Selecting the Right Electromagnet

There are many variables that must be considered in the selection of a proper magnet. To help you get the best magnet for your application, we should have the following information:

Surface of the Work
Is it scaly, rough, flat, machined or of irregular shape?
Size of the Work
Give thickness, width, length and weight, plus area of contact for the magnet
Air Gap
Distance from work surface to face of magnet, whether actually air or non-ferrous material
Composition of the Work
Hot or cold rolled steel, tool steel, high carbon content steel, nickel, carbide, etc.
Heat
Temperature in which the magnet will operate and temperature of the work
Duty Cycle
Will magnet be on 100%, 50%, or 25% of the time?
Method of Operation
Will magnet be turned on & off, manually or automatically? If the latter, how many times per minute?
Send Prints
Or sketches, parts, polaroid shots, digital images and whatever other information will help in selecting the proper magnet
Special Note
The economical pickup and transfer of small parts or scrap require a scrap yard type magnet or a magnetic conveyor. Please consult us.
Two basic types of electromagnets are available: flat-faced and bipolar.

Selecting the Right Electromagnet

Selecting the Right Electromagnet

Flat Faced Magnet
Used when the entire face of the magnet is in direct contact with the work to be held or lifted and the work surface is smooth and flat. This design usually requires less over-all height and is less expensive.

Bipolar Magnet
Has two widely spaced poles or lifting surfaces which cause the magnetic field to “reach out” further. Use the bi-polar type when the magnet has only partial contact with the work piece, handle an irregular shape or when it must work through an air gap.

When work surface is not flat and smooth the magnet cannot make close contact. Scale, rough surface, or nonferrous material between the magnet and work piece create an “air gap”. The greater the gap, the further the magnetic lines of force must reach.

Small Magnets
Generally operate on 12 volts. They will require a rectifier to convert 115 VAC to 12 VDC. Another method of obtaining direct current for magnet operation is through the use of 12 volt batteries.

Large Magnets
Will usually operate on 115 or 220 VDC. A rectifier is required to convert 115, 230, or 460 VAC to 115 or 230 VDC.

Total Wattage
Of all magnets powered by a single rectifier must not exceed wattage rating of the rectifier, e.g., from one to five 3-watt magnets can be used with a 15-watt rectifier.

Thin Gauge Sheet
Magnets to pick up thin gauge, flexible sheet, such as 1/8″, 3/16″, and 1/4″ thick, may require variable power, multiple coil or special poles to maintain holding power and prevent double sheet pickup. Two or more magnets on a spreader bar or “H” frame may be needed to eliminate “peel off”.

Lifting Capabilities
For standard Magnetic Tool Lift Magnets have been derated 50%. Do not exceed the listed capacity. These ratings are established by applying force on the magnet under registered tension until the magnet is pulled from a flat, mild steel test plate. This plate is thick enough so that magnetism cannot be detected on theopposite side of hte plate. When tubing, rounds, or odd shapes must be lifted, the de-rating of the magnet may have to be as much as 75%. The pounds pull of the smaller magnets as shown on the Small Flat-Faced Electromagnets and the Small Bipolar Electromagnets pages are the actual ratings. They have not been derated.

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