Available Neodymium Magnet Grades
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Magnetic and Physical Characteristics
Many grades of Neodymium magnets exist to support a variety of industrial applications. The range of Neo grades typically extends from 33 MGOe to 55 MGOe. This range allows for optimizing cost, performance, and operational temperature resistance.
The typical convention for “Grade” is to use the value of the particular magnet alloy’s Energy Density or Maximum Energy Product. Often, there are letters or a two digit number suffix attached to the Grade which indicates the Intrinsic Coercive Force (Hci) level of the magnet alloy. This Hci is a good indicator of the maximum allowable temperature a particular Neo alloy can tolerate before irreversible demagnetizing occurs.
The higher the “Grade number,” the higher the Energy Density. Usually, the higher the Energy Density, the stronger the magnet, but this is very much dependent upon the magnet’s operational environment.
| * Maximum Operating Temperature for this Group is 60°C / 140°F ( L/D ≥0.7) | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Dura Magnet Grade | Common Industry Notation | Residual Induction Br | Coercive Force Hc | Intrinsic Coercive Force Hci | Maximum Energy Product (BH)max |
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| Range | Minimum | Minimum | Range | ||||||
| k-Gauss | Tesla | k-Oersted | kA/m | k-Oersted | kA/m | MGOe | kJ/m3 | ||
| 5011 | N50 | 14.0 – 14.5 | 1.40 – 1.45 | 10.5 | 836 | 11 | 876 | 47 – 51 | 374 – 406 |
| 5211 | N52 | 14.4 -14.8 | 1.44 – 1.48 | 10.5 | 836 | 11 | 876 | 49 – 53 | 390 – 422 |
| * Maximum Operating Temperature for this Group is 80°C / 176°F ( L/D ≥0.7) | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Dura Magnet Grade | Common Industry Notation | Residual Induction Br | Coercive Force Hc | Intrinsic Coercive Force Hci | Maximum Energy Product (BH)max |
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| Range | Minimum | Minimum | Range | ||||||
| k-Gauss | Tesla | k-Oersted | kA/m | k-Oersted | kA/m | MGOe | kJ/m3 | ||
| 3512 | N35 | 11.8 – 12.3 | 1.18 – 1.23 | 10.9 | 868 | 12 | 955 | 34 – 36 | 263 – 287 |
| 3812 | N38 | 12.3 – 12.6 | 1.23 – 1.26 | 11.3 | 899 | 12 | 955 | 36 – 39 | 287 – 311 |
| 4012 | N40 | 12.6 – 12.9 | 1.26 – 1.29 | 11.4 | 907 | 12 | 955 | 38 – 41 | 302 – 327 |
| 4212 | N42 | 12.9 – 13.3 | 1.29 – 1.33 | 11.5 | 915 | 12 | 955 | 40 – 43 | 318 – 342 |
| 4512 | N45 | 13.3 – 13.7 | 1.33 – 1.37 | 11.0 | 876 | 12 | 955 | 43 – 46 | 342 – 366 |
| 4812 | N48 | 13.7 – 14.1 | 1.37 – 1.41 | 10.5 | 836 | 12 | 955 | 45 – 49 | 358 – 390 |
| 5513 | N55M | 14.5 – 15.2 | 1.45 – 1.52 | 12.2 | 971 | 13 | 1035 | 52 – 56 | 414 – 446 |
| * Maximum Operating Temperature for this Group is 90°C / 194°F ( L/D ≥0.7) | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Dura Magnet Grade | Common Industry Notation | Residual Induction Br | Coercive Force Hc | Intrinsic Coercive Force Hci | Maximum Energy Product (BH)max |
||||
| Range | Minimum | Minimum | Range | ||||||
| k-Gauss | Tesla | k-Oersted | kA/m | k-Oersted | kA/m | MGOe | kJ/m3 | ||
| 5014 | N50M | 13-9 – 14.5 | 1.39 – 1.45 | 13 | 1035 | 14 | 1114 | 47 – 51 | 374-406 |
| 5214 | N52M | 14.2 – 14.8 | 1.42 – 1.48 | 13 | 1035 | 14 | 1114 | 49 – 53 | 390 – 422 |
| * Maximum Operating Temperature for this Group is 100°C / 212°F ( L/D ≥0.7) | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Dura Magnet Grade | Common Industry Notation | Residual Induction Br | Coercive Force Hc | Intrinsic Coercive Force Hci | Maximum Energy Product (BH)max |
||||
| Range | Minimum | Minimum | Range | ||||||
| k-Gauss | Tesla | k-Oersted | kA/m | k-Oersted | kA/m | MGOe | kJ/m3 | ||
| 3314 | N33M | 11.3 – 11.8 | 1.13 – 1.18 | 10.5 | 836 | 14 | 1,114 | 31 – 34 | 247 – 271 |
| 3514 | N35M | 11.8 – 12.3 | 1.18 – 1.23 | 10.9 | 868 | 14 | 1,114 | 34 – 36 | 263 – 287 |
| 3814 | N38M | 12.3 – 12.6 | 1.23 – 1.26 | 11.3 | 899 | 14 | 1,114 | 36 – 39 | 287 – 311 |
| 4014 | N40M | 12.6 – 12.9 | 1.26 – 1.29 | 11.6 | 923 | 14 | 1,114 | 38 – 41 | 302 – 327 |
| 4214 | N42M | 12.9 – 13.3 | 1.29 – 1.33 | 12.0 | 955 | 14 | 1,114 | 40 – 43 | 318 – 342 |
| 4514 | N45M | 13.3 – 13.7 | 1.33 – 1.37 | 12.5 | 995 | 14 | 1,114 | 43 – 46 | 342 – 366 |
| 4814 | N48M | 13.7 -14.1 | 1.37 – 1.41 | 12.9 | 1,027 | 14 | 1,114 | 45 – 49 | 358 – 390 |
| * Maximum Operating Temperature for this Group is 110°C / 230°F ( L/D ≥0.7) | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Dura Magnet Grade | Common Industry Notation | Residual Induction Br | Coercive Force Hc | Intrinsic Coercive Force Hci | Maximum Energy Product (BH)max |
||||
| Range | Minimum | Minimum | Range | ||||||
| k-Gauss | Tesla | k-Oersted | kA/m | k-Oersted | kA/m | MGOe | kJ/m3 | ||
| 5017 | N50H | 13.9 – 14.4 | 1.39 – 1.44 | 13 | 1035 | 17 | 1353 | 47 – 51 | 374 – 406 |
| * Maximum Operating Temperature for this Group is 120°C / 248°F ( L/D ≥0.7) | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Dura Magnet Grade | Common Industry Notation | Residual Induction Br | Coercive Force Hc | Intrinsic Coercive Force Hci | Maximum Energy Product (BH)max |
||||
| Range | Minimum | Minimum | Range | ||||||
| k-Gauss | Tesla | k-Oersted | kA/m | k-Oersted | kA/m | MGOe | kJ/m3 | ||
| 3017 | N30H | 10.8 – 11.3 | 1.08 – 1.13 | 10 | 796 | 17 | 1,353 | 28 – 31 | 223 – 247 |
| 3317 | N33H | 11.3 – 11.8 | 1.13 – 1.18 | 10.5 | 836 | 17 | 1,353 | 31 – 34 | 247 – 271 |
| 3517 | N35H | 11.8 – 12.3 | 1.18 – 1.23 | 10.9 | 868 | 17 | 1,353 | 34 – 36 | 263 – 287 |
| 3817 | N38H | 12.3 – 12.6 | 1.23 – 1.26 | 11.3 | 899 | 17 | 1,353 | 36 – 39 | 287 – 311 |
| 4017 | N40H | 12.6 – 12.9 | 1.26 – 1.29 | 11.6 | 923 | 17 | 1,353 | 38 – 41 | 302 – 327 |
| 4217 | N42H | 12.9 – 13.3 | 1.29 – 1.33 | 12 | 955 | 17 | 1,353 | 40 – 43 | 318 – 342 |
| 4517 | N45H | 13.3 – 13.7 | 1.3 – 1.37 | 12.3 | 979 | 17 | 1,353 | 43 – 46 | 342-366 |
| 4817 | N48H | 13.7 – 14.1 | 1.37 – 1.41 | 12.5 | 995 | 17 | 1,353 | 45 – 49 | 358-390 |
| * Maximum Operating Temperature for this Group is 150°C / 302°F ( L/D ≥0.7) | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Dura Magnet Grade | Common Industry Notation | Residual Induction Br | Coercive Force Hc | Intrinsic Coercive Force Hci | Maximum Energy Product (BH)max |
||||
| Range | Minimum | Minimum | Range | ||||||
| k-Gauss | Tesla | k-Oersted | kA/m | k-Oersted | kA/m | MGOe | kJ/m3 | ||
| 3020 | N30SH | 10.8 – 11.4 | 1.08 – 1.14 | 10.1 | 804 | 20 | 1,592 | 28 – 31 | 223 – 247 |
| 3320 | N33SH | 11.4 – 11.8 | 1.14 – 1.18 | 10.6 | 844 | 20 | 1,592 | 31 – 34 | 247 – 271 |
| 3520 | N35SH | 11.8 – 12.3 | 1.18 – 1.23 | 11.0 | 876 | 20 | 1,592 | 33 – 36 | 263 – 287 |
| 3820 | N38SH | 12.3 – 12.6 | 1.23 – 1.26 | 11.4 | 907 | 20 | 1,592 | 36 – 39 | 287 – 311 |
| 4020 | N40SH | 12.6 – 12.9 | 1.26 – 1.29 | 11.6 | 939 | 20 | 1,592 | 38 – 41 | 302 – 326 |
| 4220 | N42SH | 12.9 – 13.3 | 1.29 – 1.33 | 12.4 | 987 | 20 | 1,592 | 40 – 43 | 318 – 342 |
| 4520 | N45SH | 13.3 – 13.7 | 1.33 – 1.37 | 12.6 | 1,003 | 20 | 1,592 | 42 – 46 | 334 – 366 |
| * Maximum Operating Temperature for this Group is 180°C / 356°F ( L/D ≥0.7) | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Dura Magnet Grade | Common Industry Notation | Residual Induction Br | Coercive Force Hc | Intrinsic Coercive Force Hci | Maximum Energy Product (BH)max |
||||
| Range | Minimum | Minimum | Range | ||||||
| k-Gauss | Tesla | k-Oersted | kA/m | k-Oersted | kA/m | MGOe | kJ/m3 | ||
| 2825 | N28UH | 10.4 – 10.8 | 1.04 – 1.08 | 9.6 | 764 | 25 | 1,989 | 26 – 29 | 207 – 231 |
| 3025 | N30UH | 10.8 – 11.4 | 1.08 – 1.14 | 10.1 | 804 | 25 | 1,989 | 28 – 31 | 223 – 247 |
| 3325 | N33UH | 11.4 – 11.8 | 1.14 – 1.18 | 10.7 | 852 | 25 | 1,989 | 31 – 34 | 247 – 271 |
| 3525 | N35UH | 11.8 – 12.3 | 1.18 – 1.23 | 10.8 | 860 | 25 | 1,989 | 33 – 36 | 263 – 287 |
| 3825 | N38UH | 12.3 – 12.6 | 1.23 – 1.26 | 11.3 | 899 | 25 | 1,989 | 36 – 39 | 287 – 311 |
| 4025 | N40UH | 12.5 – 12.9 | 1.25 – 1.29 | 11.4 | 907 | 25 | 1,989 | 38 – 41 | 302 – 326 |
| 4225 | N42UH | 12.8 – 13.3 | 1.28 – 1.33 | 11.6 | 923 | 25 | 1,989 | 40 – 43 | 318 – 342 |
| * Maximum Operating Temperature for this Group is 200°C / 392°F ( L/D ≥0.7) | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Dura Magnet Grade | Common Industry Notation | Residual Induction Br | Coercive Force Hc | Intrinsic Coercive Force Hci | Maximum Energy Product (BH)max |
||||
| Range | Minimum | Minimum | Range | ||||||
| k-Gauss | Tesla | k-Oersted | kA/m | k-Oersted | kA/m | MGOe | kJ/m3 | ||
| 2830 | N28EH | 10.4 – 10.8 | 1.04 – 1.08 | 9.8 | 780 | 30 | 2,388 | 26 – 29 | 207 – 231 |
| 3030 | N30EH | 10.8 – 11.4 | 1.08 – 1.14 | 10.1 | 804 | 30 | 2,388 | 28 – 31 | 223 – 247 |
| 3330 | N33EH | 11.4 – 11.8 | 1.14 – 1.18 | 10.3 | 820 | 30 | 2,388 | 31 – 34 | 247 – 271 |
| 3530 | N35EH | 11.7 – 12.3 | 1.17 – 1.23 | 10.5 | 836 | 30 | 2,388 | 33 – 36 | 263 – 287 |
| 3830 | N38EH | 12.2- 12.6 | 1.22 – 1.26 | 11.3 | 899 | 30 | 2,388 | 35 – 39 | 278 – 311 |
| * Maximum Operating Temperature for this Group is 230°C / 446°F ( L/D ≥0.7) | |||||||||
|---|---|---|---|---|---|---|---|---|---|
| Dura Magnet Grade | Common Industry Notation | Residual Induction Br | Coercive Force Hc | Intrinsic Coercive Force Hci | Maximum Energy Product (BH)max |
||||
| Range | Minimum | Minimum | Range | ||||||
| k-Gauss | Tesla | k-Oersted | kA/m | k-Oersted | kA/m | MGOe | kJ/m3 | ||
| 2835 | N28AH | 10.4 – 10.9 | 1.04 – 1.09 | 9.8 | 780 | 35 | 2,785 | 26 – 29 | 207 – 231 |
| 3035 | N30AH | 10.8 – 11.3 | 1.08 – 1.13 | 10.1 | 804 | 35 | 2,785 | 28 – 31 | 223 – 247 |
| 3335 | N33AH | 11.3 – 11.8 | 1.13 – 1.18 | 10.3 | 820 | 33 | 2,625 | 31 – 34 | 247 – 271 |
| 3535 | N35AH | 11.7 – 12.3 | 1.17 – 1.23 | 10.5 | 836 | 33 | 2,625 | 33 – 36 | 263 – 287 |
| Reversible Temperature Coefficients (0°C to 100°C) | ||
|---|---|---|
| Intrinsic Coercive Force (Hci) | Induction Br (G) | Intrinsic Coercivity Hci (Oe) |
| (KOe) | (%) | (%) |
| 11 | -0.12% | -0.70% |
| 12 | -0.12% | -0.70% |
| 14 | -0.12% | -0.65% |
| 17 | -0.11% | -0.65% |
| 20 | -0.11% | -0.60% |
| 25 | -0.10% | -0.55% |
| 30 | -0.10% | -0.50% |
| 35 | -0.09% | -0.40% |
| α = Δ Br / Δ T * 100 (Br @ 20°C) [ΔT = 20°C – 100°C] β = Δ Hci / Δ T * 100 (Hci @ 20°C) [ΔT = 20°C – 100°C] |
||
| Neodymium Magnets – Physical Properties | ||
|---|---|---|
| Property | Units | Values |
| Vickers Hardness | Hv | ≥550 |
| Density | g/cm3 | ≥7.4 |
| Curie Temp TC | °C | 312 – 380 |
| Curie Temp TF | °F | 593 – 716 |
| Specific Resistance | μΩ⋅Cm | 150 |
| Bending Strength | Mpa | 250 |
| Compressive Strength | Mpa | 1000~1100 |
| Thermal Expansion Parallel (∥) to Orientation (M) | °C-1 | (3-4) x 10-6 |
| Thermal Expansion Perpendicular (⊥) to Orientation (M) | °C-1 | -(1-3) x 10-6 |
| Young’s Modulus | kg/mm2 | 1.7 x 104 |
The listed values are approximate and should be used as a reference. Any magnetic or physical characteristics should be substantiated before selecting a magnet material. Please engage Dura’s magnet Design / Development team before selecting a design path.
Technical Articles
Making Sense of Neodymium Magnet Grades
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