Magnetic Separation and Metal Detection

MAGNETIC SEPARATION & METAL DETECTION

Solutions for many applications across various industries including food, pharmaceutical, plastics, recycling, aggregate, quarrying powder and bulk industries and more...

Magnetic Separation and Metal Detection
Magnetic Separation and Metal Detection

MAGNETS & MAGNETIC PRODUCTS

As a provider of Total magnetic Solutions we have been supplying permanent and holding magnets into a wide range of industries for over 50 years.

Magnetic Separation and Metal Detection

MAGNET PRODUCTION & MAGNET ASSEMBLIES

A world leader in the design and manufacture of permanent magnets, magnetisation and magnet assemblies.

Magnet production and magnet assemblies
Magnetic Separation and Metal Detection

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Magnetic Separation and Metal Detection

NOW A SINGLE MAGNETIC SEPARATION SOURCE

  • Bunting Magnetics Europe acquires Master Magnets
  • Click learn more below for more details

Magnetising

Magnetisation is the process whereby a permanent magnet material is exposed to a high intensity magnetising field in order to drive the material into saturation and develop the full permanent magnetic properties. The strength of the magnetising field needed is considerably higher than the intrinsic properties of the material and depends primarily on the type of material being magnetised. The older permanent magnetic materials such as AlNiCo’s and Ferrites are relatively easy to magnetise as they only require magnetic fields in the region of 1Tesla which can be generated by a number of methods such as DC electromagnets and even permanent magnet magnetisers. The rare earth magnets on the other hand, mainly Neodymium or Samarium Cobalt, require much higher fields in the range of 3 to 5Tesla. Although it is possible to generate DC magnetic fields of this magnitude using super conducting magnets, it is not yet practical or cost effective for industrial or laboratory situations. Consequently, most magnetising systems utilise capacitor discharge technology to generate a magnetic pulse of sufficient strength to magnetise the material, but of short enough duration to prevent the magnetising coils from overheating.

A typical Bunting magnetising system consists of a capacitor discharge magnetiser, a magnetising fixture and sometimes an additional automatic handling system. Bunting Magnetics Europe manufactures both magnetisers and fixtures in the UK to our own standard design or to bespoke customer designs.

Magnetising fixtures are generally custom designed for each application, and therefore should be the first thing to consider when purchasing a magnetising system. Fixtures can be supplied with many different types of magnetisation patterns from simple 2 pole solenoids, to complex multipole systems. As a long time manufacturer of permanent magnets, in particularly bonded Neodymium ring magnets, Bunting Magnetics have been manufacturing magnetising fixtures for our own internal use for many years, and have developed a particular area of expertise in the design of multipole magnetising systems for radial or axial ring magnet assemblies or sensor magnets.

Our magnetisers come in a number of standard ranges for use in laboratories, small scale production environments or large scale industrial applications. Magnetisers typically have two output voltage ranges dependent on the type of magnetising fixture being used. Low voltage systems, usually up to 1000V, are ideal applications where the speed of the magnetising pulse is less critical, such as for magnetising large blocks of magnet material or magnetic assemblies such as loud speaker magnets where it may be important to limit eddy currents in the magnets or surrounding steel work. High Voltage systems, usually up to 3000V, but occasionally 5000V, are better for multipole applications or high energy magnetising systems where temperature control in the windings is important and the magnetisation pules therefore need to be as fast as possible.