Customized Sintered Magnet
High frequency SMC inorganic coated soft magnetic material
| No. |
Model |
Iron loss < |
Magnetic flux density |
| 1T |
1.5T |
5000M/A |
| 1 |
H1.3W300 |
2.9 |
|
1.31 |
| 2 |
H1.1W500 |
4.8 |
|
1.13 |
Low frequency inorganic insulation layer iron silicon soft magnet
| NO. |
Model |
Iron loss < |
Magnetic flux density |
| 1T |
1.5T |
5000M/A |
| 1 |
L1.7W400 |
1.2 |
3.8 |
1.75 |
| 2 |
L1.6W600 |
1.8 |
5.9 |
1.61 |
Sintered magnets, particularly sintered neodymium magnets (NdFeB), offer a range of advantages that make them ideal for various applications in industries such as automotive, electronics, and renewable energy. Here are the key advantages:
1. High Magnetic Strength
- Sintered magnets, especially sintered neodymium magnets, have an exceptionally high magnetic strength. This allows them to produce strong magnetic fields, making them ideal for applications where maximum magnetic force is required in a compact size.
2. Excellent Temperature Stability
- Sintered magnets exhibit good thermal stability, meaning they can maintain their magnetic properties over a wide range of temperatures. This makes them suitable for use in environments with varying temperatures, such as in automotive and aerospace applications.
3. Customizable Shapes and Sizes
- The sintering process allows for the production of magnets in various shapes and sizes, tailored to specific applications. This flexibility is advantageous for designing magnets to fit complex components or systems.
4. High Coercivity
- Sintered magnets have high coercivity, meaning they can resist demagnetization under external magnetic fields. This property is crucial for maintaining the long-term stability of the magnet's magnetic performance.
5. Durability and Longevity
- Sintered magnets are known for their durability. They are resistant to corrosion and wear when properly coated, making them reliable for long-term use in harsh environments.
6. Cost-Effective Production
- The sintering process allows for mass production of magnets with consistent quality. This can be more cost-effective compared to other methods of magnet production, especially for large-scale manufacturing.
7. Versatility in Applications
- Sintered magnets are used in a wide variety of applications, from electric motors, sensors, and speakers to wind turbines and medical devices. Their versatility stems from their strong magnetic properties and the ability to be produced in different configurations.
8. Energy Efficiency
- Due to their strong magnetic fields, sintered magnets contribute to the efficiency of electrical systems, such as in electric motors and generators. This is particularly important in reducing energy consumption and improving the performance of renewable energy systems.
9. High Remanence
- Sintered magnets have high remanence, meaning they retain a large portion of their magnetization after the external magnetizing field is removed. This property is essential for applications where a strong, permanent magnetic field is required.
10. Environmental Benefits
- With advancements in recycling technologies, the environmental impact of sintered magnets can be minimized. Recycled sintered magnets are becoming an important source of raw materials, contributing to a more sustainable approach to magnet production.
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