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In modern technology, the design and arrangement of magnetic circuits are crucial to the performance of devices. The application scenarios are diverse and complex, making it challenging to meet the usage requirements with a single magnet. Additionally, when rare earth prices are high, the volume and amount of magnets significantly impact product costs. Therefore, by modifying the magnetic circuit structure to meet different usage scenarios, we can reduce the amount of magnet used, thereby lowering costs.

Common magnetic circuits include the Halbach Array, multipole magnetic circuit, addition of magnetic materials, flux concentrator, flexible drive, and single-sided magnet. Let’s introduce these one by one:

1. Halbach Array

The Halbach Array is a special arrangement of magnets designed to produce the strongest magnetic field with the least amount of magnet material. This arrangement maximizes magnetic field utilization efficiency and minimizes magnetic field leakage. Optimized Halbach ring designs can achieve up to 100% shielding in non-working areas. As shown, conventional magnetic circuits have symmetrical divergent magnetic field lines, whereas Halbach arrays concentrate most of the magnetic field lines in the working area, thus enhancing magnetic attraction.

Application Examples:

·Maglev Trains: Halbach arrays are used in maglev systems between tracks and trains, providing strong levitation and propulsion forces.

·MRI Equipment: Used in medical imaging to form a high-intensity and uniform magnetic field.

2. Multipole Magnetic Circuit

Multipole magnetic circuits consist of multiple alternating magnetic poles. This can create strong magnetic fields in relatively small spaces, making them suitable for devices requiring high magnetic field strength and precision.

Compared to ordinary monopole magnets, multipole magnetic circuits have more concentrated magnetic field lines, especially as the number of poles increases. There are two types of multipole magnetic circuits: one where a single magnet is multi-pole magnetized, and another where multiple monopole magnets are adsorbed. The main difference lies in cost, with similar functionality. Multipole magnetic circuits are particularly advantageous for short-distance attraction.

Application Examples:

·Stepper Motors: Achieve precise angle control and efficient drive through multipole magnetic circuits.

·Linear Motors: Provide smooth and efficient linear motion.

3. Addition of Magnetic Materials

By adding high permeability materials (such as soft ferrite or silicon steel sheets) to the magnetic circuit, magnetic flux pathways can be effectively guided and enhanced, increasing the strength and uniformity of the magnetic field.

Application Examples:

·Transformers: Use high permeability materials in the core to improve electromagnetic conversion efficiency.

·Motors: Enhance magnetic coupling between the rotor and stator, improving motor performance.

4. Flux Concentrator

Flux concentrator structures use specifically shaped and arranged magnetic materials to concentrate magnetic flux in a particular area, significantly increasing local magnetic field strength. Flux concentrators can be flexibly designed according to the air gap size to achieve optimal results, effectively saving magnets, and distributing the magnetic field uniformly along the yoke. However, they have higher assembly costs.

Application Examples:

·Magnetic Sensors: Improve sensor sensitivity and precision.

·Nondestructive Testing Equipment: Provide high-intensity local magnetic fields for detecting material defects.

5. Flexible Drive

Flexible drive magnetic circuits utilize the flexibility and bendability of magnetic materials to achieve non-contact transmission. This transmission method is efficient, frictionless, and low-noise.

Application Examples:

·Robot Joints: Provide flexible and precise motion control.

·Automated Conveyor Belts: Non-contact transmission reduces wear and maintenance needs.

6. Single-Sided Magnet

Single-sided magnet arrangements focus magnetic flux on one side of the magnet, creating an area with almost no magnetic field on the other side. This arrangement reduces magnetic field leakage and enhances efficiency.

Application Examples:

·Magnetic Clamps: Generate magnetic force only in the required areas during manufacturing and assembly processes.

·Magnetic Whiteboards: Provide magnetic force on one side for attaching magnetic accessories conveniently.

These magnetic circuit arrangements each have their unique characteristics and application scenarios, playing a crucial role in modern technology and industry. By choosing and designing magnetic circuit arrangements appropriately, we can significantly enhance device performance and efficiency. Newland Magnetics has rich experience and expertise in magnetic materials and magnetic circuit design, dedicated to providing high-quality magnetic solutions to meet various complex application needs.

In practical applications, different magnetic circuit arrangements are optimized according to specific requirements and technical demands to achieve the best performance. This not only improves the efficiency of devices but also drives the development of related industries. Newland Magnetics will continue to innovate and research, providing customers with the most advanced magnetic solutions.

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