Eddy Current Separator: Difference between revisions
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==The Process== | ==The Process== | ||
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|rowspan=4|[[File:Eddy Current Separator Process.png|450px|right|Eddy Current Separator Diagram. All Rights Reserved.]]<br clear=all>''Schematic Diagram of an Eddy Current Separator<ref name="ref3" />''|| 1. The waste stream is fed onto the conveyor belt and is transported towards the magnetic rotor end. | |||
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| 2. When a piece of non-ferrous metal passes over the magnetic rotor, the magnets inside the shell rotate past the metal at high speed which forms eddy currents to create a magnetic field around the piece of metal. | |||
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| 3. The polarity of that magnetic field is the same as the rotating magnet, causing the non-ferrous metal to be repelled away from the magnet. | |||
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| 4. This repulsion makes the trajectory of the non-ferrous metal greater than that of the non-metallic, allowing the two material streams to be separated<ref name="ref2" />. | |||
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==References== | ==References== | ||
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Revision as of 12:27, 2 November 2021
An Eddy Current Separator (ECS) is a machine that is used to separate and recover non-ferrous metals such as aluminium, copper and brass from non-metallic material in a waste stream[1]. Material is fed onto the conveyor of the separator, which moves it across the magnetic rotor, situated underneath, to cause in separation. The two resultant streams discharge into different bins/compartments with the aid of the splitter which divides the non-ferrous metal from the non-metallic waste such as paper, plastic, wood or auto shredder residue (known as shedder fluff)[2]. This process is usually employed after magnetic separation has removed the bulk ferrous fraction from a scrap material stream[3].
The Magnet Rotor
The key component is the magnetic rotor, which is a series of permanent rare earth magnets mounted on a support plate attached to a shaft. The magnetic rotor is surrounded by, but not attached to, a non-metallic shell which supports the conveyor belt. This allows the rotor to spin independently and at a much higher speed than the non-metallic shell and belt[2].
Benefits
- Very high hit rates
- Very high purity rates
- Compact and flexible
- Removes ranging sizes of non-ferrous materials[1]
The Process
 Schematic Diagram of an Eddy Current Separator[3] |
1. The waste stream is fed onto the conveyor belt and is transported towards the magnetic rotor end. |
| 2. When a piece of non-ferrous metal passes over the magnetic rotor, the magnets inside the shell rotate past the metal at high speed which forms eddy currents to create a magnetic field around the piece of metal. | |
| 3. The polarity of that magnetic field is the same as the rotating magnet, causing the non-ferrous metal to be repelled away from the magnet. | |
| 4. This repulsion makes the trajectory of the non-ferrous metal greater than that of the non-metallic, allowing the two material streams to be separated[2]. |