MAGINDUCT AF2 Magnetic Shielding - Width 2 Feet | Length 1 Linear Feet

Name: MAGINDUCT AF2 Magnetic Shielding - Width 2 Feet | Length 1 Linear Feet
Brand: woremor
SKU: WM-2929
Price: 69.99 USD
Availability: InStock

by woremor

$ 69.99 - $ 69.99

$ 69.99

$ 69.99 - $ 69.99

$ 69.99

The MAGINDUCT AF2 Magnetic Shielding system sets new safety standards by offering unmatched protection against magnetic induction, radio frequency interference, and fire. Designed as a flexible metal material, it isolates low-frequency magnetic fields from transformers, high-voltage power lines, and electrical equipment. With superior corrosion and fire resistance, it maintains shielding integrity even in damp environments.

Key Features:

Enhanced Safety: Combines magnetic induction, fire, and RF shielding.
Flexible & Durable: Retains shielding properties even when bent or molded.
Corrosion-Resistant: Ensures longevity in challenging conditions.
Customizable Installation: Strips can be installed side by side or slightly overlapped for seamless magnetic continuity.

Quantity

Applications
Specs

The MAGINDUCT AF2 ideal for walls, floors, ceilings, cable shielding trays, Faraday cages, transformers, hospital diagnostic rooms, and more. Available in various thicknesses (1.3 mm to 3.8 mm), it suits a wide range of shielding needs.

Magnetic Field Mitigation / Shielding

Magnetic Field Mitigation (Frequency: 50 Hz, Field: 100 μT in contact with shield)

Layers	Polarization	Attenuation	Attenuation Ratio
One Layer	Vertical	88%	8.23
	Horizontal	89%	8.4
Two Layers	Vertical	97%	35.05
	Horizontal	97%	33.82

Handling: Store indoors in a dry place. Open packaging only during installation. Always wear protective gloves.
Cutting Instructions: Do not cut with sanders, disks, or methods that generate heat.

Contact us at +1 (855) 267-2582 for expert assistance in planning your magnetic shielding.

Unmatched Protection,

Unyielding Performance.

Enclosing the Source: Shielding Magnetic Fields at Their Origin

Effectively shielding magnetic fields at their source is a proven way to reduce electromagnetic interference and protect the surrounding environment. This method involves encasing the magnetic source with high-permeability materials such as MAGINDUCT AF2, specifically designed to redirect magnetic field lines and contain their influence. In household settings, this approach is commonly used to reduce or eliminate magnetic fields exposure from sources like electrical boxes, transformers, wiring, heated floors, and other domestic systems. In industrial environments, laboratories, and power facilities, this technique ensures magnetic fields remain confined, safeguarding nearby devices, sensitive instruments, and living spaces from interference. By focusing on the source itself, this proactive strategy enhances safety, reliability, and performance in environments where magnetic fields pose a potential challenge.

Shielding The Traget From Magnetic Fields

When the source of a magnetic field is beyond our control, such as high-power lines, a large transformer near our home, or an electrical room directly beneath our apartment, shielding the affected area—like our living space—becomes essential. This approach, known as destination shielding, offers a flexible and effective method to reduce magnetic interference. It ensures the safety and performance of devices, protects critical medical implants, maintains the accuracy of sensitive equipment, and fosters safer living environments. This targeted solution is a critical strategy for addressing modern electromagnetic challenges.

Expert assistance in planning your magnetic shielding.

If you're looking to effectively plan and execute magnetic shielding for your project, expert assistance is essential. Our team specializes in providing comprehensive support, from evaluating your specific requirements to designing customized shielding solutions tailored to your application. With in-depth knowledge of materials, field interference mitigation, and advanced shielding techniques, we ensure optimal performance and reliability for your systems. Whether you're working in electronics, medical equipment, aerospace, or any other industry, trust us to deliver precision-engineered magnetic shielding that meets your exact needs.

Call Us +1 (855) 267-2582

Frequently Asked Questions

How does magnetic shielding work?

Magnetic shielding operates by providing a path for magnetic field lines to bypass the protected area. When a high-permeability material surrounds the sensitive equipment, it attracts and guides the magnetic field lines around the shielded space, effectively reducing the magnetic field's impact within that area. This method doesn't block magnetic fields entirely but significantly diminishes their influence on the protected equipment.

What are the common magnetic fields sources to shield from

Magnetic fields come from various sources, including natural like the Earth’s magnetic field, solar activity, and lightning. Man-made sources include electrical power systems such as power lines, transformers, and household wiring. Many everyday devices and appliances, such as computers, mobile phones, refrigerators, microwaves, vacuum cleaners, and electric fans, also emit magnetic fields. Industrial equipment like generators, motors, induction furnaces, and MRI machines produce strong magnetic fields, as do transportation systems like electric trains, hybrid vehicles, and airplanes. Communication systems, including Wi-Fi routers, cell towers, and broadcast equipment, contribute low-level magnetic fields, while magnets, both permanent and electromagnetic, are common in devices like speakers and industrial machinery. Scientific and medical tools, such as particle accelerators, spectrometers, and therapeutic devices, further expand the range of magnetic field sources in various environments.

How To measure magnetic fields?

Gaussmeter is a specialized instrument used to measure the strength and direction of magnetic fields. These tools are widely used in industries and laboratories.

Units of Measurement

Magnetic fields are typically measured in the following units:

Tesla (T): SI unit, where 1 Tesla = 10,000 Gauss.
Gauss (G): Commonly used in practical applications (1 Gauss = 0.0001 Tesla).
Microtesla (µT): Often used for environmental and weaker fields.

Steps for Measurement

Select the appropriate tool based on the field strength and the environment.
Place the sensor or probe perpendicular to the magnetic field for the most accurate measurement.
Record the field strength and, if necessary, its direction.

When selecting a gauss meter for measuring magnetic fields, LATNEX offers a range of devices suitable for various applications. Here are some recommended models:

LATNEX MG-300 Gauss and Magnetic Field Meter
This device measures electromagnetic fields in the extremely low frequency (ELF) range of 30 to 300 Hz. It's ideal for assessing radiation intensity from power lines, appliances, and electrical wires. Features include a single-axis sensor, data hold function, and a large LCD screen for easy reading.

LATNEX MG-2000T Triple Axis Gauss and Magnetic Field Meter

This dovice is a professional-grade gauss meter designed to measure extremely low-frequency (ELF) magnetic fields ranging from 30 Hz to 2000 Hz. Equipped with triple-axis sensors (X, Y, Z), it provides accurate readings regardless of orientation, making it ideal for assessing

LATNEX MF-30K AC/DC Gaussmeter and Magnetic Field Indicator
Designed for both AC and DC magnetic field measurements, this gauss meter is suitable for industrial applications, including detecting residual magnetism during manufacturing processes. It offers auto-ranging, peak hold, real-time zero functions, and a USB interface for data logging and PC connectivity.nces, and electrical wires. Features include a single-axis sensor, data hold function, and a large LCD screen for easy reading.

Is magnetic shielding customizable for different applications?

Yes, magnetic shielding solutions can be tailored to meet the specific needs of various industries, including electronics, medical devices, aerospace, and research laboratories. Customization involves selecting appropriate materials, determining the necessary thickness, and designing configurations that provide optimal performance for the specific application. This ensures that the shielding effectively mitigates unwanted magnetic interference in each unique scenario.

Can magnetic shielding completely block magnetic fields

No, magnetic shielding cannot entirely block magnetic fields. Instead, it reduces and redirects them. The effectiveness of shielding depends on factors such as the material's permeability, the thickness of the shield, the strength of the magnetic field, and the design of the shielding enclosure. In many cases, multiple layers of shielding materials are used to achieve the desired level of attenuation.