Magnetic Assembly By Types

Our premium magnetic assemblies offer innovative solutions for a wide range of industries. Discover the perfect combination of high-quality materials, expert engineering, and tailor-made designs to unlock the true potential of magnets for your project.

Pot Magnet

Compact and versatile pot magnets are perfect for holding, lifting, and mounting applications.

Channel Magnet

The design combines a strong permanent magnet, typically neodymium or ferrite, with a steel channel or housing.

Magnetic Bar

A permanent magnet encased in stainless steel for magnetic separation and filtration processes.

Magnetic Grid

A magnetic grid is a magnetic assembly consisting of an arrangement of magnetic bars.

Magnetic Plate

Magnetic plates efficiently capture and remove ferrous contaminants from bulk materials.

Magnetic Shuttering

Strong permanent magnets to securely hold concrete formwork in place during the casting process.

Fishing Magnet

Encased in a durable housing with an attached eyelet or hook, designed for magnetic fishing

Magnetic Recess Former

To create accurate, consistent recesses or voids within concrete structures.

Permanent Chuck

Experience the power of compact and versatile pot magnets, perfect for holding, lifting, and mounting applications.

Magnetic Couplings

Non-contact mechanical devices that transmit torque between two rotating components using magnetic force

Magnetic Lifter

A device that uses strong permanent magnets or electromagnets to securely lift, hold, and transport heavy ferrous metal objects.

What Are Magnetic Assemblies

Magnetic Assemblies

Magnetic assemblies are components or systems that incorporate permanent magnets and other materials, such as metal, plastic, or rubber, to create a specific function or application.

These assemblies are designed to provide magnetic force or to manipulate magnetic fields in various ways, depending on the intended use.

Advantages of Magnetic Assemblies?

Customizable Magnetic Force

Magnetic assemblies can be tailored to provide a specific force or field pattern by using different types of magnets, materials, and configurations.

Resistance to Environmental Factors

Depending on the materials used, magnetic assemblies can often withstand harsh environments, including high temperatures, corrosive substances, or extreme pressures.


Permanent magnets used in magnetic assemblies typically have a long life, maintaining their magnetic properties for years or even decades, depending on the material and environmental conditions.

Energy Efficiency

Some magnetic assemblies, such as magnetic couplings, can transmit motion or force with minimal energy loss, making them more efficient than mechanical alternatives.

Diverse Applications of Magnetic Assemblies

The diverse applications demonstrate the versatility and adaptability of magnetic assemblies across multiple industries, enabling efficient and innovative solutions to various challenges.


Transformers, inductors, and magnetic shielding components.


Electric motors, sensors, and magnetic couplings.

Consumer Goods

Refrigerator door seals, toys, electronic devices, and magnetic fasteners.


(MRI) machines, surgical instruments, and magnetic therapy devices.

Environment & Waste

Magnetic separators for recycling and waste processing plants

Industrial Automation

Robotics, conveyor systems, and pick-and-place machines.

Security & Safety

Magnetic door locks, alarm systems, and access control devices.

Oil & Gas Industry

Downhole drilling, flow control, and magnetic separation.


Position sensing, actuation, and torque transmission

Factors Dertermine the Strength of Magnetic Assemblies

The strength of magnetic assemblies is an essential factor to consider when designing or selecting them for specific applications. Several factors determine the strength of a magnetic assembly. Careful consideration of these factors is crucial in designing or selecting a magnetic assembly that meets the specific requirements of the intended application.

#1: Type of Magnets

Common permanent magnet materials include neodymium (NdFeB), samarium-cobalt (SmCo), alnico, and ferrite. Neodymium magnets are the strongest, followed by samarium-cobalt, alnico, and ferrite magnets.

The strength of a magnet is measured in terms of its maximum energy product (BHmax), which is expressed in Mega-Gauss-Oersteds (MGOe).

#2: Assembly Configuration

The arrangement of magnets within the assembly can significantly impact the overall strength. For example, magnets can be configured to work together to increase the magnetic field’s strength or focus the field in a specific area.

Proper configuration can enhance the magnetic field and ensure it is concentrated where needed most.

#3: Materials and Coatings

The materials surrounding the magnets can also affect the strength of the magnetic assembly. For example, ferromagnetic materials can create a magnetic circuit, directing the magnetic field and enhancing its strength.

In addition, the magnet’s coating or plating can influence the assembly’s performance, protecting the magnet from corrosion and ensuring its long-term effectiveness.

#4: Size, Shape,Temperature

Larger magnets generally produce a stronger magnetic field, but the shape and orientation of the magnets can also play a crucial role in the overall magnetic field strength.

Some magnet materials lose their magnetism at high temperatures, while others can maintain their strength even in extreme conditions.

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