Magnetic Business Cards
![]() |
Part # | L x W x H | Magnetization Pattern | Holding Force Per Foot (lbs) | Specs | Price | Quantity | |
MA1650 | 3.5" x 2" x .015" | Multipole | .98 | Download | $6.50 | Add |
Part # | 1+ | 250+ | 1000+ | Qty. | |
MA1650 | $6.50 | $5.75 | $4.50 | Add |
These Standard Energy (Type D) Flexible Magnetic Business Card Magnets have maximum holding power on one side and pressure-sensitive adhesive backing. (Max Energy Product is .65) One side is a magnet that consists of ferrite in a dark brown thermoplastic binder. The opposite side is coated with a high-tack, pressure-sensitive adhesive. These flexible magnetic strips feature multi-pole magnetization for maximum magnetic strength on the side opposite the adhesive. Simply peel off the backing and adhere to your business card. Sold in packs of 25.
Bunting® Magnetic Business Cards
Bunting® magnetic business cards help you leave a lasting impression with your clients by giving them a business card that stands out and is less likely to get lost. The standard energy, flexible magnet is sized at 3.5” x 2” x .015” to suit the majority of business cards, and features maximum holding power on one side and a pressure-sensitive adhesive backing on the opposite side. They are equipped with multi-pole magnetization for maximum magnetic strength. To attach a standard paper business card, simply peel off the backing of the magnet and adhere to your business card. Magnetic business cards are also a great way to take paper business cards you’ve been given and transform them into magnets, placing them on a magnetic surface such as a file cabinet for a convenient reference.
- Flexible business card magnets are sold in packs of 25.
- All Measurements are in inches (unless otherwise noted)
- Direction of Magnetization (DOM) is through the thickness unless noted
- Unless otherwise specified, magnets will be furnished in magnetized condition
- Holding forces are approximate. These are average values obtained under laboratory conditions. Size, shape, and material of the test piece may affect actual pull forces