N4. Schneider Electric adheres to best practices in the industry and quality management systems such as ISO 9001. These procedures ensure that the VSD is built to the highest quality standards, meeting or exceeding customer expectations for reliability and performance.

Schneider Electric also takes into account industry-specific compliance regulations. The model ATV312H055N4 may meet specific standards and regulations applicable to industries such as manufacturing, water and wastewater, oil and gas, and building automation, depending on the application and market. This industry-specific compliance ensures that the VSD meets the needs and laws of many industries.

EMC Filters:

EMC filters, or electromagnetic compatibility filters or EMI filters, are electronic components that minimize EMI and assure compliance with electromagnetic compatibility standards. These filters are frequently employed in various electrical and electronic systems to reduce electromagnetic noise and maintain signal integrity.

EMC filters prevent or attenuate unwanted electromagnetic radiation or noise electrical the ATV312H055N4 device produce. They comprise passive components such as inductors, capacitors, and resistors arranged in certain patterns to form a filtering network.

This network aids in the filtering of high-frequency noise, preventing it from being transmitted or radiated from the equipment. EMC filters' principal role is to reduce a device's electromagnetic emissions while protecting it from external electromagnetic interference.

Depending on the use and requirements, they can be positioned at various points within an electrical system, such as the power input, output, or signal lines. EMC filters can help improve the overall performance and dependability of electrical systems and decrease electromagnetic interference.

They help to maintain signal integrity, avoid data corruption, and limit the likelihood of malfunctions or failures caused by electromagnetic interference by minimizing electromagnetic noise.