1 x 1/2 x 3/16 Inch NdFeB Double Countersunk Bar Magnets N52, Counterbore Countersunk Rectangular Bar Magnet Neo Cup Magnets Pot Magnet, Strong Powerful Countersink Rectangle Square Magnets, Neodymium Iron Boron Blocks, Sintered NdFeB Fishing Magnet, NIB, Neo holding magnets, Permanent Industrial Magnet China supplier factory 1 x 1/2 x 3/16 Inch NdFeB Double Countersunk […]
D6x2.5mm N35SH Disc Magnets Diametral for Rotary Position Sensors, Rare Earth Round Neodymium Magnets, Max. 150 °C Sensor Permanent Magnets
N35SH Disc Magnets Part No.: HSND-0062.5D-35SH
Magnetisation Grade: N35SH
Material: Sintered Neodymium-Iron-Boron (Rare Earth NdFeB)
Plating / Coating: Nickel (Ni-Cu-Ni)
Magnet Shape: Disc, Disk, Round
Magnet Size: D6 x 2.5 mm
Magnetisation Direction: Diametral / Diametrical
Residual Magnetic Flux Density (Br): 1170-1220 mT (11.7-12.2 kGs)
Energy Density (BH)max: 263-287 KJ/m³ (33-36 MGOe)
Coercivity Force (Hcb): ≥ 876 kA/m ( ≥ 11.0 kOe)
Intrinsic Coercivity Force (Hcj): ≥ 1592 kA/m ( ≥ 20 kOe)
Maximum Operation Temperature: 150 °C
Tolerance: ±0.05 mm
Magnet used FOR rotary position sensor, magnets are available ex-warehouse.
Neodymium-iron-boron (NdFeB), or “neo”, magnets offer the highest energy product of any material today and are available in a range of shapes, sizes and grades. Neo magnets can be found in a wide variety of applications including high performance motors, brushless DC motors, magnetic separation, magnetic resonance imaging, sensors and loudspeakers.
Magnetic properties will differ depending upon alignment direction during compaction and upon size and shape. Download individual spec sheets from the table below, or get the full neo catalog here for specific grades and their magnetic properties, including the trade-off in Br (and energy product) for HcJ (intrinsic coercivity, resistance to demagnetization).
Maximum Use Temperature and Corrosion
Determining whether or not to use neo magnets instead of our SmCo magnets, for example, is a function of the maximum temperature of the application, required magnetic output at typical use temperature and total cost of the system.