Low price permanet magnet Isotropic ferrite magnets

Payment Type:T/T,Others

Incoterm:FOB,CFR,Express Delivery,DDU,CIF,EXW,CIP,DDP

Min. Order:1 Carton

Transportation:Ocean,Land,Air,Express,Others

Port:Guangzhou,Shenzhen,Ningbo

$50≥1Carton

Product Attributes
Supply Ability & Additional Information
Packaging & Delivery
Other information

Product Attributes

Model No.: 25*3

Brand: YB

Place Of Origin: China

Species: Permanent

Composition: Rare Earth Magnet, Ferrite Magnet, Neodymium Magnet, Plastic Magnet, Rubber Magnet, Alnico Magnet, Ndfeb Magnet

Shape: Ball, Pot / Cup Shape, Coil, Block, Sheet, Cup Shape, Strip, Stick, Bar

Application: Industrial Magnet

Tolerance: ±1%

Processing Service: Bending, Welding, Decoiling, Cutting, Punching, Moulding

Product Name: Isotropic ferrite magnet

Material Grade: Y10T

The Direction Of Magnetization: customized

Shape: round,square,ring

Supply Ability & Additional Information

Packaging: carton package and then packed in pallet

Productivity: 30000000 pcs per month

Transportation: Ocean,Land,Air,Express,Others

Place of Origin: China

Supply Ability: 30000000 pcs per month

Certificate: ISO9001

HS Code: 8505190090

Port: Guangzhou,Shenzhen,Ningbo

Payment Type: T/T,Others

Incoterm: FOB,CFR,Express Delivery,DDU,CIF,EXW,CIP,DDP

Packaging & Delivery

Selling Units:

Carton

Package Type:

carton package and then packed in pallet

Picture Example:

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Isotropic ferrite magnets

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The difference between ferrite magnet and Neodymium Magnet?

Ferrite magnets are made of iron oxide and ceramic materials, while neodymium magnets are made of a combination of neodymium, iron, and boron. Neodymium magnets are much stronger than ferrite magnets and have a higher magnetic energy density. They are also more expensive and can be brittle and prone to corrosion. Ferrite magnets are less expensive and have good resistance to corrosion, but they are not as strong as neodymium magnets.

As an AI language model, I don't have personal preferences. However, here are some tips for choosing a magnet:

1. Determine the purpose of the magnet: Magnets come in different shapes and sizes, and each type is designed for a specific application. For example, if you need a magnet for holding papers on a fridge, a small, flat, and lightweight magnet would suffice. However, if you need a magnet for industrial purposes, you may need a larger and more powerful magnet.

2. Consider the strength of the magnet: The strength of a magnet is measured in Gauss or Tesla. The higher the Gauss or Tesla rating, the stronger the magnet. If you need a magnet for a specific purpose, make sure you choose one with the appropriate strength.

3. Choose the right material: Magnets can be made from various materials, such as neodymium, ferrite, and alnico. Each material has its own unique properties, so choose the one that best suits your needs.

4. Consider the temperature: Some magnets lose their magnetic strength at high temperatures. If you need a magnet for high-temperature applications, choose one that is specifically designed for that purpose.

5. Consider the cost: Magnets come in different price ranges. Choose one that fits your budget while still meeting your needs

The process flow of Isotropic Ferrite Magnets& Anisotropic Ferrite Magnet

1. Raw materials: The process of making magnets begins with the raw materials. The most commonly used materials for making magnets are iron, nickel, cobalt, and their alloys.

2. Melting: The raw materials are melted in a furnace at a high temperature. The molten metal is then poured into a mold to form the desired shape.

3. Cooling: The molten metal is allowed to cool and solidify in the mold. The cooling process is carefully controlled to ensure that the metal solidifies in a uniform manner.

4. Annealing: After the metal has solidified, it is annealed to improve its magnetic properties. Annealing involves heating the metal to a high temperature and then slowly cooling it down.

5. Machining: The annealed metal is then machined to the desired shape and size. This process involves cutting, drilling, and grinding the metal to achieve the desired shape and surface finish.

6. Magnetization: The final step in the process is magnetization. The magnet is placed in a magnetic field and exposed to a strong magnetic field. This aligns the magnetic domains in the metal and creates a Permanent Magnet.

7. Quality control: Throughout the process, quality control checks are carried out to ensure that the final product meets the required specifications. These checks include measuring the magnetic properties of the magnet, checking the dimensions and surface finish, and testing the strength of the magnet.