Sintered NdFeB Magnets Archives

Magnetic Shielding Materials: Types, Applications, and Selection Criteria

by potmagnetson 7 February 2026in Flexible Magnet, Magnetic Materials, Magnetic Strip, Magnets Kownledge No comment

Magnetic Shielding Materials: Types, Applications, and Selection Criteria

Magnetic fields exert an invisibly powerful force that profoundly impacts modern electronics. Although essential in many fields-power generation and electric motors are examples-magnetic interference can cause irreparable harm in certain fields, such as healthcare, aircraft travel, and communication services.

Scientists and engineers employ magnetic shielding materials to combat this, specifically to reroute or reduce magnetic fields. Such components protect equipment, guarantee security, and increase functionality. Addressing industry difficulties requiring high accuracy and minimal disturbance requires understanding and commitment to the proper shielding material.

Magnetic shielding has several uses outside of research labs. In our technologically advanced world, shielding materials are used in everything from industrial machinery to consumer gadgets. For experts and enthusiasts, this guide will thoroughly explain the principles of magnetic shielding, the materials utilized, and their applications.

neodymium magnet

What is Magnetic Shielding?
Magnetic shielding redirects and weakens magnetic fields to safeguard delicate devices. High magnetic permeability materials are used because they minimize interference by drawing in and rerouting magnetic field lines. Shielding, however, confines or reroutes magnetic fields rather than eliminating them.

Why is Magnetic Shielding Necessary?
Magnetic shielding is essential because it can:

Guard delicate equipment against outside magnetic fields that could skew signals or harm parts.

Boost efficiency in high-precision applications such as navigation systems or medical imaging.

Basics of Shielding Effectiveness
The kind of material, its thickness, and the shielding enclosure’s shape are crucial elements that affect how efficient magnetic shielding is. Mu-metal and other materials with high magnetic permeability are very good at rerouting magnetic fields. However, the frequency and intensity of the field can affect how well they perform.

Another important factor is the shielding’s location and form. Compared to flat or angular geometries, rounded or seamless enclosures are superior at preventing magnetic field leakage. Furthermore, the shielding material’s resistance to greater magnetic fields is determined by its thickness. When the material can no longer efficiently reroute more field lines, saturation is more challenging to achieve with thicker materials.

Misconception: Magnetic shielding does not eradicate magnetic fields – instead, it attenuates or redirects them, thus decreasing their effect on sensitive regions. Recognizing this distinction will enable reasonable expectations when selecting or creating shielding solutions.

Basics of Shielding Effectiveness

Types of Magnetic Shielding Materials
Magnetic shielding materials are essential for managing magnetic interference in sensitive environments, providing crucial protection from harmful magnetic interference. Materials chosen based on their ability to redirect magnetic fields based on their magnetic permeability, saturation point, and environmental stability properties should be carefully considered as they could make all the difference in smooth operation versus costly disruptions. Understanding available materials helps tailor shielding solutions specifically tailored to particular applications.

Standard Materials for Magnetic Shielding
Mu-Metal
Mu-metal, or nickel-iron alloy with very high magnetic permeability, is widely recognized as one of the most efficient shielding materials, often employed in MRI machines, scientific instruments, and other precision applications requiring magnetic shielding. However, mechanical stress may reduce its efficacy over time.

Ferrites

Ferrites are ceramic-based materials with low electrical conductivity, perfect for electromagnetic interference (EMI) control at higher frequencies. They are popular in electronics like Wi-Fi routers and smartphones.

Permalloy

Another nickel-iron alloy, Permalloy, is frequently utilized for electromagnetic compatibility applications in transformers, telecom systems, and magnetic sensors due to its balance of cost-efficiency and performance – making it one of the preferred choices among industrial users.

Advanced and Emerging Materials
Amumetal and Specialty Alloys

Amumetal alloys have been developed for applications requiring high field strengths. These materials offer outstanding performance in industries like aerospace and defense.

Nanomaterials and Composites

Emerging technologies have revealed lightweight yet highly efficient nanomaterials and composites; these materials are well suited to automotive and portable electronics products where weight and efficiency are of primary concern.

neodymium magnet

Comparative Analysis of Materials
Material

Magnetic Permeability

Applications

Cost

Mu-Metal

Very High

Medical imaging, scientific tools

High

Ferrites

Moderate

Electronics, high-frequency devices

Moderate

Permalloy

High

Transformers, communication systems

Moderate

Low Carbon Steel

Low

Industrial machinery

Low

Nanomaterials

Varies (High Potential)

Aerospace, advanced electronics

High (Emerging)

Real-World Applications
From enhancing the functionality of common consumer electronics to safeguarding medical devices, magnetic shielding materials are indispensable in a wide range of sectors and applications. Their numerous applications show how diverse and essential they are to contemporary technology.

Communication and Electronics
Magnetic shielding protects sensitive parts like transformers, microchips, and sensors from electromagnetic interference, which extends their lifespan and reliability while preventing damage to consumer electronics like tablets, laptops, and smartphones.

Shielding ensures signal integrity by preventing interruptions to internet connections and mobile networks.

Healthcare Applications
Magnetic shielding is necessary for medical diagnostic equipment to be accurate and effective. For example, magnetic resonance imaging devices use powerful magnetic fields that must be free from external interference to provide clear imaging images. Shielding prevents the powerful electromagnetic fields these machines produce from affecting adjacent equipment.

Aerospace and Automotive Industries
Shielded navigation systems and communication devices are essential for space applications because they insulate them from external magnetic fields that could impair accuracy. In autonomous cars, where sophisticated sensors and computers must function continuously, shielding is especially essential.

Electric vehicle (EV) manufacturers use shielded battery management systems to lower electromagnetic interference and improve safety and efficiency.

Industrial and Defense Applications.
Heavy equipment and power systems are shielded from magnetic interference to guarantee continuous functioning in industrial environments. At the same time, shielding is crucial for military applications that protect radar equipment, electromagnetic warfare systems, and communications.

Specialty alloys and other high-performing solutions are crucial for shielding materials since they must endure severe environments.

Designing Magnetic Shielding Solutions
Effective magnetic shielding solutions necessitate a well-informed, strategic approach that considers material qualities, enclosure geometry, and application specificities to maximize shielding efficiency while reducing costs and material usage. Properly designed shields can lower material consumption costs and significantly increase shielding efficiency.

Effective magnetic shielding solutions necessitate a well-informed, strategic approach that takes into account material qualities, enclosure geometry, and application specificities to maximize shielding efficiency while reducing costs and material usage. Properly designed shields can lower material consumption costs and significantly increase shielding efficiency.

Geometry and Material Placement
The shape and location of shielding materials are crucial. Enclosures with seamless shapes or rounded corners offer superior control over magnetic field leakage and more efficient field line redirection. Additionally, it is essential to carefully position shielding close to locations susceptible to interference, such as CPUs and sensors on electrical devices.

Layering and Hybrid Solutions
Layering multiple materials enhances shielding effectiveness by targeting different frequencies and field strengths. For instance, layering mu-metal for low-frequency shielding with ferrites for high-frequency interference protection provides comprehensive coverage. Hybrid solutions may prove especially valuable where one material cannot meet all performance criteria. Layering allows designers to balance cost with efficiency by including less costly materials in less critical areas of design.

Testing and Optimization
For optimal shielding design performance, thorough testing is an absolute necessity. Devices like magnetic flux sensors and simulation software accurately evaluate shielding effectiveness under real-world conditions. Such tests help identify weak points in your design so adjustments may be made to enhance it. This might involve increasing material thicknesses or changing enclosure shapes. Optimizing may involve tweaking material thickness or combinations based on what works.

Challenges and Limitations
Magnetic shielding plays an essential role, yet implementation poses numerous difficulties for engineers and designers. They must negotiate material limitations, environmental concerns, and cost considerations while developing effective solutions. Acknowledging these hurdles is the key to making informed decisions and devising efficient shielding strategies.

Material Saturation and Limits
Magnetic shielding materials often reach their magnetic capacity when shielding environments with strong magnetic fields. They can no longer redirect additional magnetic field lines effectively, significantly diminishing their shielding effectiveness and ultimately impacting performance. When this happens, shielding performance drops dramatically, reducing performance in such environments as hospitals.

Mu-metal and similar high-performance materials were originally intended to handle moderate environments; however, extreme conditions may necessitate additional materials or solutions.

Environmental Factors
To remain effective shields for heavy-duty applications, shielding materials must meet various environmental challenges such as corrosion, temperature variations, and mechanical strain. Low-carbon steel tends to rust easily in humid environments, while materials like ferrites may resist wear better but lack the strength required by heavy-duty applications.

Selecting an optimal material requires striking a balance between performance and environmental requirements for an application.

Cost/Benefit Considerations
Mu-metal and advanced composite shielding materials may be costly solutions for large-scale shielding needs, and industries with tight budget constraints may opt for less effective but cheaper materials, like low-carbon steel.

Balance cost with shielding performance often requires creative design strategies, like layering or hybrid solutions, to optimize efficiency while keeping expenses within reasonable bounds.

Future of Magnetic Shielding Materials
Magnetic shielding technology continues to advance with advancements in materials and technologies driving innovation. Industries require increasingly efficient, lightweight, and eco-friendly solutions; researchers are exploring cutting-edge approaches to meet this demand; ultimately, the future of magnetic shielding lies within its ability to push performance, adaptability, and environmental responsibility boundaries further than ever.

Nanotechnology and New Alloys
Nanotechnology has opened up exciting prospects for ultrathin and lightweight shielding materials. Through molecular manipulation of materials, researchers can engineer nanostructures with superior magnetic permeability and efficiency that offer unparalleled magnetic shielding properties for applications within aerospace where weight reduction is critical. These materials are also handy during combat missions where weight reduction becomes vital.

New alloys are designed to withstand higher magnetic field strengths without becoming saturated, creating a more reliable performance in challenging environments like defense and industrial settings.

Integration with AI and Automation systems
Artificial Intelligence (AI) and automation have revolutionized the design and testing of magnetic shielding solutions. AI algorithms can simulate complex magnetic field interactions to optimize material placement while shortening prototyping timeframes; furthermore, automation ensures precision manufacturing that ensures consistent quality shielding materials.

These advances improve performance while decreasing production costs, making advanced shielding accessible across multiple industries.

Eco-Friendly Solutions
As environmental sustainability continues to become an international goal, researchers are considering designing eco-friendly shielding materials and manufacturing practices to minimize their environmental footprint without compromising performance. Such initiatives include biodegradable composites and decreasing dependence on rare-earth metals that require expensive mining processes for extraction. Manufacturing practices that follow sustainable principles aim to decrease impact without impactful performance loss from shielding solutions.

Summing It Up
From consumer electronics to aerospace systems, magnetic shielding materials are essential for safeguarding fragile machinery and facilitating the smooth operation of modern-day technology. Engineers, designers, and decision-makers must understand their characteristics, difficulties, and innovations.

Innovations like nanotechnology and environmentally friendly materials are transforming magnetic shielding systems in response to the growing demand for effective and sustainable shielding solutions. By using these advancements, industries may overcome present challenges and prepare for an increasingly technologically advanced future.

Purchasing magnetic shielding materials will guarantee the smooth operation of critical functions, increase dependability, and open the door for revolutionary developments. The first step to success and assurance is knowing your shielding needs, whether for industrial machinery designs, medical equipment, or automotive systems.

Bonded NdFeB Magnets and Assemblies

Sintered NdFeB Magnets and Assemblies

Pickup magnet

Strong NdFeB Magnetic Lifter PML3000A

Powerful Magnetic Lifter PML2000A

New Product 13000Gs Magnetic Rods!

Sintered NdFeB Magnetic Mounting Hook Ø48 mm

Sintered NdFeB Hook Magnet Ø38 mm

Clamping Hook Magnet Ø50 mm

Magnetic Shielding Design for Manufacturing

by potmagnetson 3 February 2026in Flexible Magnet, Magnetic Materials, Magnetic Strip, Magnets Kownledge No comment

Magnetic Shielding Design for Manufacturing

Magnetic shielding for static and low frequency (<100 kHz), time-varying magnetic fields is accomplished by containing a specific device or item within a sheet metal enclosure of high permeability material. Typically, a sensitive electronic component requires magnetic shielding protection from nearby transformers or power supplies radiating a potentially troublesome magnetic field. High permeability material is a nickel iron alloy consisting of 50 to 80 percent nickel. Initial static permeability values are in excess of 60,000. Permeability is defined as a ratio of the flux induced in a material (expressed as B, measured in Gauss) proportional to the ambient or applied magnetic field (expressed as H, measured in Oersted). As a reference, the initial permeability of a material is defined as the ratio of the induced flux B in the material divided by the ambient Earth’s magnetic field, H (approximately .50 Oersted). The high ratio indicates the material’s ability to induct magnetic flux. The simple B-H Graph shown in Figure 1 is used to determine a material’s permeability and resultant magnetic shielding performance. The orange line on the B-H Graph represents the function of high permeability material at DC and 60 Hz. The permeability value is equal to the derivative of that function. Note that as the applied field increases beyond the steepest slope, the permeability starts to decrease. This change is known as the saturation point of the material. Once the material becomes fully saturated, it offers no magnetic shielding protection as the derivative asymptotically approaches zero.

Magnetic Shielding Design for Manufacturing

Figure 1. B–H graph used to determine a material’s permeability.
.
In most shielding applications, the specified shielding alloy is between .004″ and .120″ thick sheet metal. Thicker materials can be milled from bar stock. High permeability magnetic shielding alloys are produced by several steel mills worldwide.

FABRICATION

The typical magnetic shield design requires sheet metal fabricating and metal forming techniques. Shielding shapes include simple sheet metal cylinders, complex weldments, and precision machined housings. But in almost all cases an application involves an enclosure type design. Since magnetic flux will follow the path of least reluctance, the high permeability of the enclosure shape absorbs and shunts the magnetic flux, leaving the inside of the enclosure with a lower or attenuated magnetic field. The shield enclosure can also work the other way by containing a magnetic field within the enclosure boundary.

Once a shield enclosure is designed for shielding effectiveness, a mechanical design application is needed. A simple cylindrical shape is often the most effective shield and the simplest to fabricate. Sheet metal is rolled, and a seam can be butt welded or can be overlapped and spot welded. The mechanical forming constraints of high permeability alloys are very similar to those of stainless steel.

Figure 3. Fusion welded seams are TIG (Tungsten Inert Gas) welded.

Other typical shapes are similar to electronic chassis where a prefabricated flat panel is formed using a conventional sheet metal press brake and associated forming equipment. Complex assemblies can be fusion welded (Figure 2) or spot welded or can be attached with mechanical fasteners.

CYLINDERS

Figure 2. High permeability alloys laser machine readily.

The simplest and most effective shape for a magnetic shield is a sheet metal cylinder made of a high permeability material. A machine known as a slip roll or pinch roll is employed. The material is pinched between two rollers. Motion is applied and the material is then pushed against the forming roll. The resultant diameter of the finished cylinder is determined by the position of the forming roll relative to the pinching rolls. After the cylinder is roll formed to shape, the seam can be overlapped and spot welded or butted and fusion welded.

Figure 4. Typical shapes for magnetic shields are cylinders, cans. and rectangular enclosures. The covers for the cylinders were spun to shape.

A spot weld is a simple electrical resistance weld, and a butt, fusion weld is usually accomplished via a process known as TIG (Tungsten, Inert Gas) welding. The inert gas used is argon, and it serves to prevent oxidation and carburization of the material for the brief time it is in a molten state. Laser and electron beam welding can also be used (Figure 3). High permeability alloys weld quite well, and demanding mechanical tolerances can be achieved with proper weld fixturing.

Figure 5. A small cover is spun to shape.
Figure 5. A small cover is spun to shape.
SHAPES

Boxes and chassis shapes are achieved using a pre-cut blank and a typical press brake. Usually a part is developed in a flat pattern layout, which can then be laser machined or punched in a CNC punch press. Subsequent forming operations are done in a press brake. Corners and seams can be left open or can be welded shut depending on the application. In high volume applications, tooling can be designed that will pre-cut and form the blank in a single operation.

Figure 6. Examples of spun parts.

METAL SPINNING & HYDROFORMING

When stringent mechanical tolerances are required, metal spinning and hydroforming can be utilized. Metal spinning, as the name implies, involves rotating the material in a lathe and using a forming role to flow the metal against a mandrel. See examples in Figures 4, 5, and 6. The mandrel is a machined tool made to conform to the inside profile of the desired finished sheet metal part. The forming roll is usually controlled by an operator (spinner). Spinning metal requires a great deal of experience. If forced too far, the metal will crease or tear because of work hardening. Often the metal will require in-process annealing to relieve mechanical stress, and additional spinning can then occur. Of course, spinning can only be used on parts that are round or conical. The advantage of spinning is low tooling costs as mandrels are often made from wood or aluminum.

Hydroforming involves a simple tool machined to the inside dimensions of the part and a hydroform machine. The hydroform pushes the tool into a rubber diaphragm behind which hydraulic pressure forces the sheet metal to wrap around the tool. In addition to round parts, many unique shapes can be made by hydroforming. Hydroform tools are made from tool steels and other materials such as kirksite, a zinc alloy that can be cast into unique shapes (Figure 7).

Figure 7. The hydro-forming process.

Hydoformed and spun parts usually require a final trimming operation to remove excess material and/or to add detail. Most trimming operations can be accomplished on laser, milling, or shell trimming machinery.

HEAT TREATING

Figure 8. The large grain size is evident after heat treating.

The final step in manufacturing magnetic shielding parts is heat treating. Cold working and machining will have rendered the grain structure of the material in a less than ideal shielding condition. High permeability material is best heat treated in a dry hydrogen atmosphere, or vacuum furnace. Hydrogen is preferred as hydrogen gas will help remove any carbon or oxygen impurities. The material is brought up to 2100 degrees F and held for two to four hours. The furnace is then cooled at a specific rate to optimize grain growth and reordering. A large, well ordered grain will yield maximum permeability resulting in optimum shielding (Figure 8).

CONCLUSION

Magnetic shielding characteristics are optimized if welding can be avoided. The shield designer should strive to minimize welded sections and to allow generous forming radii. Magnetic flux leakage will occur at sharp corners effecting overall shield performance. The most efficient magnetic shield geometry would be a spherical shell. Since spherical shells are difficult and costly to form, the next best design is a simple cylinder. Rectangular boxes and chassis, although not optimal, will perform adequately as magnetic shields. The design engineer has a degree of flexibility when optimizing a design. Unlike RFI shields where holes and apertures are discouraged, magnetic shields can have holes and openings although it’s best to minimize their number. In recent years, FEA (finite element analysis) modeling of magnetic shield designs has recently become very helpful and has aided in the design process described here. Since the proof is in the prototype and since so many extenuating circumstances can affect shield performance, it’s best to try one on for form, fit, and function first.
Bonded NdFeB Magnets and Assemblies

Sintered NdFeB Magnets and Assemblies

Pickup magnet

Strong NdFeB Magnetic Lifter PML3000A

Powerful Magnetic Lifter PML2000A

New Product 13000Gs Magnetic Rods!

Sintered NdFeB Magnetic Mounting Hook Ø48 mm

Sintered NdFeB Hook Magnet Ø38 mm

Clamping Hook Magnet Ø50 mm

Magnetic Shielding Sheets

by potmagnetson 24 January 2026in Flexible Magnet, Magnetic Materials, Magnetic Strip, Magnets Kownledge No comment

Magnetic Shielding Sheets

magnetic shielding sheets are classified as amorphous shielding sheets and nanocrystalline shielding sheets according to different kinds of soft magnetic materials. magnetic shielding sheets made of single-layer or multi-layer high-quality amorphous or nanocrystalline ribbon offer high permeability and low core losses. It can effectively reduce the EMI of magnetic field to the surroundings. It is widely used in aerospace, automotive, communications and other electronic equipment as EMI resistance, electromagnetic screen and wireless charging.

Features
Compared with ferrite shielding material, Magnetic shielding sheets are featured with thin thickness, excellent flexibility, easy processing and wide working frequency range, which apply to the magnetic shielding of various electronic products. For wireless charging application, the Magnetic shielding sheet performs well in high power wireless charging with its arbitrarily adjustable permeability and excellent anti-saturation current.

Typical Applications
Magnetic shielding sheets are mainly used for EMI resistance, electromagnetic screens, NFC and wireless charging of various electronic products.

Technical Specifications

Part No.	Product Description	Total Thickness (μm)	Alloy Thickness (μm)	Adhesive Thickness (μm)	Available Dimensions
					Sheet^①	Roll^②
					*LW(mmmm)*	Width (mm)	Length (m)
MDWA045025	1 Layer Amorphous	45±4	25	5	√	55/60/65	≤400
MDWA070050	2 Layer Amorphous	70±7	50	3	√	55/60/65	≤200
MDWA100080	3 Layer Amorphous	100±10	80	3	√	55/60/65	≤200
MDWA125105	4 Layer Amorphous	125±12	105	3	√	55/60/65	≤100
MDWA155135	5 Layer Amorphous	155±15	135	3	√	55/60/65	≤100
MDWA180160	6 Layer Amorphous	180±18	160	3	√	55/60/65	≤100
MDWA210190	7 Layer Amorphous	210±20	190	3	√	55/60/65	/
MDWA235215	8 Layer Amorphous	235±23	215	3	√	55/60/65	/
MDWA265245	9 Layer Amorphous	265±26	245	3	√	55/60/65	/
MDWA290270	10 Layer Amorphous	290±29	270	3	√	55/60/65	/
MDWN040020	1 Layer Nanocrystalline	40±4	20	3	√	55/60/65	≤400
MDWN060045	2 Layer Nanocrystalline	60±6	45	3	√	55/60/65	≤200
MDWN090070	3 Layer Nanocrystalline	90±8	70	3	√	55/60/65	≤200
MDWN110090	4 Layer Nanocrystalline	110±10	90	3	√	55/60/65	≤100
MDWN135120	5 Layer Nanocrystalline	135±13	120	3	√	55/60/65	≤100
MDWN160140	6 Layer Nanocrystalline	160±16	140	3	√	55/60/65	≤100
MDWN185165	7 Layer Nanocrystalline	185±18	165	3	√	55/60/65	/
MDWN210190	8 Layer Nanocrystalline	210±21	190	3	√	55/60/65	/
MDWN235215	9 Layer Nanocrystalline	235±23	215	3	√	55/60/65	/
MDWN260240	10 Layer Nanocrystalline	260±25	240	3	√	55/60/65	/
Note: ①-Sheet: Customized, depending on drawings
②-Roll: Other width can be customized.

Bonded NdFeB Magnets and Assemblies

Sintered NdFeB Magnets and Assemblies

Pickup magnet

Strong NdFeB Magnetic Lifter PML3000A

Powerful Magnetic Lifter PML2000A

New Product 13000Gs Magnetic Rods!

Sintered NdFeB Magnetic Mounting Hook Ø48 mm

Sintered NdFeB Hook Magnet Ø38 mm

Clamping Hook Magnet Ø50 mm

Sintered NdFeB Magnets and Assemblies

by potmagnetson 2 January 2026in Magnetic Materials, Magnets Kownledge, NdFeB, Neodymium Magnets, Sintered Magnets No comment

Sintered NdFeB Magnets and Assemblies

NdFeB permanent magnet has extremely high properties (high residual induction, coercive force and energy product) with really competitive price. It can be machined into all kinds of shapes easily and used in many fundamental fields directly, such as new energy, vehicles, electron & electroacoustic, energy saving household appliances, industrial motor, instrument & apparatus, nuclear magnetic resonance, magnetic suspension field and so on. Magnets are also suitable for the high property, mini-size and lighted products.

Features
HSMAG is a magnetic material supplier with R&D, production and sales ability. We are providing top level magnets with customized coatings, weights and shapes. We also provide the design program, great service and technical support during all life cycle.

HSMAG has great power in R&D and holds Hitachi license. We have two production bases in NINGBO and HANGZHOU producing high grade magnets. The total capacity reaches 6000t. For the past several year, we supplied top level products and service to the customers including the world top 500 enterprises.

Sintered NdFeB Magnets and Assemblies

Typical Applications
Typical applications are as below:

• vehicle

EPS motor/drive motor/electricity generator/pump/sensors

• electronics

mobile/digital camera/hard disk drive/CD drive

• automation

servo motor/elevator motor/liner motor/electric tools

• energy

wind power

• environment

inverter air-conditioner/refrigerator/washing machine

• medical technology

nuclear magnetic resonance/CT scanner/ventilator

• aerospace & ship

ship powertrain

• railway

electricity powertrain

Technical Specifications

Materials Grade Chart
Grade	Br		Hcb / ≥		Hcj / ≥		(BH)max
	T	KGs	kA/m	kOe	kA/m	kOe	kJ/m³	MGOe
N42	1.28~1.34	12.8~13.4	876	11.0	955	12	318~342	40~43
N45	1.32~1.38	13.2~13.8	876	11.0	955	12	342~366	43~46
N48	1.36~1.43	13.6~14.3	836	10.5	955	12	358~390	45~49
N50	1.39~1.46	13.9~14.6	836	10.5	955	12	374~406	47~51
N52	1.42~1.48	14.2~14.8	836	10.5	955	12	390~422	49~53
N54	1.44~1.51	14.4~15.1	836	10.5	955	12	398~438	50~55
N56	1.46~1.53	14.6~15.3	836	10.5	955	12	414~454	52~57
N42M	1.28~1.34	12.8~13.4	938	11.8	1114	14	318~342	40~43
N45M	1.32~1.38	13.2~13.8	976	12.2	1114	14	342~366	43~46
N48M	1.36~1.43	13.6~14.3	1012	12.7	1114	14	358~390	45~49
N50M	1.39~1.46	13.9~14.6	1035	13.0	1114	14	374~406	47~51
N52M	1.42~1.48	14.2~14.9	1042	13.1	1114	14	382~422	48~53
N40H	1.25~1.31	12.5~13.1	912	11.5	1353	17	302~326	38~41
N42H	1.28~1.34	12.8~13.4	938	11.8	1353	17	318~342	40~43
N45H	1.32~1.38	13.2~13.8	976	12.2	1353	17	342~366	43~46
N48H	1.36~1.43	13.6~14.3	1000	12.6	1353	17	358~390	45~49
N50H	1.39~1.46	13.9~14.6	1035	13	1353	17	374~406	47~51
N52H	1.42~1.48	14.2~14.9	1042	13.1	1274	16	382~422	48~53
N38SH	1.21~1.27	12.1~12.7	886	11.1	1592	20	287~310	36~39
N40SH	1.25~1.31	12.5~13.1	912	11.5	1592	20	302~326	38~41
N45SH	1.32~1.38	13.2~13.8	976	12.2	1592	20	342~366	43~46
N48SH	1.36~1.43	13.6~14.3	1000	12.6	1592	20	358~390	45~49
N50SH	1.39~1.46	13.9~14.6	1035	13	1592	20	374~406	47~51
N48SH-D	1.36~1.43	13.6~14.3	1000	12.6	1592	20	358~390	45~49
N50SH-D	1.39~1.46	13.9~14.6	1035	13	1592	20	374~406	47~51
N52SH-D	1.42~1.49	14.2~14.9	1050	13.2	1592	20	390~422	49~53
N54SH-D	1.44~1.51	14.4~15.1	1058	13.3	1592	20	390~422	50~55
N35UH	1.16~1.22	11.6~12.2	845	10.6	1990	25	263~287	33~36
N38UH	1.21~1.27	12.1~12.7	886	11.1	1990	25	287~310	36~39
N40UH	1.25~1.31	12.5~13.1	912	11.5	1990	25	302~326	38~41
N42UH	1.28~1.34	12.8~13.4	938	11.8	1990	25	318~342	40~43
N45UH	1.31~1.37	13.1~13.7	976	12.2	1990	25	342~366	43~46
N45UH-D	1.31~1.37	13.1~13.7	976	12.2	1990	25	342~366	43~46
N48UH-D	1.36~1.43	13.6~14.3	1000	12.6	1990	25	358~390	45~49
N50UH-D	1.39~1.46	13.9~14.6	1035	13	1990	25	374~406	47~51
N31AH	1.09~1.16	10.9~11.6	772	9.7	2149	27	231~263	29~33
N34AH	1.15~1.22	11.5~12.2	836	10.5	2149	27	255~287	32~36
N37AH	1.20~1.26	12.0~12.6	886	11.1	2149	27	279~310	35~39
N40AH	1.25~1.31	12.5~13.1	912	11.5	2149	27	302~326	38~41
N42AH	1.28~1.34	12.8~13.4	938	11.8	2149	27	318~342	40~43
N42AH-D	1.28~1.34	12.8~13.4	938	11.8	2149	27	318~342	40~43
N45AH-D	1.32~1.38	13.2~13.8	976	12.2	2149	27	342~366	43~46
N48AH-D	1.35~1.42	13.5~14.2	1000	12.6	2149	27	358~390	45~49
N30EH	1.07~1.14	10.7~11.4	772	9.7	2388	30	223~247	28~31
N33EH	1.12~1.19	11.2~11.9	816	10.2	2388	30	247~271	31~34
N35EH	1.16~1.22	11.6~12.2	845	10.6	2388	30	263~287	33~36
N38EH	1.21~1.27	12.1~12.7	886	11.1	2388	30	279~310	35~39
N40EH	1.25~1.31	12.5~13.1	912	11.5	2388	30	302~326	38~41
N40EH-D	1.25~1.31	12.5~13.1	912	11.5	2388	30	302~326	38~41
N42EH-D	1.28~1.34	12.8~13.4	938	11.8	2388	30	318~342	40~43
N45EH-D	1.32~1.38	13.2~13.8	976	12.2	2388	30	342~366	43~46
N48EH-D	1.35~1.42	13.5~14.2	1000	12.6	2388	30	342~366	43~46
N30TH	1.06~1.15	10.6~11.5	765	9.6	2627	33	223~255	28~32
N33TH	1.12~1.19	11.2~11.9	816	10.2	2627	33	247~271	31~34
N35TH	1.16~1.22	11.6~12.2	845	10.6	2627	33	263~287	33~36
N38TH	1.21~1.27	12.1~12.7	886	11.1	2627	33	279~310	35~39
N40TH-D	1.25~1.31	12.5~13.1	912	11.5	2627	33	302~326	38~41
N42TH-D	1.28~1.34	12.8~13.4	938	11.8	2627	33	318~342	40~43
N45TH-D	1.32~1.38	13.2~13.8	976	12.2	2627	33	342~366	43~46

Coating Type	Physical Properties	Environment of Magnet Application	Thickness of Coating Layer	Pictures
Zinc	Layer with three kinds of color: silver, blue and white, rainbow etc.Coating layer is compact, stable and homogeneous.	Suitable for common environment.	4µm ~ 10µm
Nickel	Homogeneous and Light yellow layer.	NiCuNi：Excellent corrosion resistance. Superior resistance against humidity and heat.	15µm ~ 30µm
Epoxy	Black, gray layer with certain luster.	Suitable for higher corrosive environment.	≥15µm
Al	The coating has silver-white metallic luster, uniform color and clean surface	It is used in high anti-corrosion occasions, and the coating has no shielding effect on magnetic properties.	10µm ~ 25µm
Passivation (Phosphorization)	Colorless or light gray layer	Suitable for the situation of short-term transportation and storage.	≤2µm
Micro Bluing	Colorless or light blue layer	Suitable for the situation of short-term transportation and storage.	≤2µm

Curie Point	℃	310～370
Reversible temp coeffcient of Br 20-120℃	％/℃	-0.1~-0.13%
Reversible temp coeffcient of Hcj 20-120℃	％/℃	-0.4~-0.7%
Density	g/cm³	7.3～7.7
Vickers hardness	Hv	500～700
Bending strength	Mpa	150～400
Compressive strength	Mpa	800～1250
Specific resistiance	μΩcm	110～170
Thermal conductivity	W/(m.℃)	5～15
Coefficient of thermal expansion	10^-6/℃	4～9
Coefficient of thermal expansion	10^-6/℃	-2～0
Specific heat	J/(kg.℃)	350～550
Young’s modulus	GPa	140～170