High-Performance N52 Grade Square Neodymium
Magnet for Generator Applications – Ideal for Advanced Engineering Solutions
This premium square neodymium magnet, engineered to the highest industry standards, is specifically designed for use in high-efficiency generator systems. With a maximum energy product of 52 MGOe (Mega-Gauss Oersteds), this N52 grade square magnet delivers exceptional magnetic strength and thermal stability, making it an ideal choice for applications demanding consistent power output under extreme conditions. Whether you're building permanent magnet generators, wind turbines, or industrial motors, this magnet ensures optimal performance and longevity.
The unique square geometry enhances magnetic flux concentration, improving torque density and reducing mechanical losses in rotating machinery. Unlike traditional ferrite or alnico magnets, this rare-earth neodymium magnet offers superior coercivity and remanence—critical factors for maintaining efficiency across varying loads and temperatures. Its precision-machined surface and tight dimensional tolerances ensure seamless integration into custom motor designs without compromising structural integrity.
Key Features:
Grade: N52 – Highest available neodymium grade for maximum magnetic output
Shape: Precision-cut square design for enhanced flux control
Material: NdFeB (Neodymium-Iron-Boron) alloy with protective coating (nickel-copper-nickel)
Temperature Range: Operates efficiently from -40°C to +150°C
Applications: Permanent magnet generators, electric vehicle drivetrains, renewable energy systems
Engineered for durability and performance, these
Square Magnets are ideal for high-performance environments where reliability is non-negotiable. The N52 grade provides up to 30% more flux density than standard N42 magnets, enabling smaller, lighter, and more powerful generator units. This makes them particularly suitable for aerospace, marine propulsion, and portable energy solutions where space and weight constraints are critical. Additionally, their resistance to demagnetization under load ensures stable operation even during peak electrical demand cycles.
